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=--
xo
h1xR3dEdrl, D
(5.1.64)
THE LIFTING, SURFACE EQUATION
173
as it results from (5.1.19) and (5.1.27). If we keep only the terms of order O(E), it follows: R.- _ -Poo U.2 Lo2
Rr = 2pxL
JJ
JJ D f
(x, y)dxdy,
1i1=(x, y)dxdy, (5.1.65)
(A fr, Afy) = p
A-Y'X)f (x, y)dxdy, D
M, = 2pmLo Jf (xh- yhtr)dxdy. For the lifting surface (hl = 0) the formulas (5.1.55)-(5.1.59) become R.
fD f (x, y)dxdy,
R: = -PU Lo f f f(x,y)h.(x,y)dxdy, D
(5.1.66) (M1. A.fy)
=p
LG
ff(-y, x)f (x, y)dxdy,
A9, = 2pxLo ff (xhy - yhr)dxdy.. D
Rz, Air §i My being O(s), and Rr and Al;, O(E2). 5.1.11
Another Deduction of the Representation of the Gen-. eral Solution
In the sequel we shall deduce again the representation of the solution
(5.1.8), (5.1.12). We start from D. Homentcovschi's idea (exposed in (A.81) to utilize the Fourier transform for bounded domains (A.6]. The method synthesizes the problem of determination of the fundamental solution and the problem of replacing the wing with a forces distribution.
In addition it justifies the assimilation of the wing with a distribution of forces having the form (fl, 0. f ). Indeed, employing the formulas
THE LIFTING SURFACE THEORY
174
(A.8.2) to the system of linearized aerodynamics (2.1.30) and taking into account that D is a surface of discontinuity, we get
0=-ia1A (5.1.67)
0=-iali) - iap- Pk, with the notations [jpj)e,(QI x+a2Y)d x d
y,
(W' P) = JJ D ( where, taking into account (5.1.20), (5.1.25) and (5.1.27), awj = w(x, y, +0) - w(x, y, -0) = 2hi=(x, y) (5.1.68)
W = p(x, y, +0) - p(x, y, -0) = f (X., Y) From (5.1.67) one determines first p and then w. One obtains
ia3P - ia1W
a2-M201
(5.1.69)
ia3W W =ate
+,Q2 a
ia1P
ia2P
+ a ( 2 - M22)
Utilizing the expressions of P and W, we find: 1Q3
p-
J fp(t, r?) a2-A?2aj e(-t4+0tin)9 dv7is l
dd d11,
-2 [1D hit (e, t?) a2 - M2a2
whence, taking into account (A.6.9), P(x, y, z)
fJD'02
,-I
i(o,+ozq)
a2 -
2ai d dy+ (5.1.70)
rrrr +2JJD
hlt
,rl)
az
a2 - M2a2
Employing (A.7.2) we obtain
P(x,y,z) =-4a
+ 27r
f fD rr
JJD
(_)d+ (5.1.71)
hlt (, q) 8x (R1 d dr7
NUMERICAL I`TECRATION OF THE LIFI1NC SURFACE EQUATION
175
where R1 is that from (5.1.7). We obtained in this way the representation (5.1.8). Similarly, utilizing (2.3.11) and (2.3.27), we have:
F`1 fly
_
ial(a2 - M1ai)
(5.1.72) r
0 aJ-110
1)dr
47r
ya+z2 yo
(i+) jai
such that R, having the same expression, it follows:
w(x,y,z)
=-T7r
-
1,! n
Yj)
dFdij-
/32
+ 4T 11
(5.1.73)
(R1) di;d;+
0 [ ?100+Z2 yo
(1+)].d rl,
which is just the representation (5.1.12). We have to notice that from (5.1.70) one deduces the inversion formulas 1
[Y2
at(G2 - h12a21) 1
4z y2
y
1+
X
r.' +
(a" +z-) (5.1.74)
which could be utilized in 2.3.
5.2 5.2.1
Methods for the Numerical Integration of the Lifting Surface Equation The General Theory
There are not yet known exact solutions of the equation (5.1.28). The first numerical solution was given by Multhopp in 1950 15.24]. Previously the same author had given in 1937 the approximate solution (to which one assigned his name), for the lifting line equation (Prandtl's equation (6.1.16)). Multhopp's method relies on the Gauss-type quadrature formulas for non-singular integrals. At that time there were not available quadrature formulas for singular equations. For the singularity appearing in the lifting surface equation, Multhopp utilizes a series expansion
176
THE I..IFTINC SURFACE THEORY
with Chebyshev polynomials of first kind, which is truncated in order to obtain an algebraic system. The method is analogous to Glauert's method for Prandtl's equations, except that the sin functions are replaced by Chebyshev polynomials. In 1958, at a Meeting in Fort Worth, Hsu gave a quadrature formula for integrals with a strong singularity and employed this formula for the singularity from the equation (5.1.28). However, in Hsu's formula the unknowns are present even in the collocation points and this is a drawback. Starting from a formula given by Monegato [A.52), Drago§ gives [6.5] the formula (F.3.5) where there are present supplementary unknowns in the collocation points. One utilizes successfully this formula for solving Prandtl's equation in 6.5 and for solving the lifting surface equation in [5.10] and [5.11]. These solution will be presented in 5.2 and 5.3. In 5.2 we shall sketch the solution of the equation S via the collocation method. We have to solve the equation: I 4rr
N(xo, lyo)dt dr1= -hr(x, y),
i f( Q
(5.2.1)
o
where
N(xo,yo)=1+
To
V2'or+
Y4
(5.2.2)
with the following conditions:
f (t, ±b) = 0,
x-(fb) < < x+(±b)
(5.2.3)
-b < rl < +b. (5.2.4) The first two conditions mean the continuity of the pressure on the f (x+(rl), q) = 0,
lateral edges in case that they are straight segments (if the lateral edges are represented by points the conditions disappear by virtue of (5.1.1)). The condition (5.2.4) ensures the boundedness of the pressure along the trailing edge. One performs the following reasoning: each intersection
of the wing with a plane parallel to xOz determines a thin profile; as it is known from 3.1 for such a profile one imposes the boundedness condition on the trailing edge.
In order to utilize the quadrature formulas we shall perform the change of variables
(x, y) - (u, v)
TI) --4 (a.
defined by the equations x = a(y)u + c(y) Zr = a(ri)a + c(q) (5.2.5) y
by
rl = b13
177
NUMERICAL INTEGRATION OF THE LIFTING SURFACE EQUATION
with
a(y) =
x+(y)
- z-(y) 2
,
c(y) =
x+ (y) + x-(y) 2
(5.2.6)
Writing the equation (5.2.1) as follows:
r
1
T
UFO
+(n)
f
q)N(xo, yo)d
do = -4xhz(x, y)
and taking into account that e(t,g)
= a(F)b,
.9(a, /3)
we deduce
f
a(A)
1
(v - A)2
f (a, /3)N(u, v, a, Q)da] dfl = 9(u, v),
(5.2.7)
where denoting by a(v), c(v), f (a, /3) etc., the functions a(y), c(y), f((, q) in the new variables, we have
a(v)u + c(v) - a(/J)a - c(/3)
N(u, v, a, /3) = 1 +
1/2
{[a(v)u + c(v) - a(Q)a - c(f)J' + k2b2(v - /3)21
(5.2.8) (5.2.9)
g(u, v) = -4rrbhi(u, v),
with the notation k
The Kutta-Joukowski conditions
(5.2.3) become
-1 < a < +1) , f(1,/3)=0, -1
(5.2.10) (5.2.11)
The solution of the equation (5.2.7) depends on the behaviour that we impose at the extremities of the intervals (±1). For a fixed 0 , one obtains within the wing a thin profile. For such a profile we have imposed
in 3.1 the behavior given by
++ a . Along the span one imposes in
the behaviour 1 --02. Such a behaviour ensures that the conditions (5.2.10) are satisfied. We shall seek for solutions f (a/3) having the shape
f(a,A) = f -l
++aF(a,A),
(5.2.12)
178
THE LIMING SURFACE THEORY
with F bounded. For F one obtain the equation
JT (p1- v a(13) I- t '1 + a
F(Q, 3)N (ti: vj rx $)da1 d8 _
-1
=y(u.v),
(5.2.13)
Utilizing the quadrature formula (F.2. [8), this equation becomes ni
1 ^F
t
2. (1 - a)
2
r)
,
a(;T):"(u.. v,(xi,O)F(ai, 1)d 8 = (5.2.14)
= (tin + 1)g(u.v),
where
`=cos2m= (5.2.15) i= lm. a +1' From now on Nttlithopp's method and the quadrature: formulas method are separating.
Multhopp's Method
5.2.2
Using the formula (F.4.2) for (f3 m
v)-2
,
equation (5.2.14) becomes
p
--4irEE(1+k)(1i=1 k-i
J1
-or)Uk(u) JJJ
- 3 `u(f3)N(a. v,
!
= (2m + 1)g(u,v).
(5.2.16)
One calculates the integral from this equation utilizing (F.2.12). One Obtains
r -.1-r
it
E(l+I)(I
r=1 k-l,t=1 (5.2.17)
=(2m+ 1)(n.+ 1)9(u, V),
-1 < u,v <+1,
NUMERICAL INTEGRATION O THE LIFTING SURFACE EQUATION
with
cosn+l'
7
=r
.
179
(5.2.18)
Introducing the notation
H(ai,f3j) _ (1 - ai)(1 -QJ)a(#j)F(ai,f3j),
(5.2.19)
the system (5.2.17) becomes m rn
p
-4irrG.rL.r
(1
k)Uk(v)Uk(Yj) (u, v,ai,Qj)H(ai,QJ) _
i=1 j=1 k-i
(5.2.20)
=(2m+1)(n+1)g(u,v),
-1
There are m x n unknowns, H(ai, /3j ). In order to obtain the same number of equations in (5.2.20) we shall assign m values to u and n values to v, obviously, all of them in the interval (-1, +1). As we shall see later, the aerodynamic coefficients are functions of H(ai, /3j ). It is sufficient to find out these unknowns. We may write computer programs for solving the system (5.2.20).
5.2.3
The Quadrature Formulas Method
Utilizing in equation (5.2.14) the formula (F.3.5), we obtain the equation
m n
tar E F` [1i=1 j=1
(1 - ai)(1 ()3j - Ak)2 m
-7r(2m + 1)(n + 1)2 E(1 - ai)a(.3k)N(u, Qk, ai, Qk)F(ai, Qk) _ iml
= (2m + 1) (n + 1)g(u,13k) , (5.2.21)
where
Aj=ten+1, for k = T.
(5.2.22)
180
THE LIFTING SURFACE THEORY
In (5.2.21) we have a system of n linear algebraic equations with m x n unknowns F(a1, /3j ). Imposing the system to be verified in m points ul
-
oOS
Vir 2m+1
=al,
t=T,
(5.2.23)
the number of equations equals the number of unknowns. The system will be written as follows
m n
Bik, a=Tm k=I-n(5.2.24)
Aekij Ha 13 i=1
where we denoted Alki;
(2 [1- (-1)j+k]
=t
()3j -)3k)2
-(2m + 1)(n + 1)21
j
-A
}N(atflkoi/3i)
(5.2.25)
Btk = (2m + 1) (n + 1)9(a1,Pk)
5.2.4
The Aerodynamic Action
The lift and moment coefficients are calculated by the aid of formulas (5.1.54)-(5.1.56). Using (5.2.12), (F.2.18) and (F.2.12) we obtain: CL
A
ff
D
Af
+1
=Af
f
+L +1
f(t,
1- fl2a(Q) 1
41r2b
m
[f
1
l f(a,
d/3 =
+1 1
1+
aF(a, l)da] dQ =
(5.2.26)
"
A(2m+ 1)(n+ 1) FF H(a"Pj)' w1 j=1
where H(a;, (3j) are (5.2.19). Formula (5.2.26) is valid for both Multhopp's method and the quadrature formulas method.
NUMERICAL INTEGRATION OF THE LIFTING SURFACE EQUATION
181
In a similar way we obtain: 2
=
IL of 4R
Aao
+I
J_ I
ja(,3)f (a,13)da df3 =
n
in
2b2
f
+I
aoA(2m + 1)(n + 1) E E Qj H(ai,13j) i=1 j=1
,
(5.2.27) cy
Aao 2b - Aao
11
f
r')dCdr' =
+1
+I
J-1 4-Ir
2
ta(,B)a + c(R)I a(A)f (a, Q)da d/.3 =
b
aoA(2m+1)(n+1) ao
m
r( ( it
(5.2.28)
q
ti_1 j=1
representing the length of the medium chord and
di =
CD = - A !ID 41r2 b
A(2n+1)(n+1)
n
(5.2.29)
n
i=1 j=1
For the flat plate of incidence E, we have h(x, y) = -Ex then g(u, v) _ 47rb. For the rectangular flat plate we have x_ = -1, x+ = 1, a = 1,
c=0, u-a
N(uvapl=1+ , , , 5.2.5
(5.2.30)
The Third Method
Some numerical experiments show that it is not always indicated to
impose the behaviour along the direction a under the form We shall use in (5.2.7) the following quadrature formula +1
m f (a, Q)N(u, v, a, /3)da = > f(ai, i9)Ki (u, v, f3) ,
1
i=1
(5.2.31)
182
THE LIFTING SURFACE THEORY
2i
where a; = - m , i = 0, 1'.. . , m are equidistant nodes on the interm val (-1,+1), and K1 (u, v, /3) =
joi-I
N(u, v, a, fl)da =
2
m
1
a(Q) /[a(v)u + c(v) - a(A)a; -- c(/3)1+ k2b2(v
+
- p)2+
(a(v)u + c(v) - a(/3)a{-1 - c(,6)J2 + k2b2(v - /3)2.
(5.2.32)
The behaviour in the span direction remains the same (like in the previous methods), hence:
1--#2F(&,,6),
f (a, A) =
(5.2.33)
where F(a, 3) is finite for rQ = ±1. We shall use the same formula (F.3.5) with respect to p. So, the equation (5.2.7) furnishes the following discretized form of the equation (5.2.7) ,n
n
HtkiiF(a (3:) = bh=(ailk) ,
(5.2.34)
i=I j=1
where
Htk;j _ =
1
4(n + 1)
{i_(_i+k]
2 Ak)2a(13i)Hj(ac,,6k, Qj)
(Qj -
,
k (5.2.35)
and
n +l 1 H10919 =
a(/3k)Ha(at, Qk, /3k) .
(5.2.36)
The algebraic system (5.2.34) has m x n linear equations with m x n where #j =coo 17r unknowns
n+l*
NUMERICAL INTEGRATION OF THE LIFTING SURFACE EQUATION
183
The lift and moment coefficients are calculated by means of formulas CL
_ -
2b
+1
A
11
+1
1-,2a(fl)F(a,A)da dQ =
J_1
1
2bir
(n + 1)A
j
(1-1,)a(13j) J
F(a, $$)da
1
(5.2.37)
1
n
4bnr
(1 in
n+ 1 )rr1A Jul i=1 C,
22 2
1
1+1
#a(13)
J1
=
1- J32F(a, /3)da dfl _ (5.2.38)
nm
4b2ir
E I6ja(0j)(1 - AJ)F(ai, Qi) = (n + 1)mAao, Jul i=1 Aao
f
1111
a(#)[a(A)a + c(Q)]
1- 02fla,,O)da d/3 =
n cm
-4b,r In + 1)mAan Jul iml
EEa(AJ)(1-
_Q1)(2i-'m-1a(pi)+c(fii),F(ai,QP)(5.2.39)
In the paper 15.101, from which we presented this method, there are presented computer programs for the elliptical flat plate h(x, y)
= -cx, x2 + e < 1, b = 2
and for the wing whose projection on the Oxy - plane is an rectangle
-b
h(x,y) = e(1 - x2),
e <
(5.2.40)
THE LIFTING SURFACE THEORY
184
The fluid in considered incompressible. For the rectangular wing one obtains an analytic solutions in the framework of the theory dealing with the wings of low aspect ratio. In this way we have a test solution for the third method. One deduces that this method furnishes very good results.
5.3 5.3.1
Ground Effects in the Lifting Surface Theory The General Solution
The ground effects in the lifting surface theory were taken into consideration in (5.311 and [5.371 where one utilizes asymptotic methods. An approach of this subject in the framework of curvilinear lifting line theory may be found in [1.32], [1.331. The present subsection is elaborated following (5.8], where one gives the general theory. One utilizes the fundamental solutions method. The geometry of the problem is presented in figure 5.3.1. The origin of the reference frame is located in the middle of the span, the Ox-axis
has the direction of the unperturbed stream and the Oy-axis has the span direction. The ground is considered to be the plane 1I having the equation z = -d/2. The unperturbed flow is characterized by the velocity Ui , the pressure p(,,, and the density po and it is considered to be subsonic like in 5.1. The field of velocity v1, the pressure p1 and
Fig. 5.3.1.
the density p1 for the perturbed flow have the form (2.1.3). One utilizes
185
GROUND EFFECTS IN THE LIFTING SURFACE THEORY
dimensionless variables. The equation of the upper and lower surfaces are given by (5.1.2). It results the following boundary conditions w(x, y, ±0) = hr(x, y, ±hiz(x, y)
(5.3.1)
(x, y) E D
(5.3.2)
w(x, y, -d/2) = 0, (V )x, y.
For satisfying the last condition we shall utilize the images method. This means to replace the wing with a forces distribution f + = (fl, 0, f )
defined on D and with a symmetric distribution f - = (fl, 0, -f) defined on the domain D', which is the symmetric of D with respect to the plane II. In order to write the general form of the perturbation fields p and w we have at first to write the form determined by the
concentrated forces f+ in P+(4+) and f- in P_(4-). We have therefore to determine the solution of the equations
M28p/8x + divv = 0 (5.3.3)
8v/8x + grad p = f+b(x - 4+) + f -b(x - 4-) corresponding to the system (2.3.4). The system (5.3.3) is linear and its solution is the sum of the corresponding solutions from (2.3.4). Taking into account (2.3.24) and (2.3.29), and the form of the fields f + and f -, we deduce: p(x, y, z)
=-4
w(x* y, z)
=4
0T (f,
+fa ) `R+l
8z ( R+)
4 f8 x
47r
(fie -fe)
(i)'
R+) +
+47r 5; [(y_+)2+(z_z+)2 (i+xR+ )J+ 2
+4 Oz
f
R_)+4 f8x (R_)y - 17
4ir 8y (y - 17- )2 where
R+=
(x - t:1)2+
(z - C-)2
+
-- (1 +
x R-
2n*)2 +(z - (±)2).
l
)J
' (5.3.4)
(5.3.5)
186
THE LIFTING SURFACE THEORY
The points P+ and P- are symmetric if £+ _ {- = f, tl+ = n- = n, t+ _ C, C- _ C - d. When P+ are in D((= 0), the symmetric points
P-((- _ -d) are in V. Assimilating the wing with a continuous superposition of forces defined on on D, it results the following general solution:
p(x, y, z) _
- 47r JJv [fi,-+f,q)-}
()d_
d-9(5.3.6)
rr
f (e, n) 8 l ((Rid) dkc di J
w(xy, z)
4s
IL
+47r'ID
[f(t,
n)ex
JJDf(t,rl)
4r AD
A2f(t, n)
] (R,'
) de cI +
(L)d+ (i+)}d_ [yo-0
If,V,17)z +
1
+47r
-
02f (f, n)
8J
!0-
Lyo+
dC
(1+ -10-d/J dt
dn,
(5.3.7)
where xo=x-t, yo=y-Hand Rt =
xo+(32(yo+z2), Rld= 90 +p2[yo+(z+d)2J.
(5.3.8)
This is the general representation of the perturbation, the functions f, (t, r)) and f (t, t) being determined from the boundary conditions (5.3.1). The condition (5.3.2) is obviously satisfied.
5.3.2 .
The Integral Equation
Acting like in 5.1, we shall pass to limit considering z -- ±0, (x, y) C-
E D. To the limit, only the integrals related to R are singular. Using the formulas (5.1.16), (5.1.18) and (5.1.24), from (5.3.6) and (5.3.7) we
CROU\l) EFFECTS IN THE LIFTING SURFACE THEORY
187
get
P(x, y, ±0) = 4rID fi(f,t,)Rgdt dry ± 2f (x, y) +
+ 4a JJ f1(, q)
ddi 4j r
R3 dti,
,
(5.3.9)
P(x, y, +0) - P(-T, V, -0) = f (x, y),
and
w(x, y, f0) =
2 f1 (x, y)
47
if
-
47r ,IJD
R (i+)d_
f
ff f (t, t)N(xo,
(Z' Y)
-
d'l
41r
3Nn)dt dr1,
(5.3.10)
where
N
yo) _
(d2-#
) + (d + ;'F d
2
2
(1 + xd° )
I
(5.3.11)
with the notations
R=
xo + $2y$ , Rd =
xo + 02 (y02 + d2) .
(5.3.12)
Imposing the boundary conditions (5.3.1) we deduce
fi (x, y) = -2hi:(x, y)
(5.3.13)
and then
4Rv
f
(YOT
L1+'0 R)
dk drl + 4,r
AD
f (f, rl)N(xo, yo)dC dy =
(5.3.14)
The equation (5.3.14) may be called the generalized lifting surface equation. It was given in [5.8]. The sign "*" is for the Finite Part. Using
188
THE LIFTING SURFACE THEORY
the identity (5.1.32) we may write the equation as follows:
4n 8y
jf f (,'1)
1+
o)
= h' (x, y)
drl
-
4a
If f (t, r!)N(xo Uo)df do =
.JJD hlfR3
1) dt
dtl . (5.3.15)
The Two-Dimensional Problem
5.3.3
Like in 5.1.7, in order to obtain the representation of the solution and
the integral equation for the wing of infinite span we assume that the normal sections in the wing determine profiles having the same shape. It means that the equations (5.1.2) have the form z = h(x) ± hl(x)
(V)y
and the domain D is a rectangle (-1 < x < 1, -b < y < b) with oo. We notice that in the representation of the general solution
b
(5.3.6) and (5.3.7) ff and f have the form f,(£) and f(t). Relying on formulas like (5.1.46), from (5.3.6) we deduce
P(x, z) -
1
21rp 1
)324f (t) dt+ f,2 xoft Wxo ++ $2z2 r+1 xofl (t) +,32(z + d)1 (t)
0 +$2(x2+d)2 which are just (3.2.3)1. Using formulas like (5.1.47), from (5.3.7) it results: w(x,z) __
r11 x01(0+
z2(C)dc _2 J_li xOf +fl
(
+d)2( )41
2a
i.e. just (3.2.3)2.
For obtaining the integral equation we shall use (5.1.45). We also have oo do
J
ydq
2 ,
l
00
The integral
1=
+00
L -0o (y[+
d2 _ yo
xo dn
)2 R1
= 0.
(5.3.18)
189
THE WING OF LOW ASPECT RATIO
reduces to integrals having the shape
Jo
(u2 +
r
du d2) VU-T-+31
Je
du (u2 + d&)Z u +
which may be calculated using the change of variable u -+ v where
u
V
(5.3.17)
VU-27 71
One obtains
I=
2,0
d
1-
xo
xo
arctan
xo dQ
(5.3.18)
Using the same change of variable (5.3.17) one obtains also +O0
xo d
1 (plc
01?
11
9
1
+ ;01
o
xo
x
arctan d
(5.3.19)
such that we finally obtain oo
-l
(5.3.20)
xo + d2 02
Taking into account the previous results, the integral equation (5.4.12) becomes
,r+i 1 Jl
1
xo
_
dt
-
r+i xof ()
27r JJ
1
xo + d2#2
L" /+1
clk
= (5.3.21)
h'(1)
which is just (3.2.7).
In (5.111 one extends the method from 5.2.3 also to the equation (5.3.14).
5.4 The Wing of Low Aspect Ratio 5.4.1
The Integral Equation
In the sequel we shall pay attention to the ratio A = (2b)2/A,
(5.4.1)
190
THE LIFTING SURFACE THEORY
called the aspect ratio. We denoted by 2b the span and by A the area of the domain D. For wings characterized by a small A (wings of low aspect ratio) one develops herein a theory which leads to the integration of the lifting surface equation (5.1.33). For wings characterized by a big A we shall develop in the following chapter the lifting line theory. These
are the two asymptotic theories of the lifting surface equation. If the square of the span is small with respect to the area A, we deduce that on the greatest part of the wing we have yo << xo (see fig. 5.4.1) and we may write R
Ixoi
xo
xo l
L1 + O (
)J ,
(5.4.2)
o
where R is (5.1.17). On the contrary, when the square of the span is big with respect to A (see figure 6.1.1), on the greatest part of the wing we have xo << yo, so that we can make the hypothesis (see 6.1).
Fig. 5.4.1.
R = kayo)
(5.4.3)
Returning to the wings of low aspect ratio, we notice that under the hypothesis (5.4.2) the equation (5.1.33) may be approodmated by 4rr 8y J JD
f (n) (j+LX-01 df drl =1. (z, y)
(5.4.4)
Noticing that the integrand of this equation is different from zero only on t < x, we shall consider only wings whose trailing edge is a straight line perpendicular on Ox like in 5.4.1. Introducing the unknown function F(x, q)
JS-(n)
f(s, q)d,
(5.4.5)
THE WING OF LOW ASPECT RATIO
191
utilized for the first time by Jones 15.171, 15.18), the equation (5.4.4) becomes
8
1
v+(=)
{
dry = h=(x, y) ,
2w 8y Jy_ (x)
(5.4.6)
yo
where y = y+(x) represents the equation of the leading edge OB, and y = y- (r), the equation of the leading edge OA. From (5.4.5) and from the figure one notices that F(x, y- (x)) = F(x, y+ (x)) = 0.
(5.4.7)
In (5.4.6), utilizing the definition of the principal value, we derive taking into account (5.4.7) and then we integrate by parts. It follows a
F(x, n)
ay
_f dq -
e F'
1
yo! d
_ 'v+ SF do
- Jy-
an
'
(5.4.8)
where, from now on,
y- = y-(x), y+ = y+(x) In this way equation (5.4.6) becomes + OF dr)
1
Jv-
8q
- h. (x, y)
(5.4.9)
This equation can be also obtained starting from Homenteovsch's equation (5.1.41) which, in case that one imposes the condition (5.1.44) on the leading edge, becomes equation (5.1.43). Then we can see that from (5.4.5) it follows
8F_
8f
(5.4.10)
The equation (5.4.8) is a thin profiles-type equation (C.1.1) and it has one of the solutions (C.1.9), (C.1.10), (C.1.11) or (C.1.14). The solution of the equation (5.4.8) must satisfy the condition
J
+OFdq=0 y_ a!
(5.4.11)
arising from (5.4.7). The only solution satisfying this solution is (C.1.11)
with C = 0. Hence, 8F(x,TI)
-2
1
(t-y-)(y+-t)h=(x,t)dt. t-77 (5.4.12)
192
THE LIFTING SURFACE THEORY
Integrating this solution on the interval (y_, y) and taking into account (5.4.7) and (B.6.11), we get F(x, y)
_
'
dq
2ly
(n-y-)(y+-q)
-
+
(t - V -)(y+ -' t)
t
y-
(x, t)dt .
-q
(5.4.13)
As from (5.4.5) it results f (x, y) = F, (x, y), we deduce f (x, y) =
=2
8
8x
ydq
ru+
(t -
(qy-)(y+-q) y-
ly-
t)
t-q
(x, t)dt . (5.4.14)
Employing (B.6.11) ones easily check that this solution satisfies the vanishing condition on the leading edge
f(x,y-)=f(x,y+)=0. 5.4.2
(5.4.15)
The Case h = h(x)
In case that
h does not depend on the variable
y, taking into
account (B.5.6) and performing the change of variable q = y_ cos20 + y+ sin20, we get
: Jv-
0 < 0 < 7r/2,
(5.4.16)
' V+
dt7
At - Y-) (y+ - t)dt = t-q n - y-)(y+ - q) Iv_7r
Y+-Y- r 2
-a J
y+
v-
dq
On - y-)(y+ - r!) ydq=sV(y-y-)(y+- y)
Hence,
f(x, y) = 2
[h'/i_
y)]
.
(5.4.17)
193
THE WINO OF LOW ASPECT RATdO
Utilizing (5.1.54)-(5.1.56) and Green's formula we deduce: CL
- A If
19
[W(x)Vv - v-}(v+ - Y1
f (y-a (b-y)dy=-2Ah'(1)(b-a)2,
A
-S
= - A ,,D ybx
= - Ah'(1)1
cv
A
v=
Y
[h!(x)-,/(y -
v-)(v+ - v)] dxdy =
(v - a)(b - y)dy = -
bWrh'(l)(b
- a)z,
I/I; [zWv'?j- v-)(v+ - v)1 dx dy_ A
If h'(x) vir(v -y-)(Yu)dxdy = -
_ -CL -
1
0
[v+(z) - y_(x)12 h'(x)dx, (5.4.18)
the reference chord ao bung 1. For example, fnr the rectangular flat plate of incidence -e with the span 2b one obtains CL = wk,
c, = -
c= = 0,
!
,
(5.4.19)
and for the triangular flat plate of incidence -£, we have,
CL=xe(b - a), because y+ = bx,
c, = (b2 - a')
r
,
cy = - 3 xc(b - a),
(5.4.20)
y- sax.
5.4.3 The General Case We shall write (5.4.14) as follows
f(x, y) =
2b x8s
r_
(t - -y-)(y+ - t)h.(x, t)I(y, t)dt,
(5.4.21)
THE LIFTING SURFACE THEORY
194
where
Y
d-q
I(y,t) =
(5.4.22)
(r1-y-)(y+-rl) t - n with y- < y < y+, y- < t < y+. This integral may be calculated l
fv-
explicitly.
For y < t the integral is not singular.
For
t < y the
integral is singular but noticing that we have 1(y+, t) = 0 (it results from (B.5.8)) we get IY+ 1
I(y,t)
d'l
y+-rl) t-17
(5.4.23)
which also is not a singular integral. Since
A
(n-a)(b-n) t-11 (5.4.24)
(t-a)(b-rt)+ (b-t)(q -a)
1
in
(t - a(b-it)- -v(((r1-a)
(t - a)(b - t)
we deduce the fundamental formula
f(x,y) = =
2 8 f+h
(t-y-)(y+-y)+ (y+-t)(y-y-) dt.
(x,t)
a 8x v-
(5.4.25)
For determining the lift and moment coefficients we have to calculate the integral
(t
V+
G(a, t) =
- y-)(y+ - y) +
(y+ - t)(y - y-) dy.
J(t-y-)(y+-y)- V(-y+---4(y -y-)
(5.4.26)
Performing the changes of variables
t=y++y-+y+-y-moo, y=y++y-+y+-y-cos9, 2
2
2
2
(5.4.27)
we deduce
Gxt
- y+ 2 y- fo X in
sm2 sm
B+a 2
sin 8 d9,
(5.4.28)
195
THE WINC OF LOW ASPECT RATIO
the integral having an integrable singularity for 8 = a. The integrand from (5.4.28) is the kernel from the equation (6.2.15). Using for 0 91 a the expansion (6.2.17), we get: G(x, t) = w y+
y- sin o =
2
(y+
- t)(t - y-) .
(5.4.29)
It follows
(t - a(b-y)+ (b-t)(y-a)
fb
G(I, t)
=J
In
Ja
IWa)(b-y)-'(b-t)(y-a)
(5.4.30)
=x (b - t(t-a). Similarly one deduces b
(t - a) (b - y) +
JQ y
(b - t) (y - a)
dy=
IV'(t-a)(b-y)-i(b-t)(y-a)
(5.4.31)
=att+b2a) (b-t)(t-a). Utilizing Green's formula and the expression (5.4.25) for f (z, y) taking into account (5.4.30), (5.4.31), we get:
A
CL
-
-4
,
lb 41
h`(1, t)G(1, t)d t = rb
a
_
b
cs = - AJa t (b - t)(t - a)h=(1, t)d t + !-+-b ct, Cy = -CL -
r1
4
rA
Ju
4
r2
- -CL - A
dx
y+
y_
h.(x, t)G(x, t)d t =
ry+
dT o
f
(5.4.32)
hs(z, t)
(Y+ - Wt - y-)d t .
When h(x, t) does not depend on t we find again the formulas (5.4.18).
196
THE LIFTING SURFACE THEORY
This problem, for wings symmetric with respect to the Ox-axis, was studied in [5.171. It was also included in [1.1], [1.2]. The general problem for the arbitrary wing as it was presented herein, was solved in 15.91.
Chapter 6 The Lifting Line Theory
6.1 6.1.1
Prandtl's Theory The Lifting Line Hypotheses. The Velocity Field
Prandtl's theory is the first mathematical model for the three - dimensional wing (the finite span airfoil). It was elaborated in 1918 16.211 and it remained until the years '40 the only theory for this wing. The german
scientist, gifted with an extraordinary engineering intuition, guessed very well the simplifications which may be performed. Prandtl's method consists in replacing the wing with a distribution of vortices on its plane
- form (the domain D from 5.1). Since the experience indicates that downstream the wing the flow is not potential, Prandtl introduced a vortical distribution defined on S, the trace of the plane-form D in the uniform stream (figure 6.1.1), the velocity field in the fluid being determined by the two distributions. The vortices on D are called tied vortices and the vortices on S are called fee vortices. This idea continued to dominate the aerodynamics, the models concerning the subsonic, supersonic and transonic, steady or oscillatory flows, elaborated in the years '50, '60, being conceived on the basis of this method. In 1975 D. Homentcovschi, utilizing the theory of distributions proved that the hypothesis of the existence of free vortices is not necessary because it follows from equations. L. Dragon [5.71 obtained
the same result utilizing the method of the fundamental solutions. In this subsection, we deduce the lifting line theory from the lifting surface theory, as we proceeded in [5.7], utilizing the following three hypotheses (the hypotheses of Prandtl's theory): 10 One neglects the thickness of the wing, therefore in (5.1.2) one considers hl = 0. From (5.1.27) it results fl = 0, such that the representations (5.1.8), (5.1.11) and (5.1.12) give
P(x,y,z) = -4 7r-
IL f(CTT)1 (-) dcdi 19Z
(6.1.1)
THE LIFTING LINE THEORY
198
u(x,y,z) _ -p(x,y,z) v(x,y,z)
_-
+
jo
z2(1+Rl)]dfdi7
(6.1.3)
)Io
qJ
w(x, y, z)
(6.1.2)
fD f (C, 17)
8x 1)dt d t7+
JJD0Y
(6.1.4) -+ z2
(1 + 11 )]d t d n;
2° One considers that the unknown is the circulation C. along the contour c, resulting from the intersection of the wing with an arbitrary
plane n parallel to the xOz plane at the distance y(-b < y < b) (fig. 6.1.1). This will be, obviously, a function of y
Fig. 6.1.1.
