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A(a). If either A(X):s: A(a) for every x
E
(a, b)
(3.10)
A(X) ~ A(b) for every x
E
(a, b)
(3.11)
or holds, then (3.5) is valid.
A reversal of Theorem 2.30 is given in the same paper by Pecaric (1984g): 3.12. Theorem. Let f: I ~ ~ (I an interval in ~ k ) be a continuous function with increasing increments, and let p be a real n-tuple such that (3.1) is valid. If x;EI (i=I, ... ,n), An(x,p)EI where An(x,p) is defined as in (2.32), and if
Xl :s: Aix, p) :s: ... :s: An(x, p)
(3.12)
holds (or if the reverse inequalities in (3.12) hold), then (3.2) is valid.
3.2. Refinements of Inequalities
87
3.13. Remark. In Theorem 3.12 instead of considering a function with 0 increasing increments we can let f be a P-convex function.
3.2.
Some Refinements of Jensen's and Jensen-Stetfensen's Inequalities
Let f: U ~IR be a real-valued function and U be a convex set in an arbitrary linear real space M. Let I be a finite nonempty set of positive integers. If we define the index set function F by
where 1 A/(x; p) = P ~ P i X i ' liEf
then the following theorem-is valid: 3.14. Theorem. Let f be a convex function on U. Let I and J be finite nonempty sets of positive integers such that In J = 0, P = {pJiElUJ' and x = {Xi}iElU; are real sequences such that Xi E U (i E I U J), PlUJ > 0, and As(x, p) E U (5 = I, J, I UJ). If p/ > 0 and PJ > 0, then F(I U J)
:5
F(I)
+ F(J).
(3.13)
If PIP; < 0, then the inequality in (3.13) is reversed. Iffis strictly convex, then the equality in (3.13) holds iffA/(x, p) = A;(x, p).
Proof. For n = 2, this is a simple consequence of Jensen's inequality and of its reversal. Thus the proof follows by letting Xz= A;(x, p),
3.15. Corollary.
(a) If Pi;::::O (i = 1,
F(In):5 F(In-l) and
:5
and
pz
= P;,
o
, n) and Ik = {1, ... , k}, then :5
F(Iz) :5 0
(3.14)
88
3. Reversals, Refinements, and Converses
(b) If An(x, p)
E
Pl>O,
U and Pi :$ 0 for
i = 2, ... , n,
(3.16)
then the reverse of the inequalities in (3.14) is valid, and
3.16. Remark. Theorem 3.14 and Corollary 3.15 give generalizations of results in Vasic and Mijalkovic (1976), Vasic and Pecaric (1979b), and Pecaric (1986a) (see also Bullen, Mitrinovic, and Vasic (1987, pp. 24-25). D The following result is proved in Pecaric (1984g):
3.17. Theorem. Let I and J be defined as in Theorem 3.14. Let f : U ~IR be a continuous function with increasing increments (U is an interval in IRk), and let p and xbe defined as in Theorem 3.14. (a) Let PI > 0 and PJ > O. If (3.18)
i.e., if (3.19)
then (3.13) is valid, i.e., the function F is subadditive. (b) If PI>O and PJ < 0, and if (3.18) (i.e., (3.19» holds, then the inequality in (3.13) is reversed. 3.18. Corollary. Let the conditions of Theorem 2.30 be satisfied. Then (3.14) is valid. If the conditions of Theorem 3.12 are satisfied, then the reverse of the inequalities in (3.14) holds.
3.19. Remarks. (a) Theorem 3.17 can also be formulated for P-convex functions. (b) For k 2: 2, an interesting function with increasing increments is f(xl' ... ,Xk) = Xl' .. Xk (Xi 2: 0, i = 1, ... ,k). This function is also continuous, thus Theorem 3.17 and Theorems 2.28, 2.30 and 3.11, 3.12 give generalizations of several well-known results concerning Cebysev's inequality for monotonic functions and sequences; see, for example,
89
3.2. Refinements of Inequalities
Popoviciu (1959b), Pecaric (1980b, 1980d), Fink and Jodeit (1984), Vasic and Pecaric (1981b), Biernacki (1950, 1951), and Burkhill and Mirsky (1975). 0 A related refinement of the Jensen-Steffensen Inequality is given in Vasic and Pecaric (1984):
3.20. Theorem. Let x and p be two real n-tuples such that a s: Xl ::s ... ::s X n ::s band O::s Pk ::s P;
for
k
=
1, ... , n - 1,
Then for every convex function f : [a, b] Hn(XI' ..•
,xn )
(3.20)
~ ~
~ Hn-I(XI, •.. ,Xn-I) ~ ..•
~Hz(XI' X2)
~HI(XI) = 0
(3.21)
holds, where Hk(XI, .•• ,
Proof.
xd =
C?k(Xl' •.. , Xk, PI, ..• ,Pk-l,
Pk ) ,
The inequality Hk(XI, . . . , Xk) ~ Hk-I(XI, . . . , Xk-l)
(3.22)
is equivalent to (3.23) where
Note that Xk::S Xk and Xk-I::S Xk-l. Without loss of generality we may assume Xl < ... <x n and 0 < Pk < P; (k = 1, ... , n - 1). By the substitu> e have (3.22) from tions Y I ~ X k - I ' Y 2 ~ X k >X l ~ X k - I ' X 2 ~ X k w (1.7). 0 Another type of refinement of Jensen's inequality is given by Pecaric and Dragomir (1989a):
90
3. Reversals, Refinements, and Converses
3.21. Theorem. in M, and f : U
Let M be a real linear space, U a nonempty convex set a convex function. Then
~ ~
f (P ~ ~~ p xo ) : 5 (P-1 )kII
nl-l
n
0
1)2 :5 (P
0
n
1 :5 P n
'" LJ
'1.··.,'kE1
L
po11 ",pof(!(Xo Ik k II +",+xo)):5'" lk
PiIPiJ(2! (XiI + Xi2))
11,12E1
n
~ 1P;/(Xi)'
(3.24)
where 1= {1, ... , n}, Xi E U (i = 1, ... , n), and Pi> 0 (i = 1, ... , n).
The following theorem (Mitrinovic and Pecaric, 1987a) gives a result on Jensen's inequality via the monotonicity property of certain functions: 3.22. Theorem. Let f be a convex function defined on a convex set U c M (M is an arbitrary linear real space). Let the function g be defined by n 1 ( n ) g(x) = ~ l ~ f qixAi + (r -x) ~ 1A k ,
where qi>O (i=1, x) EZ=lAk E U (i = 1, (xy > 0, Y E I), then
,n) with ~ Z = 1 ( 1 / q k ) = 1 r, E ~ , qixAi+(r, n) for all x in an interval I (I ~ ~ ) . If Ixl :5lyl
(3.25)
g(x) :5 g(y).
Proof. Let s1 E [0, 1] (i, j = 1, ... , n) with E?=l s1 = 1 (j = 1, ... , n). By (3.13) we have (3.26) Using the substitutions n
ai=qiyAi+(r-y)
LA k=l
s{ = -1 ( 1 - X) - (i =1= j), o
b
qi
Y
and we obtain (3.25) from (3.26).
o
s:. = -qi1 ( 1 - Y-X) + Yx- ,
3.2. Refinements of Ineqnalities
91
3.23. Remarks. (a) The function g in Theorem 3.22 is also convex. Indeed, we have Ag(X) + Xg(y)
= ~ ~(Af(qiXAi+ (r-x) kt1 A k) + Xf(q.yA, + (r- y) ~ 1A k)) 2: g(h
+ Xy).
(b) Using the substitutions: lIqi-Wi, q;Ai-Xi, r=l, conclude that (3.25) is also valid if g(x) =
we may
~WJ(XXi + (1- x) ~ 1WkXk),
where Wi >0 (i = 1, ... ,n) are such that I:Z=1 Wk = 1 and XXi + (Ix) I : k ~ W 1 kXkE U (i = 1, ... , n) for all x in an interval I (I ~ ~ ) . D Note that for one-variable convex functions the result in Remark 3.23(b) can be obtained by using Fuchs' generalization of a theorem on majorization. Moreover, in this case we can obtain similar results for Jensen-Steffensen's inequality. The above results give refinements of related discrete inequalities. Next we give some similar results for linear isotonic functionals. Let E be a nonempty set, d be an algebra of subsets of E, and L be a linear class of real-valued functions g : E - ~ having the properties
+ bg) E L for all a, b E ~ ; that is if f(t) = 1 for tEE, then f E L;
L1: f, g E L=;,(af
(3.27)
L2: 1 E L,
(3.28) (3.29)
L3: f E L, E 1 Ed=;' fCEl E L,
where CEI is the indicator function of E 1 (i.e., CEl(t) = 1 for t E E 1 , and 0 for t E E\E 1 ) . It follows from L2, L3 that CEI E L for E 1 E d. We also consider isotonic linear functionals A: L - ~ by assuming:
AI: A(af + bg) A2: f
= aA(f) + bA(g) for f, gEL, a, b E E L, f(t) 2: 0 on E =;, A(f) 2: 0 (A is isotonic).
~ ;
(3.30) (3.31)
Furthermore, we make use of the fact that if L also satisfies L3, then for every £1 E d such that A( C E ) > 0, the functional Al defined for all gEL by A 1(g) = A(gCE)/A(CE) is an isotonic linear functional with A 1 (1) = 1. We observe that A(g) = A(gCEJ + A(gCE\E).
(3.32)
92
3. Reversals, Refinements, and Convenes
3.24. Theorem. Let L satisfy properties L1, L2, and L3 on a nonempty set E, and assume that
1, and may apply (4.22) with p, q, f, g replaced by P, Q=(l-p)-l, fl=(fg'f and gl=g-P; in this q, case wff= wfg, wgf = wg and Wflgl = wJP are all in L. Thus we obtain A(wfP) :5 AP(wfg)A1-P(wgq),
which is (4.22) with the inequality reversed provided A(wg q ) > 0. Finally, if p < 0, then 0< q < 1 and we may apply a similar argument with p, q, f, g replaced by q, p, g, f provided A(wfP) > 0. 0 4.13. Theorem (Minkowski's inequality for isotonic functionals), Let L and A be as in Theorem 4.12. If P > 1 and w, f, g ~ on E with wi", wgP, w(f + g'f
°
E
L, then AlIp(w(f + g'f):5AlIP(wJP)
°
°
+ Al/P(wgP).
(4.24)
If < p < 1 or if p < and A(wfP) > 0, A(wgP) > 0, then the reverse inequality in (4.24) holds.
Proof.
This is an immediate consequence of Theorem 4.12.
4.14. Theorem.
0
Let L and A satisfy conditions Ll, L2 and AI, A2 on a q, base set E. Let p > 1, q = pl(p -1), and w, f, g ~ on E with wf", wg wfg E L. If < m :5 f(x)g-q/P(x) :5 M for x E E, then (M - m)A(wJP) + (mMP - MmP)A(wgq):5 (MP - mP)A(wfg). (4.25)
°
°
q) If P < 0, then (4.25) also holds provided either A (wfP) > Oar A(wg > 0; if o
Oar A(wg > 0. k" and the components of k, k* are even integers, then (14.20) holds for all such Borel-measurable functions
Proof.
First we note that if p > 0, then we have 0:5 mrwg"
:5
wfP :5 M'wg"
on E,
and the inequalities are reversed if p < 0. In particular, this shows that q) A(wfP), A(wg are either both zero or both positive for all p. If q A( wg ) > 0, then, since (x ) = x'' is convex for either p > 1 or p < 0, (4.25) follows from (4.19) by the substitutions in (4.23). If P > 1 and A(wgq) = 0, then (4.25) also holds because it reduces to the case 0:5 (MP - mP)A(wgf). q) q) If p < and either A(wfP) > or A(wg > 0, then A(wg > 0; thus (4.25) holds. (Note that (4.25) does not hold if A(wJP) = A(wgq) = 0
°
°
4.2. Holder's and Minkowski's Inequalities
115
unless A (wfg) =0, which need not be the case.) If 0
4.15. Remark. Theorem 4.14 is a generalization of the Diaz-Metcalf Inequality, which is the special case p = q = 2 with w == 1 and A(t) = 'l.7A or AU) = f ~ f d x . See, for example, Bullen, Mitrinovic, and Vasic (1987, p. 109), and Mitrinovic (1970, pp. 61-63). D 4.16. Theorem. then
Let L, A, p, q, w, f, g be as in Theorem 4.14. IfP > 1,
A(wfg) ~ Ip!lIp \qlllq
( M - m)lIP ImMP - M IMP -mPI
m
PllIq
A lip (wfP)AlI q( wg q).
(4.26) If p < 0 or 0 < p < 1, then the reverse inequality in (4.26) holds provided either A(wfP) > 0 or A(wgq ) > O.
In the case p > 1 or p < 0, (x) = x'' is convex on 1= [m, M]; thus when applying (4.20) with the substitutions in (4.23) we have
Proof.
or (4.27) In the case p > 1, (4.26) dearly holds when A(wgq ) = O. As noted in the proof of Theorem 4.14, we may assume that A(wfP) > 0 and A(wgq ) > 0 for the rest of the proof. If p > 1 and A(wgq ) > 0, then from (4.27) we obtain A(wfg)
p(wfP )A lI q( wg q),
~A-lip A II
where A is determined as in Theorem 3.39(a) with (x) =x P on 1= [m, M]. Using the same notation in Theorem 3.39(a), we find Ii
= (MP
x
- mP)/(M - m), = q(mMP - MmP)/(MP - mr], p(mMP A = p-lql- MmP)I-p(M - m)-l(MP - mP)p;
116
4. Applications of Jensen's Inequality
thus (4.26) follows for p > 1. Now suppose that 0 < P < 1 and P = P -1 > 1. We apply the result in (4.27) with p, q, t. g replaced by P, Q = (1- P )-1, it = (fgr, and gl = g-P, for which wfi = wfg, wgF = wgq, Wf1g1 = wI;,. Moreover, f1g1Q1P = holds, and since m 5,fg-q1p 5, M on E, it follows that
re :
m1 = m" 5, f1glQIP 5, MP
= M1
on E.
Thus the modified (4.27) yields
A(wfg)5, AlA1Ip(wr)A1Iq(wgq), where
A1 = p-1Q1-P(m1Mf- M1mD 1-P(M1 - m1)-1(Mf- mDP. This reduces to the constant term on the right-hand side of (4.26). Finally, if p < 0, then 0 < q < 1 and we may use a similar argument and, with P1 = q, q = p, f1 = g and gl = f We then have f1g1q,lp, = si since plq <0,
?"
The reverse inequality in (4.26) is still valid since A(wgi1 ) = A(wfP) > 0, consequently we obtain
A(wfg) 5, s'" Ipillp
M 1- m1)lIq I:;1- Mq ~m
(M
1
M1
m1qillp
AlIq(wgq)AlIP(wfP).
1
By writing -plq = 1- p, the factor on the right-hand side of this inequality reduces to that in (4.26) after an elementary calculation. This completes the proof of the theorem. 0
4.17. Remark. It is also possible to obtain (4.26) (or the reverse inequality in (4.26)) from (4.25) by using the arithmetic-geometric means inequality. Thus, for example, if p > 1 and p-1 + q-1 = 1, then the left-hand side of (4.25) is bounded below by {p(M - m)A(wr)} IIp{q(mMP - MmP)A(wgq)}lIq, and this reduces to the right-hand side of (4.26), with a factor of (MP - m'']. This shows that the inequality in (4.25) is sharper than that in 0 (4.26). 4.18. Theorem. Let L, A, p, w, f, g be as in Theorem 4.14, and let 0< m < F(x) 5, M and 05, G(x) 5, M for x E E, where F = f(f + g)-qlp,
4.2. Holder's and Minkowski's Inequalities
G
= g(f + g)-qIP.
117
If p > 1, then
A IIP(w(f + gY) 2:: K(p, q, m, M){AIIP(wfP ) + A IIP(wg P)}
(4.28)
holds where K(p, q, m, M) is the constant on the right-hand side of (4.26). If 0 < p < 1 or p < 0, then the reverse inequality in (4.28) holds provided that A(w(f+ gY) > 0 for p < o.
Proof.
This follows immediately from Theorem 4.16.
0
4.19. Remarks. (a) By writing s = ar + bt, where a + b = 1, Holder's inequality yields the following Liapunov inequality for isotonic functionals: (4.29) If we define the means of order r by
M[r](g, A) = A(gr)lIr for
r
=1=
0
and A(1) = 1, then (4.29) can be written in the form M[sl(g, A) :0:; M[r](g, A)(rls)«t-s)/(t-r))M[t](g, A )(tls)«s-r)/(t-r))
for
0 < r <s
< t. (4.30)
Hence by the arithmetic-geometric means inequality we have
r(t - s) -[
t(s - r) -[
-[I I I MS(g,A):O:;Mr(g,A)+Mt(g,A), s t-r s t-r
or equivalently, M[t](g, A) - M[rl(g, A) <: s(t - r) M[t](g, A) - M[s](g, A) - r(t - s)
for
0 < r < s < t.
This inequality was proposed by Hsu (1955) (as a problem for the classical means); see Beesack (1983), and Pecaric and Wang (1988). (b) In Beesack (1983), the last inequality in (a) for the classical means M(r) (Hsu's inequality) was proved by showing that the function M(r- 1 ) is convex for r > O. Here we give a shorter and simpler proof for a more powerful result: The function f(s) = M[lIs](g, A) is log-convex (hence convex) for s > O. Indeed, this follows from the Liapunov Inequality (4.30) by the substitutions t=x- 1, r=y-l, and t(s-r)/[s(t-r)]=A,
118
4. Applications of Jensen's Inequality
r'.
which yields 1- A = r(t - s)/[s(t - r)], s = [Ax + (1- A)y inequality f(AX+(1-A)y):;f(x)y(y)1-A for
O<x
and the
0<1.<1.
Consequently, the log-convexity property of f(s) holds. (c) Holder's inequality for isotonic functionals can be stated in the following form: Let L satisfy conditions L1, L2, and A satisfy conditions A1, A2 on a base set E. If O
E
=f~/A,
IR then (4.31) yields (4.32)
~ Hence the function G(r) = by using the substitutions f ~ ! ' and g f". A(!') is log-convex (thus it is convex) on IR. (e) Let us consider the function
g(x) =
DA(fr Dl f I ~ - x )
l Iqj
(4.33)
where A is a positive linear functional (we assume that all expressions exist, i.e., if we write A(s) we assume that s E L), fk'S are positive functions, qi > 0 (i = 1, ... , n) with 1:1 (l!qk) = 1. By using Remarks 4.19 and Theorem 2.26, we have that g is a log-convex function (thus it is convex), and for IxI:; Iy I (xy > 0) we have g(x):; g(y). This result is proved in Mitrinovic and Pecaric (1987), and it is a generalization of results in Callebaut (1965), Daykin and Eliezer (1968), Godunova and Cebaevskaja (1971), McLaughlin and Metcalf (1967), and Pecaric and Beesack (1986). As a special case we have the following generalization of the well-known Callebaut's inequalities (1965): If 1:; a:; f3 :; 2 or f3 :; a:; 1, then A(fg)Z:;A(fcxgz-a')A(fz-cxg CX) :; A(ff3g Z- (3)A(f z- f3 g f3 ) :; A(fz)A(gZ). (4.34)
(f) Some further generalizations of the previous results are given in 0 Pecaric (1989f).
4.3. Dresher's Inequality
4.3.
119
Dresher's Inequality
First, we consider a two-parameter family of means, Bp,q(f, A), defined by
Bp,if, A) = {A(fp)/A(rnl/(p-q) for
p"* q,
(4.35)
Bp,p(f, A) = exp{A(fP10gf)/A(fP)},
for p, q E IR. We assume that f(x) > 0 for x E E, JP E L, JP logf E L for all p E IR, that L satisfies Ll, L2, and that A: L ~IR satisfies AI, A2. When applying the known result for convex functions
(xz -Xl)-I{cp(XZ) - cp(Xln:s; (yz - Yl)-I{cp(yZ) - CP(Yl)} Xz:s; Yz,
Yl "*Yz
to the convex function cp(x) = 10gA(r), we can obtain
Bxz,x,(f,A):s; B)Iz,y,(f, A) for
Xl:S; Yh Xz:S; Yz and XI "* Xz,
Yl "*Yz.
(4.36)
We now show that (4.36) holds even if Xl = Xz or Yl = Yz. To prove this we use the fact that M[r1(g, A) is an increasing function of r on IR and, in particular, that
A(fx,-xZ)lI(x,-xz) :5 exp(A(logf):s; A(fx2-X,)1!(xz-x,) for
Xl < Xz. (4.37)
We then apply (4.37) to the isotonic linear functional AI: E ~IR defined for certain gEL (see Lemma 4.11) by Ai(g) = A(rig)/A(r') for i = 1, 2. By taking i = 1, the right-hand inequality (4.37) reduces to
Bx"x,(f, A):s; Bxz,x,(f,A) for
Xl < Xz.
Similarly, by taking i = 2, the left-hand inequality of (4.37) reduces to
Bx2,x,(f, A) :5 Bx2,xz(f, A) for
Xl < Xz.
These two inequalities show that (4.36) is valid even when Xl = Xz or Yl = Yz· Note that (4.36) implies that Bp,if, A) is an increasing function of both p and q for all p, q E IR.
4.20. Remarks. (a) As in Stolarsky (1975), let us take E = [x, y] for fixed x, Y with 0 < X < Y < 00, P = s - 1, q = r - 1, f(t) = t, and
f y
A(g) =
x
get) dtl(y - x),
120
4. Applications of Jensen's Inequality
where L is the set of all bounded measurable functions on E. Then the means in (4.35) become, when writing E(r, s) = Bs-I,r-I(t, A),
r (yS _ XS)}II(s-r) E(r,s)= {;(yr_xr) for E(r, 0) = E(O, r) E(r, r)
yr
xr
= { r(lny -lnx)
rs =1= 0,
r=l=s, }llr for
r =1= 0,
= e- lIr(x 'l yY') II(x' - Y') for r =1= 0, X
and E(O, 0) = yXy. By (4.36), the function E(r, s) is increasing in both r and s. These means were introduced by Stolarsky (1975), and have been considered by Leach and Sholander (1978,1983). The proof of the monotonicity property of E(r, s) given in Leach and Sholander (1978) appears to be more difficult than that given above. (b) In (4.35), take E={1,2, ... ,n}, f(k)=ak>O(kEE), and A(f) = I : Z ~ lakin. Then
B p . q ( f , A ) = D ( P , q ) = { * a ~ / ~ a kforr ( pp=l=q, -q) D(p, p)
= exp{
~ a ~log s, / ~af },
becomes the Gini-Dresherrnean (for sums), introduced by Gini (1926) and Dresher (1953). Again we can conclude that D(p, q) is increasing in both p and q; see Brenner (1978, Section 3), Bullen, Mitrinovic, and Vasic (1987, pp. 189-190) and the references given there. 0 For a second result related to the Gini-Dresher means we prove the following generalization of Dresher's inequality (1953).
4.21. Theorem. Let A, B: L- ~ be isotonic linear functionals. If fi, u;:E-[O, oo) with f'[, (1:lfiY, u ~ , (1:7u;yEL, wherep2=l>r>O and A(uD > 0 for 1:5 i :5 n, then n
{
)p}lI(p_r)
~fi B( ~ u;)' A(
:5
{A(ff)}II(p-r).
n
~
B(uD
4.3. Dresher's Inequality
Proof.
121
By Minkowski's inequality for isotonic functionals, we have
Hence
={ x
n
~ [(A(ff))lIp-r)](p-r)!p
}p!(p-r)
n {
~ [(B(uD}-lI(p-r)](p-r)!(-r)
}-r!(p-r)
n
:S
2: A(ff)lI(p-r)B(uD-lI(p-r) 1
follows from the basic Holder's inequality for sums with the conjugate indices P = (p - r)/p and Q = (p - r)/( -r). D Dresher (1953, Section 7) dealt with the special case n = 2, B = A, E = [0, 1], and A(t) = fbi du. A simpler proof, also for this case (essentially the proof given above), can be found in Danskin (1952). A special case for 1 :S P :S 2 and r = p - 1 was treated earlier by Beckenbach (1950). See also Beckenbach and Bellman (1961, 1965, pp. 27-28) for other proofs of the results of Beckenbach and Dresher. The following is a simple consequence of the above result: Let a, b, p, q be positive n-tuples, a E A, b e B, A x B be a convex set. If 0 < r < 1 < S, then
is a convex function on A x B. The proof of this result can be found in Godunova (1967a).
122
4. Applications of Jensen's Inequality
4.4.
Beckenbach's Inequality
Let E be a nonempty set, .sI1 be an algebra of subsets of E, and let L be a linear class of real-valued functions satisfying conditions L1-L3 defined in (3.27)-(3.29). The following two results are given in Pecaric and Beesack (1987b): 4.22. Theorem. Let L satisfy L1, L2, L3 on a nonempty set E and let A be an isotonic functional on L. Suppose E 1 E.sI1 has A(C E,) > 0 where E 2 = E\E l' Then for every nonnegative gEL such that gP E L (p > 1) and A(gCEJ >0, we have A(gP)1/P/A(g) 2 : : A ( g ~ Y / P / A ( g E t ) '
(4.38)
where
First observe that A(g) 2:: A (gC Et) > 0 and A(gE1) > A (gCEJ > 0; thus both sides of (4.38) are well-defined. Applying Theorem 3.26 with A replaced by A 1(g)=A(g)/A(1), F(x, y) =X llP/y1/P, ep(x)=xP, and with 1= J = [0, (0), we have
Proof.
A(gP)1/p / A(g) 2:: inf A ( g ~ ' . X ) l /A(gE IP t' x),
(4.39)
XE[
where gE,.x(t)
= g(t)CE,(t) + xCE,(t).
Hence we have By elementary calculus we find that the minimum value of k(x) = {A(gPCE,) + x PA (C Ez)}lIP/ {A(gC E,) + XA(CE2)},
x> 0
is attained at x = {A(gPCEJ/A(gCEJ}lI(p-l). Thus (4.38) follows from (4.39). 0 4.23. Theorem. Let L satisfy Ll, L2, L3 on a nonempty set E, and let A be an isotonic linear functional on L. Suppose the nonnegative functions t. g: E ~'U? are such that [P, gq,fg E L, where p > 1, p-1 + «:' = 1. If E 1 E .sI1 has A(fgCEJ > 0 and A(gqCE2) > 0 where E 2 = E\£1, then A (fP)lIPjA(fg) 2 : : A ( j ~ , ) l I P j A ( j g ) ,
(4.40)
4.4. Beckenbach's Inequality
123
where
Proof. We apply Theorem 4.22 to the functional A1(gl) defined for certain g l : E ~ ~by A1(gl)=A(kg1)/A(k), with k=gqEL. Since A ( k ) ~ A ( g q C E 2 by » 0 Lemma , 4.11 and the fact that <jJ(u)=u P is convex on 1= [0,00), we have
for all functions gl: E ~ ~ for which gqgl ELand gqgf E L. But this is precisely the inequality corresponding to (2.6) for the functional A1(gl) and <jJ(u) = u", and this in turn implies the validity of Theorem 3.31, and hence that of Theorem 4.22 with A = AI. Consequently, we may apply Theorem 4.22 with the function g replaced by gl = fg- q /p because both A1(gl C E) > 0 and A1(CE,} > 0 hold. Now gqgl = fg and gqgf = JP; thus
It is easy to verify that (4.38), with A and g replaced by Al and gl, respectively, reduces to
(4.41) where
gdt)
= gl(t)CE,(t) + {A(JPCE)/A(fgCE)}1I(p-IlCE2(t).
Hence by 1/(p -1) = q -1 = q/p, we have
gqgE , = g{fCEI + [gA(JPCE,/A(fgCE)]q/PC E,} = fgE " g q g ~ =, JPC E, + [gA(JPC E,/A(fgCE,WCE2 = It, and so (4.40) follows from (4.41).
0
4.24. Remark. (a) Beckenbach's inequality (1966) is the special case of Theorem 4.23 corresponding to E = {1, 2, ... , n}, £1 = {1, 2, ... ,m} (where 1:s: m < n), L = ~ n , the vector space of all real n-vectors a=(al, ... ,a n ) , and A(a)=I:7a;. Let a=(al, ... ,a n ) , b= (b 1 , . . . , b n ) be two n-tuples of positive real numbers, and p, q be real numbers such that p-l + q-l = 1 (p > 1). If 0 < m < n, then P ( n~af )l/P( n~a.b, )-1 ~ (n~ iif)lI ( n~ii;b; )-1 ,
(4.42)
124
4. Applications of Jensen's Inequality
where
a, ii, = I
{ (b i
m
m
1=1
1=1
2: a)/2:
for
1 ~ i ~ m,
for
m
qlp
ajbj)
+ 1 ~ i ~n,
and the equality in (4.42) holds iff iii = a, for all i. The inequality in (4.42) is reversed if p < 1 and p *0. Furthermore, for m = 1 (4.42) reduces to HOlder's inequality. (b) Some related results are also given in Pecaric and Beesack (1987b). (c) In the same fashion we can give generalizations of Theorem 4.23 and Corollaries 3, 4 in Bullen, Mitronovic, and Vasic (1987, pp. 258-260). 0
4.5. Aczel's and Related Inequalities We noted that from Jensen's inequality we can easily obtain Holder's inequality. Similarly, from Theorem 3.1 (the reverse Jensen's inequality) we can obtain Aczel's (1956) (Mitrinovic, 1970, pp. 57-58) and Popoviciu's (1959b) inequalities, and their proofs can be found in Vasic and Pecaric (1982b). The ideas can be used to prove more general results. First, we note that the following generalization of Theorem 4.22 is valid:
4.25. Lemma.
Let E, L, A, t/J be defined as in Lemma 4.11 and assume that pEL with p ~ Oon E and O < A ( p ) < U (ua-A(pg))/(uE ~ , A(p)) E I (a E I), pg ELand pt/J(g) E L. Then t/J (
Proof.
ua - A(pg)) > ut/J(a) - A(pt/J(g)) . u -A(p) u -A(p)
(4.43)
By letting p=u,
in Theorem 3.1 for n
q = -A(p),
= 2,
b = A(pq)/A(p),
i.e., from
A..(pa+qb»_pt/J(a)+qt/J(b) ." p+q p+q
for
q < 0, P
+ 1 > 0, pa+qb p+q
E
I,
4.5. Aczel's and Related Inequalities
125
we have 4J(ua - A(pg)) ~ u4J(a) - A(p)4J(A(pg))/A(p)). u-A(p) u-A(p)
By applying Lemma 4.11 we have (4.43).
0
4.26. Theorem (Aczel's inequality for isotonic functionals). Let L satisfy Ll, L2, and A satisfy A1, A2 on a base set E. IfF, s'. fg ELand g ~- A(g2) > 0 (or f ~ - A(F) > 0), where go, fo are real numbers, then (fogo - A (fg))2 ~ ( f ~- A ( f 2 ) ) ( g- ~ A (g2)).
(4.44)
4.27. Theorem (Popoviciu's inequality for isotonic functionals). Let A and L be as in Theorem 4.26. If P > 1, q > 1, p-l + «: = 1, f, g ~ 0 on E, I", s". fg E L, and fo, go are positive real numbers such that (4.45) then
(f£ - A (jP))lI P(gg - A(gq))lIq 75, fogo - A(fg).
(4.46)
In the case 0 < P < 1 and A(g!l) > 0 (or p < 0 and A(fP) > 0), the reverse inequality in (4.46) holds.
Proof.
By applying the substitutions
4J(x) =xP (p > 1),
in (4.43), we obtain (fogo - A(fg)Y ~ (f£ - A (fP))(gg - A(gq)Y-l
(4.47)
if the first condition in (4.45) is satisfied. If the second condition is also satisfied, then from Holder's inequality we have A(fg) < A (fP)lIp A(gq)lIq < fogo, i.e., fogo - A(fg) > O. Thus from (4.47) we obtain (4.46). 0
4.28. Remark. Note that for p = 2, we obtain Aczel's inequality from (4.47). Thus (4.47) is a generalization of A C Z ( ~ I ' sand Popoviciu's inequalities. 0 4.29. Theorem (Bellman's inequality for isotonic functionals). Let A and L be as in Lemma 4.25. Let f, g ~ 0 on E with I", gq, (f + g) E L, and fa, go be positive real numbers satisfying (4.48)
126
4. Applications of Jensen's Inequality
If p > 1, then «(fg - A(fP»lIP(gg - A(gP»lIPY:S (fo + goY - A«(f + gY). (4.49)
If 0 < p < 1 or p < 0 and A(fp) > 0, then the inequality in (4.49) is reversed.
Proof. We give proof for p > 1 only; the proof for the other case is similar. Using (4.48) and the Minkowski Inequality we have (fo + goY> (A(fP)lIp
+ A(gP)lIPY
From the discrete Minkowski Inequality for n «a1
+ b 1Y + (az + b zy)lIp :s (af +
~ A « ( +f gY)·
= 2, i.e.,
a ~ ) l I P+ (M + bf)lIP ,
the substitutions
and the Minkowski Inequality, we have
«(fg - A(fp»llp + (gg - A(gP»lIPY :s (fO + goY - (A(fp)llp + A(gP)lI PY :s (10 + goY - A«(f + gY).
0
4.30. Remark. The last inequality in the above proof is an interpolation of (4.49), and it is a generalization of a result in Mitrinovic and Pecaric (1988a). Similarly we can prove Theorem 4.27 by using only Holder's inequality, i.e., we can obtain a similar interpolation of Popoviciu's inequality. Of course, we can also obtain other results similar to those that can be obtained from HOlder's inequality. 0
4.6.
Further Generalizations of Holder's and Minkowski's Inequalities
Let us further consider the generalized means defined in Section 4.1, and assume that I = (a, b), -00:S a < b < 00, 1J11"'" 1J1n: I ~ ~ are continuous and strictly monotonic, X: I ~ ~ is continuous and increasing; L and A satisfy the conditions Ll, L2 and AI, A2 defined in (3.27)-(3.31), with A(l) = 1 on a base set E; gl" .. , gn : E ~ ~ and f:I1 x··· x I n ~ ~ are real-valued functions such that gl(E) c 11, ... , gn(E) c In, 1J11(gl), ... , 1J1n(gn), x(f(gl, ... , gn» E L.
4.6. Further Generalizations
127
We consider the inequality of the form
MX(f(gl, ... ,gn), A) =Sf(M"'l(gl' A), ... ,M"'n(gn, A)), (4.50) and observe
4.31. Theorem. A necessary and sufficient condition for (4.50) to hold is that the function H(Sl' ... , sn) = x(f(1J11 1(Sl)' ... , 1J1;;\sn))
is concave. If H is convex, then the inequality in (4.50) is reversed. Proof. McShane's inequality (see Theorem 2.6 and Remark 2.11(b)) for the function H becomes x(f(1J111(A(fr)), ... , 1J1;;l(A(fn)))) 2':A(X(f(1J111(fl), ... , 1J1;; 1 (fn))))' (4.51) Thus if we let t.
= 1J1i(gi) (i = 1, ... , n), then (4.51) becomes
X(f(M"'l(gl, A), ... ,M"'n(gn, A))) 2':A(X(f(gl' ... ,gn))), (4.52) which is equivalent to (4.50).
0
4.32. Remark. For the special case of discrete functionals with n = 2, this result is given in Beck (1970) (see also Bullen, Mitrinovic, and Vasic (1987, pp. 246-255). 0 The following two corollaries can be proved as in Beck (1970):
4.33. Corollary. Assume that f(x,y)=x+y, and let H(s,t)= X(1J11\s) + 1J12 1(t)), E = 1J1U 1 J 1 ~ , F = 1 J 1 ~ / 1 J 1 ~ , G = X'/ X", and all of 1J1;, 1 J 1 ~ , X', x", 1 J 1 ~ , 1 J 1 ~ be positive. Then Mx(gl + gz, A) =s M"'l(gl, A) + M"'2(gZ, A) holds iff G(x + y) 2': E(x) + F(y). 4.34. Corollary. Assume that f(x, y) =xy, and let H(s, t) = X(1J11 1(S)1J12 1(t)), A(x) = 1J1;(x)/(1J1;(x) + x 1 J 1 ~ ( x ) ) B(x) , = 1 J 1 ~ ( x ) / ( 1 J 1 ~ (+x ) X1J1~(x))C , (x) = X'(x)/(X'(x) + xx"(x)), and 1J1;, 1 J 1 ~ , X', X", 1 J 1 ~ , 1 J 1 ~ be positive. Then
MX(glgZ,A) =s M"'l(gl, A)M"'2(gZ'A) holds iff C(xy) 2':A(x) + B(y).
128
4. Applications of Jensen's Inequality
Several other results related to Holder's and Minkowski's inequalities will be given in other parts of this book. We complete this section by observing the following general result in Bourbaki (1952, pp. 9-14) (see Mitrinovic, 1970, pp. 355-56, and Kuczma, 1985, pp. 203-4): Let P be the set of all mappings of a set S into the nonnegative reals. Let M be a mapping of P into the nonnegative real numbers satisfying (i) M(O) = 0, M(At) = AM(t), where A> 0 and f E P; (ii) f(x)::5 g(x) for all XES and f, g E P implies M(t)::5 M(g); and (iii) M(f + g)::5 M(t) + M(g) for all f, g E P. Let h(t l , . . . , tn) be a real-valued function of n real variables t l , . . . , t n which is defined and continuous for t, 2= 0 (i = 1, , n). Let h have the following properties: (iv) inequalities ti > 0 (i = 1, , n) imply , Atn) = that h(tl>.'" tn) > 0; (v) if A> 0, then h(Atl, Ah(tl, ... , tn); and (vi) the set of all points (t l, ... , tn) in En satisfying t, 2= 0 (i = 1, ... , n) and h(tl>' .. ' tn) ~ 1, is convex. Then (a) fl , ... .t; E P implies
M(h(fl' ... ,fn))::5 h(M(fI), ... , M(fn))'
(4.53)
(b) O
2= 1
(4.54)
and f, g E Pimply
M«f + g)P)lIP::5 M(fP) lip + M(gP)lIP.
(4.55)
4.35. Remark. Some related results were obtained by You (1989).
o 4.7.
Some Inequalities
fOl"
Complex Functionals and Norms
As in Sections 2.1 and 3.2, we assume that L satisfies cOnditions L1, L2 (defined in (3.27) and (3.28)) on a base set E, and that A is an isotonic linear functional on L. We consider the class
L= and the functional
A:L
{ f : E ~ C Ref , E
L, Imf E L},
~C defined by
A(t) = A(Ret) + iA(lmt) = Re(A(t)) + i Im(A(t)). Clearly
A is a complex linear functional on L; that is, A(af + {3g) = aA(t) + {3A(g) for f, gEL.
In the following we give some simple properties of A.
a, {3
E
(4.56)
C. (4.57)
4.7. Some Inequalities for Complex Functionals and Norms
Theorem 4.36.
(a) Iff ELand If I E L, then (4.58)
IA(f) I :5A(lfl)·
(b) Iff E L, If I E L, and a - 8:5 argf(t):5 a 8 are real numbers such that 0 < 8 < rr/2, then
+ 8 for all
tEE, where a,
IA(f)I2= (cos 8)A(lfl).
(c) If in (b) we have a < argf(t):5a then
+8
(4.59)
for all tEE (0< 8 < rr12),
Vi IA(f)I2= 2: A(lfl)·
Proof.
129
(4.60)
(a) For arbitrary but fixed 8 E IR we have Re(eiOA(f» = Re(A(ei0f) = A (Re(ei0f) :5A(lfl).
Suppose that A(f) = Reit • Take 8 = -t to obtain IA(f)1 = r = Re(e-itA(f) :5A(lfl).
(b)
IA(f) I = le- iaA(f)I2= Re e-iaA(f) = A[lfl Re
ei(arg/-a)]
= A(Re(e-iaf)
= A(lfl cos(argf - a»
2= A(cos 8 If I) = (cos 8)A(lfl).
(c) For an arbitrary but fixed complex number z = x + iy, we have Izl2= (Vi12)(lxl + Iyl). Hence IA(f) I = le-iaA(f)I 2= Vi
V;
{IRe(e-iaA(f)1 + IIm(e- iaA(f»1}
= 2: {A(lfl cos(argf -
a»
.
+ A(lfl sm(argf -
a»},
or Vi IA(f)I 2= 2: A(lfl [cos(argf - a)
+ sin(argf -
am·
Since the function cosx+sinx=h(x)2=h(0)=h(rr/2)=1 rr/2, (4.60) follows. 0
for O:5x:5
Note that it follows from (4.59) and (4.60) that if f E L, If I E L, and + 8 for all tEE, where 0 < 8 < rr/2, then
a :5 argf(t) :5 a
V IA(f)1 2= max { 2' cosi8} A(lfl)·
(4.61)
130
4. Applications of Jensen's Inequality
4.37. Remark. (a) The inequality in (4.59) is a generalization of an inequality of Petrovic (1933), and (4.61) is a generalization of a result in Vasic, Janie, and Keckic (1971), namely, the inequality n
I
~ Zk
I
2:
max
{Vi T' cos ()}
n
~ IZkl
for
a s: arg Zk
:5
a
n + () < a +"2'
o
4.38. Theorem. If g: E -- ~ and f: E -- C are such that g2 E L, Ifl 2 E L, Ifgl E L, fg E L, and FE L, then
IA(fg)12:5 ~ A(g2){A(lfI2) + IA(f2)1}. Proof.
II = eiaf,
First we show that there exists a real number a then
A(gRelI)2:0 and
(4.62)
E
~
such that if
A(g Imh) =0.
It then suffices to prove the second of the two identities because, if necessary, we may replace f1 with (-f1) (that is, a by a + n), to yield the first. Let
k(a)
= A(g Im(eiaf) = A(g If I sin(a + argf).
Then k(O) = -k(n). Thus it suffices to prove that k is continuous on [0, n]. But this follows from
Ik(a) - k(ao)1
= IA(g If I [sin(a + argf) - sin(ao + argf)]) I :5IA(lgl . If I . la - aol)! = la - aol A(lgfl)·
With this choice of a, we have
Thus we have
by the special case p = q = 2 of the generalized Holder's inequality. Since 2(Re 1I)2 = Ifd2 + Re(fi) we have
= If/ 2 + Re(fi),
4.7. Some Inequalities for Complex Functionals and Norms
131
But A(Re(fi» = ReA(fi) ~ IA(fDI = IA(F)I;
hence (4.62) follows.
D
Note that the inequality in (4.62) is a generalization of an inequality involving sums due to De Bruijn (see, for example, Mitrinovic, 1970, pp. 313-314). It is an improvement of the generalized Cauchy Inequality IA(fgW ~ A ( l f I 2. A(g2), )
since we have IA(F)I ~ A ( l f I 2by ) (4.58). Our next result concerns a generalization of the well-known inequality of Bohr (see Mitrinovic, 1970, p. 312), or an extension of the inequality 2 n
~ Zk
1
n
n
~ ~ ak IZkl2 for
Zk E
and
1[,
2: aJ;l = 1. 1
I
4.39. Theorem. Let f: E ~I[ and p: E pll(l-r), IfI, plfl', and f E L, then IA(f)lr
~[0,
00). If for r > 1 we have
~ A ( p l l ( l - r ) y - I Ifn. A ( p
(4.63)
Proof. We use (4.56) and HOlder's inequality (Theorem 4.12) with conjugate exponents r, r/(r - 1) to obtain IA(f)lr ~ A ( l f I=YA(p-lIrplir IflY ~ A ( p l l ( r - l ) y - I Ifn. A ( p Similarly, using (4.62) we obtain a refinement of this result for r
D
= 2: (4.64)
provided that f E L, pF E L, and r:'. If I, plfl 2 E L. This follows as above with r = 2, except that (4.62) is used in place of Holder's inequality (with the substitutions g ~p-112 and f ~p1l2f). The inequalities (4.63) and (4.64) are generalizations of results given in Vasic and Keekic (1971b) which deal with the case E = {1, 2, ... ,n} and A(f) = 'L.Uk' 4.40. Theorem. Let
(4.65)
132
4. Applications of Jensen's Inequality
If tjJ is concave and decreasing, then the reverse of the inequality in (4.65) holds.
Proof. By (4.58) we have IA(!)I =sA(lf!). Thus (4.65) follows from the properties of tjJ and Jessen's inequality (2.6). For the reverse inequality, just apply (4.65) to - tjJ. 0 Now for given f : E -- C with f cos e
E
L, let us define the constant
if a -
e =s argf(t) =s a + e for e E (0, ~ ) ,
some a
c, = m a x { ~cos , e}
E
IR, and all tEE,
if a =s argf(t) =s a + e for some a
o
C, by
E
e E (0, ~ ) ,
IR, and all tEE,
otherwise.
Then we have 4.41. Theorem.
(a) A and
A satisfy
1 A(lf!) =s -IA(!)I for f
c,
E
L,
If I E L.
(4.66)
(b) If cjJ: [0, oo]__ 1R is concave and increasing and if A(l) = 1, then A(cjJOfl» =s
c j J ( ~ IAU)I)
(4.67)
f
provided that f E L, IfI E L, and cjJ(lf!) E L. If cjJ is convex and decreasing, then the reverse of the inequality in (4.67) holds.
Proof. Inequality (4.66) follows from (4.59) and (4.61), while (4.67) follows from Jessen's inequality (2.6) and (4.66). 0 4.42. Theorem. Let L, A satisfy conditions Ll, L2 and Ai, A2 defined in (3.27)-(3.31), respectively, and let gEL. If O=sg(t) =sA(g) for all tEE, tjJ: [0, oo) __ 1R is convex with tjJ(O) = 0, and tjJ(g) E L, then A(tjJ(g» =s tjJ(A(g».
(4.68)
4.7. Some Inequalities for Complex Functionals and Norms
133
Proof. This follows from Theorem 12 of Beesack and Pecaric (1985a) with Xo = O. 0 Note that in the case A(1) = 1, equality in (4.68) holds by (2.6). 4.43. Theorem. and iff E
L, IfI E
If ep is concave and increasing on [0,00) with ep(O) L, ep(lfl) E L, and If(t)1 :o:;A(lfl) for all tEE, then
ep(I.4(f)I) :o:;A(ep(lfl))· Proof.
=0
(4.69)
Since -ep is convex, it follows from (4.68) and (4.58) that A(-ep(lfl):o:;
-ep(A(lfl»:o:; -ep(I.4(f)I).
0
4.44. Remark. By applying (4.61) and (4.62) we can obtain additional generalizations of Bohr's inequality similar to those given in Vasic, Janie, and Keckic (1971), and Kocic and Maksimovic (1973). 0 Using (4.65) together with Lemma 4.11, we can prove, as in Theorem 2 of Kocic and Maksimovic (1?73), the following result: Let p(t) > 0 for tEE and ep: [0, o o ) ~IR be strictly convex, with ep(uv):o:; ep(u)ep(v) for u, v> O. Let 1jJ(t) = ep(t)/t for t > 0 and 1jJ(0+) = 0, 1jJ(00) = 00. If X(t) = 1/1jJ-\t), then
4.45. Theorem.
ep(I.4(f)I) :0:; 1jJ(A(X(p)))A(pep(lfl)) holds provided that f E L, IfI E L, x(p) E L, x(p )ep(x(p) IfI) E L, and A(X(p))> O.
pep(lfl) E L,
Note that the inequality in (4.63) is a special case of this result. In the same fashion we can prove converse inequalities similar to those in Vasic, Janie, and Keckic (1971), Kocic and Maksimovic (1973), and Pecaric and Janie (1988) by using the other parts of Lemma 4.11. Similar results for norms can be obtained by using the same arguments. First, we observe the following theorem (Pecaric and Dragomir, 1989a): 4.46. Theorem.
Iffis an increasing convex function for x
2:
0, then (4.70)
where Pi 2: 0, P; = ~ 7 ~ Pi' 1 Xi E V (i = 1, ... , n), and V is an arbitrary normed vector space with norm 11·11.
134
4. Applications of Jensen's Inequality
As a special case of this inequality we have
I I ~xl :s ( ~ 1p}I(1_,»)'-1 ~Pi Ilxill'
for
r> 1.
(4.71)
Similarly, by the reverse of Jensen's inequality, the reverse of the inequality in (4.70) holds under the same conditions on f for the following values of the p/s:
Pi :s 0 (i
Pl>O,
= 2, ... , n) and P; > O.
(4.72)
Also note that if
qi:S 0 for i = 2, ... ,n, and q1:s
( ~ z l q i l l l ( l - ' »1-', ) (4.73)
then (4.74) As a consequence of (4.71) and (4.74) we then have
Ilxl + x211' II xllI' II xzll' - , , - - - ~ - = . : . c . . . . ~_ _ + __ u+v
u
v
for
uv(u+v»O,
II x1 + xzll':s /./X111' + Ilxzll' for uv(u + v) <0, u+v
u
(4.75)
v
where 1 :s r ~ 2. Another generalization of (4.71) is given in Kocic and Maksimovic (1973). A similar result is also given in Pecaric and Janie (1988). A special case of those results is the following result of Delbosco (1980): (4.76) where Xi EX (i = 1, ... , n), and the constant cp,n = nP - 1 for P ~ 1 and cp,n = 1 for O:s P < 1 is the best possible. If z and ware complex numbers and A ~ 2, then van der Corput and Beth (see Mitrinovic, 1970, p. 322) showed that [z + wl A+ [z -
W I A ~ 2 ( l z I IwI A +A).
(4.77)
Klamkin (1975) extended this inequality by showing that z,
2: IDIVI + DzVz + ... + O n V n I A ~ 2 IVilzt n(~
(4.78)
4.7. Some Inequalities for Complex Functionals and Norms
135
where A> 2 or <0, D; = -lor 1 (i = 1, ... , n), the V;'s are vectors in Em and the summation on the left-hand side of (4.78) is taken over all 2n points of (D1 , • . . , Dn ) . The inequality is reversed for 0 < A < 2, while for A= 0,2 it becomes an identity. A geometric interpretation of this result corresponding to the case A = 1 is that: For all parallelotopes of given lengths, the rectangular one has the largest sum of the lengths of the body diagonals. Its proof follows from an identity for A= 2 and some known inequalities (see also Shore, 1980). In Pecaric and Janie (1982) further generalizations are given by using Jensen's inequality and Petrovic's inequality for convex functions. Also, Shore (1980) and Pecaric and Janie (1982) gave some inequalities for norms. However, the well-known Clarkson inequalities (see, for example, Mitrinovic and Vasic, 1977) are closely related to the above results. 4.47. Theorem. If x, yare elements of the space t p (or Lp ) , where p and «: + «:' = 1, then the inequalities 2(llxll P + lIyIlP)q- 1:s IIx + yllq 2(jjxjjP
+ lIyllP):s
jlx
+ Ilx -
yllq,
~2
(4.79)
+y
jjP + Ilx - yjjP:S 2P- 1(jjxjjP + Ijy liP),
(4.80) IIx + yliP
+ IIx -
Y II p :s 2(lIxll
q
+ lIyllqy-l
(4.81)
hold. If 1 < P :s 2, then the reverse inequalities are valid. For some similar results, see Dragomir and Sandor (1987) and Koskela (1979).
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Chapter 5
5.1.
Hermite-Hadamard’s and JensenPetrovik’s Inequalities
Hermite-Hadamard’s Inequality
On November 22, 1881, Hermite (1822-1901) sent a letter to the journal Mathesis. An extract from that letter was published in Mathesis 3 (1883, p . 82). I t reads as follows (see Mitrinovii. and Lackovii., 1985): “Sur deux Iimites d’une inte‘grale de‘finie. Soit f ( x ) une fonction qui varie toujours dans le m h e sens de x = a, ri x = b. On aura les relations
ou bien
a
suivant que la courbe y =f ( x ) tourne sa convexite‘ ou sa concavite‘ vers l’axe des abcisses. En faisant dans ces formules f ( x ) = 1 / ( 1 +x ) , a = 0 , b = x il vient XZ x - -< 2+x
log(1 + x ) < x -~ x 2 2(1+x)‘
3,
It is interesting to note that this short note of Hermite is nowhere mentioned in mathematical literature, and that these important inequalities (of Hermite) are not widely known as Hermite’s result. His note is recorded neither in the authoritative journal Jahrbuch iiber die Fortschritte der Mathematik nor in Hermite’s collected papers, which 137
138
5. Hermite-Hadamard's and Jensen-Petrovic's Inequalities
were published "so US les auspices de l'Academie des sciences de Paris par Emile Picard (1905-1917), membre de l'Institut." In the booklet on Hermite by Jordan and Mansion (1901), Mansion published a bibliography of Hermite's writings, but this note in Mathesis was not included. Beckenbach (1948, p. 441), a leading expert on the history and theory of complex functions, wrote that the first inequality in (5.1) was proved by Hadamard (1893, see, in particular, pp. 174-76, 186) and apparently was not aware of Hermite's result. It should be mentioned that Fejer (1880-1959), while studying trigonometric polynomials (1906), obtained inequalities which generalize that of Hermite, but again Hermite's work was not acknowledged. In its original form, Fejer's result reads: "Consider the integral f ~ f ( x ) g ( xdx, ) where f is a convex function in the interval (a, b) and g is a positive function in the same interval such that g(a
+ t) = g(b - t),
1 2
O ~ t ~ - ( a + b ) ,
i.e., y = g(x) is a symmetric curve with respect to the straight line which contains the point (Ha + b), 0) and is normal to the x-axis. Under those conditions the following inequalities are valid: ~
f(a;b)
J a
~
~
g ( x ) d x J~ f ( x ) g ( X ) d X ~ f ( a ) ; f J( g(x)dx." b) a
(5.2)
a
Clearly, for g(x) == 1 and x E (a, b) we obtain Hermite's inequalities. Therefore, Hermite's important result in (5.1), which provides a necessary and sufficient condition for a function f to be convex in (a, b), has not been credited to him in mathematical literature. In fact, the term "convex" also stems from a result obtained by Hermite in 1881 and published in 1883 as a short note in Mathesis, a journal of elementary mathematics. There are results of lesser importance which have received more attention in the area of inequalities, but unfortunately this fundamental work of Hermite has been frequently cited without the correct identification of its original author. It is obvious that (5.1) is an interpolating inequality for (5.3)
5.1. Hermite-Hadamard's Inequality
139
More than twenty years after Hermite's work was published, J. L. W. V. Jensen (1905, 1906) defined convex functions (i.e., J-convex functions) using inequality (5.3). His remark, which we cite here, was shown to be justified: "Il me semble que la notion de fonction convexe est a peu pres aussi fondamentale que celles-ci: fonction positive, fonction croissante. Si je ne tromp pas en ceci, la notion devra trouver sa place dans les expositions elementaires de la theorie des fonctions reelles" (see Jensen, 1906, p. 191). Indeed, it is not easy to give a complete treatment of the literature when studying convex functions, but the importance of Hermite's result is obvious. Since the inequalities in (5.1) have been known as Hadamard's inequalities, in this volume we shall call them the Hermite-Hadamard's inequalities. In the classic book of Hardy, Littlewood, and P6lya (1934, 1952, p. 98) the following result is given:
5.1. Theorem. A necessary and sufficient condition that a continuous functionf(x) be convex in (a, b) is that x+h
f ( x ) ~ 2J ~ f(t)dt
for
a ss x r-h-c x-r h ss b.
(5.4)
x-h
It can be shown that this result is equivalent to the first inequality in
(5.1) whenfis continuous on [a, b]. However, it remains unclear by who and when the transition from the inequality (5.1) to the convexity criterion in (5.4) was made. Note that a generalization of Theorem 5.1 is already given in Theorem 2.14. In the following we shall give some other generalizations. For f E C(I), h >0, and x E 11 (h ) = {t:t - h, t + h e I}, the operator Sh defined by x+h
ShU, x) =
2~
J f(t) dt
(5.5)
x-h
is often called a Steklov function, although it is an operator mapping e(I) into C(I1 ) . For a finite interval I = [a, b], the maximum value of h can be (b - a)/2. In this case 11 contains a single point and Sh becomes a functional. The Hermite-Hadamard inequality (5.4) now has the form f ( X ) ~ S h U , for X ) xEI1(h) and is equivalent to the convexity of the function. The iterated Steklov operators (with the step h > 0) S ~ (n E .N)
140
5. Hermite-Hadamard's and Jensen-Petrovlc's Inequalities
are defined by x+h
Sh(f, h) =
s2(f, x) =f(x),
2~
f
Sh-1(f, x) dt,
(5.6)
x-h
where n E X, x E In(h) = {t:t - nh, t + nh E I}. For convenience we write S; instead of sL and (5.4) becomes s2(f, x)::5 Sh
E
C(I) is convex iff for every h > 0 and
(5.7)
f(x) ::5 Sh(f, x) holds for every fixed n.
5.3. Theorem. A function f x E In(h) the inequality
E
C(I) is convex iff for every h > 0 and (5.8)
holds for every fixed n.
5.4. Remarks. (a) Theorem 5.2 can be found in Horova (1968). (b) It is known (see, for example, Timan, 1963) that f(x) can be uniformly approximated by Sh(f, x) as h ~o. (c) The operator Sh can be used for the following characterization of convex functions (see Kocic, 1984): Let I = [a, b]. Then the function f E C(I) is convex iff for every HE [0, (b - a)/2) and x such that [x - h, x + h] E I and for every h E (0, H) the inequality SH(f,X)2=Sh(f,X)
holds.
(5.9)
0
It is easy to see that Theorem 5.3 generalizes the convexity criterion based on the inequality (5.4) (we obtain (5.4) by letting h ~0). Theorems 5.1-5.3 are all related to the first inequality in (5.1). Note that the first inequality is stronger than the second inequality in (5.1); i.e., the following inequality is valid for a convex function f: b
b
_1_ ff(x) dx _f(a +2 b) ::5 f(a) +2 f(b) __ 1_ ff(x) dx. b-a b-a a
a
(5.10)
5.1. Hermite-Hadamard's Inequality
141
Indeed, (5.10) can be written as b
b: a
f
d X : 5 (f(a) ~ + f(b) + 2f(a: b)),
f(x)
a
which is 2 b-a
f
(a+b)/2
f a
b
f(x)dx+_2b -a
f(x)dx
(a+b)/2
This immediately follows by applying the second inequality in (5.1) twice (on the interval [a, (a + b )/2] and [(a + b )/2, b D. By letting a = -1, b = 1, we obtain the result due to Bullen (1978). However, the second inequality in (5.1) can also be used as a convexity criterion. In Roberts and Varberg (1973, p. 15), the following result is given:
f
5.5. Theorem. A function [a, b] we have
-l-f f
E
qa, b] is convex iff for every s < t in
I
(x ) dx :5 f(s)
t-s
+ f(t).
(5.11)
2
More general results are given by Rado (1935). In the following we state some characterization results given in his paper. Let f (x) be a positive and continuous function on (a, b) and let u, v E ~ . We define 1 ( 2h
I(f,x,h,u)=
fh -h
{
f(x + tt dt
)1IU
h
f
eXP(2~
logf(x + t) dt)
for
u=O;
-h
1 )1IV ( If(x - h)V + f(x + h)V
A(f, x, h, v) = {
(f(x + h )f(x - h
»112
for
v
=
O.
Further, let E denote the set of all pairs (u, v) such that I(f, x, h, u) :5A(f, x, h, v)
(5.12)
142
5. Hennite-Hadamard's and Jensen-PetroviC's Inequalities
holds for all x and h satisfying a < x - h < x + h < b and all positive, continuous, and convex functions f on (a, b). Similarly let E be the set of points of (u, v) such that (5.12) holds for all such x, h and all positive and continuous functions f on (a, b). The main result in Rado's paper concerns the explicit determination of the sets E and E, and the following theorems is proved:
5.6. Theorem. (a) (u, v) belongs to E iffone of the following conditions is satisfied: (i) u $ -2 and v 2': 0; (ii) -2 $ u $ -! and v 2': (u + 2)/3; (iii) -! $ u $1 and v 2': (u log2)/(log(1 + u»; and (iv) 1 $ u and v 2': (u + 2)/3. (b) (u, v) belongs to E iff3v - u - 2 $ O. In Theorem 5.5 if we replace the word "convexity" by "concavity," the inequality "/$A" in (5.12) by "/2':A" and E, E by E* and E*, respectively, then the following theorems is true (Rado, 1935):
5.7. Theorem. (a) (u, v) belongs to E* iff one of the following conditions is satisfied: (i) u $ -2 and v $ (u + 2)/3; (ii) -2 $ u $ -1 and V$O; (iii) -15U5-! and V2':(ulog2)/(log(l+u»; (iv) -!5u51 and v 5 (u + 2)/3 and (v) 15 u and v $ (u log 2)/(log(1 + u ». (b) (u, v) belongs to E* iff 3v - u - 22':0. As a simple consequence of Theorems 5.6-5.7, Rado (1935) proved the following result:
5.8. Theorem. Let f be a positive and continuous function on (a, b). Then (a) the inequality in (5.12) is equivalent to the convexity of f iff (u, v) satisfies the conditions: (i) 3v - u - 2 = 0 and (ii) either -2 $ u $ -! or 1 $ u < 00; (b) the reverse inequality in (5.12) is equivalent to the convexity of f iff (u, v) satisfies the conditions (i) 3v - u - 2 = 0 and (ii) either u 5 -2 or -! $ u $1. The following result of Pitenger (1980) is a consequence of Rado's results (see Lupas 1983):
143
5.1. Hermite-Hadamard's Inequality
5.9. Corollary. Let 0 < a
< b,
-m
< r < ~0 and define
]
log2 log(r 1)
+
for r>-l,r+O, for r =0,
r+2
for r s - 1 .
Let r, be defined similarly with min replaced by max. Then M['"(a, b ) 5 L,(a, b) 5 M[rzl(a,b)
(5.13)
holds, where L,(a, b ) is the generalized logarithmic mean given by L,(a, b ) =
{
- l(bbl a a ) l l ( b -0) for r=O ( b - a)/(log b - log a ) f o r r = -1, [(br+'- ar")/((r l)(b - a))]", f o r r # 0, -1,
+
and L,(a, a ) = a. The equality in (5.13) holds iff a = b or r = 1, -2. Moreover, the values of r, and r . are sharp.
-4,
or
5.10. Remarks. (a) LupaS (1983) also proved (5.12) by using (5.13). (b) Rado's (1935) results are further generalized in Hartman (1972).
Namely, Hartman considered the monotonicity of the difference A - Z as a function of x and h when f is positive, increasing, and convex. He also showed that Rado's inequalities are valid under some weaker conditions. This, of course, is natural because the classes of functions he considered are narrower than those in Rado's paper; i.e., positive convex functions are also monotonic. Another generalization of Hermite-Hadamard's inequalities is given in Vasi6 and LackoviC (1974, 1976) and LupaS (1976):
5.11. Theorem. Let p , q be given positive numbers and a , 5 a < b 5 b,. Then the inequalities
144
5. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
hold for A = (pa + qb )/(p tions f: [aI' b d IR ~ iff
y
+ q), Y > 0, and all continuous convex funcb-a p+q
~ - - m i n { pq}. ,
(5.15)
5.12. Remarks. (a) Observe that (5.14) may be regarded as a refinement of the definition inequality for convex functions. (b) For p = q = 1 and y = (b - a)/2, (5.15) is the HermiteHadamard's inequality. We now show that under the same conditions Hermite-Hadamard's inequality yields the following refinement of (5.15):
f
A+y
f(pa p
+ qb) ~ ~ f(t) dt ~ ~{f(A- y) + f(A + y)} ~ p f ( a +) qf(b) +q 2y A-y 2 p +q (5.16)
First, observe that if O < y ~ [ ( b - a ) / ( p + q ) ] m i n { p then , q } by , considering two cases (0 < P ::5 q and 0 < q < p ), we can easily verify that a ~ A - y < A + y so ~ bthat , f is defined on [A-y,A+y]. By Hermite-Hadamard's inequality in (5.1) with a, b replaced by Ay, A + y, we obtain
f
A+y
f(A) ~ 12 y
f(t) dt ~ 12[f(A - y) + f(A + y)].
(5.17)
A-y
By the definition of convexity, we have for a
Hence, taking
Xl
= a and X3 = b,
~Xl < X 2 < X 3 ::5 b
we obtain (5.18)
f(A+y)::5
b - (A + y) A +Y- a b-a f(a)+ b-a f(b).
(5.19)
5.1. Hermite-Hadamard's
Inequality
145
From (5.17)-(5.19) we then have A+y
f(A) ~1
2y
-
J
f(t) dt
A-y
~ 1-{f(A-
y) + f(A + y)}
2
~ !{b -Af(a) + A - a f(b)} =pf(a) + qf(b) , 2
b-a
b-a
p+1
proving (5.16). (c) Note also that (5.14) can be proved from the integral analogues of Jensen's and Lah-Ribaric's inequalities, i.e., from the inequalities b
f(
b
b
b
(J p(x)g(x) dx)/ (J p(x) dX)) ~((J p(x)f(g(x» dX) / (J p(x) dX)) a
a
a
a
~ M - g f(m) + g - m f(M), M-m
M-m
where m ~ g ( x ) ~forM all !E[a, b], g = ( f ~ p ( x ) g ( x ) d x ) / ( f ~ p ( x ) d x ) . Indeed, if we make the substitutions p(x)=l, g(x)=x, a=A-y, b = A + y, m = a, and M = b, we obtain the result that (5.14) is valid if the following condition holds:
a
~ A-
y
~b
and
a
+y
~ A
~ b.
(5.20)
We can then easily show that conditions (5.15) and (5.20) are equivalent. Therefore, condition (5.15) is sufficient. Now we show that it is also necessary. Let p >q and assume that (5.15) is not valid, i.e., y> (q(b - a»/(p + q). Since the function f(x) = a - x for x < a and f(x) = 0 for x2:a is convex, (5.14) becomes: 0 ~ ( a - A - y ) / 2 y ~a 0 con, tradiction. Therefore we must have y ~ q(b - a)/(p + q). Similarly, for the case p
146
5. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
(e) Inequalities (5.14) can also be used as convexity criteria. Of course, the first inequality is the same as (5.4), and the related result for the second inequality (i.e., the generalization of Theorem 5.4) is given in Kocic (1984). (f) Using a proof similar to that given in (b), we can prove the following generalization of (5.10): Under the same conditions as stated in Theorem 5.11,
f
A
~ 2y
A
~
f
A
f(t) dt - f(pa p ~
+ qb) :spf(a) + qf(b) - ~ +q p +q 2y
A
~
f(t) dt. (5.22) ~
o
Generalizations of Theorem 5.11 for positive linear functionals are given in Pecaric and Beesack (1986):
5.13. Theorem.
Let f be a continuous convex function on an interval I ~ [m, M], where -00 < m < M < 00. Suppose that g: E - [R satisfies m:sg(t):SM for all tEE, gEL; and f(g)EL. Let A:L-[R be an isotonic linear functional with A(l) = 1, and let p = Ps» q = qg be nonnegative real numbers (with p + q > 0) for which A(g) = (pm
+ qM)/(p + q).