Pudx,
C(y)=
because on this contour d y = 0 and wdz = O(E2) (it results from (2.1.17) and (2.1.21) ). Taking into account (6.1.2) and (5.1.20), we obtain
r C(y) =
Jx
u(x, y, -0)d x + / + u(x, y, +0)d x x
We have also
f X
f(x,
y)d x .
(u)
(6. 1 .5)
x+ (y)
C(n) = -
x_ (y)
f (f, n)d t.
(6.1.6)
PRANDTL'S THEORY
199
From (5.1.1) or (5.1.30) it results
C(±b) = 0;
(6.1.7)
30 The domain D, i.e. the projection of the wing on the xOy plane, is replaced by the segment [-b, +bJ (fig. 6.7.1); for this reason we call this theory the lifting line theory. when For studying the behaviour of the integrals (6.1.1)-(6.1.4) x_(n) -+ 0 .- x+(il), we notice that in the vicinity of this segment, for a given n , the function f (e, n) keeps a constant sign, such that we may apply the mean formula. For a function h(z, y, z, n), continuous in f, when x- (q) -+ 04-- x+(n), we have therefore f ( n)k(x, y, z,
limJ1
r+b
hm
ti)d d r! _
r+(n)
J-b [ Js_ty)
-lim
,
f (t, n)k(x, y, z, t, r1)d
d r! +b
-b
k(x, y, z, (', n)C(n)d n = - fb k(-T, y, z, 0, n)C(n)d n , (6.1.8)
where £ E (x_(rl), x+(n)). Applying this formula in (6.1.1)-(6.1.4) and taking into account (6.1.7), we obtain
2
P (x,
y, z) = -
4 rb C(n)
d n = -u(x, y, z) ,
f+b
v(x, y, z) = 4
.! b
_- a 4n
w(x,y,z) =-Q2 41r
ly2+z2
J b C('l)
f
1
)]dii
C(17)ay [ o + z2 (1 +
= rT
o
(6.1.9)
C'(n)yo+z2 ( 1 + C(n)
rb
-4 J b
Ro
}n, d
drl-
b
0,07) y02
YO
Z2
(1 + X
d
200
THE LIFTING LINE THEORY
where we denoted RD =
x2 +#(y2 + z2)
(6.1.10);
Fbr Q = 1 we obtain Prandtl's representation ((1.21], p. 708).
6.1.2 Prandtl's Equation In the sequel we shall deduce the equation for C(y). This will obviously result from the lifting surface equation by virtue of the above hypotheses. We shall employ the equation (5.1.33). Taking (6.1.6) and (D.3.6) into account it results
8
f( , n) d
8y JD y-n 1
fd n= dy -d- f' +b
C(q)
-b n-y
-
d
rJ
C(q) d n.
O
-b (n - y)2
Utilizing (D.3.7) and (6.1.7), we also deduce:
.
&
c(_)
= l1+b C'(n)
J
b
'n-yd
(6.1.12)
In the second term from (5.1.33) we take into account that when
x_(n) - 0 4- z+(n), on the greatest part of the domain D, we have so << 14, before E which intervenes in the definition of the principal value of the integral with respect to n becomes zero, i.e. before yo becomes zero. In the principal value we shall perform therefore the approximation R = fl I. An exact evaluation of this approximation is, made by D. Homentoovschi in [6.9) as follows
jjf(r)
ryxTo +
dd
XDYO
Taking into account that sign yo = 2H(yo) -1,
H'(yo) = 6(y - q),
H representing Heaviside's function and 6 Dirac's distribution we
201
PRANDTL'S THEORY
have: Z_
JJ
20
f (f, n) xovo +b
I J-b
JJ
d {d ~ Q f (txon) t
LJ
d C,
f (on) s yod fd n =
' f=+ (v) f (t'17) _ d
5(y - n)d n= 2Q
xo
(y)
(6.1.13)
Hence the equation (5.1.33) becomes: 1
+(v)
,rte C'(n) d n +
sr f b n - y
f (c Y) d
'r s_(v)
xo
= 2h' (a, y)
(6.1.14)
x]-1/2
(6.1.15)
Multiplying this equation by [x - x-(y)]11.2[x+(y)
-
and integrating it with respect to x on the interval obtain from the first formula (B.5.4): AC(y) =
(x-
a(2) 'f+b C'(n)dn+1(y),
J bn-y
(y), x+(y)), we
(6.1.16)
where we denoted
a(y) =
J(y) _ -2
W
x+ (y) - x- (y)
(6.1.17)
2
IT
x(6.1.18)
a(y) representing a half of the chord of the profile at the distance y. The equation (6.1.16) is the well known Prandtt's equation (the lifting line equation). This equation, together with the conditions (6.1.7), has to determine the unknown C(y). It is an integro-diferential singular equation, with a Cauchy-type singularity. Utilizing (6.1.12), the equation
for C(y) may be written QC(y) =
a 2y)
t +b
r
b
(n
+ (ny)2 d n
9(y) .
(6.1.19)
In this form, the equation is not integro-differential any longer, it is only integral, but with a stronger singularity. The mark "s" is for the Finite Part. As we have already shown in [6.5] [6.6), this form is more adequate for the numerical integrations (see also 6.4.2, 6.4.3).
202
THE LIFTING LINE THEORY
z
A
Fig. 6.1.2.
The significance of the function j (6.1.18) is given in [1.2J. In the case of the flat plates having the angle of attack c (fig. 6.1.2) we have
hx = -e whence (6.1.20)
j(y) = 2irea(y).
6.1.3
The Aerodynamic Action
Taking into account (6.1.6), from (5.1.54) and (5.1.56) we deduce 2 CL
2
+b
C(y)d y, c
+b
Aao 1-b
yC(b)d y, cv = 0.
(6.1.21)
The expression of c, is natural because for the wing reduced to the segment [-b, +b] the fluid cannot create a moment which should rotate this axis. By virtue of the first hypothesis (h1 = 0), in the framework of the lifting surface theory, the quantities Rs and M, which have the
order of magnitude 0(e2) are reduced to those given in (5.1.56) and (5.1.59). Utilizing (6.1.6) and (6.1.7), we obtain:
R. = -p.U.Lo
C(y)h=(0, y)d y, b
(6.1.22)
+b
M: = P,,. U,2,. L. f
yC(y)hi(0, y)d y b
But, from the boundary condition
w(x,y,0) = h,(x,y)
6.1.23)
and from (6.1.9) it results h=(0, y) = w(0, y, 0) _ -
1
lim (
41r c-.o \
f
V-s b
+
b y+c
)
C'M d Yo
rl ,
203
PRANDTL'S THEORY
because, with the change of variable n - y = u, we have y+E
Eiti y-E
C(rl)' 11o
+-Z 2 d r! _ -C'(y) lim E-0
f
+6
z = 0.
1 y+bCl(I1)d b
tl
y
rJ ,
( 6.1.24)
we deduce 2 CU
f
A J-b
C(y)w(y)d y, (6.1.25)
2
MS cZ
A
(1/2)Poo
`k
2 Alai
Aa_
Jb yC(y)w(y)d y,
representing the area of the domain D and ao, the length of
the dimensionless medium chord along the direction of the unperturbed stream. In fact, for w we may also utilize the expression
w(y) = QC(y) - ?(y)
(6.1.26)
2wa(y)
which results from (6.1.18) and (6.1.26).
6.1.4
The Elliptical Flat Plate
Until the appearance of the papers of Magnaradze [6.16] and Vekua [6.28] in the years 1942, 1945 it was available only one exact solution of Prandtl's equation corresponding to the elliptical flat plate wing. Usu-
ally this solution is obtained as an answer to the following minimum problem: "To determine among the wings having the same lift, the wing corresponding to the minimum drag" (see, for example, (1.201). Sometimes one utilizes Glauert's approximate method (see 6.2.4). In the sequel we shall present a simple method which does not need any special considerations on Prandtl's equation. Let us consider a flat plate with the angle of attack E, whose projection on the x10y1 plane is an ellipse having the semi-axes Lo and bLo (figure 6.1.3). In dimensionless coordinates, the equation of the ellipse is x2+ +y2/b2 = 1. For the edges and the chord it results y2
xf = f
1 -
2 52
,
a(y) =
1 -
2'
(6.1.27)
204
THE LIFTING LINE THEORY
YI
bLo
L=am
Fig. 6.1.3.
For a flat plate j(y) has the form (6.1.20) hence it is proportional to a(y). From Prandtl's equation it results that C(y) is also proportional to a(y). We shall look therefore for solutions having the form:
C(y) = k 1-
a Eb2
,
(6.1.28)
k being a constant which will be determined by imposing (6.1.23) to verify (6.1.27). Using the change of variables q = boos 0, y = b cos o, and Glauert's formulas (B.6.6), it results: di7
11-y such that
k
(2TE
A + 7r/2b)
_ir,
(6.1.29)
(6.1.30
Since the area of the ellipse is w b, from the formulas (6.1.23) and (6.1.27) we obtain s cL = k, CD = , cj = cs = 0. (6.1.31) 46
Obviously, cD = 0(0). For b - oo one obtains the infinite span flat plate. From (6.1.23) and (6.1.27) it results: CL =
21r8
(6.1.32)
205
THE INTEGRATION OF PRANDTL'S EQUATION
6.2 The Theory of Integration of Prandtl's Equation. The
Reduction to Fredholm-Type Integral Equations 6.2.1
The Equation of Trefftz and Schmidt
The general method of solving the integro-differential equations con-
sists in reducing them to Fredholm-type integral equations. As it is well known, for the last ones a general theory is available (existence and
uniqueness theorems, exact and approximate methods for solving the equation). The first investigation of Prandtl's equation was performed by Trefftz in 1921. He reduced the problem of solving Prandtl's equation to the problem of determination of a harmonic function in the superior half-plane with mixed conditions on the boundary. We shall prove in the sequel that such a problem may be reduced to a Fredholm-type equation. To this aim we shall consider the harmonic function U(y, z) in the superior half-plane z > 0 from the yOz plane, with mixed boundary conditions in the Z = y + iz complex plane (fig. 6.2.1). We shall also consider the complex function
F(Z) = U(y, z) + iV(y, z) =
1
2m
: ZdR. Jb+1 COO
(6.2.1)
z (Z)
-b
+b
y
Fig. 6.2.1.
Obviously this is an holomorphic function in the (Z) plane with the cut (-b, +b) and it vanishes to infinity. U(y, z) is therefore a harmonic function in the half-plane z > 0. It results obviously
U(y, +0) = 0, y E (-oo, -b) U (b, oo).
(6.2.2)
The limit values on the segment (-b, +b) are obtained by means of Plemelj's formulas. We deduce
2U(y, +0) = C(y), y E (-b, +b).
(6.2.3).
206
THE LIFTINC LINE THEORY
Taking the conditions (6.1.7) into account, we get d
-dn= f
C(t1)
ZJ
bbtj
b
=-f C(rl)'3;
rl
b
C(rl)aZ
Z)dr)_ Cn
1 Z) d+l -
f
b 71- Zdrl
Deriving we deduce from (6.2.1):
F'(Z) =
I-i
8 = 2m J-b W(Zd q
(6.2.4)
and with Plemelj's formulas ' +b
az (y, +0) = d (y, +0) = 2a f
d,
(6.2.5)
n representing the inward pointing normal of the superior half-plane on
the segment (-b, +b) of the real axis. Taking (6.2.3) and (6.2.5) into account, Prandtl's equation is transformed into the following condition on the segment (-b, +b): dU
21U(y, +o) A(y)
- J(y),
(6.2.6)
A(y) = ra(y), A(y)J(y) =1(y) ,
(6.2.7)
in
(y, +0) =
where, from now on, we denote
So, Prandtl's equation was replaced by the following mixed boundary value problem: "to determine the harmonic function U(y, z) in the z > 0 half-plane, vanishing at infinity and satisfying the boundary conditions (6.2.2) and (6.2.6)". Then, the function C(y) will result from (6.2.3). The mixed problem is reduced to a Fredholm-type integral equation. Proceeding like in [1.211, p. 713, we notice that because of the condition (6.2.2), the function F(Z) may be extended by symmetry in the lower half-plane z < 0. In this way, on the lower margin of the cut (-b, +b1 we shall have the condition dU
d n (y, -0) =
2QU(y, -0) + Ay), A(y)
(6.2.8)
So, we reduced the above mixed problem to the problem of determination of the harmonic function U(y, z), in the yOz plane, with the cut
THE INTEGRATION OF PRANDTL'S EQUATION
207
[-b, +b) and the conditions (6.2.6) and (6.2.8) on the two margins of
the cut. It is known (see for example, 11.111 [1.201 [1.31J) that the Joukovsky-
type conformal mapping Z - W: Z = I
(W + W
(6.2.9)
maps the exterior of the cut [-b, +b] from the (Z) plane onto the exterior of the circle of radius b and the center in origin from the (W) plane (fig. 6.2.2), the superior margin of the cut being mapped on the
superior half-circle from the superior half-plane. The points fb are double and singular. One obtains the correspondence of the boundaries
putting W = be''. We have
y=boost, a=0.
(6.2.10)
Fig. 6.2.2.
For 0 < a < r, (6.2.10) gives the correspondence between the halfcircle r+ and the superior margin of the cut, and for -W < a < 0, the correspondence between r- and the inferior margin (fig. 6.2.2). Since from the extension by symmetry it results U(y, +0) = -U(y, -0), we deduce that U(a) is an odd function on F. With the same application (6.2.10), the functions A(y) and j(y) become even functions. We denote them by A(a) , respectively j(o). Now we shall see how the boundary conditions (6.2.6) and (6.2.8) are transformed. To this aim we remind to the reader that, after performing a conformal mapping,
208
THE LIFTING LINE THEORY
the ratio of the lengths is given by the modulus of the derivative. More
precisely, let W = f (Z) be a conformal mapping and let M(Z) and N(Z+AZ) be two neighboring points and M1(W) and N1(W+AW) their images. Obviously we have AMN' lim I
1
= lim I1Z 1 = lim
I
AZ = If'(Z)1
Hence, returning to our problem and denoting by N the outward normal to 1', we shall have
dU_dU dN_dUIdW do
dN (a) do
TN- d
Taking (6.2.10) into account, the boundary conditions (6.2.6) and
(6.2.8) on the two half - circles r+ and r_ give dU (a) = 2/3I sin a)
dN
A(a)
U(a) - J(a) sin a
(6.2.12)
Denoting W = it + i v, the harmonic function U(y, z) in the yOz plane becomes the harmonic function U(u, v) in the exterior of the circle r. This one vanishes at infinity and has the normal derivative (6.2.12) known on 1'. It is a Neumann problem. Its solution is given by Dini's formula (see for example (1.20] p. 31). We obtain
U(u,v)=n J_" U(a)Inlbei°-Wlda+ko dN
(6.2.13)
being an unknown constant. Considering that W tends to a point be' ° from C, one obtains U(s) =
b
r+ir J JJJ
aN (o )1n I2 sin s
2 a I da + kO .
(6.2.14)
:
Since U(a) is an odd function it results dN (a)
dN
(-a) ,
and integrating only on the interval (0, 7r), we deduce U(s)
b f0" ddN (a)S(s, a)d a,
7r
(6.2.15)
THE IN'I'ECRATION OF PRANDTL'S EQUATION
209
where we denoted S(s, o) = In
(6.2.16) am
2
We have (see, for example, 11.16]): 00
S(s, o) _ -2 F sin ks sin ko km1
(6.2.17)
k
the series being absolutely and uniformly convergent (s 0 o). In (6.2.15) we did not encounter ke, because we have U(s) _
_ -U(-s) whence U(0) = 0. Taking into account the relation (6.2.12) in which 2U(o) is replaced by C(a) according to the condition (6.2.3), one obtains the following Fredholin-type integral equation C(S) = A J
C(°)
si) S(s, a)d or + Jo(a)
,
(6.2.18)
where A=
2bQ
z
Jo(s)
,
2b
x
J(o)S(s, o') sin o d o .
(6.2.19)
To
Hence we reduced Prandtl's integro-differential equation to the Fredhoimtype equation (6.2.18). The kernel of this equation has an integrable singularity. Equivalent integral equations have been given by Betz and Gebelein in 1936 and Trefftz in 1938.
6.2.2
Existence and Uniqueness Theorems
For proving the existence and uniqueness of the solution of Prandtl's equation , we shall use the first theorem of Fredholm. This may be enunciated as follows: the equation b i
P(s) = A
K(s,)p(o)ds + f(s),
(6.2.20)
fa has an unique solution for a given value of A and for every fee term f if and only if the corresponding homogeneous equation admits only the trivial solution V(s) = 0. Hence, we must show that the equation
210
THE LIFTING LINE THEORY
(6.2.18) which is homogeneous (Jo = 0) has only the trivial solution. But the homogeneous equation corresponds to the boundary problem (6.2.12) which is homogeneous (J = 0). Applying Green's formula
/ JD
U)2du dv = -JOD Ud S,
(6.2.21)
where D is an annulus, exterior to the circle r, bounded by an concentric circle of radius R > b and observing that for R -- oo the last term vanishes (see, for example, §6.1 from
1 fx A
we deduce
UdNda < 0.
Utilizing the homogeneous condition (6.2.12), we obtain: W IAsin
0.
(6.2.22)
This inequality implies U = 0, because, as it results from the definition (6.1.17), we have A > 0. Hence, Prandtl's equation has an unique solution. This result is very important, because, as we have already seen in 6.1.4 and as we shall see in the sequel, we manage, on various ways, to determine a solution of this equations. The above result ensures that if we find a solution, this is the unique solution of the equation.
6.2.3
Foundation of Glauert's Method
The integral equation (6.2.20) is a Fredholm-type equation of the second kind. This equation has a symmetric kernel if
K(s, a) = K(a, a).
(6.2.23)
The equation (6.2.18) has not a symmetric kernel, but it can be symmetrized. Indeed, multiplying the equation with
(on the inte-
A) gration interval the quantity under the radical is positive) and, taking the function as an unknown c(8) =
sins C(s) A(s)
(6.2.24)
211
THE INTEGRATION OF PRANDTL'S EQUATION
one obtains the following equation:
c(s) _ -2a
Ja
c(a)
VsTn,; i "in a A
00
sink sin ka
a ()k_i
d a + F;i(S) A(s) (6.2.25)
00
K=-2E k i1
sin s smo sin ressin rca k A(s) A(a)
is obviously symmetric. The kernel is even degenerate, but not of finite rank. As it is known (see, for example, [1.22], vol.3, p.193), the integral equations with degenerate kernel may be reduced to infinite algebraic systems and the equations with degenerate kernel of finite rank may be reduced to linear algebraic systems with a finite number of equations. We are not in this situation, and according to (6.2.25)we shall take only the property of symmetry of the kernel into account. According to the theory of Hilbert and Schmidt (see, for example, (1.22] v. 3, p. 243) the solution of the integral equation may be expanded, with respect to the eigenfunctions of the kernel, into absolutely and uniformly convergent series. Hence the solution of the equation (6.2.25) has the form: 00
C(a) =
A(a E At, sin ka. )k-1
Taking (6.2.24) into account, it results: 00
C(a) _ E Ak sin ka.
(6.2.26)
k=1
The (constant) coefficients Ak will be determined replacing (6.2.26) in the equation (6.2.18), or easier, performing this replacement in Prandtl' equation (6.1.18), which, with the change of variables y = b cos s,
(6.2.27)
1 ) = b cos a
and with the notation C(s) for the function C(y) composed with (6.2.27)1 etc., becomes 2b/3C(s + a(s)
C'(a)d a=
casa-cuss
2itbaOff( s s
)
(
6.2.28 )
Before discussing about how to determine the coefficients A, from (6.2.26) and (6.2.27), we must notice that the form (6.2.26) of the so-
lution C(a) may result directly from (6.2.18), without utilizing the
212
THE LIFTING LINE THEORY
theory of Hilbert and Schmidt. Indeed, taking (6.2.17) into account, the equation (6.2.18) becomes: _'inks
C(s) = -2a
fo"
k=1
A(( )) in k sin a d a+
V +4rb
sin ks
Air)
sin ko sin od a .
I0 The integrals are constants and the solution will have the form (6.2.26).
6.2.4
Glauert'e Approximation
We shall return now to the problem of determination of the coefficients Ai from (6.2.26). Replacing C from (6.2.26) in (6.2.28) and using Glauert's formula (B.6.6) (herein is the origin of this formula), we deduce: E Ak[2bfl sins + k7ra(s)) sin ks = 21rba(s) j (s) sins .
(6.2.29)
k=1
Glauert's approximation consists in keeping the first n terms from the expansion (6.2.26) and then imposing (6.2.29) to be satisfied for n distinct values of the variable s. The coefficients Ak are the solution of an linear algebraic system, but we cannot evaluate the error of the approximation. Many other approximations have been given in the literature (see Lotz in [1.24), Carafoli in [1.5)).
6.2.5
The Minimal Drag Airfoil
The foundation of Glauert's method,which consists in establishing the formula (6.2.26) gives the possibility to give an answer to the following problem of practical interest: to determine among the wings with the same lift, that one which has the minimum drag. In view of this determination we shall calculate, utilizing the formulas (6.1.21), (6.1.25) and (6.2.26), the lift and drag coefficients cL and CD. For determining the lift and the drag, we multiply these coefficients by the same factor 1 2 p00UUA1. Since
2! sin ka sin lad v = irdkl ,
k,1=1,2,...
213
THE INTEGRATION OF PRANDTL'S EQUATION
we deduce +b
f Jb
ct, = A
C(y)d y = A f C(a) sin ado, = JO
'At v.
(6.2.30)
Utilizing Glauert's formula (B.6.6), we obtain:
()
C'(s)s a
1
1
4ab To Cos a - oos or
such that: CD
/
2
C(V)w(y)d, y = -
b
A °°
1
2A
1 (ksmka) ksI
f
4b
sin ka kAi sin a
w(a)C(a) sin ad a =
o0
Alsinio do =
(6.2.31)
!:1
oc
kAj. k=t
The formulas (6.2.30) and (6.2.31) indicate that among all the wings with the same lift (with the same A1), the minimum drag corresponds
to the wings for which A2 = A3 = ... = 0. The solution of Prandtl's equation for these wings is
C(o) =A1sin or =C(y)=At V, where Al = C(O) may be determined obviously from the equation (6.1.26). We have _C(_)
A(N)
5
= 2w(y) + J(y) _ - 1 At + J(y).
(6.2.33)
In the case of the flat plate, j has the form (6.1.20). It results J = 2e whence we deduce that the member from the left hand side of (6.2.33) is constant. Hence,
a(y) = ao 1 -
,
(6.2.34)
the constant ao being determined by the relation
0
+
2b) Al = 2E,
(6.2.35)
214
THE LIFTING LINE THEORY
if one gives Al. The same relation determines Al if one gives ao.
For example, when Al = k like in (6.1.28), it results ao = 1, like in (6.1.27) and vice versa. The expression (6.2.33) shows that the wings which have the above property are the elliptical flat plates.
6.3
The Symmetrical Wing. Vekua's Equation. A Larger Class of Exact Solutions
6.3.1
Symmetry Properties
Very often in aerodynamics we encounter the case when the wing is symmetric with respect to the xOz plane. In this situation we have
x*(y) = xt (-y) ,
-b < y S +b
h(x, y) = h(x, -y) ,
(6.3.1)
From (6.1.19) and (6.1.20) it results
a(y) = a(-y),
j(y) = j(-y).
(6.3.2)
Let us prove that we also have
C(y) = C(-y) .
(6.3.3)
Indeed, changing in Prandtl's equation (6.1.18) y by -y and taking (6.3.2) into account, it results
AC(-y) =
a2 y)
1c (q) d q +.7(y) . Cc(q)
n
(6.3.4)
y
Putting in the integral n = -u and observing that
C(q)d17 = dC = C'(u)du, we deduce r -16 C'(rl)d
f b 1+31
_
'/'_b
C(u)du =,+b Cl(,i)d+l
J.fb -u+y
b
7I-y
(6.3.5)
Introducing this relation in (6.3.4) and comparing with (6.1.18), we get (6.3.3).
THE SYMMETIUC'AL WING. VEKt'A'S EQUATION
215
The Integral Equation
6.3.2
We shall present in the sequel the simplest method for obtaining the equation (6.2.18). The demonstration is inspired from [A.27), where, on his turn, it was taken from Magnaradze (6.16] and Vekua (6.28). With the notations (6.2.7) Prandtl's equation is I 'r+b
C"(n) d
27r ,!-b rl - y
n = 0C(y) - J(y) .
(6.3.6)
A(y)
For the existence of the principal value we have to assume that C'(y) satisfies Holder's condition on the segment (-b, +b). We shall invert this equation assuming that the right hand member is known. As it is known from (C.1.1) the solution C'(y) depends on the behaviour imposed in the points ±b. We know that we cannot obtain a bounded solution in the two points without imposing a restriction to the right hand member. In the same time, because of the symmetry of the wing,
we cannot consider C bounded only in an extremity. Hence C' is unbounded in the two extremities, i.e. the solution has the form (C'.1.11). Further, for inverting the equation (6.3.6), A(y) and J(y) have to satisfy Holder's condition on [-b, +b]. If A(y) and hs(x, y) (with respect to the y variable) have this property we deduce the same thing for J(y) . Moreover, a(y) must not vanish on (-b,+b). If all these conditions are satisfied, then, using the formula (C.1.11), we obtain
C'([/) _
-2
'r+b
1
b2y2
b
bz -
I' [#'(") - J(n)] d n+ n-y A(q) (6.3.7)
B representing a constant which has to be determined. It is zero because from (6.3.3) we have C'(y) = -C'(-y), whence C'(0) = 0. Imposing this in (6.3.7) and observing that the integrand is an odd function, it results the assertion. Utilizing now the identity
P) --r12 d dy
In
-y2- 62-n2 i(y-n)+ i(y-n)+ b2-y2+ P-
(6.3.8)
216
THE LIFTING LINE THEORY
and integrating (6.3.7) on the interval (-b, y), from (6.3.3) one obtains:
C(y) _
+b
2 W
1
110A(+l)
b
(6.3.9)
i(y-tl)+ &2y2i(y-q)+ b -y + /bbl-
-J(17)] In
because the modulus is equal to the unity for y = -b. Performing the change of variable y = b cos s ,
tI = b cos a
(6.3.10)
and taking into account that in
-y2-
(y-tl)+
(y-17)+ b2-y2+ b2-q2
is - e is = In l e-i s _ eio I
e
- S($ a)
we obtain obviously the equation (6.2.18).
Using the notation A(tr-a) we have A(bcoe(7r-a)) = A(-boos a) _ = A(-y). Hence, taking (6.3.2) and (6.3.3) into account, it results A(tr - a) = A(a),
J(tr - a) _ i(a),
C(tr - a) = C(a)
(6.3.11)
whence:
sin ad a =
I"/2 [#A(a) - J(a)J In
s+a --/z
pc(o') - J(a)J In
o
cos cos
2 s - a sin ad a . 2
But, .
sin In
sin
$-a 2 s+a 2
cos
s+a
2 s-a cos 2
= In
sins - sin or sin s+sin or
THE SYMMETRICAL WING. VEKUA'S EQUATION
217
In this way, the equation (6.2.18) for the symmetric wing becomes 26
C(s) _
J"/2 [(;) (6.3.12)
- sing -J(a) In sins sinada, sins + sin a J
with s in the interval (0, n/2).
Vekua's Equation
6.3.3
In 1945, I.N.Vekua [6.28] gave for the symmetric profile whose chord
has the form bz
a(y) =
2
-y
with p(y) = p(-y) > 0,
,
P(y)
(6.3.13)
(where p(y) is an analytic function on [-b, +b]), a Fredholm-type integral equation which has the great advantage that it may be integrated exactly for a large class of profiles. Vekua's method was extended immediately by Magnaradze [6.16] to wings for which the function p(y) is not necessarily analytic on the interval f-b,+b]. Since we had not the occasion to read this papers, we present herein a a synthesis due to Muschelisvili [A.27]. To this aim, we write the equation (6.3.7), where we considered 13 = 0, as follows 20
A(y) C'(y) +
+b
C(11 f-b ' '
1
(6.3.14)
= A(y)J1(y) -
tb
a(y) b2 - y2
R(y,n)C(rl)d>j b
where 2(3
R(y, rl) =
Ji (y) =
1
(i-r a(n)
7r 17 - y 2
-
_
a(R-7-ill
y)
(6.3.15)
Ifb +b
62 - y2
J(q)d i1.
(6.3.16)
Ji (y) _ -J1(-y) .
(6.3.17)
rl - y
Obviously we have:
R(y, ) _ -R(-y, -y)
THE LIFTING LINE THEORY
218
Further we shall assume the continuity of the first order derivative of the function
P(y) =
(6.3.18)
a(y)
In this case, R(y, i) will be a continuous function. Since according to (6.1.7) we have: C(q
ay i-bb
r1
11
=
dq =
o d y \Jb ` + Jy+a, v
11
tab
do _
J-b
17
-
dn,
from (6.3.14) it results
dy [A(y)C'(y)] +
2Q ' +b
J-b rl (y d q
B(y),
(6.3.19)
where
B(y) =
dy [A()Ji() -
lr+b
a(y)
J
R(y, n)C(r1)d n I
.
(6.3.20)
Obviously,
B(y) = B(-y)
(6.3.21)
Eliminating the integral from (6.3.19) by means of Prandtl's equation, we obtain the following differential equation: A(y)
b [A(y)C'(y)] + 4/32C(y) = A(y) [B(y) + 4i3J(y)I .
(6.3.22)
Assuming that the right hand member is known, we have in (6.3.22) a differential linear equation for C(y). The homogeneous equation has the linear independent solutions cos s(y), sin s(y), where 20
8(y) =
(6.3.23)
Jo a(rl)
Utilizing Lagrange's method of variation of constants, we deduce that the equation (6.3.22) has the following solution: C(y) = Co cos s(y) + Cl sin s(y)+
y sin [s(y) + 2Q f [B('l) + 4QJ(n)]
- s(n)]d n,
(6.3.24)
THE SYMMETRICAL WING. VEKUA'S EQUATION
219
Co and C, being constants. Obviously, Co = C(0). Calculating C(-y), taking into account that s(y) is an odd function (its derivative is an even function) and B(q) and J(n) are odd functions, and imposing (6.3.3), it results C1 = 0. Introducing B given by (6.3.20) in (6.3.24), performing an integration by parts and observing that the integrated term is zero because
JI(0) = 0,
1-b
it results the following integral equation: +1
C(y)
K(y, ii) =
a
f
+b
(6.3.25)
K(y, q)C(t7)d n= g(y) ,
R(qj, q)
cos [s(y) - s(rh)]d nl ,
(6.3.26)
To
+2 10yJ
g(y)=Cocoss
sins
s
d+ (6.3.27)
+ [iivi)ccs[a(v) - s(n)1 d q.
The equation (6.3.25) for J9 = 1 is the equation given by Vekua and Magnaradze. Unlike the equation of Trefftz (6.2.18), this is regular (the kernel has no singularity). Moreover, in case that the function p(y) given by (6.3.18) is a rational function, more precisely in case that a(y) has the form:
a(y)=a
0
-y21+ply2+...+pny2n
9
1+qly +...+gny2"
(6.3.28)
as we shall see in an example, the equation of Vekua and Magnaradze reduces to an algebraic finite system. This form for a(y) is suitable for approximating every wing of practical interest. We have to mention that, for the wings having the form (6.3.28), the case when qt = 92 =
... = q,, = 0, has been solved by H.Schmidt in 1937, 16.241, and the case when pi = pl = ... = pn = 0 belongs to a larger class, considered by the author of the present book in 1958, (6.41. For this class one obtains the exact solution.
Before passing to applications we notice that if constant, then, taking (B.5.6) into account, we deduce g(y) = Co cos s(y) + 2k1,
J(tl) = k is a (6.3.29)
220
THE LIFTING LINE THEORY
where
I (y) _
{sin[s() - s(rl)) -
cos[s(y) - s(n)J
q
dq. (6.3.30)
6.3.4 The Elliptical Wing
Denoting by a and b the semi-axes of the ellipse from the xOy plane, we deduce s
1-b V
a(y)=aa b2-y2, as=a/b.
Obviously, R = 0 whence K(y, r)) = 0. The equation (6.3.25) gives directly the solution C(y) = g(y), where g is calculated with the formula (6.3.29). In I one performs an integration by parts. Since from (6.3.23) it results 2fi s'(tl) = ira(y)
we deduce
+wao
I=
b2-y2-bcoos(y).
Since from (6.1.20) and (6.2.7) it results J = 2e, using the notation 4wea o
aao+2/9' we deduce
C(y) = Co cos s(y) + k
- kb cos s(y) .
(6.3.31)
For determining the constant Co we shall employ the condition C(b) = 0. Since from (6.3.23) it results
s(y) =
20 wao
arcsin b ,
we deduce Co = kb whence
C(y)=k b2 -y2. For ao = 1/b one obtains exactly the solution (6.1.30).
(6.3.32)
THE SYMMETRICAL WING. VEKUA'S EQUATION
221
The Rectangular Wing
6.3.5
We shall consider now that a(y) has the form a( E/)=ao
b2 -
y
21+
(6 . 3 . 33)
,
the real numbers p and q being chosen in order to ensure only positive values of the fraction one [-b, +b]. In the sequel we shall see that one
imposes pb2 > -1 whence qb2 > -1. From (6.3.15) and (6.3.33) we deduce
R(nt, n) =
c(q + Th)
(1+pip)(1+pni)'
20(g -
C
p)
(6.3.34)
irao
and from (6.3.26) K(y, r1) =
' wo(y) +'P1(y)
(6.3.35)
1+pr7
where acs{s(by} -_aq(m)) 1 +
MY) = c
1
1
d'ri
(6.3.36)
Taking into account that for pb2 > -1 we have d ,q
q 1 + pb2
1
I (1+p) b2-
1+
arct&n
from (6.3.23), for p # 0, we deduce s(y)
2Q f q arcein EI + _ 7rao Lp b
1 +'2 J
p- q p
arctan
y
1+ pb2 l
(6.3.37)
and for p = 0, (I +
s(y) _ L
c) aresin b - Zy
vfb2 --y2 l
.
(6.3.38)
Replacing K(y, q) given by (6.3.35) in the integral equation (6.3.25) and observing that the first term vanishes because the integrand is an odd function, we deduce:
C(y) + tPiny)
r-b
1
C +(p
dt = Cocoss(y) + 2k1(y).
(6.3.39)
THE LIFTING LINE THEORY
222
The integral is a constant Cl which may be determined by multiplying (6.3.39) with (1 + py2)-1 and integrating with respect to y on the
interval (-b,+b). We obtain
J
III[
b
1 + P?1
1 (6.3.40)
bbl+py2dy.
-Col bb +a( dy=2A;
Imposing (6.3.39) and the condition C(b) = 0, we deduce the relation Co cos s(b) - 91(b) CI = -2k1(b).
(6.3.41)
Determining the constants Co and Cl from the system (6.3.40) and (6.3.41), we find the exact solution of Prandtl's equation
C(y) = Cocoss(y) - !C1SOj(y) +2kI(y).
(6.3.42)
Using the inverse method, i.e. considering various values for the con-
stants p and q and calculating the form of the chord, we may find important wings for which the exact solution (6.3.42) is valid. So, in (A.271, considering q = 0 and pb2 = 0, 9, one obtains an almost rectangular wing (the variation of the chord versus the span is very small). Indeed, we have y/b
a/boo
0. 1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.00
1.02
1.03
1.05
1.06
1.06
1,03
0.95
0.75
Importantresults ofthis meth method are givenin [1.331. 6.3.6
Extensions
Modifying Vekua's method, we managed in (6.4) to give the exact solution of Prandtl's equation for wings whose chord satisfies the relation ys
a(y) =
P(y)
,
(6.3.43)
where p(Z) is a holomorphic function in the Z = y + i z complex plane, excepting the vicinity of the point at infinity where one admits
223
NUMERICAL METHODS
the following series expansion: k>O
p(Z)
=n=-oo E PAZ"
(6.3.44)
.
The determination of the solution of Prandtl's equation is reduced to solving a Hilbert-type problem, whose exact solution is given. The polynomials belong to the class (6.3.44), whence the great importance of this solution. According to Weierstrass's theorem (see for example, [6.13], p.61), every continuous function on the interval [-b, +b] (i.e., every possible form of the wing) may be approximated by polynomials. Practically, for this one may employ an interpolation method (for example, Newton or Lagrange's method). Even if p(y) is a polynomial, in this method it is not necessary to be symmetric, like in the theory of Vekua and Niagnaradze.
Numerical Methods
6.4 6.4.1
Multhopp's Method
The idea of biulthopp's method consists in approximating the func-
tion C(a) by the trigonometric polynomial P"(c) obtained by the Lagrange interpolation in the basis (sinkc)kl,...,n. For determining P", we notice that after introducing the matrices
ST = (sin c,...,sin nc),
aT
= (al,...,an),
it may be written as follows
=
P.
n
(c)
ak sin ka = sTa.
(6.4.1)
kal
The points where one imposes for PP(o) to coincide with C(o) (the nodes) are given by the uniform grid aI
n+1 -o,
a2
2a
n+1
-2a,...,c"=
na
n
1 =nor,
(6.4.2)
whidi is usual in the theory of interpolation [6.13] p.20. These are equidistant on the half-circle with the diameter on the span (fig. 6.4.1). The points xJ = cos a1
(6.4.3)
THE LIFTING LINE THEORY
224
+z
x
-1
1
b
y
Fig. 6.4.1.
are the zeros of the Chebyshev polynomial of order two (F.2.8) on the interval (0,7r).
Denoting c; = C(a1) we have to determine the matrix a from the system Sa = c,
(6.4.4)
where
sin ai sin 2a1 ... sin nal S = sin a2 sin 202... sin nag
c=
(6.4.5)
sin a, sin 20,E ... sin na
One obtains [6.131, p.21
S-1 =
IS. n2
(6.4.6)
NUMERICAL METHODS
We shall present at the end of the section this calculus. Hence,
n+l
sin v1... sin na1
Cl
... sin na
c
(sin a...sin no) I sin on
1Ecinko l 2
n+
(6.4.7)
k=1
1(sin a... sin na)
ctsinka 2
+
sin koj s i n j=1
k=1
For C(a) we have the Wowing expansion:
C(a)
= n +2 1
n
n
ck
sin ka j sin jo.
(6.4.8)
We must notice that this expression could be also obtained from (6.2.26) approximating the Fourier coefficients according to the definition of the integral for an equidistant division a. Indeed, f om (6.2.26) we have:
C(Q) sin yoda
Aj TO
+1
k,i
C(ck) sin jai, .
Since jak = jka = kof, eraplaying Glauert's approximation Al sin jo,
C(Q) _
j-1 one obtains (6.4.8).
Utilizing Multhopp'e expansion (6.4.8), from Prandtl's equation (6.2.28)
226
THE LIFTING LINE THEORY
and from Glauert's formula, we deduce: sin s
4b,3
n+1
n
n
ck > sin jka sin js+ k=1
j=1 (6.4.9)
27r
s sins.
sin jka sin js = 2irba s j=1
k=1
Giving to s the successive values La(£ = 1, ... , n) and taking into account the formulas (6.4.17) and (6.4.19) from below, we deduce the
system (£ = I,-, n), BtkCk = Bt,
Oct +
(6.4.10)
k=1
where
2Bt = (n + 1)ira(£k)j(£a).
(6.4.11)
Fbr k $ t, Btk
-
lra(£a) 2bsin£a
I - (-1)n-t 8
_
I sine
(k + t)a 2
1
sine (k - £)o`
' (6.4.12)
2
and for k = e, Att =
7ra(£a)
n(n + 1)
2b sin la
4
(6.4.13)
Determining the unknowns c1, ... , c from the system (6.4.10), one obtains the solution of Prandtl's equation from (6.4.8). Since Atk vanishes when k - £ is an even number, the system (6.4.10) may be separated; more precisely, the unknowns with odd indices may be expressed by means of the unknowns with odd indices and vice versa. This fact was proved in [1.2]. As it is already mentioned in (1.2] and in (6.17] an iterative procedure for determining the unknowns is
also established. The author had not at his disposition this paper. The procedure simplifies in the case of the symmetric wing (C(y) = C(-y)), i.e. when ck = Cn+l _k (k = 1, 2, ... , [(n+ 1)/2]) or in the case of the antisymmetric wing (ck = -c,+1_k). In the first case the system reduces to [(n + 1)/2] equations, and in the second to ((n - 1)/2]. The square brackets indicate the integer part of the number from the interior.
227
NUMERICAL METHODS
In the sequel we shall calculate the sums that intervened in the above formulas. Let it be for the beginning n
r
j=1
i=1
11.Ecosrja, 12 - Esinrja.
(6.4.14)
Denoting z = e1r`r, for r 96 0, we obtain
_
z - zn+i
-
=
l- z
1
whence, separating the real part from the imaginary one,
I1 = -1 +
1 - (-I}r ,
2
12 =
1 - (-I)r 2
cot
ra . 2
(6.4.15)
One obtains the sum n
r
Ejcosrja-
1
j=1
4
I
era
sin 2
(6.4.16)
12 with respect to a. We deduce therefore, noticing that k - f and k + f are odd or even simultaneously,
deriving
n
n
2 E sin kja sin eja = E cos(k - e) jaj=1
j=1
(6.4.17) n
-Ecos(k+f)ja= (n+l)6kt. j=1
With these formulas, the relation (6.4.6) written as follows S-1S
n2
S2=1
may be immediately proved, since we have: n
Sz
n
_ E sine ja F sins ja sin 2ja ... sine ja sin nja j=1 ial j=1
(6.4.18)
THE LIFTING LINE THEORY
228
Utilizing now (6.4.16), for k q& a we deduce n
2 E j sin kja sin eja = j=1 (6.4.19)
4
sin2
and for k = e:
(k+2 e)a
sin2
e
(k 2
n
4 E j sine kja = n(n -}- 1).
(6.4.20)
j=1
Analogously it results: n
2 E sin jka sin ja = > cos j(ka - a) - > cos j(ka + a) _ j-1 j,1 j
-Re z-Zn+1
Z-Zn+1
_Re 1- f
I-Z
s,,01(ka+.)
(-1)k+1 sin(n + 1)a sin ak COs a - COS ak
(6.4.21)
If we utilize this identity, for the formula (6.4.8) which gives the solution of Prandtl's equation , we obtain the final form
C(a) __
1
n+l
n k=1
k+1
`
sin(n + 1)a sinker . coo a - cos ka
(6.4.22)
In [A.23], p. 98-111 one gives a mathematical justification of this method. More precisely, one demonstrates that under certain circumstances, the iterative procedure that one utilizes for solving the system (6.4.10) is convergent and the solution (6.4.22) converges uniformly to the solution of Prandtl's equation.
6.4.2
The Quadrature Formulas Method
In [6.5) we gave a numerical method for solving Prandtl's equation by means of Gauss-type quadrature formulas. It is well known that these
229
NUM ERICAG METHODS
formulas give the best approximation. The key of this method consists in writing Prandtl's equation in the form (6.1.21). With the change of variables
y = bs , q7 = bz
(6.4.23)
and, keeping the notations C(s), a(s) and j(s) for C(bs), a(bs) and respectively j(bs), the equation (6.1.21) becomes .
/3C(s)
2b)
1
J-1 (z
(s)s d x + j (s) ,
(6.4.24)
and the conditions (6.1.7),
C(±1) = 0.
(6.4.25)
The solution of the equation (6.4.24) has the form
C(s) =
1
-_3 2 c(s) .
(6.4.26)
Employing the quadrature formulas (F.3.5), the equation (6.4.24) reduces to the algebraic system n
EAkici =7k, k = 1nn,
(6.4.27)
i=1
where we denoted ak = a(zk), Ck = C(xk), era k
A
2b(n + 1)
(-1):+kl
1-
Akk=fV1 -xk+6
jk = j(zk)
(x1x2
-1
i#k,
zk)2
(6.4.28)
n41; zi=Cosn+1,t I'n'
the unknowns being c1,... , c,t. The system has to be studied theoretically and solved numerically using a computer. After determining the unknowns, the lift, drag and moment coefficients, defined in (6.1.21) and (6.1.25), CL
C=
2b
win the form
f
+1
1 - s2 c(s)d s, cD = - A
1
= mA J
1
`s
1 - s2 c(s)d s, c;
r1
ZA-
j
1 - s2 w(s)c(s) ds,
11
s
1 - s2 w(s)c(s) ds, (6.4.29)
230
THE LIFTING LINE THEORY
give with the formula (F.2.12) CL =
(n + 1)A E(1 i=1
- x?)c" CD = - (n + 1)A isl
" _ {n + 1)mA E(1- x; 2)xc:, 27rb2
i_I
x?)w,c{
>,
2nb2
2 c= (n + 1)mA E(1 - xd )x:wig i_1
(6.4.30)
where
w; =
13 VI - x, .
2aai
(6.4.31)
In (6.4.30) we used, like in (6.1.21), the notations A for the area of the domain D and m for dimensionless length of the mean chord (in the direction of the unperturbed stream). For verifying the method, we applied it in [6.5) to the elliptical Sat wing, for which the exact solution is known (6.1.28), (6.1.30). With the notation (6.4.26) it results c(s) = k. Putting in (6.4.27) Aki =
1- x4Ak;,
c; = k4,
it results that the system Ak.;ci
= Q+ it/(2b)
(6.4.32)
must have the solution dl = d2 = ... = c;, = I. For b = 10 one obtains numerically dl = 4 = ... 1000. We deduce therefore that the proposed method is very good. In the sequel we shall give the numeric solution for the rectangular wing (in this case there exists no exact solution). Taking the reference
length Lo in the definition of the dimensionless variables (2.1.1), to coincide with the half of the chord, we deduce xt = :L1. It results
a(y) = 1 and j(y) = 27rc. Putting c; = 27red', the system (6.4.27) becomes Akic!
= 1, k = I- n,
(6.4.33)
where Ak; are given by (6.4.28) where we put ak = 1. The quantities
NUMERICAL 1METHODS
231
of interest in (6.4.30) are
1
kl =_ 71+1
(1-xi)c',
k2=-.1 (1-x?)3,2(c,')2, (6.4.34)
V(1-x?)x,c;, k4=
n+1 i_i
A
n+1
E(1-x?)3/2x,(cI')2. i=1
One obtains CL = 7r2ek1 ,
CD = 7r2e2(kl - k2), (6.4.35)
2c= = 7r2bek3 , 2c; = 7r2bC2(k4 - k3)
.
For b = 10 we obtain the following values:
fi
1
0.8
kl
k2
k3
k4
0.2347 0.2544
0.0907 0.0856
0
0
0
0
The result c= = c. = 0 is natural because of the symmetry of the wing. The lift and the drag increase because of the compressibility. This result is also natural. The value 2.307c obtained here for cL in the case of the incompressible fluid is smaller than the values 7.29 e, 5.28 £, ... ,
obtained with Glauert's method [1.12], but the values obtained with Glauert's method come closer to the values given here if A(= 2b/m) increases, i.e. the span is great with respect to the chord. Just in this situation the lifting line theory is valid. We may think therefore that the method we have just exposed is at the same time very simple and very efficient.
6.4.3
The Collocation Method
The simplest numerical integration method is certainly the collocation method [6.6]. In case that Prandtl's equation has the form (6.1.19) and satisfies the conditions (6.1.7), the solution has the form
C(y) =
b2
- y2 c(y) .
(6.4.36)
According to the collocation method, the segment [-b, +b] is divided into iV elements L; and the function c(y) is approximated on each
232
THE LIFTING LINE THEORY
element with its value c; from the mid - point y° of the segment. So, the equation (6.1.19) gives
,
N
[
4
c(y) = a(y)
2,8
fd
ix1
(b - y)2 d rI + 2j(y),
(6.4.37)
where, as we have already stated, Cj = c(y?). Imposing this equality to
be satisfied in every point yk, k =I,-, N, one obtains N
2
Vr2b2
- yk2ck = ak E Aloe: + 2jk k = I ,
,
(6.4.38)
i=1
where ek = c(yk), ak = a(yko), ?k = ?(yk),
Ak, -
w+1 f J(y
(6.4.39)
b-q
-
y y;+1 representing the extremities of the segment L;(y1 = -b, yN+1 = = b). So, (6.4.35) represents an algebraic linear system consisting of N
equations with N unknowns cj. For calculating Ak{, we notice that for e V (a, ?'J we have
I
a
( 7 7-e )2
d
,
y-e
a -- e
+
nee In [ (ry-e)2 + ( b -e +
+aresin
a
b2_.72s)2 (a-e)
- ry b --a- 7 (6.4.40)
For e E (a, 7) we shall write
II = o
-
(71e)2 d q b2-772
s
=J
66
(n - e)2 v° 'I
d1 (6.4.41)
T
(77 -
e)2 d
b -V2 7
(rl - e)2
d ij.
We use the formula (6.4.37) for calculating the last two integrals. Since (D.3.9)
r-b (q - e)l
d n= -7r ,
(6.4.42)
233
NUMERICAL METHODS
it results that I1 is also determined. Utilizing these formulas, for k 96 i we obtain: Aki
V - y?
b2
y
- 77i+I
yk0
yi+1 - yk
yl
(yi+1
02is
b2
72 + (Vb2_YA.
b2-t/i+l
In
y`
(Vi-Yk)2+ yi
+arcsin
(\
b2-yk2
- yko
yi+1 - yk
y,2
+
+
R--i/i+l - -Eli F1
b2
y,2
P
(6.4.43)
and for k = is y2
b2
Aii =- -7r -
Ii yt I
-
Vbi
b2 - y<+1
y2
+
+ (y +1 I Vb2 - y2
+arcsin b2
1,2+
- yI
`2
Vb2-y°2+ b2-y, )
/
2]n
t? +
(VFb2
2b (6.4.44)
Vb2
y°2
+
tJ+i
where we denoted 2ti = yi+1 - yiFor testing the method one utilizes also the elliptic flat wing. For this wing the exact solution is (6.1.28) with k determined in(6.1.30). Comparing (6.4.33) with (6.1.28), it results c = k/b. For E = 0.1,,0 = 1
(the incompressible fluid) b = 10 and N = 50, the numerical values obtained for ci are situated between 0.050 and 0.053, and the value of k/b is 0.052. For E = 0.0872, A = 1, b = 20 and N = 50 the values obtained for ci are situated between 0.0243 and 0.0252 and the value of k/b is 0.0252. The results given by this method are more accurate when the angle of attack is small. The accuracy also increases when N increases.
THE LIFTING LINE THEORY
234
Since the method is simple and can be easily applied one can accept the error of order 10-3 that it contains.
6.5 Various Extensions of the Lifting Line Theory
The Equation of Weissinger and Reinner
6.5.1
In the sequel we shall study new integral equations in order to improve
Prandtl's model. In the past the researchers did not pay too much attention to these equations because the integrands contain both the unknown C and the derivative C'. Now we may use successfully these equations because some fundamental results concerning the Finite Part are known and, as we have mentioned in 16.5], after replacing the
Principal Value of an integral which contains C' and has a Cauchy type singular kernel by the Finite Part of an integral which contains C and has an hypersingular kernel, we may employ the numerical methods. First we shall study the equation of Weissinger [6.30] and Reissner [5.29]. For obtaining it, we return to the lifting surface equation (6.1.28). Taking (6.1.6), (6.1.11) and (6.1.12) into account, we deduce +b
rlydn. l Cdn-7dt J-e 9 ff bod JJ dq+2
(6.5.1)
Utilizing (5.1.35), from (5.1.28) it results the first form of the integral equation
r+b fi(n) d n +
1
ri - y
1'rj
(1 4w JJD lJo \
_ z o d td r1= rt, (x, y). R
(6.5.2)
Multiplying this equation by (6.1.15) and integrating it on the interval [x_(y), x+(y)] one obtains
j+b
a(y)C(rl)d71+
brl - Y +
1
+b
2a J-b
+(v) x+(n)
Tx-)
x-x-(y) Mm) (i_i) dx d d E rl f(v), x+(v)-x (6.5.3)
j(y) being (6.1.18).
235
VARIOUS EXTENSIONS OF THE LIFTING LINE THEORY
Further we shall perform an approximation which consists in replac-
ing f(f,9) by C(n) A(n)
f (f, rl)
x+(n) - f
(6.5.4)
This is just the solution of the two-dimensional problem when h' is constant. Indeed, according to the formula (C.1.9), for a given y , the equation of the two-dimensional problem
1+(v) f(f,y)
T
( 6 .5.5 )
= hx (x,y),
n ,-(,) f - x
becomes, in case that h' does not depend on x: f (x , y)
x+(y) - x
= -h(y) x - x_(y)
(6 5 6) .
.
Multiplying (6.5.5) by (6.1.15), integrating the result over (x_ (y), X+ (y)] and utilizing the formulas (B.5.4) one obtains: -+(v)
C(y) __
- J:-(v)
(6.5.7)
f (f, y)d f = ira(y)h'(y)
Eliminating h' from (6.5.6) and (6.5.7) one obtains (6.5.4). With this approximation, the equation (6.5.3) becomes:
a(y) J bbC n)di? +27r YO
T-b
(6.5.8) TO
where
N (y, n)
:+(v)
_+(»)
xo rIl R)
x+(ti) - F x- x-(y) - x-(+))
x+(y) -- x
dxd
f
.
(6.5.9)
Using the notation r)) No ( y, n) = N(y,
A(y)A(n) = 1
x(y)
f A(y)A(q) J=_(vl 1
(6.5.10)
_+(,) J=-(»)
x+(r1) - f
x -x_ (y)
f- x-(rI) V x+(y) - x
d xd
f,
THE LIFTING LINE THEORY
236
we may write the equation (6.5.8) as follows: CYO
- f eb
)dn+
2A
fC
o
N°(b,n)dn = J(y).
(6.5.11)
and J(y) being defined in (6.2.7). This equation has been deduced by Reissner [5.29). Other simplifications are performed in the papers [5.24] [6.30] in order to obtain an approximate solution. The A(y)
difficulty consists in the presence of both C(n) and C'(n) in the integrand (the equation is integro-differential). Employing, as we have already shown, the Finite Part, i.e. taking (6.1.12) into account, we may write the equation (6.5.11) as follows C(q)
2 _1
y! `Ni(y, n)d, = J(y) ,
(6.5.12)
where we denoted NI = No - 2. This is the equation we are going to use in applications. This is an integral equation.
6.5.2 Welssinger's Equation. The Rectangular Wing In the case of the wings for which the lifting surface equation cannot have the form (5.1.41) (this class is established in 5.1.7, and it contains the rectangular wing) one obtains an equation which may be easily utilized in applications. This equation was given by Weissinger [6.31), and received his name. Starting from the definition (6.1.6), we have:
-i',}(n)f (x+(n) n) + x'-(n)f (x-(n), vi)-
f - f=-(")
x+(+r) a f
8dt
rx+(n) 8 f
_ J=-0)
(6.5.13)
dt.
We are going to show why the sum
-x+(n)f (x+(n), n) + x' (rl)f (x- (n), n) can be neglected. The first term vanishes by virtue of Kutta-Joukowski condition. The last term vanishes for a straight leading edge, perpendicular on the Ox axis (for example this is the case of the rectangular wing). It also can be neglected when the leading edge is slightly curved (x'_ (q) = 0). In general we can neglect this term considering that we have prolonged the theoretic leading edge in front of the real leading
237
VARIOUS EXTENSIONS OF THE LIFTING LINE THEORY
edge and in this zone f = 0. With this approximation, the equation (5.1.41) may be written as follows:
'+b
1
C'(17)
Ud,1
-a
2w
AD 09 xo
-d
fd
=-
"(x,
N)
(6.5.14)
We make a second hypothesis, having in view to be satisfied in the case of the rectangular wing of width, let's say, 2a, namely we substitute
a' instead of zo from R. This approximation is justified by the fact that (x - jj varies from 0 to 2a, hence on the greatest part of the domain D we have IxoJ = a. So, the equation (6.5.14) becomes:
'+b
1
27r
1-6
dn -
we
-
f
1
27r
f+A
"+
_. aq
(6.5.15)
x0yo
Multiplying by (a +- x a - x) and integrating with respect to z on the interval (-a, +a) one obtains
a
-d n+ L jr a C 'm
2Ja
2
30(y) _ -a
-a
C (rl)d rl
rah(y) ,
a±xh"(x,y)dx.
(6.5.16)
(6.5.17)
Introducing the non-singular kernel
K(pa) =
f, fd
a+
_ a
yo
go
(6.5.18)
the equation (6.5.4) may be written as follows C' r7)
Ir
YO
n+
Zax
f C'(rj)K(ya)d tj_ jo(y) .
(6.5.19)
This is the definitive form of Weiseinger's equation. It was created mainly for the rectangular wing. Before presenting the method of integration of this equation, we have to notice that it is not necessary to determine C(q). It suffices to find C'(t) because from (6.1.9), integrating by parts, it results CL
b yC'(y)d y, es = -aQ = -- A J b
y2C`(y)d y.
(6.5.20)
238
THE LIFTING LINE THEORY
The solution of the equation (6.5.19) has the form Cr(y)
tiP(J)
(6.5.21)
with sp satisfying the equation '''+6
1
d i7 b2
b
2 Yo
1
+ lira
f
(t ) h (Ju)d q = lo(U) . (6.5.22) b2 - rf2
6
Performing the change of variables 'i = brl', y = by' one obtains 1
rrb
'r+t
J 777=7 it
y
sp(rl)
1
d>>
;p(aT)
27ra J
i
i - >>
h0(bJo)d n = .?o(bJ) (6.5.23)
This is Weissinger's equation. It looks like the generalized equation of thin profiles (C.2.1). The numeric solution is determined by means of the formulas (F.2.5) and (F.2.6).
6.6 6.6.1
The Lifting Line Theory in Ground Effects The Integral Equation
The lifting line theory in ground effects is obtained from 5.3, as well as Prandtl's theory is obtained from the lifting surface theory. We are not interested in finding the velocity and pressure fields. The integral equation is obtained from (5.3.13) utilizing the formulas (6.1.11)-(6.1.13)
and the relation (6.1.8). One finds
1 T7r
+b E + f.?+ (y) f y, y) ! d d U f $ b 7-y y n (y)
+ (6.6.1)
1
+b
+2- J C(t)i(x, yo)dTl = 2/is(x, y) , where d2fl2x
d2
- yo
yo) _ (d2 +y()2 )R3 + (dl + y02)2 ( \1 + R2 =
x + e2 ,
e2
= 02(y2 + d2).
x
RI) '
(6.6.2)
239
THE LIFTING LINE THEORY IN GROUND EFFECTS
Multiplying (6.6.1) by (6.1.15) and integrating the relation just obtained
with respect to x on the interval (x_(, ), x+(rj)), we obtain, taking (B.5.4) into account: C'(11) d
2#C(y) + a(y) Lb
Y-17
q
r
+
,l
C(n)No(y,
yo)d n = 2j(y) , (6.6.3)
b
where we denoted s+(v)
x - x_ (y) N(x,
J:^(v)
x+(y)
1
No(y, yo)
(6.6.4)
yo)d x,
j being (6.1.18). The equation (6.6.3) is the lifting line equation in ground effects. It was given in (5.8J. It is obviously an integro-differential equation which generalizes Prandtl's equation (6.1.16) (Um N = 0). Further we shall make some considerations concerning the kernel No(y, yo)-Taking (5.3.11) into account and introducing the functions
Iv(y, yo) _ -
+(v)
r
J
z+(y) (yx (xz + e2)"/2
(v)
d x, v = 1
,
(6.6.5)
we obtain:
No(y, yo) = (a +
y)2 [I, (y, yo) - a(y)] +
#2 13(y, yo).
(6.6.6)
Performing the usual substitution x = s(y) + a(y)t,
(6.6.7)
where
s(y) = x+(y)
x-(y) , a(y) = x+(y)
X-(Y)
(6.6.8)
2
2 the integrals I become +i
1
IN = -na(y)s(y)
J
l+ t 1
t
dt P(t)v
aZ(y) 7r
r+i
.!-1
-1+-t
td t
1-t
P(t). , (6.6.9)
where
P(t) = a2t2 + last + e2 + s2 . (6.6.10) It is well known that the best approximation of these integrals is given by the Gauss-type quadrature formulas (F.2.24). With this form (6.6.9) one may study the asymptotic behaviour of the kernel No(y, yo) given by (6.6.6) depending on the parameter A2 = d2/b2.
240
THE LIFTING LINE THEORY
6.6.2
The Elliptical Flat Plate
Without considering the ground effects, the solution of this problem is (6.1.28), (6.1.30). In the sequel we shall determine the influence of the ground. We assume that the wing has the equation x2/e2 + y2/b2 = 1. We deduce
xf(y)=fb b2-y2,
a(y) =b Vb2
- y2s(y) = 0.
(6.6.11)
Assuming that the span is much larger than the chord (e << b), we shall neglect the terms of order (e/b)2. From (6.6.9) we deduce I = 0, whence
`
Integrating by parts, we deduce:
f
+b
+b
C(n)No(y,yo)dn=-a(y)f C'(n)&?yodn, b
b
and the integral equation (6.6.3) becomes:
2fC(y) + a(y) J b C,n) d q - 2a(y)
J
bb
C'(1) d2 + y02 d n =
4_-Tra(y).
(6.6.12)
For d - oo one obtains Prandtl's equation. (6.1.16). Taking into account the shape of a(y) from (6.6.11), we shall look for solutions of (6.6.12) having the form
C(y) = k b2 - y2.
(6.6.13)
The first integral was calculated in (6.1.29). The second may be calcu-
lated with the substitution y = by, n = biz. If b < < d we neglect the terms O(b/d)4 and we obtain
f
b 2ir \a)2
b
(n)d2+yody=k
2
We assumed that the span is much smaller than the distance to the ground. Replacing (6.6.13) in (6.6.12), we obtain the relation which determines k: (b `2 Tr = 1Ezr6 . (6.6.14) k 2p+ -n b
-
-I
241
THE LIFTING LINE THEORY IN GROUND EFFECTS
Denoting by k the value of the constant when there are no ground effects, i.e. (6.1.30), we deduce
k=kak, where
(6.6.15)
2f3 + (t/b)ir k0 = 20 + (t/b)ir - (e/b) (b/d)27r
(6 .6 . 16)
Obviously, k > 1. The lift, drag and moment coefficients are given by the formulas (6.1.21) and (6.1.25), where for w(y) = w(0, y, 0) we have 15.81: W(y)
C ,(n)
J 47r
bb
d
rl - 4n
C'(Tl)
b
& yo d n.
(6.6.17)
These formulas (6.1.21), (6.1.25) and (6.6.17) are valid for every shape of the wing. For the elliptical flat plate wing we obtain:
w(y) = - 4
1
2
+
C
!
(6 .6 . 18)
such that
cL=kocL, cD=klcp, c==c.=c, with the notation
(6.6.19)
2
k1=ko li(1+2 )>1,
(6.6.20)
lift
Cr and cD representing the
respectively drag coefficients in the absence of ground. Obviously, both the lift and the drag are increasing in the presence of the ground. The coefficients ko and k1 depend on M, t/b, b/d. The numerical calculations from 15.81 show that for the lift the increase is not significant
but for the drag it is considerable. The ground effect is a decreasing function of d. For the same values of the ratios t/b and b/d the influence coefficient ko is an increasing function of Mach's number M.
6.6.3
Numerical Solutions in the General Case
Utilizing the formula (6.1.12), one may write the equation (6.6.3) as follows:
2#C(y) - a(y)
f
+b b
c(n) d n+ (n - y)2
f
+b
C(n)N(y, yo)d n = 2?(y) b
(6.6.21)
242
THE LIFTING LINE THEORY
As it is known, this is an integral equation, not an integro-differential one, but the singularity is stronger than in (6.6.3). In (6.6.3) we have a Cauchy - type singularity and in (6.6.21) we have to consider the Finite Part of a hypersingularity. But for this kind of equations there are available quadrature formulas. In order to apply this method, we have to perform the change of variables y = by, q = bq' for calculating the integrals on the interval (-1, +1). We obtain 2bIC(y) - a(y)
f
+t C(n) Y)2 d n + b21 C(i7)N(y, yo)d =
+1 1
(n -
j(y)
1
(6.6.22)
Since the solution of this equation has the form C(y) = V171- y2 c(y),
(6.6.23)
we obtain
1 - yj cj - aj
2b/3
1 --17C(17) d n+
Ti
(n - yj)
1
1 - i2c(yl)N(yj, yj - n)d n = 2bjj , yj = cos n
+b21+
+ 1,
t
j=T
.
(6.6.24)
Using (F.3.5) and (F.2.12) one obtains the system: n
Ajcj + E Ajkck = 2bjj , j = 3n-,
(6.6.25)
k=1
where
A.;= MO 1-y;+aj7r Aak
-a L
n+1 2 b2k.
7r
n + 1
- yj)2 + 1(yk - (-1)'+k
n + 1
N(yj, yj - yk) (1 - yk2) J
(6.6.26)
In the first term from Ajk one excepts k = j. The system (6.6.25) is solved numerically.
6.7 6.7.1
The Curved Lifting Line The Pressure and Velocity Fields
In this subsection, we shall pay a special attention to the aspect ratio A = (2b)2/A introduced in (5.4.1). Usually, if A is small, one applies
243
TILE CURVED LIFTING LINE
the theory from 5.4 concerning the wings of low aspect ratio. If A is large one applies the lifting line theory. These are the two asymptotic theories of the lifting surface theory. As it is known, one of Prandtl's hypotheses consists in replacing the
domain D by the segment [-b, +b] taken along the span (the Oy axis). This hypothesis is plausible for the wings having the shape of an ellipse, triangle, trapezium or rhombus (see fig. 6.7.1) but it can be the source of great errors in the cage of the wings having the shape of a
swallow tail or the shape of an arrow. In the first case it is natural to replace the wing by the curvilinear median (see fig. 6.7.2), and in the second case one approximates the wing by the median broken line (fig. 6.7.3). For birds, the nature preferred the curvilinear median. These are enough reasons for studying in this subsection the curved lifting line. In YA
b
j'I i
Y
Y.
b
i
b
rt 1
1
0 x
-4 i
t
aX
0 1 1
b)
1
Fig. 6.7.1.
Fig. 6.7.2.
Fig. 6.7.3.
244
THE LIFTING LINE THEORY
this case, one starts too from the general representation (5.1.8)-(5.1.12) and Prandtl's hypotheses. We assume therefore that the wing is without
fl = 0) and that the unknown is C(y) defined thickness (hl = 0 by (6.1.5), with the conditions (6.1.7). When the domain D reduces to the curved line r (fig. 6.7.2) having the equation x = x.(y), the formula (6.1.8) is replaced by
r`
/ JD f
lim /
il)k(x, y, z, t, q)d d y = -
f
+b
k(x, y, z, x. (q), n)C(i )d +1,
b
(6.7.1)
for x-(n) -. x. (n) - x+ (n) So, with the notation R. =
ix - x.(n)]2 + A2(y02 + z2),
(6.7.2)
the formulas (6.1.9) become z
P(x,y,z) _ -4
C(ri) z dn.
(6.7.3)
rt
v(X' Y, z) = -
I
:Fir =fl
lim.
o-)]
J 1D f (C, n) gEl l yob z
.1 JD f (C W 1+ RI
(1 + R-
)
z
y2 + z2
d
d
)dtdn+
+XOZ
C(n)11+x(n)lal\
l Jb
47r
L
o+z2)dn-
JJ
p2yo
+6
[x - x.(n)]z - T7r 14 C(rl) yof-' R3 d n 1
(6.7.4)
Utilizing now the identity
r
x - x` R. R
_ 8(
8
) &1 z
z
z(x-x') /2yo y
x-x.`1 R* jl +
z2 R3 _ (6.7.5)
32z ,
THE CURVED LIFTING LINE
245
we obtain, after performing an integration by parts,
j
f
v(x, y, z) =
+b CI(rl)
f1+
x R'(q)] d,,R.
C
(6.7.6)
Q2 47T
/ +b
J
b
zZl=
C(i) R. d q .
Analogously,
w(x,y,z) =wi +w2,
(6.7.7)
where
=4a
fffri)_ j+bx R,
x}m.(_)ddtl=
(n) d n
4nx*-x.JJDf(C v?) 2[y02
W-2
47r xlim- . If,,, f (C rT) l 1 + Rt 1
lr ,ffDf( , l) o+Z2 YO X02
lice
=
art
l 6r+.2) d d'r
(6.7.8)
(_)dd= R 1
r+b
4 J b C(") ['x_x,(,i)l 09l ( T2 + Z2 l d YO
Y7+
J
+Q rb
c(n) yo +'Z2)
dn.