(5.23)
Then f(pm + qM) :SA(f(g» :spf(m) + qf(M). p+q p+q
(5.24)
Proof. Observe first that since m :s A(g) -s M, there always exist p ;::: 0, q ;::: 0, (p + q) > satisfying (5.23). The first inequality in (5.24) is just (2.6), while the second of (5.24) is (3.43). 0
°
5.14. Theorem.
Suppose that L satisfies conditions Ll-L3 defined in (3.27)-(3.29) on a nonempty set E and that f is a continuous convex function on an interval I, while g, h E L with f(g),f(h) E L. Let A, B be isotonic linear functionals on L for which A(l) = B(l) = 1. If A(h) = B(g), E[ E.s4 satisfies A(CE) > 0 and A (C Ez) > 0 where E 2 = E\E 1 , and if A(hCE)/A(CE) :sg(t) :sA(hCEz)/A(CE,) for all tEE,
(5.25)
f(A(h»:S B(f)(g) :sA(f(h».
(5.26)
then
5.1. Hermite-Hadamard's Inequality
Proof.
147
By Jessen's inequality we have i
= 1, 2.
(5.27)
Applying Theorem 5.13 «5.24» to the isotonic linear functional Band the function g with m=A(hCE,)/A(CE,), M=A(hCE,)/A(CE,), for p= A(CE,), q = A(CE,), we have P + q = A(CE) = A(1) = 1 and B(g)=A(h)=A(hCE,)+A(hCEz) =
pm+qM . p+q
Hence, by (5.24) we obtain f(A(h» = f(B(g» :s B(f(g» :s A(CE,)f(
~ ~ h ~ ~ +/ )A(CE,)f( ~ ~ ~ : ) )
:sA(f(h)CE,) +A(f(h)CEz) (by (5.27»
= A(f(h», proving (5.26).
0
Note that again the inequality (5.26) is a refinement of Jessen's inequality and is also a generalization of an inequality given in Vasic, Lackovic, and Maksimovic (1980). Wang and Wang (1982) proved the following generalization of Theorem 5.11:
5.15. Theorem. Let f: [a, b ] ~IR be a convex function, Xi E [a, b], and = 0, 1, ... , n). Then the following inequalities are valid:
Pi> 0 (i
n-l
+
2: xi1 -
n
tj + 1)t1 ••• tj
j=1
IT dt,
+ X n t 1 t 2 ••• tn )
i=1
(5.28) where
(£1'i
n
+ f3;)/2 = ~ 1Pk
/
n
k ~ - Pk 1 for i = 1, ... , n
(5.29)
148
5. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
and
O:s a i < f3i :s 1 for
i
= 1, ... , n.
(5.30)
Proof. (Pecaric, 1989a). By the integral and discrete versions of Jensen's inequality, we have
f(~PiXi/itPi)
f{n (f3j - aj)-l f
fJ,
n
=
)=1
f ... f fJ,
n
:s)] (f3j - a'j}-l
a1
fJ,
n
-s
I ~(f3) -
aJ-1
n
/
n
~Pi-
f(xo(1- (1)
an
fJn
f ---f eXt
= ~pJ(Xi)
fJn
(f(xo)(l - (1)
(1'"
o
5.16. Remarks. (a) In Pecaric (1989a) the condition in (5.30) is weakened and a generalization to Theorem 5.15 for convex functions of several variables is given. Another extension of Theorem 5.15 is given in Hu (1986). (b) Generalizations of Hermite-Hadamard's inequalities are also given in Lackovic and Stankovic (1973) and Lackovic (1969). Note that the results in Lackovic and Stankovic (1973) are simple consequences of the well-known results for support line of convex functions. For example, by integration and Theorem 1.6 we can obtain the following generalization
5.1. Hennite-Hadamard's Inequality
149
of the first inequality in (5.1): b
f(c)
b
+ f ~ ( c ) ( xf p(x) dX) /
(f p(x) dX) -
a
cf~(C)
a b
b
~ ( fp (x)f(X)dx)/(JP(X)dx) a
where
for
a
(5.31)
a
f is convex and p is a positive integrable function.
D
Another generalization of the first inequality in (5.1) can be found in ~ u ~ v and a, E IR) be an Neuman (1986). Let x(t) = I : ~ ~ ua .t' (for algebraic polynomial of degree not exceeding v and let a = min{x(t): c ~
°
t ~ d } , b = m a x { x ( t ) : c ~ t ~ d } .
5.17. Theorem.
Let f be a convex function on (a, b). Then d
f ( ~ uarm r) ~ J M n ( t ) f ( ~artu r) dt,
(5.32)
c
where M; is a B-spline and m, the rth generalized symmetric mean of to, ... , tn (see Section 1.3).
The following generalization of the first inequality in (5.1) for convex functions of several variables is given in Neuman and Pecaric (1989). 5.18. Theorem. Let f be a convex function vol([Xo, ... ,xd) > 0, Xi E IRk, i = 0, 1, ... ,n. Then f(me, , ... , mek)
on
IRk
and
let
f(xf', ... , Xfk)M(xI Xo, ... , xn ) dx, (5.33)
~J IRk
where f i
= 1, 2, ... , ; i = 1, 2, ... , k.
Proof. Consider Jensen's inequality for multivariate continuous convex functions on IRk, ( ~ 1 " ' " ~ k ) E C(lRk), and let du be a probability measure on IRk. Then
f(
f ~ 1 du, ... , IRk
J ~ kdp:) ~ J f( IRk
IRk
1>1' ... ,
~ k )d u,
(5.34)
150
S. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
and the equality in (5.34) holds iff f E III (IRk) (the space of all k-variate polynomials of total degree :51). Let df.-l(x) = M(x I Xo, ... ,xn ) dx. Then du is a probability measure on IRk. To establish (5.33) we let t(x) = Xi; i = 1, 2, ... ,k in (5.34). Hence the inequality follows from Theorem 1.6(e). 0 5.19. Theorem.
Under the assumptions of Theorem 5.18, we have
[ ( -n +1 1 2:n) xi:S i=O
f
IRk
[(x)M(x I Xo, ... , Xn ) dx:s - 1 n [(Xi), n + 1 ;=0
2:
and the equality in (5.35) holds iff[
E
(5.35)
III (IRk).
Proof. The first inequality in (5.35) follows immediately from (5.33) and (1.58) by letting t l = ... = t k = 1. To obtain the right-hand side inequality in (5.35) we apply (1.56) and
f
Ago ... APn dA = r(po + 1) ... f(Pn + 1) n
S"
r(Po+"'+Pn+n+1)'
where Po, ... , P« > -1 and f(-) is the gamma function. We then obtain
As a special case we obtain: 5.20. Theorem. Let a = [x,, ... ,xd where k::::: 1 and volk( a) > O. If [ : a ~IR is a convex [unction, then (5.36) and equalities hold iff[
Proof.
E
III (IRk).
Immediate from (5.35) and (1.57).
0
5.21. Remark. Using a proof similar to the proof of Theorem 5.18 we can give a generalization of Theorem 5.17 which includes Theorem 5.18 as a special case (see Neuman and Pecaric, 1989). 0
5.2. Jensen-PetroviC's Inequalities
151
Let X = {Xo, ... , X n } (n > k 2= 1), and assume that any subset that consists of k + 1 points spans a proper simplex. let Xj = X \ {x, : ::5 j ::5 n}. Then a multivariate B-spline can be written as M(·I X) (with knot set X). Similarly let M(·\ X) denote the multivariate B-spline with knot set Xj . For real numbers Ao, ... , An with ~ 7 = Ao j = 1, let y = ~ 7 ~ A o jXj and let z= ( ~ 7 = o x j ) / +( n1). The following generalization of Theorem 5.11 is a special case of a more general result of Neuman (1990):
°
5.22. Theorem.
f
Let f be a convex function on ~ k . Then f(x)M(x I X) dX::5
IRk
t
f
Aj
]-0
f(x)M(x I X) dx
(5.37)
IRk
holds iff y = z, and equality in (5.37) holds ifff
E
TIl
(~k).
Note that Neuman's general inequality is also a generalization of Fejer's inequality given in (5.2).
5.23. Remark. Other generalizations of Hermite-Hadamard's inequalities were obtained by Zhang (1987), Neuman (1988), Sandor 0 (1988), and Alzer (1989c).
5.2.
Jensen-PetroviC's Inequalities
5.2. 1.
Inequalities for Starshaped Functions
The following theorem is proved in Vasic and Pecaric (1979a): 5.24. Theorem.
Let x, p and q, be nonnegative n-tuples. Then (5.38)
holds for every n, x, p, and q such that
X; E
[0, a] (i
n
2. p.x, 2=Xj
i=1
= 1, ... , n) and
n
for
j = 1, ... ,n
and
2. PiX; E [0, a]
i=1
(5.39)
iff ep : [0, a] ~ ~ is a decreasing function. Similarly, the reverse inequality holds iff ep is increasing. (i) If ep is decreasing, then e p (5.38). (ii) For n = 2, XI = X, Xz = h,
Proof.
( ~ 7 =PiXi) 1 ::5
PI
ep(x). Thus we obtain
= pz = 1, ql =
1,
and
qz
= p,
152
S. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
(5.38) becomes (1 + P )¢(x + h) ::; ¢(x) + p¢(h). As p ~0, we have ¢(x + h) $¢(x). The proof for the reverse inequality is similar. 0
5.25. Remark. For Pi = 1 (i = 1, ... , n) the first condition in (5.39) is satisfied; thus we can obtain a result of J. L. W. V. Jensen (1906) from Theorem 5.24 (see also Hardy, Littlewood, and P6lya, 1934, 1952, p. 83): We say that f(x)/(x - x o) is a decreasing (increasing) function if ...J...J--'>.,. f(xt) :> Xt-rXO -r- X2 ....,... Xt-XO
Letting ¢(x) = f(x)/x and qi = p.x, (i have:
= 1, ...
«) -
f(x2) • X2- XO
o
, n) in Theorem 5.24, we
5.26. Theorem. Let x and p be two nonnegative n-tuples such that (5.39) is satisfied. If f(x )/x is a decreasing function, then (5.40)
If f(x)/x is an increasing function, then the reverse of the inequality in (5.40) holds. 5.27. Corollary. If the conditions of Theorem 5.26 are satisfied and X2 - ... - Xn > 0 (2:0 iff is defined at 0), then
Xt -
(5.41) The following generalization of Theorem 5.26 is given in Vasic and Pecaric (1979a): 5.28. Theorem. such that
Let p be a nonnegative n-tuple and x be a real n-tuple
(5.42)
5.2. Jensen-PetroviC's Inequalities
153
If (f(x) - f(xo»/(x - xo) is an increasing function, then
%1 pd(Xk):5 Af(%1PkXk) + B(%1 Pk -
1)f(xo)
(5.43)
holds, where A
=
(%1 Pk(Xk- xo»)/ (%1 pix; -xo), (5.44)
B=
(%1 PkXk)/(%/kXk-xo).
Proof. This is a simple consequence of a result given in Remark 3.45(b) by letting either m = Xo and M = ~ ? = P1 iXi or m = ~ ? = P1 iXi and M = Xo. 0 5.29. Theorem.
Let f(x)/x be an increasing function.
(a) IfO<xl:5'" :5xn and if there exists an m (:5n) such that
Pm + 1 = ... = Pn = 0, where P k = ~ 7 = I P i P' k = Pn - Pk - 1 (k=2, ... ,n), and (5.40) holds. If there exists an m (:5n) such that
P1 = Pn ,
then
Pm + 1 = ... = Pn = 0, then the reverse of the inequality in (5.40) holds, i.e.,
(5.45)
(b) Let Xl:5"':5x m:50:5Xm+l:5"':5X n and f(O) =0. Then the inequality (5.40) is valid if either (i) there exists a i. 1:5 j :5 m + 1, such that PI = ... =
Pm + 1 = ... = Pn = 0,
~ + 1 '
or (ii) there exists a k, m s; k :5 n, such that PI = .. ·=Pm=O, The inequality in (5.45) holds if there
Pk + 1 = ... = Pn = O. exist integers j and k, 1:5 j:5 m + 1,
m :5 k :5 n, such that PI = ...
=
= 0,
~ - 1
0:5 Pm + 1:::s;· .. :::s; Pk:::s; 1,
1
~ ~ ~
Fk+ 1 =
~ Pm
~ 0,
= Fn = O.
154
S. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
5.30. Remarks. (a) A new proof of Theorem 5.29 is given in Vasic and Pecaric (1979a). In fact, they proved Theorem 5.29 under weaker conditions. (b) Vasic and Pecaric (1979a) also proved that inequality (5.40) holds for every n and every f such that f(x)/x is a decreasing function iff Pi ~ 1 (i = 1, ... , n). (c) If inequality in (5.40) holds for all positive n-tuples x and p, then f(x) = cx where c is a real number (Hardy, Littlewood, and P6lya, 1934, 1952, p. 84). 0
5.2.2.
Inequalities for Convex Functions
First we give the following result:
5.31. Theorem. Let f be a convex function on [0, a). If the conditions of Theorem 5.26 are satisfied, then (5.46)
Proof. 5.26.
The function f(x) - f(O) satisfies the conditions of Theorem 0
5.32. Remarks. (a) For Pi = 1 (i = 1, ... , n). (5.46) becomes (5.47) This is the well-known Petrovic's inequality for convex functions (see Petrovic, 1932, or Mitrinovic, 1970, p. 28). (b) Inequality (5.45) was first given by Pipoviciu (1944) under the incorrect assumptions that Pi > 0 and Xi >0 (i = 1, ... ,n). Vasic (1968b) noted that this result is true for Pi ~ 1 and Xi ~0 (i = 1, ... , n). In fact, Vasic's conditions are necessary and sufficient for the inequality in (5.46) to hold for every n and every convex function f (see Vasic and Pecaric, 1989).
5.2. Jensen-PetroviC's Inequalities
155
(c) Vasic (1968b) considered the following generalization of (5.46):
~ 1Pk!(Xk) :5 r f ( ~ ~ 1PkXk) -
,n and where Xk E [0, a) for k = 1, , n) and conditions are Pk;:==: 1 (k = 1, nt- 1
nz-l
2: PkXk = k=l
2:
~ 1Pk)[(0),
(r -
1/r I : k ~ l P k EX [0, k a).
(5.48) His
n
PkXk = ...
=
2:
PkXk'
k=nr-l
k=nt
For Pk = 1 (k = 1, ... , n), we obtain an inequality of Marshall, Olkin, and Proschan (1967) which includes, as a spcial case, the inequality
-1 2:n
n k=l
s
(n)S-l( 2:
lak - al :5 -
2
n
k=l
lak -
)S
al ,
where a = (lin) I: k=l ai; ak;:==: 0 and s;:==: 1. Moreover, Vasic's conditions can be replaced by 1 n O:5Xi:5-2:PkXk for r k=l
i=l, ... ,n.
(5.49)
o
We note that the special case Pi = 1 (i = 1, ... , n) and r = 2 was considered by Petrovic (1938) with an aspect of applications in geometric inequalities (Pavlovic, 1961). Also note that inequalities (5.46) and (5.48) are equivalent. To see this, by the substitution P i ~ p J (5.48) r follows from (5.46). Similarly, for r = 1 (5.48) yields (5.46). A similar consequence of Theorem 5.28 is: 5.33. Theorem. Let f: I ~IR be a convex function where Xo and I:k=lPkXk are in 1. Let the n-tuples x and p satisfy the conditions of Theorem 5.28. Then (5.43) holds.
Proof.
The function
f satisfies the conditions of Theorem 5.24.
0
5.34. Remarks. (a) Inequality (5.43) for convex functions is proved by Giaccardi (1955) under stronger conditions. Theorem 5.33 is proved in Vasic and Stankovic (1973). In fact, they proved a generalization of Theorem 5.33 for g-convex functions. Vasic and Pecaric (1979a) showed that this result for g-convex functions can be obtained from a similar generalization of the discrete case in Theorem 3.37 (see Remark 3.45(b».
156
5. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
(b) A generalization of Theorem 5.33 for positive linear functionals is given in Beesack and Pecaric (1985a): Let L, A satisfy the conditions Ll, L2 and AI, A2 defined in (3.27)-(3.31) and let gEL. If xo*A(g) and either xo:S g(t) :s A(g) for all tEE or A(g) :s g(t) :s Xo for all tEE, and if (jJ is convex on [xo, A(g)] (or on [A(g), xoD and (jJ(g) E L, then A((jJ(g»:s ([A(g) - A(I)xo](jJ(A(g» + [A(I) - 1]A(g)(jJ(xo)}/[A(g) - xo].
o The following generalization of the well-known Brunk-Olkin Inequality (see, e.g., Mitrinovic, 1970, pp. 47-48, or Beckenbach and Bellman, 1961, 1965, pp. 47-49) is given in Barlow, Marshall, and Proschan (1969): 5.35. Theorem. Let xl:s·· ·:Sxs:sO:SXs+I:S··· :sxn (SE{O, 1, ... , n}), X; E 1(1 :s i :s n; 0 E I), and p be a real n-tuple. (a) The inequality in (5.46), i.e.,
~ lp J(x;) ~ f ( PiX;) ~ + ( ~ 1p; -1 )f(O) holds for every convex function f : I
o:s Pk :s 1
~[ffi
1:s k -s sand
for
(5.50)
iff
0 :s Pk :s 1 for s + 1 :s k :s n. (5.51)
(b) Let r..?=IP;X;
E
I. Then the inequality
(5.52) holds for every convex function f : I f}:SO
for
i<m,
f } ~ 1 for
~[ffi
iffthere exists an m :s s such that
m:Si:ss,
and
P;:s0
for
i ~ s + l ;
(5.53) or there exists an m f}:SO
for
i :ss,
~s
such that
P; ~ 1 for
s
+ 1 :s i :s m, and P;:s 0 for
i
< m.
(5.54)
5.2. Jensen-PetroviC's Inequalities
157
Proof. Let Theorems 2.19 and 3.3 (i.e., Remarks 2.20(a) and 3.4) hold for n + 1 with Xi = Xi and Pi = Pi (1 ~ i ~ n + 1). By the substitutions Xi=X;
and
P;=P;
for
and P;=P;-I
X;=X;_I
Xm + 1 = 0,
1 ~ i ~ m ;
we obtain Theorem 5.35.
for
m + 2 ~ i ~ n + 1 ;
0
5.36. Remark. We have shown that Theorem 5.35(a) is a special case of Theorem 2.19, and that Theorem 5.35(b) is a special case of Theorem 3.3. Now we show that the reverse implications are also valid (Pecaric, 1984h). Without loss of generality we may assume that P; = 1. Then (2.19) and (5.50) are equivalent and (3.2) and (5.52) are equivalent. In this case (5.51) becomes O ~ P k ~ P for n
1 ~ k ~ s and
Fk-I;:::O
for
O ~ F k ~ P for n
Pk;:::O
for
Fk;:::O,
1 ~ k ~ s and
Pk -
I ;:::
0 for
Fk;:::O
1 ~ k ~ n - 1a nd
which is equivalent to (2.20). Similarly, for m ~ ~ Ofor
i<m,
~ ; : : : P n
for
s + 1 ~ k ~ n ; i . e . ,
s
+1
for
P;-I ~0 for
i<m,
~0
for
i<m
and
becomes
i e:s
+ 1; i.e.,
i e.s
+ 1; i.e.,
m ~ i ~ sand
P ; ~ O for
P,
i.e.,
and
P ; ~ O for ~ ~ Ofor
~ n,
2 ~ k ~ n ,
~ s (5.53)
m zi i zs s
~k
P; ~ 0 for i > m,
which is the condition in (3.3). By a similar argument for m ;::: s (5.54) becomes ~ ~ Ofor
i
P;;::: t; for
~ s ,
s + 1 ~ i ~ m and
P ; ~ O for ~ ~ Ofor
F.-I
i zs s,
~0
for
s + 1 ~ i ~ m and
P ; ~ O for
P, ~0
for
i
<m
and
i<m;i.e.,
P;
~0
for
i > m.
i>m; i.e.,
158
5. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
Thus we again obtain the condition in (3.3). Consequently, we have proved Theorems 2.19 and 3.3 with the assumption that 0 E 1. Suppose that 0 $ I, and let I = [a, b]. If f is a convex function on [a, b], then F(t) = f(t + (a + b )/2)) is a convex function on [- (b - a)/2, (b - a)/2]. Thus in the case P; = 1, from (5.50) (and (5.52)) we have
i.e., f
n (
a
(
+
b)) ::s;("?:.)t:/ J
-
(a
n
~ P ; t;+-2-
a
(
+
b)
t;+-2- ,
which is
where we have used t, = X; 0 completes the proof.
+ b )/2 for
[a, b] and 1::s; i ::s; n. This
X; E
Note that similar assertions also hold for some of the results given later. To obtain an analogue of Theorem 5.35 from Theorems 2.21 and 3.6, we let I\.(x) = g(x) = g(x) + sex), where sex) = 0 for X E [a, to] and sex) = 1- G(b) for X E (t a , b], and
f
G(t)
=
f b
t
dg(x),
G(t)
a
=
dg(x).
t
5.37. Theorem. Let to E [a, b] be fixed and f be continuous and monotonic with f(to) = O. Let g be a function of bounded variation. (a) If O::s; G(t) ::s; 1 for
a s: t ::s; to,
4J: I
then for every convex function we have b
O::s; G(t) ::s; 1 for ~IR
such that f(x) E I for all x
b
a
(5.55) E
[a, b]
b
J4J(f(t» dg(t)"?:. 4J(J f(t) dg(t») + (J dg(t) a
to < t s; b,
a
1)4J(0).
(5.56)
5.2. Jensen-Petrovic's Inequalities
(b) If J ~ f ( t dg(t) )
E
159
I and either
there exists an s ::s to such that G(t)::s 0 for t < s, G(t)
~1
for
s ::s t s: to, and G(t)::s 0 for t > to,
(5.57)
or there exists an s ~ to such that G(t) ::s 0 for t < to, G(t) ~ 1 for to
b
b
J¢(f(t» dg(t) ::s ¢ (J f(t) dg(t») + (J dg(t) - 1) ¢(O). a
a
(5.59)
a
5.38. Remarks. (a) For Pk = (-1)k- 1hk> 1 ~ h, ~ ... .2: 0, we obtain the Brunk-Olkin Inequality from Theorem 5.35. It is known that this inequality is a generalization of results given by Szego (1950), Weinberger (1952), and Bellman (1953) (see also Mitrinovic, 1970, p. 1; Beckenbach and Bellman, 1961, 1965, pp. 47-48, or Karlin and Studden, 1966, p. 431). (b) A generalization for functions with increasing increments was given in Pecaric (1984b) with conditions (5.57) and (5.58) replaced by, respectively, ~1
for
a s; t < to,
G(t) ::::; 0
for
to::::; t s: b;
(5.57')
G(t) ::::; 0
for
a::::; t < to,
G(t) ~0
for
to::::; t s: b.
(5.58')
G(t)
(c) In the case to = a, inequality (5.56) and a similar result for functions with increasing increments was proved by Brunk (1956, 1964). (d) Some additional generalizations can be obtained from Theorems 2.21 and 3.6 if we let A(X)=g(x)+S(x), where S(x)=O for a::sx
= Xo·
(c) Pecaric (1983a) used Fuchs' generalization of a theorem on majorization to obtain some similar results. He also obtained some refinements of Petrovic's inequality. These results are extensions of the results in Vasic and Stankovic (1973). 0
160
5. Hermite-Hadamard's and Jensen-Petrovic's Inequalities
5.39. Corollary. Let to E [a, b] be fixed and f be continuous and monotonic with f(to) = O. Let 1J be continuous and convex on I such that f(x) E I for all x E [a, b] and 1J(0) ~O. Let A and 1t be functions of bounded variation such that: 1t(b»1t(a), 1 t ( b ) - 1 t ( a ) ~ A ( b ) - Aand ( a ) t
b
O ~J d A ( X ) J~ d1t(x) a
for
a~t~to,
for
to~t~b.
a b
b
o ~J d A ( x ) J ~ d1t(x) a
t
Then b
b
b
b
(J f(x) dA(X»)/ (J d1t(X»)} ~ (J 1J(f(x» dA(X»)/ (J d1t(X»).
1J{
a
a
a
a
(5.60)
Proof. Immediate by letting g(x) = A(X)/ f ~ d1t(y) in the BarlowMarshall-Proschan Inequality (5.56). 0 5.40. Remark. Inequality (1970a). 0
(5.60)
was
also
considered
by
Boas
5.41. Corollary. Let to, f, and 1J satisfy the conditions of Corollary 5.39. Let A and 1t be functions of bounded variation such that A ( a ) ~ A ( t ) ~ A ( b ) for + d
a ~ t ~ t o ,
A ( a ) - d ~ A ( t ) ~ A for ( b ) t o ~ t ~ b , b
A(b) > A(a),
b
Jd1t(x) ~ J dA(X) + d a
for
d > O.
a
Then (5.60) is valid.
Proof.
This is an immediate consequence of Corollary 5.39.
5.42. Remark. For to = band f decreasing, the condition f(b) 0 be replaced by f(b) ~0 (see Boas, 1970).
0
=0
can
,
5.2. Jensen-Petrovic's Inequalities
161
In a similar fashion we can obtain: 5.43. Corollary. Let to, f, and 4> satisfy the conditions of Corollary 5.39. Let A be a function of bounded variation such that b
t
f dA(t)"'?' 0 for
a s: t :s, to,
a
f dA(t)"'?' 0 for
to < t s: b,
t
b
f IdA(t)1 > O.
and
a
Then the following inequality holds: b
b
b
b
4>{(f f(x)dA(x»)/(fIdA(X)I)}:s,(f4>(f(x»dA(x»)/(f IdA(X)I). a
a
a
a
5.44. Remarks. (a) Corollary 5.43 is a generalization of the Ciesielski Inequality (1958); see also Boas (1970a) and Brunk (1956). (b) Corollaries 5.39, 5.41,_ and 5.43, are proved in Pecaric (1983b). Related generalizations for functions with increasing increments are also 0 valid (see Pecaric, 1984b). Let us consider once again the inequalities with alternative signs (see Remark 5.38(a». First we show that the well-known inequality of Szego (see Mitrinovic, 1970, p. 112; Beckenbach and Bellman, 1961, 1965, p. 47; and Karlin and Studden, 1966, p. 431) is valid under weaker conditions: 5.45. Theorem. Let Xl"'?' X2"'?' ... ",? X2m+l, Xi E I for i = 1, ... , 2m + 1, and let f be a Wright-convex function on 1. Then the following inequality is valid: (5.61)
Proof.
For m = 1, the inequality f(xI) - f(x2) + f(x3) ",? f(x I
-
X2 + X3)
(5.62)
holds if XI ",? X2 ",? x 3. This inequality is a simple consequence of the definition inequality for Wright-convex functions D"'?'O,
162
5. Hermite-Hadamard's and Jensen-Petrovie's Inequalities
by letting al = X3, az = Xz, () = Xl - Xz. Suppose that the theorem is valid for m - 1, and that the conditions of the theorem are satisfied for m. Then we have
by first using the inductive hypothesis for m - 1, then applying (5.62), because Zm+l
2:
(-l)i-l xi;:o:xZ m;:O:XZm+I'
0
i=l
Similarly, we can prove the following: 5.46. Theorem. and let
Let XkE I, k
= 1, ... ,2m + 1 (I is
Zk+l
2:
(-l)i-l Xi E I for
k
= 1, ...
an interval in IR),
, m.
i ~ l
(a) If Zk
2: (-l)i-l Xi
;:0:
0 for
k = 1, ... , m,
(5.63)
i=l
then the reverse of the inequality in (5.61) holds for every Wright-convex functions f : I ~IR. Further, if the reverse ofthe inequalities in (5.63) hold, then the reverse of the inequality in (5.61) is also valid.
(b) If instead of (5.63) the following conditions hold Zk
2: (-ly- lxi
~ o for
k
=
1, ... , m,
(5.64)
i=l
then (5.61) is valid. If the reverse inequalities in (5.64) hold, then (5.61) is also valid. 5.47. Remarks. (a) Theorem 5.46 is a generalization of an inequality of Opial (1960) (see also Mitrinovic, 1970, p. 351). For some related results see Vasic and Janie (1970a) and Pecaric (1980f).
5.2. Jensen-Petrovie's Inequalities
163
(b) Theorems 5.45 and 5.46 can be generalized for functions with increasing increments. The same is true for results given in Vasic and Janie (1970a) and Pecaric (1980f); i.e., these results can be generalized for continuous functions with increasing increments. (c) Let the conditions of Theorem 5.35 be fulfilled with Xl> 1. Then for the convex function -log(1 +x), (5.50) becomes a generalization of the well-known Bernoulli inequality n
n
II (1 + Xi)"'::; 1 + L p.x, , i=l
i ~ l
and (5.52) gives the reverse inequality.
5.2.3.
0
Combination Convexity Inequalities
Hwang and Yang (1985) gave some generalizations of results of Beckenbach (1969). First they proved: 5.48. Theorem. If f E K(b) (K(b) is the class of real-valued functions that are continuous and nonnegative on [0, b] with f(O) = 0) is convex on [0, a] and starshaped on [0, b], where a ::; b, then for all real numbers Xi in [0, b] (i = 1, ... , n) and weights Ai> such that r . 7 ~ 1Ai::; alb, we have
°
(5.65)
Furthermore, the constant alb is the best possible. By letting Ai
= aw.lb
we obtain Beckenbach's (1969) inequality.
5.49. Theorem. Iff E K(c) is starshaped on [0, b] and superadditive on [0, c] where b ::; c, then for every X in [0, c] and every A E [0, blc] we have f(Ax)::; (clb )Af(x). 5.50. Theorem. If f E K(c) is convex on [0, a], starshaped on [0, b], and superadditive on [0, c], where a z: b -s c, then for all real numbers Xi E [0, b] (i = 1, ... , n) satisfying r . 7 ~ 1Xi = co::; c, we have f«A/n)co»::; (A/n)f(co), where O::;A::;alb. This theorem is also equivalent to Beckenbach's inequality.
164
5. Hermite-Hadamard's and Jensen-Petrovie's Inequalities
5.51. Theorem. Iff E K(c) is convex on [0. a]. starshaped on [0, b] and superadditive on [0, c], where a s; b :s: c. then for all real numbers Xi E [0, c] (i = 1, ...• n) satisfying ~ 7 = X1 i E [0. c] and all weights Ai> such that ~ 7 = A 1 :S: a]c, we have
°
(5.66)
Proof. Denoting A= ~ 7 = A1 i we have Axi:S: (alc)x i E [0, a] for i = 1•...• n; and from Jensen's inequality we have n )... (C b ) -; f(Axi) = 2: -; f -b A- Xi . 1=1 1=1 C
f ( 2: AiXi :s: 2: n
1=1
)
n)... I\.
I\.
Since (blc)Xi E [0, b], (clb)A < 1, and f starshaped on [0. b], we obtain the first inequality in (5.66) from the fact that f c I b)A(b I c )x;) :s: (clb)Af«blc)x;). To prove the second inequality in (5.66). note thatfis increasing on [0, c] which implies
«
and
-bc
i
1=1
i
c AJ(!!-Xi) :S:-b f(i Xi) c 1=1 1=1
A i : S : ~ 1=1 b f (Xi)' i
Also. from f«blc)Xi):S:f(b) for i=l, ...• n, we have (clb) ~ 7 = AJ«blc)x;):s: 1 (alb )f(b); and from ~ 7 = 1AiXi:S: ~ 7 = 1AiC:S: a. we 1 :s: f(a). Since f is starshaped on [0, b]. we have obtain f ( ~ 7 = AiX;) f(a) =f«alb)b):S: (alb)f(b). 0 Note that when b = c. Theorem 5.48 is a special case of Theorem 5.51.
5.2.4.
Inequalities for Sums of Order p
Let us denote and
5.2. Jensen-Petrovic's Inequalities
165
where a and p are positive n-tuples such that Pi 2= 1 (i = 1, ... , n). The well-known inequality for sums of order p states that (5.67) for s>r>O (see Hardy, Littlewood, and Polya, 1935, 1952, pp. 28-30). But this inequality is also valid for r < s < 0 and s < 0 < r (see Vasic and Pecaric, 1979a). Furthermore, Vasic and Pecaric also proved that (5.68) for s > r > 0 and a ~> 0; and that
a ~-
vs(a,p)::svr(a,p)
a2 - ... for
> 0 or r < s < 0 and
a ~
s>r>O,
or
r<s
or
a ~-
a ~-
... -
s
(5.69) Additional generalizations of the above results are given in Hardy, Littlewood, and Polya (1934, 1952, pp. 84-85) (a generalization of (5.67» and Vasic and Pecaric, 1979a and of (5.68) and (5.69». Similarly we may define "sums" involving an arbitrary function . We write vcj>(a) =
- 1 ( ~ 1(a;)),
ocj>(a)
= -1((a1) -
Vcj> (a, p)
=
-1 ( ~ / i < / > ( a ; ) ) ,
(az) - ... - (a n
».
Here (x) is a continuous and strictly monotonic function, positive for all positive x and tends to 00 either as x ~0 or as x ~00. We shall also assume that the components of a are all positive and that Pi 2= 1 (i = 1, ... , n). The following two results are simple consequences of Theorem 5.26 and Corollary 5.27 (Vasic and Pecaric, 1979a, and Hardy, Littlewood, and P6lya, 1934, 1952, pp. 84-85). 5.52. Theorem. If 'l/J and X are continuous, posttuie, and strictly monotonic, then v1J1 and V x (v, is either vcj>(a) or vcj>(a, p» are comparable whenever (i) 'l/J and X vary in the opposite directions, or (ii) 'l/J and X vary in the same direction and X/ 'l/J is monotonic. In case (i) we have (5.70) if'l/J decreases and X increases. In case (ii) (5.70) holds if xtw decreases.
166
5. Hermite-Hadamard's and Jensen-PetroviC's Inequalities
If 'l/J and X are continuous, positive, and strictly monotonic, then D", and Dx are comparable under the conditions in the case (ii) of Theorem 5.52, and the inequality
5.53. Theorem.
(5.71)
holds if X/ 'l/J is decreasing. Jensen (1906) used (5.67) in the proof of the following theorem (see also Mitrinovic, 1970, p. 52 and p. 78): 5.54. Theorem.
numbers and r1 , r;;,! 2= 1. Then
Let a ij (i = 1, ... , n; j = 1, ... , m) be posunie real rm be positive real numbers satisfying r 11 + ... +
••• ,
Similarly, by using generalizations of (5.67) we can give some further generalizations of Theorem 5.54 (see Vasic and Pecaric, 1979a). The following result of Mulholland (1950) presents a generalization of Minkowski's inequality: Let the function f be increasing and convex for x 2= 0 and f(O) = O. Furthermore, let the function F defined by F(t) = logf(e') be convex for all real t. Then
5.55. Theorem.
vf(a + b)::s vf(a)
+ vf(b)
(5.72)
holds for all a = (aI' ... ,an), b = (b , , ... ,bn) such that a, 2= 0 and b, 2= 0 (i = 1, ... , n). Note that Milovanovic and Milovanovic (1978) proved vf(a + b, p)::s vf(a, p)
+ vf(b, p)
(5.73)
under the same conditions, and another inequality for sums was given by Klamkin and Newman (1975): n (
(r
)1I(r+l)
+ 1) ~ a ~
(
2= (s
n
)1/(5+1)
+ 1) ~ 1 a ~
,
where 0=a O::sa 1::S"'::san, a i - a i _ 1::s1 (i=l, ... ,n), r2=1, + 12= 2(r + 1).
s
(5.74) and
5.2. Jensen-Petrovlc's Inequalities
167
A weighted version of (5.74) is given in Meir (1981). A refinement of one of Meir's results is given in Milovanovic and Milovanovic (1986), and an improvement can be found in Pecaric (1989a). In the following we state a generalization of Meir's result given in 1. Milovanovic (1980) and Milovanovic and Milovanovic (1986). 5.56. Theorem. Let f(x) and g(x) be differentiable functions on [0,00) satisfying f(O) = 1'(0) = g(O) = g'(O) = O. Suppose that f'(x) and g'(x) are convex on [0,00), and denote h(x) = g(f(x». Then for any given 0= ao:5 a1 :5 ... :5 an and 0:5 Po:5 P1:5 ... :5 p; satisfying 1 a, - ai-1:52 (Pi
+ Pi-1)
i = 1, ... ,n,
for
(5.75)
we have
h - 1 ( Pih'(a ~ i») : 5 f - 1 ( p;/'(a ~ i»)'
(5.76)
If instead of (5.75) the following condition a, - ai-1 :5 Pi
for
i = 1, ... , n
(5.77)
is satisfied, then we have
) h- 1( n- 1Pi + Pi+1 h'(a i) ) :5f-1 (n-1 Pi + Pi+ 1f'(a i). 2 i=1 i-1 2
2:
2:
(5.78)
Klamkin and Newman (1975) gave a similar integral inequality which was generalized by Pecaric (1985d): 5.57. Theorem. Let g: [a, b] ~ ~ be a nonnegative differentiable function with g(a)=O, let f:[O, 0 0 ) ~ [ 000) , and w:[O, 0 0 ) ~ [ 0 00) , be differentiable increasing functions with f(O) = w(O) = 0, and let p: [a, b ] ~ ~ be a nonnegative integrable function. (a) LetO:5g'(x):5p(x)forallxE[a, b]. Ifwisaconvexfunction, i.e., w' is an increasing function, then b
b
h- 1(f p(x)h'(g(x» dX) :5f-1(f p(x)f'(g(x» a
dx),
(5.79)
a
where h(x) = w(f(x». If w is concave (i.e., if w' is decreasing), then the reverse of the inequality in (5.79) holds.
168
5. Hermite-Hadamard's and Jensen-Petrovic's Inequalities
(b) If g'(X) "2:. p(x) for all x E [a, b], then the reverse of the results in (a) is valid. Furthermore, the equality in (5.79) holds iffg(x) = f ~p(x) dx.
Proof.
(a) Since f'(g(x))g'(x) ::sp(x)f'(g(x)), we have x
f(g(x))::s J f'(g(x))p(x) dx. a
We also have h'(g(x)) = w'(f(g(x)))f'(g(x)). Then, using the fact that w' is an increasing function, we obtain x
p (x)h (g(x)) ::s p (x)1' (g(x))w I
I
(J p (x)1' (g(x)) dx)
(5.80)
a
and b
b
J p(x)h'(g(x)) dx::s w(J p(x)f'(g(x)) dX).
(5.81)
a
a
We then obtain the inequality in (5.79) from (5.81). If w is concave, then the reverse of the inequalities in (5.80) and (5.81) are valid; thus the reverse of the inequality in (5.79) holds. The proof of (b) is similar. 0 Forf(x)=x n+ 1 and w(x)=x(m+l)/(n+l) (XE[O,OO)), it follows from Theorem 5.57 that 5.58. Corollary. Let g: [a, b ] ~ ~ be a nonnegative differentiable function such that g(a)=O and O::sg'(x)::sp(x) for all xE[a,b], where p : [a, b] ~ ~ is a nonnegative integrable function. If m "2:. n "2:. 0, then b
b
«m + 1)) J p(x)(g(x))mdx)lI(m+l)::s «n a
If g'(x) "2:. p(x) for all x holds.
+ 1) J p(x)(g(x)t dx)lI(n+l). a
E
(5.82)
[a, b], then the reverse of the inequality in (5.82)
For p(x) = M for all x Newman (1975).
E
[a, b], we obtain a result of Klamkin and
5.2. Jensen-Petrovii's Inequalities
169
5.59. Remark. The following result similar to (5.48) is also valid (Delange, 1947): Suppose that f(x) and g(x) are real-valued and continuous functions on [a, b]. Letf"be continuous on [a, b] withf":50 and let g/ be continuous on the same interval. Furthermore, let g(a)=f(a), g(b)=f(b), and g ( x ) ~ f ( x f) or a<x
J h(g'(x» a
b
dx
~ J h(f'(x»
dx,
a
and equality holds ifff(x) is identical to g(x) on [a, b].
0
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Chapter 6
Popoviciu's, Burkill's, and Steffensen's Inequalities
6.1. Inequalities of Popoviciu and Burkill The following result was proved by Popoviciu (1965) (see also Mitrinovid, 1970, p. 174):
6.1. Theorem. Let n 2 3 and k be positive integers such that 2 5 k 5 n - 1. Let f be a continuous function on an interval I. Then f si convex iff
holdr for all x , , . . . , x,
E I.
We also observe the following result:
6.2. Theorem. Let f :[a, b]+ R be a convex function. Then for all x , y , z E [a, b ] and all p , q, r > 0 we have
Proof(PeEari6 (1986a)). The inequality in (6.2) can be easily proved by applying Theorem 1.7; i.e., for (6.2) to hold for every continuous convex 171
172
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
function on [a, b] (and hence for every convex function on [a, b D, it suffices to show that it holds for the functions
II(x)=4+p,
for
a:=:;x:=:;b
and Mx)=lx-cl
for
a:=:;x:=:;b,
where c E [a, b] is arbitrary but fixed. Obviously II satisfies (6.2); thus we need only show that 12 also satisfies (6.2). For real numbers x, y, z, c and positive real numbers p, q, and r the inequality (p
+ q + r) Px + qy + rz - c I -
I
p+q+r
(q
+ r) Iqy+rz - c I q+r
qy - (r + p) rz + Px - c I - (p + q) Ipx+ - cI r+p p+q I
+ pix -
c] + q
Iy -
c] + r [z - c] ~
°
is equivalent to
Ip(x - c) + q(y - c) + r(z - c)I-lq(y - c) + r(z - c)I-lr(z - c) + p(x - c)I-lp(x -c) + q(y - c)1 + Ip(x - c)1 + Iq(y - c)1 + r(z - c)1
~ 0,
which is just Hlawka's inequality (Mitrinovic, 1970, p. 171)
[u + v + wi - lu + vl- Iv + w] - Iw + u] + lui + Ivl + Iwl ~0, where u, v, ware arbitrary real vectors in a pre-Hilbert (unitary) space withu=p(x-c), v=q(y-c), andw=r(z-c). 0
6.3. Remarks. (a) Theorem 6.2 was proved by Burkill (1974) under the assumption that I is twice differentiable. In Vasic and Stankovic (1976) and Baston (1976) this assumption was removed, and both proofs use Fuch's generalization of a majorization theorem. Another proof of Theorem 6.2 can be found in Lupas (1982). We note that the differentiability condition in Burkill's result can be directly eliminated by using the fact that it is possible to approximate uniformly a continuous convex function by convex polynomials. Using the fact that the convexity of Ion [a, b] implies its continuity on (a, b) and l ( a ) ~ I ( a + ) I , ( b ) ~ I(b-), we can easily prove the validity of (6.2) for an arbitrary convex function. (b) The previous proof of Theorem 6.2 is similar to Popoviciu's proof of inequality (6.1). 0
6.1. Inequalities of Popoviciu and Burkill
173
As in Vasic and Stankovic (1976), let us denote by (Cn,d the inequality
l S i t < ~ < i k s (n ~ P i ) f ( ~ P i h/ ) ( ~ P i i )) ~ G=~ ) G = ~ ~pJ(xi) + (t/i)f((tl PiXi)/
(tl Pi)))'
where Pi>O, xiE[a,b] (i=1, ... ,n), and f : [ a , b ] ~ 1 Ris a convex function. (In fact, C3 ,z) is just inequality (6.2).) Then the implication (C 3 ,z) ::} (Cn,k) for
2 ~ k ~ n - 1 ,
n2::3
holds, and it was proved in Vasic and Stankovic (1976) (see also Pecaric, 1986a).
6.4. Remarks. (a) In the previous discussion, we require that Pi> 0 (i = 1, ... , n) for defining (Cn,k)' This condition can be replaced by a weaker one, namely, that the real numbers Pi (i = 1, ... ,n) are nonnegative such that Pit + ...
+ Pi, > 0 for 1 ~ i. < ... < ik
~ n.
This is equivalent to the condition that no more than k - 1 of the p;'s can be zero. In fact, without loss of generality we can assume that if the function f is continuous and convex, then the inequality for (C n •k ) follows under weaker conditions as we let Pi ~0+. (b) Vasic and Stankovic (1976) also proved the reverse implication (Cn,d ::} (C 3 . z) using Popoviciu's inequality. This implication can be proved as follows: let Pn = 0 (Pn ~0) in (C n.k), then Pn-l = O. Continuing D this process to P4 = 0, we finally obtain (C 3 ,z) (Pecaric, 1986a). A similar result is: 6.5. Theorem. Let the function f:(O, a ] ~ 1 Rbe such that f(x)/x is convex of order m -1, and let Xi E (0, a] (i = 1, ... , m), I:::1 Xi E (0, a]. Then the inequality
- ... + (_1)m-1
L f(Xi) 2:: 0 cn
(6.3)
174
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
holds, where
Proof. We give the proof for m = 2 and m = 3 only. For m = 2, (6.3) becomes f(XI + X2) 2::f(XI) + f(x2), which is obviously true (see Theorem 5.26). For m = 3, (6.3) becomes f(x + y
+ z) - f(x + y) - f(y + z) - f(z + x) + f(x) + f(y) + f(z) 2:: O. (6.4)
By the substitutions
f(x)- f(x)/x,
Xl=x +y +z,
X2=X+y,
and
X3=X for
x, y, z >0
and the inequality in (1.5) we have _ , - f ( - , - x _ + - - , - y ~ + ~ z_ - - , -_ ) f(x + y) + f(x) >0' z(y+z)(x+y+z) zy(x+y) xy(y+z)- ,
i.e., X
~
( y) + z(x +y
+z)
Z
f (x + y + z ) - f (x + y ) + ( )f(x) "2::0. x +Y Y+ z
If y and z are interchanged, we have
u
x y )f(x) "2::0. f (x + y + z ) - f (x + z ) + ( ( y+z ) (x+y+z ) x+z y+z Thus by adding these inequalities we have
x x x - - - f ( x+ Y + z) - - - f ( x + y) - - - f ( x + z) x+y+z x+y x+z
+ f(x) "2::0.
Similarly, we have
--,--y-f(x + y x+y+z
+ z) - -y-f(x + y) - -y-f(y + z) + f(y) 2:: 0, x+y
y+z
z z z - - - f ( x+ Y + z) - - - f ( y + z) - - - f ( x + z) x+y+z y+z x+z By adding the last three inequalities we then obtain (6.4).
+ f(z) "2::0. D
6.1. Inequalities of Popoviciu and Burkill
175
6.6. Remark. Popoviciu (1946) poved the inequality in (6.3) for the case in w h i c h f : [ O , a ] ~ is1 Rconvex, f(O) =0, andf(m-l) exists. Vasic (1968c) proved the same inequality for an arbitrary 3-convex function f without the existence of f(2) and then used this result to prove a more general result. A different proof of Vasic's result was given in Pecaric (1980e). Keekic (1970) showed that the differentiability condition in Popoviciu's result can be removed; he gave a proof for m = 4 only and concluded that the same procedure can be extended to any m. Lackovic (1975) noted that his proof remains correct if f is continuous on [0, a), f(O) = 0, and f(x)/x is a (n -I)-convex function on [0, a). In fact, if f(O) = 0 then clearly (6.3) becomes an equality for some Xi = O. Thus if f is defined on [0, a] and f(O) = 0, then the result can be extended immediately. However, the proof we give here remains correct even if f is not defined at X = O. Thus our result is more general than the result obtained in Lackovic (1975) (see Pecaric, 1986a). 0
A generalization of (6.3) that is similar to (Cn,k) was given by Keckic (1970). Additional generalizations of results of this type can be found in Vasic and Adamovic (1969) and Keckic (1969) and Pecaric (1986a). In the following we state the results due to Pecaric. Let D be a commutative additive semigroup, and let the nonempty set E c D satisfy the condition n
a, E E for i = 1, ... , nand
m
L a, E E::} L ai E E j
i=1
j ~ 1
Further, let G be a commutative additive group which is totally ordered (i.e., G possesses a totally ordering relation ::s satisfying the condition a, b, c E G and a < b ::} a + c < b + c). We start with the following simple result which will be used later. 6.7. Theorem. For any given function f: E (C n ) denote the condition
~G
and n
= 2, 3, ...
let
n
n
2:
2, a,
E
E for i = 1, ... , n,
and
L
a,
E
E.
i=1
Then (a) the implication (C z)::} (C n ) is valid; (b) for n > 2 the implication
176
6. Popoviciu's, Burkill's, and Stelleusen's Inequalities
(Cn ) ::? (C z) is valid if the neutral element 0 of D exists, 0 E E, and f(O) = o.
Proof. (a) can be easily proved by induction, and the proof of (b) is obvious. 0 6.8. Remark. A function satisfying the condition (C z) is usually called subadditive. 0 The following result is a minor modification of a theorem in Vasic and Adamovic (1969):
6.9. Theorem. For any given function f: E denote the condition
~G
and 2:::; k < n let (C n •k )
where a, E E for 1:::; i:::; n, I : 7 ~ 1a, E E. Then (a) the implication (C3,z) ::? (Cn,k) is valid. (b) For (n, k) (3,2) the implication (Cn. k ) ::? (C 3 •Z) is valid if D has the neutral element 0,0 E E, and f(O) = o.
*
Proof. The proof is similar to the proof in Vasic and Adamovic (1969). 0 6.10. Remark. Under the assumption 0 E E, we can obtain the result of Vasic and Adamovic (1969) by applying Theorem 6.2 to the function f(x) - f(O). 0 6.11. Remark. A function f satisfying condition (C 3 ,z) is said to be H-positive (Hlawka-positive; see Burkill, 1974 and Baston, 1976). 0 The preceding theorems are generalized by the following theorem which simultaneously generalizes the analogous result in Keckic (1969).
6.1. Inequalities of Popoviciu and Burkill
6.12. Theorem. For any given function f : E let (Cm,n,k) denote the condition
2J 2: a; (k) j=1 k
(
J
)
S
~G
and 3 S m
S
177
k
+1S
n
(n -m+ 1) 2: f (m-z) 2: a., k- m
+2
_ (k - m 1
j~1
(m"-2)
+ 2)(n -
m
k- m
J
2)
+ +3
k - 2 ) ( n - 2) +(_1)m-1 ( m-3 k-1 for a, E E (1 sis n),
L7=1 a, E E,
2: (m"-3)
f ( ~ 3aii) + ... j=1
(n-m+1) (n
~ f ( a i ) +k -m+l/
)
~ a i
where for all
k <no
Then (a) the implication (Cm,m,m-I) =? (Cm,n,k) is valid; (b) the implication (Cm,n,k) =? (Cm,m,m-I) is valid if D has the neutral element 0, 0 E E and f(O) =0. '
6.13. Remarks. (a) Under the assumption 0 E E, we can obtain the result of Keckic (1969) by applying Theorem 6.5 to the function f(x) - f(O). (b) We shall say that a function f is superadditioe of nth order if it satisfies the condition (Cn,n,n-I)' For n = 2, this property reduces to ordinary superadditivity, and, for n = 3, to H-positivity. 0 For a given function f : E ~G (E and G are as defined above) and for a given sequence {a;}iEK (defined on the set J( of all natural numbers or on some sufficiently large set M of J(), we define
<1>(/) = <1>(/, a, f) =
f ( ~a i)
-
~f(a;)
for
a,
E
E, i
E
I,
and
2: a, E E iel
to be a function on the power set of M. Then we have the following 6.14. Theorem. (a) Let I and J be disjoint nonempty sets of natural numbers, and let a, E E (i E I U J), and LiElUJ a, E E. If the function f
178
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
satisfies condition (C 2), then the inequality cI>(I U J) ~ cI>(I) + cI>(J) holds; i.e., the function cI>, in a limited sense, is subadditve. (b) Let I, J, and K be disjoint nonempty sets of natural numbers, and let a, E E (i E I U J U K) and ~ i E I U ] Ua,K E E. If the function f satisfies condition (C 3,z), then the inequality cI>(I U J U K) - cI>(J U K) - cI>(K U I) - cI>(I U J)
+ cI>(I) + cI>(J) + cI>(K)
~0
holds; i.e., the function cI> is H -positiue, also in a limited sense. (c) More generally, let a, E E (i E UZ=l Ik = A), ~ i E a, A E E. If the function f satisfies the condition (Cn,n,n-I)' then l
L cI>Ci Iii) ~ L c I > ( ~ I2ii) - L cI>(Y Iii) + ... ( n ~ l )
( n ~ 2 )
/=1
( n ~ 3 )
/=1
/=1
L cI>(Ii) + cI>(i I} _m
+ (-lr- l
, ~ l
which means that the function limited sense.
cI> is superadditive of nth order,
again in a
6.15. Remark. In the following we shall confine our attention to the subadditive case because properties of positive or superadditive functions of index set can be preserved by pasing to the limit. 0 Proof of Theorem 6.14. Letting a2) ~ f ( a l )+ f(az), we obtain
a l ~~ i E l a a i nd
a z ~ ~ i E ] a iin
f(al
+
and
cI>(I UJ) = f(
L
at) -
iEIU]
L
tEIU]
f(a;)
~ f ( ~ai) - ~ f ( a ; +) f ( ~ai) - ~ f ( a t ) =
cI>(I) + cI>(J).
This establishes the result in (a). The proof of (b) and (c) is similar. 0
6.1. Inequalities of Popoviciu and Burkill
179
6.16. Corollary. Let Ik = {l, ... , k}, (k = 1, ... ,n), a; E E (i = 1, ... ,n), and ~ 7 = a;1 E E. If the function f satisfies condition (C 2) , then the following inequalities hold: (In)::5 (In)::5
(In-I)::5 . . . ::5 <1>(1 2 ) ::5 0,
min (f(a;
+ a) -
f(a;) - f(aj))
::5 0.
(6.5)
ls.i<j:5n
Proof. For I=I n- 1 and J={n}, (6.1) yields (In)::5<1>(In-I); (6.4) we have
and by
Since the points a I and a2 can be replaced by arbitrary a; and aj, (6.5) follows. 0
6.17. Remarks. (a) Corollary 6.16 is an improvement of Theorem 6.7(a). (b) Let L be a real linear space and U be a convex set in L. A function f: U -IR is said to be convex if for all Xl , X2 E U and a E (0, 1) (6.6) (see Definition 1.1). We show that the well-known Jensen's inequality for convex functions can be obtained easily from (6.6) using Theorem 6.7(a). For this purpose we introduce a semigroup structure on Lx IR+ (=D). The operation "+" is defined by X+Y=(x,p)+(y,q)= (
) PX + qy ,p+q p +q
for
X, YED. (6.7)
We can easily show that this operation is commutative and associative and that X, ... , X n
where E
E
E::9 Xl + ...
+ Xn
E
E,
= U x IR +. We further define the function g: E -IR by g(X) = pf(x) for
X = (x, p)
The condition (Cn) in Theorem 6.7 becomes
E
E.
(6.8)
180
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
which is Jensen's inequality for the convex function f: U - - ~ . We note that condition (C z) is equivalent to inequality (6.6) defining the convexity of f Similarly using Theorem 6.14(a) we can obtain Theorem 3.14 and Corollary 3.15(a) when the p;'s are positive. D Note that Vasic and Stankovic's implication (C 3 ,z) ::} (Cn,k) for convex functions follows directly from Theorem 6.9(a) applied to the case when D = ~ x ~ + , E = [a, b] x ~ +where the operator "+" is defined in (6.7) and the function g: E -- ~ in (6.8). Also note that inequality (6.3) is identical to the condition (Cm,m,m-I)' Thus, by Theorem 6.12, condition (Cm,n,k) is also valid. An interesting application of Theorem 6.14(a) is that the set function considered in Theorem 6.12 is not only subadditive, as shown in Theorem 3.14, but also H-positive (Pecaric, 1986a).
6.18. Remark.
Let a be a given positive n-tuple, k an integer such that
1:5 k s: n, and denote byaik ),
.- .. ,
a ~ ) the
K
= (:) k-tuples formed
from the elements of a. If s, t E ~ , then the mixed mean of order sand t of the positive n-tuple a, when taking k at a time, is
] the power mean of order u of a given n-tuple. Ozeki where M ~ u denotes (1973) considered the special cases A k = M(l, 0; k, a), Bk = M(O, 1; k, a), and C; = M(l, -1; k, a). An inequality for A k was given by Kober (1958) (see also Mitrinovic, 1970, p. 380). Note that the following consequences of (6.1) are generalizations of related results of Ozeki (1973) and Kober (1958):
(n - k)AI + (k - l)An 2: (n - l)Ak,
(n - k)C I + (k - l)Cn 2: (n - l)Ck.
By using Vasic-Stankovic's inequality (the condition (Cn,k))' we can easily give generalizations of these results for arbitrary sand t and arbitrary weights. D
6.2. Stelfensen's Inequality
6.2.
181
Steft'ensen's Inequality
The following result was given by Steffensen (1918) (see also Mitrinovic, 1970, p. 107, and Beckenbach and Bellman, 1961, 1965, p. 48): 6.19. Theorem. Assume that two integrable functions f and g are defined on the interval [a, b] such that f never increases and that O:=; g(t) :=; 1 on [a, b]. Then b
b
a+A
J f(t) dt:=; Jf(t)g(t) dt J f(t) dt, z;
a
b-A
(6.10)
a
where b
A=
Jg(t) dt.
(6.11)
a
Proof. (6.10) follows directly from the following identities (Mitrinovic, 1969, and Mitrinovic, 1970, p. 117); a+A
b
a+A
J f(t) dt - Jf(t)g(t) dt = J (f(t) - f(a + A))(1 - g(t)) dt
a
a
a b
J (f(a + A) - f(t))g(t) dt,
+
(6.12)
a+A b
b
b-A
Jf(t)g(t) dt - J f(t) dt = J (f(t) - f(b - A))g(t)) dt a
b-A
a b
+
J (f(b - A) - f(t))(1 - g(t)) dt. b-A
(6.13)
o 6.20. Remarks. (a) Steffensen (1919) derived the Jensen-Steffensen Inequality (Theorem 2.19) using the second inequality in (6.10) (see also Pecaric, 1979b). Bullen (1970a) derived Steffensen's inequality, Theorem 2.19, using Jensen-Steffensen's Inequality «2.19)). Therefore these inequalities are equivalent.
182
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
(b) The first and second inequalities in (6.10) are equivalent. This can be proved by using the substitution g ( t ) 1~ - g(t) (see Mitrinovic, 1969, and Mitrinovic, 1970, p. 108). (c) Hayashi (1919) generalized inequality (6.10) slightly by imposing the condition: 0:::; g(t):::; A where A is any positive real number (instead of 0:::; g(t):::; 1). However, his result can be easily obtained from (6.10) by using the substitution g ~g / A. (d) Note that Steffensen's inequality cannot be found in Hardy, Littlewood, and P6lya (1934, 1952), and his paper (1918) was not reviewed in Jahrbuch tiber die Fortschritte der Mathematik. However, the paper was cited by G. Szego in his review (see Hayashi, 1919, 1920). (e) Davies (see Mitrinovic, 1970, p. 108) proved Steffensen's inequality by showing that the function a+G(x)
S(x) =
J
x
f(t) dt -
a
Jf(t)g(t) dt, a
where G(x) = S ~ g ( t dt, ) is increasing, Vasic and Pecaric (1984) used that result in the proof of Theorem 3.20 to show that monotonicity of S(x) actually follows from Steffensen's inequality. D In his short note (which contains no references) Apery (1951,1953) proved a different version of Steffensen's inequality. His result states (see also Mitrinovic, 1970, p. 116 and Riekstyn's (1986, p. 23»:
6.21. Theorem.
Let f be a decreasing function on (0,00), and g be a measurable function on [0, 00) such that 0:::; g(x) :::; A (A is a positive real number). Then A
00
J f(x)g(x) dx ss A J f(x) dx, o
0
where
f 00
A=
~
g(x) dx.
o
6.22. Remark. Apery proved Theorem 6.21 by using an identity similar to (6.12). In fact, Mitrinovic (1969) proved Theorem 6.19 by using Apery's idea. D
6.2. Steffensen's Inequality
183
Applying integration by parts, (6.12) becomes a+A
b
a+A
J f(t) dt - J f(t)g(t) dt = - J a
a
a
x
(J (1 - g(t» dt) df(x) a
b
-
J a+,t
b
(6.14)
(J g(t) dt) df(x), x
where A is defined in (6.11). Thus it is obvious that the condition 0:5 g(t):51 (for every t E [a, b]) can be replaced by the weaker condition x
J g(t) dt zzx - a for every x E [a, a + A]
and
a b
Jg(t) dt
~0 for
every x E [a + A, b].
(6.15)
x
However, the conditions in (6.15) are also necessary. Indeed, for f(t) = 1 (t :5x) and f(t) = 0 (t > x for every x E [a, b]) we obtain (6.15) from the second inequality in (6.10). On the other hand, from (6.15) we have b
x
b
J g(t)dt= J g(t)dt- J x
a
g(t)dt~A-(x-a)~O
a
for every x E [a, a
+ A]
(6.16)
and x
b
b
J g(t) dt = J g(t) dt - J g(t) dt s: A:5 X- a for every x E (a + A, b]. a
a
x
(6.17)
Combining (6.15), (6.16), and (6.17) we obtain (6.15)::} (6.18), where x
Jg(t)dt:5X-a a
b
J g ( t ) d t ~ OforeveryxE[a,b].
and
(6.18)
x
Moreover, it is clear that (6.18)::} (6.15). Thus we conclude that (6.15) and (6.18) are equivalent. Consequently, we have proved the following theorem (Milovanovic and Pecaric, 1979):
184
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
6.23. Theorem. Assume that f and g are integrable functions on [a, b], and let A be defined in (6.11). Then the second inequality in (6.10) holds for every decreasing function f iff (6.18) holds. Similarly we can prove: 6.24. Theorem. Let f and g be integrable functions on [a, b]. Then the first inequality in (6.10) holds for every decreasing function f iff x
b
J g(t)dt$b -x and
J
x
a
g ( t ) d t ~ Ofor every X
E
[a, b],
(6.19)
where A is defined in (6.11).
An immediate consequence of Theorems 6.23 and 6.24 is that (Vasic and Pecaric, 1981a): 6.25. Theorem. Let f and g be integrable functions on [a, b]. Then the inequalities in (6.10) hold for every decreasing function f iff x
b
0$ J g(t)dt$b-x and
0$ J g(t)dt$x-a foreveryxE[a,b]. a
x
(6.20)
Some converse results are considered in Pecaric (1982d). 6.26. Theorem. Let f:l ~ ~ ,g : [a, b ] ~ ~ ([a, b] c 1 where 1 is in the interval in ~ ) be integrable functions, a + AE 1 where A is given by (6.11). Then a+A
J f(t) dt a
b
$
f
f(t)g(t) dt
(6.21)
a
holds for every decreasing function f iff x
J g ( t ) d t ~ x - fa orxE[a,a+A] a
b
and
Jg(t)dt$O x
forxE(a+A,b]
(6.22)
6.2. Stelfensen's Inequality
185
and 0 :s: A:s: b - a; or x
f g ( t ) d t ~ x - af orxE[a,b];
(6.23)
a
or b
f g(t)dt:s:O
(6.24)
forxE[a, b].
x
Proof. For f(t) = 1 (t:s: x) and f(t) = 0 (t > x) for all x E I we claim that, from (6.21), (6.22) or (6.23) or (6.24) must be satisfied. To show the other direction, (i) if O:s: A:s: b - a, we can obtain (6.21) from (6.18); (ii) if A> b - a, then a+A
b
b
a+A
f f(t) dt - f f(t)g(t) dt = f f(t)(l- g(t» dt + f f(t) dt a
a
a
b
b
= f (f(t) - f(b »(1 -
sv» dt
a
a+A
+ f (a+A-x)df(x) b
x
b
(J (1 - g(t» dt) df(x)
=- f a
a
a+A
+ f (a+A-x)df(x):s:O; b
186
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
and (iii) if A< 0, then a+.l.
b
J f(t) dt - Jf(t)g(t) dt
a
a
b
J f(t) dt - Jf(t)g(t) dt
= -
a
a+).
a
b
=
Jg(t)(f(a) - g(t)) dt a b
J (x-a-A)df(x)
+
a+.l. b
=-
b
J(J g(t) dt) df(x) a
x a
J (x-a-A)df(x):50.
+
a+.l.
D
Similarly we can prove
6.27. Theorem. Let f: I - 7 functions, b - AE I. Then
~ ,
g: [a, b] - 7
b
~
([a, b] c I) be integrable
b
Jf(t)g(t) dt:5 J f(t) dt a
(6.25)
b-.l.
holds for every decreasing function f iff x
J g(t) dt:50
b
for x
E
[a, b - A]
and
a
Jg(t) dt
?
b- x
x
for x and 0 :5 A :5 b - a; or b
Jg(t)dt?b-x
forxE[a,b];
x
or x
J g(t)dt:50 b
forxE[a,b].
E
(b - A, b]
6.2. Steffensen's Inequality
187
6.28. Theorem. Let g: [a, b] ~ ~ be an integrable function such that there exists aCE [a, b] satisfying g(x) ~1 for x E [a, c] and g(x) ~0 for x E (c, b]. Then (6.21) holds for every decreasing function f: I ~ ~ provided that [a, b] c I and a + A E I. Proof.
Let 0
~A ~b
- a. If c
~a
+ A,
then clearly we have
x
b
J g ( t ) d t ~ x - aforxE[a,c] a
and
J g ( t ) d t ~ O forxE[a+A,b]. x
Suppose that for some Xl E (c, a + A) we have f ~ lget) dt <x, - a. Since f ~ l get) dt ~0, we have f ~get) dt < Xl - a, i.e., a + A < Xl' which is clearly a contradiction. Similarly in the case c > a + A we can prove that (6.13) also holds. Now let A> b - a. Then obviously we have gg(t) dt ~ X - a for X E [a, c] and for some X E (c, b Jwe have x
b
b
Jg(t)dt= Jg(t)dt-J a
a
x
b
g ( t ) d tJ ~ g(t)dt~b-a~x-a; a
i.e., condition (6.23) holds. Similarly, in the case A < 0 we can prove that (6.24) holds. Thus from Theorem 6.19 we obtain Theorem 6.21. D From Theorem 6.20 we can also prove
6.29. Theorem. Let g: [a, b ] ~ ~ be an integrable function such that there exists aCE [a, b] satisfying g(x) ~0 for X E [a, c] and g(x) ~ 1 for X E (c, b]. Then (6.25) holds for every decreasing function f: I ~ ~ provided that [a, b] c I and (b - A) E I. 6.30. Theorem. Let g: [a, b]- ~ be an integrable function such that g ( x ) ~ 1(or g ( x ) ~ O for ) every xE[a,b]. Then for every decreasing function f: I - ~ the reverse inequalities in (6.10) hold provided that a + A, a - AE I. Proof.