Introducing the identity
$2(x _ R.
yg
+Z2)
110+z2
1
T3
(6.7.9)
Jyoyo
ly +z2
[1+x-x.(n)1I+Q2yO2X1 Rl J Rs
)
246
THE LIFTING LINE THEORY
and, integrating by parts, we obtain u2. In fact, it results: x w(x' y, z)
('l) d
4a fb C(r1)
R3
+b
-4
f
b+6
q+
4n
bb C(17)
-
--d n-
r
(+I)] d>1.
y0+2 I1 + x
r
b
l`
(6.7.10)
6.7.2
The Integral Equation
We start from the lifting surface equation having the form (5.1.28). Utilizing (6.1.6) and (6.1.12), we deduce:
Y=dtdn
Eb
(q)
0
(6.7.11)
dr=
C
1 =;F
+b C'(rl)dq.
1
4'rJ-b 11-y
0
b
Taking (6.2.1) into account, we obtain:
12 = -
lim
1
47r
11D
f(
x0 d l;d
R
To
= (6.7.12)
C(n) x-x.(rl)drl,
1
R°
where
R; =
[x-x.(n)12+(.32y .
(6.7.13)
Utilizing the formula (D.3.7) and taking into account that C(±b) = 0, we deduce Iz
1
'r+6
41r ,l -b n
8r
1
u ON {C(rl)
x- x. (n)1 Ro.
Jd_ (6.7.14)
1
'' +6 C11) -x-
4ir.!_b n-y
x. Ro
d'l+la
247
THE CURVED LIFTING LINE
whore 1
13 = -
Co 8
-
n v 8n
_-
d *!
R°
(6.7.15) C(n)xx
x(n
4(n)dn
4sr
From (5.1.28), (6.7.11), (6.7.12) and (6.7.14) we obtain the equation: t bb
K(x, y, n)d n + 4A ,!_b n (ny
air
C('i)L(x,
y,,7)d n = hs(x, v) (6.7.16)
where
K(z,y,n)=1+ (6.7.17)
x - x. (n) - ray'. (n)
L(x, y,
(R.)
are non-singular kernels. The equation (6.7.10) was obtained in another way by Prosadorf and Tordella (6.22]. It is a singular Integro-differential equation.
For the straight line (x.(q) : 0) one deduces Ci(r!)
Ib n +b
47r
j' C'(n) x
- yd n + Oar J
iJ n - y Rd n - 4
x C(q)
n = h: (6.7.18)
x+ . This equation is a first approximation of the lifting line equation. Fbr deducing the equation (6.1.16) we had A < < yp on the greatest part of the domain D, such that we might where R
consider Re = i4jyo(. Here we cannot perform this approximation.
6.7.3 The Numerical Method Using (D.3.7), one denaozutrates the identity
J-bb (n -
y2K(x, y,
n)dn = Jn vK(x, wn)dn+ (6.7.19)
C(tl) 8 + 14 n-y b K(x,y,y)dn,
248
THE LIFTING LINE THEORY
such that (6.7.16) becomes: C(rl) K(x, y, ri)d rl - 1 7 T-b (11-y)'"
} C(q) 8 K(x, b, y)d q+
J b n-y q
(6.7.20)
This is an integral equation (not an integro-differential one) but with a strong singularity, for which the Finite Part is considered. We denote
AI (x, y, y) =
8
5; K(x, y, y)
(6.7.21)
and we perform the substitution y = by', v = br1'. The equation (6.2.14) becomes:
'(
A
l
C(eta
2 K (x, y, r1) d 1l -
I
b
iJ
1 C(+1)
+
n-y
M(x, y, y) d r1+ (6.7.22)
+ b2 r+1 C(i) 7r
_
L(2:, y, +1)d 17 = 4bh'. (x, y) , I
where
K(x , y , rl) = L(x, y, n)
xx.(rl)
1+
1(x - x,)2 + b2R2yo11/2
x-x,('7)-byox:
_ -F 2 1(x - x.)2 + 62Q2yo13/2
(6 . 7. 23)
M(x,y,y) = 6 W (T, y, Y) Utilizing the quadrature formulas method, we shall take into account that the solution of the equation (6.7.22) has the form:
C(n) =
--q2 c(r1)
(6.7.24)
and we shall utilize the formulas (F.2.12), (F.3.4) and (F.3.5). Denoting IM
=cosnk+l, k=in-,
(6.7.25)
one obtains from (6.2.16) the algebraic system
'AJ,ec* = 4bh2(x,g3), j = ln,
A,cj + L= I
(6.7.26)
249
THE CURVED LIFTING LINE
where
AJ =
+1 2
K(x, n;, nj),
Ask= (1 - rlk)
1[1-(-1) +k
:i+1
(nK(k x, nj n,,)nk)
-
I
2+
(6.7.27)
+b [1- (-i)+k1 M(x,17;, nk) + b2ajkL(x, n;, nk) J
rlk - ni
For writing explicitly this system we have to know the shape of the wing. For example, for the flat plate having the shape of an arrow with the angle of attack e we adopt the broken line model (fig. 6.7.3). We
have f = -E and utilizing the substitution y = by,
0
Y,
K(x,y,n) =
L(x,y,n) =
K1=1+xRn, 0
=1+
x+r7,
R
-1 < n < 0,
(6.7.28)
L,=-#2x-"-yo 0
where
1/2 R= [(z_y)2+b22(y_q)2]
The system (6.7.26) may be solved numerically using a computer.
Chapter 7 The Application of the Boundary Integral Equations Method to the Theory of the Three-Dimensional Airfoil in Subsonic Flow
7.1 7.1.1
The First Indirect Method (Sources Distributions) The General Equations
The superiority of this method in comparison with the classical meth-
ods has been exposed in Chapter 4. Using this method we succeed to impose the non-linear boundary condition just on the boundary of the wing. Moreover, it allows to solve numerically the integral equation of the problem, approximating the boundary by a polygonal line in the two-dimensional case, or by a polyhedral surface (consisting of panels) in the three-dimensional case. We deal with the problem considered everywhere in this book. A subsonic stream, having the velocity U,,.i, the pressure poo and the density per. is perturbed by the presence of a fixed body, having a known surface E. One requires to determine the perturbed flow and the action of the fluid against the body. Introducing the dimensionless variables X, Y, Z related by the dimensional variables xl, yl, zl as follows
(XI, y1, zt) = Lo(X, Y, Z)
and putting
V1=Uoc(i+V), P1=p,, +p,oU,2,.P
(7.1.1)
we obtain the system for the perturbed fields: R12OP18X + Div V = 0, OV/OX + Grad P = 0.
(7.1.2)
Projecting the last equation on the OX axis, we deduce:
P=-U
(7.1.3)
252
HIEM. THREE-DIMENSIONAL AIRFOIL
Taking into account this result, the first equation from (7.1.2) and the projections of the second on OY and OZ, give fl29U/aX + OV/aY + 8W/0Z = 0 (7.1.4)
av/ax - are/ay = o, aw/ax - av/az = 0, U, V, W representing the coordinates of the vector V. Denoting by F(X, Y, Z) = 0 the equation of the boundary E, we have to impose the condition
(1+U)Nx+VNy+WNZ=O, F=0, where
N_
(7.1.5)
Grad F (Grad F1
(7.1.6)
With the change of variables
x=X, y=AY,z=QZ u= j3U,v=V, w=W.
(7.1.7)
the system (7.1.4) becomes
au/ax +8v/ay + aw/az = 0
(7.1.8)
au/ax + 8u/ay = 0, raw/ax - su/az = 0.
(7.1.9)
Performing also a change of variables in F we have
aF/8X = OF/0x, (9F/8Y = (30F/8y 8F/8Z =130F/az , such that the boundary equation (7.1.5) becomes
un=+ f32(vny+wns) = -13b?,F = 0,
(7.1.10)
where grad F (7.1.11)
Igrad F1
We agree to utilize the inward pointing normal to the body. We also impose the damping conditions at infinity lim(u, v, w) = 0. 00
(7.1.12)
The first equation from (7.1.9) represents a necessary and sufficient condition for the existence of a function io(x, y, z) such that
u=
v = acp/ay .
253
THE FIRST INDIRECT METHOD (SOURCES DISTRIBUTIONS)
From the second equation and from the damping condition it results
w=8o/8z. With this representation, the equation (7.1.8) gives App= 0. It is well known that the fundamental solution of this equation,
tp(x)_-47r 1, r r=Ix - tI,
(7.1.13)
represents the potential of the flow determined by a source of intensity f, having the position vector . The velocity field is
v = grad p = 7.1.2
4 xr
(7.1.14)
The Integral Equation
Replacing the body with a continuous distribution of sources on E, having the unknown intensity f (x), the velocity field in fluid will be
U( ) _
-4; Iff(x) Ix -
3da,
(7.1.15)
t representing the position vector of the generic point M in the fluid.
7.1.3
The Integral Equation
In order to impose the boundary condition (7.1.10) we have to pass to
the limit in (7.1.15) considering that M(4) tends to the generic point Qo(xo) E E. To the limit, the integral from (7.1.15) becomes singular. Following the procedure from the two - dimensional case (see 4.2.1), we
shall prove that if f (x) satisfies Holder's condition on E, then v(xc)
4o - \ 4r
jf f
(x) I x - 41 3 d a1
=-2f(xo)r+o-,- 11 (X)Ix-xolda,
(7.1.16)
254
BIEM. THREE-DIMENSIONAL AIRFOIL
where (7.1.17)
6-+O1 JE-O
J JE
a representing the surface cut from E by a sphere E, having the center in Qo and the radius E. Indeed, writing
IL =
J
(7.1.18)
f,0+0
we have to calculate
L= lim
JJf(z)x x3 da,
i.e. the last term from (7.1.18). Writing this term as follows
L= lim
t-.z0 J
where Lo
d a + f (zo)Lo
J (f (z) - f (xo)l x
li n f f f
IX
,
(z)1013da,
(7.1.19)
we notice that the first integral from the expression of L tends to zero
when a - 0 because f satisfies Holder's condition. For calculating Lo we shall replace o by A, the projection of the surface a on the plane 11 which is tangent to E in Qo (fig. 7.1.1).
Fig. 7.1.1.
255
THE FIRST INDIRECT METHOD (SOURCES DISTRIBUTIONS)
On this projection we shall use the parametrization
x = xo + r(cos 9io + sin 9 jo), 0 < r < e, 0 < 0 < 27r,
(7.1.20)
io and jo being versors orthogonal to the plane n. Also, taking into account that the limit is the same on every path on which 4 --+ xo, we consider the limit on the direction of the inward
normal no = n(xo) to E in Qo. We have therefore
f =xo-qno, q>0.
(7.1.21)
Hence r 12" r(cos 9io + sin 9jo) + rlno rd rd 8 = 2zrn (r2 + 712)3/2 'i-.0 0
L0 = lim
.
(7.1.22)
Now the formula (7.1.16) is demonstrated. Imposing the condition (7.1.10), we deduce the following integral equation {n2(xo) + li2En2(xo) + n2(xo)]}f (xo)+
+T7r
A Zf ff
(x) (
x-xo)no+fit[(y-yo)noo+(z-zo)noj da= 2 Ix - xo13
.
(7.1.23}
For the incompressible fluid it becomes Lf = f (-To) +
27r
A
f (x) (
Ix
no
xxo13 d a = 2n0, .
(7.1.24)
The integrals (7.1.23) and (7.1.24) are singular.
7.1.4
The Discretization of the Integral Equation
We shall approximate the surface E of the body by a set of triangular panels TJ (j = 1, ..., N) and we shall approximate on every panel Ti , the function f by the value f; of the function in the center of mass G2 (x°) of the triangle. The equation (7.1.23) reduces to {(no)2 + f 2[('nV)2 1
//r
+ (n°)2]}f(xo)+
(x - xo)n? +,02[(y - yo)ny + (z - zo)n?}
Ix-xo13
0 da-21nx.
256
BIEM. THREE-DIMENSIONAL AIRFOIL
Imposing this equation to be satisfied in the centers of mass GG, i.e. putting xa = x°(i = 1, ... , N), we obtain the linear algebraic system N
a,f,+EA,jfj=b;, i=1,...,N,
(7.1.25)
i-1
where we have no summation with respect to i. We denoted
a = n2 (mg) + p2n?(x°) + #2n2 tx°), bi = 2 n (x°) A=i
= X,in.(x9) + O2Yjnv(x°) + Q2Z,jn:(x1
(7.1.26)
(7.1.27)
0
X`, = 2.-r, 1 M
W1
13da.
(7.1.28)
For determining the quantities n(x°) and X,j we shall denote by mil, xt2 and x,3 the vectors of position of the vertices of the triangle T{ ; we choose the sense on the sides of the triangle such that the normal n(x9) is positively oriented towards the interior of the body. Taking into account the definition of the vector product, we obviously have
n(xo) =
(x12 - Wit) X (X,3 - Oil) 2S;
'
(7.1.29)
Si being the area of the triangle Ti expressed by means of the coordinates of the vectors x,l, xi2, x13. The integrals X;j are singular when i = j. We consider at first the
case i 0 j. Denoting by xjl, xj2i xj3 the vectors of position of the vertices of the triangle T1 j, we shall consider the parametrization of the triangle
x=xjl+(xj2-xj1)Ai+(xj3-xjl)A2.
(7.1.30)
F\xrther we shall proceed like in 5.3. Introducing the polar coordinates by means of the formulas
Al = rcos0,
A2 = rsin8 0 < 0 < r/2, 0 < r < p,
(7.1.31)
where p is defined (fig. 7.1.2) by the relation (cos 0 + sin 0)p = 1
(7.1.32)
and denoting e(O) = (xj2 - xj1) cos 0 + (xj3 -
0,
(7.1.33)
257
THE FIRST INDIRECT METHOD (SOURCES DISTRIBUTIONS)
Fig. 7.1.2.
we deduce
x-x9=xj1-x°+re(O) (7.1.34)
I0 -x,012=ar2+br+c, where
a = lel2, b = 2(xjl - x°) e, c = jxj1
- x912 (7.1.35)
6 = b1- 4ac = -4(xj; - x9)e
- (vjl
<0.
For the element of area of the triangle Tj one obtains (7.1.36)
d a = 2Sjd Al d A2 = 2rSjd rd 8,
S; being the area of the triangle. Hence,
X;; = S. f"21(xii - x)I1(e) + e(e)I2(8)]de where
_
rdr
P
Jo (ar2 + br + c)3/2
=
2bp + 4c 6(ap2 + by + c)1 2
_
(7.1.37)
4f 6
(7.1.38) P
alt (O) - f (art + br + C)3/2 with the notations
J - IP
dr
are+br+c
-
2
%r-7
J1 - b11 - C/C ,
( arctan Zap + b vr-7
17)
258
13IEM. THREE-DIMENSIONAL AIRFOIL
K
_
dr
)r°
J0 (art + (n + c)3/2
4ap + 2b 2b 6(ap2 + by + c)1/2 + W c
Ones employ the formulas (7.1.29) and (7.1.37) for calculating the coefficients A1.
7.1.5
The Singular Integrals
The integrals (7.1.28) are singular when i = j. Following the model from 5.3 we shall write: T,j = T(12)
+ T(23) + 7 31)
(7.1.39)
where T!kl) is the triangle GjPkP, and we shall consider the parametriza-
tion of the triangle T,(12) putting
x - x° = (x,1 - x° )J11 + (xj2 - x°)a2 .
(7.1.40)
Passing to polar coordinates and denoting
E12=(xj1-x°)cos6+(xj2-x°)sin8,
(7.1.41)
we deduce
x - x,, = rE12,
Ix - x°I = rIE121
(7.1.42)
Utilizing also (D.2.3) it results X(12)
»
=
0
1
2n
T.02) I x
X0 13
da= (7.1.43)
=
1
Ir ' J JO 3S
X?j =
s/2 E12 (0)1np(8)
UU
(E121'
(7.1.44) + These expressions are utilized for determining the coefficients A.,,.. X123)
7.1.6 The Velocity Field. The Validation of the Method The numerical values of the velocity field are obtained from (7.1.16) with the formula N
2v(x°) _ - f
X y f3 j=1
.
(7.1.45)
THE FIRST INDIRECT METHOD (SOURCES DISTRIBUTIONS)
259
For testing the method we shall use the exact solution in the case of the sphere placed in an uniform incompressible stream. We know (see, for exaunple, [I.11 J, p.163) that if the sphere has the radius a and the center in the origin of the coordinate axes, and the uniform stream has the velocity Uk , then the potential of the perturbed flow is
a3)
(7.1.46)
and\\\V1
Calculating V1 = grado = U,,(i+ v) which results from (7.1.1) under the hypothesis that the fluid is incompressible (A = 1) and using for tv the values (7.1.45), it results the comparison from figure 7.1.3 for IVI I /U,,. We notice that the approximate method and 1.
V 1.0
Exact
...._. I talho d +
a
ao Fig. 7.1.3.
the exact one give very closed results. In the paper [7.2], that we have utilized for writing this subsection, we may find the approximate results for the ellipsoid for various angles of attack and for various Mach numbers. We may also find approximate results for the wings whose cross section is a NACA - 64 - A - 008 profile.
7.1.7
The Incompressible Fluid. An Exact Solution
We have seen that, for the incompressible fluid the integral equation is (7.1.24). In this subsection we shall determine the exact solution of
DIEM. THREE-DIMENSIONAL AIRFOIL
260
the equation in case that the perturbing body is a sphere (7.4).
INg. 7.1.4.
Considering that the points on the sphere (x and Qo(xo) have the coordinates (fig. 7.1.4): X = R(sin q, cos 92, sin ql sin 42, cos ql )
0
(7.1.47)
xo = R(sin qi cos 92, sin qi sin gZ, cos qi)
we deduce for no (the inward pointing normal to the sphere in Qo) no = -(sin g° cos q2, sin q, sin qz, coe g°) .
(7.1.48)
We have therefore:
f (x) - f (ql, q2),
f (xo) - f (q°, q2) (7.1.49)
da = R2 sin gldgidq2,
no -- no = - cos qo
and Ix - xo12 = 1X12 + Ixo12 -- 2x0 xo = 21122(1 - cos9),
(7.1.50)
cos 6 = sin q1 sin q, - cos(Q2 - q2) + cos ql cos go.
(7.1.51)
where
Hence it results
(x - xo) (no) - (x-xo) (x - xo) no Ix-x013
da=
= R(1-cosB),
(1 - cos 8) sin gldgl dq2
-sing1dgldq2
2(1-cos0) 2(1-cos9)
2 1-(oO) (7.1.52)
THE FIRST INDIRECT METHOD (SOURCES DISTRIBUTIONS)
261
With these formulas the equation (7.1.24) becomes 2w
I
f(gi,gz)+47 rJo Jo
f(gi,g2)sin2(igld)q2
=-2cpsq0j.
(7.1.53)
the sign "' indicating that one eliminates the vicinity of the point Qo, i.e. 0 = 0 according to the definition (7.1.17). Denoting 1
K(qi, qq, q1, 42) _
4ir
2(1 - cos 9) '
(7.1.54)
D = (0, 7r) x (0, 2r),
we deduce that the integral operator of the equation which determines the density f (q,, 92), is a bounded operator with respect to the uniform convergence norm for real functions, continuous on the closed rectangle b. This boundedness follows from the property
KsingldQ1dg2 = 1.
(7.1.55)
We sludl also prove that the integral operator has the invariance property
J
j(cosqi)Ksintdqidq2 = cosq°.
(7.1.56)
3 the change of variables For proving these properties we shall perform (qj, q2) -- (0, A) defined by (7.1.51) and by the following relation, which is a direct consequence of the sine rule from the spheric trigonometry
sin A sin 8 = sin q1 sin(g2 - q2),
(e, A) E D .
(7.1.57)
Hence we choose the spherical coordinates relative to the point x for which, instead of the Oz axis we take the direction -no, and instead
of the xOz plane we take the plane of the versors k and nO (fig. 7.1.5). In this way, for the element of area in the generic point Q one obtains d a = R2 sin Q1dQ1dQ2 = R2 sin 6dOdA.
(7.1.58)
Using the cosine theorem from the spherical trigonometry, we obtain cos q1 = cos q° cos 0 + sin q0 sin 9 cos A. Hence,
r
1 ID
KsingtdQldg2 = lID Ksin8d9dA
(7.1.59)
BIEti1. THREE-DLMMENSIONAL AIRFOIL
262
Fig. 7.1.5.
(2" d A /"` Jo o
=I
sin 8d 9
2(1 - cos9)
J f(cosqi)Ksinqidqidq2 = 1 (cos
Jo
n
cos) d A) / (sin 8)K sin dd 9 = 0
/R 2-(
J(cosqi)KsinodldA =
J ID cos 6K sin Bd9d.1+
r2x
+(sin q°) (
-_ 1 '
sin8cbs9
de_
1
qo
qo) 0
3 (1 - CM e) Utilizing the identity (7.1.56), we may solve the equation (7.1.53) by
means of the successive approximations method. Indeed, putting
f1 _-2cosg0,, we deduce
f2 = -
f
fnf1(41,92)K(4i,42,91,92)sing1dg1d42
=
_ -3(-2cosgi) fs =
-If
U
(,)2 (2(41,42)h'sin41d41d92 =
2cosgi)
263
THE FIRST INDIRECT METHOD (SOURCES DISTRIBUTIONS)
I
fk+I = `J
f
Jofk(q ,gs)Ksingtdqidqs =
(3
\k J
(-2cos401)
whence 00
f(gl,g2) =Ffk+1(gi,92) _ k=o 00
= (-2oosgt)
(7.1.60)
(1)k
=
-i cogt.
k=O
This is the exact solution for the spherical obstacle.
7.1.8
The Expression of the Potential
For testing the integral equation, we must prove that the potential calculated with the density (7.1.60) coincides with the exact potential given by (7.1.46). The potential in the generic point M(F) determined by a source having the intensity f placed in Q(x) is according to (7.1.13),
WW _ 4r Ix
i
EI '
whence it results that the potential determined by a continuous distribution, of intensity f (c), on the surface E, will have the expression
w(f) = --I Jf IE IM-41 da. (x)
(7.1.61)
In the case of the sphere E = S(O, R), with the density (7.1.60), the potential is
Arr) =
3 87r
cos
fJ Ix - qlEI d a .
(7.1.62)
Considering the point M(L) exterior to the sphere, having the coordinates
f = r(sin gicosgs,sinq°singscoo q),r > R, we get
Ix - Cl' = R2 - 2rReoe6 + r2
(7.1.63)
BIEM. THREE-DIMENSIONAL AIRFOIL
264
where cos O is defined by (7.1.51). Taking (7.1.58) into account, it results 3
8n 3
R2
cosglsing1dqldQ2 - '?r R cos 8+ r ID
f
c
2
8?
R-
l Jj,
qi sin Od Od A
R - 2rR cos 0 + r-
On the basis of the formula (7.1.59) and the periodicity of cos A, we obtain 3 V 3
2m
R2
_ $R
cosrqo1
ff
d A fo
8n(coc; gi)
cosOsinOd0
J
r
=
[(R2 + r2)(R2 - 2rRcvsO + 1.2)1/2_
o
-(R2 - 2rRcosO + r2)1/2 I sinOd0 = 3 16
lr- RI)- -(r+R)3- Ir-R131
and finally, since r > R,
2 T6 This is also the perturbation potential given by (7.1.46).
(7.1.64)
THE SECOND INDIRECT' METHOD (DOUBLET DISTRIBUTIONS)
7.2
265
The Second Indirect Method (Doublet Distributions). The Incompressible Fluid
7.2.1
The Integral Equation
The theory in this subsection follow the paper [1.11]. We denote by po(x) the potential of a known flow in the entire space. We assume
that this flow is perturbed by the presence of a body whose support is the simple connected and bounded domain D. We assume that the boundary of this domain, E is smooth, such that we may apply Poisson's
formula. We denote by n the outward pointing normal to E. The potential po is a harmonic function, such that we may write (1.11) (D.3.2)
J JE [fi(x) n !x 1 F{
1doi
2(pe(4),
IX-41 tin
4ED
to
(7.2.1)
EE
EE,
E representing the exterior of D. When we write F E D we understand
that the point Al whose vector of position is t belongs to D. Now we assume that the perturbation is produced by the body having the support D and let So(x) be the potential of the perturbation in E. According to the equation of continuity (7.1.8), cp will be a harmonic function which has to satisfy to infinity the damping condition line
S'(F} = 0.
141-Under these conditions, V will have the representation (D.3.10) from [1.11)
2T
J JE
- (x
x7-
x'
tEE
1
1
t)
0 T+p(x)1 d a=
So(t), 0
the normal being the same like in (7.2.1).
F= xo E
LED,
(7.2.2)
266
BIEM. THREE - DIMENSIONAL AIRFOIL
Adding (7.2.1)3 to (7.2.2)1 we obtain W(E) =
f
4a J
{ [,Po(x) + v(x)]
1 41
Ix
(7.2.3)
(s o+9)(x)}da, t E E.
1 I
Determining V in order to have A
A
(7.2.4)
W E E,
co(x) =
the representation (7.2.3) becomes
00 =
f
[PO(x) + W(x)]
Ix
1f
du.
(7.2.5)
Subtracting (7.2.1)2 from (7.2.2)2 one obtains ,P(X0) - Po(xo) = .1
g (Ix 1
f [,Po(x) + P(x)J n
Introducing the function
j u:
x01
)
E E.
d a, xo (7.2.6)
E -+ R by means of the formula
p(x) = fi(x) +
(V)x E E,
(7.2.7)
the equation (7.2.6) reduces to .U(X0) _
2zr J
Jl U(x)
,
\ Ix 1 xol d a =
JPo(xo), (V)--o E E, (7.2.8)
and (7.2.5) to
da. (7.2.9) WW = 4r ,/ / The equation (7.2.8) is the integral equation which determines the function µ, and the equation (7.2.9) shows that this function is just
h (); (Ix 1
the doublets density E which replaces the body. We may write the equation (7.2.8) as follows
lt(xo) +
2a J Js
µ(x)n(x) IxX
x013 d
a = 2cp(xo), (d)xo E E, (7.2.10)
n representing the normal pointing towards the fluid (the outward normal to E). This equation which determines the doublets density, is similar to the equation (7.2.21) which determines the sources density. Only the free terms and the normals from the kernels are different. In (7.1.24) it appears n(xo) while in (7.2.10) this is replaced by n(x).
THE SECOND INDIRECT METHOD (DOUBLET DISTRIBUTIONS)
267
The Flow past the Sphere. The Exact Solution
7.2.2
Considering the problem from (7.1.7), i.e. the integral equation in the case of the uniform flow with the velocity U,,,k past the sphere S(O, R) and utilizing the formulas (7.1.47) we have:
oo= -- =Rcosq°
(7.2.11)
such that the equation (7.2.10) becomes ir
i
II ( g , q0 )
±
47r
2w
j1 0
II (gl, 92, ) s1
-
-la- gc
V 2(l
d. B )
= 2R cos q a .
(7 . 2 . 12)
This equation differs from (7.1.53) only by the right hand side term. The equation (7.2.12) has therefore the exact solution
it = 3 R cos q1
(7.2.13)
.
For testing the integral equation (7.2.10), we shall prove that the potential ip, obtained from (7.2.9) with the density (7.2.13), coincides with the exact perturbation potential (7.1.64). Indeed, (7.2.9) becomes
- 4-r1 I Jz
u(x) '
4 d a. ix 413 Using the notations (7.1.47) and (7.1.63) we have cp(l;) =
(7.2.14)
(x - la) n = R - r cos 9
x F = Rr cos 6,
da = R2 sin glclgldq2,
such that, utilizing (7.2.13), we deduce
1 3k 1P 4ir 2
0 2n'
(R-rcos0)cosgjsingtd
(R2 - 2Rr cos 9 + r2)3/2
J0
91 d q2.
Passing to the variables 0 and A and taking the formulas (7.1.58), (7.1.59) and the periodicity of the function cos A into account, it results 3
'P = - 4 R 3cos ql0
fW sin O cos 0(R - r cos 9) (R2
J
- 2Rr cos 0 + r2)3/2
Performing the change of variable 0 -+ u : it = (R2 - 2Rr cos 0 + r2)1/2
we deduce
f
x sin0cos0(R -
Jo (R2 - 2Rr cos 0 + r2)3/2 d and finally, (7.1.64).
6
2
- - 3r2
d0,
268
I3IEM. THREE - DIMENSIONAL AIRFOIL
7.2.3
The Velocity Field
Since the potential has the expression (7.2.14) we deduce:
v(t) = grade = - 4 Jj;(x)gracI£ 47r
n(x)] d a =
L lx - 41
l I µ(x) (n grad) 1 Ix -
X12
Ida
and finally
vW =
4zr !
j1`(x) [n(x) - 3(x - ,)(IX -
I2nl
Ix - 413
(7.2.15)
This formula gives the velocity field in the fluid. We deduce that far away
the kernel has the order I4I-3, as it is natural to be (see for example (6.1.16) from 11.11]). On the boundary of the body, the integrals from (7.2.15) have strong singularities. We have therefore to transform these integrals.
7.2.4
The Velocity Field on the Body. N. Marcov's Formula
In the beginning we have to notice that the double layer potential of constant density equal to 1 defines a piecewise constant function whose gradient is obviously zero in the continuity points. Indeed, from (7.2.1) it results: 1
1,
fr
x 1 t)
TT(1)da=
1/2, 0
4ED E
(7.2.16)
EE,
and for the gradient we have 1
4n
ff n(x) - 3(x -)
da
Ix - tp2 ] Ix - CI3
(7.2.17)
in E (and D). Multiplying this identity by the constant jt(xo) and subtracting it from (7.2.15), it results
J
P( X)
!t(xo)
Ix-EI
- n n-3(:c-F) (xIx-412
da
Ix-EI2
(7.2.18)
TILE SECOND INDIRECT METHOD (DOUBLET DISTRIBUTIONS)
269
for AI(D) in E.
For calculating the velocity when AI(F)
Qo(xo), a point on the boundary E, we shall denote again by or the portion cut from E by the sphere with the center in Qo and the radius s and we shall use the definition of Cauchy's principal value lim
JJa-
JJE
(7.2.19)
if it exists. With no the outward normal in Qo, we put t = xo +qno (q > 0). For the limit value of the velocity in this point, we have: =bin
tje(xo) = 1-0 v(xo + qno) = It + 12,
(7.2.20)
for every F > 0. We denoted
11 = lira
1 if
ti--o 47r
-3(x I2
no4r
12(x) -11(xa) _o
x - 41
da
j
Ix - 412
Ix _ X12 ' (7.2.21)
11 !l( Ix -
4Ixa) [n-
-3(x-4) (x - t) - n
da
Ix-XI2,
Ix-£12
where = xo + q no. The first limit and the integral may be interchanged because the integrand has no singularities on E - a. Hence
one obtains 1t
=
/e(x) _ 14(x0)
1
47r
E-o
Ix - xol
[n (7.2.22)
(x - xo) n Ix-xo12
da ix-x012
For every e > 0 this integral exists if µ(x) satisfies Holder's condition. So, we deduce v(xo) = Jim (1) + 12) = w(xo) + link 12 ,
(7.2.23)
270
RIEM. THREE - DIMENSIONAL AIRFOIL
where
w(xo) =
1
Jf_
/L(x) - JL(xo)
Ix-xol
-3(x - xo)
L
(7.2.24) J
Ix - xo12
da IX - X012
For calculating the last limit from (7.2.23), when s is small enough,
we may replace a with its projection A on the tangent plane in Qo and we shall utilize (7.2.17). It results that we have
x - t = r(cos Oio + sin Ojo) - i'no,
Ix
- t12 = r2
+.q2
,
(7.2.25)
µ(x) - /&(xo) = (V /)(x0) ' (x - xo) + ... _ = rvp(xo) (CDs NO +Sill 8jo, where V1z(xo) = (V/c)(xo), according to the usual notation in Analysis. Considering the scalar product Vy - (cos Bin + sin Ojo) ,
in the basis io,)o we obtain the identity [V -(cos Oio + sin 8jo)](cos Oio + sin 8jo) =
= [(Viz io)cos8+ (V/z jo)sinO](cos8io + sinOjo) = (7.2.26)
= (Vp - io)(cos2 Oio + cos8sin 6jo)+
+(Vp . jo)(sin Ocos 8io + sine` 0jo) .
Noticing that some terns vanish after integrating with respect to 0, from 12 it remains 3 12
t
2-x
r- 0 47 r Jo JO
r3)?
(r2 + i,2 )5/2 X
(Qµ io) x (cost 8io + cos O sin 8jo)+
drdO,
x
+(QJJt jo) x (sill 8 cos 8io + sine 8jo)
I2 = lim 4
J'
(r2 r3'1
[(VJt - io)io + (ViA - ?o)7o)Id r .
't'ilt: l)IRECT ME IIOI). THE INCOMPRESSIBLE FLUID
271
One obtains (Vi)(xo) in the square bracket and we take it off from the integral. So, t I., =
r3
17
(r2+ 2)b/2dr=
Op(io)
Hence. taking (7.2.23) into account, we obtain the velocity on E by ineans of the formula
v(xo) = 2(V1)(xo) + w(xo),
(7.2.27)
w(xp) being given in (7.2.24). This formula was obtained by N.Markov in a unpublished paper. Since P(x) and Qo(zo) from (7.2.25) belong to the plane which is
tangent to r in Qo, we deduce that Vp(zo) is in the tangent plane. Hence, the boundary condition
(i+v).n=O pe E determined the following integral equation: 1
-1s(xo) f Fi(x) Ix - xol
4A E
da =-n=, VxoEE -3(x-xc) no Ix-moll Ix-xo12 which is an alternative to (7.2.8).
7.3 7.3.1
The Direct Method. The Incompressible Fluid The Integral Representation Formula
For writing this subsection we used the paper (7.3]. Since we study the same problem like in the previous subsections, we shall utilize the repre-
sentation (4.6.1). the equations (4.6.2), the boundary condition (4.6.3) and the condition to infinity (4.6.4). The difference is now that the prob-
lem is three - dimensional. In (4.6.3), C will be replaced by E, the surface of the perturbing body B. For avoiding the singular integrals, we shall replace the equations (4.6.2) by the equations
div(v-c)=O, rot(v-c)=O,
(7.3.1)
272
BIEM. THREE - DIMENSIONAL AIRFOIL
c being a vectorial constant. The system (7.3.2) div v' = 6(x - xo) , rot v' = 0 for every point xo E D + E, D representing the domain occupied by
the fluid (the exterior of the body B), defines the fundamental solution V* =
x - xO 41rIx-x013 1
(7.3.3)
From the equations (7.3.1) we deduce the identity
4,
[ f div (v - c) + g rot (v - c))d v = 0
(7.3.4)
for every two functions, or regular distributions, f and g. We denoted by Do the exterior of B, bounded by a sphere S(O, R), R being great enough, such that the body B is included into the interior of the sphere. Utilizing the identity (4.6.9)1 and the identity
rot [g x (v-c)]
(7.3.5)
and applying Gauss's formula, from (7.3.4) we deduce
( v - c) (grad f - rot g)d v = (7.3.6)
(v - c) (fn - (n x g)id a, E
n being the outward pointing normal on Do. Substituting successively
(f, g) -' (7 - v*, -9 x VI)
(7.3.7)
we find the projections on the axes of coordinates of the following identity:
J (v - c)div v'd v = LER {n (v - c)v' + [n x (v - c)] x v' }d a , Do
xoEDo+E (7.3.8)
273
THE DIRECT METHOD. THE INCOMPRESSIBLE FLUID
proving in this way that it is correct. Taking (7.3.2) into account, it results
V(x0) - c = f
{n (v - c)v* + [n x (v - c)j x v' }d a .
(7.3.9)
+ER
The integral on ER may be written as follows
v)v+ (n x v) x vjd a - hR
c)v' + (n x c) x v*] d a .
IS,,
T he first term vanishes when R
oo, because of the condition
(4.6.4). For calculating the second term we use the spherical coordinates: R, 9, cp:
x = R sin O cos V
y = R sin O sin p
0<9<7r.
z=Rcos9, We obtain
lim. JR [(n c)v' + (n x c) x v')d a = C 47C
f
0
2A
f
A
sin 9d 9d W = c.
0
Now, the representation (7.3.9) becomes
v(xo) =
j{n
(v - c)v+ [n x (v - c)] x v}d a ,
xoED+E. Setting c = v(xo) = vo we obtain the representation formula V(x0) =
j{n. (v - vo)v* + [n x (v - vo)) x v' }d a
.
(7.3.10)
This is a regularized representation, valid both for xo in D and for xo on E. Obviously when xo E D, the integrand has no singularity. This property is also valid when xo E E because of the factor v - vo which vanishes for x -- xo. This representation formula is fundamental [7.1j. Utilizing the boundary condition (4.6.3), the formula (7.3.10) becomes
vo=1 E
(v-vo)) x v*}da.
(7.3.11)
274
7.3.2
RIEM. THREE - DIMENSIONAL AIRFOIL
The Integral Equation
The vector
F- nxv
(7.3.12)
which intervenes in the surface circulation
C= J nxvda.
(7.3.13)
E
introduced by Pascal and utilized again by R.von Mises 11.271, [1.20], has a great importance herein. We shall deduce the equation for P. To this aim we write the formula (7.3.11) as follows: (7.3.14)
vo =
After the vectorial multiplication by no one obtains
Fo = J[_(nz + n - vo)(n° x v') + (n° v')F(7.3.15)
-(n° F)v - (n v')Fo + (vo . v')(n(' x n)ld a. But, from the boundary condition n v = -it, and from (7.3.12) we
deduce v = -nxn - n x F such that n - vo = -non ' no - (n, n°, Fo)
(v' vo)(n° x n) = -n°(v` n°)(n° x n) - (n°, Fo, v*)(n° x n). (7.3.16)
One obtains therefore
Fo = J(._(ni - nn n°)(n° x v°) + (n, n°, Fo)(n° x
+(n° v')F - (n° - F)v' - (n v')Fo-n°(v' n°)(n° x n) - (n°, Fo, v)(n° x n)Jd a . Utilizing the double vectorial product formula
(UxV)xW
(7.3.17)
275
THE DIRECT METHOD. THE INCOMPRESSIBLE FLUID
it results
(n, n°,
x v°) - (n°, Fo, v*)(n° x n) _
= no x ((n°, Fo, n)v' - (n°, Fo, v')nJ =
(7.3.18)
= no x [(n x v') x (n° x Fo)J = -(no ,n,v')(no x Fo). Hence, the equation (7.3.10) becomes
F°+
J,
[(n° F)v' - (n° v')F + (n v')Fo] d a+
+ no x Fo) f (n° x n) v'd a = j {n(v" n°)(n x n°)+ + (7.3.19)
this representing the integral equation of the problem. This is a regularized equation. The integrals are not singular. Although the denominators of the distribution v' vanish for x -+ x°i we have to take into account that in these points the numerators vanish too. Indeed,
no -.0,
7.3.3
Kutta's Condition
In the sequel we shall study the flow around lifting bodies (with smooth surfaces). In order to solve this problem, the classical theory, beginning with the lifting line theory (Prandtl 1918), introduces a vortical surface behind the body. In this way the flow in no longer irrotational in the exterior of the body, hence the above solution cannot be utilized. For defining the fluid How with the aid of the solution given herein, we shall consider a discrete distribution of vortices located in certain points from the interior of the body [7.3]. In this way, the external flow remains everywhere irrotational and it will be characterized by the solution given herein. Nloreover, the circulation C defined by (7.3.13) does not vanish on the trailing edge. It remains to discuss the location of the vortices. The Kutta-Joukowskicondition concerning the continuity of the pres-
sure on the trailing edge will be imposed, like in the two-dimensional
BIEM. THREE - DIMENSIONAL AIRFOIL
276
case, writing that the velocity in plane cross-sections, perpendicular to
the trailing edge, is continuous when P, and P, - Pf (4.6.21). Considering in figure 7.3.1 the point P, and the local frame n, a and
Fig. 7.3.1.
(3 = n x s and knowing that V = V,s, we deduce
n x V = V,/3.
(7.3.20)
Hence, the vectorial form of (4.6.21) is:
(n x V)(P,)+(nx V)(P,)-o 0 (7.3.21)
P P; - PI.
Taking into account that V has the form (4.6.1) it results the condition
(7.3.22)
<¢>=q(P,)+ b(P.).
(7.3.23)
with the notation
7.3.4
The Lifting Flow
One knows from the theory of the two - dimensional potential in compressible flow that the lift is generated by a vortex of intensity rk placed in a point from the interior of the body. For example, in the case of the flow past the circular obstacle with the center in ;.o (see [1.11) p. 117), the potential Ua, f(z - zo)e-io +
l
R2 _
Z-20
1l
et° I
characterizes the non-lifting flow and the potential
r
27ri
In (z - zo)
277
THE DIRECT METHOD. THE INCOMPRESSIBLE FLUID
defines the lifting flow, the lift being -pU,:1'. According to this model,
we shall try to generate the lift by means of some vortices from the interior of the body, the number of vortices being determined by the number of pairs of panels adjacent to the trailing edge for which we have to write Kutta's condition (7.3.22). To this aim we need at first the velocity field w' generated by a vortex line of constant intensity r. This will be determined by the system div w' = 0,
rot w' = r6(x) ,
(7.3.24)
w' being a distribution (for this reason it was marked by *).
For
determining the solution we apply the Fourier transform, like in the case of the system (7.3.2). Using the formulas (A.6.5) we deduce
axiv'=ir, whence, utilizing (A.6.9),
w'=rx(-
w' =rxVF-'
2
and then (A.7.10) and (7.3.3)
w` = v' x r.
(7.3.25)
If the vortex is located in the interior of the body, in a point having the vector of position xi, then
w(x) = v'(x - xi) x r,
(7.3.26)
and if there are L lines, since the equations (7.3.24) are linear, it results L
w'(x) = E v'(x - xk) x rk .
(7.3.27)
k=i
Returning to our problem and considering, for the sake of simplicity, a single line, we shall write the formula (4.6.1) as follows:
V=U_ (i+w'+v).
(7.3.28)
From div v = 0 and rot r = 0, taking (7.3.24) into account, it results
div v = 0, rot v = -ri(x - xh),
(7.3.29)
278
BIEMM. 'THREE . DIMENSIONAL AIRFOIL
and the equations (4.6.5) will be replaced by
div(v-c) =0 rot(v - c) = -ra(x-xl).
(7.3.30)
The identity (7.3.4) will be written as follows: Joo
[fdiv(v-c)+g.rot(v-c)]ctv=
,xl E D° ,x1 D°.
0
(7.3.31)
Since the point having the vector of position xl is in the interior of the body, we shall obtain a second equality identical to (7.3.4), such that all the consequences follow like above. We have therefore (7.3.10). From the boundary condition v - n = 0 we deduce (7.3.32)
such that the formula (7.3.11) becomes
vo=
R
xv'}da (7.3 .33)
xoED+E. The relation between v and F is now
v=-(n,, +wn)n-nxF,
(7.3.34)
and the integral equation (7.3.19) becomes
Fo+
JN
[(n° - F)v* - (n° - v')F + (n v')Fo]da+
+ (n° x Fo)
x n) v'd a + wn(xo)
I [(n° v')(n° x n)-
-(n°.n)(n° x v`)]da+J wn(x)(n° x v')da = E
= f, { n2(n° v*) (n x n°) + [n0. (n - n°) - n.,] (n° x t
v')}da, (7.3.35)
where, taking (7.3.27) into account, we have:
wn(xo) _ I no x v'(xo - xi)] r (7.3.36)
w,,(x) = [n° x v(xo - xi) ] . r. L
THE DIRECT METHOD. THE INCOMPRESSIBLE FLUID
279
In (7.3.35) the dependence of F and r is linear. In the case of L vortices, the equation (7.3.35) remains unchanged and the expressions (7.3.36) become L
Wn(x0) _ F [no X v'(x0 - xk)] r 11
k=1
(7.3.37) L
W4(z) _ E In X v'(xo k=1
- xk)1
r.
In equation (7.3.34), F, r1i rL are unknown. For specifying the conditions (7.3.21) we shall write the product n x V as a function of the principal unknown F. From (7.3.28) and (7.3.34)
it results
nxV=Uoo(F+nzj-nyk).
(7.3.38)
The condition (7.3.21) will be written as follows 0
F + (nx -ny
0
(P,) +
[F+ (n,
(P;) = 0,
(7.3.39)
-ny
for every pair of panels from the trailing edge. It will result therefore L equations. These ones, together with the equation (7.3.35) discretized below, will determine the solution F, F1,... , r,. The numerical results are more accurate when the points P, and P; are closer from the corresponding point Pf from the trailing edge (see [7.31, p. 364).
7.3.5
The Discretization of the Integral Equation
Like above, one approximates the surface of the body by N panels (triangles and quadrilaterals) and we approximate on every panel III
the function F by the constant value F,,, that it has in the center G, (x9) (the collocation method). If we impose to the equation just
obtained from (7.3.35) to be verified in all the centers G,(x°) and we denote
X;;=J v'(x-x°)da
(7.3.40)
280
BIEM. THREE - DIMENSIONAL AIRFOIL
we deduce, for i = 1 N 1
Fi+ L.. [(ni Fj)Xji - (iii X ji)Fj + (nj Xji)Fi] + j=1
N
L
+ (ni x Fi) J(ni x nj) Xji + j
[(ni x x;k) . rk]' k=1
1
[(ni x nj)(ni Xjj) - (ni x X ji)(ni ' nj)] + E j=1
[(nj x xjk) rk] (ni x xji) =
+ j x1 k=1
{
(7.3.41)
- ni(ni.
,j=1
X ji)(ni x nj) + {n(rsi.nj)_n}(ni x Xji) }, In this system, the singular terms Xii disappear, because the integrals from (7.3.35) are regularized. Taking into account the relations
(nj Fj)X3i - (ni ' Xji)Fj = ni x (Xji x Fj)
(ni nj)X ji - (ni Xji)nj = nj x (Xji x N), we deduce that the system (7.3.41) may be written as follows N
L
LA,,F,f+EBk{lrk=Ci, i= 1,...,N j=1
(7.3.42)
k=1
where
AiiFi = Fi+FnEnj Xji+(ni x Fi)E(ni x nj) Xjie j#i
j#i
AijFj = ni x E(Xji x Fj), j#i Bki?rk = [rk(na x Xik)j
E(ni Xji)(ni x nj)+ ;oi
+ > {r. j#i
[ - (ni x Xik)(ni nj) + nj X Xjk] }(ni x Xji), 1
THE DIRECT METHOD. THE INCOMPRESSIBLE FLUID
281
Ci= nixE[n (njxXji)xn1-n Xji! i0i the unknowns being F1,... , FN,
r1, .... r1. To this system of N
equations, we add the equations (7.3.39) written for every pair of panels
adjacent to the trailing edge. The number L of vortices equals the number of pairs; in this way, the number of (N+L) equations obtained from (7.3.42) and (7.3.39) equals the number of unknowns F1,... , FN,
rl,... , ri.
For calculating the coefficients Xji (7.3.40) one utilizes either the quadrature formulas (for example, the Gauss-type formulas), or the analytical formulas given by Hess and Smith in [7.10]. Denoting by x, =21, x23, (24) the vectors of position of the vertices of the panel lIl which is a triangle (or a quadrilateral), with the definitions
Vill
- y)2 + ( k+1 - 4)2
(xik)2+(yiyk)2+ (Z, -k)2,
Tk= mk,k+1 =
'.)I + (yll +
(k+1
dk,k+1 =
+1 -
, ek = (xi-2'k)2+(zi-k)2 , hk = (xi-
)2(Yi-yk)2 ,
k
the formulas of Hess and Smith are
Xji = (Xji,Yji,Zji), +1 - Ylk
Xji =
dk,k+l
k=1
Yji = -
3(4)
-4+1
4s k=1 4 = -
-
` k In rk + rk+i - dk,k+1
dk'k+l
rk + rk+1 + dk,k+1
3(4)
1
41r
rk + rk+1 + dk,k+1
arctan
k=2
'mk,k+lek - hk (zi
-arctan mk,k+1 + ek+1 '- hk+1 (zi - k)rk+1 k)rk
In fact, Hess and Smith deduced the formulas assuming that the panels IIj are situated in planes parallel to xOy (4 = 0). An example is presented in [7.3].
Chapter 8 The Supersonic Steady Flow
8.1 8.1.1
The Thin Airfoil of Infinite Span The Analytical Solution
In this subsection we study the same problem like in 3.1. The only difference is that the unperturbed flow is assumed to be supersonic (M > 1). Hence the uniform flow, having the velocity Ui, the pressure p,. and the density p,, is perturbed by the presence of an infinite cylindrical body. The xOy reference plane represents a cross section and the leading edge is the origin of the axes of coordinates. The length of the projection of the airfoil on the direction of the unperturbed stream (which does not always coincide to the length of the chord) will be taken as reference length (fig 8.1.1). Utilizing the coordinates defined
Fig. 8.1.1.
by (2.1.1), we shall denote the equations of the profile determined by the xOy plane
y = hf(x),
(8.1.1)
284
THE SUPERSONIC STEADY FLOW
the functions h..(x) being defined on the interval
(0, 1J
and and
possessing first order derivatives. Taking into account the formulas (2.1.3), we deduce that the perturbation (which is obviously steady), will be defined by the system (2.1.32) and by the boundary conditions (2.1.33). From this system, taking into
account that the perturbation is plane, it results:
u = -p, v= + py = 0, M2pz + ut + vy = 0 ,
(8.1.2)
whence one obtains
k2vtt - vyy = 0,
(8.1.3)
with the usual notation k = M - 1. The boundary condition (2.1.32) becomes
v(x,±0)=ht(x), 0<x<1,
(8.1.4)
and the damping conditions at infinity lim (p, u, v) = 0.
(8.1.5)
The equation (8.1.3) is hyperbolic and the families of characteristics C+
and C_ are defined by the equations
x-k-y=c+, x+ky=c_.
(8.1.6)
Obviously, the first family consists of parallel half-lines which make the
angle µ with the Ox axis, the second consists of parallel half-lines which make the angle -µ with the Ox axis, where tan p
=1 (sins =
,
oos p =
(8.1.7)
For determining the characteristics passing by a certain point, we write that the coordinates of the point verify the equations (8.1.15) and and then we determine the constants c+ and c_. For example, the characteristics detaching from the leading edge have the equations x - Icy = 0 and x+ky = 0. We assume that the profile is in the interior of the angle having the opening 2µ which is determined by these characteristics. It is well known that the equation (8.1.3) has the general solution
v(x, y) = F(x - ky) + G(x + ky),
(8.1.8)
such that from (8.1.2) and (8.1.5) it results kp(x,y) = F - G
(8.1.9)
ku(x, y) _ -F + G.
'I'III: TIIIN AIRFOIL OF INFINITE SPAN
285
'I'll(- function F is defined on the characteristics from the superior half-plane, and the function G on the characteristics from the inferior half-plane. We have in view the characteristics detaching from the segment [0, 1) which replaces the profile that represents the source of perturbations. The solution from the strip I will be determined by F(x - ky) which will be denoted by F+(x - ky) and the solution from the strip II will be determined by C(x + ky) which will be denoted by F_. (x + ky). Hence the solution has the shape
vf(x,y) = FF(xT ky), kpf(x, y) = ±F±(x T ky),
(8.1.10)
ku±(x,y) = T Ff(xT ky), the upper sign corresponding to the solution from the y > 0 half-plane and the lower sign to the solution from the y < 0 half-plane. In fact one may demonstrate that if upstream of AOA' the flow is not perturbed, then the solution of the equation (8.1.3) has necessarily the forum (8.1.10). Indeed, if the assumption is true, it means that OA and OA' are lines of discontinuity where we have to impose the jump relations (1.3.8), (1.3.9) and (1.3.10) Op1V1nO = 0,
Opl'IVln +P1nO = 0,
(8.1.11)
with the notations (2.1.1) and (2.1.3). Taking into account the order of magnit.ucle of the perturbations, by linearization it results
=0, Ovn,, +pnO =0.
(8.1.12)
On the line OA we have n = (sin p, - cos µ). Taking into account that in front of OA and OA' the perturbation vanishes, from (8.1.12) we obtain:
0=using-vcosa+psina (8.1.13)
U=vsina - pcosa, the relationships being imposed on the line x = ky. Replacing here u, v and p given by (8.1.8) and (8.1.9) and taking (8.1.7) into account, from the second condition we find C = 0. Since in the linear steady theory we have p = M2p, it follows that the first condition is identically verified.
In the sauce way one demonstrates that in the zone II v = G(x + ky). Hence the solution of the equation (8.1.3) has the form (8.1.10).
286
THE SUPERSONIC STEADY FLOW
Imposing the boundary conditions (8.1.4), it results
F±(x) = 14(x).
0 < x < 1.
(8.1.14)
These relations determine the functions F±(x) on the segment 10, 11. In the exterior of this segment we take F±(x) = 0 because v and p are continuous functions on the Ox axis in the exterior of the segment [0,11 (it results from (8.1.12), setting n = (0, 1)), such that F+ = F_, F+ = -F_. Hence the perturbation zones are I and II. For c E [0, 1], on the half-line having the equation x - ky = c we deduce: v(x, y) = h+(c), and on the half-line x + ky = c
kp(r, y) = h+(c),
(8.1.15)
(8.1.16) u(x, y) = h' (c), kp(x, y) = h' (c) . Along a characteristic, the velocity and the pressure take the values that they have in the point where the characteristic intersects the segment [0,11.
In the sequel we shall prove that all these results may be obtained directly with the fundamental solutions method, as we could expect, taking into account that this is a global method.
8.1.2
The Fundamental Solutions Method
We know that. the perturbation produced in the uniform stream hav-
ing the velocity Ui, the pressure p,., and the density po, by a force density (fl, f2) uniformly distributed along an axis which is parallel to Oz and intersects the xOy plane in the point of coordinates (F, 0), is given by the formulas (2.3.30) and (2.3.31). Replacing the profile from figure 8.1.1 with such a density applied on the segment [0, 1) from the Ox axis (i.e. on the strip whose cross sect ion is the segment [0, 1] from the Ox axis), the perturbation will be given by the formulas i
2kp(x, y) = in [ - fl(E) + kf ()sign y] b(xo - klyl)d (8.1.17)
2v(x, y) =
J0
[
- fl ()sign y + k f
6(xo - klyl)d
Taking into account the property of the distribution
f
f (t)6(x
- )d
=
f (x), 0,
if:
ifx E (a, b) ifx E C(a, b),
(8 . 1 . 18)
287
THE THIN AIRFOIL OF INFINITE SPAN
we deduce that if x - klyl = c E (0,1), then we have: 2kp(x, y) = -ft (c) + k f (c)sign y (8.1.19)
2v(x, y) = - f, (c)sign y + k f (c) .
Conversely, if c E C(0,1), then p = 0, v = 0. The set of points for which x - kly) = c determines the characteristic half-lines
x f ky = c
(8.1.20)
which detach from the point x = c belonging to the segment (0,1). On these half-lines, the pressure and the velocity have constant values, equal to their values in c.
8.1.3
The Aerodynamic Action
From the representation (8.1.10) we deduce that the jump of the perturbation pressure on the profile
p(x, -0) - p(x, +0) is given by the formula
kOP1 = -[F+(x) + F-(x)] = -[h+(x) + h'-(x)]
(8.1.21)
which results from (8.1.14). In this way, the lift and moment coefficients CL
=
L
CM =
(1/2)po,U2Lo'
M (l/2)poU2Lo'
(8.1.22)
are given by the formulas CL = - 2 1'[W+ (x) + h'_ (x)Jd x CA! = -
2
k
(8.1.23)
rx[h+(x) t
+ h'(x)]d x
the moment M being calculated with respect to the origin of the axes of coordinates.
We notice from the formulas (8.1.10) and (8.1.23) that the linear theory cannot be applied in the vicinity of the value M = 1(k = 0).
288
THE SUPERSONIC STEADY FLOW
As a first example, we shall consider again the case of the flat plate having the angle of attack e with E < y (fig. 8.1.2). Since the equation of this profile is y = -Ex, we deduce h.4. = h' = -E whence
v = -E, ku = ±e,
kp = T- e,
(8.1.24)
the total velocity and pressure being A
Pig. 8.1.2.
vl
U [CI± ) i - Ej]
P1 = poc
,
_T P00U2 k
.
(8.1.25)
For CL and cM we obtain cL =
4e ,
T
2s CM=T.
(8.1.26)
These formulas have been obtained for the first time by Ackeret in 1925. The torsor of the aerodynamic forces reduces to a lifting force L, applied in the middle of the chord of the profile, force which tends to rotate the airfoil in the trigonometric sense. The graphic representation of the function cL(M) (fig. 8.1.3) shows
that the linear theory is not valid in the vicinity of the value M = 1, because the lift cannot be infinitely great. One estimates that the validity of this theory begins from approximately M = 1, 2 and finishes to approximately M = 2, 5, because the lift cannot be extremely small.
For the zone M = 1(0,8 < M < 1,2) one elaborates the theory of transonic flow (see Chapter IX), and for M > 2, 5, the theory of hypersonic flow.
289
THE THIN AIRFOIL OF INFINITE SPAN
CO
O Fig. 8.1.3.
8.1.4
The Graphical Method
This method relies on the following fundamental theorem: in every point the perturbation velocity is perpendicular to Mach's line (the characteristic line) which is passing through that point. The demonstration results at once if we take into account that the characteristic lines have the versors i of coordinates (cos p, ± sin µ) and we utilize the representation (8.1.10) and the formulas (8.1.7). Indeed, we have
v-if=uoosµfvsinµ=
kF*
±Ftj=0.
(8.1.27)
Let us show for example how we can utilize this theorem for obtaining the graphical representation of the perturbation in the case of the flat plate. We consider at first the region I from the 8.1.2. In an
arbitrary point M from OA we draw the vector MP = Ui and a vector V1 parallel to the plate and having an arbitrary magnitude; the perpendicular on OA which passes through the vertex P of the vector
Ui determines the magnitude of the total velocity V 1 = MQ; the perturbation velocity Uv is given by the vector PQ. For determining the perturbation velocity from the region II, in a certain point M' from OA' ones draw the vectors M'P' = Ui and V'1, the last being parallel to the plate and having the magnitude unprecised yet; drawing from P (the vertex of the vector Ui) the perpendicular line on OA' we determine the vector V' = M'Q' and then the perturbation
Ua,v=P'Q'. Beyond FB and FB' the flow becomes again parallel to Ox. One knows the non-linear solution of the supersonic flow past a convex dihedron(the Prandtl-Meyer fan). See for example [1.21], [1.34). In the framework of the non-linear theory, the velocity which is parallel
290
THE SUPERSONIC STEADY FLOW
to Ox before OA , becomes at last parallel to the plate, crossing the Prandtl-Meyer fan. In the framework of the linear theory this fan is reduced to the half-line OA.
8.1.5
The Theory of Polygonal Profiles
In the case of polygonal profiles, the solution may be easily determined starting from the solution for the flat plate. The solution, which obviously is piecewise constant, may be analytical, graphical or mixed.
Ui
Fig. 8.1.4.
We shall consider at first the profile from figure 8.1.4 (E < p) with and e1CO8E1 + e2COSE2 = 1. According to the linear theory, the last relation will be replaced by el + t2 = 1. From the formulas (8.1.14) it results
OP = el, PQ = e2
F+=-El, 0
f1COSE1^'e1 <x<1,
(8.1.28)
FI=E, 0<x<1. We deduce, k Up0 =
E+E1, C + E2,
(8.1.29)
291
THE THIN AIRFOIL OF INFINITE SPAN
whence CL =
I(e+E1e1 +E2e2), CM =
a
kE2(1- e,).
(8.1.30)
Further we shall determine the pressure in different zones starting from the solution for the flat plate. Taking (2.1.3) and (8.1.24) into account, we deduce in zone I that P1 = Poo - POQU2
k
.
(8.1.31)
In zone II we take into account that the deviation with respect to the direction of the uniform stream from zone I is 62 - E1. Using again the formula (8.1.24) it results P2=PI-PI
V
(8.1.32)
Using the formulas (2.1.3), we deduce P1V2 = p ,,,,U2 +... Taking into account that the factor (E2 - E1) has the order of magnitude of the perturbations, in the framework of the linear theory we have to retain E E E P2=P1-Po,U2 2k 1 =Poo_PooUT
In zone III we have: p3 = poo +
po0U2
.
(8.1.33)
(8.1.34)
For the jump of the pressure we get the formulas (8.1.29). In fact the formulas (8.1.33) and (8.1.34) coincide with the formulas given by the analytic method. We shall calculate now, in a different way, the resultant of the pressure on the wing. The perpendicular to the plate OP oriented towards the body has the director cosines
nl =
coos (El +
2) , - sin (El + 2 )) _ (-E1i -1).
(8.1.35)
In the linear approximation, the perpendicular to the plate PQ has the director cosines (-E2, -1), and the perpendicular to OQ pointing towards the body (e, 1). Hence the resultant of the pressure is R = (pit, n 1 + p2e2n2 + p3n3)Lo
(8.1.36)
We took into account that the real lengths of the plates are I, LO, 12L0, L0.
For the lift we obtain the formula 2
L = Ry - paoUk'0(e+f1e1 +E2e2).
(8.1.37)
292
THE SUPERSONIC STEADY FLOW
In the framework of the linear theory the drag (8.1.38)
R. = (E - 1191 - e2E2)LoPoo
vanishes because, from the projection of the contour OPQ on the Oy axis we deduce E = 11E1 + 12E2
In fact this is a known result. The drag has the order of magnitude two CD =
2 (92 + E1t + 6212) k
(8.1.39)
In the sequel we shall consider the polygonal profile from figure 8.1.5,
symmetric with respect to the OR axis. We assume that all the E-s are small. Obviously, the profile is considered to be in the interior of Mach's angle with the vertex in the origin. We deduce like above that in zone I the pressure is given by the formula P1 = Poo +
p00U2
(8.1.40)
E,
in zone II by the formula
86
Fig. 8.1.5.
k E2
p - p00U2
,
(8.1.41)
P3=Pa-PzV2E3 kE2 =Poo-PooU2k ,
(8.1.42)
P2 = P1 - P1VzE1
k
in zone III by
293
THE THIN AIRFOIL OF INFINITE SPAN
in zone I', P1
=Poo+p00U2!1
,
Ei = 2E+e1,
( 8.1.43)
in zone IF, -P'1V1' k
Ps=Pi
=Poo+p,,U2k2,E'2=2E-E2
(8.1.44)
2kes"'p.-.U2k3,E's=ES-2E
(8.1.45)
and in zone III', P'P2P',Vi2C1
We denote by n 1, n2, n3, n1, n; and n3 the perpendiculars to OP, respectively PQ, QR, OP, P'Q' and Q'R pointing towards the body. In the framework of the linear theory they will have the coordinates
(E1,-I),(-E2r-1),(-E3,-1),(es, 1),(E'2,1) and (-E'3i1). The resultant of the pressure is
R = Lo(£1pini + t2P2n2 + 13p3n3 + tlp/ini + t21/2ns + tsp3n3)
.
(8.1.46)
The lift is
p _ Poo 2 Lo
[6 (E' - E1) + 12(C'2 + E2) + t3(E3
- 6'3))
.
(8.1.47)
Taking into account El, c'2, r'3, and the relation t1 + t2 + t3 = 1 , we deduce CL =
(8.1.48)
In the framework of the linear theory, the drag Rt = 2p ,Lo(E + t1E1 - t2E2 - t3e3)
(8.1.49)
vanishes, because from the projection of the polygonal contour ORQ'P'
on the Oy axis we deduce E = titJl + t2bJ2 - tstJ3
(8.1.50)
whence, taking into account the expressions E'1, E12, E13 we get
E + ties - t2E2 - 1363 = 0.
The formula (8.1.39) is very important. It shows that cL has the same expression like in the case of the wing consisting only of its skeleton OR. The result is natural, because of the symmetry of the wing with respect to OR.
294
THE SUPERSONIC STEADY FLOW
8.1.6
Validity Conditions
We shall investigate, for the flat plate, the limits of validity of the linear theory. Since the flow is defined by the formulas (8.1.25) in I and II (fig.
8.1.1) and by Vt = Ui, pt = p in the regions upstream of AOA' and downstream of BQB', we find that pi < pil and pi < p,,. Hence, in order to have a positive pressure all over the fluid (this is a physical condition), we must have (8.1.51) Pi > 0, this representing a first condition of validity. Taking into account the
expression of pf given in (8.1.25), we deduce, with the notation kX = = M2e,
0
(8.1.52)
A second condition must ensure us that the flow is everywhere supersonic. Since from (8.1.25) or from Bernoulli's integral it results IVtlf'2 < (Vt1 12, we deduce that we must have ( 1)2 < (V ')2, whence
'7Pf'/pfl = (cl'2 < U2 [(i - k)2 + x,2]
.
(8.1.53)
Taking into account that in the framework of the steady linear theory we have p = M2p (it results from (2.1.7)), we deduce the inequality
11+X equivalent to
k)2
<M2 (1
+s2,
1 +yX < (1+X)(M2 - 2X + X2).
(8.1.54)
(8.1.55)
In the linear approximation with respect to e, this inequality becomes
1-M2<(M2-2--y)X.
(8.1.56)
Further we shall deal with the inequalities (8.1.52) and (8.1.56) when
the fluid is the air ('y = 1, 405). For M2 < 3,405, the two inequalities are satisfied in the shaded region from the (M2, X) plane (fig. 8.1.6), where M2 - 1 2 f (Af 2) = 3,405 - M
(8.1.57)
295
GROUND AND TUNNEL EFFECTS x+
0.711
............. ......... ........... ............
0 Fig. 8.1.6.
This result shows that the linear theory is valid only in the zone 1 < M2 < 2. For a certain value given to M2 in this zone, E is subjected to the restriction (M2
e<
- 1)3/2
M2(3,405 - M2)
(8.1.58)
The last ratio increases when M2 increases, hence the superior limit of the angle of attack is increasing with M2. Other results concerning this subject are given in [8.17] [8.32].
8.2 8.2.1
Ground and Tunnel Effects The General Solution
We assume now that the wing lies between two parallel planes having the equations a
y=-2 and y=Z
(8.2.1)
In this case, the general solution (8.1.8) and (8.1.9)
ku(x, y) _ -F(x - ky) + G(x + ky) v(x, y) = F(x - ky) + G(x + ky)
(8.2.2)
P(x, y) = -u(x, Y), with the damping condition
lim F(x - ky) = lim s--00 x--ooG(x + ky) = 0,
(8.2.3)
296
THE SUPERSONIC STEADY FLOW
has to satisfy besides the slipping conditions on the profile, v(x, ±0) = h4 (0),
x E [0,1] ,
(8.2.4)
the slipping conditions on the planes
,-a) = 0,
v
v
(x, 2 1 = 0,
x E R.
(8.2.5)
We assumed that the equations of the profile are
y = ht(x)
(8.2.6)
In the sequel we have to calculate the velocity field in the domain
D-={(x,y):x+kyE[0,1),0>y>-2}.
(8.2.7)
We consider the natural number n such that nka < 1 < (n+ 1)ka and the segments (0, ka), (ka, 2ka), ..., ((n - 1)ka, nka), (nka, 1) on the chord of the profile which is the segment [0,1] from the Ox axis. We consider the characteristic having the equation - kq = C E (0, ka).
2).
For n=-2 wehave
The characteristic having the equation x + ky = E
(- ka ka
2,
2
ka
2, t E
does not intersect the chord of the profile, i.e. the
segment y = 0, x E (0, 1]. We have, by virtue of condition (8.2.3) G
ka) =
G(x + ky) = 0, t E
lim
ka, ka (8.2.8)
From (8.2.5) it results
0=va)
2
and from (8.2.8) and (8.2.9)
F(f+
Z)=0,
2
)
t E(-2, 2j.
(8.2.9)
(8.2.10)
Utilizing the notations
G(x+ky) = G- (x + ky), F(x - ky) = F"(x-ky),(x,y) E D" (8.2.11)
GROUND AND TUNNEL EFFECTS
297
we have on the upper surface of the profile
F- (x) = 0,
x E (0, ka) .
(8.2.12)
From the previous equation and from the slipping condition on the profile (8.2.4)
h'_ (z) = v(x, -0) = F- (x) + G` (x), x E (0,11
(8.2.13)
it follows that
G-(x) = h'_(x) x E (0, ka) .
(8.2.14)
Further one demonstrates by induction that for x E (jka, (j+1)ka) , j E N, j < n, we have:
G-(x) = h'_(x) +h'_(x-ka)+h'_(x-2ka)+... ... + h'_ (x - jka), F- (x) _ -h'-(x - ka) - h' (x - 2ka) - ... - h'_ (x - jka) .
(8.2.15) (8.2.16)
Indeed, for j = 0 the relations are true. Assuming that the relations are true for j, we shall demonstrate that they are also true for j + 1. Let us consider x E ((j + 1)ka, (j + 2)ka). From (8.2.5) we obtain:
0=v(x-k2,
-G'(x-ka)+F-(x).