This is a simple consequence of Theorems 6.28 and 6.29.
D
6.31. Remark. As noted in Remark 6.20(a), Steffensen (1919) derived the Jensen-Steffensen Inequality using the second inequality in (6.10). In
188
6. Popoviciu's, Burkill's, and Steffensen's Inequalities
the following we show that Theorem 3.3 (the reverse of the JensenSteffensen Inequality) can be obtained from Theorem 6.28; namely, letting Xl;:::' •• ;:::x n and fortE(Xk+l,xd
g(t)=gk=Pk/P n
and
1 ~ k ~ n - 1 ,
where Pk = r . ~ = P 1 i' we show that
Since I can be approximated uniformly on [a, b] by polynomials with nonnegative second derivative, without loss of generality we may assume that ['(x) exists and is increasing, i.e., -['(x) is a decreasing function. Then, from (6.21), we obtain (3.2). 0 By letting get) = AG(t)/ S ~G(t) dt, where A> 0 and S ~G(t) dt > 0, we obtain that (Mitrinovic and Pecaric, 1988c):
IJ b
b
~Jl(t)G(t) dt /
I(t) dt
b-A
a
b
a+A
JG(t) dt
~ I J I(t) dt
a
(6.26)
a
holds iff b
b
J
J
x
a
O ~ A G ( t ) d t ~ ( b - x )G(t)dt x
and
b
J
J
a
a
O ~ A G ( t ) d t ~ ( x - a )G(t)dt
(6.27)
hold for every x E [a, b]; and that the second inequality in (6.26) is valid iff x
J
A G(t) dt a
b
~ (x -
a)
JG(t) dt a
b
and
JG(t) dt;::: 0
(6.28)
x
hold for every x E [a, b]. Of course, using these results we can give extensions of the results related to Bellman's generalization of Steffensen's inequality (Pecaric, 1982b, 1984f). The following theorem (Godunova, Levin, and Cebaevskaja, 1967) is also a consequence of the result stated above:
6.2. Steffensen's Inequality
189
6.32. Theorem.
Let f(x) be a nonnegative decreasing function on [a, b], and <jJ( u) be an increasing convex function for u 2:: 0 with <jJ(0) = O. If g(x) is a nonnegative increasing function on [a, b] such that there exists a nonnegative function gl(X) defined by the equation gl(X)<jJ(g(X)/gl(X)) = 1,
(6.29)
and that J ~gl(t) dt ~ 1, then the following inequality is valid: b
a+).
b
~ iJ
<jJ(J f(t)g(t) dt / J g(t) dt) a
a
(6.30)
<jJ(f(t)) dt,
a
where A = < j J ( J ~g (t) dt).
For <jJ(u)
= uP (p > 1),
Theorem 6.32 becomes
6.33. Theorem. f
Let f(x) be a nonnegative decreasing function on [a, b], Lp(a, b), and let g(t) be nonnegative and increasing on [a, b] such that J ~gq(t) dt ~ 1, where p > 1 and q = p/(p - 1). Then E
b
(J f(t)g(t) dt a
r
a+).
~
(6.31)
J fP(t) ft a
holds, where A = ( J ~g(t) dtY'.
Proof of Theorem 6.32.
Using Jensen's inequality for convex functions and the second inequality in (6.26) we have b
<jJ
(J f(t)g(t) dt / a
b
b
~J
J g(t) dt) a
b
g(t)<jJ(f(t)) dt / J g(t) dt
a
i
~
a
a+).
J
(6.32)
<jJ(f(t)) dt
a
provided that x
b
<jJ(J g(t) dt) J g(t) dt a
a
b
~ (x -
a) J g(t) dt a
b
and
J g(t) dt
2:: 0
(6.33)
x
hold for every x E [a, b]. The second condition in (6.33) is obviously satisfied. On the other hand, the increasing convex function <jJ with
190
6. Popoviciu's, Burkill's, and Stelfensen's Inequalities
<j>(0) = 0 is starshaped, thus <j>(ax) ::;a <j> (x) holds Consequently by (6.29) and Jensen's inequality we have
for
0 < a ::; 1.
x
b
<j>(J get) dt) J get) dt a
a b
b
x
b
I
= <j>(J gl(t) dt(J get) dt) (J gl(t) dt)) J get) dt a
a
a
b
a
b
x
b
::; (J gl(t) dt)<j>(J gl(t)(g(t)jgl(t)) dtl J gl(t) dt) J get) dt a
a
a
b
a
x
::; J gl(t)<j>(g(t)jgl(t)) dt J get) dt a
a b
=J a
x
x
1 . dt J get) dt
= (b - a) J g(t) dt.
a
a
Since g is an increasing functiori, we have (see, for example, Mitrinovic, 1970, p. 9) b
x
_1_ J get) dt b-a
~ _ 1 J_ get) dt,
a
x-a
a
i.e. x
b
(b-a) J g(t)dt::;(x-a) J g(t)dt. a
a
Hence the first condition in (6.33) is also satisfied.
0
We note that (a) (6.32) is an interpolation inequality of (6.30). Also note that the condition in (6.29) can be replaced by (6.29') or, more generally, by b
J gl(X)<j>(g(X)jgl(X)) dx s: b - a;
(6.29")
a
and (b) the proof given above can be found in Mitrinovic and Pecaric (1988b). The same is true for Remarks 6.34(a).
6.2. Steffensen's Inequality
191
Inequality (6.31) was given by Bellman (1959), and has been stated in Beckenbach and Bellman (1961, 1965, p. 41) and Mitrinovic (1970, p. 111). However, this result is incorrect as stated, as noted by Godunova, Levin, and Cebaevskaja (1967). The results given above represent a more general and correct version of that in Bellman. Another corrected version of Bellman's inequality can be found in Bergh (1973):
6.34. Theorem. Let f and g be positive functions on (0, (0), f decreasing and g measurable. If for some p 2: 1, f E LP + L and g E Lq n L 1 such that IIfllL" = 1 and IIgllo = t, where lip + 1/q = 1, then 00
tP
00
r p
J f(x)g(x) dx :521/q(J (f(x»)P dx o
0
(6.34)
holds, and the constant 2 1/q is the best possible.
°
A similar inequality for < P :5 1 can be found in Godunova and Levin (1968). In fact, that result is a consequence of a more general result given below: Let K(x, t) (x EX, t E [0, a]) be a given nonnegative kernel. We say that the function 1>: [0, a ] ~ ~ belongs to the class U(K) if it can be expressed in the form ep(t) = Ix K(x, t) do(x), where o(x) is an increasing function on [0, a] with f x do(x) = 1. Let f be a positive, increasing, and strictly convex function such that f' (x )/f"(x) is concave, and let t
h(t)
=J
t
dh(s),
get)
=J
h(O) = g(O) = 0,
dg(t),
h(a)=1,
o
o
where get) and h(t) are increasing functions on [0, a]. Then a
a
(J f( ep(t») dh(t)
J ep(t) dg(t) :5 f- 1 o
0
holds for every function ep in the class U(K) iff a
J
a
(J f(K(x, t)) dh(t)
K(x, t) dg(t):5 f- 1
o
holds for every x E X.
0
(6.35)
192
6. Popoviciu's, Burkill's, and Stell'ensen's Inequalities
The following generalization of Steffensen's inequality is given in Pecaric (1982f):
6.35. Theorem. Let h be a positive integrable function on [a, b] and f be an integrable function such that f(x)/h(x) is increasing on [a, b]. If g is a g(x):s for every x E [a, b], real-valued integrable function such that then (6.21) holds, i.e.,
O:s
b
f
1
a+A
~
f(x)g(x) dx
a
f
(6.36)
f(x) dx
a
where A is the solution of the equation a+A
f
b
hex) dx =
a
f
h(t)g(t) dt.
a
If f(x)/h(x) is a decreasing function, then the reverse of the inequality in (6.36) holds.
Proof. a+A
a+A
b
J f(t) dt - Jf(t)g(t) dt = f a
a
b
f
g(t)(1 - g(t»f(t) dt -
a
f(t)g(t) dt
a+).
a+A
: s ~ ~ : ~: ~ f
h(t)(1- g(t» dt
a b
-f
f(t)g(t) dt
a+A b
a+A
= ~ ~ : : ~(f~ h(t)g(t)dt- f a
h(t)g(t)dt)
a
b
- J f(t)g(t) dt a+A
f ( b
= and the proof is complete.
g
a+A
D
t )h (t )( f (a + A) h(a + A)
f(t») dt:S 0 h(t) ,
6.2. Steffensen's Inequality
193
Applying Theorem 1.43(a) we obtain, from Theorem 6.34: 6.36. Theorem. Let g be an integrable function such that O:s g(x) :s 1 for every x E [a, b]. (a) If the function f is convex of order n with t
f b
A= (n
lin
(t - at-lg(t) dt)
.
(6.37)
a
(b) Iff is a nonnegative and concave function of order n with f(k)(a) = 1, ... , n - 2), then the reverse of the inequality in (6.36) holds.
=0
(k
6.37. Remarks. (a) Theorem 6.36(a) is proved in Milovanovic and Pecaric (1979), and a similar generalization of the first inequality in (6.10) is also given there. (b) By using Theorems 6.35 and 6.36 we can obtain Theorems 2.68(b) 0 and 2.69, respectively (see Pecaric, 1982f). Some additional generalizations of results in Milovanovic and Pecaric (1979) are given in Fink (1982b). Let f E Mo where Mo is the class of nonnegative and increasing functions. Then f(x) = H dv(t) for some nonnegative Borel measure v, If f(O) > 0, then it includes an atom at 0 and, to facilitate the arithmetic we introduce the notation x , = max{x, O}. Also x':- denotes (x. )" except that 00 will be interpreted as being 1. Thus the indicator function of [t, (0) is (x - t ) ~ . The above formula for f E M o may be written as
f 1
f(x) =
(x -
t ) ~ dv(t).
o
The following class of functions which we consider is larger than that containing such f(x). Let M; denote the class of functions f with the representation
f 1
f(x) =
(x -
t ) ~ dv(t)
for x
E
[0, 1]
o
for some v which is a nonnegative regular Borel measure. Note that k need not be an integer, although the case of great interest is when it is an integer. In particular, M, is the class of increasing convex functions with a value zero at O. More generally, if f E c(n+l)(o, 1) with f(i)(O) = 0 for i = 0, ... , n - 1, f(n) 2:: 0, and I":" 2:: 0 on [0,1], then f E M n .
194
6. Popoviciu's, Burkill's, and Stetrensen's Inequalities
6.38. Theorem. Let J.. be a regular Borel measure such that f6ldJ..(x)1 < 00, and let dx denote Lebesgue measure, then f6f(x) dJ..(x) 2: fof(x) dx holds for all f E Mo iff
f 1
dJ..(x) 2: 0 foreverytE[0, 1]
t
and 1
a
~Or:!}!:l {t +
f
dJ..(x)}.
t
Therefore 1
a = Or:!}!:l {t -
f
dJ..(x)}
t
is the best possible choice.
6.39. Theorem. Let J.. be a (signed) regular Borel measure such that HIdJ..(x)1 < 00. Then f6f(x) dA(X)2: fof(x) dx holds for all f E M; iff
f 1
(x -
t ) ~ dJ..(x) 2: 0
for every t E [0, 1]
o
and (6.38) Therefore the best possible choice is that a equals the right-hand side of (6.38).
6.40. Remark. Some generalizations of Steffensen's inequality for functions of several variables are given in Pecaric (1980d), Fink (1982b), and 0 Pecaric and Janie (1989). Pecaric (1989b) proved the following theorem:
6.41. Theorem. Let G: [a, b] ~ ~ be an increasing and differentiable function and f: I ~ ~ be a decreasing function (I is an interval in ~ such
6.2. Stelfensen's Inequality
that a, b, G(a), G(b)
E
195
I). (a) If G(x) ?x, then
b
G(b)
f f(x)G'(x) dx?
f
a
f(x) dx.
(6.39)
G(a)
(b) If G(x) =5 x, then the reverse of the inequality in (6.39) is valid. Proof.
By letting G(x) = z we have b
b
G(b)
f f(x)G'(x) dx = f f(x) dG(x) = a
a
f
f(G- 1(z» dz.
G(a)
If G(z) > z, then G-1(z) < z and f(G-1(z» ?f(z). Thus we have Glb)
G(b)
f(G-1(z» dz > G(a)
f
f(z) dz;
G(a)
i.e., (6.39) holds. If G(z) =5 z then, of course, we obtain the reverse of the inequality. 0
6.42. Remarks. (a) For a = 0 and G(O) = 0, we obtain a result in Ostrowski (1970, pp. 83, 161,263) from Theorem 6.41(b). , G ( b ) ~ o o we , obtain the result in Volkov (b) For a=O, b ~ o o and (1969). This result is a generalization of the following inequality of Gauss (see, for example, Mitrinovic, 1970, p. 300): Letfbe never increasing for x> 0 then, for any A> 0, 00
2
1.. f A
00
f ( X ) d x = 5 x~ 2f(x)dx. f 0
Indeed, this inequality follows if we also let G (x) = 4x 3 /271.. 2 + A for 1..>0. (c) Theorem 6.19 is, in fact, a consequence of Theorem 6.41. To see this, let G(x) = a + f ~ g(t) dt in Theorem 6.41 where g satisfies the conditions of Theorem 6.19, then G(x) =5x holds and we obtain the second inequality in 6.10. To obtain the first inequality we let G(x) = b - f ~ g ( t d) t in Theorem 6.41. (d) For another generalization of Gauss' inequality, see Petschke 0 (1989).
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CebySev-Gruss’ , Favard’s, Berwald’s, Gauss-Winckler’s, and Related Inequalities
Chapter 7
7.1.
Cebysev-Griiss Inequality
A classic result due to CebySev (1882,1883) is stated in the following theorem. 7.1. Theorem. Let f, g : [ai b ]+= R and p : [a, b ]+= R + be integrable functions. I f f and g are monotonic in the same direction, then b
6
a
a
b
a
b
a
provided that the integrals exist. I f f and g are monotonic in opposite directions, then the reverse of the inequality in (7.1) is valid. In both cases, equality in (7.1) holds iff either g or f is constant almost everywhere. A discrete analogue is given by 7.2. Theorem. Let a and b be two n-tuples of real numbers monotonic in the same direction, and p be a positive n-tuple. Then
If a and b are monotonic in opposite directions, then the reverse of the inequality in (7.2) holds. In either case equality holds iff either a , = . . = a, o r b , = b,.
-
=
a
CebySev’s inequality can be generalized for m (>2) functions (or n-tuples).
197
198
7. Related Inequalities
7.3. Theorem. Let t., ... .t: (m > 2) be nonnegative real-valued functions and p a positive function on [a, b]. If t., ... .I; are monotonic in the same direction, then b
(fp(x) dx a
r-
1
il
b
b
f p(x) rlfi(X) dx 2= (f p(x)f;.(x) dX). a
(7.3)
a
If It, ... ,fm are positive on [a, b], then the equality in (7.3) holds iff at least m - 1 of the functions f1' ... .I; are constant almost everywhere. 7.4. Theorem. Let aj (j = 1, ... , m; m > 2) be nonnegative n-tuples which are monotonic in the same direction, and p be a positive n-tuple. Then
(7.4) If all n-tuples are positive, then the equality in (7.4) holds iffat least m - 1 n-tuples among a1' ... , am have identical components.
7.5. Remarks. (a) The history of Cebysev's inequality and the question concerning its priority are considered in the expository paper by Mitrinovic and Vasic (1974). It was noted that for the special case in which Pi = a, (i = 1, ... ,n), inequality (7.2) was obtained earlier by Laplace (1749-1827), and that inequality (7.1) with p(x) == 1 was obtained by Winckler (1866). (b) Cebysev's papers were published in 1882 and 1883, and inequality (7.3) with p(x) == 1 was considered by Andreief (1883a). (c) There exist several results which show that Cebysev inequalities are valid under weaker conditions: (i) The condition that the functions be monotonic can be replaced by the condition that they be similarly ordered. The same is valid for sequences. In this case Theorem 7.1 is a simple consequence of the following identity:
f b
a
f b
p(x) dx
f b
p(x)f(x)g(x)dx -
a
a b
b
= ~ J a
f b
p(x)f(x) dx p(x)g(x) dx a
Jp(x)p(y)(f(x)-f(y»(g(x)-g(y»dxdy. (7.5)
a
7.1. Cebysev-Griiss Inequality
Note that the functions f: I ordered if
~IR
and g: I
~IR
199
are said to be similarly
(f(x)-f(y))(g(x)-g(y))2:0 forevery
x. v e I
holds, and they are said to be oppositely ordered if the reverse inequality holds. A similar definition applies to sequences. Of course, the generalization of the identity in (7.5) for functions with several variables is also valid (see Berljard, Nazarov, and Svidskii, 1967, or Mitrinovic and Vasic, 1974). Thus similar generalizations of Theorems 7.1-7.4 are valid (for similarly ordered functions and sequences). The first such result is given in Hardy, Littlewood, and P6lya (1934, 1952, p. 168). (ii) The condition that the functions be monotonic can be replaced by monotonic in mean. Such a result for two functions (sequences) was given by Biernacki (1951), and for m (2:2) functions (sequences) by Burkill and Mirsky (1975). A simple proof and some interpolations were given in Vasic and Pecaric (1982d), and additional generalizations for functions with increasing increments were given in Pecaric (1984g) (see Theorems 2.30, 3.12, 3.17 and Remark 3.19(b)). (iii) Steffensen (1920) noted that Theorem 7.1 is valid when f is an increasing function on [a, b] and g satisfies the condition x
P ~ XJ ) p(t)g(t) dt:5 P ~ b J ) p(t)g(t) dt, a
x
b
where
P(x) =
Jpet) dt. a
a
(7.6) Pecaric (1980b) (see also Vasic, Stankovic, and Pecaric, 1985b) noted that instead of pet) > 0, we need only that P(x) > 0 and P(b) > O. Steffensen and Pecaric also gave corresponding discrete analogous results. Steffensen's result contains a result of Biernacki (1951), and Pecaric's results is a generalization of Popoviciu (1959b) (see also (iv)). (iv) The condition that pet) > 0 (Pi> 0) can be replaced by
0:5 P(x):5P(b)
for
a:5x:5b.
(7.7)
The same condition also appears in the Jensen-Steffensen Inequality; thus Cebysev's inequality and the Jensen-Steffensen's inequality are related. If the functions have increasing increments, then both (7.1) and (7.2) follow from Jensen-Steffensen's inequality. For the general case, a proof for (7.2) can be found in Popoviciu (1959b).
200
7. Related Inequalities
(v) The conditions that the functions (and sequences) be positive in Theorems 7.3 and 7.4 were weakened by Ahlswede and Daykin (1979). That is, if p(x) == 1 and Pi == 1, then Theorems 7.3 and 7.4 are valid for increasing functions and increasing sequences aj which satisfy
t
b
t ( 0 ) + b ~ a J t ( X ) d x : 2 for :0
j=1, ... ,m
(7.8)
a
and 1
n
ajl + - - L aji:2: 0 for n -1 i=2
j
= 1, ... , m.
(7.9)
(vi) Another modification of the conditions for Cebysev's inequality was given by Levin and Steckin (see, for example, Karlin and Studden, 1966, pp. 414-415). The following result is a generalization of their result and can be proved similarly: Let v: [0, 1] ~ ~ be an increasing function such that v(x) = -v(1- x), and let f: [0, 1 ) ~ ~ be an integrable function with respect to v such that the following two conditions hold:
f ( X ) i s i n C r e a S i n g f O r X E [ oand ,~l
f(x)=f(1-x)
for
xE[0,1].
Then for every continuous convex function <j> we have 1
1
1
1
J dv(x) J f(x) <j>(x) dv(x):::; J f(x) dv(x) J <j>(x) dv(x). o
0
0
0
As a special case we have the inequality of Leven and Steckin: 1
1
1
J f(x) <j> (x) dx:::; J f(x) dx J <j>(x) dx, 0 0 0
For a more general result, see Clausing (1980). (d) For other similar results, see the noted paper by Mitrinovic and Vasie (1974) and Section 8.l. (e) Theorems 7.1-7.4 have been generalized for monotonic functions of several variables. The case p(x) == 1 was generalized by Vietoris (1974). Pecaric, Janie, and Beesack (1982) showed that an analogous generalization is valid for the case when p(x) = P\(Xl) ... Pk(xd, and for similarly defined sequences of weights. In fact, they gave a related result for Stieltjes' integral. Additional generalizations are given in Pecaric and
71..
Cebykv-Griiss Inequality
201
Mesihovik (1988), where a similar generalization of (b) is also given. Some applications in number theory are given in Rutkowski (1989). 0 In the rest of this chapter we shall use the following notation
a
a
A simple consequence of (7.10) is the following result: Let p be a nonnegative function. If 2 0 for all x i , . . ,x,
I.L(xi)ln Igi(xi)ln
E
[a, b ] ,
then (7.11) Simple consequences of (7.11) include the inequalities of CebySev, Cauchy, and other inequalities. Of course, Gram’s inequality
II
b
a
p(x).L(xl&(x)dx
1
20
(7.12)
is also an obvious consequence of (7.11). Identity (7.10) for Stieltjes’ integral is given in Chokhate (1929). A generalization of (7.10) for functions of several variables is also valid (the
202
7. Related Inequalities
case p ( x ) = 1 is given in Ogura, 1920). Results analogous to (7.11) and (7.12) are also valid in this case. An interpretation of (7.12) for the case p ( x ) = 1 is given in Ogura (1920), and using the idea in his proof we can obtain the weighted version of his result: Let q51(x), & ( x ) , . . . , q5n(x), . . . be a system of normalized orthogonal functions with respect to p, i.e.,
a
If we denote by a i ( i ) the following
I
b
ai(fi) =
p(x)fi(x)&(x) dx for j = 1, . . . ,p ,
i = 1, 2, . . . ,
a
then we have 2
h
where C denotes the summation with respect to m , , . . . , mP satisfying 1P m , < m2 < * . < mP 5 k ; k z p being any fixed positive integer. Of course, similar results can be formulated for Stieltjes’ integral. Discrete versions of (7.10) are also valid. For example, we have
If Ne let f i= x i , x ; = y i , g $ = z j , g$ = u j , then, after simple algebraic manipulations, we obtain the following identity in Seitz (1936/37):
I
i=l j=1
;=I j = 1
As an immediate consequence of the above identity we can formulate the following (Seitz, 1936/37): If, for all positive integers i, j , r, s such that
7.1.
l l i < j s n and l l r < s < r n , we have 2 0 and
IYi
CebySev-Griiss Inequality
;: : 1
203
:;120,
then the inequality
holds. This inequality is also a generalization of CebySev's and Cauchy's inequalities (see, for example, MitrinoviC and VasiE, 1974). Finally, we give an interesting consequence of (7.11) for generalized convex functions. Let f : (a, b ) 4 R be a convex function with respect to an ECT-system of functions {ui}: (see (7.4)) (in symbols, we write f E C(bio, u l , . . . , u,)). The following result is a simple consequence of (7.11): Let f E C ( u o ,u l , . . . , u,) and g E C(vo,' u l , . . . , vn), and let p be a nonnegative integrable function. Then
2
a
l a
0.
(7.13)
a
+
If f, g : (a, )+ R are two (n 1)-convex functions, i.e., if f, g E C(1, t, . . . , t"), then (7.13) becomes (for p ( x ) = 1)
...
a
...
...
...
a
a
204
7. Related Inequalities
For n = 1, we obtain that for all convex functions inequality is valid: b b b f f(x)g(x) dx - b
~ _a f
a
f and g the following
f(x) dx f g(x) dx
a
a
7.6. Remarks. (a) Inequality (7.14) was proved by Lupas (1972a). Moreover, in the case when S: (x - (a + b )/2)g(x) dx = 0, this result was proved by Atkinson (1971) with the additional condition that the second derivatives of f and g exist. (b) In Pecaric (1989d), inequality (7.14) is generalized for (2,2)convex f u n c t i o n f : P ~ (/= 1 R [a, b]): b b b
~a f
f f(x, x) dx - b a
a
;:::
12
f f(x, y) dx dy a
(b - a)3
fbfb(x_a+b)(y_a+b)f(X y)dxdy. 2 2'
(7.15)
a a
(c) Some other results related to inequality (7.14) are given in Lupas D (1972a), Vasic and Lackovic (1979), and Pecaric (1983d). Fan (1953) considered the inequality b b
b
f f K(x,y)f(x)g(y)dxdy:5Bf f(x)g(x)dx a a
(7.16)
a
for nonnegative and decreasing functions f and g; there exist many generalizatons of this result (see Pecaric, 1980d, Pecaric and Crstici, 1981b, and Pecaric, 1984d, 1987). For example, the following theorem holds:
7.7. Theorem. Let p : P ~IR and q:I ~IR (/ = [a, b]) be two integrable functions. Then for every (1, I)-convex function f: P ~IR the inequality b b b K(f,p,q)=
f a
a(x)f(x,x)dx-
ff a
a
p(x,y)f(x,y)dxdy;:::O (7.17)
7.1. Cebysev-Griiss Inequality
holds ifffor every x, y Pea, y) = Q(y),
E
205
[a, b] we have P(x, a)
= Q(x),
P(x, y):s Q(max(x, y»,
(7.18) where Q(x)
=
f ~ q(t) dt and P(x, y) = f ~
g pes, t) dt ds.
Interpolation inequalities of Cebysev's inequality are given in Vasic and Djordjevic (1973), Vasic and Pecaric (1981b, 1982c), and Mesihovic (1985). In the following we give the result in Pecaric (1987). 7.8. Theorem. Let Pij (ij = 1, ... , n) be nonnegative real numbers such that Pij = Pji (i, j = 1, ... , n). If (7.19) holds, then
(7.20) where n
Cn(a, p)
= 2:
i=l
n
n
n
2: Pijajj - 2: j=l 2: Pijaij' j=l i ~ l
7.9. Remark. Theorems 7.3 and 7.4 follow from Theorems 7.1 and 7.2 by induction. Note that by applying Theorem 6.7 we can obtain many results that are usually proved by induction. The same is true for Cebysev's inequality. Indeed, the set of all positive and decreasing (or increasing) functions X defined on [a, b], with the multiplication of functions as an interior operation, is a semigroup D. Let the set E c D be nonempty and have the property that Xl' X 2 E E implies Xl + X 2 E E, and let us define the function f : E - ~ by b
f(X) =
b
JX(t) d{t(t)/ Jduit), a
a
{t being a nonnegative measure such that f ~dll(t)
'*
0 and such that the integral in the numerator exists for every X E E. For the operation "+" in ~+, let us take the ordinary multiplication of positive numbers; then this operation has neutral element 1. Let us denote b
r: = }] [f Xi du./ a
b
b
f J/[f du
a
a
b
Xl' .. x; du./
f J. du
a
206
7. Related Inequalities
Since the function X(t) = 1 (a ~t E, we have (by Theorem 6.7) T2
~ b)
is a neutral element and belongs to -s 1, and Corollary 6.15 yields
~T;
~1
(7.21) and b
b
b
b
~ l s ~ ~ s (f n Xi du f x, dll) / (f du f XiX dll) ~ 1.
t;
(7.22)
j
a
a
a
a
o
G. Gruss (1935) proved the following converse of Cebysev's inequality (conjectured by H. Griiss-see footnote in G. Gruss, 1935):
7.10. Theorem.
Let f, g be two integrable functions defined on I
= [a, b]
and satisfying
(7.23) for every x
E
(a, b), where c l' C2> d 1, d 2 are fixed real numbers. Then
(7.24) where b
T(f, g) = b
b
~ a f f(x)g(x) dx -
(b
b
~ a)2 f f(x) dx f g(x) dx,
a
a
a
and the constant ~ in (7.24) is the best possible.
A discrete analogue of (7.24) is given in Biernacki, Pidek, and Ryll-Nardzewski (1950):
7.11. Theorem. d l ~ b i ~ d 2 f
Let a and b be two n-tuples such that lo ~r i ~ n Then .
Cl
~a,
~ C2
and
(7.25) where [x] denote the largest integer
~ xand
7.1. Cebysev-Griiss Inequality
207
The following result is related to Griiss' inequality:
7.il. Theorem. Let f, g be absolutely continuous on I = [a, b], and let be bounded on I. Then 1 IT(f, g)l:::; -2 (b - a)2 sup II'(x)l- sup Ig'(x)l, (7.26) 1 XEI XEI
1', g'
where equality in (7.26) holds iff I' and g' are constant. Moreover, if are continuous, then
1', g'
1 T(f, g) = 12 (b - a f l ' ( ~ ) g ' ( 1 / ) for some ~ , 1/ E I.
(7.27)
7.13. Remarks. (a) Inequality (7.26) was proved by Cebysev (1882), and identity (7.27) can be found in Ostrowski (1970). (b) Several generalizations of Theorems 7.10-7.12 are given in Pecaric (1984d, 1987). For example, the following result is valid: (i)
Let a = (ai, ... , an) and b = (b l , . . . , bn) be real n-tuples monotonic in the same direction, and let p = (PI, .. _, Pn) be a real n-tuple such that k
0:::; Pk
:::;
P;
for
k
= 1, ... , n -
1
and
Pk
= L. Pi'
(7.28)
i=I
If lilakl
~ m and lilbkl ak+1 - akJ then
~r
T(a, b; p)
for k = 1, ... , n -1 where Sa; = ~ mrT(e, e;
p)
~ 0,
(7.29)
where
and e = (0,1, ... ,n -1). If a and b are monotonic in opposite directions, then
T(a, b; p):::; mrT(e, e; p):::; 0,
(7.30)
where e= (n -1, ... ,1,0). (ii) Let a and b be real n-tuples monotonic in the same direction such that lilakl ~ m, lilbkl ~ r for k = 1, ... , n - 1, and let p be a real n-tuple such that either 0< P; :::; Pk
for
k: = 1, ... , n - 1
(7.31)
208
7. Related Inequalities
or
0:5 P; :5 Fk
for
k = 2, ... ,n
and
h
= P; - Pk -
I •
(7.32) Then the reverse of the inequalities in (7.29) is valid. If a and b are monotonic in opposite directions, then the reverse of the inequalities in (7.30) holds. l c and I ~ b k :l 5 d (iii) Let a and b be two real n-tuples such that I ~ a k :5 for k = 1, ... , n - 1, and let p be a real n-tuple such that (7.28) is satisfied. Then IT(a, b; p)l:5 cdT(e, e; p) holds. If (7.31) or (7.32) holds instead, then IT(a,b;p)l:5cdT(e,e;p). These results are generalizations of results in Lupas (1981) and Mitrinovic (1970, p. 341). In fact, for m = r = 0 (7.28) is a generalization of Cebysev's inequality, as noted in Remark 7.5(c.iv). Pecaric also proved some more general results. For a (l,l)-convex sequence {aiJ ((1, 1)concave sequence {aij}) he obtained the inequality
The continuous analogue of (7.33) is that (iv) Let F be a (l,l)-convex function, and let f and g be two real-valued functions such that F(f(x), g(y)) is integrable over [z and a :5f(x):5 A, b :5g(x):5 B for all x E [a, b], where a, A, b, B are fixed real numbers. Then b
b
b
I b ~ a f F ( f ( X ) , g ( X ) ) d x - ( b ~ af ) F(f(X),g(y))dXdyj zf a
a
a
1 :5 4: (F(A, B) - F(A, b) - F(a, B)
+ F(a, b)).
The following Pecaric's result generalizes (7.27): Assume that p, q satisfy the conditions in Theorem 7.7, and let K(f, p, q) be defined as in (7.17). We have (1) If f: P ~ ~ has continuous partial derivatives t., fz, and fZI on P, then
Ki], p, q)
= fZI(;, 1/)K((x - a)(y - a), p, q) for all
;,1/ E [a, b];
7.1. Cebysev-Griiss Inequality
209
and (2) if f, g : P ~IR have continuous partial derivatives f1' fZ1' gl' gz, and gZl with gZl 0 on P, then
*"
f Z l ~ ~1J ~ K(g, p, q) gZl ,1J
K(f, p, q) =
for all
fz,
~ , 1 JE [a, b].
(c) Similar converses of Theorems 7.3 and 7.4 are given in Pecaric (1980g) and Roghi (1971-72). Pecaric's result states: Let
(J p(t) dt) m-1 JDh(t) dt -/1 (J jj(t)p(t) dt). b
D m(f1, ... ,fm; p)
=
b
a
b
a
a
If jj(x) are monotonic functions on [a, b] for j = 1, ... ,m, and if p is a nonnegative function on [a, b], then IDm(f1,'" ,fm;P)1 ::5(m _1)m-m/(m-1) b
x
(J p(t) dtf jU (ljj(b)1 + Ijj(b) - jj(a)l). a
Furthermore, the constant is the best possible. (d) In the proof of Theorem 7.10 given in Mitrinovic (1970, pp. 70-71), the following inequality is given: T(f, gf::5 T(f, f)T(g, g).
(7.34)
Note that a more general result is also valid: Let b
[f, g]
= IJ p(x)t(x)gj(x) dxl a
n
be the determinant given in the identity (7.10). Then [f, gf::5 [f, n[g, g]. The result is due to Davis (see Beckenbach and Bellman, 1961, 1965, p. 61), where the inequality with p(x) =' 1 is given, and was first proved by Everitt (1957). 0 Ostrowski (1970) gave the following result:
7.14. Theorem.
Let f be a bounded measurable function on I such that ::5f(x)::5 Cz for x E I, and assume that g'(x) exists and is bounded on I. Then
Cl
1 IT(f, g)1 ::5 -8 (b - a )(c z - c 1) sup Ig'(x)l· xel
Furthermore, the constant A in (7.35) is the best possible.
(7.35)
210
7. Related Inequalities
The following two theorems are proved in Lupas (1973) and are refinements of the results in Ostrowski (1970). For notational convenience let us define b
Ilfllz =
(b ~ a J If(x)I dX) Z
liZ
.
a
7.15. Theorem. Let f, g be locally absolutely continuous on I = (a, b) with f', g' E Lz(I)· Then (b - a)Z IT(f,g)l:5
n
z 11f'llz·llg'llz.
(7.36)
Furthermore, the constant 1/nz in (7.36) is the best possible.
7.16. Theorem. Let f be locally absolutely continuous on I with f' E Lz(I) and let g be bounded and measurable on I with d, :5g(x):5 d z on I. Then 1 IT(f, g)l:5 2n (d z - d 1)
,
Ilf liz·
(7.37)
7.17. Remark. The weighted versions of (7.36) and (7.37) are given in Milovanovic and Milovanovic (1979). D Of course, the Gruss Inequality can be improved if we consider smaller classes of functions. A function f defined on (a, b) is said to be monotonic of order p if it is a convex (concave) function of order 1, ... ,p. If f is monotonic of order p in (a, b) for every p = 1, 2, ... , it is said to be absolutely montonic in (a, b). If f is absolutely monotonic in (a, b), then it has derivatives of all orders and f(kl(X) 2':
°
or
f(k l(X):5
°
for all
k
=
1, 2, . ..
and x
E
(a, b).
A function f is said to be completely monotonic on (a, b) if f( -x)
absolutely monotonic in (-b, -a) or equivalently, and it satisfies f'(x):50,
f"(x) 2': 0,
f"'(x) :50,
...
f"(x) :5 0,
f"'(x) 2': 0, ...
or
IS
7.1. Cebysev-Griiss Inequality
for x in (a, b). Griiss (1935) proved that if monotonic functions, and if (7.23) holds, then
211
f and g are absolutely
4 IT(f, g)l:5 45 (cz - cl)(d z - d 1 ) ,
(7.38)
and the constant 15 is the best possible. Pecaric (1983e) noted that (7.38) is also valid if f and g are completely monotonic functions. If f is absolutely monotonic and g is completely monotonic, then (7.39) where the constant -b is also the best possible. Pecaric also gave a result for three functions, and a related result was given by Hardy (1936) (see also Mitrinovic, 1970, p. 72). Landau (1935) proved that (7.38) holds if f and g are monotonic of order 4. Needless to say, this is a nontrivial improvement of Griiss' result. For functions of order k = 2, 3, Landau proved that 1 ' IT(f, g)1 :5 9(cz - Ct)(d z - d 1 )
for
k = 2,
(7.40)
9 IT(f,g)I:5100(cZ-Cl)(dz-dl) for
k=3.
(7.41)
Note that using inequality (7.34) we can obtain a series of results when
f and g belong to different classes of functions. For example, if f is monotonic of order 2 and g is monotonic of order 3, then (7.42) Some other bounds for IT(f, g)1 can be obtained by using the Berwald inequality (see Section 7.2). As a special case, we have
where f is a positive and concave function on (a, b). This inequality is equivalent to the inequalities b
T(f, f):5
~ (b ~ a J(f(x))Z dx) z a
b
and
T(f, f):5
~ J (f(x))Z dx.
212
7. Related Inequalities
Thus, using (7.34) we obtain b
IT(f, g)l:5
b
~ IIfllzllgllz:5 ~ (b ~ a Jf(x) dx )(b ~a Jg(x) dx ), a
a
(7.43) where f and g are positive and concave functions on (a, b). This is an interpolation inequality for an inequality given in Mitrinovic (1970, p. 73) (see also Gruss, 1935, and Franck and Pick, 1915). Other bounds can be obtained from theorems which are proved in Franck and Pick (1915) and Blaschke and Pick (1916). For other related results, see Fempl (1965) and Knopp (1935). Griiss' inequality provides bounds for the difference in T(f, g). An analogous result for the ratio 1
R(f, g)
=
1
1
(J f(x) dx Jg(x) dx ) / (J f(x)g(x) dX) 0 0 0
was obtained by Karamata (1948). He proved that if integrable functions on [0, 1] and if O
and
O
for
f
and g are
0:5X:51,
then K
-z :5 R(f, g):5 K zwith · y(ib+VAB K = Viii YAh >- 1. aB+
Ab
Lupas (1978) gave an analogous result for positive linear functionals.
7.2.
Favard's, Berwald's, Gauss-Winckler's, and Related Inequalities
Favard (1933) proved the following result:
7.18. Theorem. Let f(x) be a nonnegative continuous concave function on [a, b], not identically zero, and let ep(y) be a convex function on [0, 2f], where b
- b -a 1 f=
J f(x)dx. a
(7.44)
-r
Then
;1
7.2. Related Inequalities
213
b
<jJ(y) dy
~b ~ a f
o
<jJ(f(x)) dx.
(7.45)
a
7.19. Remarks. (a) In Karlin and Studden (1966, p. 412) a more general inequality is given: 2J-c
21 ~ 2c f
b
<jJ(y) dy
~b ~ a f
<jJ(f(x)) dx,
(7.46)
a
c
where c satisfies 0 < c s; fmin (where fmin is the minimum of f(x)) and <jJ is convex on [c, 21- c]. The reverse inequality is also given in Karlin and Studden (1966, pp. 412-13): If f is a continuous nonnegative convex function on [a, b], d > fmin, and <jJ is convex on [d, 21- d], then 2J-d
b
2 1 ~ 2 d f < j J ( Y ) d y s ; b ~<jJ(f(x))dx. af d
(7.47)
a
(b) In Popoviciu (1944, p.' 35), Favard's inequality is given in the form (with a = 0 and b = 1) 1
1
(7.48)
f <jJ(f(x)) dx s; f <jJ(21x) dx. o
0
This fact suggests that Theorem 7.18 is a consequence of majorization theory (see Section 12.1) in an integral form. 0 Pecaric (1984b) used (7.48) in the proof of the following generalizations of Favard's inequality:
7.20. Theorem. Let x(t) = (Xl(t), ... ,Xk(t)), where the components Xj(t) are nonnegative concave functions defined on [a, b] such that b
i = b
~a
f
Xj(t) dt
for
j = 1, ... , k.
(7.49)
a
r.
If f: I ~ ~ (I = [0, p 2i s; p, and x(t) E I for t function with increasing increments, then
f
E
[a, b]) is a continuous
2i
1 2i
o
f(y,···, y) dy ~ b _1 af(x(t)) dt.
(7.50)
214
7. Related Inequalities
If the components xlt) are nonnegative convex functions with xj(a) = the reverse of the inequality in (7.50) holds.
o(j = 1, ... , k), then
An important generalization of Favard's inequality is given by Berwald (1947):
7.21. Theorem.
Let f(x) be a nonnegative, continuous concave function, not identically zero on [a, b], and X(t) be a continuous and strictly monotonic function on [0, Yo], where Yo is sufficiently large. If i is the unique positive root of the equation z
~
f
b
X(y) dy
=b
~a
o
then for every function we have
f
(7.51)
X(f(x» dx,
a
1>: [0, Yo]
~IR
which is convex with respect to X,
~o J 1 > ( Y ) d Y 2 : b1>(f(x»dx. ~af
(7.52)
a
7.22. Remark. A generalization of Berwald's inequality for concave functions of several variables is given in Borell (1973b). 0 The following related results (Theorems 7.23 and 7.24) were given by Popoviciu (1939):
7.23. Theorem.
Let 1>:[a, b ] ~ 1 R be convex and f:[O, 1 ] ~ 1 Rbe continuous, increasing, and convex such that a ~f(x) ~ b for x E [0, 1]. Then 1
f
1>(f(x» dx ~
b
+ a - 2c b_ a
f b
2(c - a) 1>(a) + (b _ a)2
o
1
1>(x) dx,
C
=
f
f(x) dx.
o
a
(7.53) If 1> is strictly convex, then the equality in (7.53) holds iff xf(x)=a+(b-a)
A+ Ix - AI
2(1-A)
,
where
A= b +a -2c. b- a
(7.54)
7.2. Related Inequalities
215
7.24. Theorem. Let ¢: [a, b] ~ ~ be continuous and convex, and let f: [0, 1] ~ ~ be convex of order 1, ... , n + 1 such that a :s; f(x) :s; b for x E [0, 1]. Then 1
1
J¢(f(x)) dx:s; J ¢ ( ~ ( A x)), dx o
0
tor
J'
ja
+b
U - 1)a
+b
- - <: C <: -'-'-----'--j +1 - j ,
2:s; j:s; n,
(7.55)
and 1
J¢(f(x))dx:S;V(c)
for
o
na +b a:S; c :s;-n+1 '
(7.56)
where ja +
b) + (U - l)aj + b-t)).
~ ( t , x ) = a + j U((+t1 )j+1
X X
1- 1
(7.57) and b
¢(x)dx _ b + na - (n + 1)x () (n+1)(x-a)f V(x) b-a ¢ a + n(b_a)(n+l)/n (x_a)(n-l)/n' a
(7.58) If ¢ is strictly convex, then equality in (7.55) holds iff f(x) =
(7.59)
~ ( c ,x);
and equality in (7.57) holds if f(x)=a+(b-a)
X (
A+ Ix - AI)n
2(1-A)
,
where
A= b
+ na - (n + 1)c. b-a (7.60)
All of the results stated above may be regarded as converses of Jensen's inequality. Thus Popoviciu used Theorem 7.23 to obtain a bound for c'" - ¢(c",) where c'" = f6 ¢(f(x)) dx. More general results are given by Pecaric (1986b). For example, Pecaric proved 7.25. Theorem.
(a) Let ¢ and f be defined as in Theorem 7.23, and let
g : J2 ~ ~ be increasing in its first component, where J is an interval such
216
7. Related Inequalities
that ¢(x) E J for all x
E
[a, b]. Then b
g(cep, ¢(c» s:
max
xE[a.(a+b)/2]
b + a - 2x g( b ¢(a) a
-
2(x-a)f ) + (b )2 ¢(x) dx, ¢(x) . - a
a
(7.61) (b) Under the same conditions as in (a) except that g is decreasing in its first component, we have g(cep, ¢(c» ~
. nun
(b +b a - 2x ¢(a) + 2(x - a) f ) g (b )2 ¢(x) dx, ¢(x) . b
xE[a.(a+b)/2]
a
-
- a
a
(7.61') Proof.
(a) By (7.53) and the increasing property of g(', y), we have b
b + a - 2c 2(c-a)f ) g(cep,¢(c»s:g ( b-a ¢(a)+(b-af ¢(x)dx;¢(c) -
s:
max
xE[a.(a+b)/2]
g(
b
+a b
-
a
f
)
b
2x
a
2(x - a) ¢(a) + (b )2 - a
¢(x) dx; ¢(x) ,
a
since c E [a, (a + b)/2]. (b) Similar. D If g(x, y) =x - y in Theorem 7.25, then from (7.61) we obtain the noted Popoviciu's result. Also, if we let X(y) = y' and ¢(y) = yS for O
7.26. Theorem. Iff is a nonnegative concave function on [a, b], then for o< r < s we have b
[ ~ ~ ~f a
11
(f(x»S- . Ss:
b
[ ~ ~ ~f
11
(f(x», - . '.
(7.62)
a
7.27. Remark. For s;::: p ;::: 1 and r = 1, we obtain the inequality of Favard, which is a consequence of (7.45). D
7.2. Related Inequalities
217
Thunsdorff (1932) proved the following similar result: 7.28. Theorem. Iff is a nonnegative, convex function with f(a) ifO
= 0,
and
7.29. Remark. Theorems 7.26 and 7.28 provoked a strong interest among mathematicians, and thus there exist a number of results related to these inequalities. A new proof of Theorem 7.28 is given in Nishiura and Schnitzer (1971). The weighted version of Theorem 7.26 is given in Pecaric (1983c) (which also contains a related result for concave sequences). The weighted version of Theorem 7.28, i.e., the related generalization for k-convex functions, is given in Stankovic (1975, 1976). Analogues of Theorem 7.26 for convex sequences are proved in Rahmail (1978) and Vasic and Milovanovic (1977), and a generalization for k-convex sequences can be found in Milovanovic and Milovanovic (1983,1985). Although this problem has a long history, it is not well-known that the first result of this type was given by Gauss (1821). Let F: IR ~[0, 1] be a probability distribution function, a E IR, and let
f 00
v, = vr. a =
Ix - air dF(x) for
r ;:::: 0
(7.63)
denote the rth absolute moment of F about a. Let us consider the probability functions P(x)
= Pr(IX - al ;::::x),
Q(x) = 1- P(x)
= Pr(IX -
al <x).
If F is continuous, then we have
Q(x) = F(a +x) - F(a -x),
x ;::::0,
from which it follows that
f 00
v, =
x r dQ(x).
(7.64)
o
Note that Q(O) = 0, Q(x) = 1, and Q is increasing on [0,00). Inequalities involving the absolute moments have a long and rich history dating (at least) back to Laplace (1810) and Gauss (1821). For example, one classic result is (7.65)
218
7. Related Inequalities
If Q' is continuous and decreasing on (0,00), then we have the
Gauss-Winckler inequality (7.66) which is an improvement of (7.65). Winckler (1866) obtained (7.66) using an argument which was later found invalid, and the first correct proof is due to Faber (1922). A special case of (7.66) with n = 2 and r = 4 is (7.67) which was stated without proof by Gauss (1821, Art. 10); a proof of (7.67) can be found in Krafft (1937). For other proofs of (7.66), see Bernstein and Krafft (1914), and Fujiwara (1926). 0 We also note that Theorems 7.26 and 7.28, as well as the GaussWinckler Inequality, are related to a well-known result of Marshall, Olkin, and Proschan (1967) for the monotonicity of ratio of means, and their result was proved by using the theory of majorization. Note that this result was previously proved in Izumi, Kobayashi, and Takahashi (1934) and later given in Sunouchi (1938). A simple proof of their result with weights is given by Vasic and Milovanovic (1977), and it can also be proved using a generalization of a majorization theorem (Pecaric, 1984b). Moreover, by using an idea in Vasic and Milovanovic's paper a more general result can be obtained:
7.30. Theorem. For k = 1, ... ,r let Uk: [ak> b k]- ~ be increasing du;(x;), A = {x = (Xl' ... ,Xr ) :ak $,Xk $, bi; 1 $, functions, du(x) = k $, r}, and let f, g : X - ~ be positive real-valued functions. Then for rEI (I is an interval in IR) there exists a function F(r) defined by
m=l
F(r)
= (f
r
(f(x)Ydu(x)/
A
F(O) = exp(
f (g(x)YdU(X)f
for
r *0,
A
f 10g(f(x)1g(x)) du(x)/ f dU(X)). A
A
Furthermore, when g and fig are similarly ordered on A, then F(r) is increasing on ~ ; when g and fig are oppositely ordered on A, then F(r) is decreasing on ~ .
7.2. Related Inequalities
219
Proof. The proof given here depends on Cebysev's inequality and the well-known theorem concerning the power means H(r) defined for positive functions h given by (f p(x)(h(x))' du(x)/ f p(x) dU(X))lIr H(r)
=
A
{
for
,,#0,
for
r=O.
A
exp(f p(x)log h(x) du(x)/ f p(x) dU(x)) A
A
The function H is increasing and continuous on ~ (we assume that I = ~ ) . Now for convenience we rewrite Cebysev's inequality in the form (f p(x) du(x)) (f p(x)F(x)G(x) dU(X)) A
A
s;
(f p(x)F(x) du(x) )(f p(x)G(x) du(x)) , A
(7.68)
A
provided that F, G are oppositely ordered on A, with the inequality reversed if F, G are similarly ordered. For s s; r (s 0, r 0), take p(x) = (f(x))" F(x) = (g(x)lf(x))" and G(x) = (g(x))s-r in (7.68) to obtain
*" *"
(f (f(x))' du(x))(f (g(x))S dU(X)) A
A
2:
(f (g(x))' du(x))(f (f(x)Y(g(x))s-rdU(X)), A
(7.69)
A
«:
provided that (g If)" are similarly ordered, or the inequality in are oppositely ordered. If (7.69) reversed, say (7.69'), when (gln r , r > 0, it follows from (7.69) that
«:
{f (f(x)Y(g(x)y-rdu(x)/ f (g(x)Ydu(x)}lIr A
A
-s
{f (f(x))' du(x)/ A
f (g(x))' dU(X)}lIr
for
s s; r
(7.70)
A
holds when g and fig are similarly ordered. Similarly, if r < 0, then (7.70) follows from (7.69') when fig and II g are oppositely ordered, i.e.,
220
7. Related Inequalities
when g and we have
f /g are similarly ordered. By the increasing property of
H,
(f p(x)(h(x»S du(x)/ f p(x) du(x)fS A
A
::; (f p(x)(h(x»' du(x) / f p(x) du(x)f ' A
for s::; r (s, r:#: 0).
A
(7.71)
In (7.71) we then let p = gS and h = fg- 1 to obtain
{f (f(x»S du(x)/ f (g(x»S du(x)} A
lis
A
::; {f (f(x)Y(g(x)Y-' du(x)/ f (g(x)Y du(x» A
A
r'
for
s s: r.
(7.72) By (7.70) and (7.72) we have F(s)::; F(r) for s s; r (s, r:#: 0) whenever g and f /g are similarly ordered. Suppose now that s = 0 < r so that by the power mean inequality exp(f p(x)log hex) du(x)/ A
f
p(x) du(x»)
A
::; (f p(x)(h(x»' du(x)/ f p(x) dU(x)f' A
holds. By letting p == 1 and h exp(f log(f(x)/g(x» du(x)/ A
(7.73)
A
= f /g in (7.73) we obtain
f
dU(X»)
A
-s
(f (f(x)Y(g(x»-' du(x)/ f du(x)f'· A
A
When g and f /g are similarly ordered, so are f".g r and gr. Hence by Cebysev's inequality with m = 2 we have -r
f (f(x)Y(g(x»-' du(x) J(g(x»' du(x)::; Jdu(x) J(f(x»' du(x). A
A
A
A
(7.74)
7.2. Related Inequalities
221
Combining with the preceding inequality yields F(O) ~ F(r). Now, in the case r < 0, the inequality in (7.73) is reversed (and this reverse inequality is denoted by (7.73'», and again we take p = 1, h = fig. When g andf Ig are similarly ordered, so also are gr andj'g-r, thus (7.74) still holds, and, from r
7.32. Theorem.
if the function f(Q(x»Ix is decreasing, then the reverse inequality in (7.75) is valid.
Proof. Since x andf(Q(x»lx are similarly ordered, by Theoem 7.30 the function a
F(r)
a
U
= (!f(Q(x»'dQ(x)/!xrdQ(X») o
is increasing. Thus holds. D
r
for
r>O
0
for
n ~ r
we have
F(r):2=F(n),
and
(7.75)
222
7. Related Inequalities
7.33. Examples. (a) For f(t) == 1, we have (7.65). (b) For f(t) == t, i.e., in the case when Q(t)/t is increasing, we have (7.66). If Q is a starshaped function, i.e., if Q(t)/t is decreasing, we have the reverse of the inequality in (7.66). (c) If f(t) = t llk (k > 0), i.e., if Q(x)/xk is decreasing, then
(r+k k v, )lIr - (n +k k ) lin <:
Vn
for
n::::;r;
(7.76)
if Q(x)/xk is increasing, then the reverse of the inequality in (7.76) 0 holds. We note that for the rth absolute moment given in (7.63) (or (7.64)), it is known that the function fer) = log v, is convex (see Theorem 13.8 and (14.13)). Furthermore, in the case when Q' is continuous and decreasing on (0,00), the function j.fr) = log((r + l)vr ) is also convex. Beesack (1984) implicitly proved the following generalization of these results: 7.34. Theorem. If Q is a probability distribution function with Q(x) = 0 for x::::; 0, Q(O) = 0, Q(oo) = 1, and if (_I)k-lQ(k) is positive, continuous, and decreasing on (0, 00) for k = 1, 2, ... , N, then
is a convex function of r for k = 1, ... , N. In the following we give some corollaries which follow from this result and some known results concerning convex functions (see Mitrinovic and Pecaric, 1986): 7.35. Corollary. (7.78)
7.36. Remark. Corollary 7.35 is the corrected version of a result Beesack (1984). o
In
7.2. Related Inequalities
7.37. Corollary.
223
For m:5 n z; r we have (7.79)
7.38. Remark. Corollary 7.37 is a generalization of the well-known Lyapunov Inequality. 0
7.39. Corollary.
7.40. Remark. (1927). 0
For m :5 nand r :5 s we have
Corollary 7.39 is a generalization of Izumi's inequality
Similarly, we can give a generalization of Narumi's inequality (1927), i.e., for I defined in (7.77) wehave
q-t t-p s-t t-r --A(p)+--A(q) 2::.-lk(r) +-lk(S) q-p q-p s-r s-r for
p
< r < s < q,
p:5 t s; q.
We also note that in their papers Favard (1933) and Berwald (1947) considered similar inequalities with several positive concave functions. Results of this type are extensively treated in the mathematical literature. In this connection we consider the following expression b
H(fl' ...
b
.t.: g) = [(f g(x) Jljj(X) dX)/
(f g(x) dX)]/
a
a
II (f b
a
b
g(X)jj(XYidx/
f
g(x) dx
f
Pi ,
a
where g, t., ... .I; are nonnegative integrable functions, and Pl , ... , P« positive real numbers. In the case g(x) == 1, we write Htf.; .L«: g) as H(ft, ,1m); and for Pi = ... = P« we write H(fl, .I«: g) as T(ft, ,In). In the literature H is well-known as Holder's ratio, and T as Cebysev's ratio.
224
7. Related Inequalities
7.41. Theorem. (a) Let j;:[a, b ] ~ 1 (Ri = 1, ... , n) concave functions. Then the following results are valid: (i) For Pi
~ 1 (i
= 1, ...
, n) we have
~(n ~ 1)! ( [ ~ } ) ( [ n 1; }) [II (Pk + 1)lI
Pk
H(fl' ... ,fn) (ii) For 0 < Pi
be nonnegative
~ 1 (i
= 1, ...
, n) we have 1
•
(7.81)
n
H(fl' ... , f n ) ~ -IT- (Pk+1)lIPk. n +1 k ~ l
(7.82)
(b) Let j ; : [ a , b ] ~ 1 be R nonnegative convex functions with j;(a)= o(i = 1, ... ,n). Then, for 0
7.42. Remarks. (a) Inequality (7.81) was proved by Godunova and Levin (1972), and it is an improvement and a generalization of results in Nehari(1968) (see also Bellman, 1956). Inequality (7.82) is proved in Pecaric (1983c) and Rahmail (1972a), and inequality (7.83) in Vasic and Pecaric (1980b). (7.81) and (7.82) are generalizations of results in Barnes (1969). The weighted version of (7.82) and (7.83) are given in Pecaric (1983c) and Vasic and Pecaric (1980b), where in the latter a related generalization for k-convex functions is also given. The weighted version of (7.81) for n = 2 is given in Pecaric (1983c). (b) For PI
= ... = Pn = 1,
(7.82) yields Favard's inequality (1933):
T(fl' .. '
2n , f n ) ~ - ,
n+1
(7.84)
when t.. .. . .I: are nonnegative concave functions, and (7.83) yields Anderson's inequality (1958) (see also Mitrinovic, 1970, p. 306):
T(fl' .. '
2n , f n ) ~ -
n
+1
(7.85)
when fl> ... .I; are nonnegative convex functions. The weighted version of (7.84) is given in Vasic and Pecaric (1981c, 1982a), and the weighted version of (7.85) in Vasic (1972). For a generalization of (7.85) (i.e., of a result in Vasic, 1972), see Stankovic (1974, 1976) (for the case of k -convex functions).
7.2. Related Inequalities
225
(c) For discrete versions of previous results (convex, concave, and k-convex sequences) and some similar results see Barnes (1970,1984), Pecaric (1982e, 1982f, 1983c, 1984b), Vasic and Djordjevic (1973), Vasic and Pecaric (1980b, 1981c, 1982a), Milovanovic and Milovanovic (1982a, 1982b, 1983, 1985), Rahmail (1978), Wang (1978a), Stankovic and Milovanovic (1980), Vasic, Stankovic, and Pecaric (1985a), Borell (1973b), and Beesack and Pecaric (1985b). 0 It should be noted that inequalities (7.82) and (7.83) and their weighted versions are simple consequences of the following result (Pecaric, 1982f and Beesack and Pecaric, 1985b):
Let g be a nonnegative integrable function on [a, b] and be integrable positive functions on [a, b] such that they are all similarly ordered. Furthermore, let O
t.. hi (i = 1, ... , n)
H(ft, ... ,f;. ; g)
2:.
Hilt«, ... , hn ; g).
(7.86)
If they are oppositely ordered, then the reverse ofthe inequality in (7.86) is valid. A discrete analogue of Theorem 7.43 is that 7.44. Theorem. Let p, aj, b j (j = 1, ... , m) be nonnegative n-tuples such that aj , bj (j = 1, ... , m) are all similarly ordered, bji > 0, and 0< qi :s 1 (i = 1, ... , n). If b, and a)bj (= (ajr/b jl, ... , ajn/b jn)) are also similarly ordered, then
H(aj, ... ,am; p)
2:.
H(br, ... ,bm ; p),
where
If b, and aJbj are oppositely ordered, then the reverse of the inequality holds. 7.45. Remark. For the special case in which hl(x) = ... = hn(x) == 1 and b i = ... = b., = (1, ... ,1), both Theorems 7.43 and 7.44 yield Cebysev's inequality. In fact, Godunova and Levin (1972) proved (7.81)
226
7. Related Inequalities
as a special case of a more general result obtained by using the Bellman (1956) method. An additional generalization of his result is given in Mitrinovic and Pecaric (1987b). 0 Next we consider the nonnegative kernel K(x, y) (a::; x::; b, a::; y ::; b) such that, for some P (given as Pi in Theorem 7.46), we have
f b
0<
K(x, yfdx <00.
a
We shall say that the function u belongs to the class U(K) if it admits the presentation
f b
u(x) =
K(x, t)v(t) dt,
a
where v is an integrable nonnegative function (v(t) *- 0).
7.46. Theorem.
Let Ui(X) E U(Ki), i nonnegative integrable function. Let
= 1, ... ,n,
and g: [a,
b ] ~IR
be a
b
f g(X>C~l
ui(x») dx
T(Ul(X), ... , un(x);g(x»=
a
b
.
i ~ l (f g(x )Ufi(X) dX)
lip;
a
(a) If Pi 2= 1 (i
= 1, ... , n),
then
T(Ul(X), ... , un(x); g(x»
2=
C(K),
(7.87)
where C(K) = inf T(K1(x, Yl), ... , Kn(x, Yn); g(x».
(7.88)
Yi
(b) If Pi::; 1 (o#oO)(i (7.88) holds, where
= 1, ... ,n), then the reverse of the equality in
C(K) = sup T(K1(x, Yl), ... , Kn(x, Yn); g(x». Yi
Furthermore, the constants (7.88) and (7.89) are the best possible.
(7.89)
7.2. Related Inequalities
Let P; > 1 (i
Proof.
227
= 1, ... ,n). Then
b
b
b
1 Y;)V;(Y;»)dY1 ... dy; dx Jg(x > C ~ u;(x») 1 dx J ... J g(x > C ~ K;(x, a
a
a
b
b
b
;91 (J g(X)(U;(X)Y'idX) ;9 (J g(x)(u;(x)Y'i- J K;(x, y;)v;(y;) dy, dx) 1
1
a
a
a
It! 12 2= C(K)13/14
=
(n (J
b
= C(K)/
Pi, g(X)(Ui(X)Y'idX) l-lI
a
where b
11 =
b
J .. -J T(K
1(x,
a
01 (J n
X
lIPi
b
Vi(Yi»)dYI, ... , dYn,
nJ
b
J
(Vi(Yi) g(x)Ki(x, Yi)(U;(X)Y'i-1 dx) dy.,
a
b
13 =
) ( K ; ~ Y;) , Y'i dX)
g(x
a
b
12 =
Yl), ... , Kn(x, Yn);g(X»
a
b
(n
a b
11
J ... J (J g(x)(K;(x, Y;)Y'idX) PiVi(Yi)dYI... dYn, a
a
a
and n 14=]1
Jb Vi(Y;)(Jb g(X)(K;(X,y;)Y'idx)lIPi(Jbg(X)(U;(x)Y'idx)(pi-1)/pi dy., a
a
a
Therefore (7.87) is valid. For Pi < 1 (i = 1, ... , n), the reverse of the inequalities is valid (with C(K) given in (7.89». A similar proof applies 0 for Pi = 1 or by letting Pi - 1 in the above proof. 7.47. Remarks. (a) Inequality (7.87) for p(x) == 1 is proved in Godunova and Levin (1972). (b) Let o for a:Sx:Sy K 1=K(x,y)= {1 for
y
<x :sb.
228
7. Related Inequalities
Then x
U(X) =
Jv(y) dy
E
U(K1),
o
where U(K 1 ) is the class of nonnegative increasing functions with u(O) = O. The last condition can be easily eliminated, and in this case Godunova and Levin (1972) obtained the Cebysev inequality for n nonnegative increasing functions. Note that we can obtain the weighted version of this result from Theorem 7.46 by a similar argument. When the two functions are monotonic in opposite directions, the reverse inequality can also be so obtained. (c) Theorem 7.46 can also be applied to obtain other important results. For example, some results in Barnes (1969) are simple consequences of Theorem 7.46. (d) Some related results are given in Atanackovic (1981) and Barnes (1982, 1984). 0
Chapter 8
8.1.
Hardy's, Hilbert's, Opial's, Young's, Nanson's, and Related Inequalities
Hardy's, Hilbert's, Opial's, and Related Inequalities
In this section we give some useful inequalities for convex functions which imply well-known results as special cases. First, we observe the following theorem due to Boas (1970b):
8.1. Theorem. Let ep be a continuous convex function. Let f be measurable and nonnegative, A be increasing and bounded, and L = A(oo) - A(O). Then
f 00
f 00
x- 1ep{ L -1
o
f 00
~
f(ux) dA(u)} dx
0
x- 1ep(f(x» dx,
(8.1)
0
If ep is a continuous concave function, then the reverse of the inequality in (8.1) holds. Proof.
If
ep is convex,
then by Jensen's inequality we have
00
ep{ L -1
00
Jf(ux) dA(U)} ~ L Jep(f(ux» dA(u), -1
o
0
229
230
8. Special Related Inequalities
i.e., we have 00
00
JX-I{ L Jf(ux) dA(U)}dx
~ L -1 JJx-
-1
o
0
0
= L -1
dA(U)dx
1(f(ux»
dx dA(U)
0
JJxo
=L- 1
1(f(ux»
0
JJto
1(f(t»dtdA(U)
(t=ux)
0
00
=
Jt-
1(f(t»
dt.
0
o
8.2. Remark. A special case of Theorem 8.1 is the well-known Hardy Inequality. Indeed, let (x) =x P , a> 0, f3 > 0, and a - 1U '" for A1(U) = { 1 afor
O ~ u ~ l , /1, 2':
(thus L 1 = a-I),
1,
o
O ~ U~ 1,
for for
Az
U2':1.
Then (8.1) becomes x
00
J xor
1-cxp(J
o
00
~ «» J x-1(f(x))P dx,
t"'-lf(t) dtf dx
0
00
J
00
(Jt-fl-y(t) dtf dx
x- 1+ flP
o
(8.2)
0 00
~
Jx-
f3-P
x
1(f(x))P
dx
(8.3)
0
for either p > 1 or p < O. If 0 < P < 1, then the reverse of the inequalities in (8.2) and (8.3) is valid. If we let f(t) = t 1-"'g(t) and a = (k - l)/p in (8.2) andf(t) = t 1 + flg(t) and f3 = (1- k)/p in (8.3), we have x
00
Jx-k(J g(t) dtf dx o
1fJ 00
~ (k ~
0
xp-k(g(x))p dx
(8.4)
xp-k(g(x))p dx
(8.5)
0
when either k> 1, P > 1 or k < 1, P < 0; and 00
00
Jx-k(f g(t) dtr dx ~ (1 o
x
oc
~ kr f 0
8.1. Hardy's, Hilbert's, Opial's and Related Inequalities
231
when either k
f
x
00
f 00
X-k(fget) dty dx >:
(1
~ kY
xp-k(g(x))P dx.
0 0 0
(8.6)
o
Godunova (1965) (see, for example, Bullen, Mitrinovic, and Vasic, 1987, pp. 271-73) proved a result by using a similar method:
8.3. Theorem. Let F: ~+ ~ ~ be continuous and strictly increasing with limx->o+ F(x) = 0 or -00, and F- 1 be convex. Let {ad and {bk} be two positive real sequences such that for every n e: 1, w(n) = { W r ) } k ~ isl a positive n-tuple satisfying n
2:
w ~ n )= 1
and
k=l
2:
w ~ n ) b n :C 5
for
k e: 1.
n=k
If F',. is a quasi-arithmetic mean (for definition, see Bullen, Mitrinovic, and Vasic, 1987, p. 215), then 00
2:
n=l
00
bnF',.({ad,w(n»):5C
2: an;
(8.7)
n ~ l
if in addition 1 n C = lim bk> n-+ oo n k=l
2:
then the constant in (8.7) is the best possible.