Since x - ka E (lka, (l + 1)ka), by the induction hypothesis we have
F-(z) =-G- (x-ka)=-h! (x-ka)-h! (x-2ka)-... (8.2.17)
...-h'(x-(j+1)ka). From the slipping condition on the profile
h'_ (x) = v(x, -0) = p-(x) + C-(z) and from (8.2.14) it follows:
G-(x) = h' (x) +h'_(x-ka)+h'_(x-2ka)+...+h'_(x- (j+1)ka), (8.2.18)
whence we deduce by induction the validity of the relations (8.2.15) and (8.2.16).
Taking into account that
P(x, y) = -u(x, y) = k [F(x - ky) - G(x + ky))
,
(8.2.19)
298
THE SUPERSONIC STEADY FLOW
we may calculate the velocity field on the lower surface of the profile [h'_ (x) + 2h' (x - ka) + ... + 211- (x - jka)]
p(x, -0)
,
(8.2.20)
x E (jka.(j+1)ka)n[0,1]. Considering the domain
D= (x, y) : x - ky E [0,1), 05Y:5 Z
(8.2.21)
and utilizing the notations
G(x + ky) = G+(x + ky), F(x - ky) = F+(x - ky), (x, y) E D+, (8.2.22)
we can prove, like in the previous case, that for x e (jkb, (j + 1))kb) fl [0, 1) we have
G+(x) = -h+(x - kb) - h+(x - 2kb) -
... - h+(x - jkb),
(8.2.23)
F+(x) = h+(x)+h+(x-kb)+h+(x-2kb)+...+h+(x- jkb), (8.2.24) whence it results
P(x, +0) = k [h+(x) + 24' (x - kb) + ... + 2h+(x - jkb)] (8.2.25)
x E (jkb,(j+1)kb)n[0,1).
8.2.2
The Aerodynamic Coefficients
As we know from section 8.1, the aerodynamic coefficients are given by the formulas
cL =
j rt
[p(x, -0) - p(x, +0)) d x (8.2.26)
cA( = J x [p(x, -0) - p(x, +0)1 d x. ..110
In the sequel we shall consider some examples. For the profile in a free stream (a = oo, b = oo), it results the already known formulas (8.1.23).
299
GROUND AND TUNNEL EFFECTS
For the thin profile in ground effects (b = oo), taking for example 1 > ka > 1/2, we deduce 1
CL =
j[14(x) + h'_ (x)] d x- k
jh..dx (8.2.27)
1
2
1
cM= --
x[h+(x)+h'_(x)]dxo
k
f
1-ka
(x+ka)h'dx.
o
For the thin profile in a wind tunnel, taking for example 12: ka >
1>_kb>1/2,we get CL = - I
J
1 [h+ (z) + h' (x)] d x - k
-2 JI
h+(x)d x,
k 0 1
CM = -
k1
f 1-ka h'_ (x)d x-
1
2
j1-ka
x (h'+ (x) + h'_ (x)] d x - 2
(x + ka)h'_ (x)d x-
-2 11-kb (x + kb)h+(x)d x. k
(8.2.28)
For the flat plate with the angle of attack e, we have h+(x) _ = h_ (x) = -Ex, x E (0,1], whence 2E
E
L= k, CM=k7
(8.2.29)
for the profile in a free stream,
(2 - ka), cm = k (2 - k2a2) ,
CL =
(8.2.30)
k
for the profile in ground effects (12: k > 1/2) and cL =
(3 - ka - kb),
cu= k (3 - k2a2 - k2b2) ,
for the profile in tunnel effects (1 > ka > 1/2, 12: kg > 1/2). This subsection was written following the paper [8.8].
(8.2.31)
300
8.3 8.3.1
THE SUPERSONIC STEADY FLAW
The Three-Dimensional Wing Subsonic and Supersonic Edges
In this subsection we present the general theory of the thin wing in a supersonic stream. We shall utilize the coordinates (2.1.1) and the fields (2.1.3). The free flow is by hypothesis supersonic. Like in the subsonic case, we shall denote by z = h(x, y) ± hi (x, y) (8.3.1)
= er(x, y) ± hi (x, y)} the equations of the upper and lower surfaces of the wing. The projection of the wing on the xOy plane will be the domain D, assumed to be simple connected. On the boundary r of this domain we have:
hi (x, y) = 0.
We assume that r is smooth. Then there exist a point F where the tangent to r makes with the direction of the stream at infinity the angle of Mach p defined by the formulas (8.1.7) and a point A, where the tangent to r makes with the direction of the stream at infinity the angle -µ (fig. 8.3.1). The point of intersection of these tangents will be considered the origin of the frame of reference. There also exist two
Fig. 8.3.1.
Fig. 8.3.2.
points B and E where the tangents are parallel to the direction of the stream at infinity. As we know from the subsonic case, the points
B and E separate the boundary r in two portions: the leading edge
301
THE THREE-DIMENSIONAL WING
EFAB and the trailing edge BCDE (C and D are the points where the tangents make the angles p respectively -p with the direction of the free stream). Obviously, we assume here again that every parallel to
the direction of the stream at infinity intersects the edge r in at most two points at a finite distance. Definition. We name supersonic (subsonic) part of the leading or trailing edge, the part for which the absolute value of the component normal to the edge of the velocity of the free stream is greater (smaller) then the sound velocity. We shall prove that this definition is equivalent to the following one: If in a certain point of the leading or trailing edge the angle of the tangent to the edge with the direction of the unperturbed stream is greater (respectively smaller) than Mach's angle, then in that point the edge is supersonic (respectively subsonic). Indeed, from figure 8.3.2 it results that the component normal to the
edge of the velocity of the free stream in the generic point P has the magnitude U sin p1. If this is greater than the velocity of the sound in the unperturbed flow we have U sin p > c, whence sin pl >
1
-
= sin p
Utilizing the second definition, it results that the edge FA1 A from
figure 8.3.1 is a supersonic leading edge, the edges AB and FE are subsonic leading edges, the edges BC and DE are subsonic trailing edges, and the edge CB'E'D is a supersonic trailing edge. It is known from the theory of hyperbolic partial differential equations (see also the plane problem from 8.1 and 8.2) that the zones of influence are the zones delimited by the characteristic lines. For example, in figure 8.3.1, the zone of influence of the subsonic leading edge
FE is FF'E'E, FP and EE' being parallel to OA. Definition. We name wing with independent subsonic leading or trailing edges, a wing for which the zones of influence of these edges are disjoint.
It results therefore that a wing has independent subsonic leading edges if the Mach lines AN and FP do not intersect in the domain D and independent subsonic trailing edges if BY and EE' do not intersect in D. For example the wing from figure 8.3.1 has dependent subsonic leading edges and independent subsonic trailing edges and the wing from figure 8.3.3 has only independent subsonic edges.
THE SUPERSONIC STEADY FLOW
302
Fig. 8.3.3.
8.3.2
The Representation of the General Solution
Like in the subsonic case, we shall replace the wing with a continuous
distribution of forces having the form f = (fl, 0, f) defined on D. We shall see that we may determine such a structure of f, in order to satisfy the boundary conditions. The perturbation of the pressure determined in the uniform stream by the distribution f will be, according to the formula (2.3.32),
P(x,y,z) = -T"
fi)a-+f(Tl)8
'ID
J
G(ro,yo,z)ddq, (8.3 2)
where G(zo, yo, z) =
H(zo - s) ' z0-9
s = k ya + za.,
zo=z-t,
yo = Y-17. (8.3.3)
For the velocity field, from (2.3.12) and (2.3.34), it results
v(z, y, z) = 6(z) lID f (rl)II (zo)6(yo)ddi+ V ,
(8.3.4)
where ( X, y, z) =
2Tr
ff
fi
n) - f (t+ o
G(zo, yo, z)dc dTl
z2
J
(8.3.5)
Obviously, the perturbation is potential excepting the trace of the domain D in the uniform stream, where the first term from the expression
of v does not vanish.
303
THE THREE-DIMENSIONAL WING
For the component w from (2.3.12) and (2.3.34) it results:
fJ f (, n)H(xo)6(yo)de dt7+
w(x, y, z) = 6(z)
+ 2a 8z JJD [h (t, n) - f
rl) 0 +
y
G(xo, I, z)dtdo z2 J
(8.3.6)
For w we also have the representation: w(x, y, z) = -'ID'n) 2
8 G(xo, y, z)d (8.3.7)
+2x 11 f(t,n)N(xo,yo,z)dt dtl, D
where N(xo, yo, z) = k2
G(xo, yo, z) +
8
xo+G
(xo, Y0,
[-yol-+-Z2
z)(8.3.8) J
which results from (2.3.37) and the representation
w(x, y, z) = ' AD ft (t, n) 8z G(xo, yo, z)dF dn+
1(2_02 _ (k
2n
8x2
2
2) AD f (C,
r(
)
H -7.1 [1-0*077
d11 d drl , (8.3.9)
which results from (2.3.38). Each of these representations determine an integral equation for the function f (x, y). All the known representations (Evvard (8.9], Ward (8.34), Krasilscicova (8.20], Heaslet and Lomax (8.15], Homentcovschi (8.16] and Dragoq (8.7)) are found in the formulas
(8.3.6)-(8.3.9). Prolonging the functions fl and f with 0 in R2\\, the above representations may be written as convolutions. For example, p(x, y, z) and rp(x, y, z) have the following form:
p=-2A 8 fl*G+BZf*G
if h #G-f * y2+z2G) 7r
where the sign x, y.
*
(8.3.10) ,
indicates the convolution relative to the variables
304
8.3.3
THE SUPERSONIC STEADY FLOW
The Influence Zones. The Domain Di
First of all we must notice that the perturbation my be represented by integrals whose integrand contains the factor H(xo - 8). Indeed, for (8.3.5) this is obvious. Taking into account the formulas (2.3.35) and (2.3.36), it results that the assertion is also valid for (8.3.2) and (8.3.7). In (8.3.9) we have
f 7
f zp H(r - s) d-r = H(xo - s) J 2 T -s .ll:
rdT-s
(8.3.11)
Since the above integrands contain the factor H(xo - s) we deduce that for a point M(x, y, z) from the domain occupied by the fluid, the
integrals on D are in fact calculated only on the domain Dl where we have:
xo > s
(8.3.12)
This inequality implies 4 < x (x - 4)2 > k2[(y
-
11)2
+ z2].
(8.3.13)
The points from D verifying these inequalities are situated between the leading edge and the hyperbola C which has the equation (x - )2 = k2[(y
-
q)2
+ z2)
(8.3.14)
and the branches to -oc because < x (fig. 8.3.4). The hyperbola C (the variables are and t) has the axis parallel to Ox. In fact, C represents the intersection of the cone having the equation (x - C)2 = k2 [(y - t1)2 + (Z -
()2)
with the plane C = 0. This is Mach's cone. It has the vertex in Al and the axis parallel to Or. From the mechanical point of view, this result represents a consequence of a fact known from the hyperbolic partial differential equations theory [1.6] namely the fact that in Al one can receive only the perturbations produced in the points belonging to the interior of Mach's cone with the vertex in Al. When Al will be on the wing (z = 0), the hyperbola C will be reduced to the half-lines
x-==±k(y-,). These are the characteristics issuing from M (fig. 8.3.5).
(8.3.15)
THE THREE-DIMENSIONAI. WING
FIg. 8.3.4.
305
Fig. U.S.
We may easily explain why the points from D - D1 do not affect the perturbation in M if we have in view (the significance of the fundamental solution) that the perturbation produced in a point Q E D propagates only in the interior of Mach's cone with the vertex in Q. The point 141 is in the interior of all the cones with the vertices in Dl and in the exterior of all the cones with the vertices in D - D1. It also results that in the fluid exterior to the envelope of the posterior
cones with the vertices on D, the perturbation is zero. Hence we can give up the factor H(xo-s) in the integrals expressing the perturbation if we replace the domain D by D1. Prolonging the
functions f, and f in the exterior of D with the value zero, for a given i;
,
ij will vary between Y_ and Y+ defined by (8.3.14) through
kYf = ky ±
xo - kszs .
(8.3.16)
The vertex of the hyperbola C has the coordinates tI = y, = x - kjzj (obtained for Y+ = Y_). 8.3.4
The Boundary Values of the Pressure
For the integrals having the form: I (x, y, z)
=
JJ
rl) 8zG(xo, yo, z)d>; dry
(8.3.17)
306
THE SUPERSONIC STEADY FLOW
we have: Jz-kJ=I
1 _ 8z
d
f Y+
fy_
r1)
ro-s
(8.3
dt) .
Performing the change of variables rq -+ 8: kn = ky - Jxo - k2 z2 cos 0
(8.3.19)
we obtain jx_&.izi
I (x, y, z) =
k.
z
d/f
rR
!
f
y - rx.2 - k2z2 cos 9) d8 = C
z -L-1-TI
_ -sign z !O f (x - kjzj, y)d©+ JJ
dC oo
Of
Jo 8rr
noose
xo - k z
dO.
Hence,
I (x, y, f0) = F it f (x, y) .
(8.3.20)
Using this formula, from (8.3.2) we obtain
Ax, y, ±) = - 2I j
jD f1 (e, n)
G(xo, No, 0)d do f 2 f (z, y)
whence, (8.3.21) f (x, y) = F(x, y, +0) - P(x, y, -0) . This result puts into evidence the significance of the function f.
8.3.5
The First Form of the Integral Equation
The simplest way to obtain the lifting surface equation relies on the representation (8.3.7). Taking into account the derivation formula (2.3.35), we may write the kernel (8.3.8) as follows: N(xo, yo, z) =
-k2
H(xo - s) _ xo(yo - p2) H(xo - s) xo - s yo + z2 (xo - s2)312 (yo x022
(8.3.22)
We notice that for z = ±0 it appears the singular line n = y. Detaching
from D the domain DE defined by y - e < n < y + E in Dl - D, (fig. 8.3.5), it is possible to simplify by yo after putting z = ±0. Performing this.operation we deduce N(xo, yo, f0)
xO
H(xo
o
xo
so) so
H(xo, yo) .
(8.3.23)
307
THE THREE-DIMENSIONAL WING
Adopting the definition
f-'0 11.
f- D2
(8.3.24)
,
we shall prove that
j = lim lID. f ( r1)N(xo, Uo, z)ddq = 0 .
(8.3.25)
Fore small enough, we may perform the replacement n = y in the integrand. Hence, rx
= C-0
0o
lirn
(
x-kIzl ao
[f-" f (F, n)N(xo, yo, z)di7 I d _ c
v-c d= 0 [f()N(zotz)jdfll 1
-
.
Using the form ula (8.3.20) from (8.3.7) we deduce:
w(x, y, +0) = T 2 f1(x, y) +
27r
JJ f(f, n)N(xo, yo)dtdo . (8.3.26) D
Adding and subtracting the boundary conditions w(x, y, f0) = h..(x, y) ± h1x(x, y) (x, y) E D ,
(8.3.27)
one obtains:
h71 f(f,n)N(xo,yo)dt do = h.(x,y), ft (x, y) = -2h1x (x, y) ,
(x, y) E D.
(8.3.28)
(8.3.29)
The equation (8.3.28) is the lifting surface equation in the supersonic stream. It can be also written as follows:
f(")
_ ,
yo
o::ll
xox k
(8.3.30)
o
D1 representing the shaded domain from figure 8.3.5. The analogy of this equation with equation (5.1.28) is obvious. The equation (8.3.30) was given in [8.7). For the sake of simplicity we shall name it the equation D.
308
THE SUPERSONIC STEADY FLOW
The Equation D in Coordinates on Characteristics
8.3.6
We know from (8.3.15) that if the current point M is on the wing (x, y) E D, z = 0, the hyperbola C from (8.3.4) degenerates in the characteristics MMl and MM2 (fig. 8.3.5) having the equations
t -- krt = x - ky respectively t; + kr' = x + ky ( and q are the variables, x and y are the coordinates of the point M). Performing the change of variables C, ,q - a, Q, x, y -+ a, b defined by the formulas
- kn = a
x-ky=a
t;+kn =Q
x+ky=b,
(8.3.31)
we deduce
2kdt; drt = da d#.
The characteristic MAi1 has the equation a = a and the characteristic MM2, the equation Q = b. The domain Dl given in the old variables by the inequalities
t-k, <x-ky, +krl<x+ky
(8.3.32)
will be characterized in the new variables by a < a;
f3 < b .
(8.3.33)
The axes OA and OF will be the new axes of coordinates because
on OA we have /3 = 0 and a is variable, and on OF, a = 0 and 0 is variable. The coordinates of M with respect to the new axes are (a, b) (fig. 8.3.6). Since the new axes are characteristic lines, the coordinates a and /3 will be named coordinates on characteristics. In these coordinates the equation (8.3.30) becomes
f(a,
k 2rr
Dl
a - a + b -,8 (a - a - (b - Q)(2
dadQ = H(a b), (a a)(b - /3) (8.3.34)
where we denoted by f (a,,6) the unknown f in the new variables, H(a, b) the function given by h=(x, y) in the new variables and Dl, the domain D in the new variables, i.e. the shaded domain from figure
8.3.6 (a
THE THREE-DIMENSIONAL WING
309
Fig. 8.3.6.
and denoting by D6 the parallelogram indicated on figure 8.3.6. We adopt in (8.3.34) the definition
Jf
,
C0
(8.3.35)
if, -n. *
In this way, the non - integrable denominator from (8.3.34) does not vanish (even if a = a). In Dl - D6 we may utilize the identities
a - a+b _
1
-a-(b- /3)]2 n-a b-
2
0
a
s
a- a -(b-Q)-
P-i
a-a+_/_-_
82
-2 8a8b In
_
I
a --a - VS --- I I ' (8.3.36)
such that the equation (8.3.34) may be also written as follows
k0
('Pv, f(a, Q)
dadf
T-,6 a-a- (b-Q)
it 8a k 82 ;r 8aOb
a --a
JID,Di
H(a, b)
,
a --a + V- da d,B = H(a, b)
(a, Q) In I
a --a - ../b-/31
(8.3.37)
(8.3.38)
310
THE SUPERSONIC STEADY FLOW
in order to have weaker singularities. In [8.7) one gives another form for equation (8.3.37).
The Plane Problem
8.3.7
We act like in 5.1.7. In order to have a plane-parallel flow, we must consider the case when the conditions that determine the flow are iden-
tical in every plane parallel to xOz. We assume therefore that the equations (8.3.1) have the form z = h(x) ± h1(x),
(8.3.39)
and the domain D is rectangular, such that the span 2b tends to infinity (b - oo). Hence we assume that D is characterized by the inequalities 0 < x < 1, -b < y < b. These conditions imply ff = fi(t) and f = f (t;). Noticing that 2 100 H(xo
+0o
Ed
xp
k
1.00
_
- u + k z) du
-k'z2 u
°-k I 2T
2
kH(x0 -
lID f()8!!
(y02
(8.3.40)
xo - k222 - u
o
= kH(xo - kizi)
du
ldv v
10
= -H(xo - kjzi),
+z2E/dj?=
f [.1:(j2 E)cli}df 1
we deduce the representation (8.1.17).
(8.3.41)
=0,
THE THREE-DIMENSIONAL WING
311
8.3.8 The Equation of Heaslet and Lomax (the HL Equation) This equation may be deduced from the representation (8.3.6). To this aim we denote L(x, y, z)
8z
(/
f f fx° Di
6z
.
!l
2
do =
82.+8
+
(8.3.42) d
+z2
Y_ 747-77
the functions Y+, Y_ being defined in (8.3.16). Here the change of variable (8.3.19) is not indicated, because the term that one obtains by deriving the superior limit of the first integral becomes oo for z --+ 0. We act therefore as follows:
r-k L = limm
Y+
as J-oo
f (4, q)
x0z
a yp + z2
fY_
(8.3.43)
so Ll (x, y, z) + Twki,1 xot(x0, Y, 44,
where, after performing the change of variable 9 -, it : q - y = u, we have:
V+cf(x-k[+ £ q)
L1=-k2Jim c-+o lyt -
e-
do + z2
+s
_ -kz2f (x - kizl, y) hm
t(xo, y z )
F,
f
ft
-ki f (x - kjzj, y), e - u (u2 + z2) = (8.3.44)
Y+
z
f (F, n)
Y_
x0 - a Y + z
d ry =
a(s)
8 as
a(:)
F(u, z)zdu,
+z
(8.3.45)
with the notations a(z) _
x8 - k2z 2
,
F(u z) ,
M,u+y)
(8 . 3 . 46)
x - k u2 + z)
We deduce therefore
L(x, y, ±0) _ -ka f (x, y) + f xot(xo, y, ±0)d.. 00
(8.3.47)
312
THE SUPERSONIC STEADY FLOW
For determining the function L(xo, y, t0) we notice that a'(+-0) =0. It results that the derivative from (8.3.45) and the integral interchanges. We have therefore: l(xo, y, ±0) =
_ limo sL m
8z
+* OIF
f
8uOz
8 zUM
+°
8.. J C r
a
{ [F(a, z) + F(-a, z)] arctan
z-»f0
J
+a OF
f4
=
}-
U2
+ z-.f0 lim
a z2 + a2
z
+a OF
arctan z -d u + yli
lim (F(a, z) + F(-a, z)(
u
F(u, z)d arctan
u
+0
f
+ Z2
8F
du=
z
87Z u2 + ..2 d u+ c
u2+z2du.
8u
But lim z* .O lim z
0
r+n OF
f
a
J
du=
z
J
z-.f0 8z
8Z u2 + z2
+° OF
8F (0,z): /+` du
lim
u
du
a 8u u2 + z2
_ - el 0 z
0
f7rBF
f u2 + z2 =
8z (
+c OF
r
(-a
j+d019F
)
+ Ja
u
8; u2 + z2
0, 0)
du=
du
(u, U)
u
where ao = a(0). Finally, taking the formula (D.3.7) into account, we obtain:
t( x0, y, f0 ) _ + W OF ( 0 , 0) =
F(oo, 0)
- F(-ao, 0) +
ao
ao
r
'/ +°O OF (u, 0) d
1
8u
u±
u (8.3.48)
F(u2 0)d u
-,-0
f
BF(0 , 0) .
Having in view the expression of F(u, z) (8.3.46), we deduce: L ( x, y, f0 )
= -k rf (x, y) +
f oo
x0
T y
f(t, n)
do x =k-2-y- d on d t (8.3.49)
313
THE THREE-DIMENSIONAL WING
Hence,
w(x,y,±0) _ T 2ft(x,y)+ Zf(x,y)(8.3.50)
[*
T7r
v- s
f xk'y yo
L771 d
such that, imposing the boundary conditions (8.3.27), we find: f
kf (x, y) - ! J
xo [
T
ok2yo
24(x, y), (8.3.51)
d
ao J
I1 (x, y) = (h' -
(8.3.51) is the HL equation. Integrating in (8.3.42), at first with respect to respect to y, we obtain
w(x,y,±0) = T 2ft(x,y) -
oo
«
2zr
(8.3.52)
(x, y).
.
°
r-kh#o)
d2y b0
and then with
[.! ro-k o
dl .
8.3.9 The Deduction of HL Equation from D Equation This deduction was performed by V. Iftimie. To this aim, we shall extend the integral from (8.3.30) from the shaded domain Dl, in figure 8.3.5 to the infinite domain D&, situated between the characteristics
MMl and MM2 extended to infinity, putting f = 0 in the exterior of the arc M1 M2. We denote by I the integral obtained in this way and we perform the change of variables t, n -+ u, v:
u=x-Z;, v=y-y.
(8.3.53)
In the new variables, the domain Df, will be transformed into the domain Du,, (fig. 8.3.7) determined by the angle Mi MMz. Denoting g(u, v) = f (x - u, y - v), we deduce f(x,y) = g(0,0).
(8.3.54)
THE SUPERSONIC STEADY FLOW
314
Fig. 8.3.7.
The HL equations result from the formulas
g(u'
v)
u
dudv
v2
u-k
_ d
=-k,rg(0,0)+or duTAOU,v 00
=
it
v)
J
u
u
(8.3.55)
k
akv
which have to be demonstrated (the demonstration was given by V.1ftimie). For proving the first formula, we isolate the singularity by
two parallels to the Mu axis (fig. 8.3.7) at the distance e from this DD axis. We denote by D' and D" the domains composing and by I' and I" the integrals I corresponding to these domains. Using the definition (8.3.24) we get I = limo(I, + 1") .
Putting v = tu, we deduce:
I'-
11 JfJJJJ
g(u,v)u
v2
dudk u
_ r0O 1
=J. u[u /k
oc
v
-lip uI,J
(8.3,58)
r
JJ
t2
g(u,tu)
1-k t
dt du.
u
1
dv'du
315
THE THREE-DIMENSIONAL WING
We expand g in a Taylor series:
g(u,tu) = g(u,0) + tug"(u,0) + t2u2m(u,tu). and we introduce this series in the above integral. Acting analogously for 1", we deduce:
- °° u F f-`
I"
9(u, v)
d vl d
v2 u -k
J
1-v-1g(u,tu) kE u l Jl
t2 1- k t
u=
dt1du
whence,
f
00
1' + 1" =
g(u, 0)
[ JiY
U
Jibe
r
t2 1- k t
+Jits g°(u,0)LI=" t lack t
+
i m(u, tu)
uf
LJ4
+r
dt
1-k t
d
The factor which multiplies
L
J_
+J-I
t+!J_
1t
dt du+ t2 1- k "t
t I-
m(u, tu) 1
t
t,du+
d t d u.
is zero if we replace in the second
integral t by -t. An elementary calculus gives
rk1-k t
dt 411
_r
dt
_ u -k E
t2 1- k t - J_ t2 1- k t
whence,
P+ I"
E
e
k2E2d u+
u
(8.3.57)
+fJ-u(j1+j-'U) m(u,tu) dtdu When a -+ 0, the first integral is a Finite Part. Hence 2 /'O g(u, 0) C JkE
U
1 9(u1 0) - 9(01 0)
u2 - k2E2d u E
fkC
U
u2
k2E2+
316
THE SUPERSONIC STEADY FLOW
u u
+E g(0,0}
ke du+E foo 9( L+0)
u2 - k2F2 d u .
JEc
The first and the last integrals from the right hand member are finite. When we consider the Finite Part, we neglect these integrals because they h a v e the factor E t . One calculates the integral from the middle and one obtains
FP 2
0o
E Jke
u2 - k2e2d u = -kirg(0, 0) .
g(u' 0) U
Hence, from (8.3.57) we deduce: r00
I= lim(I`+I") =-k7rg(0, 0)+J
o
oJ
I
m1(uk tut)
,
d t]d u. (8.3.58)
We set now
J= f 00 [1" 9(u,v)v f
dUk
Jdu.
u
(8.3.59)
Using the same Taylor expansion we deduce:
J' _
J6
u v)
g('
[Ilk
u
d v=
- Js
v2v
Y
d tk
9(u. 0)
t2 VI
U
t +9u(u1 0)J°
f I m(u, tu)
+u f
1 - 00
0
J =Jr 9(u, v)
dv
u - kv
+gv (u,
Y
0)
J
dt g(u, tu) u t2 1 - k t
t
latkt
-
+
d t,
u dt
t 1-k t
f_1 -{-
t2 1-k t+
.. .
whence,
J' + J" =
2 g(u, 0)
u - k e + u{
m(u, tu)
U 43
1-kt
dt.
317
THE THREE-DIMENSIONAL WINC
When we consider the Finite Part (FP) we neglect the first term and we get li
m
(J' + J") = u
m(u, tu)
f
J= /
1-k t
u
Jo
[
JI
m(u, tu) d t d u.
1-k t
(8.3.60)
From (8.3:58) and (8.3.60) it results
I = -k7rg(0, 0) + J,
(8.3.61)
which demonstrates the first equality from (8.3.55). For proving the second equality, we denote: 00
K
I
T0,
J
u
g(u,v)
kv
dudv= lim(K`+K"),
where (we may change the order of integration)
K' - r-E r r J_O0
sr
fI
g(u, v) d v2 7u!=-=kFJug(u, v)
kv v2 u - u v
0o
v du = I', (8.3.62)
K" = 100 [/
r - Jkr
d ul d v =
ky v2 u- JC v
h
00 u
Jk
uy(u, v)
du] d v =
c
u
g(u,v)
i v2Vu- 72 -k v
dv du = l"
Hence K = I and the demonstration is finished. The HL equations resulting from (8.3.27) are
kf (x, y) - a
-1
f
a'° 00
l vklvo!
co
p
o°
f(")
d? l d t = 2h.(x, U),
k Uo V5
o-n)k o
F--7
d
t
(8.3.63)
= 2h= (x, y)
These are the equations (10-21) and (10-22) from (8.151.
(8.3.64)
318
THE SUPERSONIC STEADY FLOW
8.3.10 The Equation of Homentcovschi (H Equation) This equation results from the representation (8.3.9). Taking into account (8.3.20), we deduce:
w(x, y, t0) = T 1h (x, y)+
+2
f
l rr
(k2 52 +J
2/
_
=o
Id f H(T ^s)drdn,
L
.0
o
(8.3.65)
such that imposing the boundary conditions (8.3.27), we obtain the equation (k 2
ll
axe - r7y2)
ff f
n)
f
r:o d T d dn = 2 (x,b) J H(T - so) J
(8.3.66) which was given for the first time (in a different way) by D.Homentcovschi (8.16].
We have to notice that after evaluating the interior integral with the formula (8.3.11) one obtains the equation
!
..
(k2..02
_
vx-!::
02
aye) Jf,
f (E, n) In xa + 40 ,
sod d r1= 2h (x, b) (8.3.67)
In the variables on characteristics this equation becomes (8.3.38). However, Homentcovschi does not follow this way. Inspired probably by the papers of Evvard (8.9], Ward (8.33] and Krasilscicova (8.20], he intro.
duces the unknown N, related to f by the equality N(x, y) = 1-00 f (t, y)d t,
(8.3.68)
f (x, y) = N= (x, y) .
(8.3.69)
whence it results
We have seen in (5.4.5) that o function similar to N also intervenes in the theory of low aspect wings in a subsonic stream. Taking (8.3.69) into account, the integrand from (8.3.66) becomes:
N
:° H(T - so)dT J
-
= 0
[NJ° H(T - so)dT
9[NH(x(, -4o) f°u
x2 -4
o
dT
a_
so) 0J
V0-
o
_
319
THE THREE-DIMENSIONAL WING
[N(f , n) In 'To + sp o - so] +
= H(xo - so) {
F(I,,,) 1. 0
0
In this way, after applying Green's formula, the equation (8.3.66) becomes
111I N(C, g) d i d n+
a_ 82
(kz
xo-8o
81l
+ POD N(t, Y)) In
sod
xo +
so
1
(8.3.70)
n} = 2h.(x,1!)
In variables on characteristics this equation becomes k
a dQ
02
8
AD
l
- 0) +
V'r(a - C
v1_a --a
+ JeD; v(a' Q) In
a-a
+ VT--71
d ( - a) } = H(a, b). (8.3.71)
From (8.3.68) it follows that N(£, n) vanishes on the leading edge, hence
on EFAB.
N = 0,
(8.3.72)
Indeed, for every point
n) E EFAB, the integral (8.3.68) is calculated on the half -line having the applicate q upstream of the wing, where f = 0. We also notice that the curvilinear integral from (8.3.71) vanishes on the characteristics a = a and (3 = b (fig. 8.3.6), because the logarithm vanishes. Hence, for a given M(a, b) , the curvilinear integral from (8.3.71) will differ from zero only in those points of the trailing edge belonging to 0DI. For example, for the wing from 8.3.1, the curvilinear integral will differ from zero only for M situated in the zones of influence of the subsonic trailing edges BC and DE, respectively in the domains BCB' and EE'D. Utilizing the definition (D.3.6) for (8.3.71) we also have the equivalent forms: k 4ir
N(a) p)d a d.8
f JD1
(a - or)-111(b - 0)312
+ (8.3.73)
+_7r 8a JD a - a - (b, Q)
-d(A-a) =H(a,b)
320
THE SUPERSONIC STEADY FLOW
k "f 4;r J
N(a,A)da dA 7D) (a - c')3/2(b - 10)3/2
8
f
N(a,
A) d
(8.3.74)
+k 8b oD1 b-,C-(a-a) a-a (A - ) = H(a, b), the curvilinear integral being different from zero only in those points of
the trailing edge where a < a and A < b (see the definition of D1 in coordinates on characteristics (fig. 8.3.6). The equation (8.3.71) is the equation of Homentcovschi (H equation). In the following subsection we shall present the solutions of this equations as they were determined by the author himself.
The Theory of Integration of the H Equation
8.4 8.4.1
Abel's Equation
Abel's equation has the form x f"Jdx=h(Y)1 -x
a< y.
(8.4.1)
This was the first equation encountered in applications. Multiplying (8.4.1) by (A - y)-1/2 and integrating with respect to y on the interval (a, A) we obtain:
dy
J
rV
Ja
f(x) dx
y-x
rA h(y) dy
-JQ Vx --y
Changing the order of integration in the first member (fig. 8.4.1), we have: A
A
f (x)
J=
dy
(A - y) (y - x)
and then
f f(x)dx = I
fA
dx=
Jay
h
dy.
A
h(y)
dy
Deriving this relation and utilizing the definition of the Finite Part (D.4.3), we deduce: d
f (A) = a d A
f'\
hid
y
I
21r
,
{A
h(y)3/2 d y.
(8.4.2)
THE THEORY OF IN BGRATION OF THE X EQUATION
321
y
a
x
1)
Pt
8.4.1.
It results that the solution of the equation (8.4.1) is (8.4.2) and conversely, the solution of the integral equation (8.4.2), where h is the unknown, is given by the formula (8.4.1).
8.4.2
The Solution of the H Equation in the Domain of Influence of the Supersonic tailing Edge
If M is in the zone of influence of the supersonic trailing edge (fig. 8.4.2), as we noticed at the end of the section 8.3., the curvilinear integral from the equations (8.3.73) and (8.3.74) disappears. We see in
fact on the figure 8.4.2 that on the arc BM2 we have a > a and on the arc Ml E, /3 > b. It remains to integrate the equation: k
4a
N(a, /3)d a d,6 JDI
(a - a)3/2(b -
= H(a, b) .