8.4. Remark. For F(x) = !ogx, w ~ n =) s.ln, and b; = 1/(k + 1), we have 1
2: - n=l n + 1 00
Since e- 1 < (n!)lInl(n
(
n
n!
IT ak k=l
) lin
<
2: an' n=l 00
+ 1), this implies Carleman's inequality 00
2:
k=l
00
Gk({ak})<e
2: ak>
k=l
where G; ( {ak}) = Va 1 • • • an' Of course, many other examples can be found in Godunova (1965) and Bullen, Mitrinovic, and Vasic (1987, pp. 272-73). Godunova also gave many integral analogues of the results. 0
232
8. Special Related Inequalities
In her proof Godunova used the well-known inequality for quasiarithmetic means. Since this result is a simple consequence of Jensen's inequality, by using Jensen's inequality we can have more general results. This fact is noted in Vasic and Pecaric (1982c), where the following results are given: 8.5. Theorem. Let f: 1-->; ~ be a convex function, Xi E I (i = 1, 2, ... ), {cd be a positive sequence, and for every n ~ 1 let qn = ( q ~ , ... , q ~ ) be a positive n-tuple such that ~ 1 : ~ 1ql: = 1 (n ~ 1). If ~ cnql:::=; d k
for
k ~ 1,
(8.8)
n ~ k
then (8.9)
If f is a concave function and the reverse of the inequality in (8.8) holds, then the reverse of the inequality in (8.9) holds.
Proof.
By Jensen's inequality we have
Thus
co
cc
= ~ f(xd ~ cnql:::=; k ~ l
n ~ k
~
~ dd(xd·
0
k=l
8.6. Theorem. If in Theorem 8.5 we replace I by a convex set U in ~ m and the points Xi (i = 1, 2, ... ) by points in U, then the conclusion remains valid.
Proof.
The proof is similar to the one-dimensional case.
0
,
8.1. Hardy's, Hilbert's, Opial's and Related Inequalities
Let us consider the two quasi-arithmetic means (see Mitrinovic, and Vasic, 1987, pp. 215-82) given by Kn({ak}, p)
=
233
Bullen,
K - l ( ~ n ~ 1PkK(ak)),
Ln({bd, p) = L
- l ( ~ n ~ lPkL(bk)),
Then the following result holds:
8.7. Coronary. Let f : [k 1 , k 2 ] x [ e1 , e2] ~ ~+ be a real-valued function, {ad, {bd, and {cd be positive sequences, and assume that, for every l = 1. n 2: 1, qn = ( q ~ , ... , q ~ ) is a positive n-tuple such that ~ Z = qZ (a) If H(s, t) then
=
f(K-1(s), L -l(t)) is a convex function and (8.8) holds,
00
00
2: cnf(Kn({ak}, qn), Ln({bd, qn)) L dnf(a n, b n). $
n ~ l
(8.10)
n ~ l
(b) If H(s, t) is concave and the reverse of the inequality in (8.8) holds, then the inequality in (8.10) is reversed. Proof. This follows from Theorem 8.6 by letting m = 2, f(s, t) = H(s, t), s, = K(aJ, and t, = L(bJ for i = 1, 2, . . . . 0 8.8. Remark. In the previous result we assume that all sums are finite. Of course, we can use other generalizations of Jensen's inequality (e.g., a generalization of Theorem 8.1) and related inequalities to obtain similar results. For example, in Vasic and Pecaric (1982c) the Jensen-Petrovic Inequality is used, and Imoru (1977) contains a generalized Hardy's 0 inequality.
Similarly, Godunova (1967b) proved the following result:
8.9. Theorem. Let K(t) 2: 0 be defined on ~ = {t = (tl , ... , tn): 0 < t, < 00, i = 1, ... , n} with f v, K(t) d ~= 1, and let V" and Vy be defined similarly. Let (u) be a nonnegative convex function for u 2: 0 and f be such that f(y) 2: 0 for y E Vy , f $ 0, and (f(x))/(x) ... x n) is integrable
234
on
8. Special Related Inequalities
v,..
Then
By using this result Godunova obtained many general inequalities, which include (i) Hardy's and Knopp's inequalities (Hardy, Littlewood, and P6lya, 1934, 1952, p. 250): x
00
00
J e x p ( J~ logf(t) dt) dx < e Jf(x) dx, o
0
0
which follows from Theorem 8.9 by letting n = 1, (jJ(u) = e" and K(t) = {01
for for
0 ~ t ~ 1, t> 1;
(ii) Hilbert's inequality:
by letting n = 1, (jJ(u) = u", and K(t) = [sin(.n/p)/.n][r and (iii) Hardy-Littlewood-P6Iya inequality:
1(1 m ~ ~ ~ ~
y} dy
f
dx <
(p ~If
1
(f(x)Ydx
llP
for
/ (l
+ t)];
p> 1,
0 0 0
by letting n
= 1,
(jJ(u)
= u", and K(t) = (p
-1)/(p2t llp max{l, t}).
In the following we give some results from Mitrinovic and Pecaric (1988c). We say that a function u : [a, b ] ~ ~ belongs to the class U( v, K) if it admits the representation
f b
u(x) =
K(x, t)v(t) dt,
(8.12)
8.1. Hardy's, Hilbert's, Opial's and Related Ineqnalities
235
where v is a continuous function and K is an arbitrary nonnegative kernel such that v(x) > 0 implies u(x) > 0 for every x E [a, b]. We also assume that all integrals under consideration exist and are finite. First we prove the following theorem.: 8.10. Theorem. Let u, E U(v" K) (i = 1, 2), where vz(t) > 0 for every t E [a, b], r(t) ~0 for every t E [a, b], and ¢(u) is convex and increasing for u ~ O. Then
(8.13) holds, where b
() J r(t)K(t, x) d s (x ) - Vz x ( t. Uz
a
Proof.
(8.14)
t)
Using Jensen's inequality for the convex function ¢ we have
b Ja r(x)¢
(I
1 Jb , v 1(t) uz(x) K(x, t)vz(t) vz(t) dt
I)
a b
b
::; J r(x)¢(J K(x, t)vz(t) Iv 1(t) I dt) dx Uz(x) vz(t) a
a
b
b
= f ¢(jV1(t) !)vz(t)(f r(x)K(x, t) dX) dt vz(t) Uz(x) a
a
b
=fS(t)¢(I~:~:~I)dt.
0
a
8.11. Remark. If for a> 0 we let K(x, t)
= { ~ X- t)a-l/f(a)
for for
t ::; x
t >x,
(8.15)
then v is the derivative of order a of u in the sense of RiemannLiouville, and from Theorem 8.1 we obtain Theorem 8.3 from Godunova and Levin (1969) (see also Rozanova, 1976a). 0
236
8. Special Related Inequalities
Note that Theorem 8.1 can be generalized for convex functions of several variables. For example, the following result is valid:
8.12. Theorem. Let u, E U(vi , K) (i = 1, 2, 3), where vz(x) >0 and r(x) 2: 0 for every x E [a, b], and 4>(u, v) is convex and increasing for u, v 2: O. Then b
b
J r ( x ) 4 > ( I ~ : i ; ~ I ,1 ~ : i ; ~ I ) d XJ~ S ( X ) 4 > ( I ~ : i ; ~ I 1, ~ : i ; ~ I ) d X ' (8.16)
a
a
where s(x) is given in (8.14).
Let U1(v, K) denote the class of all functions u E U(v, k) such that K(x, t) = 0 for t > x. Note that if U E U1(x, K), then we have b
u(x) =
JK(x, t)v(t) dt.
(8.12')
a
Let u, E U1(Vi , K), vz(x) > 0, and r(x) 2: 0 for every x E [a, b]. Further, let 4>(u) and f(u) be convex and increasing for u 2: 0 and f(O) = O. Iffis a differentiable function and max K(x, t) = M, then
8.13. Theorem.
b
M
.
J vz(x)4>(I ~ : ~ !~ )f'(u z(X)4>(I~ : i ; ~I)) dx
a
b
~ f ( MJ v z ( t ) 4 > ( I ~ : i : ~ I ) d t .(8.17) a
Proof. Since f' is an increasing function, by using (8.12') for the function Ul and the well-known inequality for the absolute value of a function, we have
b
~M
x
)4>( Ivz(x) v1(x) 1)f'(uz(X)4>(J K(x, t)vz(t) Iv1(t) I dt)) dx. uz(x) vz(t)
J vz(x a
a
8.1. Hardy's, Hilbert's, Opial's and Related Inequalities
237
Now using Jensen's inequality for the convex function ep and the condition K(x, t) :s: M, we have x
b
V z C X ) e p ( I ~ ~ i ; ~ l ) fK(x, ' ( f t ) V z C t ) e p ( I ~ : i dt) : ~ 1 )dx
I:s:M f a
a x
b
:s: f
M V 2 ( X ) e p ( I ~ ~ i ; ~ I ) fM' V( fz C t ) e p ( I ~ : ~ : dt) ~ I ) dx
a
a b
= f(M f V2(t)ep( I
~ : ~ : ~1) dt.
0
a
8.14. Remark. Note that for Riemann-Liouville's derivative we have For a=l, we have M=l, and we obtain Theorem 1 in Rozanova (1972a). Therefore, Theorem 8.13 is a further generalization of Theorem 2 in Godunova and Levin (1967). 0 M=(b-a)a-1jr(a).
In the following we give another generalization of Theorem 2 in Godunova and Levin (1967). 8.15. Theorem. Let ep: [0, (0) ~ ~ be a differentiable function such that for q> 1 the function ep(x1/q ) is convex and ep(O) = O. Let u E U1(v, K) where ( f ~(K(x, t)Y' dt) lIP :S: M, P -1 + = 1. Then
«'
b
b
f lu(x)1
1- qep'(!u(x)l)
Iv(xW dx:s:
1/
~ q
(8.18)
a
a
If the function
Proof.
Using Holder's inequality we have x
lu(x)l:S: f K(x, t) Iv(t)1 dt s; a
x
1/X
(f (K(x, t)Y' dt) (f Iv(tW dt) P
a
a
1/
q
238
8. Special Related Inequalities
To prove (8.18), let z(x) = f ~ Iv(tW dt, so that z'(x) = Iv(xW and lu(x)l:5 M(Z(X»l/q. Further, from the convexity of fj>(x llq) it follows that the function x llqfj>'(x) is increasing. Thus, we have b
q f lu(x)11- fj>'(lu(x)l) Iv(xWdx a b
:5 f M 1-q(z(X»lIq-lfj>'(M(z(X»lIq)Z'(X) dx a b
q) q) = :q f fj>'(M(Z(X»lI d(M(z(x»lI a
o a
8.16. Remark. Similar results can be given for the class of functions U2(v, K) in which K(x, t) = 0 for t <x. If u E U2(v, K), then we have b
u(x) = f K(x, t)v(t) dt.
(8.12")
o
x
8.17. Corollary. Let fj>, q, and p be defined as in Theorem 8.15. If uCn-1)EAc[a,b) and either uCk)(a)=O for k=0,1, ... ,n-1 or uCk)(b) = 0 for k = 0, 1, ... , n - 1, then b
f lu(x)1
b 1-qfj>'(lu(x)1)
11
luCn)(xWdX:5 :q fj>( M(f luCn)(tW dt) ' )
a
a
where M = (b - at- lIq/«n -I)! (np - p + l)lI p ) . For some related results, see Rozanova (1972a, 1976a, 1976b). The following theorem is due to Rozanova (1972b). 8.18. Theorem. Let y(x) be an absolutely continuous function on [0, a), y(O) = 0; r(x) be increasing, and r(O) = O. Let fj>(w) and F(w) be convex
8.2. Young's Inequality
239
and increasing functions for w > 0, F(O) = 0, Q(w) be a convex and increasing function, and 'ljJ(w) be an increasing function with 'ljJ(0) = 0. If F'(z(x»z'(x )'ljJ(11 z '(x)') ~(F(z(a »1z(a »'ljJ' (x 1z(a»,
(8.19)
where z(x) = H r'(t)¢(Iy'(t)llr'(t» dt, then
f a
F'(r(x)¢ )(1 y(x)llr(x»G(r' (x )¢(I y' (x )llr'(x» dx
o a
~ H ( r'(x)¢(ly'(x)llr'(x» J dX),
(8.20)
o
where G(w) = wQ('ljJ(l/w», H(w) = F(w)Q('ljJ(alw». Further, the equality in (8.20) holds iff y(x) =Ax, rex) = Bx, and 'ljJ(w) = CF(aw), where A, B, C and a are constants.
If in (8.20) we let y(x) = f(x), f'(x) > 0, f(O) = 0, ¢(w) = w, F(w) = 1P(w) = w 2, and Q(w) = VI + w, we obtain the following result (see Rozanova, 1972b): Let a and b be given positive real numbers, and let f be a real-valued function such that f(O) = 0, f(a) = b, f(x) ?::. 0, and f(x )/1' (x) ~x on the interval [0, a]. Then
8.19. Remark.
f(a)
= b,
f a
2
f(x)(l + (f'(X»2)112 dx
~b(a 2 + b 2)1I2,
(8.21)
o
and equality holds iff f(x) = (bla)x. Inequality (8.21) is given in P61ya (1947) with a stronger condition that f"(x)?::.O instead o f f ( x ) / f ' ( x ) ~ x . 0 Rozanova (1972b) also gave some other examples which give generalizations of Opial's inequality.
8.2.
Young's Inequality
The following result is known as Young's inequality: 8.20. Theorem. Let f be a real-valued, continuous, and strictly increasing function on an interval 1= [0, c] (c > 0) such that f(O) = 0, and let
240
8. Special Related Inequalities
a
b
ab::::; ff(X)dX+ f g(y)dy forall o
a,b::::;c,
(8.22)
0
= f(a).
and equality holds iff b
This inequality was proved by Young (1912) with the additional condition that f be differentiable, and another proof is given in McShane (1947, pp. 131-32). Proofs of Theorem 8.20 under the present conditions are given in Diaz and Metcalf (1970), Bullen (1970b), and Nieto (1974). For a geometric interpretation of the result in Theorem 8.20, consider Figures 8.1 and 8.2 given below. The area of the curvilinear triangle OAP is given by SU(x) dx, and the area of the curvilinear triangle ORB is given by S ~g(x) dx. Thus the inequality in (8.22) is justified. On the other hand, Young's inequality is related to an integral representation of convex functions (see Theorem 1.2(a)). Namely, let f: [0, 00) - [0, 00) be a continuous and increasing function such that f(O)=O and f(x)_oo as x_ oo. Then exists and has the same properties as f. Further, if we let
r:
f
f
o
o
y
x
F(x)
= f(s) ds and F*(y) =
f-1(t) dt,
y
B(O,b)
x A(a,O)
C(X,O)
Figure 8.1.
8.2. Young’s Inequality
241
Y
A
Figure 8.2.
then F and F* are both convex functions on [ o , ~ ) Thus . the following results are valid (Roberts and Varberg, 1973, pp. 29-30):
+ +
(i) xy 5 F ( x ) F * ( y ) for all x 2 0 and y 2 0 (Young’s inequality), (ii) xy = F ( x ) F * ( y ) iffy = f ( x ) = F ’ ( x ) , (iii) (F*)’ = (F’)-’, (iv) (F*)* = F, and ( 9 F * ( Y ) = SUPX20 ( X Y -f(x>). Note that property (v) is used for defining a conjugate function: If f :I+ R is a convex function defined on an interval I, then f * :I*+ R denotes the conjugate function given by f * ( y ) = supxEI(xy - f ( x ) ) with domain I*= { y E (w :f*(y) < m}. Some properties of conjugate functions are given in Roberts and Varberg (1973, pp. 28-36). In a similar fashion we can define a conjugate function corresponding to a convex function f of several variables (see PSeniEnyi, 1980, p. 64):
f*(Y)=sup ((x, Y> -f(x)). This function is also convex with the property f ( x ) = ( f * ) * ( x ) . In this case Young’s inequality is also valid, i.e., we have
f(x) +f*(Y)
2
(x, Y>.
A function f is called an N-function (Krasnosel’skii and Ruticii, 1958 and 1961) if it admits to the representation M ( u ) = J g ’ p ( t )dt where the
242
8. Special Related Inequalities
function p is continuous from the right for t ~ 0, increasing, positive for t > 0, and such that p(O) = 0, limHoop(t) = 00. The class of such p functions will be denoted by '!fl. Let p E '!fl. For a function q defined by q(s) = supp(t)"Ss t for s ~ 0, we say that it is the right-inverse function of p. It can be easily verified that q has the same properties as p. We now introduce a concept of complementary N-functions: Let M be an N-function and p E '!fl be its right-derivative. Then the N-function v, N(v) of the form N(v) = fb q(s) ds, where q is the right-inverse function of p, is called the complementary N-function to function M. M and N are mutually complementary N-functions. For these functions Young's inequality is also valid, i.e., the following results are valid (Krasnoselskii and Rutickii, 1958 and 1961): (i) If M and N are mutually complementary N-functions, then for every u, v E ~ Young's inequality is valid, i.e.,
uv ::s;M(u) + N(v).
(8.23)
(ii) Equality in (8.23) holds iff either
v=p(u)
or
u=q(v)
for
(8.24)
u , v ~ O .
Consequently we have
up(u)
= M(u) + N(p(u»
and
vq(v) = M(q(v» + N(v) for
u, v
~ O.
(8.25)
(iii) If for a given N-function M the inequality in (8.23) holds for all u, v ~0, then the function N is the complementary N-function of the function M. Now let f be an increasing function on an interval I, let (1' = inf{f(x):x E I}, 13 = sup{f(x):x E I}, and let J = «(1', 13) (or [(1', 13), «(1', 13], or [(1', 13] if the values of (1', 13 are attainable). A function g with domain J is called a pseudo-inverse of f if for each Y E J we have
XL(Y)== sup{x :f(x) < y} ::s; g(y) ::s; inf{x:f(x) > y} == XR(Y)' Cunningham and Grossman (1971) proved an extension of Young's inequality for the case a > O. For general a the following result holds: Let f be an increasing function on an interval I containing the points x = and x = a (where a> 0 or a < 0). Let g be a pseudo-inverse of f with domain J. If f(O) = 0 and b e J, then (8.22) holds, and equality holds iff f(a_)::s; b ::S;f(a+).
°
8.2. Young's Inequality
243
Boas and Marcus (1974b) proved the following theorem, which is equivalent to the above result: 8.21. Theorem. If f is an increasing function on an interval I containing the points x = c and x = d, and g is a pseudo-inverse off, then d
f ~ )
cf(c) + ff(x)dx-=:=dt+
f g(y)dy,
e
(8.26)
t
d
t
df(d)+ f g(y)dy-=:=ct+ f f(x)dx fed)
(8.27)
e
for all t in the domain of g. Furthermore, equality in (8.26) holds iff t is between f(d-) and f(d+), and equality in (8.27) holds iff t is between f(c-) and f(c+). If f is decreasing instead of increasing, then the inequalities in (8.26) and (8.27) are reversed. In that case the conditions for the equalities to hold remain unchanged. Proof. Suppose f is increasing. Let f(c) = A, and define F by F(x) == f(x + c) - A. Then F is increasing in I} = {x:x + c E I} with F(O) = O. Furthermore, letting I denote the domain of g, the function G defined by G(y) = g(y + A) - c for y E I} = {y :y + A E I} is seen to be a pseudo-inverse of F. Thus, for arbitrary d E I and t E I we have (d - c) E I} and (t - A) E I}. By the result of Cunningham and Grossman (1971), it follows that d-e
t-A
(d - c)(t - A)::; f
F(x) dx + f
o
o
G(y) dy,
which implies d
dt - cA::; f f(x) dx e
t
+ f g(y) dy. A
Since A = f(c), this is equivalent to (8.26). Moreover, the equality holds iff F«d-c)_)::;t-A::;F«d-c)+) holds; that is, iff f(L)::;t::;f(d+) holds. The inequality in (8.27) is equivalent to that in (8.26), because interchanging c and d in (8.26) yields (8.27), and vice versa. Finally, the proof for the case in which f is decreasing follows in the same fashion by
244
8. Special Related Inequalities
a similar application of a result of Cunningham and Grossman 0 (1971).
8.22. Remark. A result which is analogous to Theorem 8.21 can be 0 found in Milicevic (1975). Merkle (1974) noted that the following converse of Young's inequality is valid: 8.23. Theorem. Let f be a continuous and strictly increasing function on an interval I which contains x = 0 such that f(O) = 0, and let g = f-l. Then b
a
Jf(x) dx + J g(y) dy s: max{af(a), bf(b)} o
holds for every a
(8.28)
0
E
I and b Ef(I).
8.24. Remark. Similar results can be obtained for other forms of Young's inequality. For example, from (8.25) we obtain M(u) + N(v):5 up(u)
for
p(u)
~v
and M(u) + N(v):5 vq(v) for
Thus for every u, v
~0
p(u):5 v
i.e.,
u
z;
q(v).
we have
M(u) + N(v):5 max{up(u), vq(v)}.
o
The following result is given in Beesack, Mitrinovic, and Vasic (1980): 8.25. Theorem. Let f be continuous and strictly increasing on an interval I containing x = 0 such that f(O) = O. Let g be a continuous function with domain J = f(I) such that (8.22) holds for a E I and b E J, where equality l • holds for b = f(a). Then g =
r
Proof.
For an arbitrary but fixed a
f
E
a
ep(b) =
o
I let
f b
f(x)dx+
0
g(y)dy-ab.
8.2. Young's Inequality
245
Then <jJ(f(a» =0, f(b)?O for all bEl, and <jJ'(b)=g(b)-a exists for all s «: It follows that <jJ'(f(a» =0; thus g(f(a))=a for all aEI. Suppose that g(b) =1= f-\b) for some b e J. Let a = f-\b) so that b = f(a); then a = g(f(a» = g(b) =1= f-l(f(a» = a, a contradiction. Hence g(b)=f-l(b) for all s «: D 8.26. Corollary. Let f satisfy the conditions of Theorem 8.23, and g be a continuous function with domain 1 = f (I) such that g( y) ~f - \y) for all y E I. If (8.22) holds, then g = f-l.
8.27. Remark. In Takahashi (1932) it is assumed that g is continuous and strictly increasing with g(O) = 0 and g-l(X) ?f(x). This result is somewhat weaker than Corollary 8.26. Similarly, a result of Bullen (1970b) is weaker than Corollary 8.26. A similar result for N-functions is given in result (iii) of Krasnoselskii and Rutickii (1958, 1961). D 8.28. Theorem. conditions:
Let T: P - P be an operator satisfying the following
x y ~ T ( p ) ( x ) + T ( q ) for ( y )
p,qEP,X?O,
and
y?O;
xy= T(p)(x) + T(q)(y) if y=p(x),
(8.29) (8.30)
where pEP and q is its right -inverse function. Then
f x
T(p)(x) =
p(t)dt for
pEP
and
x?O.
(8.31)
o
8.29. Remark. Theorem 8.28 is proved in Lackovic (1974b). It is a minor generalization of a result in Hsu (1972). D There exist generalizations of Young's inequality which involve several functions. The following is given in Beesack, Mitrinovic, and Vasic (1980): 8.30. Theorem. Let f be continuous and strictly increasing on an interval I containing the points x = a and x = b, and let g be an increasing function on I. Then
f b
t g ( b ) - f ( a ) g ( a ) ~f(x)dg(x) +
f t
f(a)
g(f-l(y»dy fort Ef(I),
(8.32)
246
8. Special Related Inequalities
= f(b)
and equality holds iff either t
or g is a constant between band
r\t). Cooper (1927), Takahashi (1932), and Oppenheim (1927) also give generalizations of Young's inequality which involve several functions. The following result is due to Oppenheim: 8.31. Theorem. Let t.. ... ,fn be continuous, nonnegative, and strictly increasing on 1= [0, 00). If at least one of them takes the value zero at x = 0, then 'k
D1 fk(tk)
~ktl
f (I] i*k
o
for tk E I (k
= 1, ...
(8.33)
t(x») dA(x)
, n). Moreover, the equality holds iff t 1 = ...
°
Proof. Without loss of generality we may assume that Define the functions Fk (1 ~ k ~ nJ by Fk(x) = A(x) for Fk(x) = fk(tk) for x 2= tk. Then
t1 f (ll
t1 f (ll
4
~ •••
~x
~ tk
~tn' and
~
Fj(x) ) dFk(x) =
f
~
=
°
Since ~ Fj(x) ~ t ( x )and differences), we also have
°
o
Fj(x») dFk(x)
n
d
n
n
(J] Fj(x») = J] Fj(tn) = Jl t(ti)'
~ ~ F k ( X )~ ~ f k ( X h ) old
for all x, j, k (and all
f ( I T F j ( x » ) d F k ( Xf) ~ 4
o
~t1
°
= tn'
4
l*k
0
(ITt(x»)dfk(x) for l*k
1 ~ k ~ n ,(8.34)
and the inequality (8.33) follows. Furthermore, if t 1 = ... = t.: then clearly the equality in (8.34) holds, hence also that in (8.33). On the other hand, if ~ tk < tn for some k, then
°
IT Fj(x) = Fk(x) IT
i*n
i*n,k
Fj(x) < fk(X)
IT
i*n,k
t(x) =
IT t(x)
i*n
holds for tk < x ~ tn ; thus strict inequality must hold in (8.34) for k Consequently, strict inequality also holds in (8.33). D
= n.
8.3. Nanson's Inequality
8.3.
247
Nanson's Inequality
The following result is due to Nanson (1904):
8.32. Theorem.
If the real sequence { a k n : ~isl convex, then
al
+ a3 + ... + aZn+l:> az + a4 + ... + a Zn n+1 n
(8.35)
with equality iff {ak} is an arithmetic sequence.
Proof.
Since {ad is convex, we have ak - 2ak+l
+
a k + Z ~ Ofor
k
= 1, 2, ...
,2n-1.
(8.36)
By virtue of this fact, we conclude that k(n - k
+ 1)(azk-l -
2aZk + aZk+l) ~ 0
for
k
= 1, ... , n
and k(n - k)(aZk - 2aZk+l + aZk+Z) ~ O.
By adding these inequalities we obtain (8.35). Furthermore, equality in (8.35) holds iff equality in (8.36) holds for every k, which occurs iff {ak} is an arithmetic sequence. 0
8.33. Remarks. (a) Another proof of (8.35) is given in Adamovic and Pecaric (1989). (b) Steinig (1981) noted that the following extension and interpolation of (8.35) is equivalent to (8.35): Zn+l
2:
k=l
1 n 1 Zn+l 1 n ( - I ) k + l a k ~ - a Z k + l ~ - 2 - a k ~ - a Zk' n + 1 k=O n + 1 k=l n k=l
2:
2:
2:
(c) Let the sequence {ak} satisfy the conditions m s 6?an s M
for
n ~ 1.
(8.37)
Then the sequences {Cn}n;"l and {dn}n;"l given by en =a n -m(nZj2) and d; = M(n z/2 ) are convex. Thus the following results are valid (see Andrica, Rasa, and Toader, 1984): 2n+l 1 n In 2n+l - - m ::s-aZk+l - aZk ::s--M 6 n +1 k ~ O n k~l 6
2:
2:
248
8. Special Related Inequalities
and n(2n + 1) 6
Z ~ l()k+l
m ~L.
k=l
-1
1 ~ n(2n + 1) ak---1 L. a Z k + l ~ 6 M. n + k=O
(d) Stankovic (1976) gave the following generalization of (8.35): (n - 2p )(al + a3 + ... + aZn+l) + (2p - n - l)(az + a4 + ... + azn)
+ 2p(a l + aZn+l) - p(az + azn)
~
° for all
p ~ 0.
For p = 0, it reduces to Nanson's inequality. Note that this inequality yields the special case neal + a3 + ... + aZn+l) - (n + l)(az + a4 + ... + azn) ~ 2p(a3
+ ... + a Zn- l) - p(az + 2a4 + ... + 2azn- z + azn),
which is weaker than Nanson's inequality. This is so because it follows from
which in turn follows by adding the inequalities 2aZk+l
~ aZk
+ aZk+Z for k = 1, ... , n -
1.
(e) Adamovic and Pecaric (1989) proved the following generalization of Nanson's inequality: 1 n-m+l 1 n+l 2 2 aZk ~ - - 1 aZk-l for m e n - m + k =m n + k= 1
L
L
j{
and
2m ~ n.
However, this inequality is also weaker than (8.35) due to the inequality 1
n - 2m + 2
n-m+l
L k=m
1 n «» ~ -L aZk' n k=l
(8.38)
which will be proved as a consequence of Theorem 8.34 below. (f) Lackovic (1975) proved that the inequality
is valid for every convex sequence {ad iff the sequence {pd is given by Pk = constant (k = 1, ... , 2n + 1). 0
8.3. Nanson's Inequality
249
Adamovic and Pecaric (1989) proved:
8.34. Theorem. Let {akH be a convex sequence and In = {1, ... , n}, and let I, J, and M be nonempty subsets of In such that I and J are non-overlapping. Let I, J, and M have cardinal numbers a, f3, and y, respectively, and denote v = 2: i,
w
=
ieJ
2: i. ieM
If u
v
u
v
-<- and -<m
(8.39)
then the inequality yv 2: a, =5 ll'V -
iEM
f3w - yu 2: a, + ll'W 2: a, f3u iEI av - f3u iEJ
(8.40)
holds. If in addition to (8.39) the condition
w
u+v
y
a+f3
(8.41)
is also satisfied, then
-1 2: a, = 51- - 2: a
y iEM
+ f3 iEIUJ
a,
(8.42)
holds. If M and I U J are also non-overlapping, then the inequality 1 1 1
-y 2: a, =5 a + f3 + Y 2: iEM
iEIU}UM
a, = 5 - - 2: a, a + f3 iEIU}
(8.42')
holds. Furthermore, each of the inequalities (8.40), (8.42), and (8.42') becomes an equality iff {ak} is an arithmetic sequence on the set S = {min(I UJ), min(I UJ) + 1, ... , max(I UJ)}. Note that without the condition
u a
v
- =5 m =5 -
f3
for every n EM,
(8.39')
the conditions u] a < vi f3 and (8.41) do not imply the inequality in (8.42).
250
8. Special Related Inequalities
8.35. Corollary. Let {akH be a convex sequence. Then for m e N and 2m :::5 n - 1 the inequalities 1 n-m 1 n 1 (m ai:::5 a, :::5 a, + n - 2m i ~ m + 1 n i=1 2m i=1
2:
2:
2:
n) 2: a, i ~ n - m + l
(8.43)
hold, and both inequalities become equalities iff {ak} is an arithmetic sequence.
8.36. Remark. If we replace m - 1 by m and aZk by ak in the first inequality in (8.43), we obtain (8.38). 0 Next we observe the following definition: 8.37. Definition. A real sequence { a (p, q > 0) if Lpq(a n) ~0 for n ~ 1, where Lpq(a n) = an+z - (p
d ~is
said to be p, q-convex
+ q)an+l + pqa n·
8.38. Remark. In Milovanovic, Pecaric, and Toader (1985) it is shown that the theory of p, q-convex sequences plays an important role in the ~ by sequence { w n } given p n _qn W = P - 1 for p*"q n { np'"? for p = q. For example, the following result is proved: The sequence {an} satisfies the relation n = 1,2, ... (8.44) iff an = UWn + VWn+l' (8.45) where u and v are arbitrary real numbers.
0
Milovanovic, Pecaric, and Toader (1986) also proved the following generalization of Nanson's inequality: 8.39. Theorem.
If the real sequence {ak}f'+l is p, q-convex, then
(pqta 1 + (pqt-1a3
+ ... + aZn+l
...:..o.-..o...:...----=-_..:.::-::...:.-_--=--
(pqt-1az
+ (pqt- Za 4 + ... + aZn
~ ~ ~ - - - " - - - - - - ' ' ' - - ' ~ - - - ' - - - - - - - . . . = : . . :
(8.46) and equality holds iff {ad satisfies (8.44).
8.3. Nanson's Inequality
251
8.40. Remarks. (a) For s.; = Wl + ... + Wn we have Lpisn) = 1; thus if the real sequence {ad satisfies m
:s; L p q :s; M
for
n = 1, 2, ... ,
then the sequences {b n} and {en} given by
are p, q-convex. A generalization of the first inequality in Remark 8.33(c) can be given by using this fact (see Milovanovic, Pecaric, and Toader, 1986). (b) As shown in Mitrinovic (1970, pp. 205-6), Nanson's inequality for k- 1 ak =X gives an inequality of J. W. Wilson. However, the results given in this section can also be applied to yield results in Mitrinovic (1970, p. 198, (3.24» and in Mitrinovic (1965, p. 139, 2.3.1.4 and 2.3.1.5). All of these results are further generalized in Adamovic and Pecaric (1989), where the following result is proved: Let p and q be real numbers such that p >q.
(i) If either (1) q >
°
°
or (2) p > > q and p + q < 0, then
p
q
a + -1
p +q p- q
-P- -q> - - for O
°
-
a
(8.47)
(ii) If either (1)' p < or (2)' p > 0 > q and p + q > 0, then the reverse inequality in (8.47) holds. 0 Besides the generalizations of Wilson's inequality and other related results, this result represents an improvement of a result of D. Z. Djokovic (Mitrinovic, 1965, pp. 162-63, 2.3.2.8, or Mitrinovic, 1970, p. 276, 3.6.26). It also improves the inequality in Mitrinovic (1970, p. 279, 3.6.31). Furthermore, some other examples are given in Adamovic and Pecaric (1989).
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General Linear Inequalities for Convex Sequences and Functions
Chapter 9
9.1.
Inequalities for m-Couvex Sequeuces and Functions
The following theorem is given in Pecaric (1981e): 9.1. Theorem. Let p = (Pl' ... ,Pn) be a real n-tuple, where n > m. Then the inequality n
2: p.a, 2:: 0
(9.1)
i=1
holds for every m-conuex sequence
{ a i } i~ ff
n
2: (i -
i=1
1)kp i = 0 for
k
= 0, 1, ... , m -
1
(9.2)
+ 1, ... , n,
(9.3)
and n
2: (i -
k
+m -
1)(m-1)Pi 2:: 0 for
k =m
i ~ 1
where
P) = j(j -
1) ... (j - k
+ 1), /0) = 1.
Proof. The sequences a, = (i - 1)k and a, = -(i - 1)k (1 -<:; i -<:; n) are m-convex for every k = 0, 1, ... , m - 1; thus (9.1) becomes (9.2), and the condition (9.2) is necessary. On the other hand, the sequence
o
a i = {(i - k
for
+m -
1)(m-1) for
1 -<:; i -<:; k - 1 k -<:; i -<:; n
is convex for every k = m + 1, ... ,n. Thus by (9.1), condition (9.3) is also necessary. 253
254
9. General Linear Inequalities
That the conditions are also sufficient follows directly from the identity rn-I
n
1
1
n
~p.a, = ~ ok! /j.ka l ~(i -1yk)Pi + (m -1)! X
k ~ ~ + 1 ( ~(i - k + m _1)(rn-I)Pi)/j.rn ak_rn;
(9.4)
this identity represents a generalization of the well-known Abel Identity given by (9.5) which can be easily proved by mathematical induction. 9.2. Remarks.
o
(a) It is clear that conditions (9.2) can be replaced by n
2.: (i -
1)(k)Pi =
i=1
°
for
k = 0, 1, ... , m - 1.
(9.2')
(b) In Theorem 9.1 the result for the case in which m = 1 and Pi is replaced by Pi - qi can be found in Marshall and Olkin (1979, p. 445). The corresponding integral analogue is also given in Marshall and Olkin (1979, p. 444) and Mitrinovic (1970, pp. 114-15), and it was pointed out that this result is due to Steffensen. (c) For m = 2, the result in Theorem 9.1 is given in Karlin and Studden (1966, p. 421). Moreover, Karlin and Studden (1966, p. 422) also gives the following interesting special case: Let p be an n-tuple i 0, (ii) I : ? ~ Iipi = 0; and let { a ; } ~be satisfying the conditions (i) I : ? ~ I P = such that
then for every convex sequence { a i } ~t he inequality in (9.1) is valid. (d) The identity in (9.4) can be expressed as (see Milovanovic and Pecaric, 1986): n
rn-I
.=1
k
2.: p.a, = 2.: X
1 n-k 1 k' Vkan_k (n - i)kpi + ( -1)' ~ O ' . ~ 1 m.
: ~ ~ ( ~(k -
2.: i
+ m _1)(rn-l)Pi)V rna k'
(9.6)
9.1. Inequalities for m-Convex Sequences and Functions
255
Thus the following result is a modification of Theorem 9.1: Let p be a real n-tuple (n > m). Then the inequality n
2 : P i a i ~ O i=l
holds for every V-convex sequence of order m iff n
2: (n - i)kpi = 0
for
k = 0, 1, ... , m - 1
i=l
and k
2: (k - i + m _1)(m-I)Pi ~0
for
k
= 1, ... , n - m.
i=l
(e) In Pecaric, Toader, and Milovanovic (1986) it was shown that, by using (9.4), Taylor's formula for sequences can be given by
(f) The following identities are consequences of (9.4) and (9.6): (9.8)
(9.9)
For Pi =
(:)i we can obtain (from (9.9)) the following identity given in
Drazin (1955):
256
9. General Linear Inequalities
By using this identity, Drazin proved the following inequalities (see also Mitrinovic, 1970, p. 348): (i) If (-1
r-
s
~n-sa s
inequality, then (ii) If
2: 0 (s = 0, 1, ... , n) with at least one strict
I:7=o
~ n - s a 2: s 0
(s
inequality, then
C)iai > 0 for y > -1.
= 0, 1, ...
,n)
with
I:7=o ( ~ ) i a i > 0 for y <
at
least
one
strict
-1.
We can obtain some similar results by using (9.8) for Pi
=
C)yn-i, i.e.,
(g) Let us denote by Km(n) the class of all m-convex sequences, i.e.,
and similarly we denote
Then Theorem 9.1 yields the following result (Toader, Pecaric, and Milovanovic, 1985): p belongs to K:'(n) iff P i = v m q i = ( - I ) m ~ for m q i = 1, ... , n, where
=o for qi{2:0 for
i = 1, ... ,m and i =m + 1, ... , n.
i =n
+ 1, ... , n + m,
Of course, this result is related to the well-known Minkowski-Farkas' lemma (see, for example, Tchernikov, 1968). D
In Pecaric, Mesihovic, Milovanovic, and Stojanovic (1986) it was noted that identities (9.4) and (9.6) can be used for proving the following generalization of Theorem 9.1:
i
9.1. Inequalities for m-Convex Sequences and Functions
9.3. Theorem.
257
Let {Pi}]' be a real sequence (n > m 2: 1). Then
(i) Inequality (9.1) holds for every sequence {aJ 7' that is convex of orders j,j + 1, ... , m (j E {I, ... , m}) iff n
2: (i -
i=l
l)(klp i = 0 for
k
= 0, 1, ... ,j -
1,
(9.10)
n
2: (i -
l)(klp i 2: 0 for
k
= j, j + 1, ... , m - 1,
(9.11)
i ~ l
and n
2: (i -
k
i=k
+ m _1)(m-1 lp i 2:0
where a(kl = a(a - 1) ... (a - k
for
+ 1),
k= m
+ 1, ...
,n,
(9.12)
a(Ol = 1.
(ii) Inequality (9.1) holds for every sequence {aJ7' that is V-convex of orders j, j + 1, ... , m ti E {I, ... , m}) iff n
2: (n -
i=l
i)(klp i = 0 for
k
= 0, 1, ...
,j - 1,
(9.13)
n
2: (n -
i=l
i)(klp i 2: 0 for
k
= j, j + 1, ... , m - 1,
(9.14)
n
2: (k -
i
+m -
1)(m-1lp i 2: 0 for
k
= 1, ... , n - m.
(9.15)
i ~ l
The following definition, given in Toader (1985b), concerns starshaped sequences: 9.4. Definition. A sequence {a i}7' is said to be starshaped of order m if the sequence {(ai+l - a 1)/i}7' is convex of order m-1. The following theorem is proved in Pecaric and Agovic (1988) (see also Pecaric, Toader, and Milovanovic, 1986):
258
9. General Linear Inequalities
9.5. Theorem.
Inequality (9.1) is valid for every sequence starshaped of order j, ... , m iff the sequence { P i } satisfies ~
2)Pi = 0
n
n
(.
~ k(i -1) ~ ~2
LPi=O; ;=1
2)Pi
n
i ~ (i -1) ( .~ ~2
L (i i=k n
1)
2= 0
(i + m -_ k - 2)Pi m
k
for
2
2= 0
is
k = 2, ... ,j;
for
= j + 1, ... for
{ a i } ~t hat
k=m
,m;
and
+ 1, ... , n.
*
Let P 0 be a real number. We define the operator Lp by (see Lackovic and Kocic, 1979b): Lp(a n) = an+l - pan
for n E.N,
where .N is the set of all positive integers. For a given sequence {aJ ~ , we say that it is p-monotone or that it belongs to the class Kp , if the inequality Lp(a n) 2= 0 holds for all n E.N. By the well-known Abel Identity, we then have (9.16) Thus from (9.16) we can easily obtain the following theorem (Pecaric, 1981d):
9.6. Theorem.
Let
{ p J b ~e
(a) Inequality (9.1) 'L.?=lpi-lPi = 0 and
an arbitrary real sequence. Then
holds for
every sequence
{ a J ~
in
K p iff
n
L pi-kPi
2= 0
for
k
= 2, ...
, n.
i=k
(b) Inequality (9.3) holds for every sequence a l 2= 0 iff
{ a J ~in
Kp such that
n
L pi-kPi 2= 0
for
k = 1, ... , n.
i=k
9.7. Remark.
Note that
Lpq(ak) = Lp(Lq(ak» = Lq(Lp(ak» = ak+2 - (p
+ q)ak+l + pqak
9.1. Inequalities for m-Convex Sequences and Functions
259
holds for every k = 1, ... , n - 2; and that the inequality Lpq(ak) 2: 0 for k = 1, ... , n - 2 defines p, q-convex sequences (see Definition 8.37). We D shall denote this class by K pq . Note that necessary and sufficient conditions for (9.1) to hold for all sequences in K pq are given in Milovanovic and Kocic (1989). Instead of the inequality in (9.1), Popoviciu (1959b) considered an inequality of a bilinear form, and proved the following result: 9.8. Theorem. E?=r E7=s x ij ·
Let Xjj (1:5 i, j:5 n) be real
numbers and X r •s =
(a) For all sequences a=={aJ7 and b=={b j}7 monotonic in the same direction, n
F(a, b) ==
n
2: 2: Xijaibj 2: 0
(9.17)
i=l j=l
holds iff X r •s X r • l = 0 for
2:
0 for
r = 1, ... ,n
r, s = 2, ... , n, and
X l •s = 0 for
(9.18) s =2, ... , n.
If a and b are monotonic in opposite directions, then the inequality in (9.17) is reversed. (b) For all nonnegative increasing sequences a and b, F(a, b) 2: 0 holds iffX r •s 2: 0 (r, s = 1, ... , n).
9.9. Remark. As noted in Pecaric (1979a) and Kovacec (1983), the condition Xl,s = 0 is missing in Popoviciu (1959b) and Mitrinovic (1970, p. 38). Pecaric's proof uses a generalization of Abel's identity given in (9.5), D and Kovacec's proof uses Theorem 9.1, with m = 1. A similar result of multilinear form is given in Pecaric (1979a), and a new proof of that result is given in Kovacec (1984). This result states: 9.10. Theorem. and
Let Xi, , ... , x im(1 :5 ik :5 n, 1:5 k :5 m) be real numbers Sl
XS''''Sm =
2: ...
i}=l
s,«
~ Xi,"'Xim ' i",=1
260
9. General Linear Inequalities
Then for all nonnegative decreasing n-tuples aj= {aj1"'" m), the inequality
ajn} ( l ~ j ~
n
2:
F(a1' ... , am) =
Xi,'" Xim a1i, ... amim ~
;t,···,i m = l
holds iff X
s ,
• • • Sm
~
°
for
1
~ Sj ~ n,
° (9.19) (9.20)
l ~ j ~ m .
9.11. Remarks. (a) In Pecaric (1979a) integral analogues of Theorems 9.8 and 9.10 are also given. (b) Generalizations of Theorems 9.8 and 9.10 for p-monotone sequences are given in Pecaric (1981d). (c) Necessary and sufficient conditions for the validity of inequality (9.17) for convex sequences a and b are given in Pecaric (1983d). A generalization of this result for p, q-convex sequences is given in Milovanovic, Pecaric, Stojanovic, and Mesihovic (1988). Analogous results for convex and V-convex sequences of order m and n are given in Pecaric, Mesihovic, Milovanovic, and Stojanovic (1986), and for starshaped sequences of higher order in Pecaric and Agovic (1988). 0
The following generalization of Theorem 9.8 (and many other related results) is given in Pecaric, Mesihovic, and Milovanovic (1989):
9.U. Theorem.
Let
Xij, aij
(i = 1, ... , N;j = 1, ... ,M)
be
real
numbers.
(a) The inequality N
F(a) ==
M
2: 2: Xijaij
~
i=l j=l
°
(9.21)
holds for every sequence {aij} that is (n, m )-convex iff N
M
r=l
s=l
N
M
r=l
s=j
N
M
r=i
s=1
2: 2: (r -l)(i)(s -l)(j)x
rs
2: 2: (r -
l)(i)(s - j
=
°
for
i = 0, ... , n -l;j
+ m - 1)(m-1)xrs =
°
= 0, ...
for
i = 0, ... ,n -l;j = m
2: 2: (r -
i
+n -
1)(n-1)(s - l)(j)x rs =
, m -1,
+ 1, ...
,M,
° for
i=n
+ 1, ... , N;j = 0, ... , m -1,
9.1. Inequalities for m·Convex Sequences and Functions
261
and N
M
2: 2: (r -
i
+n
- 1)(n-1)(s - j
+m
- 1)(m-l)xrs
2:
° for
r=i s=j
i= n
+ 1, ...
, N, j = m
+ 1, ...
, M.
(b) The inequality in (9.21) holds for every sequence {a ij } that is convex of order (u, v) (u =0, ... , n; v =0, ... , m) iff N
M
r=1
s=1
N
M
r=1
s=j
N
M
2: 2: (r-1)(i)(s-1)(j)x 2: 2: (r -
1)(i)(s - j
+m
rs2:0
for
i=0, ... ,n-1;j=0, ... ,m-1,
_1)(m-1)xrs
2:
° for
i = 0, ... , n -1;j
2: 2: (r -
i + n - 1)(n-1)(s - 1)(j)xrs
2:
= m + 1, ...
, M,
° for
r=i 5=1
i
= n + 1, ...
, N;j
= 0, ... , m -1,
and N
M
r=i
s=j
2: 2: (r -
i + n - 1)(n-1)(s - j
+m
- 1)(m-l)xrs i=n
2:
° for
+ 1, ... , N, j = m + 1, ... , M.
9.13. Remark. Theorem 9.1 may be formulated more generally as the following: Let S be a vector space of all sequences, X be a topological vector space, and Pc X be a closed, convex cone in X. The following result is given in Toader (1987b) (see also Lackovic and Kocic, 1984): Let A: S ~X be a continuous linear operator. In order that A(x) E ~ for every x E K m it is necessary and sufficient that (i) A( {ed) = for k =0,1, ... , m -1 and (ii) A({ed) E P holds for k 2:m, where {ed is the sequence with components eki =
(m- 1 + 1i - k) m _
and
° (n) = ° for j
n <j. Another generalization of Theorem 9.1 is given in Toader (1988a). 0 Of course, instead of inequality (9.1) we can also consider similar results for convex functions. First we shall give a result of Popoviciu (1940a) (see also Popoviciu, 1944, p. 35) which contains Theorem 9.1 as a special case. Popoviciu proved this result by using an identity which is a generalization of (9.6).
262
9. General Linear Inequalities
9.14. Theorem. Let f : I ~IR be a discrete n-conuex function and p be a real n-tuple (p 1= 0). Let Xi E I (i = 1, ... , m) and Xl < X2 < .. ·Xm. Then m
2: pJ(x;)
(9.22)
~ O
;=1
holds iff m
2: Pi x 7= 0
for
k = 0, 1, ... , n - 1
i=l
and r
2: Pi(Xi -
Xr+l)(Xi - Xr+2) •.. (Xi - x r+ n- l) :::::;
0 for
r
= 1, ... , m - n.
i ~ 1
Popoviciu (1940a, 1940b) also proved the following theorem (see also Popoviciu, 1944, pp. 35-36 and Mitrinovic, 1970, p. 160):
9.15. Theorem. The inequality (9.22) holds for every 1= 0 (i = 1, ... , m) and every n-conuex function f iff
Xl:::::;·· . :::::; Xm ,
Pi
m
2:
P r X ~= 0
holds for
k
= 0, 1, ... , n -
1
r=1
and k
- 2: Pr(x r -
m
t)n-1
=
r=l
holds for t E
(Xb xk+d
2:
p.i»; -
rr-
l
~0
r ~ k + 1
and k
= 1, ... , m - n.
9.16. Remark. For convex functions we have the following result (Pecaric, 1989f): Inequality (9.22) holds for all m-tuples x and p and all convex functions f iff Pm = 0 and m
2: Pi IXi -
xkl
~0
for
k
= 1, ... , m.
0
i ~ 1
9.2.
Some Generalizations and Refinements
The following results are some generalizations of Theorem 9.15 (see Vasic and Lackovic, 1978 and Lackovic and Vasic, 1979).
9.2. Some Generalizations and Refinements
Let the norm of a function f
E
263
C[a, b] be defined in the usual way:
Ilfll = as/sb max If(t)l· For a sequence of function Un}, fn E C[a, b], we say that the sequence of functions converges (uniformly) to the function f E C[ a, b] if limn--->oc IIfn - fll = O. Let us assume that D c ~ , and let S(D) be one of the normed subspaces of the space of all real functions defined on D, where the norm of a function f E S(D) is denoted by Ilflll' We consider operators A of the following form A:C[a, b ] ~ S ( D and ) , say that A is continuous if from the condition Ilfn - fll ~0 (as n ~(0) it follows that IIAfn - Aflll ~0 as n ~00. Also, we write Af?:. 0 if g(t) = Af?:. 0 holds for every tED, where f is a given function in the space C[a, b]. The set of all functions which are convex of order n and continuous on [a, b] (continuous from the right at a and continuous from the left at b) will be denoted by Kn[a, b]. Clearly we have Kn[a, b] c C[a, b]. We shall consider the classes K n [ a, b] for n e: 2, and define for i = 0,1,2, ....
ei(t) = ti for
a
~t
~b.
(9.23)
Furthermore, for t, C E [a, b] we define the function wn+l(t, c) by t - C
Wn+l(t,C)=
(
+ It - CI)n 2
9.17. Theorem. Assume that A: C[a, tinuous operator. Then
f
E
= (t-c)':-.
b ] ~S(D)
(9.24)
is a linear and con-
Kn[a, b]:? Af?:. 0
(9.25)
holds for every function f iff Aei = 0 for
i = 0, 1, ... , n - 1 and
Awn(t, c)?:. 0 for every Proof.
c E [a, b].
(9.26) (9.27)
(a) If: Let us denote m
Fm(x) = Pn(x) + L cjwn(x, Xj)'
(9.28)
j ~ 1
where Pn(x) E fIn (the set of all polynomials of degree at most n), and assume thatf E Kn[a, b]. Then by Theorem (1.44) there exists a sequence
264
9. General Linear Inequalities
the form (9.28) with Cj 2: 0 (j=1, ... ,m) such that the functions wn(t, c) are of the form (9.24) and { F m ( x ) }of ~
lim IlFm(x) - f(x)11 m---+ oo
= o.
(9.29)
By virtue of (9.28) and the linearity of the operator A, it follows that m
AFm(x) = APn(x) + m
2: cjAwn(x, Xj)
j=l
m
= 2: ajAe/x) + 2: cjAwn(x, Xj)' j ~ O
j=l
(9.30)
Since (9.26) and (9.27) are valid where the e/s and wn's are given in (9.23) and (9.24), respectively, by virtue of (9.29) we obtain m
AFm(x)=2:c jAwn(x,xj)2:0 forevery j=l
m=1,2, ....
(9.31)
By using the continuity property of the operator A in (9.30) and (9.31), we find that Af
= A ( ~ ~ Fm(X)) o o = E ~ o Ao Fm(x) 2:0,
which implies (9.25). (b) Only if: Suppose that the implication in (9.25) is valid for an arbitrary function f E Kn[a, b]. By a direct verification it follows that the functions ej and -ej defined in (9.23) are in the class Kn[a, b]. Thus by (9.25) we have Aej 2: 0 and A(-ej) 2: 0, and (9.26) is satisfied. In the same fashion we conclude that wn+1(t, c) E Kn[a, b]. Using (9.25) one more time, we obtain (9.27). D We say that the operator A:C[a, b] x C[a, b ] ~ S ( D is) bilinear if the operator Bu = A(u, v) is linear with respect to u for every function v E C[a, b] and if the operator Cv = A(u, v) is linear with respect to v for every function u E C[a, b]. From Theorem 9.17 we can obtain the following theorem. 9.18. Theorem. Let the operator A: C[a, b] x C[a, b ] ~SeD) be bilinear and continuous. Then for every pair offunctions (t, g),
9.2. Some Generalizations and Refinements
265
is valid iff (i) A(ei,ej)=O for O::5i, j::5n-1, (ii) A(ei,wn(t,C»= A(wn(t, c), ej) = 0 for every c E [a, b] and every i, j = 0, 1, ... , n - 1, and (iii) A(wn(t, Cl), wn(t, C2»"? 0 for every (c 1 , C2) E [a, b] x [a, b].
9.19. Remarks. (a) For n = 2, instead of w2 (t, c) = (t - c)+, we can let W2(t, c) = oc(t) = It - c] (see Vasic and Lackovic, 1978). (b) Vasic and Lackovic's papers were published in 1978, and earlier Bojanic and Roulier (1974) proved the following general result: Let A: C[a, b ] ~X be a continuous linear operator. Then AU) E P holds for every f E Kn[a, b] (n "? 2) iff we have (i) A(p) = 0 for every p E IIn - 1 (the set of all polynomials of degree at most n - 1), and (ii) A(wn(t, c» E P for every c E (a, b), where X and P are defined as in Remark 9.13. (c) Theorems 2.24 and 2.26 are simple consequences of Theorem 9.17. (d) Vasic and Lackovic (1978, 1979) give some majorization-type theorems which follow by replacing A with A - B in Theorem 9.17. (e) In Kocic and Lackovic (1986) and Kocic (1984) the reverse of the implication in (9.25) is considered. For that result we need the concept of one-sided strong local maximum (OSLM) of real-valued functions: A function rjJ E C(/) has a OSLM at the point Xo E 1 (an interval) if there exists an h > 0 such that for every x E (xo - h, Xo + h) £; 1 we have rjJ(x) ::5 rjJ(xo), and rjJ(x) < rjJ(xo) holds at least in one of the intervals (xo - h, xo) or (xo, Xo + h). We denote by C(/) the set of all functions in C(/) that have a OSLM in at least one point in 1. Now we can give a result of Kocic and Lackovic (1986): Let {A;J be a i family of linear operators such that A),: C ( / ) S ~ (D) and e;(t) = t (i = 0, 1). If (i) A),eo = 0 for every AE A, where A denotes the index set which is at least countable, (ii) A),e1 = 0 for AE A, and (iii) for every rjJ E C(I) there exists at least one Ao E A and Yo E D such that AAo(rjJ, Yo) < 0, then
A),"? 0 for every AE A
f
~
E
K(I) for every f
E
C(/),
where K(I) is the set of all convex functions on I. As a special case, they gave a linear criterion of convexity: Let {A),} be a family of continuous ~ (D) where 1 is a finite interval. If the linear operators A),: C ( / ) S previous conditions (i)-(iii) and (iv) A),0c"? 0 for every C E I, AE A are satisfied, then
Ad"? 0 for A E A¢:}f E K(I) holds. The function o; in (iv) can be replaced by W2(t, c).
266
9. General Linear Inequalities
(f) A result similar to Theorem 9.17 for starshaped sequences is given in Milovanovic, Stojanovic, and Kocic (1986). 0 The following theorem is proved in Brunk (1964):
9.20. Theorem. Let I be an interval in ~ k ; X(t) = (XI(t), ... ,Xk(t» be a vector of functions where the X;'s (1:5 i:5 k) are increasing and continuous from the right on [a, b). Let H be continuous from the left and of bounded variation on [a, b), with H(a) =0. If H(b)=O, fra,b)H(u) dX(u) =0, and
f
H ( u ) d X ( u ) ~for[a,t]c[a,b], O
[a,t)
then
f
~0
f(X(t» dH(t)
(9.32)
[a,b) holds for every continuous function f: I ~ ~ with increasing increments, where JH dX = (f H dXI, . . . , f H dXk)· The conclusion also holds when [a, t] is replaced by [a, t). Now let dp, denote a signed measure on (a, b) such that f ~ Idp,1 < 00. Such a measure possesses a decomposition du = dP,1 - dp,zwhere dP,1 and dp,z are finite nonnegative measures on (a, b). We restrict our attention to the measures du such that for each (jJ E C(uo, u l , ••• , un) the integral f ~ (jJ du is well-defined, with infinite values permitted. Specifically, if (jJ+(t) = max{ (jJ(t), O} and (jJ-(t) = (jJ+(t) - (jJ(t), then we can write b
b
b
f (jJ du = f (jJ+ a
dP,1
a
+ f (jJ- dp,z-
b
b
(f (jJ- dP,1 + f (jJ+
a
a
dP,z).
a
That f ~ (jJ du is well-defined means that at lest one of the sums b
f (jJ+ a
b
dP,1
b
f
f
a
a
+ (jJ- du., and
b (jJ- dP,1
+ f 4>+ dp,z a
is finite. The dual cone of C(uo, u l , . . • , un), denoted by C*(Uo, UI , ... ,un), is the set of signed measures du on (a, b) which
9.2. Some Generalizations and Refinements
267
obey the above integrability requirements and satisfy b
JcI>(t)u(dt)
~0
for all cI>
E
quo,
Ul, •.. ,
un)
a
(see Karlin and Studden, 1966, p. 405). In the following we state some characterizations of the cone C*(uo, Ul,"" un) as given in Karlin and Studden (1966, pp. 405-10.). 9.21. Theorem. A signed measure du is contained in the dual cone C*(uo, Ul,"" un) iff b
J
Uj
du = 0 for
j
= 0, 1, ... , n
(9.33)
~0,
a <x
(9.34)
a
and b
Jcl>n(t, xl dp,(t) a
where cl>n is given by (1.84).
9.22. Theorem. A signed measure du is contained in the dual of the cone nj=k quo, Ul, . . . , uj ) , k:5, n - 1, iff b
J
(i)
Uj
du = 0 for
j
= 0, 1, ... , k;
a
f b
(ii)
Uj
dp.
~o
for
j
= k + 1, k + 2, ... , n;
a
and b
(iii)
J cl>n(t, x) dp,(t)
~0
for
a < x < b.
a
For the next result we need the following definition: 9.23. Definition. A signed measure du is said to have k sign changes on (a, b) if there exists a subdivision of (a, b) into disjoint consecutive
268
9. General Linear Inequalities
intervals .lo,. . . ,Jk such that dp is of alternating sign and non-null on Jo, . . . ,Jk. (In the case that d p =f (t)dt for some continuous function f, the number of sign changes of d p is equivalent to the number of ordinary sign changes of the function f.)
9.24. Theorem. (a) If d p satisfies the orthogonality relations (9.33), then d p exhibits at least n + 1 sign changes. (b) Let d p satisfy (9.33). Zf dy possesses exactly n 1 sign changes on (a, b ) , is a nonnegative measure, and is non-null on some interval extending to the endpoint b, then d p E C*(uo,u1, . . . , u,).
+
Proof. (a) Suppose that d p possesses p 5 n sign changes. Then there exists a subdivision J o , . . . ,Jp such that d p is non-null and alternates in sign on .Io,. . . ,J p . Let ti = sup{t: t eJi} for i = 0, . . . ,p - 1, and define
Then the polynomial u(t) satisfies u(t)dp(t)2 0. Furthermore, since the support of d p cannot be confined to the finite set { t o , .. . , t,-,}, it follows that u ( t )dp(t) > 0. However, this inequality is incompatible with the orthogonality properties assumed for dp. Thus we conclude that dp must possess at least n + 1 sign changes. be the subdivision of (a, b ) associated with d p (b) Let .To, . . . , obeying the precepts of Definition 9.23. (Note that d p is a nonnegative measure on J,,+l.) Define t o , . . . , t, by ti =sup{t:t E J , } for i = 0, 1,. . . , n, and let
s:
8(t) =
(9.35)
where @ E C(uo,u l , . . . , u,). Expanding the determinant in (9.35), we see that s(t)can be written in the form
9.2. Some Generalizations and Refinements
269
With the aid of the orthogonality requirements satisfied by du, we obtain b
f
a
f b
Un)
(J(t) d{l(t) = U(u o' to,
, , tn
ep(t) duit].
a
However, it follows from (9.35) that (J(t) d{l(t) is a nonnegative measure throughout (a, b), so that f ~ ep(t) du ~O. Consequently we have du E C*(uo, Ul, . . . , un)' 0
9.25. Remarks. (a) Theorems 9.21, 9.22, and 9.24 contain many linear inequalities for convex functions, as was shown in Karlin and Studden (1966, pp. 410-31). This is a consequence of the fact that every linear continuous functional has an integral representation (see, for example, Kolmogorov and Fomin, 1972, pp. 347-48). (b) In Kocic (1982b) the implication f E quo, Ul) ~ A f " :0 ? is considered where A is a linear continuous operator defined as in Theorem 9.17. . (c) Note that Theorem 9.14 is used in Kovacec (1984) for a generalization of some classic inequalities for a rearrangement of vectors. (d) In Karlin and Studden (1966, p. 411), the Steffensen inequalities are also obtained as a consequence of Theorem 9.21. 0 In the following we give some refinements and converses of the previous results. First, we note that a simple consequence of Abel's identity in (9.5) is the well-known Abel Inequality (see Mitrinovic, 1970, pp.32-33): 9.26. Theorem. al":?· •. ":? an":?
Let {akH be a sequence of real numbers satisfying and let Wk = al + ... + ak (k = 1, ... , n). If
°
m
=
min Wk and l ~ k ~ n
M
=
max Wk, l ~ k $ n
then n
mai s;
L ;=1
wjaj:S Mal'
(9.36)
270
9. General Linear Inequalities
Bromwich (1908, 1955) gives the following generalization of (9.36): 9.27. Theorem. n), define
Given a real sequence {ad1 and an integer v (1::5 v::5 k
Ak
= 2:
a,
for
k
= 1, ... , n,
i=l
H;
= max
H ~
vsksn
= l:",:,;k:-s:v-l max Ak> Ak
and
,
h; =
min
Ak ,
l ~ k = : : : ; v - l
= min
h;
Y=:::;ksn
Ak ,
If {vd 1 is a decreasing sequence ofpositive real numbers, then n
2: a
hy(Vl - vy) + h ~ v y : : 5
ivi::5
Hy(Vl - vy) + H ~ v y . (9.37)
i=l
9.28. Remark. Bromwich (1908, 1955) also gave an integral analogue of the previous result with many applications. 0 Since the previous results (especially Abel's inequality) are related to the second integral mean value theorem, we give the following theorem and discuss some related results: Let t. g be real-valued functions which are defined and bounded on a compact interval I = [a, b], and let f be Stieltjes integrable with respect to g on I, written as f E L(g) on I. Further, let V(f, [a, b]) denote the total variation of f on I and "r the total variation function of f, i.e., vf(a) = 0 and vf(x) = V(f' [a, x]) for x E [a, b]. 9.29. Theorem (Second integral mean value theorem). Let f be increasing (decreasing), g be continuous, and h e L(g) on [a, b]. Then there exists a Z E [a, b] such that z
b
b
Jf(s)h(s)dg(s)=f(a) J h(s) dg(s) +f(b) J h(s)dg(s). a
a
(9.38)
z
If instead f is nonnegative and increasing (decreasing), then there exists a z, E [a, b] (zz E [a, b]) such that
f b
a b
f b
f(s)h(s) dg(s) =f(b)
h(s)dg(s)
~
~
(f f(s)h(s) dg(s) = f(a) Jh(s) dg(s»). a
(9.39)
271
9.2. Some Generalizations and Refinements
Proof. Denote G(x) = f ~ g ( s d) g(s) for x E [a, b]. Then G is continuous on [a, b] and f E L( G). Integrating by parts yields b
b
f f(s) dG(s) =f(b)G(b)- f G(s)df(s). a
a
By the first mean value theorem there exists a b
[a, b] such that
b
f G(s)df(s)=G(z) f df(s) a
Z E
= G(z)(f(b)-f(a».
a
Combining, we have (9.38).
D
Note that if we redefine f(a) = 0 (or f(b) = 0), then the result in (9.39) follows from (9.38). As an immediate consequence of the second mean value theorem we obtain (Karamata, 1949, p. 264 and Boas, 1970a): 9.30. Theorem. Let f be nonnegative and monotonic on [a, b], and assume that h E L(g) and fh E L(g) on [a, b]. (a) Iff is increasing, then b
f(b )inf{fh(s) dg(s): a z: t s:
-l-
b
f f(s)h(s) dg(s) a
t
b
::Sf(b)sup{f h(S)dg(s):a::st::Sb}. t
(9.40) (b) Iff is decreasing, then t
b
f(a)inf{f h(s)dg(s):a::st::Sb}::S f f(s)h(s)dg(s) a
a t
::Sf(a)sup{f h(s) dg(s):a::s t s; b}. a
(9.41)
Moreover, if g is continuous at b (at a), then we may replace f (b) by f(b_) in (9.40) (f(a) by f(a+) in (9.41».
9.31. Remark. In the same fashion we can obtain analogs similar to the D results of Mitrinovic (1970, pp. 301-2, 3.7.35 and 3.7.36).
272
9. General Linear Inequalities
The following result is a modification of a result in Karamata (1949, pp. 77-79) (see also Marik, 1949): 9.32. Theorem. Let f be a function of bounded variation on [a, b) = I, and let g, h be bounded functions such that h E L(g) and fh E L(g) on I. Then b
IJ f(s)h(s) dg(s) I ~ If(b)1 + V(f, I)
x
~ ~ ~IJ h(s) dg(S)I,
a
(9.42)
a b
b
IJ f(s)h(s) dg(s) I ~ If(a)1 + V(f, I)
~ ~ ~iJ h(s) dg(s)\.