(8. 4 . 3)
/3)3/2
Denoting:
a = A(,B), the equation of the arc DEFA and (8.4.4)
/3 = B(a), the equation of the contour FABC, t h e equation (8 .4 . 3 ) may be wr itten as follows
k'b
Ni (a, fl)
4ir JBi,l (b -8)3/2 d
= H( at b) ,
(8. 4 . 5)
THE SUPERSONIC STEADY FLOW
322
Fig. 8.4.2.
where
r
Nt (a, Q) _
N(a' a)
A(p) (a - a)3/2
(8.4.6)
d c t.
Utilizing (8.4.2) and (8.4.1), we deduce from (8.4.5) 2
_
(a, Q)
J
°)
H(Nl 3d
(8.4.7)
br
In this way, the equation (8.4.6) becomes _
1
27r
N(a,fl) da =
1A(8) (a - a)3/2
T11
H(a,b')db'.
(8.4.8)
$(°)
The equation (8.4.8) is similar to (8.4.2), so that 1V(a, A)
ra
d a'
JA(9)
a--a,
1 r H(a', b') dg.
Irk ,lg(a') 13
b'
For a = a, 6 = b we obtain N(a,b) _
1
"
Irk IA(b)
da' H(a',b')db, b - b' a --a' J Br(.') b (8.4.9)
1 If r(ab)
H(a',b')da' db' a - a' (b - d)
THE THEORY OF INTEGRATION OF TIIE H EQUATION
323
This is the solution in the zone of influence of the supersonic leading edge.
8.4.3 The Solution in the Domains of Influence of the Subsonic Leading Edge We assume that M(a, b) is situated in the zone of influence of the subsonic leading edge AB (fig. 8.4.3). In this case, the curvilinear
integral also vanishes, because on BM2 we have a > a, and on M1E, ,8 > b. The equation which has to be integrated is also (8.4.3). Obviously, A(b) < a1 < a, B(a) < b < b1. The equation (8.4.3) may be written as follows k 47r
J
N(a, /3)
da
(b) (a - a)3/2 B(a) (b - 0)112
d p = H(a , b) ,
(8.4.10)
such that we denote
N2 ( a, b)
(
2 JB(a) (b
we obtain the integral equation
Fig. 8.4.3.
0Q/2 d
1
(8 .4 11) .
324
THE SUPERSONIC STEADY FLOW
k
N2(a, b) JA(b)
(a - a)3/2
da
= H (a, b )
( 8 . 4 . 12)
whose solution is
N2(a, b) =
-1
k
H(a'' b)
J
A(b)
a- a' d a
(8.4.13)
for a > A(b). From (8.4.11) we obtain for N(a,/3)
the following
integral equation
2 r r l B(o) (b
(IB 2 d 1 3 =
7rk IA'
(b)
Haas'
d a'
(8.4.14)
Utilizing again the solution of the equation (8.4.2), we deduce:
N(a, R) = irk 1 J B(a)
for a > A(b) and
N(a,6) -
d &'
H(O' b') d a , f(- b JA(bl) a - a'
> B(a). Putting a = a, Q = b, we obtain: 1
db' JB(4) b - b'
(8.4.15)
H(a', b')d a' d b'
D]
Irk
fN)a='
H(a,b')dIrk
(0)
V'r(a,
- a) (b - b')
Dl being the shaded domain from figure 8.4.3 We notice that in this case D1 is not the entire domain determined by the leading edge and the characteristics issuing from M. From this domain one eliminates the strip where b' < B(a). This result was obtained for the first time in 1949, independently, by Evvard and Krasilscicova and it is called in some books the theorem of Evvarrl and Krasilscicoua
The solution is obtained analogously when M is in the zone of influence of the edge FE, with the difference that in this case one eliminates from Dl a strip parallel to the 0/3 axis. 8.4.4 The Wing with Dependent Subsonic Leading Edges
and Independent Subsonic Trailing Edges For a wing with dependent subsonic leading edges and independent subsonic trailing edges (fig. 8.4.4) the solution in the domain bounded
TIE THEORY OF INTEGRATION OF THE H EQUATION
325
by the curve AHFA is given by the formula (8.4.9), the solution in the domain bounded by ABH'HA - by the formula (8.4.15), and
the solution in the domain bounded by FHH"EF - by a formula analogous to (8.4.15). The case when M is in the common zone of influence HH'B'E'H"H of the subsonic leading edges is presented in the sequel.
Fig. 8.4.4.
We notice at first that in this case the curvilinear integral from
(8.3.73) also vanishes, because on BM2 we have a > a, and on All E'3 > b. Hence, we have to integrate the equation (8.4.3). Denoting by R1, R2 the domains bounded by the curves FM"RF, respectively FMIt'M"F and by Q1, Q2 the domains bounded by the curves
AQA1', respectively AM'M'A, we notice that on Rl and Q, we have N = 0 (it results from (8.3.68)). Hence, the domain of integration from (8.4.3) may be prolonged to the domain bounded by MRFAQM, i.e. to the domain
D2+R1+R2+QI +Q2, where D2 is the shaded region from figure 8.4.4, i.e. the region bounded by the contour Iii"'AMA! A.!"Al't'. The leading edge of this domain is entirely supersonic, such that the solution of the equation (8.4.3) is given by the formula (8.4.9)
N(a,b)
k
[Jf.+JJRi+fJR,+ff, +ff. (8.4.16)
H(a', b') d a' d b' . (a - a)(b - b')
THE SUPERSONIC STEADY FLOW
326
Let us consider now that M belongs to the zone of influence of the subsonic leading edge AB. From formula (8.4.15) we deduce: 1V(a'b)
irk IJJ
+
f+[ ,
R, ,
(a-a)(b-b')
da'd (8.4.17)
Similarly, taking into account that M belongs to the zone of influence of the leading edge FE, we deduce: N(a, b)
Tk-
f
ffDz +If +f fQz, Q1
H(a', b')
(a - a) (b - b')
dadbl. (8.4.18)
From the formulas (8.4.16) - (8.4.18) it results
N(a,b)
irk
ff
bi)da'db',
(8.4.19)
(aH(a',b')
this representing the solution in the common zone of influence of the two subsonic leading edges. We notice that the solutions from the previously considered domains have the same form, differing only the domains of integration. But we
may establish a common rule for determining the domains of integration. They are bounded by the parallels to the characteristics issuing from the points where the first parallels intersect the leading edge and by the remaining portion of the leading edge. In the first case, when M is in the zone of influence of the supersonic edge, the parallels to the characteristics issuing from the points where the parallels from M towards infinity upstream intersect the leading edge, do not intersect any longer this edge.
8.4.5
The Wing with Dependent Subsonic Trailing Edges
We consider now a wing for which the parallels M'M", M"Mf V
intersect in a point P belonging to the interior of the domain D (fig. 8.4.5). In this case, denoting by R2 the domain bounded by FM'PM"F and by Q2 the domain bounded by AM'PMIVA, (the domains R1 and Ql keeping the same definition) and performing the same reasoning like in the previous subsection, we obtain successively
N(a,b)=1(D3+R1+R2+D4+Q2+ Q1) N(a, b) = I(Ds + Ri + R2) ,
N(a, b) = I(D3 + Q2 + Q1) ,
327
THE THEORY OF INTEGRATION OF THE H EQUATION
R'%G A
Fig. &4.6.
I representing the symbol for the integral appearing in (8.4.19). It results the solution N(a, b)
AD,
(a H(a,' '){
b
d a' d b'(8.4.20)
kiDD.
H(a',b')
(a-a' (b-b')
dadb'
The result may be generalized for every wing having finite dimensions.
For example, for the wing from figure 8.4.6 the solution in the point M(a, b) is
N(a,b)=I(D3-D4+Ds-Ds).
(8.4.21)
We stop here the presentation of the solutions in the zones of influence of the leading edge.
8.4.6
The Solution in the Zone of Influence of the Subsonic Edges under the Hypothesis that the Subsonic Leading Edges are Independent
For the wing from figure 8.4.7 the solution is determined in the domain bounded by the curve ABB'E'EFA. It remains to determine the
THE SUPERSONIC STEADY FLOW
328
solution in the zones BCB'B and E'DEE'. To this aim we shall use the method of Homentcovschi [8.16].
Fig. 8.4.7.
Let M(a, b) be situated in the last zone. In this case, the curvilinear integral from (8.3.73) does not vanish. More precisely, it is zero on BM2,
where a > a, it is zero on M1M", where 6 > b, but it is not zero on WE. We assume at first that N is known on the trailing edge. Since M is in the zone of influence of the subsonic leading edge FE, the double integral may be inverted with a formula similar to (8.4.15). We have therefore
N(a ,b) =
fl EM"
1
Irk AD, (a,b)
/a'-a
H(a',br)da'db' (a ---a') -(b- b'
b'-p a'-a-(b'-p)
+
1
W2
d(!g-a)1
AD
'
8a'.
da'db'
(a-a')(b-b') (8.4.22)
where D1 (a, b) is in the shaded domain from figure 8.4.7, i.e. the domain A(b) < a' < a, b' < b. In front of the last integral we have the
329
THE THEORY OF INTEGRATION OF THE H EQUATION
sign + because we have changed the sense on WE to EM". On WE we shall denote N(a,10) = N(A(Q), Q) = N(3) ,
(8.4.23)
because the equation of the edge DEFA is a = A(13). The curvilinear integral imposes to eliminate from D1 (a, b) the points where b' < p. D1 from the second integral (8.4.22)is therefore the shaded domain from figure 8.4.8. Denoting this integral by T and interchanging the curvilinear integral and the integral on the domain we get:
T=
--In, a 8a' a[,! a da' -a')(b _ )(b-b') rb
[ a' - A(/3) /
N(Q) V
1
J
[I-A'((3),d0 1. a'-A(l3) b'-(3 a -A(Q)-(b'-0)J +
bN(f3)[1-A'(A)]dfJ
2
db' (b' -)3)(b - b') u - b',
da' a A(b) 7a =' r?a'
1
,
(8.4.24)
where u=a'+A-A(/3).
Fig. 8.4.8.
330
THE SUPERSONIC STEADY FLOW
For calculating the interior integral we shall prove first that b < u, i.e. that
b
(8.4.25)
Denoting by P, R, S the points having the ordinates 3 namely, P on the trailing edge, R on the la intersection with the direction of the unperturbed stream and S on the boundary of the domain Dl (fig. 8.4.8), we have R(A(fl),,3), S(A(b), (3), 3 RM"S =3 SRM" = it, p representing Mach's angle (the angle made by the characteristic lines with the direction of the unperturbed stream). It results
PS = A(b) - A(#).
RS = SM" = b - f3,
Since M"P is an are on the trailing edge we have RS < PS whence
6 < A(b) + A - A(#) < a' +,0 - A(/3) ,
(8.4.26)
because a' > A(b). Employing the substitution b'-b+A+b-Qcose,
2
u=b+A+b-Qs 2 2
2
we obtain b
db'
1
d0
2
b-# 0 cosO-s'
(b'_/3)(b--b') u-b'
the inequality b < u implying 1 < s. This integral has the form (B.6.1) and the solution is given by (B.6.4). One obtains:
Il =
(u -b (u--/B) 7r
7r
a'-A(A)][a'+Q-A(Q)-
(8 . 4 . 27 )
The following integral has the form
°
8(
1
1
a' -v J
8a'
da
'=-1
Q
1
2 JAM (a'-v)3/a
da'
a-a,
where v = b + A(fl) - Q < A(b). This inequality results from the first inequality (8.4.26). Noticing that 1
ZA(b)
(a'-v)3/2
da'
_
2
fa - A(b)
a-a' a-v A(b)-v
331
THE THEORY OF INTEGRATION OF THE H EQUATION we deduce
T=-
1- A'(#)
N(/3)
a - A(b) ) 6
f3-A(f3)+A(b)-b 13-A(a)+a-b
62
(8.4.28)
whence
N(a,b) _
H(a',b)da' dN +T
1
Irk
(8.4.29)
ADi(a,b) -vf(-a - a' (b - 6')
in T, N(fl) being unknown. The form (8.4.29) is given in [8.16].
We consider-that M tends to the position M" on the boundary. It means that we make in (8.4.29) the substitution, a integral is 1
1=
-
ll
H (a', b')d a' d b' r( ab)
-
(a - a')(b - b')
where
L(a')
= jb
A(b). The first
L(a')d a' I irk JA(b) a - a'
H(al'b')db'
(8.4.30)
(8.4.31)
(a)
b = B(a) representing the equation of the edge FABC. Obviously, this integral vanishes when a - A(b). We shall perform in the expression of T the substitution 0 - t 13 - A(/3) = t and we shall denote N(Q) = N1(t). We also denote
a-A(b)=E, b-A(b)=c, b2-A(b2)=c2.
(8.4.32)
From the first inequality (8.4.26) it results 13 - A((3) > b - A(b) whence C2>C. Hence,
T,=
ff Ni(t) 1r
c
dt t - C+E
We shall integrate by parts setting
u=N1(t), dv= 7tIm td(t-c) - c+E It results V=
arctan rLe--f = The integrated term vanishes because t = c2 implies A = b2 and .
N1(c2) = N(b2) = 0.
332
THE SUPERSONIC STEADY FLOW
r
We obtain therefore:
T=--J and 2
f_m T = -- 2 f
Ni (t) arctan
Vt
e
cd t
(8.4.33)
C2
Ni(t)d t = Ni (c) = N(b).
In this way, passing to the limit in (8.4.29) we obtain
N(A(b),b) = N(b), i.e. an identity. This means that for an arbitrary given N(b)
, the function N(a, b) given by (8.4.25) is a solution of the integral equation (8.3.73). One obtains an indetermination like in the subsonic case). This indetermination exists in the zones of influence of the subsonic
edges EE'DE and BCB'B. In these zones the integral equation of the problem is not sufficient for determining the solution. Like in the subsonic case we remove this indetermination imposing
the Kutta-Joukovsky condition. Imposing a finite velocity on EE', it results that the jump of the velocity on EE' is finite. Since the jump of the component u is given by the jump of the pressure with the changed sign, and the jump of the pressure by f (x, y), it results that it is sufficient to impose for f to have finite values on the subsonic trailing edge. We have
f(x, y)=8xN(x,y)_
\8a+
bN(a'b)=(8a+gb)(I+T).
(8.4.34)
Performing in (8.4.30) the change of variable a' -- s : a - a' = _ (a - A(b)]s and keeping the notation a - A(b) = s we deduce I
I=
rkoJ
L(a - es) f =
2
L(a) - O(£3/2) _
a V - A(b)L(a) - O(e312) ,
whence
a
+
)
I
k .1-AI(b)
=
a fk
Ate)) L(a) +
jb (a)
H(a, b')d b' + 0(E) b - b'
(8.4.35) .
333
THE THEORY OF INTEGRATION OF THE H EQUATION
From (8.4.32) we deduce
T=- 2 J 7t
(b2-A(bz)
t- b+ A(b)
NfI (t) arctan
&-A(b)
a - A(b)
dt
whence,
s
a
as + ab
b:-A%)
1- Al(b)
T=
t- b+ A(b)
N' (t)
Jb
?r/e-
t-b+a
b-A(b)
V
d t + O(,/E .
But
t-+A -b
(b) t-b+a
t --b + A(b) =
1
t-b+A(b)+e
t-b+A(b)
[1 + O(e))
,
such that finally we have: a +
:b) T (aa
N'(t)dt
1 - Al(b) f*2-A(b2)
7r f
It - b + A(b)
-A(b)
+O(f). (8.4.36)
We obtain therefore
f(x,3!) =
A'(b) 1
1
[k
b B(a)
H(a, ) db,+ %lb
(8.4.37) -A(b z)
LAb)
N(t)d t
1
t --b + A(b)
+ O(f) .
The function f (x, y) has finite values on the trailing edge (a -+ A(b), e -+ 0) when the square bracket vanishes i.e. when Ni (t)d t
pb:-A(b,)
1 fb
t - b + A(b)
Jb-A(b)
k JB(A(b))
H(b(b), ) d b'
-G(b) . (8.4.38)
This condition is an integral equation (of Abel type) for determining the unknown N' (t). Using the notations (8.4.27) we may write this equation as follows
j2 Ni (t)d t
(8.4.39)
J
v where Gl (c) = C1 (b - A(b)) = G(b). We deduce f'2
z
dc C
(C3 N'(t)dt
-xJc
t-C
-
t z
C, (C)
xdC.
334
THE SUPERSONIC STEADY FLOW
Changing the order of integration in the left hand member we get: C2
NI(t)dt J
do (c - x)(t - c)
- _ f C2 Gi(c) dc. c-x
s . 1. Since Nl(c2) = N1(b2 - A(b2)) = N(b2) = 0 (on the leading edge N vanishes), we obtain
j Glt f t --X d t.
1
N, (x)
7r
For x = b - A(b) we deduce l Jbz-A(bz) _A(b)
Gl dt (t) t - b + A(b)
or, using the change of variable t
i3 : 3 - A(,3) = t,
N(b)
G(i3)[1
1
N(b) _ R
A'(/3)l d /3
VP - A(/3) - b + A(b)
rb
(8.4.40)
K(fl)[1 - A'(i3)ld/3 (3 - b + A(b) - A(I3)
I f' bz
where
8 H(A(#), b') db k D(A(#)) VF-7 1
(8.4.41)
.
This formula determines N in every point of the subsonic trailing edge ED. Replacing this expression in (8.4.28), we may find out T. In the sequel we shall give an explicit expression of T. Changing the order of integration (fig. 8.4.9), we deduce:
T= 12 --A
b
dJ3 ,3 - A(/3) + a
b
Jbzb2
A (fl) + A(b) - b a
_b. [1
K(E3')(1-A'(f)ldA'
-b+A (b) -A(f3)J
_-
(8.4.42)
b
_
2
a --A (b)
b
K(A')I (1Y)(1 - A'(Q'))d // ,
where, using the substitution p -+ t:,3 - A(0) = t,/3' - A(i3') = t',
IV) =
f
1
(t - c)(t'-
dt (8.4.43) (b - a)
THE THEORY OF INTEGRATION OF THE H EQUATION
335
0
b
be
I
0
be
Fig. 8.4.9.
From (8.4.26) It results b - A(b) < i - A(8) for every j6, hence for
_ P. This implies c < t'. The integral from (8.4.43) has the form (B.6.11). It results Ir
1=-
[a-A(b)]
-A(.')-b+a
whence T=_1
K ) [1-A'(B)]d3
(8.4.44)
rb, /3-A(P)-b+a Using this form of T, we express the solution in the domain bounded by the curve EE'DE by means of the formula (8.4.29). 2. If M(a, b) is in the domain bounded by the curve BCB'B (fig. 8.4.10), then we shall utilize the integral equation (8.3.74). Obviously, the curvilinear integral does not vanish on the arc BM'. Utilizing the solution (8.4.15), we deduce: N(a, b) where Tl
= plc 1 JJD1(.,b)
H(a', b')
a - a' b -
d a' d b' + Ti
(8.4.45)
a' d b' =- 2 JJJD, ad-a(b-Y) (8.4.46)
ef° 8b' f
FL- B(a) N(°`)
1]d a
-a b'-a'-B(a)+a
THE SUPERSONIC STEADY FLOW
336
Taking into account that the equation of the edge BC is Q = B(a),
we denoted N(a, B(a)) = N(a). Dl (a, b) is the shaded from figure (8.4.10), i.e. the domain bounded by MM', the parallels 0 = B(a) and A = b and the leading edge included between these parallels. D] is the
domain bounded by the contour MPQM' imposed by the condition
a < a'. Interchanging in (8.4.45) the curvilinear integral and the double in-
337
THE THEORY OF INTEGRATION OF THE H EQUATION
tegral we obtain
JaN(a)[1
T, =
T1
a 5-b'
- B'(a)] az
f
(
a)
b - b'
do
({/_B(a)j
' w-all
db' d1
I
(8.4.47)
where
w=b'+a-B(a). The similarity of the expressions (8.4.47) and (8.4.24) is obvious. TI
may be obtained from T replacing b, /3 and A by a, a and B and conversely. It results therefore
N(a) 1-B(a) da T,=- Ir b-B(a)f \/a - B(a) + B(a) - a a - B(a) + b - a az (8.4.48)
and then 1
T1 = - -
r° Kl (a) (1 - B'(a))d a aZ
where R 1 (a )
I
a-B(a)-a+b
k A(B(.))
H(a B( )) d a ' Q
(8.4.49)
(8 . 4 . 50)
The solution in the domain bounded by BCB'B is (8.4.45) where Tl is given by (8.4.49).
8.4.7
The Wing with Dependent Subsonic Trailing Edges
For a wing with subsonic dependent trailing edges (fig. 8.4.11) the solution in the zone AHF is determined by the formula (8.4.9), the solution in the zone ABPH by the formula (8.4.15), the solution in the zone FHA'E by a formula analogous to (8.4.15), the solution in the zone HF'IA' by the formula (8.4.19), the solution in the zone BCE'IB by the formula (8.4.45), where T1 is (8.4.48), and the solution
in the zone E113'DE by the formula (8.4.29), where T is (8.4.44). It remains to determine the solution in the zone IE'B'I, i.e. in the common zone of influence of the subsonic trailing edges.
Noticing that the curvilinear integral does not vanish on BM' and WE and utilizing in the first case the expression from (8.3.74), and in
338
THE SUPERSONIC STEADY FLOW
the second case the expression from (8.3.73), we deduce that the integral equation has the following form:
N(a , Q)
k
TJ , (a -
k Of +7r 8b
0)3/2(b - /3)3/2 a d p+
N( a)
al,a)
+k f ir 8a AruE 0
- B(a)
(B'(a) - IId a
a-a b-a-B(a)+a+
a - A(#)
(8.4.51)
[1 - A'(Q)]d 0
b-(3 a-b-A(O)+#
the integral on BM' representing in fact the integral with respect to
a on the interval (a2, a) and the integral on WE representing the integral with respect to 13 on the interval (b, b2). 03 b
b3
M'
a.b)
O-
Fig. 8.4.11.
In this case, the point M(a, b) is in the common zone of influence of the subsonic leading edges AB and FE. Hence the double integral may be inverted according to the formula (8.4.19), D2 representing the shaded domain from 8.4.11, i.e. the domain bounded by the curve
THE THEORY OF CONICAL MOTIONS
339
Af AI"AI""A1I,` AI'A1.
N(a,b)=
1 %TA'
ff , n
V
H (a' ) da'db'+Tt+T, (a - a')(b - b')
(8.4.52)
where Tt has the expression (8.4.43), and T, (8.4.27). Setting Al AI"(a -+ A(b)), the integral on BM' vanishes (as we can see on the figure), such that from (8.4.52) one obtains N(A(b), b) = = N(b). Imposing the Kutta-Joukovsky condition, we deduce that T has the form (8.4.43). Similarly we deduce that Tt has the expression (8.4.49).
Now the problem is completely solved. In the end, it is at pleasant duty for me to mention that for elaborating this section I utilized especially Homentcovschi's paper [8.16] and the license thesis of my former student Luminita Berechet [8.2].
8.5 8.5.1
The Theory of Conical Motions Introduction
The theory of conical motions was initiated by Busemann in 1943, 18.31. It refers to wings bounded by conical surfaces with the vertex in the origin of the system of coordinates, the body being placed downstream.
The surface of such a body is a smooth surface consisting of half-lines issuing from the origin and leaning on a closed curve situated in the plane
x = 1(xi = L I). According to the boundary conditions the velocity is constant along every half-line passing through the origin and belonging to the boundary of the body. The hypothesis of conical flow leads to the assumption that the velocity has everywhere in the fluid this property. We have therefore
v(mx, my, mz) = v(z, y, z)
(8.5.1)
for every in . real and positive. It means that the velocity is a homogeneous function having the zero degree. Under this assumption the equation of the potential becomes simpler, the unknowns depending not on three but on two variables. After Busemann, many authors (Langerstrom [8.22]. Germain [8.11], Poritsky [8.28], Ward [8.34], Heaslet and Loniax [8.15], Iacob [8.18], Carafoli [1.5] $.a.) have contributed decisively to the development of this theory. In all this theory, which will be called
the classical theory, we make the hypothesis that the motion is conical.
340
THE SUPERSONIC STEADY FLOW
Starting from the lifting surface equation in a supersonic stream, one may prove that if the wing is conical, then the solution of the integral equation is conical. For the equation (8.3.30) this thing is done in (8.5], and for equation (8.3.71), in [8.161. In the present subsection, utilizing the solution from the previous subsection, we shall give the solution of the conical motions by particularization. We shall also give the basic elements of the classical method, because they may be obtained directly, without knowing the solution of the lifting surface equation.
8.5.2
The Wing with Supersonic Leading Edges
We assume that the surface of the wing is a conical surface. From
z = h(x, y) it results that Az = h(ax, ay) and, with A = (l/x), h(x ,y ) = xh (1 , x ) = xg (x )
(8 . 5 . 2)
We deduce therefore
hr =.9 (x)
- r9 \x)
and then
H(a, b) = F (a )
Fig. 8.5.1.
.
8.5.3)
341
THE THEORY OF CONICAL MOTIONS
We shall consider now a wing with supersonic leading edges (fig.
8.5.1). Denoting by b = mla the equation of the edge OA and by b = m2a the equation of the edge OF, it is obvious that m1 < 0, m2 < 0, because on OA we have a > 0 , b < 0, and on OF, a < 0 , b > 0. Since the entire domain D is only in the zone of influence of the supersonic leading edge, for every M(a, b) the solution is given by the formula (8.4.9) where D1(a,b) is the domain limited by the curve
OAMFO, and H(a',b') will be replaced by F(µ), where b' = µa'. We have therefore to put b = ma and to replace the variables b and b`
by m and p. For M in the zone OCD we shall denote N = N2 N2 (a, ma) = N21 + N22 + N23,
(8.5.4)
where
k 1., Y-f*Jo
N21(a,m) --
1
-
ad 'a'
\J°
k
+
N23 (a, m)
m F()
1
N22(a, m) =
aa')(al-c)}dµ, c=
(a
Pa,.
'dµ+
(a - a) (c - a)
r°O F(µ)
r °'d a'
1dµ ,
Fv
14lJco
oo
aa''-c))df
(a
(8.5.5)
N21 representing the integral on OAA', N22 on OA'MF' and N23 the integral on OF'F. Performing the calculations we find: a irk
N21 = -
µ m+11
C,
arctan
it m
-
VM--\ Jt
/I F(µ)d µ
N23 = - a /"'.W 2 /m+p
ak J7-71 arccot rr m -
N22
a irk
f o
µ
,
)F(P)d,
(8.5.6)
\m+µ '+' -'1F(µ)dµa.
2µf If - /I
it
It is obvious that
f(x,Y) = (Oa + 8b)N2
(8.5.7)
342
THE SUPERSONIC STEADY FLOW
is constant on every half-line issuing from the origin. The flow is conical.
If M(a, b) is in the zone OBC, then the solution is
kJmt F(-) Jco
N2(a, m)
(a
aa')(a' - c) )
dy (8.5.8)
a
f
m
F(p) m+1dp
M17-p
A
and if M is in the zone ODE, then Ns(a, na) -
1
wk
-a 8.5.3
(p) z FlN
f.
V---14
a d a'
C
(Z
(a - a')(a' - c) (8.5.9)
"'2 P((µ) m+{A dµ, Im 11 fl
V-
The Wing with a Supersonic Leading Edge and with Another Subsonic Leading or Trailing Edge
Further we shall consider a wing having a supersonic leading edge (the
edge OB from figures 8.5.2) and another subsonic leading edge (fig. 8.5.2a)), or a subsonic trailing edge (the edge OE from fig. 8.5.2b)). In this case, the solution is obtained with the formula (8.4.15) where Dl is the domain limited by MFF'AM. For M belonging to the interior of Mach's cone i.e. M in the zone OCEO, noticing that the equation of the line FF' is a= d (it is obtained from the intersection rn of b' = b with b' = m2a') where d = a, we deduce N2 (a, m) w
i
m2
F'(µ) d
ak
mi
+.1, J0 1
+ ;k J,,,
µ
ad a' (a - a')(a' - c)
d
7
F)dµJ ' F(p)d µ rjA
(a
sa a'
+ +
(8.5.10)
a'd a' Jd
(a- a) (c - a') '
c being defined in the previous section. The interior integrals are elementary.
THE THEORY OF CONICAL MOTIONS
343
Oa
b)
a) Fig. 8.5.2.
For M in the zone OBC noticing that the intersection of the line b' =pa' with b' = b has the abscissa c, we obtain
Ni(a,m)
- ak a
ffl
dJ
,
(8.5.11) rm
F(p) m + µd
/ml 7 8.5.4
(a-&)(a'-c)
L
The Wing with Subsonic Leading Edges
When the two leading edges are subsonic, it is difficult to utilize the solution from the previous subsection. We shall use therefore Homentcovschi's idea concerning the direct integration of the equation (8.3.73).
Assuming that N(a, µa) has the form
N(a, µa) = aN(µ),
(8.5.12)
344
THE SUPERSONIC STEADY FLOW
the equation we have in view reduces to k a2N(µ)d a d µ _ 47r JJD (a - a)3/2(ma - Na)3/2 - F(m)
(8.5.13)
D being the shaded domain from figure 8.5.3. With the same notation for c (= ma/p), the equation (8.5.13) may be written as follows
/° , µ3/2 fmjV('2
4a
0
a2da d is (a - a)3/2(c - a)3/2 J (8.5.14)
N(p) J.r`
+k 47
r
a2d a {a - a)3/2 (c - a)3/2
µ'/2 Obviously, in the first integral a < c, and in the second, c < a. The interior integrals are considered in Hadamard's Finite Part sense. Taking into account the formula da
ml
f
aa
d,,=-'2
a a
0 (a
f
a)3/2
d a,
(8.5.15)
given in (D.4.3), the equation (8.5.14) may be written as follows k
a2do I -N(p)(02 )dp+ 3/2 f a a (a a)(c - a) ,ni o
k,
14
(8.5 .16)
ml N(
492
cf
143/2
0
2
a2da ld it (a - a)(c - a) / µ
We notice that in the first case (c > a), we have
f
- 4ac In fc + f - 34 (a + c) fac+ 3(a + c)2 8 f - fa
a2d a
(a - a)(c - a)
Jo
and in the second (c < a),
f V(a -a)(c-a) a2d a
`
_
3
4(a+c) ac+
3(a + c)2 - 4ac f- + f In 8
.
Vc-
(8.5.17)
The results are the same if we put under logarithm (/ - . Performing the calculations, it results that the integral equation (8.5.16) may be written as follows k
T' N) In
-2 mµ(M
+14)2}dµ=F(m) 1
(8.5.18)
THE THEORY OF CONICAL MOTIONS
345 0,
(N Fig. 8.5.3.
for ml < m < m2. We put N(p) = µNI(µ). Denoting
H(m) =
k
.,
In .IA
/./ + ///7;, t%' V''
d µ,
on the basis of the equation (8.5.18) we obtain the following differential equation
m2H"(m) + mH'(m) - 4H(m) = -F(m).
(8.5.20)
The homogeneous equation has the linearly independent solutions v/ and l//. Hence, the general solution of the equation (8.5.20) is: H(m) = 2cl frra --
202
+ Fo(m),
(8.5.21)
cl and CG2 representing constant which have to be determined, and Fo representing a particular solution of the non-homogeneous equation. From (8.5.19) and (8.5.21) we deduce the following integral equation
for Ni k fm
Nl(N) In
/ + `dµ = 2c1 VG
+ Fo(m).
(8.5.22)
Deriving with respect to m we obtain k
Ni (l+) d
7r,'µ-m
p = cl +
- + /o (m) , m
(8.5.23)
THE SUPERSONIC STEADY FLOW
346
which is the classical equation of the thin profiles. As we have already observed, from the definition of N it results that Nl (N) vanishes on the leading edge. The solution of the equation (8.5.23) which vanishes
for m = ml and m = m2 has the form (C.1.14) with a condition having the form (C.1.13). Taking also into account (B.5.8) it results ' mZ
1
fFa(µ)
Nl(m) = -7r (m - ml)(m2 -
+c2
m1){m2 -
dp N-m+
(m - ml)(m2 - m) m mlm2 (8.5.24)
The condition (C.1.13) will give
x cl +
rm
C2
mlm2
Voµ
+f
m, ( nl)(m'l -P)
d y= 0
(8.5.25)
and will be useful for the determination of the constant cl, after determining the constant c2. In fact, the constant cl is of no interest. The constant c2 which intervenes effectively in the solution (8.5.24) will be determined imposing for the solution to verify the integral equation (8.5.18). This condition is necessary because the solution was determined after some derivations. Writing the equation (8.5.18) as follows 2
T",
Nl (µ) d µ+
N1(l1) d
1
µ-m
2m
(8.5.26)
- 4m jrn, ' Nl (i)K(m, it)d /1 = - k
F( m) M3/2
where K(m, µ) is the symmetric kernel K(m, u) =
+ 1
Inl%FM-VjAI'
(8.5.27)
we notice that the equations (8.5.24) and (8.5.26) will determine the un-
knowns Nl and c2. The replacement of Nl from (8.5.24) in equation (8.5.26) leads to difficult calculations. It is necessary, for example, to know the formulas for interchanging the FP (Finite Part) with PV (Principal Value) and PV with FP (the formula of Poincar&Bertrand [A.27]).
FLAT WINOS
347
The equation (8.5.26) may be also solved numerically using the Gauss-type quadrature formulas (because N has the form N1(µ) =
(8.5.28)
(µ - ml)(m2 - A)n(p),
n(p) representing the new unknown).
Flat Wings
8.6
The Angular Wing with Supersonic Leading Edges
8.6.1
For the flat wings having the angle of attack e we have F = -e. The theory of the angular airfoil with supersonic leading edges may be
obtained from 8.5.2, putting F = -2. Since m 6 m=-, U= b,W, c=-a, a it
(8.6.1)
it results
°
ad a'
(a-a')(a'-c)
Jo
N21 (a, m)
a r 1 + m) arctan F-!A+aFT, ( 8.6.2)
-
k-v [ m -mli arctan
-
(8.6.3)
Similarly one obtains N23
m)
2ac (M -m 2
arctan
(8.6.4)
We have also a
L
a'd a'
(a-a')(c-a')
-a
Iv-
m + a rI + ml 1i) V u 2`
VrM +
and then, from (8.5.5) or directly from (8.5.6),
N22(a,m)ael,I J' ffm-1 kzr
2 .
m in Vm- +f ddµ
1
+
µ/
i
i- V M (8.6.5)
THE SUPERSONIC STEADY FLOW
348
In I we make the change of variable In this way one obtains
l1 = x and we denote vM- = q.
I=I1+g212-2g13,
(8.6.6)
where r4
11= J In x+qdx+ i:° In x+qdx=111+112, 12-
Ix-g1
ix - qj
v
2In
x
13= 11 d. +
f
x
Ix - q)
=131+132.