(9.43)
a
Beesack (1975) gave the following generalization of a result of Darst and Pollard (1970): 9.33. Theorem. Let f be of bounded variation on [a, b) = I and h, g be bounded functions such that hE L(g) and fh E L(g) on 1. Let m = inf{f(x): a ~ x ~ b}, then b
v
b
Jf(s)h(s) dg(s)
~m Jh(s) dg(s) + V(f, I) a s ~ ~ ~ s J b h(s) dg(s),
a
a
u
(9.44) b
v
b
Jf(s)h(s) dg(s)
"2
a
m
Jh(s) dg(s) + V(f, I) a
a s ~ ~ ~ s Jb h(s) dg(s). u
(9.45)
An interesting related result is given by Marik (1974) (we state the result in the form given by Beesack): 9.34. Theorem.
Let the conditions of Theorem 9.32 be satisfied. Then v
b
If a
f(s)h(s) dg(s) I
~ ~ (V(f, I) + If(a)1 + If(b)1) U ~ ~ ~Jl h(s) dg(s). U
(9.46)
Proof. Let H o ( x ) = f ~ h ( s ) d g ( s ) , u=inf{Ho(x):xEI}, v= sup{Ho(x):x E I}, c = !(u + v), and H = H o - c. (Note that in general the
9.2. Some Generalizations and Refinements
273
values of u, v need not be attained, the same is true for sUpu,vEI g h(s) dg(s)). Then
IIh II g =
1 H(x) = -2
x
x
t
Ih(s) dg(s) _!2 inf Ih(s) dg(s) +!2 Ih(s) dg(s) tel
a
I
a
a
t
1 - -2 sup tEl
h(s) dg(s)
a
x
=2! SUp teI
x
x
(I h(s) dg(s») +!2 inf (I h(s) dg(s») ::;!sup (I h(s) dg(s») 2 t el
t
t e!
t
t
Thus we have
I b
f(s)h(s) dg(s)
=-
a
II
I b
H(s) df(s) + H(b)f(b) - H(a)f(a),
Q;
b
I::; I b
f(s)h(s) dg(s)
a
IH(s)1 dVf(S)
+ ~II hllg (If(b)1 + If(a)I),
a
and (9.46) follows.
0
The following result is a simple modification of an inequality in Karamata (1949, p. 79):
Let h, g, hf,fg E L(A), and denote G(x) = f ~ g ( s d) A(S), H(x) = f ~ h(s) dA(S)(H(x) > 0 for all x E (a, b D. If f is a nonnegative, decreasing function on I such that f ~ h(s)f(s) dA(S)> 0, then
9.35. Theorem.
I I b
inf G(X)::; a < x ~ H(x) b
a
g(s)f(s) dA(S) ::;
b
sup G(x). H(x)
(9.47)
a-c.x zzb
h(s)f(s) dA(s)
a
Proof. Denote the terms on the left-hand side and right-hand side in (9.47) by u and v, respectively. Then
uH(x)::; G(x)::; vH(x) for x
E
[a, b)
274
9. General Linear Inequalities
and b
b
Jf(s)g(s)dA(S)=f(b)G(b) + JG(x)d(-f(s)) a
a b
~ v V ( b ) H ( bJ) H(x)d(-f(s))) + a b
=V
Jf(s)h(s) dA(S). a
Since f ~ f ( s ) h ( s ) d A ( S » Othe , follows. 0
right-hand
inequality
ill
(9.47)
Karamata gives a discrete analogue of (9.47), and an extension of that result is given by Simeunovic (see Mitrinovic, 1970, p. 223). In the following we give an integral analogue of Simeunovic's result (see also Pecaric and Savic, 1984): If the conditions of Theorem 9.35 are satisfied, h(s) > 0 for all s E I, and A is increasing, then b
J
g(s)f(s) dA(S) inf g(x) ~ inf G(x) ~ . : : . , a b - - - - asxsbh(x) a<xsb H(x) h(s)f(s) dA(S)
J
a
~
G(x) sup - a<xsbH(x)
g(x) sup - - . asxsbh(x)
~
(9.48)
We also give the following generalization of Abel's inequality: Let Xij (i = 1, ... , n, j = 1, ... ,m) be real numbers, and let a = {aiJ (i = 1, ... , n, j = 1, ... , m) be a nonnegative, decreasing (1, i)-convex sequence of real numbers. Then
9.36. Theorem.
n
all min Xij -s
m
L L Xijaij i ~ l
holds, where Xij = ~ ~ ~ 1 ~ ~ = X 1 rs '
j=l
~ all max x;
(9.49)
9.2. Some Generalizations and Refinements
275
Proof,
n-1
= anmXnm -
m-1
x.; !:i.a rm - s=l 2: x; !:i.a r=l 2:
1
2
n-1 :5 max Xij( a nm -
2:
r=l
m-1 !:i.a rm 1
n-I
ns +
2:
s=l
!:i.a ns + 2
m-1
2: 2:
r=l s=l
n-1 m-1
x; !:i.1, 1a.,
2: 2:!:i. «:
)
1,1
r=l s=l
= all maxXij. This establishes the second inquality in (9.49). The first inequality can be proved similarly. D
9.37. Remark. Integral analogues of this and of the next two theorems ~ can be proved similarly. In the next result (proved in Pecaric, 1979a), we shall adopt the notation in Theorem 9.10. 9.38. Theorem.
Let XiI' .. Xim (1:5 ik
:5
n, 1:5 k :5 m) be real numbers.
(a) For all nonnegative and decreasing n-tuples a (1:5 j:5 m), we have
all' .. amIminXst···sm:5 F(a
j , ••• ,
a m) :5 all' .. ami maxXSt"'sm' (9.50)
(b) If aj (1 :5 j :5 m) are monotonic n-tuples, then m
IF(a 1 ,
.•• ,
am)1 :5 max IXs!,,,sml
IT (Iajnl + lajn -
aj11)·
(9.51)
j ~ l
The following result is given in Pecaric, Mesihovic, and Milovanovic (1989): 9.39. Theorem. Let xij (i = 1, ... , N, j = 1, ... ,M) and F(a) be defined as in Theorem 9.12 (a), and let en,m = (i -ltU -1)m.
276
9. General Linear Inequalities
(a) If aij (i = 1, t1n , m aij 2: a (i = 1,
, N;j = 1, ,M) are real numbers such that ,N - n, j = 1, , M - m), then F(a)
a
2: - ' - I
n.m.
F(en,m)'
(9.52)
(b) If lt1n , m aij !::; A (i = 1, ... , N - n;j = 1, ... ,M - m), then A IF(a) I ::;F(en,m)' n!m!
(9.53)
Chapter 10 Orderings and Convexity-Preserving Transformations
10.1. Orderings of Convexity: Generalizations and Related Results Partial orderings of notions of convexity and related preservation properties play an important role in the theory of inequalities. In this section we discuss some useful results on this topic. For notational convenience, we shall express a sequence { a , } ~(defined for n = 0, 1, 2, . . .) simply as {a,}. We first observe the following result due to Ozeki (1968): Let { a , } ; be an increasing sequence, and let the sequences { B , } ; and {C,}; be defined by B, = (lln) C;='=,iaj and C, = (lln) Cy=n bi (bo = 1). Then
for n = 2 , 3 , . . . and C , r C , / 2 . Of course, the main results of Ozeki (1965, 1967, 1968, 1969, 1970, 1971, 1972) are for the sequence {A,}: where A, = l / n C;='=, a,. Ozeki (1972) proved that if the sequence {a,}: is k-convex, then {A,}; is also k-convex. His proof depends on the following identity (see also MitrinoviC, LackoviC, and StankoviC, 1979): (n
+ k)AkA, = (n - l)AkA,-l + Akan
for n = 2,3, . . . .
From this identity we can obtain the following inequality for k-convex sequences:
277
278
10. Orderings and Convexity-Preserving Transformations
For the case k = 2, Ozeki first considered this problem in 1965 and gave the following list of implications:
where the inequalities hold for every n E}( (the set of all positive integers). It should be pointed out that the implication ~ 2 l o an g 2= O=> ~ 2 a n2=0 was proved earlier by Montel (1928). 1 where p = On the other hand, let An(a, p) = (1/ Pn) ~ 7 = p.a., (PI, ... ,Pn) is a real n-tuple and P; = ~ 7 = Pi' 1 Then the following identity is valid: A k+ 1(a, p) - Ak(a, p)
=
:;+1
k
~ Pi(ak+1 -
k k+1 i=1
ai),
(10.1)
and it follows that if the sequence { a n } is ~ increasing, then for arbitrary weights Pi > 0 (i E}() the sequence {An(a, p)} is also increasing. This, of course, is a weighted version of Ozeki's result for k = 1.
10.1. Remarks. (a) A related result is the following (see Pecaric, 1980b): Let p be such that 0 < P; < P; (k = 1, ... , n - 1), and let a be an increasing n-tuple. Then (10.2) Integral analogues of these results are also valid. Note that an integral analogue of (10.2) is given by Lovera (1957) and Ozeki (1965) when the weights are positive. The special case in which the weights are 1 was considered by Mott (1963) (see also Mitrinovic, 1970, p. 9). (b) Note that the monotonicity property of the arithmetic mean stated above can be used to prove the monotonicity property of an arbitrary quasi-arithmetic mean (Bullen, Mitrinovic, and Vasic, 1987, p. 215), i.e., we have
where M: (u, v ) ~ ~ (-oo:s u < v:s 00) is a continuous and strictly monotonic function, u :S a, :S v, and Pi 2= 0 (i = 1, ... , n). 0
10.1. Orderings of Convexity
279
We also note that the generalization of Ozeki's result for k > 1 is not possible for arbitrary weights. To see this, let us consider the sequence {An} defined by (10.3) where a = {an} is a real sequence and p = {Pn} is a positive sequence, and observe that: 10.2. Theorem. If a is a k-convex sequence, then the sequence defined in (10.3) is k-convex iff the sequence p is given by
_ (u +n -1) ,
P« - Po
n
(10.4)
where Po and u are positive real numbers.
10.3. Remark. For k = 2, Theorem 10.2 is proved in Vasic, Kecic, Lackovic, and Mitrovic (1972). For general k, an attempt to prove this theorem was made by Lackovic and Simic (1974), and a proof can be 0 found in Toader (1988c). A result of Toader (1983), which is a modification of the result of Bruckner and Ostrow (1962) (see (1.24)) for sequences, deals with an ordering of convexity. In the following we give some further generalizations of that result. Let K be a class of convex sequences, a = {an}, S* be a class of starshaped sequences of a such that the sequence {(an+lao)/(n + I)} is increasing for n 2: O. Let S be a class of superadditive sequences satisfying a n+ m - an - am + ao 2: 0 for every n, m > 0, and let W be a class of weak-superadditive sequences, i.e., for every n we have a n+ 1 - an - al + ao 2: O. We say that the sequence a = {an} has the property "P" in the u-mean if the sequence AU = { A ~ }given in (10.3) and (10.4) has the property "P." We denote by MUK, MUS*, MUS, and MUW the sets of sequences which are convex, starshaped, superadditive, and weak-superadditive in u-mean, respectively. The following result is given in Toader (1983): If 0 < v < u, then we have K eMuK eMvKeS* eMuS* «u-s-, S* eS e W,
MUS* eMUS eMuW,
MVS* eMVSeMVW,
W eMuWeMVW.
Some more general results can also be found in Toader (1986a).
280
10. Orderings and Convexity-Preserving Transformations
Mocanu (1982) considered the weighted mean
Fg(x)
=
g ( ~ )Jg'(t)f(t) dt,
(10.5)
o
where g is a real-valued function such that g' exists. Toader (1986b) proved the following results: If the transformation (10.5) preserves the convexity (or the starshapedness, or the superadditivity), then the function g is of the form
u>o,
ki=O.
(10.6)
Denoting by F; the function in (10.5) with g given in (10.6), let MUK(b), MUS*(b), and MUS(b) denote the classes of functions f E C(b) with the property that the corresponding functions E, belong to K(b), S*(b), and S(b), respectively, where C(b), K(b), S*(b), and S(b) are the classes of continuous, convex, starshaped, and superadditive functions, respectively. It follows that if 0< v < U, then the following implications are true: K(b) c MUK(b) c MVK(b) c S*(b) c MUS*(b) c MVS*(b), S*(b) c S(b),
MUS*(b) c MUS(b),
MVS*(b) c MVS(b).
Note that (10.6) was also obtained by Lackovic (1975). Some similar results are given in Toader (1986a, 1988b). Lackovic (1975) also proved the following result: Let the function f be defined and continuous on [0, b] such that f(O) = 0, and consider the following conditions: (i) f is m-convex on [a, b], (ii) fis m-convex in mean, i.e., the function F(x) = (1/x) gf(t) dt (0 < X :5 b), where F(O) = 0, is m-convex on [0, b], (iii) the functionf(x)/x is convex of order m -1 on (0, b], (iv) fis superadditive of order m on [0, b] (see Remark 6.13(b», (v) f is superadditive of order m in mean, i.e., F is superadditive of order m on [0, b]. Then the following implications are valid: (i) => (ii) => (iii) => (iv) => (v). Partial orderings for sequences that are convex of higher order was also considered by Toader (1985c). He considered the ordering of order
10.1. Orderings of Convexity
281
three, and provided the following definitions: The sequence {an} is said to be: starshaped of order three if the sequence {(a n + ! convex of order two; (ii) superadditive of order three if
(i)
-
ao)/(n + I)} is
for every
m, n, P ;::: 0;
(iii) 2-starshaped of order three if it satisfies the relation: an + 3
-
ao:> a n + 2
n+3
-
at
n+1
f
or
:> 0 n e: .
Let us denote by K 3 , S;, and S ~ *the classes of convex, starshaped, and superadditive and 2-starshaped of order three sequences, respectively. Further, we denote by M UK3, MUS;, M US3, and M U S ~the * classes of sequences {an} with the pro('erty that { A ~ given } in (10.3) and (10.4) is in K3 , S;, S3' and S ~ * , respectively. If < U < v, then the following implications are true:
°
For results of higher order, see Toader (1986a). Finally, we give some generalizations of Theorem 10.2. Let (Pn,i) (i = 0, 1, ... , n; n = 0, 1,2, ... ) be a triangular matrix of real numbers, let A(a) = {An(a)} be the sequence defined as n
An(a) =
L Pn,n-IJh k=O
for
n = 0, 1, 2, ....
(10.7)
Ozeki (1967) obtained necessary conditions for a triangular matrix (Pn,i) to possess the following property: The sequence {An(a)} defined in (10.7) is convex for every convex sequence {an} (see also Mitrinovic, Lackovic, and Stankovic, 1979; Lupas , 1979; and Kotkowski and Waszak, 1978). The following is a generalization of Ozeki's result (see Lupas, 1979).
282
10. Orderings and Convexity-Preserving Transformations
10.4. Theorem.
Let An(a) be defined as in (10.7). Then the implication /:1r an;::=: 0::;> /:1rA n(a);::=: 0
(10.8)
is valid for every sequence {an} iff
u+ 1, j) = 0
/:1rxn
for
= 0, 1, ... , r -1;
j
n
= 0, 1,2, ...
and
(10.9) /:1rXn(r, i + r);::=: 0 for
i = 0, 1, ... , n;
n = 0, 1,2, ... ,
where Xn(m, k) =
for
{~~k
(n - k
+m -
1 - j)
m -1
LJ
J=O
. Pn,J for
n
(10.10)
n;::=:k.
Theorem 10.4 was obtained in Lupas (1979) by using the following interesting identity: /:1 rAn(a)
r-l
n
u-
= 2: /:1 jao/:1rx n + 1, j) + 2: /:1raj/:1rXn(r, j + r). j=O
j=O
(10.11) A generalization of Theorem 10.4 is given in Pecaric (1982g). By using (9.4), i.e., n
m-l
~Wiai = ~ o/:1
kao
(1k!
n
)
n
i ~i(k)wi + k ~ m/:1m ak_m x (
,±
1 (i - k (m - 1). i=k
where i(m) = i(i -1)· .. (i - m /:1 sAn(a)
+ m - l)(m-l)wi ) , (10.12)
+ 1), and (10.7), we have
n+s
= 2: (/:1
SqnU»aj
j=O
for every s,
(10.13)
where qn( ]") = {O Pn.n-j
for for
n<j n ;::=:j.
Thus from (10.12) and (10.13) we obtain n+s
m-l
/:1 SAn(a)
=
2:
k=O
/:1k ao(/:1sXn(k+1,k»+
L
k=m
/:1m ak_m(/:1sXn(m,k».
Choosing s = m = r we then obtain (10.11) from (10.14).
(10.14)
10.1. Orderings of Convexity
283
By using (10.14) and a similar argument we have (Pecaric, 1982g): 10.5. Theorem.
Let An(a) be defined as in (10.7). Then the implication
/1man 2= a:::} /1sAn(a)
2=
°
for
s
E
.N' (the set of all positive integers)
is valid for every sequence {an} iff /1sXn(k + 1, k) =
°
for
k
= 0, 1, ... , m -1;
n
= 0,1,2,
...
and /1sXn(m,k)2=O for
k=m, ... ,n+s;
n
= 0,1,2,
... ,
where Xn(m, k) is given (10.10).
10.6. Remark. Necessary and sufficient conditions for the inequality ~ 7 = wia o i 2= to hold for every m-convex sequence are given in Theorem 9.1; using that result and (10.13) we can also obtain Theorem 10.5. 0
°
The following theorem is also valid: 10.7. Theorem. Let a = {an} be a real sequence, and let An(a) be defined as in (10.7). If l/1manl:5 N for n = 0, 1,2, ... , and /1sXn(k+1,k)=0
for
n = 0,1,2, ... ,
k=0,1, ... ,m-1;
where Xn(m, k) is given in (10.10), then l/1sAn(a) 1 :5 N
n+s
2:
l/1sXn(m, k)l.
k=m
Proof.
This is an immediate consequence of (10.14).
0
10.8. Remarks. (a) Theorem 10.7 is a generalization of Ozeki's result (see Theorem 2 in Mitrinovic, Lackovic, and Stankovic, 1979): If An*( a ) = -1 - LJ~ ak n + 1 k=O
and
1/1k ajl :5M,
then
* 1/1k An(a)1 : 5M --. k
+1
A similar result is also given in Lupas (1983, 1985). (b) Further generalizations of the previous results are given in Milovanovic and Pecaric (1986) and Pecaric, Mesihovic, Milovanovic, and Stojanovic (1986) (see also Mesihovic, 1987).
284
10. Orderings and Convexity-Preserving Transformations
(c) Analogous results for p-monotonic and p, q-convex sequences are proved in Pecaric (1981d) and Milovanovic and Kocic (1989), respectively. (d) A result similar to Theorem 10.4 for continuous linear operators was given by Tzimbalario (1975) (see also the results given in Remarks 9.13 and 9.19(b)), and he gave necessary and sufficient conditions for the implication
f
e Cia«, Ul,""
u n ) ~ A f E q uu 1 o, · , .
· ,
un).
0
Ozeki (1967, Theorem 2) presented a theorem for logarithmically convex sequences, and it is analogous to Theorem 10.4. To describe his result we first introduce some notation: Let the sequences {Pn} and {rn} be strictly positive, and let
For a given sequence {an} let the sequence {an} be defined by an ==
poao + ... + Pnan
for
r;
n == 0, 1, ....
(10.15)
Then we have 10.9. Theorem (Ozeki, 1967). Assume that the sequences {Pn} and {rn} satisfy the conditions Qo == 0,
2Qn > 1 > Qn for qn
(1 - Qn_lQn)2
$
~ Qn
for
(10.16) n == 1, 2,
n == 1, 2,
4qn(1- Qn-l)(l - Qn) for
,
(10.17)
,
(10.18)
n == 1, 2, .. "
(10.19)
If {an} is a positive and logarithmically convex (written as log-convex) sequence, then the sequence {an}, defined in (10.15), is also positive and log-convex; in other words, the implication is valid.
Proof.
Let totl· .. tn == poao + ... + Pnan
for
n == 0, 1, ....
(10.20)
10.1. Orderings of Convexity
285
Then the sequence {tn } is well defined, and we immediately have tn > 0 for all n. Similarly, we have Pnan = totl ... tn-l(tn -1),
so that from p.a; > 0 we have t; > 1. Since by assumption an-lan+l holds, we have tn + l
~
qntn-l(tn - 1)2 1 + ..:c..:.....:..:.......::....:....:.:_----'-tn(tn-l - 1)
~ a ~
(10.21)
Using (10.15), the definition of the sequence {r,}, and (10.21), we then have
= C(tn+l -
tnQn)
~ c(qntn-l(tn - 1)2 + 1 - tnQ n) tn(tn-l - 1)
= CI/(qn, Q, tn-I, tn), where C and C l satisfy C
~0
and
Cl =
C
tn(tn-l - 1)
> 0 for n > 1,
and
(10.22) is a function of tn only when qn' Qn, tn- l are kept fixed. From (10.18) we have qntn-l - Qntn-l + Qn > O. Clearly the discriminant form of fUn) is
If D :s: 0, then it is immediate that 0n-l 0n+l - o ~ ~ 0; thus we consider only the case D > o. Since t.;.«> 1, we see that t n_ I ( I - 4qn(1- Qn» > 1
286
10. Orderings and Convexity-Preserving Transformations
and 1 - 4qn(1- Qn) > O. Thus the condition D > 0 implies 1 . 1 - 4qn(1- Qn)
(10.23)
~ - l >
To show that 0n-lOn+l - o ~2: 0 holds for all n, we proceed by induction. For n = 1, it follows by a direct verification that 000z -
ai = (poao)Z (-Q1t Z+ (1- 2Ql)t + 1- Ql +Pza z), rorz
where t 000z -
poao
= (Plal)/(poao) > O. Since C = (poaof/(rorz) > 0, we have
of = C(ql = C(ql 2:
z) Ql)tZ+ (1- 2Ql)t + (1- Ql) - qltZ+pza poao Ql)t Z+ (1- 2Ql)t + 1-
e. +pz(aoapoaoz; aD)
C«ql - Ql)t Z+ (1 - 2Ql)t + 1 - Ql) == Cfl(t)
(note that the last step is given incorrectly in Ozeki, 1967). The discriminant form of the polynomial ft(t) is Do = (1- 2Ql)Z - 4(1- Ql)(ql - Ql) = 1- 4ql(1- Ql)'
Applying (10.16) and (10.19) for n = 1, we find that Do ::5 0, i.e. ,fl(t) 2: O. Thus we have 000z - ai 2: O. Now let us assume that (10.24) for some n 2: 1 where C 2: 0 was defined earlier. By a direct verification we have f(Qn-ltn-l)
= tn-1«qn + (Qn-1Qn
Qn)Q~-lt~-l
+1-
2qn)Qn-l tn-l
+ (qn -
Qn-l»
= tn-1F(tn-l), and the discriminant form of the quadratic polynomial f(t) is D 1 = (1 - Qn-1Qnf - 4qn(1- Qn)(1 - Qn-l)'
From (10.19) we have D 1 ::5 0, i.e., f(Qn-ltn-l) 2: O.
(10.25)
Thus the assumption D > 0 implies that equation f(t) = 0 (where f is defined in (10.22» has two distinct real roots, a and {J, say. Moreover,
10.1. Orderings of Convexity
287
we have
a+f3 1 Qn-lln-l - -2- = 2« qn - Qn )i.., + Qn ) x (2Qn-l(qn - Q n ) l ~ - +l (2QnQn-l + 1- 2qn)ln-l -1)
= Cdiln-l), where Cz > O. For the quadratic trinomial jjtr) we have
Iz(O) = -1,
(10.26)
and by a direct calculation we find that
Iz(' -
4 q n ~ -1
Qn»)
= C 3(2Qn -
1)(Qn-l(2Qn - 1) - 1 + 4qn(1- Qn»,
(10.27)
where, from (10.17), 2Qn > 1 and C3 > O. From (10.19) we have
4 (l-'Q) ~(1- Qn_1Qn)Z qn n 1- Qn-l Thus from (10.27) we obtain
Iz(' _
4 q n ~ _1 Qn») ~ C
4(Qn_l)z(1-
Qn)Z
~0,
(10.28)
where C 4 > O. Combining (10.23), (10.25), (10.26), and (10.28), we then have (10.29) and from (10.24) it follows that In (10.25) and (10.29) we obtain
~ In-1Qn-l.
Consequently, from
Note that in Theorem 10.9 if we take r., = 1 and Po = PI = ... = p.; = 1 for all n = 0, 1, ... , then the assumptions (10.26)-(10.29) are satisfied and, from the log-convexity property of the sequence {an} the logconvexity property of the sequence {An} follows, where An is given by An = (lin) ~ 7 ~ a., 1
288
10. Orderings and Convexity-Preserving Transformations
Ozeki (1967) also obtained the following result: If a positive sequence {an} is log-convex, then the sequence {an} defined by for
n = 0, 1, ...
(10.30)
is also log-convex. Together with the sequence {an} let us consider another sequence {Sn} given by (10.31) It is clear that {an} is log-convex iff {Sn} is log-convex, and Ozeki's
(1967) proof is based on this idea.
10.2.
Various Results
Let {an} and {bn} be two given sequences. A result which general than (10.31) was given by Davenport and P6lya (1949):
10.10. Theorem.
IS
more
Let the sequence {wn} be defined by
(10.32) where {an} and {bn} are positive and log-convex. Then the sequence {wn}
is also positive and log-convex. Let the sequence {c n } be defined by n
c, = 2:
ak b n -
k1
(10.33)
k=O
which is the convolution of {an} and {bn}. Then (10.33) gives the coefficients of the expansion
and the following result is valid (Kalusa, 1928; Karamata, 1933;
10.2. Various Results
289
Davenport and P6lya, 1949; Jurkat, 1954; Lorentz, 1954; and Menon, 1969):
10.11. Theorem.
If {an} and {b n} are posuuie and logarithmically concave (written as log-concave) sequences, then their convolution {cn} defined in (10.33) is also positive and log-concave.
Note that if {an} and {bn} are positive and log-convex, then their convolution {cn } need not be log-convex. The following result is proved in Vinogradov (1975): Let {an} and {b n} be two nonnegative log-concave sequences such that ao - Aal 2:: 0 and b., - Ab1 2:: 0, where A 2:: O. Let the sequence {cn } be defined by n
c;
= 2: aib n-i i=O
n-l
A 2: ai+1b n-i for
n
2::
1,
i ~ O
Then {c.} is also log-concave. Ozeki (1969) also considered a sequence related to the convolution sequence {cn}; namely, for given {an} and {b n}, let {cn} be given by (10.34) Then the following theorems are valid:
10.12. Theorem. Let {an} and {bn} be positive and convex sequences. If al2::ao and b l2::b o, then the sequence {cn} defined in (10.34) is convex. In other words, if
i = 1, 2, ... ,
for
(10.35)
then ~ 2 C i _ 2:: l 0 for i = 1, 2, ....
The following theorem concerns log-convex sequences.
10.13. Theorem.
If {an} and {bn} satisfy the conditions bi-1b i + 1 2::
bf,
for
i
=
1, 2, ... ,
then the sequence {c.} defined in (10.34) also satisfies the condition Ci-1C i + 1 2::
cf
for
i = 1, 2, ....
(10.36)
290
10. Orderings and Convexity-Preserving Transformations
It is easy to prove that if {an} and {b n} satisfy the conditions of Theorem 10.12, then they are increasing. This fact follows from (10.35) by induction. The proof of Theorem 10.12, as given in Ozeki (1969), is very similar to that of Theorem 10.9. By a direct calculation we can verify that for the sequence {cn } the equality
L\2(n + I)c,
= (n + 1)L\2cn + 2L\cn+ 1
holds. This implies that if {an} and {b n} satisfy the conditions of Theorem 10.12, then not only is {c.} convex, but also their convolution sequence {cn } defined in (10.33) is convex. Some related problems were studied in Jurkat (1954). The proof of Theorem 10.13 given in Ozeki (1969) is also similar to that of Theorem 10.9. Note that the sequence {cn} defined in (10.34) can be written in the form c; = (l/(n + l»cn , where cn is given by (10.33). Upon applying this identity, the inequality in (10.36) becomes (see Mitrinovic, Lackovic, and Stankovic, 1979).
(i + 1)2 -
"(" 1 1
-
-2
+ 2 )Ci-1Ci+1;:::Ci .
f
or
"1 2
1=
,
, ... ,
which is a weaker result than log-convexity. Ozeki (1970) also gave some theorems related to coefficients of functions given in the form of a power series. In particular, the following result was proved. 10.14. Theorem.
For a given real sequence { P n } let ~ the sequence { q n } ~ be defined by the following equality
1+
k ~ lqkx k = (1- ~ 1Pkxk)
-1;
(10.37)
n = 2,3, . . ..
(10.38)
= 1, 2, ....
(10.39)
that is, let n-1
qn = Pn
+
L Pkqn-k
for
k ~ l
If
{ P n } is ~
positive and log-convex, then qn > 0
and
qnqn+2;::: q ~ + l for
n
The proof of this theorem, given in Ozeki (1970), is based on the following theorem, which can be found in the same paper. We note that the fact qn > 0 was already proved in Karamata (1933). Some similar (but more general) results were obtained by Jurkat (1954).
10.2. Various Results
10.15. Theorem. Let D; (n n X n matrix (a i) where
= 1, 2, ... )
aij = -1
denote the determinant of the j = i - 2,
for
291
and a ij = 0 for
j
< i - 2.
If and then (-ltD n 2= O(n = 1, 2, ... ).
The proof of this theorem by induction is given in Ozeki (1970). A result that is similar to Theorem 10.14 is proved in Ozeki (1971):
10.16. Theorem.
Let {a;}, {b;}, and {c.} be sequences of real numbers such that the following conditions are satisfied:
rr
n i=O
(x
~
+ aZi+l) = j-::O
rr n
(n +i 1) b.x
n+l-i
b o = 1,
,
(10.40)
n
(x
+ azi )
i ~ O
If a, > 0 and aiai+Z - af+l
=
L cjx
n
-
1
Co
,
(10.41)
= 1.
i ~ O
2= 0
(i
= 1, 2, ... ),
then b,
2= c,
(i
= 1, ...
, n).
The proof of Theorem 10.16 given in Ozeki involves a partial ordering k be two power series. They defined below: Let ~ ~ ~ aix" o and ~ ~ = bkx o are said to be partially ordered, denoted by ~ ~ ~ aix">» o ~ ~ ~ bix", o if ak 2= b k holds for k = 0, 1, 2, . . .. Ozeki (1968) proved the following results concerning this partial ordering:
10.17. Theorem. Assume that f(x) = ~ ~ ~ O P k X If k . the sequence {pd is positive and log-convex, then f(k-l)(x)f(k+l)(x) (f(k)(x»)Z (k - 1)! (k + 1)! » k ! for
_ k - 1,2, ... ,
(10.42)
where the derivatives f(m) are taken in the usual sense.
The proof of this theorem, as stated in Ozeki (1968), follows immediately by calculating the coefficient of .r" on the left-hand and the right-hand sides of (10.42).
292
10. Orderings and Convexity-Preserving Transformations
Ozeki (1971) also studied some properties of the partial ordering for polynomials (see also Mitrinovic, Lackovic, and Stankovic, 1979). Let (E, A, fl) be a probability space. For p E ~ let Dp,1' be the set of all functions f: E ~ ~ such that (i) f is measurable and nonnegative (or positive if p 2: 0), and (ii) < f fP du < 00 for p#:O and 0< flogfdu < 00 for p = 0. For f E Dp,1' let us define the LP -mean of f with respect to fl by
°
for p#:O, forp=O. If A denotes another probability measure on (E, A), and q
:5,
p, then we
denote the quotient of the respective means by (10.43)
for positive functions whose domains are the convex cone Dq,A n Dp,w Clausing (1983) proved that:
10.18. Theorem. domain
If q
:5,
1 :5, p, then
¢q,p,A,1'
Dq,p,A,1'
=
is quasiconvex in the whole
Dq,p,A,W
This result is a generalization of a result in Clausing (1982) which concerns the special case q = -1 and p = 1. Using that result Clausing (1982) obtained results in Kantorovich (1948) and Wilkins (1955). The following result can be found in Peetre and Persson (1988). Special cases of this result are treated in Pecaric and Beesack (1986), Capocelli and Tanja (1985), Daroczy (1964), Dresher (1953), Persson (1987), and Sharma and Autar (1973a, 1973b).
10.19. Theorem. Let F: ~ ' : - ~ ~+ be an increasing function, and let g: D ~ ~+ (D is an additive Abelian semigroup) be superadditve. (a) If F is convex and f: D ~ ~ , : - , is subadditive, F(O) = 0, then the function H(x) = g(x)F(f(x)/g(x» is subadditve. (b) If F is concave and f: D ~ ~':- is superadditve, then H (x) is superadditive. Let us assume that the function f is defined and continuous on [0,1]. Bernstein's polynomial Bn(x, f) of order n = 0, 1, ... of the function f is
10.2. Various Results
293
defined by Bn(x,f) =
~ O( ~ ) X k ( I - X r - k f ( ~ ) .
It is a well known fact that the sequence {Bn(x, f)} converges to f(x) uniformly as n ~00 under reasonable conditions on f A systematic study of Bernstein's polynomials of convex functions was first made by Popoviciu (1961) (see also Popoviciu, 1944, pp. 43-44). For example, it is known that Bernstein's polynomials of continuous m-convex functions are also m-convex functions, and similar results are valid for functions of several variables. Moreover, the following result is valid:
10.20. Theorem. A continuous function f: [0, 1] every n = 0, 1, ...
~IR
is convex iff for (10.44)
10.21. Remark. Inequality (10.44) was proved by Temple (1954), and the same result was also proved by Arama (1960). In fact, Arama proved the following result: For an arbitrary continuous function f and ;1, ;2, ;3 E[0, 1], we have
Theorem 10.20 was also proved by Moldovan (1962) under a condition 0 weaker than f E C 2[0, 1] (which was given by Kosmak, 1960). The following theorem is related to Theorem 10.20: 10.22. Theorem. A continuous function f: [0, 1] every n = 0, 1, ... f ( x ) ~ B n ( x , forevery f )
~IR
is convex iff for
XE[O, 1].
(10.45)
10.23. Remarks. (a) Inequality (10.45) was proved independently by Arama (1960) and P6lya and Schoenberg (1958), and Theorem 10.22 was also obtained by Moldovan (1962). (b) Inequalities (10.44) and (10.45) imply that the sequence {Bn(x,f)} is decreasing and converges to f from above, and Theorems 10.20 and 10.22 assert that these properties are valid only for convex functions.
294
10. Orderings and Convexity-Preserving Transformations
(c) The convexity property of the sequence {Bn(x, f)} was considered by Popoviciu (1961) and Arama and Ripianu (1961) (see also Mitrinovic, Lackovic, and Stankovic, 1979). (d) Let S denote the class of all star-shaped functions on [0,1]. Lupas (1972a) showed that
f
E
~Bn(x, f) E
S
S.
(e) Theorems 5.2 and 5.3 are similar to Theorems 10.20 and 10.22. 0 The following theorem was proved by Artin (1931) (see also Marshall and Olkin, 1979, p. 452): 10.24. Theorem. Let U be an open convex subset of ~ n , and let <jJ: Ux(a, b ) [~0, (0) satisfy (i) <jJ(x, z) is Borel-measureable in z for each fixed x, and (ii) log <jJ(x, z) is convex in x for every fixed z. If v is a measure on the Borel subsets of (a, b) such that <jJ(x, .) is v-integrable for every x E U, then b
ljJ(x) ==
J<jJ(x, z) dv(z)
(10.46)
a
is a log-convex function on U.
An important example is that ¢(x,z)=(<jJ(z)Y, where <jJ(z) is a positive function, and in this case the function b
A(X)=
J(<jJ(z)Y dv(z)
(10.47)
a
is log-convex. This is a special case of a result given in Remark 4.19(d). 10.25. Remark. Theorem 10.24 is equivalent to Holder's inequality (see Marshall and Olkin, 1979, p. 461). 0 Suppose that for every x E ~n and every convex subset A c ~m there exists an integral of the form fAf(x,y)dy==I(x,A). Then the following theorems are valid (Tomilenko, 1976): 10.26. Theorem. Let f(x, y) be a function of (n + m) variables, where x E ~ nand y E ~ m .Iffis a finite log-concave function on ~ n + and m A and
10.2. Various Results
B are convex subsets in
295
~ m , then
I(AXI+ (1- A)X2' AA + (1 - A)B) ~I(xl, A)'J(X2' B)l-;" (10.48)
where Xl' X2 E
~ n and
0 < A < 1.
10.27. Theorem. If f(x, y) is a finite log-concave function of (n + m) variables, where X E ~nand y E ~"', then y
I(x, y) is log-concave on
=
Jf(x, t) dt
(10.49)
~ n + m .
10.28. Remark. Theorem 10.26 is a generalization of a result of Prekopa (1973). For Prekopa's result and its applications in statistics, see Section 13.5. 0 In Bodin and Zalgaller (1968) (see also Mitrinovic, 1970, p. 309) the following result is given: '
10.29. Theorem. by
Let A be a negative semidefinite quadratic form given all' a22::; 0 and
alla22 - ai2 ~ o.
If D(m) is a parallelogram in the xy-plane, whose center is m, then the function p defined by p(m) =
JJ eA(x.
y
)
dx dy
D(m)
is a log-concave function of m. Abdel-Hameed and Proschan (1976) considered the transformation g(A) =
J rp(A, x)f(x) duix],
(10.50)
where f and rp are nonnegative Borel-measurable functions of nonnegative arguments, !l denotes the Lebesgue measure on [0, (0) or the
296
10. Orderings and Convexity-Preserving Transfonnations
counting measure on {O, 1, ... }, and the integral is assumed to exist. They showed that various geometric properties possessed by fare inherited by g under appropriate assumptions on cp. To describe their results we first observe some definitions and basic properties. The first definition concerns four geometric properties of a function.
10.30. Definition. Let f : [0, 00) (a) (b) (c) (d)
~[0,
00). We say that
° °
f is star-shaped if f(ax) ~ af(x) for every x 2= and ~ a ~ 1, f is superadditive if f(x + y) 2= f(x) + f(y) for every x 2= 0, Y 2= 0, fis root-increasing iffllX(x) is increasing in x >0, f is supermultiplicative if f(x + y) 2= f(x)f(y) for every x
2= 0,
Y 2= 0.
10.31. Theorem. The following elementary relationships among the geometric properties are valid:
~f
Proof.
Easy.
f star shaped
~et(x)
superadditive
~ef(x) supermultiplicative.
root increasing
0
10.32. Definition. Dual geometric properties may be defined by reversing the direction of the inequality in Definition 10.30(a), (b), and (d), and by replacing "increasing" by "decreasing" in (c). The dual geometric properties are called, respectively: (a') antistar shaped, (b') subadditive, (c') root-decreasing, and (d') submultiplicative. The relationships among (a'), (b'), (c'), and (d') in Definition 10.32 are analogous to those among (a), (b), (c), and (d) in Definition 10.30. We next define completely monotonic functions:
10.33. Definition. A nonnegative function f of a nonnegative argument is completely monotonic if it has derivatives of all orders and (-1),,!(k)(X) 2= for x 2= and k = 1, 2, ....
°
°
We shall need to define two more notions in order to state and prove the main results.
10.2. Various Results
297
10.34. Definition. Let (jJ(A, x) be defined on A x X, where A and X are ordered sets. Then (jJ(A, x) is said to be totally positive of order 2(TPz) if (jJ(A, x) ~0 for AE A, x E X, and (jJ(Al , Xl)
I(jJ(Az, Xl)
(jJ(A l, xz) (jJ(Az, xz)
I
~0
Totally positive functions of order 2 and of higher orders play an important role in analysis, statistics, inventory theory, reliability theory, and many other theoretical and applied fields.
10.35. Definition. A function (jJ(A, x) is said to obey the semigroup property if
where Il denotes the Lebesgue measure on [0, co) or the counting measure on {0,1,2, ... }, AE[O,CO) 'or alternatively, AE{0,1,2, ... } and XE [0, co).
10.36. Theorem.
(a) Let (jJ(A, x) be TP z , and assume that
JX(jJ(A, x) dll(X) = aA
for all
A> 0
(10.51)
holds for some a > O. Then f is star-shaped implies that g is star-shaped.
(b) Let (jJ(A, x) satisfy the semigroup property, and f (jJ(A, x) dll(X) == 1. Then f is superadditive implies that g is superadditive. (c) Let (jJ(A, x) satisfy the semigroup property. Then f is supermultiplicative implies that g is supermultiplicative. (d) (jJ(A, x) satisfy the semigroup property iff f is exponential implies that g is exponential. (e) Let (jJ(A, x) be TP z and satisfy the semigroup property. Then (e-1) f is root-increasing and Il is the Lebesgue measure imply that g is root-increasing. (e-2) f is root-increasing, Il is the counting measure, and for all A> O. lim i;Ho
J (jJ(A, x );X dll(X) == 0
imply that g is root-increasing.
for some
;0 E [-co, co)
298
10. Orderings and Convexity-Preserving Transformations
(f) Let @(A, x ) satisfy the semigroup property. Then f is completely monotonic implies that g is completely monotonic.
10.37.
Remark. Examples of kernels
@(A,
x ) satisfying (e-2) are:
(i) the Poisson kernel @(A, x ) = e-A(A"/x!),A 2 0 and x and 0 (ii) the binomial coefficients (t), A, x = 0, 1, . . . .
= 0,
1, . . . , ;
Proof of Theorem 10.36. (a) For each c > 0, g ( A ) - cA =
I
[
,'I
@(A, x ) f ( x ) - - x d p ( x ) .
Since f is star-shaped, then f ( x ) - ( c / a ) x changes sign at most once in 2 0, and if once, from - to By the variation diminishing property o f the TP, function @(A, x ) (Karlin, 1968, p. 21), it follows that g(A) - cA changes sign at most once, and if once, from - to +. Hence g must be star-shaped. (b) Write
+.
x
+ A*)
=
j
@(A1
+ A2
J
.If
(x) 4 4 x )
=I j @ ( L x
-Y)@(A,,Ylf(x)dp(Y)dCl(x) [by the semigroup property]
[since f is superadditive] [since
I
@(A, z ) d p ( z ) = I].
Thus g is superadditive. (c) Using (10.50), the semigroup property, and the supermultiplicativity o f f , we obtain
Thus g is supermultiplicative
10.2. Various Results
299
(d) Let rjJ(A, x) satisfy the semigroup property and f be exponential. Then by the same kind of argument as in (c), we obtain g(A] + Az) = g(A])g(Az) for all A] 2: 0 and Az 2: O. Since rjJ and f are measurable, it follows from Tonelli's theorem that g is measurable (Royden, 1968, p. 270), and thus g(A) must be exponential, as pointed out by Breiman (1968, p.305). Suppose now that (10.50) maps exponential functions into exponential functions. Take f(x) = e :", s 2: O. For each fixed A, consider the measure VA defined for every Borel set A explicitly by the relation vA(A) =
JrjJ(A, x) d!J(X). A
Define the Laplace transform of
VA
by
Then, by the well-known property of the Laplace transform, for every A] 2: 0 and Az 2: 0, we have that gAl(S)gA2(S) is the Laplace transform of the convolution measure vt. VA2; i.e.,
Since g is exponential in A by assumption, we have gAt(S)gA2(S)= gAt+A2(S); i.e.,
By the uniqueness of the Laplace transform (see Theorem 1a of Feller, 1971, p. 432), it follows that
i.e., rjJ satisfies the semigroup property. (e-1) We can assume that for each A, rjJ(A, x) is strictly positive on a set of positive Lebesgue measure; otherwise g(A) would be zero and we would have nothing to prove. Since f is root-increasing, it follows that for each fixed a, O::s: a < 00, f(x) - a" changes sign at most once in x 2: 0, and if once, from - to +.
300
10. Orderings and Convexity-Preserving Transformations
Also, by the previous result (d). f
changes sign at most once in ).. 2": 0, and if once, from - to conclude that g()..) is root-increasing.
+.
We
(e-2) The proof of (e-2) is similar to that of (e-1), with obvious modifications. (f) Result (f) follows from Theorem 12a of Widder (1946, p. 160) and (d) above. D
10.38. Remark. A dual theorem exists in which each geometric property is replaced by its dual property. Thus the geometric properties defined in Definition 10.32 are also preserved under the integral transformation (10.50). D In the following we give some similar results for means (note that a result of this type was already given in Remark 4.19(b». The following result is proved in Hardy, Littlewood, and P6lya (1934, 1952, pp. 85-88) and Bullen, Mitrinovic, and Vasic (1987, p. 253): 10.39. Theorem. Let a = (a l , . . . ,an), p = (PI' ... ,Pn), P; = r.7=lPi, and let f: ~ nX ~ n ~ ~ be a real-valued function. If f has continuous second order derivatives and is strictly increasing and strictly convex, then the quasi-arithmetic mean
is a convex function of a ifff' If" is concave. A simple consequence of this result is the following (Godunova and Cebaevskaja, 1971): 10.40. Theorem. Let f and t; satisfy the conditions in Theorem 10.39, ak > 0 (k = 1, ... , m); let b, be positive n-tuples and Zk (k = 1, ... , m)
10.2. Various Results
301
be real n-tuples. Then the function
is convex and Sex) ~ f ( I : k ~ akAn(xZk> l bd) holds, where An(xzk> b k ) is the weighted arithmetic mean of the n-tuple XZk with weight vector b k . Let a and p be two positive n-tuples, and let f be a continuous and strictly monotonic function that is positive for all positive x and tends to 00 either as x ~0 or as x ~00. We write (10.52) If Pi ~ 1 (i = 1, ... ,n), we write In(a, p) instead. Of course, in the case P; = 1 we have a quasiarithmetic mean, i.e., In(a, p) == fn(a, p).
10.41. Theorem. Let f have continuous second derivatives and be strictly monotonic and convex.
r.r:
(a) If It!' is a convex function, i.e., if is decreasing, then In(a, p) is a convex function of a. (b) A necessary and sufficient condition that lea, p) is a convex function of a is that the function f is of the form (ax + b > 0, c> 1), or
eax + b •
na
10.42. Remark. The result in Theorem 1O.41(a) is proved in Vasic and Pecaric (1979a), and for Pi == 1 we obtain a result in Hardy, Littlewood, and P6lya (1934, 1952, pp. 85-88), where the result in Theorem 1O.41(b) is also proved. 0 In the following we give some similar results with symmetric functions and means. Let a be a positive n-tuple and k an integer satisfying 1 -s k :S: n. Then the kth elementary symmetric function of a is defined by
e ~ k J ( a= ) ~ ) a ~ l . . . a ~ n(= G ) p ~ k l ( a ) ) ,
(10.53)
where S(A) = {J.:Ai=O or 1 and I:7=lAi=k}, e ~ O ] ( a ) = p ~ O l ( a and ) = l , p ~ k l ( a is ) the kth symmetric mean of a. It is important to note that the
302
10. Orderings and Convexity-Preserving Transformations
symmetric functions and means can be generated as the following: (10.54)
or equivalently, (10.55)
10.43. Theorem. (a) If a is a positive n-tuple, then the sequence { p ~ k l } k : is ~ log-concave. (b) If a is a positive and log-convex sequence, then P ~ " . ! . 2 P ~ k l ~ ( p ~ k l l ) 2 for
1:s k :s n - 2.
(10.56)
(c) If r and v are integers such that 1:s r s; n - 1, O:s v:s k - 1, then ( ~ve!;-vl
?
~ ( ~ v e ! ; - v - 1 ) v(e!;-v+l». ~
(10.57)
10.44. Remark. Theorem 1O.43(a) is a old result (see Bullen, Mitrinovic, and Vasic, 1987, pp. 285-88), (b) is proved in Ozeki (1972) as a consequence of Theorem 10.9, and (c) can be found in Mitrinovic (1967) (see also Bullen, Mitrinovic, and Vasic, 1987, pp. 295-96). 0 Let a again be a positive n-tuple, k be an integer such that 1 :s k :s n, and .N* = {O, 1,2, ... }. Then the kth complete symmetric function of a is defined by
c ~ k l ( a =) ~ ) a ~ l ... a ~ n( = (n +: - 1 ) q ~ k l ( a » ) ,
(10.58)
where S(I.) = {I.:AiE.N*, I : 7 ~ l A i = k } c , ~ o J ( a ) = q ~ O l ( a ) and = l , q ~ k J ( a )is the kth complete symmetric mean of a. The complete symmetric functions can be generated similarly, i.e., (10.59)
10.45. Theorem. (a) If a is a positive n-tuple, then the sequence { q ~ k l } is log-convex. (b) If the sequence {ai } is log-convex, then (10.60)
10.2. Various Results
303
10.46. Remarks. (a) In Hardy, Littlewood, and P6lya (1934, 1952, p. 164) it is noted that Theorem 10.45(a) is due to Schur. This inequality has been cited in many papers (see Mitrinovic, Lackovic, and Stankovic, 1979, and the references given therein). Theorem 1O.45(b) was proved by Ozeki (1967) as a consequence of Theorem 10.10. (b) For some further generalizations of symmetric means and of Theorems 1O.43(a) and 1O.44(a), see Bullen, Mitrinovic, and Vasic (1987, 0 pp. 317-30). Ozeki (1973) proved the following result: Let Ak> Bi , C; (1 < k s; n) be defined as in Remark 6.18. Then the following inequalities are valid:
10.47. Theorem.
A'-l
+ A'+l 2: 2A, (n 2: r + 1),
(10.61) (10.62)
C,-l + C,+l
2:
2C,
(n
2:
r
+ 1).
(10.63)
Note that Theorem 10.47 is a simple consequence of Theorem 3.30. McLeod (1958/59) and Bullen and Marcus (1961) proved the following theorem as a generalization of an inequality of Marcus and Lopes (1957):
10.48. Theorem.
Let rand s (1 ::s; r ::s; s ::s; n) be integers.
is a concave function of a. 10.49. Remarks. (a) By assuming that C(a) = ( c ~ ] ( a ) / c ~ - p l ( a ) ) l(1::s; Ip p::S; r) is a convex function of a, McLeod (1958/59) proved his own conjecture for p = r. In Baston (1978) this conjecture was proved for p=r-l.
(b) A similar result for the well-known Dresher Inequality was proved by Godunova (1967a) (see Section 4.3). She proved this result by using Theorem 10.39 and the following result: Let A and B be sets in two linear spaces LA and L B , let x = Sea) and y = T(b) be real-valued functions which transform A and B into R, and Ry , respectively. Assume that x = Sea) is concave (convex) on A and y = T(b) is convex (concave) on
304
10. Orderings and Convexity-Preserving Transformations
B; and that M(x, y) is a concave (convex) function of two real variables,
defined on R;
X
R y, and is increasing in x when y is kept fixed. Then
M(S(a), T(b)) is concave (convex) on AxB. If S(a)=a or T(b)=b, then the monotonicity condition for M(x, y) in x or y is not necessary.
(c) In the same paper Godunova (1967a) proved the following result: ,Xn-I) is a concave (convex) function of n -1 variables for ,Xn-I ~0, then, for Xn > 0,
If f(xI' XI ~0,
is a concave (convex) function of (XI' ... ,xn ) . (d) Of course, Theorem 10.48 and Dresher's inequality are related to the well-known Minkowski Inequality. For many other related results, see Bullen, Mitrinovic, and Vasic (1987, especially pp. 267-268, 309, D 323-324, 330), and Pales (1982). Let LrCx, y) = (x r+ 1 + yr+I)/(x r + yr), then the following result is valid (Alzer, 1988). 10.50. Theorem. Let X and y be two positive real numbers such that X y, then the function L(r) = Lr(x, y) is strictly convex in ~_, strictly concave in ~+, strictly log-convex in (-00, -1/2], and strictly logconcave in [-1/2, +(0).
*"
Proof.
From L"(r)
= (xy)'(log(x/y))2(y -x)(xr -
we have L"(r) > 0 for r fer) = log Lr(x, y). Then r(r)
yr)/(x r + yr)3,
< 0 and L"(r) < 0 for r > O. Similarly, let
= (xy)'(log(x/y)?(y -x)(X2r+ l
_
y2r+I)/«x r + yr)(x r+ 1 + yr+l)f
holds. Thus r(r) > 0 for r < -1/2, and r(r) < 0 for r> -1/2. For arbitrary but fixed x, y (x F,.(x, y) = (r/(r
D
*" y) let us define
+ 1))(xr+ 1 -
F'o(x, y) = (x - y)/(logx -logy),
yr+I)/(x r - yr)
for
r ='= 0, -1,
F_ 1(x, y) =xy(logx -logy)/(x - y).
10.2. Various Results
305
(Note that Lr(x, y) = F,.(x 2, y2)1F,.(x, y).) Then the following results holds (Alzer, 1989b): 10.51. Theorem. The function F(r) = F,.(x, y) (x =1= y) is strictly logconvex in (-00, -1/2] and strictly log-concave in [-1/2, +(0). A similar result is also given in Alzer (1989b): Let
Then we have 10.52. Theorem. Let x, y, u, and v be positive real numbers such that max(x, y)/min(x, y) > max(u, v)/min(u, v). Then the functions SlIlx, y)/SlIr(u, v) is strictly convex for r E IR+.
10.53. Remark. There exist many other results which can be included in this section. See, for example, Lupas and Muller (1967,1970), Ibragimovand Gadziev (1970), Wood (1971), and Ross (1978,1980) (see also Riekstyn's (1986, pp. 22, 25-26). D
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Chapter 11 Convex Functions and Geometric Inequalities
In this chapter we give some results concerning convex functions and geometric inequalities, mainly from Mitrinovic, Pecaric, Tanasescu, and Volenec (1988) and Tanasescu (1989). Note that the recent book of Mitrinovic, Pecaric, and Volenec (1988) contains a chapter with the same title, and many useful applications of convex functions to geometric inequalities are also given there. The theory of majorization is closely related to inequalities based on convex functions; it was treated comprehensively by Marshall and Olkin (1979), and will be reviewed in Chapter 12. Some recent related results concerning majorization and geometric inequalities can be found in Mitrinovic, Pecaric, Tanasescu, and Volenec (1988), and results in Tanasescu (1990) concern the concavity property of some hyperbolic forms. Those results can provide an answer to some geometric problems and their generalizations, and will be treated in this chapter.
11.1.
Old and New Results via Majorization Theory
11.1. 1. A Partial Ordering of Triangles
Let il(s) denote the set of all metrically distinct triangles with given semi-perimeter s > 0 (degeneracy allowed). An irredundant abstract representation of ~ ( s ) is immediate: il(s) = {T = (x, y, z): s
2:
x
2: Y 2: Z 2:
307
0,
X
+Y + z
=
2s}.
308
11. Convex Functions and Geometric Inequalities
Of course, a vector T = (x, y, z) uniquely determines a triangle with (ordered) sides x ~y ~ z, thus for convenience we shall use "T = (x,y,z)" to mean a triangle, where x ~ y ~ are z the lengths of the triangle T.
11.1. Definition. The set of triangles ~ ( s ) is a partially ordered set (denoted by p.o. set) with the partially ordering relation T=(x,y,z)-
iff x:Sx' and
z ze z "; (11.1)
that is, the vector Tis majorized by the vector T' (see Definition 12.1). Clearly, ( ~ ( s ) ,-c) has a "1" and a "0"; that is, letting T 1 = (s, s, 0) and To = ('ls13, 'ls13, 'ls13), we have To -< T <, T 1 for every T E ~ ( s ) . The most important sup-p.o. sets are the chains, i.e., totally (linearly) ordered sub-p.o. sets. (Here we use the language of ordered structures.) As a chain is a special kind of interval, we may abuse the notation a little and write L = [T', Til], which means that T', Til E ~ ( s ) , T' -< Til, are the extreme elements of the chain L. In fact, a chain in ~ ( s ) is a one-free-parameter family of triangles. (a) Apart from To and T 1 , we distinguish the following elements in (see Fig. 11.2):
~ ( s)
Tz = (\12 - 1)(2,2, \12 - l)s,
T3 = (\12 - 1)(2,
\12, W)s,
T= ( 1 , ~ , ~ ) s . 4
(b) Distinguished chains: (i) L 1 = {(x, x, 2s - 2x):x E [2(W -l)s, s]),
(ii) (iii) (iv) (v) (vi)
L z = {(x, x, 2s - 2x):x E [2s13, 2(\12 -l)s]), L 3 = {(x, s -x/2, s -x/2):x E [2s13, 2(\12 -l)s]), L 4 = {(x, S - x12, s - x/2):x E [2(\12 - l)s, s]), L s={(s,sI2+t,sI2-t):tE[0,sI2]}, and L 6 = {(x, S - xl2 + (x Z/4 + sx - SZ)lIZ, S - xl2 - (x z/4 + sx x E [2(W -l)s, s]).
(c) Distinguished sub-p.o. sets: (i) (ii)
~ a ( s ) : properly ~ a ( s )= ~ a ( s )U
acute triangles, L 6 : nonobtuse triangles; To -< T -< T 1 ,
SZ)1!z:
11.1. Old and N e w Results via Majorization Theory
:
Figure 11.1
X
Figure 11.2
309
310
11. Convex Functions and Geometric Inequalities
(iii) L\o(s): properly obtuse triangles, (iv) L\o(s) = L\o(s) U L s U L 6 : nonacute triangles; T 3 < T < T 1 , (v) L 6 = [T3 , Ttl: right (angled) triangles, L 6 \ {T1 } : properly right triangles, (vi) L 1 U t., U L 3 U L 4 : isosceles triangles, L 1 U t., U L 3 U L 4 \ {T4, TI}: nondegenerate isosceles, (vii)L s: degenerate triangles. In the diagram of the p.o. set (L\(s), <) given in Fig. 11.1, we can easily "read" any particular chain and represent it graphically by an oriented path. Apart from the above described chains L 1 , ••• , L6 , of special interest are the level lines, i.e., chains of triangles with maximal side of constant length. Through each T E L\(s) "passes" a unique level line, i.e.,
LT = {(XT,y, z)}, T=(XT,YT,ZT)' In the diagram in Fig. 11.1, L T appears symbolically as a line "parallel" to Ls , and this represenation is suggestive enough and plainly justified. But it is interesting to notice that any level line is actually a straight line parallel to T 1T4 in the geometric model of L\(s) in 1R 3 (see Fig. 11.2). In fact, this model is simply the graphic representation of the vectors T = (x, y, z) E L\(s) on a tridimensional Euclidean space and consists of the right triangle T 1T4To , where T 1 = (s, s, 0), To = (lsI3, ls13, lsI3), and T 4 = (s, s12, sI2). The plane x = XT cuts T 1T4To along a segment parallel to T 1T4 , which is precisely the representation of LT' The ordering on a level line is indicated by the arrow (see Fig. 11.1). On the other hand, L\T1T4T3 is a compact space topologized relative to the standard Euclidean topology of 1R 3 on T 1T4T3 . This makes significant the later remark that, geometrically speaking, the bounds at the extreme points, or boundary points, for continuous functionals on T 1T4T3 are the best. This is so because L 1 , L z, L 3 , L 6 , L 4 , L, actually belong to the topologic closure of L\a(s) and L\o(s), respectively. 11.1.2.
Schur-Convex and Schur-Concave Functionals
The classic definition of Schur-convex (concave) functionals and the classic results also hold for (L\(s), <); e.g., using Schur's characterization theorem (1923), we can easily show that F = (s(s - x)(s - y)(s -
Z»l/Z
(x, y, z are the sides),
11.1. Old and New Results via Majorization Theory
311
and r = Fs- 1 are Schur-concave on the whole set Ll(s), strongly Schurconcave on L 3 U L 4 , and vanish on L«, Thus the maximal points on Llo(s) and Lla(s) are given uniquely by T 3 and To, respectively. But the circumradius R
= xyz/4F = xyz/4(s(s - x )(s - y)(s -
Z))1I2
is Schur-convex only on Lla(S) (the value at T 1 is defined by continuity). It is interesting to note that on Llo(s)\Ls R is neither Schur-convex nor Schur-concave; although it is strictly decreasing on the intersection of each level line within the domain, and strictly increasing on L 4 and L 6 • Indeed, these properties are simple consequences of elementary calculations performed on the real-valued one-variable functions. It follows that R(T) ~R(T3 ) holds on Llo(s)\Ls, i.e., R ~ s ( v ' -2 1)
and R(T)
(11.2)
on the set {T3},
on Llis), i.e.,
~ R ( T o R(T) ) , =:;R(T 1 )
2 R ~ 3 0 s on the set {To}, R =:;s/2
(11.3)
(11.4)
on {T 1 } .
From the previous discussion concerning F and r, we have F(T 1) -s F(T) =:; F(T o)
and
F(T 1 ) =:; F(T) =:; F(T 3 )
r(T 1) =:; r(T) =:; r(To)
and
r(T 1) -s r(T)
=:; r(T3 )
on
Llis),
on Llo(s).
Consequently we have
y'3
r =:; - s 9
(11.5)
on Lla(S) or {To},
r =:; (3 - 2v'2)s
y'3
on Llo(S) or {T3 },
(11.6)
-
F =:; 9 S2 on Lla(S) or {To}, F =:; (3 - 2v'2)S2
on Llo(S) or {T3}'
It is straightforward to see that the functional 4Rrs Schur-concave (in (x, y, z I). Thus we have 2s 2 Rr=:;27
(11.7)
on Llis)
or {To},
(11.8)
= xyz is
strictly
(11.9)
312
11. Convex Functions and Geometric Inequalities
and (the values on L s are defined by continuity): Rr ~ (50 -7)S2 on L\o(s) or {T3 } .
(11.10)
To give another example, consider the functional f(T) = f(x, y, z) = LXy==xy + xz + yz, which is strongly Schur-concave on L\(s). We have f(T1 )
~ f ( T )~ f ( T o )
and
f(T1)
~ f ( T )~ f ( T 3 )
on L\o(s).
Consequently we obtain the following inequalities: S2
S2
4 S2 3
~Lxy ~-
on L\a(s)
~LXy ~ 2(40 - 5)S2
g(x, y, z)
or {TI , To}
(11.11)
on L\o(s) or {T I , T 3 } .
= (LX2)/(LXY)= 4s2/(LxY)-
2,
(11.11) and (11.12) yield Groenman's inequalities: 1 ~ (Lx 2)/(Lxy)::;'2 on L\is) or {To, T ( 8 0 - 4 ) / 7 ~ ( L X 2 ) / ( L xonL\o(s) y ) ~ 2
(11.12)
I },
or {T3,T1} .
(11.13) (11.14)
Suppose that a certain functional f (on L\(s» can be written in the form f(T)=f(x,y,z)= CP(s,x,y, z)=cP (
X
+ 2y + z ,x,y,Z. )
Then, for verifying the Schur's conditions, we need to evaluate (X_ y)( of _ of) = (x _ y)(! ocp + ocp _! ocp _ oCP) ox oy 2 os ox 2 os oy = (x _ y)(ocp _ oCP), ox oy and f is Schur-convex (Schur-concave) iff (x, y, z) and
cP is permutation invariant in
(X_ y )( 04> _ oCP ) ! 2=0 ox oy s=(x+y+z)/2
(~O)
(11.15)
on I R ~ ,where the partial derivatives are taken by treating s as a constant, and we let s = (x + y + z)/2 only afterward (if necessary) to determine the sign in (11.15).
11.1. Old and New Results via Majorization Theory
313
Another simplification arises if the function f can be written in the form
f(x, y, z) = g(u, v, w), whereu=s-x, v=s-y, andw=s-z. Since of ox
og OU
og ov
og ow'
2-=--+-+-
2 of = og _ og
oy
ou
ov
+ og for u - x = y ow
- x,
we find
(x _ y)( of _ of) = (u _ v)(Og _ Og). ox oy ou ov Thus f is Schur-convex (Schur-concave) on ~ ~ iff g is Schur-convex (Schur-concave) . In the following we provide some examples for the purpose of illustration. Since the function g(u, v, w) = VIi + VV + YW is Schurconcave, we have, for LVs - x defined similarly, y'S -s LYs
-.x; ~ V3S
on ilaCs) or {T 1 , To}
y'S ~ '2:.Ys - x ~ (0 - 1 + 2Y0 - 1)y'S
on ilo(s) or {T 1 , T 3 }
Furthermore, the function g(u, v, w) = u- 1 + V-I Thus
1 s-x
(11.16) (11.17')
+ w-1 is Schur-convex.
9 on ilaCs) \ {T 1 } or {To}, s
' 2 : . - - ~ -
(11.17) (11.18)
Note that in many examples f(To) lies surprisingly close to f(T3 ) . However, we should be cautioned not to conclude that this is always the case, as shown in the prior example. We conclude this section by considering a classic problem of finding max f(T),
where f(T) = min{lx - yl, Iy - z], [z -xl}·
T E ~ ( S )
Although this is often encountered as an extreme value problem in real numbers or in the class of (R, r)-triangles, or R-triangles, it is most suitably formulated as a maximization problem in il(s). The function f vanishes on L 1 U L; U L 3 U L 4 , and it is neither Schur-convex nor
314
11. Convex Functions and Geometric Inequalities
Schur-concave on ~ ( s ) . However, on every level line L T , first it is increasing, then decreasing, always having its maximum value at y = 2s/3, attainable only when x - y = y - z. Indeed, on ~ ( s ) f can be simplified as f(T) = min{x - y, y - z} and, on each LT , x - Y is Schurconcave, while y - z and x - z are each Schur-convex. Thus Maxf = (x - z )/2 on each level line, and x - z is Schur-convex on the whole set ~ ( s ) . It then follows that Max minj]» - YI, Iy - z], [z - xl} = s/3,
(11.19)
attained uniquely at T= (s, 2s/3, s/3) (an old but beautiful result). Moreover, for T E ~ a ( s ) we have Maxf(T) = 5/6, attained uniquely at T = (5/6)(5, 4, 3), a nice right triangle. 11.2.
Concavity via Hyperbolic Forms
11.2. Definition. A real n-ary form is a homogeneous polynomial in n indeterminates with real coefficients. A real form P of degree m is said to be hyperbolic with respect to some a E IRn (or a-hyperbolic) if the equation in t E IR P(ta + x) = 0
(11.20)
has previsely m real roots for each given real vector x E IRn. Let us denote these roots by tl(a, x):s; ... :s; tm(a, x) (for fixed a they are all continuous in x). Let 'Jtp be the set of vectors a E IR n such that Pis a-hyperbolic. Note that for every a E 'Jtp the function Ha(x) = maXlsksm tk(a, x) and ha(x) = minlsksm tk(a, x) are continuous, positive, and homogeneous on IR n with H a ( -x) = -ha(x). Also note that the open cone CCP, a) = {b E IR n: Ha(b) < O} is the desired neighborhood of a in 'Jtp that is an open subset of IRn. Moreover, this cone is convex. (More results on hyperbolic form can be found in Garding, 1959, and Tanasescu, 1990). Throughout this section it will be assumed P is a hyperbolic form of degree m ~ 2 and LP = <jJ, where LP is the set of all common zeros of the partial derivatives of P of order m - 1. Furthermore, let us assume that the cone C = CCP, a) £; 'Jtp satisfies a E IR':-+ and pea) > 0 (hence P>O on C). Now let K be a convex cone included in the nonnegative orthant IR':-. For every s > 0 let K denote the set of all x' = { X : } 7 ~ 1such that x = { X ; } 7 ~ E1 K. Of course, under the prior assumptions we have K S £; S
11.2. Concavity via Hyperbolic Forms ~ ~ . Take
315
p = lIs and define on K the positively homogeneous function
1';, by (11.21)
Clearly, we have tacitly assumed that KlIp ~ C = C(P, a). In the following theorem P, and ~ j denote partial derivatives of the first and second order, respectively.
11.3. Theorem. Let K some real number p 2:: 1.
~ ~ :
be a convex cone such that Kl1p
~C
for
(a) If P; 2:: 0 on Kl/p n {Xi> O} for every i = 1, ... , n, then the function 1';, defined in (11.21) is strongly concave on K. (b) If ~ j 2:: 0 on KlIp n {Xi> 0, Xj > O} for 1:s; i <j:s; nand p < m, then the same conclusion as in (a) holds.
11.4. Theorem. If 1';, is strongly concave on some convex cone K c ~ : , then it is strongly concave on cl(K)+ (the closure of K) except for the trivial case 1';,(x) = 1';,(y) = 1';,(x + y) = 0 for x, y E cl(K). The following result is a consequence of Theorems 11.3 and 11.4.
11.5. Theorem. If T I = (Xl, xz, X3) and T z = (YI, Yz, Y3) are two triangles with areas Al and A z, respectively, then for each p 2:: 1 there exists another triangle with sides (xf + yf)lIP , i = 1, 2, 3, and with area A, such that: (a) If 1 :s;p :s; 4, then (11.22)
and equality holds iff (i) the triangles are similar or (ii) they are both degenerate, with the longest side on the same position (in (ii) it occurs only for p = 1); (b) if both triangles are nonobtuse, then the inequality in (11.22) holds for all p 2:: 1, and equality holds iffthe triangles are similar.
11.6. Remarks. (a) Theorem 11.5 was first stated as a conjecture by Oppenheim (1971), and later proved by him (Oppenheim, 1974) for p = 1, 2, 4 only (which is part (a». Carroll (1982) gave a complete proof for both parts of the theorem.
316
11. Convex Functions and Geometric Inequalities
(b) In fact, the inequality (11.22) is a consequence of Jensen's inequality for n = 2. Using the weighted Jensen's inequality, we can obtain known results for n triangles (see Mitrinovic and Pecaric, 1988a). (c) If a hyperbolic form P in Theorems 11.3 and 11.4 is also symmetric, then the function F;,(x) defined in (11.21) is also Schurconcave on K. This is a generalization of a related result in Mitrinovic and Pecaric (1988a). (Note that the results in their paper are given in Mitrinovic, Pecaric, and Volenec, 1988.) 0 Theorem 11.5 may be nicely generalized in an obvious manner by letting (for n 2= 2)
k= 1, ... , n,
P=Tt···Tn
and
Q = ToP.
Note that the forms P, Q are positive in IR':- whenever the Tk's are. Thus it seems natural to define C = {x E 1Il':-: P(x»O} = C(P, In)
n IR':- = C(Q, In) n IR':-.
where In = (1, ... , 1). This follows from the obvious fact that P, Q are In-hyperbolic and Tk(ln) > 0 for k = 0, 1, ... , n. Theorem 11.3(a) assures that F;" Gp are strongly concave on K p = CP for every p 2= 1, where
Consequently, the following theorem is valid.
11.7. Theorem.
(a) If 1:s p :s n, then
F;,(x + y) 2= Fp(x) + F;,(y)
for every x, y E cl(Kp),
(11.24)
and equality holds iffeither x, yare proportional, or p = 1, FI(x) = FI(y) = F1(x + y) = 0, and the largest component ofx, yare similarly placed. (b) If1:sp:sn+1, then Gp(x
+ y) 2= Gp(x) + Gp(y) for every x, y E cl(Kp),
(11.25)
and equality holds under the same conditions as in (a).
For n = 4, each point x = (Xl' Xz, X3' X4) can be considered as representing an inscribable quadrilateral of sides Xl,"" X4 with area Z A(XI' xz, X3, X4) = 2- (p (X)) lIZ, where P = T; T Z ~ 4 and x E C =
11.2. Concavity via Hyperbolic
FOnDS
317
C(P, 14 ) , Thus Theorem 11.6(a) yields a perfect analog of Theorem 11.5. This is precisely what the third theorem in Carroll (1982) says (also see Theorem 0 in Mitrinovic and Pecaric, 1988a). Theorems 11.3 and 11.4 give many other nongeometric applications. For example, Tanasescu (1989) used them to prove Minkowski's inequality, Bellman's inequality (the discrete case of Theorem 4.29), and a generalization of Theorem 10.48. A geometric implication of Theorem 10.48 is:
11.8. Theorem. If T 1 = (Xl, X2, X3) and T 2 = (Y1' Y2,Y3) are two arbitrary triangles, degenerate or not, with radii R 1, r1 and R 2, r2, respectively, then for every p ~ 1 there exists a triangle T with sides z, = (xf + yf)1/p for
i = 1,2,3,
and radii R, r such that
(11.26) Furthermore, equality holds iffthe triangles T 1 , T 2 (even if degenerate) are similar. .
11.9. Remark. Note that Remarks 11.6(b), (c) are also valid for Theorems 11.7 and 11.8. D
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Chapter l2
Convexity, Majorization, and SchurConvexity
In this chapter we describe some results on convexity, majorization, and Schur-convexity (Schur-concavity). The notion of majorization arose as a measure of the diversity of the components of an n-dimensional vector (an n-tuple) and is closely related to convexity. It is formally discussed in Hardy, Littlewood, and P6lya (1934, 1952) and is treated most comprehensively by Marshall and Olkin (1979). In this chapter we shall restrict our attention to results in majorization and Schur-convexity theory that directly involve convex functions. Most of the results are already given in Marshall and Olkin (1979); thus to avoid duplication of effort we refer to their book for most of the proofs.
12.1.
Majorization and Convex Functions
For fixed n
I2
let x=(x1,.
* *
>X,),
y = ( y , , ... ,y,)
(12.1)
. . . 2&,I, Y(1)5 Y ( 2 ) 5 . . S Y ( , )
(12.2)
denote two n-tuples. Let X [ l l ? X[2] 2 X(1) S X ( 2 ) 5
a
-
a
*
?X[n]
Y [ l ]2 Y [ 2 ] 2
9
SX(n),
*
(12.3)
be their ordered components.
121.. DeJinifion. y is said to majorize x (or x is said to be majorized by y ) , in symbols y > x, if m
m
i=l
i=l
2 x [ ; I ~ y[;l
holds for rn = 1, 2, . . . , n - 1
319
(12.4)
320
U. Convexity, Majorization, and Schur-Convexity
and n
n
2: Xi = i=l 2: Yi' i=l
(12.5)
Note that (12.4) is equivalent to n
2: i=n-m+l
n
XU)::5
2:
holds for
Yu)
m
= 1, 2, ... , n -
1.
(12.6)
i=n-m+l
This definition provides a partial ordering, namely, y > x implies that, for a fixed sum, the y;'s are more diverse than the x;'s. To illustrate this point, we see that (i) y > y always holds for y = (Y, ... ,y), where y = (lin) I:7=1 Yi' and (ii) ( I : 7 ~ Y 1 i, 0, ... , 0) > Y holds for all y such that Yi ~ 0 (i = 1, ... , n). This notion is closely related to convex functions as shown in the following theorem. 12.2. Theorem. Let I be an interval in such that Xi' YiE I (i = 1, ... ,n). Then n
~ ,
and let x, y be two n-tuples
n
2: cp(x;}::5 2: CP(Yi) i=l i ~ l
holds for every continuous convex function cp: I -
~
iff Y > x holds.
12.3. Remark. Theorem 12.2 is well-known as the majorization theorem, and a convenient reference for its proof is Marshall and Olkin (1979, p. 11). It is due to Hardy, Littlewood, and P6lya (1934, 1952, p. 75), and can also be found in Karamata (1932); for a discussion 0 concerning the matter of priority see Mitrinovic (1970, p. 169). The partial ordering of majorization defined in Definition 12.1 assumes that the sums of the components of x and yare the same. When this condition is replaced by a weaker one, we have the notions of weak submajorization and weak supermajorization (see, e.g., Marshall and Olkin, 1979, p. 10):
12.4. Definition. (a) y is said to weakly submajorize x, in symbols Y>wx, if (12.4) and n
n
;=1
;=1
2: Xi::5 2: Yi
(12.7)
12.1. Majorization and Convex Functions
321
hold. (b) Yis said to weakly supermajorize x, in symbols y>w x, if m
m
i=1
i=1
2: xU) ~ 2: Y(i)
for
m
= 1, 2, ... , n
- 1
(12.8)
and n
n
2: Xi ~ i=1 2: Yi i=1
(12.9)
hold. It is known that (see, e.g., Marshall and Olkin, 1979, p. 11, p. 22):
12.5. Fact. (a) Ify > x holds, then there exist a finite number of n-tuples Z1 , •.. , ZN such that y
= Z1 > Z2 > ... ZN-1 > ZN = x,
(12.10)
and that for all j, Zj and Zj+1 differ in two coordinates only.
(b) y > x holds iff there exists a doubly stochastic matrix Q = (qiJ (i.e., qij ~ 0 and Li qij = 1 for all j, l: j qij = 1 for all i) such that x = yQ.
12.6. Fact. (a) y >w x holds iff there exists an n-tuple Z such that y > Z and z e x (i.e., z, ~ x d o ir = 1, ... , n) hold. (b) y > W x holds iff there exists an n-tuple Z such that Z > x and Z ~ y. In view of Fact 12.5(a) we can prove Theorem 12.2 simply by proving it holds for n = 2. Similarly, by combining Theorem 12.2 and Facts 12.5(a) and 12.6 we can obtain (see e.g., Marshall and Olkin, 1979, p. 10):
12.7. Theorem. Let I be an interval in ~ , and let x, y be two n-tuples such that Xi, YiE I (i = 1, ... ,n). Then (a) n
n
2: cf>(Xi) :5 2: cf>(Yi) i=1
(12.11)
i ~ 1
holds for every continuous increasing convex function cf> iff Y> w x holds; and (b) the inequality in (12.11) holds for every continuous decreasing convex function cf> iff Y>W x holds.
12.8. Remark. Theorem 12.7 is due to Weyl (1949) and Tomic (1949). Weyl obtained the result by assuming Xi> 0 and Yi> 0 (i = 1, ... , n),
322
12. Convexity, Majorization, and Schnr-Convexity
whereas Tomic did not assume this condition. Earlier Polya (1947) proved Theorem 12.7 by using Theorem 12.2 for the special case I = IR, and a similar proof for an arbitrary interval is given in Mirsky (1959). In fact, Mirsky proved a more general result which includes Theorem 12.7 as a special case. 0 In the following we discuss related results for Wright-convex functions and for functions with increasing increments. In Theorems 12.9, 12.11, and 12.12 we assume that x, yare n-tuples such that Xi' Yi E I (i = 1, ... , n) for some interval I.c: IR.
12.9. Theorem. For k that Xk + Ck E I for all k.
= 2, ...
,n let Ck
= I:7,;:l
(Xi - Yi), and assume
(a) If Yk:s Xk+l for k
= 1, ...
, n - 1,
(12.12)
k
2: Xi;:::: 2: Yi i ~ 1
k
for
i=1
k = 1, ... , n - 1,
(12.13)
and n
n
2: Xi = i=1 2: Yi'
(12.14)
i ~ 1
then (12.11) holds for every Wright-convex function cf> :1- IR. Furthermore, (12.11) holds for every Wright-convex function cf> if the reverse of the inequalities in (12.12) and (12.13) hold.
(b) if (12.12) and (12.14) hold and the reverse of the inequality in (12.13) holds, then the reverse of the inequality in (12.11) holds for every Wright-convex function cf>: I -IR. Furthermore, the same is true if (12.13) and (12.14) hold and the reverse of the inequality in (12.12) holds.
Proof. The proof follows by changing X2k-l to x; and X2k to Yk (k = 1, ... , n) in Theorem 5.46 and the fact that z;:::: maxl05i05n {Xi' Yi}, where z is the value of X2m+l in (5.64). 0 12.10. Remark. The following result is a special case of Theorem 12.9: Assume that a l 2: a3;:::: ... ;:::: a 2n+l' a2k;:::: 0 (k = 1, ... , n), al, a2k+l E I,
12.1. Majorization and Convex Functions
ak + ak+l E I (k f/>(al
= 1, ... , 2n).
323
Then we have
+ a2) + ... + f/>(a2n-l + a2n) + f/>(a2n+l) ~ f/>(al) + f/>(a2 + a3) + ... + f/>(a2n + a2n+l)
for all Wright-convex functions f/>: I
0
~ ~ .
The following theorem is a weighted version of Theorem 12.2. It can be regarded as a generalization of the majorization theorem in Theorem 12.2 and is given in Fuchs (1947).
12.11. Theorem. Let x, y be two decreasing n-tuples, and let p = (PI' ... ,Pn) be a real n-tuple such that k
k
i=1
i=1
2- PiXi:=; 2- PiYi
for
k
n
n
i±1
i=1
= 1, ... , n -
1;
2- p.x, = 2- PiYi'
Then for every continuous convex function f/>: I n
n
i=1
i=1
(12.15)
(12.16) ~ ~ ,
we have
2- Pif/>(X;) :=; 2- Pif/>(Yi)'
(12.17)
Similarly, a weighted version of Theorem 12.9 is given in Bullen, Vasic, and Stankovic (1973):
12.12. Theorem. n-tuple. If k
Let x, y be two decreasing n-tuples, and p be a real k
2- p.x, :=; 2- PIYi i ~ 1
for
k
= 1, ... , n -
1, n
(12.18)
i=1
holds, then (12.17) holds for every continuous increasing convex function f/> :I ~ ~ . If x, yare increasing n-tuples and the reverse inequality in (12.18) holds, then (12.17) holds for every decreasing convex function f/> : I ~ ~ . Proof of Theorems 12.11 and 12.12. Without loss of generality, assume that Xi =1= Yi' and define d, = (f/>(Xi) - f/>(y;))/(x; - Y;) (i = 1, ... , n). Then
324
12. Convexity, Majorization, and Schur-Convexity
from (12.7) we have d,
n
n
~ di+1
for i:5 n - 1, and the proof follows from
n
2.: P;CP(Xi) - ;=1 2.: PiCP(Yi) = ;=1 2.: Pi(Xi ;=1
Yi)di n-I
= (Xn - Yn)dn +
2.:
(Xk
-
Yd(dk
-
dk+I),
k=1
12.13. Remarks. (a) In Mitrinovic (1970, p. 165), it is stated that (12.15) and (12.16) hold iff (12.17) holds. Imoru (1974) presented what he claimed was a proof for this statement, but Cheng (1977) and Pecaric (1980a) independently showed, by a counterexample, that (12.15) and (12.16) are sufficient, but not necessary, for (12.17) to hold. Furthermore, they showed that (12.15) and (12.16) become necessary (and (12.18) is necessary in Theorem 12.12) when the components of p are all nonnegative. (b) Theorem 12.11 can be used to prove a number of inequalities for convex functions, including Petrovic's inequality (see Remark 5.38(e» and the Jensen-Steffensen Inequality and its reverse inequality (see Peearic, 1981c). 0 The definition of majorization stated in Definition 12.1. involves the comparison of the diversity of the components of two n-tuples. In the following we state a similar definition for integrable functions. Let x(t), y(t) be real-valued functions defined on an interval [a, b] such that f ~ x ( t dt, ) f ~ Y ( td ) t both exist for all s E [a, b].
12.14. Definition. y(t) is said to majorize x(t), in symbols, y(t) > x(t), for t E [a, b], if they are decreasing in t E [a, b] and s
s
J x(t) dt:5 Jy(t) dt o
0
and equality in (12.19) holds for s
= b.
for s
E
[a, b],
(12.19)
12.1. Majorization and Convex Functions
325
An integral analog of Theorem 12.2 is the following: 12.15. Theorem. y(t) > x(t) for t [a,b] and b
f
[a, b] iff they are decreasing in
E
b
a
f
(12.20)
a
holds for every
An inequality that is related to the majorization theorem is given in Fan and Lorentz (1959) (see, e.g., Mitrinovic, 1970, p. 304, or Roberts and Varberg, 1973, pp. 157-58). In the following we state a more general form of that result (Pecaric, 1981a and 1981c). 12.16. Theorem. for (t; Ul, ... , un) k, His
Let H(t; Ul' ... , un) be a real-valued function defined E [a, b] X [al , btl X . . . X [an, b n] such that, for fixed
(i) a (1, I)-convex function of (Ui' uj) for 1:5 i, j:5 k and k + 1:5 i, j:5 n when the remaining variables are kept fixed; (ii) a (1, I)-concave function of (Ui' Uj) for 1:5 i s: k and k + 1:5 j :5 n; (iii) a (1, I)-concave function of (t, Ui) for 1:5 i z: k and a (1, I)-convex function of (t, uj) for k + 1 :5 j :5 n; (iv) a convex function of u, for 1 :5 i :5 k. Let Ii, gi : [a, b] ~[ai' bJ (i = 1, ... , n) be real-valued continuous functions which are decreasing for 1:5 i :5 k and increasing for k + 1 :5 i :5 n; and let G : [a, b] ~ ~ be a function of bounded variation.
(a) If x
f
x
Ii(t) dG(t):5
a
gi(t) dG(t)
for all x
E
[a, b]
1:5 i :5 k,
and
a
b
f
f
(12.21)
b
Ii(t) dG(t):5
x
f
gJt) dG(t)
for all x
E
[a, b]
and
k
+ 1:5 i :5 n,
x
f b
a
f
(12.22)
b
h(t) dG(t):5
a
gi(t) dG(t)
for all
1:5 i:5 n,
(12.23)
326
12. Convexity, Majorization, and Schur-Convexity
then b
b
JH(t;fI(t), ... ,fn(t» dG(t):::; JH(t;gl(t), . . . ,gn(t» dG(t). a
(12.24)
a
(b) If H satisfies (i)-(iv), is an increasing function of u, (1:::; i :::; n), and x
x
J/;(t) dG(t):::; J gi(t) dG(t) a
for all x
E
[a, b]
1:::;i :::; k,
and
a
b
(12.25)
b
J/;(t) dG(t):::; Jgi(t) dG(t)
for all x
E
[a, b]
and
+ 1:::; i :::; n,
k
x
x
(12.26) then (12.24) is also valid.
Proof. Since H is continuous, it can be uniformly approximated by Bernstein's polynomials. Furthermore, if H satisfies the conditions of Theorem 12.16, then the polynomials satisfy the conditions
a2 H
--:::;0 for
l:::;i:::;k
ataui
a2H aUi su, a2 H - - :::; 0
- - 2: 0 for for
aUi Bu,
and
a2 H
--2:0 for ataui
k+1:::;i:::;n,
1:::; i, j :::; k
and
k
+ 1 :::; i, j
1:::; i :::; k
and
k
+ 1 -s i :::; n;
:::; n,
which follows by repetitively applying the formula
-dxd 2: (n). . aix'(l- xt-'.= n 2:i ~ O (n -. 1) (ai+l n-l
n
i=O
l
.
..
a;)x'(l - xt-1 -
,.
l
Thus, without loss of generality, we can assume that the partial second derivatives of H exist and satisfy those conditions. Let us define ui(t, A)
= Agi(t) + (1 -
H(t;
U 1, . . . ,
A)/;{t) for' 1:::; i :::; n,
un) = H(t, u(t, A»,
b
F(A) =
J H(t, u(t, A» dG(t), a
A E [0,1]
12.1. Majorization and Convex Functions
Since u;(t, A) are decreasing in t for i = k + 1, ... , n, we have
E
[a, b] for i
aH(t'a:;t,
A» dG(t)
b
r(A)
J(g;(t) - /;(t»
= ~1
= 1, ...
, k and increasing
a k
b
= ~aH(b'a:;b,
A» J (g;(t) - h(t» dG(t) a
stu», neb, A» J b
k
= ~
au;
(g;(x) - h(x» dG(x)
a k
b
t
- ~J(J (g;(x) - h(X» dG(x») a a
2
H ~ ~; ~ ' A»
dt
a
b
+
; ~ ~ + 1a H(a'a:;a,
A» J(g;(x) -
h e x » d~ G(x)
a
b
+
b
i J(J (g;(x) -
;=k+l
a
t
b
+
2H(t, net, at au;
A» dt
b
; = ~ + 1 j ~ J(J (g;(x) - h(x» dG(x») a 2 H ~ ~ ~ A» ~ , dUj(t, A) a
:2: O.
h e x » d~ G(x») a
t
327
'\.- J
328
12. Convexity, Majorization, and Schur-Convexity
Therefore F(A) is increasing on [0,1], and from the inequality F(O)::::; F(l) we obtain (12.24). This completes the proof under the conditions in (a). The proof under conditions in (b) is similar.
0
The following result is a simple consequence of Theorem 12.14 (Pecaric, 1984b): 12.17. Theorem. Let x(t) = (XI(t), ... ,Xk(t» and y(t)=(YI(t), ... ,Yk(t» denote the mapping from the real interval [a, b] into an interval I in the k-dimensional Euclidean space IRk such that the components of x(t) and y(t) are continuous and increasing, and let G:[a, b ] ~ 1 be R a function of bounded variation. (a) If b
b
J Xi(t) dG(t)::::; J yJt) dG(t) x
for all x
E
[a, b],
(12.27)
x
and b
b
J Xi(t) dG(t) = J Yi(t) dG(t) a
(12.28)
a
hold for i = 1, ... , k, then for every continuous function f with increasing increments on I we have b
b
Jf(x(t» dG(t)::::; Jf(y(t» dG(t). a
(12.29)
a
(b) If (12.27) holds for i = 1, ... ,k, then (12.29) holds for every continuous increasing function f with increasing increments on I.
12.18. Remarks. (a) Assume that in Theorem 12.17 G is an increasing function. Then (12.29) holds for every continuous function f with increasing increments on I iff (12.28) holds. Similarly, (12.29) holds for every continuous increasing function f with increasing increments on I iff (12.27) holds for i = 1, ,k. If (12.29) holds for f(x) = Xi and f(x) = -Xi for each i = 1, ,k and x = (Xl, ... ,Xk), then (12.28) holds. Furthermore, let c" = max{O, c} and for u E [a, b] let f(x) = (Xi Yi(U»+ for a given i. Then f(x) is continuous with increasing increments
12.1. Majorization and Convex Functions
on I, and f(x)?: 0, f(x) ?: X; b
f
b
x;(t) dG(t) - y;(u)
u
f
-
y;(u). Since G is increasing, we have b
f =f
dG(t)::;
u
329
b
f(x(t)) dG(t)::;
a
f
f(y(t)) dG(t)
a
b
f b
y;(t) dG(t) - y;(u)
u
dG(t),
u
and thus we obtain (12.27). Similarly, we can prove a result when f is increasing. For k = 1, we then have the known result for convex functions. (b) In the proof of Theorem 12.15 we actually proved more general results such that the function F(A) is increasing. Therefore, for 0::; u ::; v::; 1 we obtain the following refinement of the result in (12.24): F(O)::; F(u)::; F(v)::; F(1).
(12.30)
In a similar fashion we can obtain a corresponding refinement of the result in (12.29). (c) As a special case of Remark (b) we obtain the following result: Let f, p, and x satisfy the conditions of Theorem 2.19; then
. hen p is a positive n-tuple, is decreasing on [0,1], where P; = ~ 7 = l P ; W this result is valid for convex functions f on a real linear vector space (see Theorem 3.22 and Remark 3.23(b)). For some related results, see Marshall and Olkin (1979, p. 134). (d) It is clear from the proofs of Theorems 12.16 and 12.17 that the statement in (c) also holds when f is a discrete convex function. (e) Fan and Lorentz (1959) proved the result in Theorem 12.16 for k = nand G(t) = t. It should be noted that, as shown in Theorem 11.3, 0 the results for k = n and for any k are equivalent.
The following result, due to Boland and Proschan (1986), depends on a result in Fan and Lorentz (1959) and has an application in reliability theory: Let F(t), G(t) be two continuous and increasing functions for t e: such that F(O) = G(O) = 0, and define
°
F(t)
= 1-
F(t),
G(t) = 1 - G(t)
for
t e: O.
(12.31)
330
U. Convexity, Majorization, and Schar-Convexity
By taking [a, b) e [0,00) if
= [0,00)
in Definition 12.14, we say that F(t) > G(t) for
t
s
s
JF(t) dt ~JG(t) dt o
for all s > 0
(12.32)
0
and =
=
J F(t) dt = J G(t) dt < 00. o
(12.33)
0
The following theorem is the integral inequality of Fan and Lorentz (1959) in a slightly different form:
12.19. Theorem. Let : [0, 1l" - [0, 00) be function, and assume that for i = 1, ... , n, F; for t E [0,00). If 4> is nonnegative decreasing (concave) in each variable separately, and property:
a continuous increasing and G; satisfy F;(t) > G;(t) (increasing), is convex satisfies the following
(u;
+ h,
Uj
+ k) - (u; + h,
Uj) -
(u;,
Uj
+ k) + (u;,
Uj)
((u;
+ h,
Uj
+ k) - (u; + h,
Uj) -
(u;,
Uj
+ k) + (u;,
Uj):5
for all i =1= j, 0:5 U; :5 U; + h :51, 0:5 Uj:5 integrals are finite,
0)
+ k:5 1, then providing the
=
co
J4>(t)(G
Uj
~0
1(t),
... , Gn(t)) dt s;
( ~ )J4>(t)(F 1(t), ... , F;.(t)) dt.
o
0
(12.34)
As a consequence of Theorem 12.19, Boland and Proschan (1986) obtained the following results:
12.20. Corollary. Assume that co
co
Jt dF(t) < 00,
J t dG(t) < 00.
o
o
Then F(t) > G(t) for t E [0,00) holds iff for all nonnegative increasing continuous convex (concave) functions 4> and nonnegative decreasing
12.1. Majorization and Convex Functions
331
(increasing) functions , 00
00
J (t)( G(t» dt s;
J (t)(F(t»
(2=)
o
dt,
(12.35)
0
provided the integrals are finite.
Proof. The "only if' part follows immediately from Theorem 12.19. To prove the "if" part, assume now that (12.35) holds. Letting (u) = u and x(t) = I[x, (i.e., the indicator function of the interval [x, (0», it follows that f; G(t) dt 2= f; F(t) dt for all x 2= 0 since x is nonnegative and increasing. Taking (t) == 1, it also follows that f ~t dF(t) = f ~ t dG(t), and hence F(t) > G(t) for t E [0, (0). D 00)
12.21. Corollary.
F(t) > G(t) for t E [0, (0) holds iff 00
00
J(t) dG(t) J(t) dF(t)
(12.36)
2=
o
0
holds for all convex functions , provided the integrals are finite.
Proof. The "if" part of the result is immediate. Now suppose F(t) > G(t) for t E [0, (0). It suffices to prove (12.36) for the case where has derivative 1jJ and (0) = O. Then, by Theorem 12.19, 00
00
J (t) dG(t) = J 1jJ(t)G(t) dt o
0 00
=
00
J[1jJ(t) - 1jJ(O)]G(t) dt + 1jJ(0) Jt dG(t) o
0
00
2=
00
J[1jJ(t) - 1jJ(0) ]F(t) dt + 1jJ(0) Jt dF(t) o
0
00
= J (t) dF(t).
D
o
12.22. Remark. Another approach to proving the necessity of (12.36) in Corollary 12.21 is as follows (see Bhattacharjee, 1981): Suppose
332
12. Convexity, Majorization, and Schur-Convexity
pet) > G(t) for t E [0, (0). Let ZG and ZF be the random variables with [5;;' t dG(t)]-l fO G(t) dt and respective distribution functions [f;;' t dF(t)t 1 S ~Pet) dt (these are the equilibrium distributions of G and F respectively). Then ZG >st ZF (ZG is stochastically larger than ZF) and hence E( 'lJ!(ZG» 2 E('lJ!(ZF» for all increasing functions 'lJ!. But 00
00
00
f 'lJ!(t)G(t) dt = [f t dG(t) ]E( 'lJ!(ZG» 2 [f t dF(t)] E('lJ!(ZF» o
0
f
0
00
=
'lJ!(t)P(t) dt;
o
hence the statement follows.
12.2.
D
Schur-Convex Functions
The following notion of Schur-convexity and Schur-concavity, due to Schur (1923), generalizes the definition of convex functions and concave functions via the notion of majorization. 12.23. Definition. A real-valued function f defined on a set A c said to be Schur-convex (Schur-concave) on A if y > x on A =? fey) 2 (::5)f(x).
~ n is
(12.37)
If equality in (12.37) holds only when x is a permutation of y, then said to be strictly Schur-convex (Schur-concave) on A.
f is
We note the trivial fact that f is a Schur-concave function on A iff -f is a Schur-convex function on A; thus results for Schur-convex functions immediately apply to Schur-concave functions, and vice versa, under obvious modifications. Furthermore, we note in the following theorem that all Schur-convex functions are permutation invariant. 12.24. Theorem. Assume that A c
~ n is
permutation invariant, that is, x E A implies that Px E A for every n X n permutation matrix P. If f is a Schur-convex function in A, then f(x) = f(Px) for all P and all x E A.
Proof.
For an arbitrary but fixed permutation matrix P, we have x > Px
and
Px > x
for all x E A;
U.2. Schur-Convex Functions
333
thus we have f(x) "2:.f(Px) and f(Px) "2:.f(x).
This implies that f(x) = f(Px)
for all x E A
and all P.
D
A useful condition for verifying the Schur-convexity property of f is known as the Schur-Ostrowski condition, and is stated in the following (see, e.g., Marshall and Olkin, 1979, p. 57): 12.25. Theorem. Let f : A ~Iffi be a real-valued function where A c Iffi n is permutation-invariant, and assume that the first partial derivatives of f exist in A. Then f is Schur-convex in A iff f)"2:. (x; - xJ( af - a 0 for all x E A ax; aXj holds for all 1 :5 i =1= j
:5
(12.38)
n.
The next theorem is a restatement of Theorem 12.2 and illustrates how one-dimensional convex functions and n-dimensional Schur-convex functions are related (see, e.g., Marshall and Olkin, 1979, p. 64). 12.26. Theorem. Let I be an interval in Iffi. Let x, y be two n-tuples such that x., Y; E I(i = 1, ... , n) and definef(x): I">« Iffi bea real-valuedfunction such that f(x) = ~ 7 = 1¢ (x;)for some continuous function ¢: I ~Iffi. Then f is a Schur-conuex function on I" iff ¢ is a convex function on I. A corresponding result can be given for functions of the form f(x) = n 7 ~ 1¢ (x;) when ¢ is a log-concave function (see Fact 13.24), and it has important statistical applications when the random variables are i.i.d. with a common density function ¢(x). To see how n-dimensional convex functions and n-dimensional Schurconvex functions are related, we observe the following result (Marshall and Olkin, 1979, pp. 68-69). 12.27. Theorem.
Let f :A
~Iffi
where A c Iffi n is permutation invariant.
(a) If f is permutation invariant and convex in A, then it is Schurconvex in A.
334
U. Convexity, Majorization, and Schur-Convexity
(b) More generally, if f is permutation invariant and convex in each pair of arguments (where the remaining arguments are held fixed) in A, then f is Schur-convex in A.
By combining Schur-convexity and monotonicity, useful results can be obtained via weak majorization. For example, a restatement of Theorem 12.7 is (Marshall and Olkin, 1979, p. 59): U.28. Theorem. Assume that f is defined as in Theorem 12.26. If 4J is an increasing (decreasing) convex function on I, then f is an increasing (decreasing) Schur-convex function on I", Similarly, we observe an analog of Theorem 12.27 for monotonic convex functions defined in IR n (marshall and Olkin, 1979, p. 68): U.29. Theorem. Let f be defined as in Theorem 12.27 where A c IR n is permutation invariant. If f is permutation invariant, increasing (decreasing), and convex in A, then f is increasing (decreasing) and Schur-convex in A. Marshall and Olkin (1979, p. 61) contains a detailed study of closure properties of compositions of Schur-convex and Schur-concave functions of the form
'ljJ(x) = h(4Jl(x), ... ,4Jk(X)),
X
E IR n •
For example, they illustrate that (i) If each of 4Ji (i = 1, ... ,k) is Schur-convex and if h : IR k ~IR is increasing (decreasing), then 'ljJ: IR n ~ IR is Schur-convex (Schur-concave); and (ii) if each of 4Ji (i = 1, ... , k) is Schur-concave and if h is increasing (decreasing), then 1/J is Schurconcave (Schur-convex). Combining those results with Theorem 12.27, we immediately obtain useful results when each of 4Ji (i = 1, ... , k) is a permutation-invariant convex function in IR n • If each of 4Ji is also monotonic, then similar results in their Table 1 apply. For details, see Marshall and Olkin (1979, p. 61). The notions of Schur-convexity and Schur-concavity are useful in obtaining inequalities via majorization and weak majorization, and there exist numerous results in this area. In the following we describe two convolution theorems (Theorems 12.30 and 12.32) due to Marshall and Olkin (1974) and Proschan and Sethuraman (1977a), respectively (see also, Marshall and Olkin, 1979, pp. 100-101).
U.2. Schur-Convex Functions
335
12.30. Theorem. If and f are two Schur-concave functions defined on IR n, then the function tjJ defined on IR n by tjJ(a)
=
J (a - x)f(x) dx ~ n
is Schur-concave (whenever the integral exists).
An application of Theorem 12.30 yields the following Schur-concavity property of distribution functions when the density functions are Schurconcave. This result is due to Marshall and Olkin (1974, 1979, p. 101). 12.31. Corollary. Let f(x): IR n ~[0, 00) be a probability density function of a random variable X = (Xl' ... , X n ) such that the probability measure is absolutely continuous with respect to Lebesgue measure. If f is a Schur-concave function of x for x E IR n, then the distribution function of X
F(a)
=
l
~ L Q{Xi ~a;}
a
E
IR
n
is a Schur-concave function of a.
Proof.
For i = 1, ... , n, let I if a, - Xi 2= 0, I(-oc.ail = { 0 otherwise
be the indicator function of {x, :Xi of the set
~ ai}'
Since the indicator function (x)
A = {x: x E IR n , Xi 2= 0 for i = 1, ... , n}
is a Schur-concave function of x E IR n and, by (a - x) F(a) can be expressed as
F(a)
=
= II7=1 I(-OC,ail'
J (a - x)f(x) dx, ~
n
then the conclusion follows from Theorem 12.30.
0
12.32. Theorem. Suppose that either (i) .r = IR, e c IR is an interval and f.l is Lebesgue measure or (ii) .r is the set of all integers, e is an interval or an interval of integers, and f.l is the counting measure. If g: e X . r ~[0,00)
336
12. Convexity, Majorization, and Schur-Convexity
is totally positive of order two (TP2) and satisfies the semigroup property g(OI
+ O2, x) =
Jg(OI' t)g(02' X- t) dv(t) .1'
for some measure von x, and 1J(x) is Schur-convex for x E IR n. Then the function 1jJ defined for 0 == (0 1 , • . . , On) E ex· .. X e by 1jJ(O) ==
J}] g(
0i' x i)1J(x) }] d/l(xi)
is a Schur-convex function of O. Theorems 12.30 and 12.32 can be applied to obtain useful integral inequalities and probability inequalities. Some of the recent results derived from those two theorems using Schur-concavity can be found in the review article by Tong (1988).
12.3.
Multivariate Majorization and Convex Functions
As indicated in Definition 12.1, the notion of majorization concerns a partial ordering of the diversity of the components of two n-tuples x and yin IR n • A natural problem of interest is the extension of this notion from n-tuples (vectors) to k X n matrices. For example, let
X == (XI, X2, ... ,Xk)
,
=
Y==(YI,Y2"",Yk)'==
Xl2 X22
X2n
Xkl Xk2
Xkn
C X21
Yl2 Y22
C Y21
Ykl Yk2
be two k X n real matrices, where responding row vectors. If Xi == Yi
for
Xl, . . .
X'") , (12.39)
Y'Y2n") Ykn
,Xk; y, ... , Yk are the cor-
i == 1, ... , k
(12.40)
12.3. Multivariate Majorization and Convex Functions
337
where (12.41) then intuitively speaking the components of x are less diverse than those of y. The question of interest is, of course, how to find a useful definition so that meaningful results can be obtained. This involves a multivariate extension of Definition 12.1. To state a definition of multivariate majorization given in Marshall and Olkin (1979, Chapter 15), we first observe the definition of a T-transform matrix (Marshall and Olkin, 1979, p. 21):
12.33. Definition. An n it is of the form
X
n matrix is said to be a T-transform matrix if
T = a1+ (1 - a)Irs
(12.42)
for some a E [0, 13, where I is the n X n identity matrix and I, is obtained by interchanging the rth and sth columns of I for some r Zs.
12.34. Definition. Let A, B be two k x n real matrices for k 2 2, n 2 2. (a) Y is said to chain majorize X (in symbols, Y >X ' ) if there exists a finite number of T-transform matrices T I , . . . ,TN such that X = YIIEV=,Ti. (b) Y is said to majorize X in a multivariate sense (Y > m X) if there exists an n x n doubly stochastic matrix Q such that x = YQ. (c) Y is said to row-wise majorize X (Y >'X) if yi > x i holds for i = l , 2 , . . . , k. The implications of partial orderings defined in Definition 12.34 are given in the following theorem: 12.35. Theorem. Let X, Y be two k x n real matrices. Then (ii)
Y>'X$
Y>"X+Y>'X.
(12.43)
Furthermore, the implications (i) and (ii) are strict. Proof. (i) follows from the fact that the multiplication of a finite number of T-transform matrices is doubly stochastic; (ii) follows from Fact 12.5(b). TOshow that (i) is strict, by Fact 12.5(b) it suffices to find a
338
12. Convexity, Majorization, and Schur-Convexity
matrix Q that is doubly stochastic but it not the multiplication of a finite number of T-transform matrices; such a 3 x 3 matrix can be found in Marshall and Olkin (1979, p. 431). The proof for the strict implication (ii) follows immediately from Fact 12.5(b) and Definition 12.34. 0 Rinott (1973) considered the notions of multivariate majorization given in Definition 12.34 and derived some useful results in probability and statistics. He also provided a characterization of chain majorization and row-wise majorization. His result is stated in the following theorem, and a convenient reference for the proof is Marshall and Olkin (1979, pp. 434-435). 12.36. Theorem. Let f(X) =f(XI' ... ,Xk): I R k x n IR~ be a differentiable function. Then (a) f(Y)
for all Y >c X
~f(X)
holds iff (i) f(X) = f(XP) holds for all n x n permutation matrices P and (ii) ~ 7 ~ 1(Xjr - xjs)[fUr)(X) - f u ~ ) ( X ) ] ~0 holds for all r, s = 1, ... , n, where fUr)(X) = 0/ oajr!(U)/u=x. (b) f(Y) ~f(X) for all Y »: X holds ifffor every fixed j = 1, ... , k, (Xjr - xjs)[fur/ X) - ks)(X)] ~0 holds when the values of the other columns of X are held fixed.
12.37. Remark. Note that the statement of Theorem 12.36(b) is just that xj , Yj satisfy Theorem 12.25 for each j
= 1, ...
, k.
0
Marshall and Olkin (1979, p. 435) proved a result for majorization in a multivariate sense. Their result is related to symmetric convex functions: 12.38. Theorem. Let X, Y be two k x n matrices as defined in (12.39). If y>mx, then f ( Y ) ~ f ( Xholds ) for all f(X)=f(XI"" , x d : l R k x n ~ 1 R which are symmetric and convex in the sense that (i) f(X) = f(XP) for all n x n permutation matrices P and (ii) f(aU for all a
E
+ (1- a) V)
~ af(U)
+ (1- a)f(V)
[0, 1] and k x n matrices U and V.
Chapter 13 Convexity and Log-Concavity Related Moment and Probability Inequalities
In this chapter we discuss some moment and probability inequalities that arise from the applications of convexity, Jensen-type inequalities, and log-concavity. We shall assume without explicit statement that expectations and other integrals mentioned in theorems, corollaries, etc., exist. If an expectation or integral does not exist, the corresponding statement is to be considered vacuous.' The convexity-related results are given in Sections 13.1-13.3, and results that arise from the log-concavity property of probability density functions are discussed in Sections 13.4 -13.7.
13.1.
Jensen's Inequality
Jensen's inequality for one-variable functions and for functions of several variables, and its reversals, refinements, and converses have been treated extensively earlier in this book. In this chapter we first present a stochastic version of Jensen's inequality. It is a probabilistic analog of the previous results and has important applications in probability and statistics. For n 2 1 let X = (XI,. . . , X, ) be an n-dimensional random variable. Let F ( x ) = P [ X s x ] be the distribution function of X, and let p = ( p l , . . . , p,) denote the mean vector of X.
13.1. Theorem. For n 2 1 let @ : A + R be a continuous convex function where A c R" is an open convex set such that P[X E A] = 1. Then p E A 339
340
13. Convexity and Moment and Probability Inequalities
and E1'(X)
=
J1'(x) dF(x)
2:
(13.1)
1'(r.a).
A
Proof. The fact that r.aEA is easy to verify. To show that (13.1) holds we use the proof in Marshall and Olkin (1979, p. 454). For Z E A and i = 1, , n, let 1't)(z) = lim.!. [1'(Zl'
,
dO E
+ E, Zi+l ,
Zi-l' Zi
... ,
zn) - 1'(Zl' ... , zn)],
and denote
V+ l' (x) = (1'(l)(x), ... , 1't.ix)),
x EA.
Then V+ l' (x) is Borel-measurable and, more importantly, 1'(x) - 1'(z) 2: [V+ l' (z)][x - z),
x,zEA
holds (Marshall and Olkin, 1979, p. 451). Choosing z = u, we have 1'(X) - 1'(r.a) 2: [V+1'(r.a)](x- u)
a.s.
(13.2)
The proof follows by taking expectations on both sides of (13.2).
0
Note that if l' is differentiable, then V+l' (x) is just the gradient vector of l' at x. Furthermore, note that if A is an interval in IR and the distribution of X is discrete, this result reduces to the result treated in Theorem 2.1. For n = 1, a more general result is known (Chow and Teicher, 1978, pp. 102-103): 13.2. Theorem. c E IR and r : IR
Let 1': IR ~IR be a continuous convex function. Let be Borel measurable. If r(x) and
~IR
6(x) == (x - EX) - (r(x) - Er(X))
are both increasing for x
E
IR, then
E1'«X - EX) + c)
2:
E1'« reX) - Er(X)) + c).
(13.3)
Proof. If P[ 6(X) = 0] = 1, then (13.3) is immediate. Otherwise, by the convexity of l' we have 1'«X - EX) + c) - 1'«r(X) - Er(X)) + c) 2:
6(X)V+1'«r(X) - Er(X)) + c)
a.s.,
(13.4)
13.1. Jensen's Inequality
341
where
and (by the convexity of 1J) 'y+ 1J(z) is increasing in z. By the mono tonicity of <5(x), there exists a real number Xo such that <5 (x){ :s;O ~ O
for all x < Xo for all x > Xo .
Furthermore, the monotonicity of r(x) and V+ 1J implies <5(x)V+1J«r(x) - Er(X))
for all x
E
+ c)
~ <5(x)V+ep«r(xo)
- Er(X))
+ c) (13.5)
IR. Thus (13.4) and (13.5) together imply
1J«X - EX)
+ c) -1J«
reX) - Er(X)) ~ <5 (X)V+ 1J«
+ c)
r(xo) - Er(X))
+ c) a.s. (13.6)
The conclusion follows from taking expectations on both sides of (13.6). 0 13.3. Remarks. (a) If 1J:A ~IR is a continuous convex function on an interval A such that P[X E A] = 1 and A is a proper subset of IR, then
Theorem 13.2 can be modified accordingly. (b) For n = 1 and A = IR, (13.1) follows from (13.3) as a special case by letting r(x) = 0 and c = EX. (c) If r } : I R ~ 1and R r 2 : 1 R ~ 1 are R such that r}(x) and
are both increasing for x
E
IR, then
holds, as noted in Liu (1988). The proof for this result is similar. (d) Note that the proof of Theorem 13.2 cannot be modified in a routine fashion for n > 1. 0 A different generalization, given below, depends on a partial ordering of the distribution functions. Its proof can be found in Karlin and Novikoff (1963) or Stoyan (1983).
342
13. Convexity and Moment and Probability Inequalities
13.4. Theorem. Let X, Y be two univariate random variables with a common mean EX and distribution functions F(x), G(x), respectively. If for all x < (2::)EX,
F(x)::5 (2::)G(x)
(13.8)
then Ecp(X) 2:: Ecp(Y) holds for all convex functions cp.
13.5. Remark. For n = 1, Theorem 13.1 follows from Theorem 13.4 by 0 letting pry = EX] = 1.
13.2.
Moment Inequalities for Univariate Random Variables
Let Z be a univariate random variable with distribution function F(z).
13.6. Definition.
The fith moment of Z for fi E [0, (0) is /-l(3
/-lo= 1,
= EZ(3=
f
z(3 dF(z)
for
fi > O.
(13.9)
13.7. Theorem. If a', fi are positive real numbers such that fila' is a positive even integer, then /-lf3 2:: (/-la )(3la. In particular, /-In 2:: (/-lnlzf and /-In 2:: (/-lIt hold for all positive even integers n.
Proof.
Immediate by choosing cp(z) = (zj(3la in Theorem 13.1.
0
The following results concern moments of nonnegative random variables.
13.8. Theorem. If Z 2:: 0 a.s., then log /-lf3 is a convex function of fi for fi E [0, (0). Consequently (13.10) /-l(3 2:: (/-la )f3la for all 0 < a' < fi, /-lf3
2:: /-la/-l(3-a
(13.11)
for all 0 < a' < fi,
and, more generally, /-la,/-l(3-at
2:: /-la 2J.t(3-a2
for all
0<
a'i
< a'z::5
en.
(13.12)
13.3. Dimension-Related Inequalities
Proof (see, e.g., Loeve, 1963, p. 156). inequality, Il~
343
By the Cauchy-Schwarz
= [E(Z
holds for all 0 < a < {3. Thus
holds for all 0 < {31 < {32' and this is equivalent to the log-convexity of 1l13' 0 Theorem 13.8 may also be proved by using total positivity arguments. A consequence of Theorem 13.8 is that 13.9. Corollary (see Loeve, 1963, p. 156). an increasing function of {3 for (3 E [0, (0).
13.3.
13.3.1.
If Z ~ 0 a.s., then (1l13)1113 is
Dimension-Related Inequalities for Exchangeable Random Variables
Exchangeable Random Variables and de Finetti's Theorem
The notion of exchangeable random variables involves changeability of an infinite sequence of random variables.
the ex-
13.10. Definition (Loeve, 1963, p. 364). An infinite sequence of random variables {Xn::l is said to be exchangeable if for every fixed n and every permutation (Jrl""" Jr n ) of (1, ... , n), the two ndimensional random variables ( X ~ ., .. ,X:) and ( X ~ I " .. , X ~ Jare identically distributed. For a finite integer n > 1, let X = (Xl' ... , X n ) be an n-dimensional random vector. 13.11. Definition. Xl"'" X n are said to be exchangeable if there exists an infinite sequence of exchangeable random variables { X n ~ ~ such that X and ( X ~, ... , X:) are identically distributed.
l
344
13. Convexity and Moment and Probability Inequalities
It is obvious that the joint distribution of exchangeable random
variables must be permutation invariant. But the converse is false. In fact, it is known that the common correlation coefficient of any pair of exchangeable random variables must be nonnegative, thus if the joint distribution of X is permutation invariant and if the common correlation coefficient is negative, then XI, ... , X; are not exchangeable. The following theorem, known as de Finetti's theorem (see e.g., Loeve, 1963, p. 365), states that exchangeable random variables must be a mixture of conditionally independent and identically-distributed (i.i.d.) random variables: 13.ll. Theorem. Let the distribution function F(x.) of (XI, ... Xn) be X; are exchangeable random permutation invariant. Then X I variables iff F(x) is of the form I
I
F(x.) =
J !I.
•••
I
n
(13.13)
Gv(x;) dH(v) ,
where H(v) is the distribution function of an r-dimensional random variable V taking values in A, and Gv(XI) is the conditional distribution of Xl given V = v.
An equivalent condition for exchangeability is (see, e.g., Shaked, 1977, or Tong, 1980, Section 5.3): 13.13. Theorem. Xl ,Xn are exchangeable random variables iff there exist i. i. d. random variables UI , • • . , Un' an r-dimensional random variable V (r ~ 1) independent of the U;'s, and a Borel-measurable function g: I W + I ~~ such that (XI X n) and (g(UI V), ... ,g(Un, V» are identically distributed. I
•••
I'
••
I
I
Note that Gv(XI) in (13.13) is in fact the conditional distribution function of g(UI V) defined in Theorem 13.13, given V = v. Because of this fact, exchangeable random variables have been called conditionally i.i.d. random varibles (Tong, 1977) or positively-independent-by-mixture (PDM) random variables (Shaked, 1977), and events defined by those random variables are said to be events which are almost independent (Dykstra, Hewett, and Thompson, 1973). This mixing process also I
13.3. Dimension-Related Inequalities
345
creates some positrve dependence properties of exchangeable random variables. For example, it is known that if V is a random variable such that {Gv(x): v E A} is a stochastically increasing family, then Xl, ... , X; are associated random variables in the sense of Esary, Proschan, and Walkup (1967).
13.14. Example. The random variables Xl, ... ,Xn given below are exchangeable random variables which are useful in statistics: (a) Multivariate normal. (Xl'.'" X n ) has a multivariate normal distribution with a common mean, a common variance, and a common correlation coefficient p E [0, 1]. t. (X 1, . . . , X n ) 4 (Y1 / S, ... , Yn / S), where (b) Multivariate (Yl , . . . , Yn ) has a multivariate normal distribution with a common mean 0, a common variance a 2 , and a common correlation coefficient p E [0, 1]; S is independent of (Y1 , ••• , Yn ) , and vS2 /aZ has a X2(v) distribution.
(c) Multivariate binomial. (Xl' ... ,Xn ) 4 (U 1 + V, ... , U; + V), where U1 , . . • , Un are i.i.d. binomial variables with parameters n1 and p, and V is independent of the U;'s and is a binomial variable with parameters no andp. (d) Multivariate Poisson. Similar to (b) except that U1 , • • • , Un are Poisson variables with parameter Al and V is a Poisson variable with parameter Ao. (e) Multivariate exponential. (Xl' ... , X n ) 4 (min(U1 , V), ... , mineU;; V)), where U1 , ••• , Un are i.i.d. exponential variables with common mean AI' and V is an exponential variable with mean Ao and is independent of the U;'s (Marshall and Olkin, 1967). More general forms of the multivariate exponential are also available. (f) Multivariate gamma (chi-squared) variables. Similar to (c) except that U1 , ••• , U; are i.i.d. gamma variables with parameters (Y1 and {3 (chi-squared variables with degrees of freedom VI) and V is a gamma variable with parameters (Yo and {3 (a chi-squared variable with degrees of freedom Yo). (g) Multivariate F. (Xl' ... ,Xn) 4 (UdV, ... , Un/V), where 2 m 1U1 , ... , m1 Un are i.i.d. x ( m 1) variables and mo V is a x2(m o) variable independent of the V;'s. 0
346
13. Convexity and Moment and Probability Inequalities
13.3.2. Inequalities In the following we describe some dimension-related inequalities for exchangeable random variables. The inequalities can be obtained by combining Theorem 13.12 (or 13.13) with the moment inequalities in Section 13.2. The first result (Tong, 1970) deals with exchangeable normal variables only and follows from an application of Theorems 13.7 and 13.8. 13.15. Theorem. Let (Xl"'" X n ) have a multivariate normal distribution with a common mean u, a common variance 0 2, and a common correlation coefficient p ? O. Let A( n) be defined as
Then A(n)? (A(k)t/k and A(n)? A(k)A(n - k) hold for all positive integers k < n. Proof. Consider A(n) = p[n7=1 {Xi 5:: a}], and let V, VI, ... ,Vn be i.i.d. K(O, 1) variables. Then (Xl' ... , X n ) and
are identically distributed. Thus, after first conditioning on V = v and then unconditioning,
A(n) =
E[J] P[o(yT=p U; + VP v) + fl5::a IV= v]]
= Ern(V) ?
[Erk(V)r/ k = [A(k)r/\
where r( v) = P[ 0(yT=p (U; + VP v) + fl 5:: a I V = v]. equality now follows from Theorem 13.8. Similarly,
The proof for the case A(n) =
p [ n 7 ~ {!X 1 i ! 5::
The
a}] is similar.
first
D
In-
13.4. Brunn-Minkowski Inequality
347
The result in Theorem 13.15 was generalized by Sidak (1973) to all exchangeable random variables and all Borel-measurable sets:
13.16. Theorem. Let B c
~
Let Xl' ... ,Xn be exchangeable random variables. be a Borel-measurable set. Define y(k) =
pLo
l
{X; E B}
k = 1, 2, ... , n.
(13.15)
Then y(n) ~ (y(kW/k and y(n) ~ y(k)y(n - k) hold for alII:::::: k < n.
Proof.
Let V, U1 ,
U; and g be defined as in Theorem 13.13, and
••• ,
let I for x E B, I B () X = { o otherwise. Then, by Theorem 13.8 and an argument similar to that given in the proof of Theorem 13.15, y(n) = E
D
IB(X;) == E[ ED IB(g(U;, v)) I V = v]
~ ( E [ E n I B ( g (v)) U ;I v=v])n/k , = (y(k)t/k • The second inequality follows similarly from (13.11).
D
13.17. Remark. A generalization of Theorem 13.16 from exchangeable random variables to a class of positively dependent random variables with a common marginal distribution will be given in Theorem 14.18. The proof of that theorem depends on an application of a moment inequality via Muirhead's theorem. D
13.4. Bmnn-Minkowski Inequality In the rest of this chapter we study inequalities via the log-concavity property of certain probability measures. In particular, we treat the Brunn-Minkowski Inquality and the theorems of Prekopa (1971), Borell (1975), and their generalizations (Rinott, 1976, and Das Gupta, 1980). We then describe some applications of these results in statistics.
348
13. Convexity and Moment and Probability Inequalities
Let 53 denote the class of all Borel-measureable sets in R", and let B be a measure defined on 53. For arbitrary but fued ( Y E [0, 11 and B , , B2 E 53, let us define &I+
(1 - a)B,
+ (1 - a ) x 2 for some x1 E B1 and x2 E B2}. (13.16) We assume that B , , B2 are in 53, are nonempty, and (aB, + (1 - a ) B Z )E = {x:x E R", x = ax,
53.t Let X = (X, , . . . , X n ) have a probability density function f (x) that is absolutely continuous w.r.t. Lebesgue measure. The inequalities we study here concern lower bounds on P(crB1+ (1- a)Bz) in terms of P ( B , ) and P(B2), where, if B is a probability measure, then P ( B ) stands for P(X E B). The classical Brunn-Minkowski Inequality states: 13.18. Theorem. If 9 si the Lebesgue measure, then
+
P((YB1 (1 - a)&)
holds for all B 1 , B2 E 53, all
2
[a(P(B1)),'"+ (1- (Y)(P(B2))""]"
(Y
E
[0, 11, and all n = 1, 2, . . . .
When B 1 , B2 are convex sets (which implies that aB1 + (1 - a ) B 2 is also convex), this inequality was first proved by Brunn (1887). Minkowski (1910) derived conditions for equality to hold when B , , B2 are convex. Later Lusternik (1935) generalized this result to any Borel-measurable set, and his conditions for equality to hold were corrected by Henstock and Macbeath (1953). A treatment of the historical developments related to this inequality can be found in Das Gupta (1980). Das Gupta (1980) also provided a generalization that includes a previous generalization of Henstock and Macbeath (1953) as a special case.
13.5. A Class of Log-Concave Probability Measures If 9 is a probability measure such that P(B)=
If
(x) dx
for all B E 53,
(13.17)
B
t Karlin (1983) provided a counterexample showing that B , , B , E 93 does not necessarily imply (CUB,+ (1 - (Y)B,) E B for all (YE [0, 11. Thus this assumption is needed.
13.5. A Class of Log-Concave Probability Measures
349
then (W, 00, gp) is a probability space. Prekopa (1971) considered probability measures with the following property: Ct' E [0, 1]. (13.18) If all the probabilities are positve, then (13.18) is equivalent to
log P(Ct'B I
+ (1- Ct')B 2 ) 2: Ct' log P(B I ) + (1- Ct')log P(B 2 ) ,
which is just the log-concavity of gp. He studied conditions on f(x) for (13.18) to hold, and proved that a sufficient condition is the log-concavity of f.
13.19. Definition. Let
f ( x ) : [ R n ~ [(0) o , be a probability density function such that gp is absolutely continuous w.r.t. Lebesgue measure. f is said to be log-concave if
(13.19) holds for all Ct' E [0, 1] and all Xl' X2 E [Rn. When f(x) > 0 for all XE [Rn, then (13.19) is equivalent to 10gf(Ct'xl + (1- Ct')X2) 2: Ct' log j'(x.) + (1- Ct')logf(x2)'
(13.20)
The main theorem of Prekopa (1971) states: 13.20. Theorem. Let gp be defined as in (13.17). Iffis log-concave, then (13.18) holds for all B I' B 2 C [Rn and all Ct' E [0, 1]. An immediate generalization of Theorem 13.20 is: 13.21. Coronary. Let X be an n-dimensional random vector with probability density function f(x), and let B I , . . . , B; (k 2: 2) be subsets of [Rn. Iff(x) is a log-concave function of x, then (13.21) holds for all Ct'; such that Ct'; >
0 and
I : 7 ~ 1Ct';
= 1.
350
13. Convexity and Moment and Probability Inequalities
Proof,
p[ X
E
~ 1a;B;]
=
p[X
E
~ {P[X E Bd}"" { P [ X E ~ {P[X E
X
p[x
~ 2( aJ(l-
a1 B1 + (1- (1) k
(1))B;]
~(aJ(l- ( 1))B;
]}1-"'1
Bd}"'l{P[X E B 2 ]}"'2 E
~(a;/(l-
~
...
~
TI {P[X E B
a1 - (
2
»BT-"'1-"'2
k
0
i ]} "" .
i=l
Prekopa's original result is given when B 1 , B 2 are convex sets only; his original proof depends on an application of the Brunn-Minkowski Inequality and is quite lengthy. His result was generalized to a larger class of probability measures for convex sets by Borell (1975). Borell considered measures with the property that
(13.22) n
holds for all convex sets B 1 , B 2 C IR , all a E [0, 1], and for some s E [-00, lin). When s = O,then by continuity (13.22) reduces to (13.18). When s = -00, then the right-hand side of (13.22) is just min{P(B 1 ) , P(B 2 )} . Borell (1975) first showed that 13.22. Theorem. If the probability measure !!J satisfies (13.22) for all B 1,B2clR n , all aE[O, 1], and for some SE[-OO, lin), then it is absolutely continuous w.r.t. Lebesgue measure. As a consequence of Theorem 13.22, the class of measures satisfying (13.22) for some s E [-00, lin) must be of the form (13.17) for some f. Borell's (1975) main theorem concerns a characterization of the class of probability measures satisfying (13.22). His original result concerns convex sets only. In the following theorem the convexity condition on B 1 , B 2 is removed: 13.23. Theorem. Let f: IR n ~[0, (0) be a probability density function, and let !!J be the probability measure defined in (13.17). Then the following
351
13.5. A Class of Log-Concave Probability Measures
statements are equivalent: (a) $9' satisfies (13.22) for all sets B , , B, E 93, all a E [0, 11 such that B E 3, and for some s E [-a, l / n ) . (b) There exists a Borel-measurable function g:Rn+R such that f(x) = g(x) almost everywhere and (i) i f s E [-cot 0), then (g(x))"'('-") si convex, (ii) i f s = 0, then logg(x) is concave, (iii) i f s E (0, U n ) , then (g(x))""l-"' 1s. concave.
Sketch of Proof. The original proof of Borell (1975) is lengthy and is for convex sets only. In the following we adopt the proof given by Rinott (1976). Rinott's proof involves replacing integrals on f over sets in R" by a certain measure Y of epigraphs in Fin+'. Thus his proof is valid only for s E [-m, l / ( n 1)). Let B* be any set in R"+'. Consider a measure Y given by
+
=(
dv(B*)
for s # 0, s E [-m, l / ( n
+ l)),
for s = 0.
(13.23) Then it can be shown that, for B:, B; c Rn+l,
+
V ( ~ B T ( 1 - (Y)B;)
2[
" ~ s f 0, s E [-m, l / ( n + l ) ) , [a(v(B:))s+ ( 1 - a ) ( ~ ( B 2 * ) ) " ]for (Y(BT))a(4B;))1-a for s = O . (13.24)
The inequality in (13.24) can be obtained by first showing it for rectangular sets, then extending it to any Bore1 measurable sets by using the argument in Borell (1975). (b) .$ (a): For arbitrary but fixed B c R" and g :R" + R, let us define the epigraph in Rn+l: A ( B , g ) = {(x, A) : x E B , a E R , g(x)
5
A).
352
13. Convexity and Moment and ProbabiJity Inequalities
Let us first consider the case s = 0 and assume that f satisfies (13.19). Denoting B* = A(B, -log!) c IR n +\ we can easily verify that for measure v defined in (13.23) we have PCB) = v(B*)
(13.25)
for all Be IR n and [aB 1 + (1- a)B 2)* ~ aBr
for all B 1 , B2 c;; IR
n
•
+ (1- a)Bi
(13.26)
Thus (13.24), (13.25), and (13.26) together imply
P[aB 1+ (1- a)B 2l = v[aB 1 + (1- a)B 2*l 2:
2:
v[aBr
+ (1 -
a)Bn
(v(Bt))"'(V(B;))l-'" = (P(B 1))"'(P(B 2))1-""
which completes the proof for s = O. For s < 0 we can repeat the above arguments with B* = A(B, rl(l-ns»), and for s E (0, 1/(n + 1)) we can define B* = H(B, r /(1-ns») where the hypograph H(B, g) is given by H(B, g)
= {(x, A):X E B, AE IR, and 0$ A$g(x)}.
(a):::;> (b): First consider the case s =0 and assume that (13.18) holds. Let Sk(X)= {y: Iy - x] $ IIk} and define !k(X) = [
f
fey) dy
Sk(X)
J/ f
dy.
Sk(X)
Then (13.18) implies !k( axl
+ (1 - a)x2) 2: (!k(x 1))"'(!k(x2))1-", for a E [0, 1].
Consequently the function g(x) = limk->oo inf!k(x) satisfies
g( ax1 + (1- a)x2) 2: (g(x 1))"'(g(X2))1-", for
a E [0, 1].
By differentiation of the integral argument, we have f = g almost everywhere. Thus the proof is complete for s = O. For s = -00, a similar argument yields g( axl + (1 - a)x 2) 2: min{g(x1)' g(X2)}' For s E ( -00, 0), we can consider the sets C 1, C 2 C IR n + 1 defined by C; = B; X (c., (0), where the B;'s are spheres in IR n and c, >0 (i = 1, 2). If B 11 B 2 are chosen to satisfy
(f fI dx,/ f fI dX;) = (Ct/C2r, 8,
1
8
2
1
then C 1 , C 2 satisfy (13.24) for some s E (-00,0). Suppose rl(l-ns) is not convex. We choose C 1, C 2 in this fashion to satisfy C; c A(B;, r/(l-ns))
13.6. Some Properties of Log-Concave Density Fnnctions
353
and
Thus we have
P[aB 1+ (1- a)Bzl < v(aC 1 + (1- a)C z)
= [a(v(C1))S + (1- a)(v(Cz)Yp/s< [a(P(B1))S + (1- a)(P(B 2)Yllls, which is a contradiction. For s E (0, 1/(n by choosing C; = B; x (0, c;) (i = 1, 2).
13.6.
+ 1)) the proof follows similarly 0
Some Properties of Log-Concave Density Functions
Log-concave density functions which satisfy (13.19) play an important role in statistics and probability. In the following we observe some known facts concerning this class of densities. 13.24. Fact. Let Xl' ... , X; be i.i. d. univariate random variables with a common density function hex). If hex) is a log-concave function ofx for x E [R, then the joint density function of (Xl' ... , X n ) is a log-concave function of x for x E [Rn. 13.25. Fact. If f(x) = g(T(x)) where g: [R ~[0,00) is decreasing and T(x) is a convex function of x for x E IRn, then f is a log-concave function ofxfor XE [Rn. The following theorem, due to Prekopa (1971) and Brascamp and Lieb (1975), shows that the integral of a log-concave function is log-concave: ~ be a log-concave function 13.26. Theorem. Let f(x, y): [ R n + m[0,00) of (x, y) for x E [Rn and y E [Rm. Then the function g: [Rn ~[0, 00) given by
g(x)
=
I
f(X, y) dy
(13.27)
[I;lm
is log-concave. Proof. We adopt the proof in Brascamp and Lieb (1975). First note that it suffices to prove the theorem for m = n = 1 because the general case
354
13. Convexity and Moment and Probability Inequalities
follows by Fubini's theorem and induction. Let Xl' X2 be two points in such that g(X1)g(X2) 0. For convenience we may assume that
~
'*
supf(x, y)
= supf(x', y);
y
y
because otherwise we can replace f(x, y) by ebXf(x, y) for suitably chosen b and the problem remains unchanged. For each fixed A> 0, denote C1(A) = {(x, y) :f(x, y) Cix, A) = {y :f(x, y)
2= A} C
2= A}
~ 2 ,
c ~ .
Then, by log-concavity of t. C1(A) is convex and C 2 (x , A) is an interval. (For the convexity of C 1(A), see Fact 13.28). Letting v(x, y) = f C2(X.).) dy be the Lebesgue measure of the set C 2 (x, A), we have, by Theorem 13.18, V(ax1 + (1- a)x2' A)
+ (1- a)v(x2' A) for all a E [0,1]. Since g(x) can be expressed as g(x) = fO' v(x, A) ds, we have g(ax1 + (1- a)x2) 2= ag(x1) + (1- a)g(x2) 2= (g(X1))"'(g(X2))1-", 2=
av(x1' A)
for all a E [0, 1], where the second inequality follows from the arithmetic mean-geometric mean inequality. 0 A simple application of Theorem 13.26 is (Brascamp and Lieb, 1975; see also Barlow and Proschan, 1981, p. 104): 13.27. Corollary. The convolution of two log-concave density functions 0 in ~ n is log-concave.
Proof. Let f1' f2 be log-concave density functions. Then h(x - y)fz(y) is jointly log-concave in (x, y) E ~ 2 n . Thus by Theorem 13.26 g(x)
=
f
ft(x - y)fiy) dy
JR"
is log-concave.
0
A density function f is said to be unimodal if the set
D).
= {x:x E
~ n , f ( x 2= ) A}
(13.28)
is a convex set in ~n for all A> 0. The following facts show how log-concavity and unimodality are related.
13.7. Some Statistical Applications
355
13.28. Fact. If f: ~ n- [0, (0) is a probability density function, then log-concavity offimplies unimodality off.
Proof. Let XI' Xz E (13.20),
~ n be
in D)... Then for every a
E
[0, 1], we have, by
log j'(ux, + (1- a)xz) 2: a 10gf(xI) + (1 - a)logf(xz) 2:
Thus axl
a log A + (1 - a)log A 2: log A.
+ (1 - a)xz is also in D)...
(13.29)
D
A function f is said to be Schur-concave if y > X implies f(x) 2: f(y) for all x, y E ~ n (see Definition 12.23). It is known that all Schur-concave functions are permutation invariant (see Theorem 12.24). Furthermore, it is known that
13.29. Fact. If f: ~ n [0, _ (0) is a permutation-invariant and logconcave function ofx E ~ n , then it is a Schur-concave function ofx E ~ n .
Proof. Assume y > x and, without loss of generality, it may be assumed that x, yare of the form
I and XI + Xz= YI + Yz· Let y* = (». YI, X3' ... , x n ) . where Yz<X2 ~ X
logf(x) = logf(ay + (1 - a)y*)
= logf(y).
2:
a logf(y) + (1 - a)logf(y*)
D
13.7. Some Statistical Applications In this section we describe some examples of applications of Prekopa's theorem (Theorem 13.20) and Borell's theorem (Theorem 13.23) in statistics and reliability theory. Application 13.30 is easy. Applications 13.31-13.33 were given in Rinott (1976), and Application 13.36 was given independently by Karlin and Rinott (1983) and Tong (1983, 1989).
356
13. Convexity and Moment and Probability Inequalities
13.30. Application. Let X = (XI , ... ,Xn ) have a probability density function [(x) and distribution function F(x). If [(x) satisfies the condition in Theorem 13.23(b) for some S E [-00, lin), then F( axl + (1
Proof.
-
) )
a X2
~
{[a(F(xI))S + (1- a)(F(x2)Y]lIs for S';tO I (F(XI))£>:(F(X2)) -£>: for s = o.
Choosing B, = {x:x E aB I
~ n , x:5
+ (1- a)B 2 = {x:x E
Xi} for i
= 1, 2, we have
~ n , x es aXI
+ (1- a)x 2}.
Thus the inequality follows from Theorem 13.23.
0
For s = 0 this result states that the distribution function of an n-dimensional random vector is log-concave if its density function is log-concave.
13.31. Application. Let (XI, ... , X n) have density function [(x) such satisfies the condition in Theorem 13.23. Let that t T/J(tl, ... , tn-I), 112(t1, ... , tn-I) be the implicit functions given by the equations tn-I, X n :5 T/J(tl,
, tn-I)]
= aI,
P[X I ~ t 1 , ... , X n_1 ~ tn-I, X; ~ T12(tI,
, tn-I)]
= a2'
P[X I :5 t l
for
arbitrary
1}j(t1' ... , tn-I)
defined in
, .•• ,
X n_l
:5
but fixed aj E (0, 1) (j = 1, 2). Then for j = 1, 2, is a concave function on the convex region where it is
~ n - I .
When n = 2 and [ is the bivariate normal density function, this result was given earlier by Tihanski (1972).
13.32. Application. Consider the problem of hypothesis testing concerning a location parameter 0 E ~ n of a density function [(x - 0). If (i) the acceptance region is a convex set in ~ n , (ii) the test is ao-similar on the boundary of H o (under the null hypothesis), and (iii) [(x) satisfies the conditions in Theorem 13.23 for some S E [-00, lin), then the test is unbiased with level ao' 13.33. Application. Let
[(x),
(XI' ... ,Xn), satisfy (13.19).
the density Let eJ>(x): ~ n-
function of X = be a log-concave
~
13.7. Some Statistical Applications
357
function of x and define G(t) = P[ ep(X) 2: t]. Then Theorem 13.20 implies G(at l
+ (1- a)t z) 2: (G(tl»"'(G(tzW-'"
for all t l , t z 2: 0 and all a E [0,1]. concave function, this result implies the life lengths of n independent log-concave, then the distribution of increasing failure rate property.
Since ep(x) = min{xl' ... ,xn } is a that if the joint density function of components in a series system is the life length of the system has the
The final application (Application 13.36) given later is for the special case when f(x) is both log-concave and permutation invariant. We first observe
13.34. Fact. Let the probability density function of X = (Xl, ... , X n ) be permutation invariant and log-concave. Then
P[X E (aB + (1- a)3t(B))] 2: P[X E B], where 3t(B)
= {y: y = 3t(x), X E B}
and 3t(x) is any given permutation of x. By applying this result to n-dimensional rectangles, we obtain the following result: Let B be an n-dimensional rectangle given by B
= B( c., cz) = {x: x E
~ n , Cli :5 Xi :5 CZi
for i
= 1, ...
,
n},
where Cz
= (CZI ,
•.. ,
czn ) ,
and Cli < CZi (i = 1, ... ,n). Let 3t = (Jrl' ... , Jr n ) be a permutation of (1, ... , n) and let b be the inverse permutation of 3t. Then it is easy to see that 3t(B)
== {x: x E
~",
= {x: x E
~ n , CI6 t :5 Xi :5 CZ6 i
CIi :5 X n,
:5 CZi
for i = 1, for i
= 1,
, n} , n}.
Thus aB
+ (1 -
a)3t(B)
= {x: x E ~ n , aCti
+ (1 -
a)C 16i :5 Xi :5 aCZi
+ (1 -
a)c Z6 i
for i
=
1, ... ,
n},
358
13. Convexity and Moment and Probability Inequalities
which is also an n-dimensional rectangle. Now let {:It!, ... , :lt n !} be the group of n! permutations, and for a'i ~ 0, ~ 7 ~ 1a'i = 1 consider the rectangle given by n!
S
=L
(13.30)
a'iJri(B).
i=l
Then we have (Karlin and Rinott, 1983, and Tong, 1983, 1989):
13.35. Fact. S is of the form (13.30) iff there exists an n stochastic matrix Q such that d,
= (d ll ,
..• ,
dIn)
= ClQ,
X
n doubly
d z = (d zl , ... , d zn) = czQ
and
S = {x: x E IR n, d li
::; Xi::;
dzJor i = 1, ... , n}.
For notational convenience we may write S = Q(B). Note that when < Cli < CZi < 00 (i = 1, ... , n), the perimeter of S is equal to the perimeter of B, but S is closer to being an n-dimensional cube. Using Theorem 13.20 and Fact 13.34, Karlin and Rinott (1983) and Tong (1983, 1989) independently obtained: -00
13.36. Application. Let f(x), the density function of X= (Xl' ... ,Xn ) , be permutation invariant and log-concave. Then for every given n-dimensional rectangle B, we have P[X E B]::; P[X E Q(B)]
for each n x n doubly stochastic matrix Q. In particular,
(13.31) holds, where Cj
= (lin)
n
~ cji
is the arithmetic mean (j = 1, 2).
i=l
13.37. Remarks. (a) With the definition of multivariate majorization stated in Definition 12.34, an equivalent condition on A, B in Application 13.36 is that the 2 x n matrix (Cji) majorizes (d ji ) in the multivariate sense. (b) When -00 < Cli < CZi < 00 for each i = 1, ... ,n, the region on the right-hand side of (13.31) is a cube; and the inequality holds when Q is chosen to be the matrix with all elements being lin.
13.7. Some Statistical Applications
359
(c) When Cli = -00 (i = 1, ... , n), Application 13.36 states that the distribution function of an n-dimensional random vector with a permutation invariant log-concave density is Schur-concave. In view of Fact 13.29, this also follows from a result in Marshall and Olkin (1974) (see Corollary 12.31). (d) When Cli = -CZi < 0, the statement in Application 13.36 yields a result in Tong (1982). D
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Chapter 14 Muirhead’s Theorem and Related Inequalities
Muirhead’s theorem is one of the most well-known results involving convexity and majorization and is described in detail in Hardy, Littlewood, and P6lya (1934, 1952, pp. 44-49). In this chapter we first state Muirhead’s Theorem and some analogous and more general results, then describe some useful moment and probability inequalities that follow from their applications. The moment and probability inequalities involve a majorization ordering of the dimension vectors, and have a significant implication in the study of positive dependence of random variables.
14.1 Muihead’s Theorem and Generalizations Muirhead’s theorem, in it original form, deals with an algebraic inequality for positive real numbers:
14.1. Theorem. Let y i > O for i = 1,. . . , n ; a = ( a l , . . . , a,), b = ( b l , . . . , b,) be two n-tuples of real numbers; and let C! denote the summation over the n ! permutations of (yl , . . . , y,). If a > b, then (14.1) i=l
t=l
Marshall and Proschan (1965) proved an inequality for the expectation of permutation-invariant and convex functions of permutation-invariant random variables. Their result, which follows, implies Theorem 14.1 as a special case. 361
362
14. Muirhead's Theorem and Related Inequalities
14.2. Theorem. Let X = (Xl' ... , Xn ) be an n-dimensional random vector with a joint distribution that is permutation invariant. Let a, b be two n-dimensional n-tuples, and 1>: ~ n - - - + ~ be a continuous convex function that is permutation invariant in its n arguments. If a > b, then (14.2)
If 1> is strictly convex, then equality occurs only when a = b, possibly after reordering components, or when the X;'s are all zero with probability one. A convenient reference for the proof of Theorem 14.2 is Marshall and Olkin (1979, p. 287).
14.3. Remark. A special consequence of Theorem 14.2 is that: If a, b, and 1> satisfy the conditions in Theorem 14.2, then (14.3) where I:! is defined as in Theorem 14.1. By choosing i = 1, ... , n,
for each permutation (Jrl, ... ,
Jr n )
Xi
= tny,
for
of (1, ... ,n), and
(14.3) implies (14.1) as a special case.
0
As applications of Theorem 14.2, Marshall and Proschan (1965) gave the following results: 14.4. Theorem. If the joint distribution of X = (Xl' ... ,Xn ) is permutation invariant, then 1
- E max{O, Xl' ... , Xn } is decreasing in n for n = 1,2, . . .. n
(14.4)
Proof. Immediate by letting 1>(Xl,'" ,xn)=max{O,xl,··· ,xn }, a= «n -1)-1, ... , (n _1)-1, 0) and b = (n-1, ... ,n- l) in Theorem 14.2. 0
14.1 Muirhead's Theorem and Generalizations
363
14.5. Theorem. Let Xl' ... , X; be independent and identically distributed random variables with a common distribution function F(x), and let 1J : ~ ~ ~ be continuous and convex. Then (14.5)
is decreasing in n
= 1, 2, ... ,
where F(n) is the nth convolution of F.
Proof. This follows from Theorem 14.2 by letting a = «n1)-1, ... , (n -1)-1, 0), b = (n- 1 , ••• ,n- 1 ) , and Xl, ... ,Xn be i.i.d. D random variables with distribution function F. A different generalization of Theoerm 14.1, given in Proschan and Sethuraman (1977b), concerns the multiplication of log-convex functions. Their result states: 14.6. Theorem. Let x = (Jt1 , ••• , Jr n) be a permutation of (1, 2, ... , n) and let ~ ! denote the summation over all such n! permutations. Let a, b be two n-tuples, 'ljJ(i, z) be a log-convex function in z for each i E {I, 2, ... ,n}, and define (14.6)
Then g(a) 2: g(b) holds for all such 'lJ1 iff a > b. For a continuous analog of Muirhead's theorem, Ryff (1967) gave the following result: 14.7. Theorem. Let a(s), b(s) be two bounded measurable functions defined on [0, 1], and let y(t) be a positive function defined on [0, 1] such that (y(t)Y' ELl for all p E (-00, 00). Let 1
1
g(u, a) = J log{J [y(t)]a(s) dt} ds. o
(14.7)
0
Then g(y,a)2:g(y,b)¢::>a(s»b(s)
for
sE[O,l].
(14.8)
364
14. Muirhead's Theorem and Related lnequalities
A generalization of Theorem 14.7 along the direction of Theorem 14.6 can be found in Proschan and Sethuraman (1977b):
14.8. Theorem. Let 'ljJ(t, z) defined on [0, 1] x (-00,00) be a log-convex function of z for each fixed t. Also let SUPlzlsk 'ljJ(t, z) belong to L 1 for each k < 00. For any bounded measurable function a(s) on [0, 1], define I
g",(a)
I
= f 10g{f 'ljJ(t, o
a(s)) dt} ds.
(14.9)
0
Then g",(a) "2=g",(b)
(14.10)
holds for all such 'ljJ iff a(s) > b(s).
14.9. Remark. Theorem 14.1 follows from Theorem 14.6 by choosing 'ljJ(i, z) = y ~ for i = 1, ... ,n. Similarly, Theorem 14.7 follows from Theorem 14.8 by choosing 'ljJ(t, z) = [y(t)y. 0 14.10. Remark. Examples of log-convex functions 'ljJ(t, x) that arise in probability, statistics, and analysis are as follows: (i)
Laplace transforms. Let f E L1[0, 00) and f(z) "2=0 for all z. Then the Laplace transform f*(x) = f ~fez )e- X Z dz is log-convex where-
ver finite. (ii) Examples of log-convex functions arising in analysis are presented in Mitrinovic (1970, pp. 18-20). (iii) Moments of distributions. Let f be a probability density on [0,00). Then the moment Il<x = f ~ z<Xf(z)dz is log-convex wherever finite (see e.g., Theorem 13.8). (iv) Additional examples of log-convex functions arising in stochastic 0 processes are given in Keilson (1971).
14.2.
Moment Inequalities
Applying Theorem 14.1 to permutation-invariant nonnegative random variables, we obtain the following moment inequality (Proschan and Sethuraman, 1977a; Tong, 1977):
14.2 Moment Inequalities
365
14.11. Theorem. Let (Zl' ... , ZN) have a permutation invariant density function such that p [ n ~ {Z, l 2: O}] = 1, and let a = (ai, ... , aN) and b = (b 1 , ••. , b N) be two N-tuples. If a > b, then E
Proof.
N
N
j=l
j=l
IT Zji 2: E IT ZJi.
(14.11)
By Theorem 14.1, for every w in the sample space the inequality N
N
IT
~ ! ~ Z';;lw) 2 : ~ ! j=l
(14.12)
Z~lw)
j ~ l
holds, where I:! denotes the summation taken over all permutations of (1, ... , N). The conclusion follows by taking expectations on both sides of (14.12) and the permutation invariance property of the distribution function. 0 A special case of Theorem 14.11 is 14.12. Corollary. For {3 E [0, 00) let !l(3 denote the 13th moment of the random variable Z(!lo == 1). If Z 2: 0 a.s. and a> b, then N
N
IT !lo} 2: IT !lbi'
j=l
First Proof. Immediate from Theorem Z, Z, , Z2' ... , ZN be i.i.d. random variables For the special case in which aj is possible:
(14.13)
j ~ l
2:
14.11
by
letting
o
0 and b, 2: 0 for all j, a different proof
Second Proof. Without loss of generality, we may assume that a 1 < b, :s: b 2 < a2, a l + a2 = b l + b 2 and a, = b; (i = 3, ... , n). The conclusion then follows immediately from Theorem 13.8. 0 14.13. Remark. Corollary 14.12 asserts that the function tjJ(a) = IIf=l !loi is a Schur-convex function of a. This result, in fact, is equivalent to Theorem 13.8 and is closely related to a known classic result in Hardy, Littlewood, and P6lya (1934, 1952, p. 72). It will be used in the rest of the chapter to derive probability inequalities for a class of positively dependent random variables. 0
366
14. Muirhead's Theorem and Related Inequalities
14.3. Additional Inequalities for Exchangeable Random Variables Applying Corollary 14.12 to exchangeable random variables (defined in Definition 13.11), we have the following result (Tong, 1977): 14.14. Theorem. Let X I , . . . ,Xn be exchangeable random variables and let a = (ai, ... , aN) and b = (b l , . • • , b N) be vectors of nonnegative integers such that I:;':I a; = I:;':I b, = n. Let B c ~ be an arbitrary but fixed Borel-measurable set, and denote
y(k) =
p[O {X;
E
J.
k= 1, ... , n,
B}
as defined in (13.15), where y(O) == 1. If a > b, then N
N
Il y(a;) ~Il y(b;). ;=1
(14.14)
; ~ I
Proof. Following the line of argument given in the proof of Theorem 13.16, from Corollary 14.12 we have
N
= Il ErQj(V) j ~ 1
Jl N
~
Jl N
Erbj(V)
=
rt b
E[ E
IB(g(V;, v)) I V
=
v]
N
=
n y(bJ
j=1
where r( v) = E {IB(g( VI, v)) I V
= v} is the
conditional expectation.
o
Note that Theorem 14.14 implies Theorem 13.16, but the converse is false. To see this, consider the inequaltiy y(n - 1)y(1)
~ y(n
- 2)y(2),
n
~ 3,
which follows from (n - 1, 1) > (n - 2,2) and Theorem 14.14. But Theorem 13.16 fails to apply.
14.3. Additional Inequalities
367
A special result from Theorem 14.14 and (n, 0, ... ,0) > (1, 1, ... , 1) is that
p[O {Xi
E
B}]
2:
D
P[Xi E B].
(14.15)
Since the right-hand side of (14.15) corresponds to the case of independent Xl' ... , X n , this result can be restated as:
14.15. Fact. Let Xl, ... , X; be exchangeable random variables and let ¥t, ... , Yn be i.i.d. random variables such that Xi' 1'; have a common marginal distribution. Then
p[O {X;
E
B}] 2:
p[O {1';
E
B}
J
(14.16)
holds for all Borel-measurable sets Be IR. A question of interest is whether the inequality in (14.16) also holds when the 1';'s are less positively dependent than the X;'s in a certain fashion. This leads to the problem of a partial ordering of positive dependence of exchangeable random variables, a natural extension from the comparison between positively dependent random variables and i.i.d. random variables to the comparison between two sets of exchangeable random variables. Rinott and Pollak (1980) and Shaked and Tong (1985), among others, studied this problem recently and obtained results under reasonable assumptions. A special result they obtained is for exchangeable normal variables (Rinott and Pollak, 1980, for n = 2, Shaked and Tong, 1985, for general n):
14.16. Fact. Let X I , . . . , X; be exchangeable normal variables with a common mean fl, a common variance o", and a common correlation coefficient pz. Let YI , . . . , Yn be exchangeable normal variables with a common mean fl, a common variance o", and a common correlation coefficient Pl' If 0 ~ PI < Pz, then E r r 7 ~ 14>(X;) 2: r r 7 ~ 41 >(1';) holds for all Borel-measurable functions 4>: IR - [0,00) such that the expectations exist. Consequently (14.16) holds for all Borel-measurable sets B. 14.17. Remark.
For n = 2, E
m=1 4>(X;) 2: E
r r ~ ~ 14>(1';) holds iff
Corr(4>(X I ) , 4>(Xz)) 2: Corr(4>(¥t), 4>(Yz))
(14.17)
368
14. Muirhead's Theorem and Related Inequalities
holds, which is the motivation given by Rinott and Pollak (1980) for studying this problem. Furthermore, if
14.4. Inequalities for a Class of Positively Dependent Random Variables We now show how to use the Muirhead-related moment inequality given in Theorem 14.11 to obtain more general results. We consider ndimensional random vectors X == (Xl' ... ,Xn ) and Y == (YI , . . . , Yn ) such that the X/s are not necessarily exchangeable and the Y;'s are not necessarily exchangeable, but they all have a common marginal distributon. We show that if the X;'s are more positively dependent than the Y;'s in a certain fashion, then the inequality in (14.16) holds. To obtain sufficient conditions for such a partial ordering, we first consider a sequence of i.i.d. random variables {V;}7=1> another inde' an independent pendent sequence of i.i.d. random variables { V ; } 7 ~ 1and random variable W as "building blocks." Then for a given Borel measurable function g: [ffi3 ~[ffi and a fixed n-tuple of nonnegative integers k == (k l
, ••• ,
k., 0, ... , 0),
1:s r z: n, r
k, ~ 1 for
j:S rand
2: k, == n,
(14.18)
j=l
we define an n-dimensional random vector
~ ==
(;], ... , ;n) given by
and ;k t+---+k,_1+ 1
== g(Vk 1+ ---+ k , _ I+ I , V" W), ... ,
;n == g(Vn, V"
W).
(14.19)
That is, each of the ;;'s depends on the common variable Wand on a different variable Vi' Furthermore, the first k 1 of them depend on the common variable VI' the next k z of them depend on the common variable Vz , and so on. The vector (';1, ... , ';n) will be denoted by l;(k).
14.4. Inequalities via Positive Dependence
369
It is obvious that ;1' ... , ;n have a common marginal distribution. Furthermore, the vector k plays an important role in the positive dependence of ;(k). Consider the following two special cases. Case 1: (i) W is a singular random variable and (ii) k = (1, 1, ... ,1). Clearly ;1, , ;n are i.i.d. random variables. Case 2: (i) P[ U; = u] = 1 (i = 1, , n) and (ii) k = (n, 0, ... ,0). Then P[;! = ... = ;n] = 1, so that Corr(;;, ;;') = 1 for i =1= i', This illustrates the fact that for given random variables {U;}, {V;}, and W, the "strength" of the positive dependence of the components of !;(k) can be partially determined via the diversity of the components of k. In the following theorem (Tong, 1989) we make this idea more precise by using Corollary 14.12.
14.18. Theorem. For fixed n 2:2 assume that (i) {U;}7, {V;}7, and W are stochastically independent, U1 , ••• , U; are i. i. d., V1 , ••• , Vn are i.i.d., (ii) g: ~ 3 _~ is any Borel-measurable function, and (iii) k and k* are two vectors of the form given in (14.18). Let X = !;(k) and Y = !;(k*) be two random vectors as defined in (14.19). If k > k*, then E
n
n
;=1
;=1
n eJ>(X;) 2: E n eJ>(Y;)
(14.20)
holds for all Borel-measurable functions eJ>: ~ - [0, 00) such that the expectations exist. Consequently (14.16) holds.
Proof. write
For every given eJ> 2: 0 such that the expectations exist, we can
r
= En E[ rki(l-) , W) I W],
(14.21)
j=l
where (14.22) denotes the conditional expectation. Now for every given W = w the random variables r(V1 , w), .... , r(Vn , w) are i.i.d. and are 2:0 a.s. By defining Ilkj to be the krth moment of r(l-), w) and applying Corollary l w) 2: TIj:1 Erkt(l--j, w) holds for every 14.12, we see that T I j ~ Erkj(l--j,
370
14. Muirhead's Theorem and Related Inequalities
fixed w. Thus E
n
r
i=1
j=1
f1 (Xi ) = E f1 E[ rkj(l-j, 2:: E
I
W) W]
r"
n
j ~ 1
i ~ 1
II E[ rkt(l-j, W) I W] = E Il (1';).
D
In the following corollary we show that if the elements in k and k* are even integers (including 0), then the condition that eJ> 2:: 0 can be dropped. 14.19. Corollary. Let {Uin {V;E, W, and g satisfy the conditions stated in Theorem 14.18. Let k, k" be two n-tuples such that their components are nonnegative even integers. If k > k", then (14.20) holds for all Borel-measurable functions : IR ~IR such that the expectations exist. Proof,
The proof is as for Theorem 14.18 since 1k> 1k*.
D
In certain applications the special case k" = (1, ... ,1) is of great interest. In the following corollary we show that if the vector k contains only even integers, then again the condition that 2:: 0 can be removed. 14.20. Corollary. Let {Ui H, {V;H, W, and g satisfy the conditions in Theorem 14.18. Let k, k" be two n-tuples such that k" = (1, ... ,1) and the components of k are nonnegative even integers such that ~ 7 = k1 , = n. Then (14.20) holds for all Borel-measurable functions : IR ~IR. Proof. For every fixed W = w the function r defined in (14.22) satisfies (again from Corollary 14.12) r
Il Erkj(l-j, w) 2:: [Er
2
(V1 '
wW/2 2:: [Er(V1 , wW·
j=1
The conclusion then follows after unconditioning.
D
As a special consequence, we observe 14.21. Corollary. Let {UiH, {V;}'i, W, and g satisfy the conditions in Theorem 14.18, and let s(k) be the random vector defined in (14.19). Let
14.5. Applications to Special Families
371
k = (n, 0, ... , 0), k* = (1, ... ,1), and let n be an even positive integer. Then (14.16) holds for all Borel-measurable functions cf>: ~ ~ ~ .
In certain applications to be discussed in Section 14.5 we restrict our attention to a family of random variables such that ;(k) is obtained by choosing k = (s, 1, ... , 1,0, ... ,0) in (14.18). For notational convenience we shall denote this random vector by ;(s). The following corollary shows how the components of ;(s) depend on s. Its proof follows immediately from Theorem 14.18 and is omitted. 14.22. Coronary. Let {U;}7, { ~ H ,W, and g satisfy the conditions in Theorem 14.18. For given s 2: 1, let ;(s) = (;1' ... , ;n) be the random vector obtained according to (14.18) by choosing
k2
= ... = k n - s + l = 1,
kn -
s +2
= ... = k; = O.
Let X = ;(s + 1) and Y = ;(s). Then (14.20) holds for all such cf> all n, and all s < n.
14.5.
(14.23) 2:
0, for
Applications to Special Families of Random Variables and Distributions
In this section we state some applications of the main results in Section 14.4 for obtaining inequalities via this partial ordering of positive dependence for several families of random variables and distributions (see Tong, 1989).
14.5.1.
Exchangeable Random Variables
Consider the random variables defined for i X;=g(lf;, VI' W),
= 1, ... , n by
Y;=g(U;,
~ , W).
Then Xl' ... ,Xn are exchangeable and Y\, ... , Yn are exchangeable. But for k = (n, 0, ... ,0) and k" = (1, ... ,1), we have X 4 ;(k) and y 4 ;(k*). Thus a partial ordering of positive dependence can be
372
14. Muirhead's Theorem and Related Inequalities
obtained by applying Theorem 14.18 and the related results given in Section 14.4 By applying this result to the exchangeable normal, t, chi-square, gamma, F, and exponential variables, we obtain many useful inequalities as special cases. The multivariate normal variables will be treated separately in this section. Exchangeable exponential variables can be obtained by taking feu, v, w) = min(u, v, w) as considered previously by Marshall and Olkin (1967), and have an important application in reliability theory.
14.5.2.
Distributions with the Semigroup Property
Let {fe(x): () E Q} denote a family of density functions, and assume that Q is an interval of real numbers or an interval of integers. It is said to possess the semigroup property (see, e.g., Proschan and Sethuraman, 1977a) if ()', ()" E Q implies ()' + ()" E Q and the convolution fe'(x) * fe"(x) = feo+e'.(x),
14.23. Application. Let X e,I' ... , Xe,n denote i.i.d. random variables with density fe(x), and for fixed ()o and ()o - () E Q let X eo-e denote another independent random variable with density feo-eCx). Next define an n-dimensional random vector X( () = (XI' ... , X n) such that Xi = Xe,i + X eo-e for i = 1, ... ,n. If {fe(x): () E Q} possesses the semigroup property and if ()1, ()z E Q, ()1 =1= ()z implies 10 1 - Ozl E Q, then (a) E e II7=1 ¢(Xi ) is a decreasing function of () for () < ()o for all Borelmeasurable functions ¢ ~ 0 (provided that the expectation exists); (b) E e II7=1 ¢(X;) is a decreasing function of () for () < ()o for all even positive integers n and all Borel-measurable functions ¢; (c) Pe[XI E B, ... , X; E B] is a decreasing function of () for () < ()o for all Borelmeasurable sets B c IR . Proof. For every fixed ()1' ()z E Q such that ()1 < ()z < ()o, define U; = X elo i' ~ = X e 2 - e l o i ( i =... 1 , ,n) and W=XeO-Xe2. The conclusions follow from Theorem 14.18. D Note that Application 14.23 applies to the binomial, gamma, Poisson distributions, the Poisson process, and several other distributions.
14.5. Applications to Special Families
14.5.3.
373
The Multivariate Normal Distribution
Applying Theorem 14.18 we now show how the positive dependence of a multivariate normal variable with a common marginal distribution can be partially ordered via the correlation coefficients.
14.24. Application. Let 0::; PI < pz::; 1, k and k* be two n-tuples of nonnegative integers given as in (14.18), and R =R(k) = (Pij) be a correlation matrix such that for i =1= j, Pij
= ,-I
pz if 1::;i,j::;k l,k l+1::;i,j::;kl+k z , ... , :!=/m+ 1::;i,j::;n; {
PI
otherwise.
[That is, the random variables X I, . . . , X; are partitioned into r groups of sizes k«. ... , k, respectively; the correlation coefficients of the variables within the same group are pz, and the correlation coefficients between groups are Pl'] Let X - . N " n ( crR(k)) ~ , and Y ~ K n ( ~aZR(k*)), , where ~ = ( t J "... , tJ,). (a) If k>k*, then (14.20) holds for all such
Proof.
The result follows immediately by choosing
g(u, v, w) = tJ,
+ a(Y1- pz u + YPz - PI V tV;;; w)
in Theorem 14.18 and Corollary 14.19.
D
14.25. Example. Let X = (Xl' X z , X 3 , X 4 ) have a multivariate normal distribution with a common mean, a common variance, and a correlation matrix R. Let pz pz 1 pz PI pz pz 1 PI ' PI PI PI 1 pz PI 1 PI PI PI PI 1 pz PI PI pz 1
R'~C R'~C'
P') P')
374
14. Muirhead's Theorem and Related lnequalities
Then 4
E Pij=P2
4
IT cfJ(X
i)
i=l
holds for all cfJ
~E
R=R 3
IT cfJ(X
i)
4
;=1
~0
IT
4
IT cfJ(X
~ E R ~ R 2 cfJ(Xi ) ~ E P i j ~ P I i=1
i)
;=1
and all 0:5 PI < pz :5 1.
Proof. This follows from Application 14.24 and the fact (4,0,0,0) >(3,1,0,0) >- (2, 2, 0, 0) >- (1,1,1,1). 0 A special consequence of Application 14.24 is the result given in Fact 14.16 for exchangeable normal variables. For other related applications in the multivariate normal distribution, see Tong (1990, Chapter 7).
Chapter 15 Arrangement Ordering
In this chapter we present the theory of a relatively new partial ordering of vectors (of length n, unless otherwise indicated) based on the n! permutations of their elements. We consider functions that increase as the arrangement of vector elements becomes more ordered. As an unexpected bonus, we find that we can obtain as special cases majorization and Schur functions, totally positive functions of order two, and positive set functions. Our discussion is largely based on Hollander, Proschan, and Sethuraman (1977). Applications of this arrangement ordering theory in probability, statistics, reliability, and rearrangement inequality mathematics are presented in Chapters 16 and 17.
15.1.
Definitions and Basic Properties
Let S be the group of permutations of (1,2, ... ,n). A member of S is denoted by n = (n 1 , ••. , nn)' The product operation is the composition of 1[ and 1[' E S; i.e., 1[01['(i)
= 1[(1['(i)),
i = 1, ... ,n,
(15.1)
where 1['(i) = n;. Thus S is a noncommutative group. The identity element is e = (1, ... ,n).
15.1. Definitions. (a) Let 1[ and 1[' be two members of S such that 1[' contains exactly one inversion of a pair of coordinates that occur in the 375
376
15. Arrangement Ordering
natural order in :n:; e.g., (15.2) (15.3) where i <j and x, < Jrj' We say that :n:' is a simple transposition of :n:; in t symbols, :n: > :n:'. (b) Let :n: and :n:' be two elements in S such that there exists a finite number of elements :n: D, :n: 1 , ••. , :n:k in S satisfying :n: = k 1> :n:D>:n: ... >:n: = :n:'; i.e., :n:' is obtained from :n: by a finite number of simple transpositions. We say that :n: is better arranged than :n:'; in sumbols, :n::5- :n:'. Note that the elements of S are partially ordered by arrangement.
15.2. Definition. A function f from S into IR is increasing in arrangement or arrangement increasing (AI) if :n::5-:n:' implies that f(:n:) 2:: f(:n:') for :n:, :n:' in S. In earlier papers on the subject, the term "decreasing in transposition" was used rather than "arrangement increasing."
15.3. Remark. From Definitions 15.1 and 15.2, it is clear that the simplest way to obtain a result for AI functions is to consider a pair of permutations :n: >:n:' that by definition differ only in two coordinates. Thus we will see that proofs throughout are generally brief and simple. In the same vein, we will see that generalization and strengthening of certain well known rearrangement inequalities may be achieved by arguments shorter and simpler than those used in the original proofs. See, e.g., results in Section 15.2. 0 15.4. Examples. The following functions are AI functions from S into IR: (a) fl(:n:) = -(Jrl + ... + Jrk) for 1 :s k :s n. (b) h(:n:) = ~ 7 ~ a1 .x., where al:S' .. :S an' (c) N:n:) = r 1 7 ~ lg ()'i, Jr i), where AI:S"':S An' and g(A, i) is totally positive of order 2 (TP z) for -00 < A < 00, i = 1, ... , n.
15.1. Definitions and Basic Properties
377
(d) hen) = I : 7 ~ 1g (A;, nJ, where A1 s; ... S; An' and g(A, i) is a nonnegative set function; i.e., -00 < A1 < Az < 00, 1 s; i 1 < i z s; n implies that g(A1, i 1) - g(A1 , i z) - g(Az , i 1) + g(Az , i z) ~ O. (e)
1 if fen) ~a fsCn) = { 0 if fen) < a,
where f is an AI function on S.
0
Thus far we have considered functions of one vector argument. Next we consider functions of two vector arguments. Let g(A, x) be a function from IR n X IR n into IR. Let Aon denote (An" ... , An.), where n is a permutation in S. We say that g(A, x) is permutation-invariant if g(A 0 n, x 0 n) = g(A, x)
(15.4)
for all n E S; i.e., applying a common permutation to both vector arguments Aand x leaves the function g unchanged. 15.5. Definition. Let A, M be subsets of IR. We say that g(A, x) is arrangement increasing (AI) in (A, x) (or in A and x) on An X M" if
(i) g(A, x) is permutation-invariant, and (ii) AEAn , xEM n , A1 S; · · ·S;An, X1S; .. ·s;xn, n$.n' implies that , g(A, xon) ~ g ( A xon'). Note that condition (ii) above may be replaced by the equivalent condition: (ii') Define[;..,x(n)=g(A,xon), where A1S;···S;An andx1s;·· ·s;xn. Then f.jn) is AI on S. In the statistical context, we may think of Aas a parameter vector, x as an outcome vector, and g(#.-, x) as the corresponding density. In a probabilistic context, we may view g(A, x) as the probability that a Markov chain makes a transition from permutation state #.- to permutation state x in a step. 15.6. Examples. The following functions are AI functions on IR n x IR n .
(a) g6(A, x) = h(#.- - x), where h is a Schur-concave function on IR n ; g6,(A, x) = h(A + x), where h is a Schur-convex function on IR n •
378
15. Arrangement Ordering
(b) g7(l, x) = 07=1 ¢(A i , Xi), where ¢(A, x) is TP z in -00 < A< 00, < x < 00. Conversely, if an AI function gel, x) is of the form 07=1 ¢(Ai , Xi) with ¢ 2= 0, then ¢ must be TP z . -00
(c) g8(l, x)
= :E7=1 ¢(Ai , x;),
where ¢ is a nonnegative set function.
0
We can also define AI functions on IR n • A function h defined on M" is said to be arrangement increasing (AI) on M" if for every x E M" with Xl::; ••. ::; Xn and for every pair n, n' E S satisfying n >- n', we have
h(xon) 2= h(xon').
(15.5)
Note that the corresponding function defined by
fin)
= h(xon) is AI on
S.
(15.6)
It is clear from the definitions above that AI is essentially a property of functions on S. In most situations we can put A = IR = M, though in some cases, like Corollary 15.16, and in some applications, the functions are defined only on An x M", where A and M are proper subsets of IR. Thus it is more convenient for many theoretical and practical applications to formulate the AI property for functions on IR n x IR n and on IR n . We summarize the relationships among the various domains in the following lemma. From now on we set A = M = IR, unless essential generality is to be gained by doing otherwise.
15.7. Lemma. IR n • Define (i) g*(x, l)
Let gel, x) be a permutation-invariant function on IR n x
= gel, x)
(ii) h..(x) = gel, x) for
for l, x E IR n , X E
(iii) A.in) = gel, xon) for
IR n,
AI::; ... ::;
AI::;' .. ::;
An'
An' Xl::;'
•• ::;X n ,
and n
E
S.
Then the following statements are equivalent; (a) g is Alan IR n
X
IRn.
(b) g* is Alan IR n X IRn. (c) h;. is Alan IR n for each l such that AI::;' .. ::; An' (d) A.x is Alan S for each l and x such that AI::;"'::; An and Xl::;"
·::;xn ·
15.2. Arrangement Increasing Functions
379
The equivalences follow immediately from the definitions of the various types of AI functions. The next lemma shows that the concept of an AI function yields as special cases such well known and useful concepts as (a) Schur-concave and Schur-convex functions, (b) total positivity of order 2, and (c) nonnegative set functions. 15.8. Lemma.
(a) Let g(J.., x) = h(J.. - x). Then g is AI on
is Schur-concave on
(b) Let g(J.., x) convex on [Rn.
[Rn X [Rn
iff h
[Rn.
= h(J.. + x).
Then g is AI on [Rn
X [Rn
iff h is Schur-
(c) Let g(J.., x) = II7=1 h(Ai' Xi). Then g is AI iffhis TP2 in J.. and x. (d) Let g(J.., x) = ~ 7 = h1 (Ai, Xi). Then g is AI iff h is a nonnegative set function.
Proof. We give the proof of (a) only. The rest are proved similarly. Let AI::;A2 and Xl ::; X2::; ... ::; Xn ; Now
and (AI - X2, A2 - Xl) majorizes (AI iff h is Schur-concave. D
15.2.
Xl,
A2 - X2). This shows that g is AI
Preservation Properties of Arrangement Increasing Functions
In this section we show that the AI property is preserved under a number of basic mathematical and statistical operations. 15.9. Lemma. Let g(J.., x) be AI on [Rn X [Rn. Let f and h be permutation-invariant and nonnegative functions on [Rn. Then k(J.., x) =' f(J..)g(J.., x)h(x) is AI on IR n X [Rn.
Proof. The conclusion follows immediately from the definition of an AI function. D
380
15. Arrangement Ordering
The AI property is preserved under mixtures:
15.10. Theorem. Let fer be AI on S and integrable with respect to nonnegative measure. Then fen) = f fer(n) dp,(a) is AI.
p"
a
The proof is obvious and hence omitted. A similar preservation under mixtures property holds for AI functions g(A, x) on ~ n X ~ n and AI functions hex) on ~ n . More interesting and useful is the fact that the AI property is preserved under composition:
15.11. Theorem. Let gj be AI on ~ nX ~ n , i = 1, 2. Let g(x, z) = f ... f gl(X, y)gz(y, z) doiy«, ... ,Yn) be well defined, where fA da(y) = fA da(yon) for each permutation n E S and Borel set A in ~ n . Then g(x, z) is AI on ~ n X ~ n . Proof. g(x, z) is obviously permutation-invariant. To complete the proof it will suffice to show that g ( x , z ) - g ( x , z ' for ) ~ OXI:5·· ·:5xn, Zl < Zz, z ~ = Zz, z ~= Zl, and z{ = z, for i = 3, ... , n. Write g(x,z)-g(x,z') =
f··· J
[gl(X,YI,YZ," .)gZ(YI,YZ,'" ;ZI,ZZ,"')
-gl(X;YI,YZ," .)gZ(YI'YZ'···;zz, Zl," .)]da(y),
(15.7)
where the " ... " indicates natural ordering of the omitted arguments. Breaking up the region of integration into the two regions YI < Yz and YI ~Yz, and making a change of variable in the second region yields:
g(x, z) - g(x, z')
=
J... J[gI(x; YI , Yz, ... )gZ(YI, Yz, ... ; Zl, z«, ... ) y,
-gl(X;Yl,YZ," .)gZ(Yl,YZ,"·;zz, Zl"")
=
+gl(X;YZ, Yl,
)gz(Yz, Yl,
; Zl, Zz,
)
-g\(x; Yz, YI,
)gz(Yz,YI,
, Zz, Z\>
)] da(y)
J.. -J [gl(X; y)gz(y; z) - gl(X, y)gz(y; Zz, Zl, ... ) y,
+gl(X; Yz, YI,
)gz(y; Zz, Zl' ... )
-g leX; Yz, YI ,
)gz(y, z)] da(y),
15.2. Arrangement Increasing Functions
381
by virtue of the permutation-invariance property of gz and of a. The integrand may be rewritten as [gl(X, y) - gl(X; Yz, Yl , ... )][gz(y, z) - gz(y, ZZ, ZI , ... )].
Since gl (gz) is AI, the first (second) square bracket is nonnegative. Thus 0 the integrand is nonnegative, and so g(x, z) - g(x, z') ~O. In a similar fashion, we may prove analogous composition theorems for AI functions on S and ~": 15.11'. Theorem.
Let fl and 12 be AI functions on S. Define f(1t)
= 2:
fr(1t° o1t- 1)fz(1t°).
(15.8)
ri'ES
Then f is an AI function on S.
15.11". Theorem.
Let hi and h z be AI functions on
h(1t)
=
is well defined for each
J... J h 1t
1(x
o1t- 1)h
~ n . Suppose
z(x) dx ; ... dx;
that
(15.9)
in S. Then h is an AI function on S.
An immediate application of the composition theorem (Theorem 15.11) and of Lemma 15.8(a) is: Let hi be Schur-concave on ~ n , i = 1, 2. Let h(x) = - y)hz(y) dYI ... dy; denote the convolution of hI and h z· Then h is also Schur-concave on ~ n .
15.12. Corollary.
J ... J h
1(x
Corollary 15.12 is equivalent to the main result in Marshall and Olkin (1974) (see Theorem 12.30). Given a multivariate density f(";.., x) with parameter vector ";.., let F(";.., x) denote the corresponding distribution function and F(";.., x) denote the joint survival probability f:, ... r;J(";.., y) dYI ... dy.: Then the next corollary shows that both F(";.., x) and F(";.., x) inherit the AI property from f(";.., x). 15.13. Corollary. Write H(u) = 1 if u,
Let f(";.., x) be AI. Then F(";.., x) and F('#.., x) are AI.
= J ... f f('#.., x)H(x - y) dYI ... dy;; where = 1, ... ,n, and 0 otherwise. Now !('#.., y) is AI by
F('#.., x)
Proof.
~0,
i
382
15. Arrangement Ordering
hypothesis, while H(x - y) is AI, as is readily verified. Thus F()', x) is AI by the composition theorem. Writing F()', x) == f ... f f()., y)H(y - x) dYI ... dYn, we may prove F()', x) is AI by the same argument. D The AI property of nonnegative functions is preserved under products: 15.14. Theorem. Let gi(X, y) be a nonnegative AI function on IRn i = 1, 2. Then g(x, y) == gl(X, y)g2(X, y) is AI on IR n X IR n.
X
IRn,
The proof is obvious and thus omitted. A similar preservation under products property holds for AI functions f(1£) on S and AI functions h(x) on IR n • To present the next preservation property of AI functions, we need some definitions. Let A and T be semigroups in IR. Let f-l be a measure on T. It is said to be invariant if f-l(A
n T) = f-l«A + x) n T)
for each Borel set A of IR and each x E T. A measurable function ep()., x) integrable with respect to u, defined on An X T" is said to have the semigroup property with respect to u if for each ).1' ~ in An and x in T", ep().1 + ~ , x) =; f T" CP().I' X - y ) c p ( ~ y) , df-l(Yl) ... df-l(Yn). The next theorem shows that the Schur-convex (Schur-concave) property of functions is preserved under an integral transform by an AI function possessing the semigroup property. 15.15. Theorem. Let f(x) be Schur-convex (Schur-concave) on IR n. Let cp()., x) defined on An X T" have the semigroup property with respect invariant measure f-l and be AI. Let h()') = to an f T" cp(A, x)f(x) df-l(x 1) ••• df-l(x n) be well defined for). E An. Then h()') is Schur-convex (Schur-concave).
Proof.
We write
h()' + A')
=
J ep(). + ).', x)f(x) df-l(X1) ... df-l(x n) Tn
=
J ep()., x - y)ep().', y)f(x) df-l(Yl) ... df-l(Yn) df-l(Xl) ... df-l(x T2n
n)·
15.2. Arrangement Increasing Functions
Substituting z = x - y and using the fact that h(i.+I:)=
f
~ is
383
invariant, we obtain
q>(i.',y)
Tn
x
[f
q>(i., Z)f(z + y)
d ~ ( z 1 .) .. d ~ ( z n] ) d ~ ( Y 1 ... ) d~(Yn).
Tn
Since q>(i., z) is AI in i., z and f(z + y) is AI in z, y, the composition, appearing within the square brackets above, is AI in i., y from the composition theorem (Theorem 15.11). By a second application of the same theorem, h(i. + i. ') is AI in i., i. ', and hence h(i.) is Schur-convex (Schur-concave) from Lemma 15.8b(a). 0 The following special case of Theorem 15.15, equivalent to Theorem 1.1 of Proschan and Sethuraman (1977a) (see Theorem 12.32), is obtained by restricting q>(i., x) to be of the form 117=1 q>(A i , Xi). 15.16. Corollary. Let f(x) be Schur-convex (Schur-concave). Let q>(A, x) defined on (0,00) x (0, 00) obey the semigroup property in A with respect to an invariant measure ~ on [0, 00) and be TP z in (A, x). Define (15.10) Then h (i.) is Schur-convex (Schur-concave).
Interpreting q>(i., x) as a multivariate density function with vector parameter i., we may interpret Theorem 15.15 as stating that the Schur property of a function on the sample space is transformed into a corresponding Schur property of the expected value of the function on the parameter space. This type of preservation property is very useful in deriving inequalities and bounds for a variety of multivariate distributions, as shown in Proschan and Sethuraman (1977a) and in Nevius, Proschan, and Sethuraman (1977). By application of the next theorem, we may demonstrate that a large number of well known multivariate densities are AI.
384
15. Arrangement Ordering
Let g(#.., x) be an AI density of X = (Xl' ... ,Xn ) . Let u(x) be a permutation-invariant function on IR n . Then the conditional density guCA, x) of X, given that u(X) = u, is an AI density function.
15.17. Theorem.
Proof. gu(#.., x)
= g(#..,
x)I[u(x)=u]/h(#.., u),
where h(#.., u) is the induced density of u(X). By hypothesis, g(#.., x) is AI. Clearly, I[u(x)=uJ is permutation-invariant, as is the denominator. 0 Thus by Lemma 15.9, the desired result follows.
15.18. Example. The following multivariate densities are AI, as is verified following the listing (the indices of sums and products all range from 1 to n). (a) Multinomial.
where
Ai>
0;
Xi =
0, 1, ... for- i = 1, ... , n;
I:
Ai =
1; and
I: Xi = N.
(b) Negative multinomial. #..
)
gz( ,x
= r(N + I: x;) {(1 + " k)-N- ~ X i } IAfi 1 r(N)
'--'
Xi!'
I
where Ai> 0; Xi = 0, 1, ... for i = 1, ... , n; and N > O. (c) Multivariate hypergeometric.
where Ai = 1, 2, ... , and (d) Dirichlet.
where Ai> 0; Xi 2:: 0 for i (e) Inverted Dirichlet.
where Ai> 0;
Xi 2:: 0
Xi =
0, 1, ... for i = 1, ... , n;
= 1, ...
, n;
I: Xi =
I: Xi:S; 1; and (} > o.
for i = 1, ... , n; and (} >
o.
N
< I:
Ai.
15.2. Arrangement Increasing Functions
385
(f) Negative multivariate hypergeometric.
where Ai>O;Xi=O, 1, ... , N; ~ x i = N and ; N= 1, 2, .... (g) Dirichlet compound negative binomial.
(I... x) g7,
=
r(N + ~ Xi)r( 8 + ~ Ai)r(N + 8) IT r(Xi + Ai) II Xi! r(N)r( 8)r(N + 8 + ~ Ai + ~ Xi) r(Ai) ,
where Ai> 0; Xi = 0, 1, ... for i = 1, ... , n; 8> 0; and N (h) Multivariate logarithmic series distribution.
(I... x) = ( ~ X -i 1)! (1 + ~ A)-Ex; gs, log(l + ~ Ai) L.
IT A:;
I
where Ai> 0; Xi = 0, 1, ... for i = 1, ... , n; and (i) Multivariate F distribution.
= 1, 2, ....
Xi! '
~ Xi >
where Ai> 0 for j = 0, 1, ... , n; A = ~ ~Ai; x.> 0 for j (j) Multivariate Pareto distribution.
O.
= 1, ... , n.
where xi> Ai> 0 for j = 1, ... , n; a> O. (k) Multivariate normal distribution with a common variance and a common correlation coefficient. gl1(l..., x)
= (2Jt)-nIZI1:;1- lI Ze-(lIZ)(X-A)I:-l(x-A)',
where (x - I.)' is the transpose of (x - I.) and 1:; is the positive definite covariance matrix with elements oZ along the main diagonal and elements pif elsewhere, p> -l/(n - 1). To verify that gu gz, g4, gs, and gs are AI, note that AX is TP z, and form Lemma lS.8(c), the product g(l..., x) = II A7; of TP z functions is AI. The additional factors that appear are functions of ~ Xi and thus are
386
15. Arrangement Ordering
permutation-invariant. Hence by Lemma 15.9, the desired conclusion follows. To verify that g3, g6, and g7 are AI, we use a similar argument. We note that the functions
( ~ ) and I'( A + x)
are TP z. The remainder of the
argument is as just above. To verify that S» is AI, we first note that g9 is the joint density of (X)Aj)/(Xo/Ao), j = 1, ... , n, where X, has a xZ-distribution with 2Aj degrees of freedom, j = 0, 1, ... , n. For fixed outcome X 0 = Xo, say, the conditional density of (X)Aj)/(Xo/Ao) is TP z in Aj, Xj' Thus the corresponding joint density of (Xt!Al)/(Xo/Ao),'" , (Xn/An)/(XO/Ao) is AI. By unconditioning on X 0 and using the fact that the AI property is preserved under mixtures (Theorem 15.10), we conclude that g9 is AI. Note that glO is AI since ( ~ Aj-lXj- n + 1)-(a+n) is AI. D
15.19. Remark. Eaton (1967) and Marshall and Olkin (1974) gll is AI. (This can be verified directly from the definition showing that (x - J..)I:-l(x -J..)' ~ ( x -* J..)I:-l(x* - J..)', where .. ' ~ X n , A l ~ A Z ~ '" ~ A n andx*=(xz,Xl,X3"" , ,Xn).)
15.3.
show that of AI by
Xl ~Xz
~
D
Arrangement Increasing Property of Overlapping Sums
In order to state the main result of this section, we need notation as follows: For k = 2, 3, ... , n, let Ik
= {I: I is a subset of size k from {I, ... , n}},
(15.11)
h,i = {I C Ik : i E I}. 15.20. Theorem. Let X={Xl, ... ,Xn}, {XI,Ich}, k=2, ... ,n, be independent collections of random variables. Let X have an AI density function. Let the random variables in {Xl> I c Id be i. i.d. and have a common log-concave density gk, k = 2, ... , n. For i = 1, ... , n let
Zi=Xi +
L
XI
[C]k,i
k"Z:2
Then Z = (Zl, ... , Z,.) has an AI density function.
(15.12)
15.3. Arrangement Increasing Property of Overlapping Sums
387
15.21. Remark. Note that the summands in the ZI' ... , Z; overlap considerably. For example, Xu appears in the expressions for ZI and Z2,X123 appears in the expressions for Z I, Z2' and Z3' etc. Thus, the inheritance of the AI property of Z from that of X is complicated by the overlapping of the X/so 0 15.22. Remark. Theorem 15.20 takes on added interest if we note that the tempting conjecture that "the convolution of AI functions is AI" is false. An even more tempting conjecture that "the convolution of an AI density and a permutation invariant density is AI" is also false. These facts point up the need for the log-concavity of the S« density in the statement of Theorem 15.20. 0 15.23. Remark. Random variables ZI, ... , Z; of the type specified in (15.12) arise routinely in shock models, inventory problems, biometric models, and elsewhere in multivariate statistics, where the occurrence of an event simultaneously affects two or more random variables of interest. A classical example is the multivariate exponential of Marshall and Olkin (1967), where a shock of type (iI' i«. ... , ik) results in the simultaneous failure of components iI, ... ,ik. In Example 15.25 we give illustrative examples from reliability theory, in particular, in which the main theorem would apply. 0 To prove the main result, we shall find it helpful to have available the following lemma:
15.24. Lemma. For some k ~2, let {Xl, I c: h} be i.i.d. random variables with a common log-concave density function g (with respect to the counting measure on a lattice or the Lebesgue measure). Let lV; =
~
x.,
i
= 1, ... ,n.
(15.13)
IEh,i
Let f(Wl' ... , wn ) be the density function of W = (WI' ... , Wn ) . Then f is a Schur-concave function. The proof is rather lengthy; we refer the reader to Hollander, Proschan, and Sethuraman (1981).
388
15. Arrangement Ordering
Note that the result extends the class of Schur-concave functions considerably since it allows for mutually dependent random variables. We now present:
Proof of Theorem 15.20. Let X ~ k= )
L
X},
i = 1, ... , n,
k=2, ... , n.
b=h,i
Let XCk) = ( X ~ k ) ., .. , X ~ k » k, = 2, ... , n, and X = (Xl, ... ,Xn ) . Then Z=X+X(2)+ ... +x(n).
From Lemma 15.24, the density functions of X (2 ) , . . . , x(n) are all Schur-concave. Hence the density of X(2) + ... + x(n) is Schur-concave by Corollary 15.12. Finally, the density of Z = X + (X(2) + ... + x(n» is Schur-concave by Lemma 15.8 and another application of Corollary 0 15.12.
15.25. Example. The density functions of the following distributions are AI densities of overlapping sums: (a) Multivariate Exponential of Marshall-Olkin. Marshall and Olkin (1967) introduce the widely used multivariate exponential in which a shock of type I causes the simultaneous failure of components in I, where I is a subset of {I, ... , n}. The shocks of type I are governed by a Poisson process with rate Ai' The 2n - 1 such Poisson processes are assumed mutually independent. Numbers of replacements, amounts of damage cumulated, and down times for components. Assume failed components are immediately re, , Z ~ R o ) f replacements in a fixed placed. Then the numbers Z ~ R ) ... interval of time have a joint multivariate Poisson distribution. (See Teicher, 1954, and Dwass and Teicher, 1957.) If AI :5 A2:5 ••• :5 An ; Aij = A(2) for all pairs i<j; Aijk=A(3) for all triplets i<j
15.3. Arrangement Increasing Property of Overlapping Sums
389
ecological situations. Let Zl' ZZ, ... ,Zn denote the number of individuals of type 1,2, ... ,n, respectively, in a quadrant of land. We suppose that these individuals arise from independent clusters and assume that the number of clusters N is a Poisson random variable with parameter m. In cluster j, there are
Z{=X{+
2: x, IE!t,i K""Z
individuals of type i, i = 1, ... ,n, where X{, Xl' Ie Ik , k = 2, ... , n, are independent Poisson random variables with parameter m., mr, k = 2, ... ,n, respectively and satisfying m, = mZ for I c: Ik , k = 2, ... , n, for each cluster j. Thus z» = ( Z ~ ,... , Z ~ ) has a multivariate Poisson distribution. The vector Z of the number of individuals of the different types in the quadrat is given by Z
= Z(1) + ... + Z
and is said to have a compound multivariate Poisson distribution. We now show that the density of Z is AI. Conditional on N = No, Z is the sum of No i.i.d. multivariate Poisson vectors and therefore is multivariate Poisson from the closure under convolution property of the multivariate Poisson established by Dwass and Teicher (1957). Thus the conditional density of Z is also AI. This proof also shows that the random number of clusters N could be any random variable taking values on the positive integers. 0
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Chapter 16 Applications of Arrangement Ordering
In this chapter we describe applications in probability and statistics of the theory of arrangement ordering developed in Chapter 15. We note that “density function” is used in place of “density or mass function.” Sections 16.1 and 16.2 are largely based on Boland, Proschan, and Tong (1988).
16.1. Moment and Geometric Inequalities In this section we assume that the density function of X = ( X , , . . . , X,) is permutation invariant. Many interesting moment and geometric probability functions that are arrangement increasing may be generated by using the following corollaries.
16.1. Corollary. Let X be a random vector with density function f ( x ) that is permutation invariant. Let hi be an A1 function on R” x R” and @i be an increasing function on R --., R for i = 1, 2. Then W(a,b) = E,[@1(h1(a,X))@2(h2(X, b))l si A1 in ( a ,b) E R” x R“.
Proof. Let g,(a,x ) = @(h’(a,x ) and g2(x,b) = &(h2(x, b)). Then g , and g, are A1 since increasing functions of A1 functions are AI. Since u(dx) =f(x) dx is a permutation invariant measure, we conclude from 39 1
392
16. Applications of Arrangement Ordering
Theorem 15.11 that 1jJ(a, b) =
I
gl(a, x)gzCx, b)f(x) dx
i s A I i n ( a , b ) E ~ n x ~ n .0
16.2. Corollary. Let X be a random vector with density function f(x) that is permutation invariant and hi be an AI function on ~ n X ~ n for i = 1, 2. Then for real constants CI and Cz.
Pa,b(X) = P[hl(a, X) 2=: CI' hZ(X, b) 2=: cz]
is an AI function of (a, b) E
(16.1)
~ nX ~ n .
Proof. The result follows from Corollary 16.1 by choosing rJ>i the indicator function of the set [ci , 00) for i = 1,2. 0
=
I[ci'oo) ,
16.3. Example. The following are some elementary examples of AI functions useful in illustrating the application of Corollaries 16.1 and 16.2 (all indices in sums and products range from 1 to n):
(a) hl(u, v) = I[Ui"",Vi:i=I, ... ,n); (b) hz(u, v) = I: UiVi; (c) h 3 (u , v) = - I: iu, - vif; (d) (e) (f) (g)
h 4 (u , v) = - I: (u7IvT) X I[ui>o,vi>o:i=I, ... ,nl; hs(u, v) = IT tu, - vi)+' where a+ = max{O, a}; h6(u, v) = -max lUi - Vii; h7 (u , v) = - I: lUi - v;/. 0
16.4. Example. Judicious selection of hI and h Z from, say, Example 16.3, can yield some useful AI geometric probability functions:
(a) The rectangular probability P[ai::; Xi::; b.: i
= 1, ... , n] = P[X E [a, b]]
is an AI function of (a, b), as can be seen by using hl(a, x) = hl(a, x) and = hl(x, b). (See Boland, 1985, for more rectangular probabilities of this type.) (b) P[I:?=I a.X, 2=: c l , ~ 7 ~ b1 .X, 2=: cz] is AI in a and b, as can be seen by letting hl(a, x) = h 2(a, x) and h 2(x, b) = h 2(x, b). For example, if X = hZ(x, b)
16.1. Moment and Geometric Inequalities
393
( X , , X , ) has a permutation invariant density function, then
PvA = P[4x1 -k x , 2 4 , 2 x , -k 4x2 2 21 5
P [ X I-k 4x2 2 4 , 2 x , -k 4x2 2 21 = P[&q.
(See Fig. 16.1) (c) Of course, any combination of two of the types of functions in Example 16.3 gives us a probability function which is A1 in (a, b), such as a,Xi Ic1and
P[ r=l
( X i - bi)’
5 c2]
i=l
or Xi 2 a, for all i
= 1,
. . . , n and
0
IXi - bil Ic 2 ] . i=l
2x,
+ 4x,=
Figure 16.1. Regions generated by A1 functions.
2
394
16. Applications of Arrangement Ordering
Now let X be a random vector with density function f(x) that is permutation invariant, hi be an AI function for i = 1, 2, and (a, b), (a', b') E IR n x IR n satisfy (a, b) ~ (a', b'). We use the notation Y = (1'1, Yz) '=' (hl(a, X), hZ(X, bj) and Y' = ( Y ~ , Y ~ ) ' = ' ( h l ( a / , X ) , h Z ( X , bSince ' » . the distribution of X is permutation invariant, Y and Y' have the same marginals. In other words, the distributions of the marginals of Yare unaffected by a permutation of the components of a or b, although their joint distribution may be altered. 16.5. Remark. Corollary 16.2 states that ( Y ~ , Y ~ ) is in a sense more positively quadrant dependent than (YI , Yz). See Lehmann (1966), Barlow and Prosch an (1981, Chapter 5, Section 4), and Tong (1990, Chapter 5) for concepts of dependence. 0 We might say that the bivariate vector ( U ~ , U ~ ) is more positively dependent than (UI , Uz) if the two vectors have the same distribution and
or equivalently,
for every pair cf>1' cf>z of increasing functions. (See Rinott and Pollak, 1980; Shaked and Tong, 1985; and Tong, 1989, for a slightly different concept of more positive dependence.) Then Corollary 16.1 implies that ( Y ~ , Y ~ ) is more positively dependent than (YI , Yz), since for any increasing cf>I and cf>z, Cov( cf>I(YD, cf>z(ym - Cov( cf>1(1'1), cf>z(Yz»
=
E ( c f > I ( Y D c f > z ( -Y ~E(cf>I(YI)cf>z(Y » Z».
16.6. Remark. Corollary 16.1 yields moment inequalities when the distribution of X is permutation invariant and X takes values in [O,oor. We use the notion of the previous remark except that now we assume that (a,b),(a',b')E[O,OOrX[O,oor and hI and h Z take nonnegative values. Let cf>i(y) = ymi for y;:::: 0 and m, be a positive integer, i = 1, 2. Then Corollary 16.1 implies that when (a, b) ~ (a', b'), E « y ~ ) m l ( y ; );::::m zE )( Y ~ l Y i z ) for
all m l , m2;:::: 1.
0
16.2. Arrangement Increasing Probabilities
16.2.
395
Arrangement Increasing Probabilities for AI Families of Densities
Many families of multivariate densities A(x) possess the property that the function ep(l.., x) = A(x) is arrangement increasing in the parameter I.. and the outcome x. The multinomial n
epl(l.., x) = N!
A ~ i
2: -' ;=lX; !
for O
1»
16.7. Corollary. Let {A(X):I..EA} be an AI family of probability densities (or frequency functions). Let X have density A(x). Let h be an AI function on ~ X ~nand c be an arbitrary constant. Then
Pi-,a(X) = P[h(a, X)
2= c]
is an AI function of (1.., a). Proof. This follows from Theorem 15,11 by letting gl(a, x) = and gz(x, 1..) = A(x). D
I[h(a,x)2"cj
We illustrate the application of Corollary 16.7 with various examples.
16.8. Example. Assume that X is a multivariate random vector with density A(x) and that the family {A(x): I.. E A} is an AI family of densities. = l , ,n] and F..(a)=Pi-[X;2=a;:i= (a) F i - ( a ) = P i - [ X i ~ a ; : i ... 1, ' .. , n] are AI in (1.., a). (See Corollary 15.13). (b) P i - [ E 7 ~ l a ; X i 2 = isc ] AI in (I..,a). In particular, it follows that if Xi> 0 for all i and 1.., then Pi-[E7=dXdaJ ~ 1] is AI in (1.., a), where a E (0, oot.
396
16. Applications of Arrangement Ordering
(c) P , . [ E ? ~ d X i - a i ) 2 ~isc ]AI in (A, a). Hence for a given A, the probability that X lies in a sphere of radius y7; with center a = (aI' ... , an) increases as the order of the coordinates of a becomes more similar to the order of coordinates in A= P'l' ... , An)' Similarly,
are both AI in (A, a). (d) If XE [0, with probability 1 for all A, then P , . [ L ? ~ l( X ; / a ; ) 2 ~ c ] is AI in (A, a), where a E (0, (e) p,.[n?=l (Xi - a;)+ ~ c] is AI in (A, a). The boundary of this region in the two-dimensional case is a hyperbola, illustrated in Fig. 16.2. 0
oar
oar.
16.9. Example. Suppose that {A(x): AE A} is an AI family of densities, Now n?=l X'!'i is an AI function where each A(x) has support in [0, of m and X. Hence an application of Theorem 16.3 yields that E.. n?=l X'!'i = f-l'::" .... m n is an AI function of Aand m. Similarly, eX'. = eExiti is also an AI function of x and t. Thus the multivariate moment
oar.
Figure 16.2.
Illustration for Example 16.8(e).
16.3. Applications to Rank Order Problems
397
generating function
is an AI function in (l, t).
16.3.
D
Applications to Rank Order Problems
This section is largely based on Hollander, Proschan, and Sethuraman (1977). Given a set of real numbers {Xl' ... ,Xn }, let ri denote the rank of Xi; i.e., ri = 1 + Lj*i I(xi' xJ, where 1 if c>d I( c, d) = ! if c = d { o if c < d.
If there are tied x's this definition yields the average of the corresponding ranks. Let r = (r1 , ... ,rn ) , the vector of ranks, or the rank order. Similarly, for random variables X 1 , • . . , X n , let R, denote the rank of Xi' and R= (R u · · · , R n ) .
16.10. Theorem. Let Xl' ... ,Xn have joint density ep«l, x), an AI function on [Rn X [Rn with vector parameter l. Let g(l, r) = P,.[R = r] for r E [Rn denote the probability of rank order r. Then g(l, r) is an AI function on [Rn x [Rn. Proof.
We may write g(l, r) as
g(l, r)
f
= ep(l, x)J(x, r) dotx, , ... , x n ) ,
(16.2)
where a is a permutation-invariant measure and where J(x, r) = 1 if Xi has rank r., i = 1, ... ,n, and =0 otherwise. Since ep(l, x) is AI by hypothesis and J(x, r) is AI by construction, it follows that the composition g(l, r) given in (16.2) is AI by Theorem 15.11. D Thus if a set of random variables has an AI density, then the corresponding rank order has an AI frequency function.
398
16. Applications of Arrangement Ordering
16.11. Corollary. Let f be an AI function on IR n. Let R be the rank-order of vector X, where X has the AI density
(16.3) Then for each real fixed c, h c ( ')..) is an AI function on IR n •
Proof. hc (').. ) = ~ r Il!(r),,-,cjg«').., rj). By Theorem 16.10, g(').., r) is AI on IR n x IR ", Since f (r) is AI on IR", it follows that II!(r),,-,cJ is AI on IR". Thus by Theorem 15.11, the composition h c ( ').. ) is AI on IRn. 0 16.12. Remark. Thus if A1::S ... ::S An and x >,,;', then the distribution of feR) when X has parameter ')..0"; is stochastically larger than the distribution of j'(R) when X has parameter ')..0";'. 0 16.13. Remark. Note that Theorem 16.10 and Corollary 16.11 do not require that the AI density of X be absolutely continuous. The theory easily covers ties; we simply use average ranks and thus do not require that r be restricted to the set S. Thus subsequent applications discussed in this section also apply to multivariate discrete AI densities such as gl, gz, s«, s«. s-, and s« in Example 15.18. 0 16.14. Application (The trend problem). Let Xi have TP z density and let A1::S ... ::S An' Then Theorem 1 of Savage (1957) states essentially that g(').., r) = p'.[R = r] is an AI function.
f (Ai, x)
Note that Savage's result follows from the application of Theorem 16.10. As a further application, put U(r) = - ~ ; : l r., where 1::s m s: n, and note that U(r) is AI on IR n • From Corollary 16.11 it follows that if Al::S"'::SA n and ,,;>,,;', then the distribution of U(R) under ')..0"; is stochastically larger than the distribution of U(R) under ), 0";'. Restricting Al = ... = Am = 1 and Am+ l = ... = An = A> 1 in the above, we obtain a stochastic comparison result for the Wilcoxon statistic in the two-sample problem if the experimenter mistakenly counts observations from the second distribution as arising from the first distribution. These ideas are generalized and summarized in the following theorem. 16.15. Theorem. Let the random vector X have a density
16.3. Applications to Rank Order Problems
399
E n1::::; E n2::::; · .. ::::; E nn be numbers (scores) and let T(R) = I: 7:= 1 E nr" where 1::::; m::::; n. Finally, let AI::::; ••• ::::; An and :rr; 5- :rr;'. Then the distribution of T(R) under J..o:rr; is stochastically smaller than the distribution under J..o:rr;'.
Proof.
The conclusion follows directly from Theorem 16.10, Corollary 0
16.11, and the easily verified fact that T(r) is AI.
16.16. Remarks. (a) Theorem 16.15 is applicable to many two-sample rank statistics, including the Wilcoxon statistic (E ni = i) and the normal scores statistic (E ni = the expected value of the nth order statistic in a random sample of size n from a standard normal distribution). (b) There is an open question in this connection that we have not answered and that does not follow merely from the AI concept. In Theorem 16.15 set Al = ... = Am = 1, Am+ 1 = ... = An = A> 1, and cjJ(J.., x) = ll7=1 cjJ(A;, x;}. Can it be shown that the distribution of T(R) has a monotone likelihood ratio in A? (c) In Application 16.14, Savage's result for the trend case, the X;'s are assumed to be mutually Independent. However, Theorem 16.10 is applicable even when the X;'s are dependent, as long as cjJ(J.., x) is AI. Thus Theorem 16.10 gives conditions under which one rank order is at least as likely as another, under densities corresponding to dependent variables. In the spirit of Savage's paper, these results are readily translated into conditions for admissible rank tests in dependency situations. Examples of densities corresponding to nonindependent X;'s are given in Section 2. (d) Similarly, Theorem 16.15 is applicable in two-sample cases where the assumption of independence within each sample, and between samples, can be relaxed to AI densities corresponding to non independent X;'s such as those given in Section 15.2. In this sense, Theorem 16.15 generalizes results of Savage (1956) to dependency situations. 0 Consider a randomized block experiment with n treatments and N blocks. Let Xi = (XiI, ... ,Xin), i = 1, ... , N, be N mutually independent vectors. From Corollary 16.11 and the independence of the X;'s, we can state: 16.17. CoroUary. Let Xi have density cjJi(J.., x), where each cjJi is AI on n ~ n X IR . Let f be an AI function on S. Let R, = (ril , ... , rin), where rij is
400
16. Applications of Arrangement Ordering
• a
•
the rank of Xij among Xii , ... , X in· If Al ~ ... ~An and n > n', en the distribution of ~f f (RJ when each Xi has parameter I.. n is stochastically larger than the distribution of ~ ff (Ri) when each Xi has parameter I..°n'. 0
16.18. Remark. Corollary 16.17 gives powerful results about certain rank tests of H o : Al = Az = ... = An versus ordered alternatives A ~ Az ~ ... ~ An' since many such tests are based on statistics of the form ~ ~ lT (R i ) , where T(R i ) is an AI function of the form T(RJ = ~ 7 = c1 jEnr'i' where C l ~ Cz ~ •.. ~en are "regression" constants and E nl ~ E nz ~ ... ~ Enn are scores. Ordered alternative test statistics of this form for which Corollary 16.17 is applicable include those due to Page (1963) (Cj = j, E nj = j) and Pirie and Hollander (1972) (c, = j, E nj = the expected value of the jth order statistic in a random sample of size n from a normal distribution). Note here that the blocks can have different densities c/>i and once again the c/>/s need not be joint densities of independent random variables. 0
16.4.
Monotonicity in the Selection of Populations
In this section, we show how the theory of the arrangement increasing ordering may .be applied in statistical problems of selection of populations. Essentially we show in a simple unified way that the desirable property of monotonicity holds for a wide class of selection rules. The discussion is based on Berger and Proschan (1984a). Let X = (Xl' ... , Xn) be a random observation with density g(l., x), where the unknown parameter I. = (AI, ... , An)E A c IR n. The general goal of a selection problem is to decide which coordinates of I.. are the largest or which are larger than a value Ao (possibly unknown). This is accomplished by selecting S c {I, ... , n}, a random set depending on X, and asserting that the largest parameters are in {Ai:i E S}. The subset S may be of fixed or random size depending on the formulation of the selection problem under consideration. See, for example, Bechhofer (1954), Gupta and Sobel (1958), Lehmann (1961), Gupta (1965), and Tong (1969) for five formulations. Gupta (1965) calls a selection rule monotone if Ai 2: Aj implies P,..(i E S) 2: p•.(j E S). This monotonicity property is a desirable property for a selection rule, given the goal of selecting a subset consisting of the large values of Ai' Many authors (for example, Santner, 1975) have shown that
16.4. Monotonicity in the Selection of Populations
401
their heuristically proposed selection rules are monotone. Berger and Proschan (1984a) generalize the above notion of monotonicity and present some other notions of monotonicity. Then they show in a unified way using arrangement ordering theory that for many selection problems a large class of selection rules possesses these monotonicity properties. The monotonicity properties are as follows. Let A = {ai, ... , ad and B = {b l , ••• , bd denote two subsets of {1, ... , n} with IAI = IBI = k, where IA I denotes the number of elements in set A. Subset A is better than subset B if for some arrangements a j ( I ) , " " aj(k) and bj(l) , . . . , bj(k)' Aai(r) ~ Abi(r) for r = 1, ... , k. If A is better than B, then each of the following inequalities would be desirable for a selection rule: p ) ' [ I A n S I ~ m ] ~ P ) ' [ I B n Sforevery ~ m ]
(in words, p)'[at least m elements of A are selected] elements of B are selected]). p,.[A = S] P).[IA c
n SI:5 m]
c
~ P,'[IB
~ P,.[B
m E ~ ; ~ p)'[at
= S];
n SI:5 m]
for every
(16.4)
least m (16.5)
m
E ~ .
(16.6)
Some special cases may be of particular interest. By setting m = k in (16.4), we obtain P),[A c S] ~ P,,[B c S]. Furthermore, if k = 1, we obtain the classic monotonicity property of Gupta (1965). By setting m = 0 in (16.6) we obtain p',[A::::> S] ~ P,,[B::::> S]. We assume that the observation vector X = (XI' ... ,Xn ) has a density g(l., x) with respect to a measure a(x), where a satisfies fAda(x) = fA da(xox) for each permutation x and Borel-measurable set A c ~ n . We assume further that g is AI. Eaton (1987) and Gupta and Miescke (1982) have investigated selection problems involving an AI density. They compared the operating characteristics of risk functions of different selection rules, whereas inequalities (16.4)-(16.6) compare different operating characteristics of a single selection rule at a time. Let tp be the set of all subsets of {1, ... , n}. A selection rule is a function o ( s ; x ) : c p x ~ n ~ 1] [ o satisfying , (i) ~ s E < p o ( s ; x ) for = 1 every x E ~ n , and (ii) o(s;·) is measurable for every s E tp. When X = x is observed, an element of cp is chosen according to the probability distribution on cp defined by 0('; x). This selected subset, which depends on X and 0, is what we have called S. The individual selection probabilities, 1fJt(x), ... , 1fJn(x), are defined by 1/J;(x) = ~ S E < P o(s; i x), where tp, = {s E tp : i Es}. 1fJ;(x) is the probability i ES, where X = x is observed.
402
16. Applications of Arrangement Ordering
In simple language, we wish to select the "best" (having largest parameter value) population (or subset of populations) from observations made on each of, say, n populations. To this end, we rank the observations and then claim that the best population corresponds to the largest value observed (or to one of the m «n) largest values observed). A good selection rule should have the obviously desirable property that if population i is better than population j, then the rule is more likely to select population i rather than population j. This property is called the monotonicity property. (Actually, our model is somewhat more generalwe permit dependence among the observations from the n populations.) We consider selection rules D(S; x) that satisfy (16.7) and (16.8) for every i andj E {1, ... , n}, XE IRn, and a s rJ: Xj 2:: Xi
implies
lMx)
(16.7)
2:: 1J!i(X),
(16.8) Rules satisfying (16.7) have been called "natural" in some of the selection literature (for example, Eaton, 1967). Gupta and Miescke (1982) have shown that for problems involving exponential families, selection rules satisfying (16.7) form an essentially complete class among all rules satisfying (16.8) for many loss functions. The permutation invariance assumption (16.8) is standard and reasonable in light of the permutation invariance of the density g and measure o. Lemmas 16.19 and 16.20 will be used to prove the following monotonicity results. 16.19. Lemma. If A is better than B with k vectors A* and A** such that (a) {Ai:i EA} = { A ~ - k + l ' (b) {Ai:i E B} = { A ~ . " ' k + I ' (c) A * * ~ A * .
= IAI = IB\,
then there exist
' A~}, , A ~ * } a, nd
Proof. We will define A* and A** and then show that they have the required characteristics. Let Al consist of the elements of {Ai:i E A nBC} in an arbitrary but fixed order. Let A2 consist of the elements of {Ai:i E A n W} arranged in increasing order. Let A3 be defined like A2 but using An B Let A4 be defined like Al but using An B. The two vectors are A* = (AI,A2 , J.?, A4 ) and A** = (AI,A3 , A2 , A4 ) . C
C
C
•
16.4. Monotonicity in the Selection of Populations
403
Clearly (a) and (b) are true by the definition of J.. * and J.. * *. Let r = lAc n BI. Note that r = IA n BCI. To show that A ** is a transposition of J..", it suffices to show that ;":-k+i ~;":-k-r+i for i = 1, ... , r; for if this is true, then;" ** can be obtained from;" * by the sequence of r simple transpositions which switch ;":-k+i and A:-k-r+i for i = 1, ... , r. To verify that ;":-k+i ~ ;":-k-r+i, i = 1, ... , r, fix i. Let t = IA n B n {j: Aj ~ A ~ - k - r + I.i } At least t + r - i + 1 elements of B are greater than or equal to A:-k-r+i because the coordinates of J..2 are in increasing order. Since A is better than B, corresponding to each of these there must be an element in A which is greater than or equal to A:-k-r+i' The definition of t implies IA n B" n {j: Aj ~ A:-k - r +;} I ~ r - i + 1. Since the elements of A3 are in increasing order A ~ - k + jA ~~ - k - r + ji '= i, ... , r. In particular, ;":-k+i ~ A ~ - k - r + as i ' was to be shown. 0 Let IDO denote the indicator function of the set D. Let v' be the transpose of the row vector v. Finally, let ljJ(x) = ('l/Jt(x), ... , 'l/Jn(x», 16.20. Lemma. Assume the density g(x; J..) is AI and the selection rule (j satisfies (16.7) and (16.8). Fix m E ~ . Then the function K(v,J..) defined on ~ n X A by K(v, J..) = E..I[m,oo\ljJ(X)v') is AI. The result is also true if [m, (0) is replaced by (m, (0).
Proof. That H(v, x) = ljJ(x)v' is AI is easily verified using (16.7) and (16.8). That H*(v, x) = I[m,oo)(ljJ(x)v') is AI follows from !s(n,), Examples 15.4. The composition theorem, Theorem 15.11, yields that K(v, J..) is AI. The proof for (m, (0) is similar. 0 We are now able to prove the monotonicity properties (16.4)-(16.6) for nonrandomized selection rules. Properties (16.4) and (16.6) are immediate consequences of the following general theorem concerning selection rules. 16.21. Theorem. Assume that the density g(J.., x) is AI and the selection rule (j satisfies (16.7) and (16.8). For any Dc{1, ... ,n}, let VD= (I D(1), ... ,ID(n». Let A c {1, ... , n}, Be {l, ... , n}, and m E ~ . If A is better than B, then p.. [ l j J ( X ) v > ~ m] ~ p.. [ l j J ( X ) v > ~ m]. The result is also true if ">" is replaced by " ~ . "
Proof. Let n,* (n,**) denote the permutation such that J..on,* (J..on**) J..*(J..**), where J..*(J..**) is defined in Lemma 16.19. Then VA on,*
= =
404
16. Applications of Arrangement Ordering
VB 031:** = (0, ... ,0,1, ... , 1), a vector n - k zeros followed by k ones. Since 1..** is a transposition of 1..* (Lemma 16.19) and K(u, v) is AI
(Lemma 16.20), we obtain P J . [ t p ( X ) 2=m] v ~
= K(vA, 1..) = K(VA «n", 1.. = K(VB I..on:*) 2: K(v B 031:**, 1.. = K(v B, 1..) = PJ.[tp(X)vs 2: m]. 031:*)
031:**,
031:**)
The
"2:" result follows from the
(m, 00) part of Lemma 16.20.
0
The function tp(x) . vh is the conditional expected value of IS n DI given X = x. The conclusion of Theorem 16.21 can be restated as E).(IS nAil X) is stochastically larger than EJ.(IS n BII X) if A is better than B. This implies other inequalities such as EJ.(IS nAI) 2: EJ.(IS n RI). If {) is a nonrandomized selection rule, then these and related rsuIts are more simply stated as follows. 16.22. Theorem. Under the assumptions of Theorem 16.21, if {) is a nonrandomized subset selection rule, then all the following are true: PJ.[IS
nAI > m] 2: PJ.[IS n BI > m]
(16.9)
nAI2: m] 2: PJ.[IS n BI2: m] PJ.[IS nAcl::; m] 2= PJ.[IS n BCI::; m]
(16.10)
nAcl <m] 2:PJ.[IS n SCI <m]
(16.12)
= A] 2: PJ.[S = B].
(16.13)
PJ.[IS
PJ.[IS
PJ.[S
(16.11)
Proof. If {) is nonrandomized, tp(X)vh = IS n DI. Thus (16.9) and (16.10) are just the inequalities from Theorem 16.21. If A is better than B, it is easily verified that SC is better than A Thus (16.11) and (16.12) follow from (16.9) and (16.10), respectively. To prove (16.13), consider the function H**(v, x) = /(-oo,Ol[tp(x)(1_ v)'], where 1 is a vector of n ones. Arguing as in Lemma 16.20, we can show that H** is AI. By Theorem 15.11, EJ.H**(v, X)H*(v, X) is also AI (H* is from the proof of Lemma 16.20). But for nonrandomized selection rule with m = IDI in H*, EJ.H**(VD' X) = PJ.[S = D]. Thus arguing as in 0 the proof of Theorem 16.21, we obtain (16.13). C
•
In many problems the model depends not only on I.. but also on another parameter r, and the selection rule depends not only on X but
16.4. Monotonicity in the Selection of Populations
405
also on another statistic Y. If the probability model and assumptions are extended as in Eaton (1967, Section 3), the results of this section, in particular (16.9)-(16.13), continue to hold. For example, in the comparison of n treatments with a standard, Gupta and Sobel's (1958) proposed selection rule will satisfy (16.9)-(16.10) if the same number of observations are taken on each treatment. For this application, we would set 't = ()'O' 0 2), the control mean and common variance, and Y = (X 0, S2), the estimate of 'to These results are discussed in Berger and Prosch an (1984b).
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Chapter 17 Multivariate Arrangement Increasing Functions
In Chapters 15 and 16 we presented the theory and applications of arrangement ordering, a partial ordering. Arrangement ordering basically partially orders vectors of length, say, n, according to how well they compare with the "perfect" ordering: x I :5 X2 :5 . . . :5 X n • Alternatively, pairs of vectors, each of order n: (x, y) may be compared on the basis of the degree of agreement between the ordering of x and the ordering of y. In the present chapter we introduce a multivariate version of the arrangement ordering, obtain its basic properties, and give a number of examples of arrangement increasing functions, including many wellknown multivariate densities, measures of concordance among judges, and the permanent of a matrix with nonnegative elements. Applications are given including useful probabilistic inequalities for linear combinations of random vectors whose distributions are permutation invariant. Our presentation is based largely on Boland and Proschan (1988).
17.1.
Definition and Basic Properties of Multivariate Arrangement Increasing Functions
For an n-tuple x = (Xl' . . . , X n ) E ~ n , we let x] = (X[I] , . . . , x[nl) denote the vector with the components of x arranged in decreasing order. Similarly, xi = (X[n] , ••• ,X[l]) with the components arranged in increasing order. For any permutation 3t = (n l , . . . ,nn) of {1, ... , n}, we let x", = (X]fl' ... , X]fJ. 407
408
17. Multivariate Arrangement Increasing Functions
17.1. Definition. For (Xl" .. ,xs ) and (Zl" .. , z,') E ( ~ n y , we define (Xl, ... ,Xs) ~ (z., ... , zs) if there exists a permutation 3t such that
(17.1) for each k = 1, ... , s. We define (Xl,' .. ,Xs) ~ (z, , ,zs) if there exist a finite number of elements (yt ... ,y;), ... , ( y ~ , , yf) in ( ~ " ) ' - lsuch that (i) (Xl,'" .x.) = (Xli, yt ... ,y;) and (Zl'''' ,zs) ~ ( X l i , ~ ... , , yD, and (ii) for each j = 2, ... , p, there exist a pair of coordinate indices e, m (e < m) such that (x, j, yt ... , y ~ ) may be obtained from (x, j, yiz-l , ... , y,-l) by interchanging the e and m coordinates of any vector yik-l such that yi:? > y ~ - ; " l . (We call such an operation of obtaining (Xli,yZ,"" i) from (Xlj,rl- l, ... , i-I) a basic rearrangement. ) 17.2. Example.
(7,5,3,1), (2,6,4,8), (6,0,9, 3) ~ (1, 3, 5, 7), (8,4,6,2), (3, 9, 0, 6) ~ (1, 3, 5,7), (2,4,6,8), (3,9,0,6) ~(1,3,5, 7), (2, 4, 6, 8), (3, 0, 9, 6) ~ (1, 3, 5, 7), (2, 4, 6, 8), (0, 3, 9, 6) ~ (1, 3, 5, 7), (2,4,6,8), (0, 3, 6, 9).
o 17.3. Remarks. (a) It should be clear that ~ is a partial ordering on (IR")' and that if (Xl, ... , Xs ) ~ (Zl' ... ,z,), then the components of the vectors Xl" .. 'Xs are relatively less similarly arranged than the components of the vectors Zl , ... , Zs . Of course if (Xl, ... , Xs) ~ (Zl, ... ,zs), then the relative arrangement of the components in the vectors Xl' ... ,Xs is equivalent to that of the components in the vectors ZI, ,Zs' For any (XI, ... ,xs) E ( ~ n ) ' , it follows that (XI,
,xs) ~ (XIj, ... , X s j) ~ (Xlt. ... , xsl )·
(b) For the case s = 2, it is clear that for any pair of vectors Xl and Xz , we have:
17.1. Definition and Basic Properties
409
This yields the well-known rearrangements inequality of Hardy, Littlewood, and P6lya (1934, 1952, p. 261). 0
17.4. Definition. Let D; c IR n for i = 1,2, ... ,s and let D = D I X .•• X D, c (R")'. Normally we consider sets D satisfying: (Xl, ... ,Xs) ED=? (XlJ,., ... , Xsn:) E D
(17.2)
for any permutation, :71:, of {I, 2, ... , n}. Then a function f: D --IR is said to be multivariate arrangement increasing (MAl) if:
(Xl,'"
, X s ) ~ ( Z I ",Zs)=?f(XI,··. " ,Xs)$,f(ZI"" ,zs)·
Alternatively, f is said to be multivariate arrangement decreasing (MAD) if -f is MAL Note that MAl functions are permutation invariant in the sense that for any permutation :71:,
f(xl
, •••
,xs )
=f(Xbt,
... ,
X S 1t )
.
We recognize that MAl functions of two vector arguments coincide with AI functions defined in Section 15.1. Thus Definition 17.4 represents a generalization of Definition 15.2. The next proposition is useful in obtaining many examples of MAl functions, as well as in relating several basic classes of functions. We first present two definitions. Consider the lattice IRs with componentwise ordering. For X, y E IRs, let X v y = (maxfx. , YI), ... , max(x s , Ys» and X A Y = (min(xI' YI), ... , min(xs , Ys)).
17.5. Definition. A real valued function f satisfying f(x v y)
+ f(x A y)
+ f(y)
~ f ( x )
(17.3)
is called L-superadditive (or lattice superadditive). See Marshall and Olkin (1979, Sec. 6.D) for results concerning L-superadditive and L-subadditive functions.
17.6. Definition. A real valued function f satisfying f(x v y)f(x
A
y)
~ f ( x ) f ( y )
is called multivariate totally positive of order 2 (MTPz) .
(17.4)
410
17. Multivariate Arrangement Increasing Functions
In the following proposition, let E = IR n or IR':-.
17.7. Theorem. (a) Let f(x l, ... ,xs ) = g(x i + Xz + ... + x,}. Then f is MAlon D = E' iffg is Schur-convex on E. (b) Let f(XI' ... ,xs ) = L7=1 g(Xli' XZi, ... , xsi). Then f is MAlon D = E' iff g is L-superadditive on E. (c) Let f(XI' ... ,xs ) = TI7=1 g(Xli' XZi, ... ,Xsi), where g > 0. Then f is MAlon D = E iffg is MTP z . S
Proof. (a) Let g be Schur convex on E. From the definition of <, we , Xs ) < ( X ~ , ,X;) then Xl + + Xs <' X ~+ + X;. see that if (x., , x,) = g(XI + + xs ) ~ g ( x + ~ + x;) = f ( x ~ , , x;) Hence f(x!> andfis MAL Next suppose that f is MAl and that y > z, where y and Z E E. We need to show that g(y) ~g(z). Since g is permutation invariant, by the basic property of majorization, we may without loss of generality assume that y = (YI, Yz, Y3, ... , Yn) and that z = (YI + E, Yz- E, Y3, , Yn), where ~ E ~Yz- YI. Let us define Xl = (YI, Yz- E, Y3, , Yn), Xz = O , ,O). Then (XI,XZ,O, ,O)< (E,O,O, ,O), and X ~ = ( O , E , ... (Xl' X ~ ,0, ,0) and thus g(z) = g(XI + XZ) = f(XI' XZ, 0, , 0) ~ f ( X I ' X ~ , O , ,0) =g(y). Parts (b) and (c) may be proved in a similar way by noting the following: Let us suppose that Xl = Xli and that (Xl' X;, ... , X;) may be obtained from (Xl, Xz, ... ,xs ) by the basic rearrangement which interchanges the e and m (e < m) coordinates of any vector Xk such that Xkf > Xkm' Then
°
17.8. Example. The function g: [0, C X l r IR~ defined by g(YI' ... , Yn)= TI7=1 Yi is Schur-concave and hence -g is Schur-convex. It follows from Theorem 17.7(a) thatf:([O, C X l r Y ~ defined 1 R by n
f(XI, ... ,xs) =
s
IT 2: Xki i=l k=!
(17.5)
17.1. Definition and Basic Properties
411
is MAL In particular, n
s
n
s
IT 2: Xki ~i=l IT k=l 2: Xk[i)' i=l k=l an inequality proved by Ruderman (1952).
(17.6)
0
17.9. Remark. The function g: [0, roy ~ ~ defined by g(Y1' ... ..») = Y1... Ys is L-superadditive. It follows from Theorem 17.7(b) that f(X1' ... ,xs ) = I:7=1 Xki is MAlon ([0, roty. In particular, as Ruderman (1952) observed,
rnA
n
s
n
s
2: IT Xki::; i=l 2: k=l IT Xk[i) , i=l k=l From this result, it is easy to see that for any r z: s, f,.(X1' ... , x s ) =
2:
n
2: Xk,i... Xk,i
kt<"'
is also an MAl function.
0 .
17.10. Remark. Lorentz (1953) proved that I:7= 1 g(Xli' ... , Xsi)::; I:7= 1 g(X1[i)" ... ,XS[i)) for any L-superadditive function g on ~ s . Derman, Lieberman, and Ross (1972) observed that a cumulative joint distribution function F(Y1' ... , Ys) is L-superadditive and derived some implications concerning the optimum assembly of systems from components. For example, assume that s components make up a system and that component i has known reliability r., i = 1, ... ,s. Assume further that F(r 1 , ••• , rs ) is the corresponding reliability of the system. Finally, assume that n components of each of types k = 1, ... , s are available. Thus the n systems may be assembled in (n!y-l possible ways. Let N denote the number of systems that function properly; N is a random variable whose distribution depends on the way in which the n systems are assembled. It follows that EN = EN(r1' ... , rs ) , the expected number of properly functioning systems, is an MAl function which is maximized when the most reliable component of each type is assembled into one system, the second most reliable component of each type is assembled into a second system, etc. 0 17.11. Example. The function min(Y1' ... ,Ys) and -max(Yl' ... , Ys) are L-superadditive on ~ s (max(Y1' ... ,Ys) is L-subadditive). It follows
412
17. Multivariate Arrangement Increasing Functions
from Theorem 17.7(b) that n
2: min(xli' ... , Xsi) i=1
n
are respectively MAl and MAD on Minc (1971). n
2: min(xli
2: max(xli' ... , Xsi) i=1
and
( ~ n y .In
particular, as was proved by
n
J
••• ,
x s;) :s
i=1
2: min(xl(ij" ... , XS[i]) i=1
and n
2: max(x 1i,···,
i=1
n
X S i ) 2: ~ max(xl[i]""" Xs[i])' i ~ 1
Similarly, we note that since log min(Yl' ... ,Ys) and -log max(Yl' ... ,Ys) are L-superadditive on «0, oo)ny, it follows that: n
n min(xli' ... ,XSi)
n
n max(xli' ... , XSi)
and
i=1
i=1
are respectively MAl and MAD on proved by Mine (1971), n
,
«O,ooty.
In particular, as also
n
n min(xli' ... , XSi) :s n min(xl(i]', ... , Xs[ij)
i=1
i=1
and n
n max(x
n
Ii' . . . ,
XSi) ~
i=1
when all Xki > O.
2: max(xl(i]" i=1
... , Xs[i))
0
17.12. Example. The permanent of an n x n matrix with positive elements ia a MAD function of its columns and a MAD function of its rows. Proof. Let P(al' ... , an) be the permanent of the n x n matrix with kth column = ak' Then P(al' ... ,an)
=
2: 3tESn
an
,I " . annn'
17.2. Preservation and Closure Properties
413
To show that the permanent is MAD, we need only show that P(a1' , an) ~ P(ai , ... , a ~ ) , where (a}, ... , a ~ ) is obtained from (a., , an) by interchanging the e and m coordinates of each vector a, such that ake > akm (here t, m are arbitrary but fixed and t < m). Without loss of generality, we assume that ake :s akm ~k :s r for some r, 1:s r:S n. Let us define S' to be the set of permutations ,w; on {1, ... , n} such that ,w;( t) < ,w;(m). Now for any permutation ,w;, define ,w;* by ,w;*(i) = Jr(i) for i =t- t, m and ,w;*( t) = ,w;(m), ,w;*(m) = ,w;( t). It is clear that if,w; is such that either max{,w;(t),,w;(m)}:sr or min{(,w;(t),,w;(m)}>r, then
On the other hand, if ,w; does not fall into either of these categories, it is easy to see that
Hence P(al"" ,an)= 2:'[a".,l·· . a"'nn+a".n " . ·a".;n] 1EES'
;::: 2:
[ a ~ 1 1 · · · a ~ n n+ a ~ i l ... a ~ ; n ]
"'ES'
=P(ai, ...
, a ~ ) .
For a probabilistic interpretation of this result, suppose n balls are to be thrown (independently) into n urns. Let Pk = (Pk1' Pk2' ... ,Pkn) be ,n. That is, the probability distribution of the kth ball for k = 1, Ph = probability that ball k lands in urn i. Then P(P1 , P2, , Pn) is the probability that the n balls end up in n different urns. This probability function is MAD in the vectors PI , ... , Pn' and in particular,
P(P1' ... ,Pn) ~ P(pi, ... ,p,n, where p%
17.2.
= (Pk!l]' ... ,Pk(n»
for each k
= 1, ' .. , n.
0
Preservation and Closure Properties of Multivariate Arrangement Increasing Functions
The class of multivariate arrangement increasing (decreasing) functions is clearly closed under addition and under formation of mixtures (with respect to positive measures). The product of positive MAl functions is
414
17. Multivariate Arrangement Increasing Functions
cp is an increasing function on cp(h<'), ... ,fm('» is also MAl.
MAL If
~ mand
h, ... .i;
are MAl, then
17.13. Example. Let Eo, E 1 , ••• , E s c ~ n . For i = 1, 2, ... ,s, let gi: Eo x E c [~0, (0) be MAL Then f(l.., Xl, . . . ,Xs ) = m=l gi(I..,Xi) is MAl in 1.., Xl , . . . , Xs ' From this result, we deduce that for many classic multivariate densities, the joint density of a random sample Xl, , X, of size s is MAl in the arguments I.. (a parameter vector), Xl, , x, . Some examples are: (a) Multinomial:
Here 0 < Ai; Xki = 0, 1,2, ... ; i n
LA = l , i
;=1
= 1, ...
, n; k
= 1, ... } s,
n
L Xki = N
for each k.
i=l
(b) Multivariate normal distribution with a common variance and a common correlation coefficient s
f(l.., Xl"
.. ,Xs )
= (2Jr)-ns/2/1::I- S/2 f1 e- 1( Xk - A)I; - 1(Xk - Ar , k=l
where 1:: is the positive definite covariance matrix with elements a 2 along the main diagonal and pa2 elsewhere, p E (-l/(n - 1), 1). Additional examples are presented in Example 3.10 of Hollander, Proschan, and Sethuraman (1977). 0 A basic theorem in many partial orderings is the preservation of the defining property under composition. In the present case, this enables us to construct many interesting examples of MAl functions. 17.14. Theorem. Let gk(X, z) be positive AI functions on ( ~ n ) 2 for k = 1, ... ) s. Let /.l be a permutation invariant Borel measure on IR n (i.e., fA d/.l(z) = fA d/.l(z 0 Jr) for each permutation n). Then the composition f defined by (17.7) is MAlon (IRny.
17.2. Preservation and Closure Properties
415
Suppose that (Xl' •.. ,xs ) and (xi, ... ,x;) are such that Xl = xi = Xl i, and (xi, ... ,x;) may be obtained from (Xl, . . . ,xs ) by interchanging the e and m coordinates (t < m) of any Xk such that Xke > Xkm . We need only show that f(xt> . . . ,xs ) $f(xi, ... ,x;). Without loss of generality, we may assume that the indices k such that Xu $ Xkm are the indices k = 1, 2, ... , r, where r < s. For any vector W E ~ n , let us define w* to be the vector obtained from w by interchanging its e and m coordinates. By breaking up the region of integration into the 3 regions Ze < z.; , Ze = Zm' and Ze > Zm, we obtain
Proof.
f(xi, ... ,x;) - f(x l
- J Zf
=
J
[n
OJI
, ... ,
gk(Xb
gk(Xk, z)
z)
-
xs )
J2~
g k(Xb
[II
z)
gk(Xk, z") ]
Zf
since each
s, is AI.
D
An application of Theorem 17.14 yields the following extension of Corollary 2.1 in Boland, Proschan, and Tong (1988) (see Corollary 16.1). The proof is similar and thus omitted.
416
17. Multivariate Arrangement Increasing Functions
17.15. Coronary. Let X be a random vector with density or mass function f(x) that is permutation invariant. For k = 1, ... , s, let h k be an AI function of two vectors on ~ n X ~ n and let 1Jk:!R _ [0, 00) be increasing. Then (17.8) is an MAl function of (a., ... , as)
E
(!Rny.
By choosing 1Jk(hk(ak> x)) to be the indicator function of the set {x:hk(ak> x) 2: cd, where Ck is an arbitrary but fixed real number, we obtain 17.16. Corollary. that
Under the assumptions of Corollary 17.15, it follows
(17.9) is an MAl function of (a., .. ,as) E (Cl"'" c.),
( ~ n r for
each real vector c =
Note that Corollary 17.16 is an extension from the bivariate case to the multivariate case of Corollary 2.2 of Boland, Proschan, and Tong (1988) (see Corollary 16.2).
17.17. Remark. Many useful transformations of the random vector X that are MAl functions are given in Boland, Proschan, and Tong (1988). A particularly useful transformation is the linear transformation hk(ak> x) = E7=1 akiXi' For two s X n real matrices
let us define YA = AX and Y B = BX. If the joint density or mass function of X = (XI' ... , X n ) is permutation invariant, then by Corollary 17.16, it
17.3. Applications to Measures of Agreement
417
follows that (a., ... , as) ~ (bj , ... , bs) ::} P[YA ~ c] ::5 P[YB ~ c] for all real vectors c = (Cl' ... , c.).
17.3.
D
Applications to Measures of Agreement Among s Judges
Various measures of concordance have been used to evaluate the degree of agreement among s judges. Consider the situation in which each of the s judges ranks n objects. Perhaps the most widely used measure of this type is Kendall's coefficient of concordance W. (See Kendall, 1970.) For each k = 1, ... ,s, let R k = (R R be the vector of ranks of the kth judge, where Ri, is the rank assigned by judge k to the ith object. Kendall's W is defined by
ki,... , kn)
12 W(R 1 ,
••• ,
it [kt (Rki- ~ + 1))
Rs ) =
S
2( 3 n -n
(n )
r
(17.10)
We mention three other measures of concordance: (a) p (average Spearman's Rho) defined by 1
G) L
p(R1, ... .R,) = -
[
6 in~ 1 (R k; - R e; ) 2 ] 1(2 1) S S -
k<e
=1-
2(2s + 1) _
s
1
1
+ (;)s(s
L ( L Rk;R ei n
)
,
+ l)(s _ 1) k<e 1 ~ 1
(17.11) where the quantity in the bracket is just Spearman's rho for judges k and t . Note that p and Ware related through the equation
p= see Kendall (1970).
sW-1 ; s-l
418
17. Multivariate Arrangement Increasing Functions
(b) t (average Kendall's tau) is defined by
t(R 1 ,
=-
..• ,
1
Rs )
2:
. (Kendall's tau for Judges k and €)
( ~ ) k<e
__1 2: [1- 4Q(k, t)J
G)
=
n(n - 1)
k<e
_1_ 2: [1- (4I)J 2: [1 - (sgn(R ki - Rkj))(sgn(Re; - Rej))] G) k<e n ni<j
= -1 +
1
G)G)
2: 2: [sgn(Rki -
R kj)][ sgn( Re; - Rej))];
«-:« i<j
see Ehrenberg (1952) and Hays (1960). (c) PF (average Spearman's footrule) defined by: PF(R 1 ,
••• ,
Rs )
1 =-( ) 2: { 1 - n (n 2_ 1) 1=1 2:n IRki S «-:«
Reil
}
2 1
n
=1-( s)( n )k<e 2: 2: IRki-Re;I;
(17.12)
i=1
2
2
see Diaconis and Graham (1977). ~ 7 ~ RkiR 1 Note that for any fixed k < t; the functions ei, ~ i < sgn(R j ke - Rkj)sgn(Re; - ReJ, and - ~ 7 = 1IRki - Red of (Rk , R;) are all arrangement increasing. If g is an MAl function of r vectors (r::s: s) that is symmetric in its arguments, it is clear that: f(Xl' ... , xs )
=
2:
g(Xk l
'
· · · '
Xk)
(17.13)
k 1<···
is an MAl function of s vector arguments (which is also permutation invariant in its vector arguments). It follows that all four of these measures of concordance among judges (W, P, t, and PF) are MAl functions. This is a justification of their use, since we would certainly expect these measures to increase as the judges increase in agreement.
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Author Index
A Abdel-Hameed, M., 295, 419 Aczel, J., 6, 53, 124,419 Adamovic, D. D., 6,175,176,247-249, 251,419,453 Agovic, E. M., 257, 260, 445 Ahlswede, R., 200, 419 Alzer, H., 151,304,305,419 Anderson, B. J., 224, 419 Ando, T., 11,52,419,433 Andreief, C., 198, 201,420 Andrica, D., 4, 68, 70,105,247,420,445 Apery, R., 182, 420 Arama, 0., 293, 294, 420 Artin, E., 294, 420 Atanackovic, T. M., 228, 420 Atkinson, F. V., 204, 420 Autar, R., 292, 449
B
Barlow, R. E., 156,354,394,420 Barnes, D. C., 224, 225, 228, 420, 421 Baston, V. J., 172, 176,303,421 Bechhofer, R. E., 400, 421 Beck, E., 112, 127,421 Beckenbach, E. F., 8, 12,72,95, 121, 123, 138, 156,159,161,163,181,191, 209,421 Beesack, P. R., 45, 56, 92, 93, 98, 99,101, 103, 1l0, 111, 117, 118, 122, 124,
133,146,156,159,161,200,222, 225,244,245,272,292,421,422,445 Bellman, R., 12,72,121,156,159,161, 181,191,209,224,226,421,422 Berger, R. L., 400, 401, 405, 422 Bergh, J., 191,422 Berljand, O. S., 199,422 Bernstein, F., 218, 422 Berwald, L., 214, 216, 223, 422 Bhattacharjee, M. C., 331, 422 Biernacki, M., 89, 199,206,422 Blaschke, W., 212, 422 Boas, R. P., 58, 60, 62, 63,160,161,229, 243,271,422,423 Bodin, N., 295, 423 Bojanic, R., 265, 423 Boland, P. J., 329, 330, 391, 392, 407, 415, 416,423 Borell, c.. 214, 225, 347, 350, 351, 423 Bourbaki, N., 128,423 Brascamp, H. J., 353, 354, 423 Breiman, L., 299, 423 Brenner, J. L., 120,423 Bromwich, T. J. I'A., 270, 424 Bruckner, A. M., 279, 424 Brunk, H. D., 13, 14,60,62,159,161,266, 424 Brunn, H., 348, 424 Bullen, P. S., 71, 80, 82, 88, 95, 109, 112, 115,124,127,141,181,231,233, 240,245,278,300,302-304,323,424 Burkill, H., 89,199,424 Burkill, J. c.. 82,172, 176,424
457
458
Author Index C
Callebaut, D. G., 118,424 Capocelli, R. M., 292, 424 Cargo, G. T., 7, 424 Carroll, C. E., 315, 317, 424 Cavaratta, A. S., 19,424 Cebaevskaja.T. V., 118, 188, 191,300,424, 429 Cebysev, P. L., 197,207,424 Cheng, K. W., 324, 424 Choi, M.-D., 52, 424, Chokhate, 1., 201, 424 Chow, Y. S., 340, 424 Ciesielski, Z., 161,424 Clausing, A., 200, 292, 424 Cooper, R., 246, 424 Crstici, B., 27, 32, 33,105,204,424,445, 446 Cunningham, F., 242, 244, 424 Curri, H. B., 15,424 D
Dahmen, W., 20, 424 Danskin, 1. M., 121,426 Daroczy, Z., 292, 426 Darst, R., 272, 426 Das Gupta, S., 347, 348, 426 Davenport, H., 288, 289, 426 Davis, C., 11,51,52,426 Dawson, D. F., 39, 426 Daykin, D. E., 118,200,419,426,427 Delange, H., 169,426 Delbosco, D., 134,426 Derman, C., 411, 426 Diaconis, P., 418, 426 Diaz, 1. B., 240, 426 Djordjevic, R. Z., 35, 204, 225, 426, 453 Dragomir, S. S., 89, 97,133,135,427,445 Drazin, M. P., 255, 427 Dresher, M., 120, 121,292,427 Drimbe, M. 0., 105,420 Dwass, M., 388, 389,427 Dykstra, R. L., 344, 427 E
Eaton, M. L., 386, 401, 402, 405, 427 Ehrenberg, A. S. C., 418, 427
Eliezer, C. 1., 118,426,427 Esary, 1. D., 345, 368, 427 Everitt, W. N., 209, 427
F
Faber, G., 218, 427 Fan, K., 204, 325, 329, 330, 427 Farwig, R., 30, 31, 75-77, 79,427 Favard, 1., 212, 223, 224, 427 Fejer, L., 138,427 Feller, W., 299, 427 Fempl, S., 212, 427 Fink, A. M., 63, 89,193,194,427,428 Fomin, S. V., 269, 433 Frank, Ph., 212, 428 Fuchs, L., 323, 428 Fujii, 1.1.,52,53,428 Fujiwara, M., 218, 428
G Gabler, S., 97, 428 Gadziev, A. D., 305, 431 Garding, L., 314, 428 Gauss, C. F., 217, 218, 428 Gavrea, 1., 70, 428 Ger, R., 23, 428 Giaccardi, F., 155,428 Gini, c., 120,428 Godunova, E. K., 80,118,121,188,191 224,225,227,228,231,233,235, 237,300,303,304,428,429 Graham, R. L., 418, 426 Grolous, 1., 42, 429 Grossman, N., 242, 244, 424 Gruss, G., 206, 211, 212, 429 Guseinov, F. V., 51, 429 Gupta, S. S., 400-402, 405, 429, 430 Gurzau, M., 72, 428
H
Haber, S., 77, 430 Hadamard, 1., 138,430 Hakopian, H. A., 77, 430 Hamel, G., 6, 430
Author Index Hansen, F., 52, 430 Hardy, G. H., 1,4,6,45,72, 108, 139, 152, 154,165,182,199,211,234,300, 301,303,319,320,361,365,409,430 Hartman, P., 142, 430 Hayashi, T., 182,430 Hays, W. L., 418, 430 Henderson, R., 42, 430 Henstock, R., 348, 430 Hewett, J. E., 42, 344, 427 Holder, 0., 44, 430 Holgate, P., 388, 430 Hollander, M., 375, 387, 397, 400, 414, 430, 446 Horova, 1.,140,431 Hsu, I. C., 117,245,431 Hu, K., 148,431 Hwang, L.-N., 163,431
Ibragimov, I. I., 305, 431 Imoru, C. 0., 324, 431 Issacson, E., 15,431 Izumi, S., 218, 223, 431
J Janie, R. R., 72,130,133-135,162,163, 194, 200, 445, 453 Jensen, J. L. W. V., 6, 44, 53, 139, 152, 166,431 Jessen, B., 47, 431 Jodeit, M., 63, 89, 428 Jordan, D., 138,431 Jovanovic, M., 41, 431, 434 Jurkat, W. B., 289, 290, 431 K
Kainuma, D., 52, 53, 431 Kaiusa, Th., 288, 431 Kantorovich, L. V., 292, 431 Karamata, J., 212, 271-273, 288, 290, 320, 431,432 Karlin, S., 23, 25, 26, 30,159,161,200, 213,254,267,269,298,341,348, 355,358,432
459
Karamanov, V. G., 41, 432 Keckic, J. D., 7, 8, 81, 82,130,131,133, 175-177,279,432,453 Keilson, J., 364, 432 Keller, H. B., 15,431,438 Kendall, M. G., 417, 432 Kenyon, H., 7, 432 Klamkin, M. S., 134, 166-168,432,445 Klee, V. L., 7, 432 Knopp, K., 102, 112,212,432 Kobayashi, K., 218, 431 Kober, H., 180, 433 Kocic, Lj. M., 40, 55,133,134,140,146, 258,259,261,265,266,433,435, 438,439 Kolmogorov, A. N., 269, 433 Korablev, A. I., 41, 433 Koskela, M., 135,433 Kosmak, L., 293, 433 Kotkowski, B., 281, 433 Kovaeec, A., 259, 269, 433 Krafft, N., 218, 422, 433 Krasnosel'ski'i, M. A., 241, 242, 245, 433 Kubo, F., 52, 53, 428, 433 Kuczma, M., 4, 6, 22, 23, 53,128,433 Kuhn, N., 55, 434
L
Lackovic, 1. B., 4, 8, 55, 72,81,82,137, 143,147,148,175,204,245,248, 258,262,265,277,279,280,281, 283,290,292,294,432-434,439, 451,453 Lah, P., 98, 435 Landau, E., 211, 435 Lapidot, E., 30, 435 Laplace, P. S., 217, 435 Lawrence, S., 72, 435 Leach, E. B., 120,435 Lehmann, E. L., 394, 400, 435 Levin, V. 1., 80, 188, 191,224,225,227, 228,235,237,429 Levinson, N., 71, 435 Lieb, E. H., 353, 354, 423 Lieberman, G., 411, 426 Littlewood, J. E., I, 4, 6, 45, 72, 108. 139, 152, 154, 165, 182, 199, 234, 300, 301,303,319.320,361.365,409,43
460
Author Index
Liu, W. W., 341, 435 Loeve, M., 343, 344,435 Lopes, L., 303, 436 Lorentz, G. G., 289, 325, 329, 330, 411, 427,435 Lovera, P., 278, 435 Lupas, A., 35, 142, 143, 172,204,208,212, 281-283,294,305,435,436 Lupas, L., 210, 436 Lusternik, I., 348, 436 M
Macbeath, A. M., 348, 430 Magnus, A., 62, 436 Maksirnovic, D. M., 133, 134, 147,433, 436,453 Mansion, P., 138,431 Marcus, M., 243, 303, 423, 424, 436 Marik, J., 272, 436 Markovic, D., 82, 436 Marshall, A. W., 155, 156, 218, 254, 294, 307,319-321,329,333-335,337, 338,340,345,359,361,362,372, 380,381,386-388,409,420,437 Matric, B., 33, 437 McLaughlin, H. W., 118,437 McLeod,J. B., 303,437 McShane, E. J., 48-51, 95, 240, 437 Meir, A., 167,437 Menon, K. V., 289, 437 Merkle, M. J., 244, 437 Mesihovic, B. A., 105,201,205,256,274, 283,437,446 Metcalf, F. T., 118,240,426,437 Micchelli, C. A., 19,20,424,437 Miescke, K. J., 401, 402, 429 Mijalkovic, Z. M., 88, 92, 438, 453 Mikusiriski, J. G., 7, 438 Milicevic, M., 244, 438 Milisavljevic, B., 39, 438 Milovanovic, G. V., 16,35,39,166,167, 210,217,225,426,438 Milovanovic, I. Z., 40, 53, 166, 167,210, 217,218,225,250,251,255-257, 259,260,266,275,283,284,433, 438,439,446,450,451,454 Mine, H., 412, 439 Minkowski, H., 348, 439
Mirsky, L., 89, 199,322,424,439 Mitrinovic, D. S., 39, 44, 55, 71, 72, 80-82, 88,90,95,96,99,104,109,112,115, 118, 120, 124, 126-128, 131, 134, 135,137,154,156,159,161,162, 166,171,180-182,188,190,195, 198-200,203,208,209,211,212, 221,222,224,226,231,233,234, 244,245,251,254,256,259,262, 269,271,274,277,278,290,292, 294,295,300,302-304,307,316, 317,320,324,325,364,421,424, 439,440 Mitrovic, Z. M., 279, 453 Mocanu, c., 280, 440 Moldovan, E., 293, 440 Montel, P., 278, 440 Mott, T. E., 278, 440 Mulholland, H. P., 166, 440 Muller, M., 305, 436
N
Nakamura, M., 51-53, 431, 440 Nanson, E. J., 247, 440 Narumi, S., 223, 441 Nazarov, I. M., 199,422 Nehari, Z., 224, 441 Neuman, E., 21, 38, 79,149-151,441 Nevius, S. E., 383, 441 Newman, D. J., 166-168,432,441 Nieto, J. 1.,240,441 Nishiura, T., 217,441 Norlund, N. E., 23, 441 Novikoff, A., 341, 432
o Ogura, K., 202, 441 Olkin, 1.,155,218,254,294,307,319-321, 329,333-335,337,338,340,345, 359,362,372,380,381,386-388, 409,437 Olovyanisnikov, V. M., 32, 441 Opial, Z., 162,441 Oppenheim, A., 80, 246, 315, 441, 442 Ostrow, E., 8, 279, 424 Ostrowski, A. M., 195,207,209,210,442
Author Index Ozeki, N., 180,277,278,284,286, 288-291,302,303,442
P Page, E. B., 400, 442 Pavolovic, S., 155,442 Pecaric, J. E., 6, 16,21,27,32,35,36,39, 45,55,56,57,59,62,63,66-68, 70-72,74,76,79,81,83,86,88-90, 92,93,96-98,101,103,105,111, 117,118, 122, 124, 126, 133-135, 145, 146, 148-152, 154-157, 159, 161-163,165-167,171, 173, 175, 180, 183, 184, 188, 190, 192-194, 199,200,204,205,207,209,213, 215,217,218,221,222,224-226, 232-234,247-251,253-260,262, 274,275,278,282-284,292,301, 307,316,317,324,325,328,419, 422,426,438-446,451,454 Peetre, J., 292, 446 Persson, L. E., 292, 446 Petrovic, M., 130, 154, 155,446 Petschke, M., 195,446 Picard, E., 138, 446 Pick, G., 212, 422, 428 Pidek, H., 206, 422 Pirie, W. R., 400, 446 Pitenger, A. 0., 142,446 Pollak, M., 367, 368, 394, 448 Pollard, H., 272, 426 P6lya, G., 1,4,6,45,72,108,139,152, 154,165,182,199,234,239,288, 289,293,300,301,303,319,320, 322,361,365,409,426,430,447 Ponstein, J., 7, 447 Popoviciu, T., 1,5,16-18,21,23,47,71, 89,102,124,154,171,175, 199,213, 214,259,261,262,293,294,447 Prekopa, A., 295, 347, 349, 353, 447 Proschan, F., 155, 156,218,295,329,330, 334,345,354,361-364,368,373, 375,383,387,391,394,397,400, 401,405,407,414-416,419,420, 422,423,427,430,437,441,447,448 Psenicynyi, B. N., 241, 448
461
R
Rado, T., 141-143,448 Rahmail, R. T., 217, 224, 225, 448 Ra§a, I., 4, 47, 48, 97, 247, 420, 448 Ribaric, M., 98, 435 Riekstyn's, E. Ja., 182, 305, 448 Rinott, Y., 338, 347, 351, 355, 358, 367, 368,394,448 Ripianu, D., 294, 420 Roberts, A. W., 1, 4-7, 9-13, 53, 70,141, 241,325,448 Rockafellar, R. T., 42, 448 Roghi, G., 209, 448 Ross, D. K., 305, 411, 426, 448 Roulier, J., 265, 423 Royden, H. L., 299, 448 Rozanova, G. 1.,235,237-239,448,449 Ruderman, H. D., 411, 449 Ruticii, Ya. B., 241, 242, 245, 433 Rutkowski, I., 201, 449 Ryff, J. V., 363, 449 Ryll-Nardzewski, C., 206, 422
S Sandor. I., 135, 151,427,449 Santner, T. J., 400, 449 Savage, I. R., 398, 399, 449 Savic, B., 27, 30, 32, 274, 446, 449 Schnitzer, F., 217, 441 Schoenberg, I. J., 15, 31,32, 293,424,447, 449 Schur, I., 310, 332, 449 Segalman, D., 72, 435 Seitz, G., 202, 449 Sethuraman, J., 334, 363, 364, 372, 375, 383,387,397,414,430,441,447,448 Shaked, M., 344, 367, 394,449 Sharma, B. D., 19,292,424,449 Shisha, 0., 77, 430 Sholander, M. C., 120,435 Shore, T. R., 135, 449 Sidak, Z., 347, 449 Sirnic, S. K., 279, 434 Sirotkina, A. A., 56, 450 Slater, M. L., 63, 66, 450 Sobel, M., 400, 405, 430
462
Author Index
Stankovic, Lj. R., 4, 72, 73, 75,80,159, 172,173,199,217,224,225,248, 323, 424, 450 Stankovic, M. S., 39,148,277,281,283, 290,292,294,434,438,439 Steffensen,J. F., 57, 181, 182, 187, 199, 450 Steinig, J., 247, 450 Stojanovic, N. M., 256, 260, 266, 283, 439, 454 Stolarsky, K. B., 119, 120,450 Stoyan, D., 341, 450 Studden, W. J., 23, 25-27,159,161,200, 213,254,267,269,432 Sunouchi, G., 218, 450 Svidskii, P. M., 199,422 Szego, G., 159,450
v Varberg, D. E., 1,4-7,9-13,53,70,141, 247,325,448 Vasic, P. M., 7,8,44,72,73,75,80,81,83, 88,89,92,95,99, 104, 105, 109, 112, 115,124,127,131,133,135,143, 147,151,152,154,155,159,162, 165, 166, 172, 173, 175, 176, 182, 184,198,199,200,203-205,217, 224,225,231-233,244,245,262, 265,278,279,300-304,323,421, 424,434,440,452,454 Vial, J.-P., 42, 454 Vietoris, L., 200, 454 Vinogradov, O. P., 289, 454 Volenec, V., 96, 307, 316, 440, 446, 455 Volkov, V. N., 195, 455 von Neumann, J., 49, 455
T
Takesaki, M., 52, 440 Takashashi, T., 218, 245, 246, 431, 450 Tanasescu, c., 307, 314, 317, 440, 450 Tanja, I. J., 292, 424 Tchernikov, S. N., 256, 450 Teicher, H., 340, 388, 389, 424, 427, 450 Temple, W. B., 293, 451 Thompson W. A, Jr., 344, 427 Thunsdorff, H., 217, 451 Tihanski, D. P., 356,451 Timan, A. F., 140,451 Toader, Gh., 57, 247, 250, 251, 255-257, 261,279-281,439,446,451 Toda, K., 5, 452 Tomic, M., 321, 452 Tomilenko, V. A, 294, 452 Tong, Y. L., 336, 344, 346, 355, 358, 359, 364,366,367,371,374,391,394, 400,415,416,423,449,452 Tudor, Gh., 27, 32, 33,424,446 Tzimbalario, J., 284, 452
W
Walkup, D. W., 345, 368, 427 Wang, C.-L., 117,147,225,446,455 Wang, X.-H., 147,455 Waszak, A., 281, 433 Weinberger, H. F., 159,455 Weyl, H., 321, 455 Widder, D., 300, 455 Wilkins, J. E., 292, 455 Winckler, A., 198,218,455 Wood, B., 305, 455
Y
Yang, G.-S., 163,431 You, G.-R., 128,455 Young, W. H., 240, 455
Z
U
Umegaki, H., 51, 52, 440, 452
ZalgalIer, V., 295, 423 Zhang, Y. T., 151,455 Zmorovic, V. A, 34, 455 Zwick, D., 30, 31, 74-77, 79, 427, 446, 456 Zygmund, A, 39, 456
Subject Index
A
Abel's identity, 254 generalization of, 254, 274 and star-shaped sequences, 258 Abel's inequality, 271 Aczel's inequality for isotonic functionals, 125 AI functions, see Arrangement increasing functions Anderson's inequality, 224 Arrangement increasing (AI) functions, 376 definition of, 376 examples of, 376, 377,384-386, 392 and moment inequalities, 391-392, 394 multivariate generalization of, see MAl, MAD functions for overlapping sums of random variables, 386-389 preservation properties of, 379-384, 391, 392 and probability inequalities, 392, 395, 396 and rank order problems, 397-400 and Schur-concave densities, 379 and selection of populations, 400-404 and TP 2 densities, 379
B
B-spline, 20 Beckenbach's inequalities, 123, 161 Bellman's inequality for isotonic functionals, 125
Bernoulli Inequality, 163 Bernstein's polynomials, 293, 326 and continuous convex functions, 293 definition of, 293 Berwald's inequality, 216 Boas' inequality, 229 Bohr's inequality, 131 Boland-Proschan Inequality, 330-331 Borell's theorem, 351 Brunk-Olkin Inequality, 156 Brunn-Minkowski Inequality, 348 Burkill's inequality, 171, 172 C
Callebaut's inequality, 118 Carleman's inequality, 231 Cauchy Inequality, 131 Cebysev-Gruss Inequality, 88, 206-209 discrete analogue of, 206 improvements of, 210-211 Cebysev's inequality, 197 generalizations of, 198-201 interpolation inequalities of, 205 Cebysev's ratio, 223 Concave functions, 1 definition of, 1 of higher order, 15, 325 and Fan-Lorentz Inequality, 325 and hyperbolic forms, 314-317 Convex functions characterizations of, 140-142 in terms of Bernstein's polynomial, 293
463
464
Subject Index
Convex Functions (Continued.) in terms of Steklov functions, 140 closure properties of,S definition of, 1, 13 geometric interpretation of, 2, 3 of higher order, 15-17,22, 23, 203 definition of, 15, 17 inequalities for, 262 and inequalities for derivatives, 31-39 and inequalities for differences, 33-37 in Jensen sense, 17,21 and Jensen's inequality, 71-75, 77, 79-82 and kth order divided difference, 14,22 and Popoviciu's inequality, 175 inequalities for derivatives, 31-39 of a normed linear space, 9-13 and Jensen-convex functions, 7 and Jensen's inequality, 43-46, 83 and majorization, 320, 321 in means, 8 of one variable, see One variable convex functions operator convex functions, 11 of order (m, n), 18,21,208,325 and Fan-Lorentz Inequality, 325 and (m, n) divided differences, 18 P-convex functions of order n, 18 with respect to ECf system of functions, 23-29 and Schur-convex functions, 333 strongly convex functions, 40 strongly Jensen-convex functions, 40 and Wright-convex functions, 7 Convex sequences closure properties of, 289 conditions for, 279 definition of, 6 of higher order, 21, 250 equivalent conditions for, 279 identities of, 277,278 inequalities for, 253-257, 260, 261 implications of, 279 D
de Finetti's theorem, 344 Dresher's inequality, 120
E
ECf (extended complete Tchebycheff) system of functions, 23 definition of, 24 functions convex with respect to, 23-29, 203 F
Fan-Lorentz Inequality, 325 Favard's inequality, 212, 224 generalizations of, 213, 214 Frechet derivatives, 10
G Gauss' inequality, 195 Godunova-Levin Inequality, 80 Goldman's inequality, 109 Gram's inequality, 201 Groenman's inequality, 312 H
H-positive functions, 176-178, 180 Hardy-Littlewood-Polya Inequalities, 234, 412-413 Hardy's inequality, 230 Hermite-Hadamard's inequality, 79,137, 139 discrete analogue of, 145 generalizations of, 143, 144, 147-151 historical background of, 137-139 for positive linear functionals, 146 Hilbert's inequality, 234 Hlawka's inequality, 172 Holder's inequality generalizations of, 127, 128 for isotonic functionals, 113, 118 HOlder's ratio, 223
Inequalities for absolute moments, 217, 218 via arrangement increasing property, see Arrangement increasing functions
Subject Index
Inequalities (Continued.) for complex functionals and norms, 128-135 for dependent random variables, 368-374 for exchangeable random variables, 343-347,366-368 and de Finetti's theorem, 344 for generalized means and moments, 107, 342,343 generalization to functionals, 108-112 log-convexity property of, 117,118, 222, 342, 365 via Muirhead's theorem, see Muirhead's theorem via majorization, see Majorization for means for isotonic functionals, 108,
109 for star-shaped functions, 153, 164 for sums of order p, 165-168
J
Jensen- (J-)convex functions, 5 and convex functions, 7, 13, 44 definition of, 5 of higher order, 17,21 strongly Jensen-convex functions, 40 and Wright-convex functions, 7 Jensen-Boas Inequality, 59 reversal of, 86 Jensen-Brunk Inequality, 60 Jensen's inequality companion inequalities of, 63-64 converses of, 98-103 and convex functions, see Convex functions generalizations and refinements of, 47, 48,51-53,87,88,90-97 geometric formulation of, 48-51 higher order of, 71, 73-78, 82, 97 via monotonicity, 90 for random variables, 339, 340 generalizations of, 340-342 reversals of, 83-85 Jensen-Steffensen Inequality, 57, 324 generalizations of, 60, 91 integral analogue of, 59 refinements of, 89 reversal of, 83
465
K kth order divided difference, 14 and higher-order convex functions, 14 integral representation of, 15 Knopp's inequality, 234
L
Liapunov's inequality for isotonic functionals, 117 Log-concave density functions and Prekopa's theorem, 294-295, 348-351 properties of, 353-355 and Schur-concave density functions, 355 Log-concave functions, 7, 304-305, 348-351 closure properties of, 294, 295, 383 definition of, 7 Log-concave sequences, 302 closure properties of, 289 Log-convex functions, 7, 304, 305, 363, 364 and convex functions, 7 definition of, 7 examples of, 364 Log-convex sequences, 302 closure properties of, 284, 288, 290, 294
M
Majorization and convex functions, 319, 323, 333 definition of, 75, 319 and doubly stochastic matrices, 321 for functions, 324, 325 multivariate majorization definitions of, 337 and n-dimensional rectangles, 358 and partial ordering of triangles, 307-313 and Schur-concave functions, 332 and Schur-convex functions, 332 and Schur's condition, 312 submajorization, 320-321 supermajorization, 321 Marcus-Lopes Inequality, 303 Marshall-Olkin Theorem, 335 Marshall-Olkin-Proschan Inequality, 155 Marshall-Proschan Inequality, 362
466
Subject Index
McShane's inequality, 48, 49, 127 Mine's inequalities, 412 Minkowski Inequality, 166 generalizations of, 127, 128 for isotonic functionals, 114 Mitrinovic-Pecaric Inequality, 90 Muirhead's theorem, 361 generalizations of, 361-364 and inequalities for means, 365 integral form of, 363 Multivariate arrangement decreasing (MAD) functions, 412 Multivariate arrangement increasing (MAl) functions, 407, 411 and AI functions, 414, 416 definition of, 408 examples of, 410-412, 414 and Lorentz's inequality, 411 and measures of agreement, 417, 418 preservation and closure properties of, 413-416 and Ruderman's inequality, 411 and Schur-convex functions, 410 Multivariate majorization, see Majorization Multivariate probability inequalities dimension-related, 343-347, 366-371 for distribution functions, 335 for long-concave probability measures, 349-351 for n-dimensional rectangles, 358 Multivariate totally positive of order two (MTP z) functions, 409 and multivariate AI functions, 410 N
N-Functions, 241, 242 and Young's inequality, 242 Nanson's inequality, 247 generalizations of, 248, 250, 251
o One-variable convex functions closure properties of, 5 and compositions of functions, 7 and continuity, 6 definition of, 1 derivatives of, 4, 5 Opial's inequality, 162,239
Ordering of convexity, 8, 279-281 Ostrowski's inequality, 209 P
Partial ordering of triangles via majorization, 307-313 Petrovic's inequality, 154, 324 generalizations of, 155 Popoviciu's inequality, 171 for isotonic functionals, 125 Prekopa's theorem, 349 and n-dimensional rectangles, 358 Proschan-Sethuraman Theorem, 335-336, 383 Proschan-Sethuraman-Tong Inequality, 364-365
Q Quasi-arithmetic mean, 231, 300, 301 Quasi-convex functions, 7, 40, 41 definition of, 7 and quotient of means of nonnegative functions, 292 strongly quasiconvex functions, 40 weakly quasiconvex functions, 42 R Root-increasing functions closure property of, 296 definition of, 296 Ruderman's inequality, 411 S Schur-concave functions, 310-312, 332 definition of, 332 and majorization, 332 Schur-convex functions, 75, 310-312, 332, 365 closure properties of, 334-336 definition of, 75, 332 and distribution functions, 335 and higher order convex functions, 76 and majorization, 332 and permutation-invariant convex functions, 334-334
Subject Index
Schur's (Schur-Ostrowski) condition, 310, 312,333 Second integral mean value theorem, 270 Semigroup property, 297 Sign-changes of a measure, 267-269 Similarly-ordered functions, 199 definition of, 199 Similarly-ordered sequences, 199 definition of, 199 Slater's inequality, 66-67, 69 Star-shaped functions, 8, 296 definition of, 296 inequalities for, see Inequalities in mean, 8 Star-shaped sequences inequalities for, 258 of order m, 257 orderings for, 279, 281-284 Steffensen's inequality, 181 generalizations of, 182, 184, 192-175 and Jensen-Steffensen Inequality, 181 Steklov functions, 139 Subadditive functions, 8, 176-178, 180,280, 409 closure property of, 300 definition of, 296 in mean, 8 Subadditive sequences, 279 Subrnultiplicative functions, 109 Superadditive functions, 8, 176, 178,280, 296,409 closure property of, 296 definition of, 296 in mean, 8 of nth order, 177, 178 Superadditive sequences, 279 Supermultiplicative functions, 109 closure property of, 296 definition of, 296
467
Szego's inequality, 161
T
Totally-positive-of-order-two (TP 2) functions, 297 and arrangement increasing functions, 379 multivariate generalization of, see Multivariate totally positive of order two (MTP 2) functions
v van der Mende's determinant, 24 Vasic-Pecaric Inequality, 232
W
Wright-convex functions, 7,13,161,162, 322, 323 and convex functions, 7 definition of, 7 inequalities for, 55 and Jensen-convex functions, 7 and Szego's inequality, 161
Y
Young's inequality, 239 converse of, 244 generalizations of, 245, 246 geometric interpretation of, 240
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