The integral 11, is elementary (it has an integrable singularity). One obtains (8.6.8)
111 = 2q In 2 .
The integral 121 has a strong singularity in x = 0. It must be considered in the Finite Part sense. On the basis of the formula (D.2.2) we have
12i =
f9ln(x+q)-1n(q-x)-2x/q + 2Inq x2
q
Integrating by parts, one obtains 121 =
2(ln2q+ q
1).
(8.6.9)
Using (D.2.3) we deduce (8.6.10)
131 = In q.
For calculating 112,122 and 132 we make the substitution x = 1/y and we utilize the results (8.6.8) - (8.6.10). One obtains 13 = 0, 11
2
q( -+1 q
=2g1u2+2
In
(8.6.11) 2
12=2g11n2+1) +g1n2, such that
N22(a, m) = -, /m-(2 2 + 1) .
(8.6.12)
349
FLAT WINGS
In this way, taking into account that m = b/a, the formula (8.5.4), together with (8.6.3), (8.6.4) and (8.6.12) give a
b
N2(a, b) _ -
- Zee (
-m VM1
am
b
_n2-aarctan v72
a -b -
arctan
2
-
)! -
ab) v a (2 in 2 + 1) . (8.6.13)
This is the solution when M is in the zone limited by the characteristics
OC and OD . If M(a, b) is in the domain limited by OD and OE, then we use (8.5.9). We deduce that N3 (a, b)
k
£ 7n2 (m2a
- b),
(8.6.14)
and if M is in the zone OB, OC (fig. 8.5.1) N1 (a, b) _ - k
8.6.2
b
mla
(8.6.15)
The Triangular Wing. The Calculation of the Aerodynamic Action
In order to obtain a finite action, it is necessary to consider a wing having a finite area. We assume that in the physical plane it has the triangular form from figure 8.6.1. In order to obtain a well determined wing we must give the coordinates of the points A and F. Let mi be the inclination of the line OA and ai the ordinate of the point A in the frame of reference Oa,J and m2 the inclination of the line OF and a2 the ordinate of the point F in the same frame of reference.
Then the equations of the edges OA and OF will be b = mia respectively b = n2a, and the coordinates of the points A and F respectively (ai, bi = ml al) and (a2i b2 = m2a2). The equation of the line is b = (m1 - m3)a1 + mia, where m3
_
7Tb2a2 - miai
a2 - a1
(8.6.16)
(8.6.17)
350
'rilE SUPERSONIC STEADY FLOW F(a,.b,)
Ap .e
.0
D(O.b4)
A(a,.b,) Fig. 8.6.1.
Denoting by (a3, b3) the coordinates of the point C and by (a,,, b4) the coordinates of the point D, we deduce a3=1-m1,
b3=0; a4=0, b4=(m1-9n3)a1.
(8.6.18)
As we already know, the lift is given by the formula
= L
- ffD(x.y) Bpi I d x, d yi = -PmU,2,,,Lo J1D(=.y) epO d x d y,
and the lift coefficient cL, by the formula CL = 1 L 2P0U00A
,
(8.6.19)
where A is the area of the wing and Lo, the reference wing. Taking (8.3.69) into account, passing to coordinates on characteris-
FLAT WINGS
351
tics and applying Green's formula, it results CL = - A
rf
2 o JJD(= v)
2L A
f
f (x, y)d x d y = 8 N(x, y)d x d y ax (8.6.20)
A
IJD(a, b)
(8a + ab
)N(ab)da d b =
- - Ac /eD(a,bjM (b - a)
IA 1,
where
1=11 + 12 + 13, It = JOA+AC+cd"1 d(b - a), (8.6.21) 12
13 = JoD+DF+F 3 d (b - a).
- JO C+CD+DO-2 d (b - a),
Taking (8.6.15) into account, it results
Nid(b-a)loA=0 N1d(b-a)IAC_N1d(b-a)
b=(ml -m3)a1+msn
-E(m3 - m1)(m3 -1) (a k
m1
N1d(b-a)I co=Nid(b-a)lb_o-
- ai)da
kmlada,
such that
I1
= _E(m3 km1)(m3 - 1)
at)da - £'nl
3
ada =
To
S(m3 - m1)(m3 - 1) (a3 - at)2
k -m1
2
E -m1 a3 k
2
(8.6.22)
In the same way one calculates 13. Taking into account (8.6.14), one
352
THE SUPERSONIC STEADY FLOW
obtains 13
- k -m2 2 E
443
E(n3 - 1)(m2 - 1n3) k --r n2
a!+ 2
(8.6.23)
+Eata2(m3 - 1)(m1 - m3)
k -rn2 and the problem of calculating c1, is solved.
8.6.3
The Trapezoidal Wing with Subsonic Lateral Edges
We assume that the projection of the wing (which is flat and has the angle of attack s) on the plane xOy is the isosceles trapezoid ABEF from figure 8.6.2, having the bases 21, 2L and the height h (dimensionless quantities). The direction of the unperturbed stream is perpendicular to the bases.
Fig. 8.6.2.
We consider the case a <,u. The leading edges AB and FE are subsonic and the edge AF is supersonic. We also assume that h is such that the subsonic edges are independent (for the sake of simplicity).
Obviously, in this case the fluid motion is not conical. In the domain D2 the solution may be obtained from (8.4.9), and in D1 and D3 from (8.4.15). For developing these solutions, we must characterize the domains in coordinates on characteristics. We must specify at first the
FIAT WINGS
353
physical coordinates. We introduce the parameter m by the formula
0<
h
tangy =
< tan p
.
(8.6.24)
It results therefore 0 < m < 1. The distances dl and d2 are defined bu the formulas
d1=lk,d2=d1+h.
(8.6.25)
The equations of the straight lines AB and FE are respectively
-y=l+ m(x - dj),y = t + m(x - d,).
(8.6.26)
The equation of the wing (see figure 8.6.3) is
d12d2 )
x
(8.6.27)
the function being defined on the domain D + D1 + D2 + D3 from the XOy plane:
d1 <x
-yi(x) < y < y1(x),
where (x - d1).
y1(x) = e1
(8.6.29)
k
Fig. 8.6.3.
It obviously results
H(x, y) = -c.
(8.6.30)
Passing to coordinates on characteristics we put
b-a
a+b 2
'y
2k
(8.6.31)
It results
H(a, b) = -e
(8.6.32)
354
THE SUPERSONIC STEADY FLOW
and the following equations for the sides of the domain D
AF:a+b=2d1,
BE:a+b=2d2 (8.6.33)
AB:a=2d1+mob,FE:b=2d1+moa, where we denoted mo
=
i+ m
(8 . 6 . 34)
For the vertices we deduce the following coordinates:
A = (2d1, 0), B = (d2 + kL, d2 - U), (8.6.35)
F= (0,2d1),E= (d2 -kL,d2+kL). Taking (8.4.9) into account, we deduce for the solution in D2 a kir
N2(a,b)
da'
1-b
db' f a - a' J2d1 -a, %Fb - b'
(8.6.36)
=-1(a+b-2d1). The solution in D1 is given by (8.4.15). Noticing that A(b) = 2d1 - b,
B(a) = 2d1 - a,
(8.6.37)
it results Nl
(a'
er
b)
krr
d b' , -4
b
a
da' b' Jet -V a - a'
(8.6.38)
Obviously, this expression may be obtained from (8.6.36), changing a with b. Hence
N1(a,b) = -1(a + b - 2d1)
(8.6.39)
and an identical expression for N3(a, b) (because of the symmetry). According to (8.6.20), for cL we have the expression 2
CL = - kA
(8.6.40)
where
I= POD N(a + b - 2dj)d (b - a)
-
(a + b - 2d1)d (b - a) = (1- m02)(d2 - kL)2. AB+BE+EF
FLAT WINGS
355
The Trapezoidal Wing with Lateral Supersonic Edges
8.6.4
We consider an isoeoelea trapezium with the bases having the length
2L respectively 2t perpendicular on the direction of the stream at infinity (fig. 8.6.4). We Introduce here again the parameter m defined by the relation:
k-tana=Lht>tanw=k
(8.6.41)
F. 8.6.4.
Obviously, m > 1. Denoting by dl the distance from the small basis to 0 and by d2 the distance corresponding to the great basis, we obviously have d2 = dl + h, and for the c arte ian coordinates of the vertices of the trapezium
A = (d,, t), B = (da, -L), F = (dl, t), E = (d2, L)
(8.6.42)
The coordinates on characteristics are obtained from the formulas,
a=x-ky, b=x+ky. No ti c i ng
th a t
(8.6.43)
d2 = kL, we ded uce A = (di + kt, dl - kt),
B = (2kL, 0)
F = (dl - kt, dl + kt),
E _ (0, 2kL)
(8.6.44)
356
THE SUPERSONIC STEADY FLOW
Using the notation
d1-k£ d1+2h-k8
k
2
k-1
m+1
(8.6.45)
and observing that from figure 8.6.4 we have the compatibility condition ao < p, which implies
dl = tan ao < tan p =
1
dl > kt,
(8.6.46)
we deduce 0 < k < 1. Now, the equations of the sides of the trapezium may be written as follows
AB :a+kb=2d2iFE: k-la +b=2d2, (8.6.47)
BE:a+b=2d2,AF:a+b=2d1. The entire leading edge is supersonic. The solution may be expressed by means of the formula (8.4.9). To this aim it is necessary to specify
the functions a = A(#) and A = B(a). We have: - on the edge BA, b .- BI(a) = -- on the edge AF,
2d2
a,
a = Bi 1(b) = 2d2 - kb, (8.6.48)
b = B2(a) = 2d1- a,
a=
t
1
}=Li_b.
We must also observe that for determining the lift coefficient we do not need N(a, b) on the entire wing, but only on the trailing edge BE. Indeed, this may be expressed with the formula (8.6.20), and N on the leading edge BAFE vanishes as we have already mentioned in formula (8.3.68). The domains of influence are (fig. 8.6.3) : D1 = ABA'A,
D2 = AA'A"A,
Do = AA"F"A,
D3 = FF"F'F, D4 = FF'EF Hence, we shall put
I=11-+-12+I3+ 14,
(8.6.49)
FLAT WINGS
357
where
r
it = J
BA'
I. = r
JA"F"
14 =
JF"F.
12 = f
Ni (a, b)d (b - a),
JA'A"
No(a, b)d (b -- a). 13 = J
Ni (a, b)d (b - a)
"F'
N2 (a, b)d (b - a),
N3(a, b)d (b - a),
(8.6.50)
.
Using the formula (8.4.9) and the equations (8.6.47), we deduce
__ 8
N1 (a'b)IBA' =
N2 (a, b)IA'A#l
a
k
,l Bt I(b)
E
Tr -
Bi (b)
No= -h, N4=
-,-(I -
da' Ilrb dillu a -a' B,(u') vb - v 1,9A'
da' a - a'
b
JB2(n')
_eb(l-k)
db' b - b' L'A" - ... ,
)a
After elementary calculations we deduce: E(I - k)
11 = 14
and finally,
k2
k.
f
d2-"-h
bdb
e(1 - k) (dl - kf)
= k2 Vk-
2
4Eh = - E(1- k) (d1 -2kt)2 ' to =-k2 (k£ - h),
2'
kv-.
Chapter 9 The Steady Transonic Flow
The Equations of the Transonic Flow
9.1 9.1.1
The Presence of the Transonic Flow
We call transonic flow the flow which is subsonic in a domain of the space and supersonic in the adjacent domain. One demonstrates (for the potential flow - see [1.21] pp 517, 518) that the equality v = c comes true in E2 only on curves separating the domains where the flow is subsonic from the domains where the flow is supersonic, and in E3 on the surfaces which separate such domains. The name of transonic flow was introduced by Th. von in 1947.
In the present paper the transonic flow has been encountered in several situations. At first, we have to mention the one-dimensional flow [1.11] §4.5.
The formula (4.5.8) which gives the variation of the velocity against tile variation of the cross section indicates that, in the subsonic flow (Al < 1). the velocity increases when the area decreases and decreases when area increases (like ca in the incompressible fluid), while in the supersonic flow (M > 1) the variations are produced in the same sense. This circumstance leads to the conclusion that in a tube having the shape from figure 9.1.1 the flow may become transonic. To this aim it is sufficient for the upstream subsonic velocity to have the critical value in the section of minimum area. Further since the area of the section increases, the velocity also increases, remaining supersonic. In the linearized theory we deduced for the aerodynamic action the
formulas (3.1.33) and (3.1.34) in the subsonic case and (8.1.9) in the supersonic case. It is obvious that these formulas are not valid in the vicinity of A! = 1. For the flat plate these formulas become (3.1.35) and (8.1.22). The figures (3.1.3) and (8.1.3) are very suggestive. In the cause of the subsonic flow with great velocity past thick bodies like in figure 9.1.2. the flow may become transonic. Indeed, considering
THE STEADY 'TRANSONIC FLOW
360
Fig. 9.1.1.
the flow between the streamline which includes the boundary and a neighbor streamline L, we shall find that the flow is like in a tube. Since the domain between these lines narrows because of the body, it
Fig. 9.1.2.
follows that in the vicinity of the body the flow nay become supersonic. The transition from the supersonic flow to the subsonic flow is performed
by a shock wave S according to the scheme described in 1.3.6. Until S the flow is transonic. We shall deduce in the sequel the equations which describe this flow. The flow with great subsonic velocity past thick bodies is described by the scheme from 9.1.3.
-> V
y« r- Loctaau Fig. 9.1.3.
Finally, in the supersonic flow, for great velocities, practically in the
hypersonic regime, it appears, as we noticed in 1.3.6, detachedor at-
361
THE EQUATIONS OF THE, TRANSONIC FLOW
tached shock waves (figure 1.3.5). Behind these waves the flow is transonic (it passes from the subsonic regime (A,12 < 1) to the supersonic one (A12 > 1)). As we could see, in modern aerodynamics the transonic regime is frequent. So one explains the great number of papers devoted to this subject in the last years. We mention especially the papers of Bauer,
Garabedian and Korn [9.1] devoted to the theory of minimum drag wings. There are three dominant methods for studying the transonic flow, namely:
1° the hodagmph medwd, suitable only for the plane steady jet flow (see for example Ferrari and Tricomi [9.11], Manwell [9.30], [9.31] etc.);
2° direct analytical methods, based on the semi-linearized equation of the potential. They lead to integral equations which may be solved numerically;
3° numerical methods applied directly to the system of equations which describes the fluid flow (we mention especially the finite elements method). In this chapter we present some direct analytic methods.
9.1.2
The Equation of the Potential
The reasoning based on the assumption that the independent variables x, y, z have the same role in the structure of gyp, (utilized for deducing the equation (2.1.39)), is not valid for the flow in the vicinity of M = 1. Indeed, in this vicinity M2 - 1 becomes itself a small
parameter. If, for example AI2 - 1 = O(E), then for V_: = 0(cp) it results +p.y and W.'. = 0(E2). One imposes an analysis of the order of magnitude of the perturbations depending on the geometry of the body and the conditions which determine the flow (Mach's number Al, the thickness and length parameters, the angle of attack, etc.). In fact, the idea that the variables y and z do not behave like the variable x.
results from the special property of the Ox axis (which is parallel to the direction on the unperturbed stream). We shall introduce therefore the variables y = u(E)y.
4 = V(C)Z,
(9.1.1)
expecting for vv(e), like for q(r) from the expansion Or, Y. Z' `) = U (x + T (E),(x, J, <_) +
... ]
to be determined by comparing the orders of magnitude.
(9.1.2)
362
THE STEADY TRANSONIC FLOW
Coining back to the linearized theory 2.1, we notice that for Al = = 1 a catastrophe is produced (it disappears terms from the equations). The lift and moment coefficients become therefore infinite. But this catastrophe has only a mathematical nature, not a physical one. It is
determined by the fact that in the vicinity of the value Af = 1, the order of magnitude of all the first order derivatives is not the same (E). One imposes therefore (9.1.1). It results
0r=U(1+1150:+...),OS,=U1)v
+...,O:=Urpi (9.1.3)
Orr = UtWrr,
Ory = UTJVP,,y,
0, = Ugv2 ;OW .
From (1.2.17) we deduce c2 = c2 -
(7 - l )U2>);pr + 0(112) ,
(9.1.4)
and from (1.2.16) written explicitly as follows
(r.2¢r).o +(C?-0y)Oyy-20=.ysOv+...=0,
(9.1.5)
we deduce
[1 - M2 -(y + 1)(M2 -
(y +
+ [1 _ (y - 1)(Af
0(7)2)l(p=r+
(y - I)W=)v2 y-
(9.1.6)
- 2M2vrl2"o + 0(1j2v2) + ... = 0. For a fixed Al , we see that the equation is consistent if ii --+ 0 when
q-'0,so
v2, t), 1- M2_ 71.
(9.1.7)
We introduce now the boundary condition. If z = eh.(x, y)
(9.1.8)
is the equation of the perturbing surface, imposing the condition to be a material surface i.e. Eh=dOr + Eh,,Oy = &
which implies, taking into account (9.1.2) Eh. =
(9.1.9)
THE EQUATIONS OF THE TRANSONIC FLOW
363
whence
E = 9V.
(9.1.10)
Taking (9.1.7) into account, we deduce
t)=E2'3
V=Et13
(9.1.11)
When M - I
we have to compare. in (9.1.6) the terms of order immediately superior to those which gave (9.1.7). It results I - M2 = = Kv2 whence
K-
_ hl2
1 .
(9.1.12)
.
K is called the parameter of the transonic similitude. In this way, the first approximation from (9.1.6) (the dominant equation) is
[K - (7 +
rpyp + 4p: = 0.
(9.1.13)
This is the equation of the transonic flow (the equation of the potential). It is elliptic if Cpl < K/(7 + 1) and hyperbolic if gyp= > K/(y + 1). The relation V_ = If/(-y + 1) is verified on the surface where
V2 = c2. Indeed, using the notations (2.1.3), and taking (1.3.32) into account, the condition V2 = c2 becomes
V2=c2=co-7 v;2=cam- 1 o (Vt2-U2).
(9.1.14)
Here, the dominant relation is u2 1+2 u, } = c2 - (7 - 1)U2vu,
(9.1.15)
T
whence ii = K/(7 + 1). Now it is clear that the non - linearity is necessary for making this transition possible.
The first study of the transonic flow has been performed by von Karmsui [9.26). By various methods the problem was investigated by Ovsiannikov [9.531, Guderley [9.15), Cole & Messiter [9.6[ etc. Cole's study from 1975 relying on the method of perturbations was continued by the same author in 1978. In the last study one proves that if we denote by s the thickness parameter and we set for the cross sections
y-Et13y, =-E113' , then the potential 0 has the following structure [9.54]:
4)(i',y,4;Al ,Q,b,b) = U[z+E2/39(x,V,z;K,A,B)+ (9.1.16)
+E413 t'2(x, y, Z; K, A, B) + ...,
,
364
TilE STEADY TRANSONIC FLOW
where K is the transonic parameter (9.1.12), A, the parameter of the angle of attack = aft, and 13, the span parameter = 6e113. For p one obtains the equation (9.1.13).
9.1.3
The System of Transonic Flow
It is rigorous to perform the asymptotic analysis on the system of equations and not on the equation of the potential which has been obtained from the system by derivation with respect to the x, y, z coordinates. We present here such an analysis which was performed together with professor A. Halanay in the years '80. We utilize the coordinates y and r in the form (9.1.1) and we denote E)
=v
\x' V(E) , +'7 (E)
)'
h(x, y,
E) = h (x,
(9.1.17)
It results r"(X,j/,E)
= it , x,
h,
V(£)
(2-,
y(E)/ V(E)
and the boundary condition Elts(x, y) 11 + u(x, y, Eh(x, y))] + Eh' ,(x, y)v(x, y, eh(x, y))
_
= w(x, y, Eh (x, y))
becomes
X.
(r, y,
c) [1 + u (1', lI, - h(x, P, E), E)] +
+sv(E)hV(x, N, 0V (x, /,
TU
_ S,fj,
E
_
v(E)-(x'v,
ll
v(s)h(x,p,E),EJ
The dominant term in the first member would be Ehx(x4, E) if 9 would not disturb. But for a small p we have hr (x, y) E) =1t= (T, vVE) )
=
hx (x, 0) + Y( h=y(x, 0) +
r)
...
From the physical conditions of the problem it results that le, (x, 0) 74 0.
365
THE EQUATIONS OF THE TRANSONIC FLOW
The condition (9.1.18) suggests that the right hand and member has the order of c. Hence, w (x,
v(E)
h(x, y, e) J = Eii (X,
h(x, b,
v{s)
E)>
E
(9.1.19)
We assume that this is valid in the entire domain occupied by the fluid, i.e.:
i (x,y,',E) = ew(x,y,;F,E).
(9.1.20)
Taking (9.1.19) into account, from (9.1.18) we retain in the first approximation, under the hypothesis that v(E) --+0
111 +u(x,y,0,e)] = ii (x,y,0,E)
(9.1.21)
Using the notations (2.1.3) the system which determines the perturbation produced by a fixed body in the uniform flow of a compressible fluid characterized by M is determined (see (2.1.10) - (2.1.13)) by the system (9.1.22) (1 + p)M2p = (1 +7M2p)p M2p + (1 + yM2)div v = 0
(9.1.23)
(1+p)v+gradp=0
(9.1.24)
where
[(1+u
a
8
)8x+vp,....
(9.1.25)
We notice now that from the structure
p x,
(9.1.26)
v(E)
it results the formulas Op Ox
_ Op ap _ Ox ' 8g
Op Op v(e) 8y ' 8~ I
1
Op
v(e) Oz '
(9.1.27)
which will be replaced in the projections of the equation (9.1.24) on the axes of coordinates. In this way, the projection on Oz gives r
here
Comparing
thu8x
8w Op +evVOw +e2vw +v !=0.
(9.1.28)
the dominant terms we deduce that P(x, y, =, E) =
v(E)
'lx,
, z, £)
1
(9.1.29)
THE STEADY TRANSONIC FLOW
366
and from (9.1.28) one retains
(1+p)(1+u)8 +-=0.
(9.1.30)
Analogously, from the projection of the equation (9.1.24) on the Oy axis, it results
+v(E)v-+EV(E)w-J +E
v8/
=0,
(9.1.31)
From this equation it follows v(x, y, z, E) = 6(x, T, z, E)
and then (1 +;5)(1 + u)
(9.1.32)
e + 5i = 0.
(9.1.33)
At last, the projection of the equation (9.1.24) on the Ox axis gives (1 + P)
}- EYi
1(1 + u)
GIV
zi + EvUI
v(E)
= 0,
whence we obtain 11(X,
Y(E)
u(x,
(9.1.34)
and then
89 = 0 . (9.1.35) + P) Fx + 8x The behaviour (9.1.34) determines for (9.1.33) and (9.1.30) the forms: (1
8; + 8y =0,
(1+P)LW
(1+P)WV +-=0,
8x
(9.1.36)
and the boundary condition (9.1.21) determines the equality
K(x,y,E) = 10(x,9,0,E) which implies hx(x, y) = w(x, y, 0) .
(9.1.37)
Knowing that M2 = 1 constitutes a singularity, we shall consider in (9.1.22) and (9.1.23) M2 = I + µ and we shall keep the dominant
367
THE EQUATIONS OF THE TRANSONIC FLOW
terms for a small p . Utilizing the previous results, the equation (9.1.22) becomes
l+YU1a+£vu+evrI [1+-1(1+µ)EPI 11
p
+EVWF
K
whence we deduce
4
7
v e Pox,
,
(9 . 1 . 38)
and then
89 = ap . (9.1.39) 8x 8x Having in view the damping condition at infinity for the perturbation, from the last equation we deduce
p =P-
(9.1.40)
Taking the relation (9.1.38) into account, it results that the dominant parts in the equations (9.1.35) and (9.1.36) are
8
+8 =0, 8 + =0, 8 F=0,
(9.1.41)
whence it results
u=-p,
ex
-=0, -=0.
(9.1.42)
Z
Finally, from the equation (9.1.23) written as follows
(1+µ){I1+ _u) 2ff +EVv V
ax
+£VW
+
+[l+ry(1+µ)ipj[+2+v] =0 ax ay 6F we obtain, if we have in view
(µ+vu+µv +'Y(1+µ)vpe
(9.1.41)1,
+(1+µ)EV(v +10 Lv) + ax 8Y ft 4rV
&0
0.
368
THE STEADY TRANSONIC FLOW
The dominant part is obtained from the linear terms. We may write therefore P
\µ+;u}
49V
+7vpax+uj( O-V + E
E
v
v
az-
J
0,
(9.1.43)
and the residual equation
(-K+u) 2E +YpBx+ a +a =0. Bxp
(9.1.44)
At last, from (9.1.43), (9.1.44) and (9.1.42) one obtains
K=
v(£) _ £1/3
try
r?x
1 - M2 £2/3
tr =0.
(9.1.45)
(9.1.4G
)
This equation, together with the equations (9.1.42) constitutes the gen-
eral system of equations of the steady transonic flow. In the x, V, z space the equations (9.1.42) give the irrotational conditionof the velocity of coordinates (u, u, is). Introducing the potential jp(x, ji, -_,F) by means of the formulas u = c0*,
V = cpy,
w = Pz'
(9.1.47)
one obtains (9.1.13) from (9.1.46).
9.1.4 The Shock Equations In the case of the flow with shock waves, from the integral form of the equations of motion (9.1.42) and (9.1.46), written in the conservative form (by means of the div operator),
vi+(-u)y=0, vas+(-u): =0 r f Kii I
(9.1.48)
- L+-'iP 2
+i%+urf=0, 1 :
369
THE PLANE FLOW
integrating on every domain which contains the shock surface and passing to the limit as usually, it results [i1n+: [IKu
-
- Qulny = 0, 9wf ns - QiiOnr = 0, 7+ 2
(9.1.49)
421% + Ovlny + OwOny = 0,
where n=, ny, n1 are the coordinates of the normal to the shock surface, i.e.
n;r = (d7jdz)
ny = (d-zdx)
ns = (dxd-y), .
(9.1.50)
If, for example, the parametric equations of the shock surface are x = x(A1, A2),
11=
A2),
z = {ai, 2) ,
then from n = da1z x da3X, it results n=
9.2
"2
8a1 812
"Z
8a1
dJ11da2i
... .
(9.1.51)
The Plane Flow
9.2.1
The Fundamental Solution
\Ve consider. like in Chapter 3, that an uniform stream, having the Mach number M is perturbed by the presence of an infinite cylindrical body, with the generatrices perpendicular on the direction of the stream
which coincides with the Ox axis. The Oy axis is in the section perpendicular to the generatrix. Let
y=h*(x),
1xI <1
(9.2.1)
be the equations of the profile determined by the cross section. Our aim is to determine the perturbation and the action of the fluid against the profile.
The flow is obviously plane. The velocity will lie in the xOy plane and will not depend on the variable z. Taking into account the orientation of the axes, we deduce from (9.1.37) the boundary condition v(x, ±0) = h' (x),
jxI < 1.
(9.2.2)
370
THE STEADY TRANSONIC FLOW
According to (9.1.42) and (9.1.46), the perturbation will be determined by the equations
il = -n i y - vs = 0,
(9.2.3)
Kit= + ij = ( + 1) uit= .
(9.2.4)
Using the change of variables
y=fl?i, u'=VY u,
(9.2.5)
we reduce the system (9.2.4) to
NO 8 ay-ax=0' ax
a
86
NO
2 gay=kaxu,
9.2.6
)
where we denote ry + I = 2kK3/2. In the sequel we shall integrate the system (9.2.6) without writing the marks *;' any longer. The fundamental solution of this system is determined by the equations au ay
av
8u
a
8u
- ax = ld(x, Y), ax + ay = k ax u2 + m (x, y) .
(9.2.7)
For the Fourier transforms u and v one obtains the formulas
-ial£+ia2n+kala2F
tl =
a2
a2
,
(9.2.8)
where F = F[u2 ], a2 = a + a2. We take into account the formulas F-'
a2,
-
i _ 2a In ro - e, ro = !LA
x2 + y2 (9.2.9)
F-1
[F]
4",
u2 * e
11
t d ri,
tt
where u2 * c is the convolution product and r =
+ yo,
xo = x - C YO=Y-71-
(9.2.10)
From (9.2.8) it results
1 mx + ly
u(x, y) = 21r x2 + 2 +
k
8J
ax
xo rJ)
r2
d (9.2.11)
1 My-ex
v(x, y) = 2ir x2 + y2
u2 s
+ 2 ax
fJasr
*1)
d d il .
371
THE PLANE FLOW
Obviously, the last integrals are singular. They have the shape (E.3). Isolating the singular point (x, y) with a circle having the radius a and setting f = xo/r and respectively yo/r we deduce that the condition (E.5) is satisfied and the integrals are singular. Also, from the formula (E.10) we getr
I = Ox / f z =
+7) r0 d d rl =
2U2
JJ.
J=a JIz
(n)df dn,
II2
(9.2.12)
or, performing the calculations,
=Jju2(,q)dxd,7_,ru2(x,y) 17y0r4x0J
I
(9.2.13) U2(t,11)x2
=-ff 9.2.2
2dOdx
dn.
The General Solution
Replacing the profile by a perturbing distribution defined on the segment (--1, +1) (the chord of the profile), it results the following general representation of the perturbation:
u(x, y) =
1
1
27r
40Y + m(Oxo
P-1
O2
-}- y 2
k d t + 2n I , (9.2.14)
1
v(x, y) = 2a 1
+1 m(E)v - f(F)xn 1
0
-
k -
T2r
Taking into account that xo + y2 = (xo - i y)(xo + i y),
xo + yo = (xo - i yo)(xo t i yo) ,
for complex velocity
w(z) = u(x, y) - i v(x, Y),
372
TUE STEADY TRANSONIC FLOW
it results the following formula: W(y)
=
1
+i
2k L(-),
M(C) +i
2
(9.2.15)
where
ata JJ
=
u2( F''1)L(z)
Z-(
1,
and
_=x+ir1, In order to impose the conditions (9.2.2) we shall pass to the limit on the segment [-1, +11. Using Plemelj's formulas we obtain from (9.2.15)
u(x, f0) - i v(x, f0) = T 2 [rrt(x) + i e(x)] + (9.2.16)
1
+ 'IrJr+l m(O + i e(f) xo
k 0 If r u2(t, 71) d
d +27r OxJf T x-
do
whence
k 0 f/ 2 +2;r 8a R su
xa
4
,dl; r1`
(9.2.17) ' +1
v(x, ±0) = ± m(x)
- 2n 11 zn) d £-
49
-2 a_JJ
2d dn.
It results
e(x) = u(x, +0) - u(x, -0) = K (p(x, -0) - p(x, +0)1.
(9.2.18)
The function l(x) will determine therefore the lift. Imposing the conditions (9.2.2) we shall obtain
m(x) = h+(x) - h' (x) twt h`(x),
lxj < 1
(9.2.19)
373
THE PLANE FLOW
' +t
w 8x fir ul{t,*))
J-t
dd dn+
o
(9.2.20)
C(Z), IxI < 1,
+h+(x)
where we have utilized the notation h+(x) = h+(x) + h'-(x). The relation (9.2.19) determines the unknown m(z). Considering that G(x) is known, the equation (9.2.20) determines f with the aid of the formula (C.1.9)
t(x) -_ 1
Vi- a
l+z
7r
1-z
1
/;:E t h+(t) d t-
l+t 8
+1
l+xJ_
n
1
-t t - x k
d
1-t 8t
)2+tp}
dt
t-x' (9.2.21)
Noticing that according to the formulas (B.5.3) and (B.5.4) we have
f+l 1-t dl: t-.z(1+ t-z
dt
1
(9.2.22)
-J
1-4 df ) a 1+4f-t t-z
+1
1 VEZ+ 1
and, after replacing (9.2.21) in (9.2.15), it results W(Z)
+t
1
C (9.2.23)
z- 1 1 tai z+
+l 1
1+ t h+(t)
1-t
dtk
k
t-z+2L(z)-wM(z),
where we denoted
M(z)
-M
z
+1J 1 1
1+trd fr 1
n dCdr1 ( - t)2 +V2
z
t d t Jf u ('*1) (9.2.24)
dt
--:
the formula coinciding with (4.11) from [9.21].
TIIE STEADY TRANSONIC FLOW
374
In the sequel we shall deal with M(z). We may write
M(')
7ri
z + I f12 u2(f, q)
ltd
f+1 {
,
q
1-t8t (t-t)2+q2,
dt
t-z1dq
1
7n
x
1
z+1
+1
ILl (F, q)' 2
The last integral is calculated by Homentcovschi by means of the residue
theorem. It may be calculated elementary noticing that we have q
1
1
1
t-z - 2i((-z) t - (-
(t-e)2+
rt
1
1
1
2i((-z) t-(+((-z)2+q2 t-z and taking (B.5.1) into account. It results
_ M(z)
1
z+lIir z
1
u2((,ri)8
1
1
I(1_ +
We write the first integral as follows
If u'(t,n) I
1
dt drt_
1
z
C1z s±i u2(E,17)-u2(t,-17) C-z JJR2
r
1
_
and the second
8z 11.2 u2(t,q)( (1-z
(1 z}d(dq
1
}dtdn,
THE PLANE FLOW
375
=
Jf/f
u2(
((- z)2
JJR2
We have therefore +00
M(z) = 2 If [u2(.7,) - u2(C, -t1)] K(z,C)dC d tj-00
(9.2.25) 1
+00u2(t, n)
-2rJ -00
u2(C, -n)
((-z)2
d d tj,
where
K(z'
}
_
z
1
z+1
(+1
1
_
C - 1 L(S - z)2
1
(9.2.26)
(C - z)(C2
Taking also (9.2.13) and (9.2.14) into account, we have that y02 -x02 +2ix°y°
1
(C - z)2 ,
H
L(z) = I - i J = -7ru2(x, y) - IL
(9.2.27)
' 'ddrj.
(9.2.28)
(C - Z)2
We replace the expressions (9.2.25) and (9.2.27) by (9.2.23) and we obtain the complex velocity. Separating the real part of the complex velocity, we obtain the integral equation of the problem. We have:
'j,
+1
u(x, y) =
--fl 1
h
1
l
4tr
l+th+(t) t
x2 + y2
d
z+l 1- z+l z
1t-z
VE
1
i t-; jdt+ (9.2.29)
+00
+2I(x,Y)-$ JJ
q)
[K(z,c)
-00
+K(,)]d drj+ !T[u2(1
yor4x°dC
dn
This equation, was given in a slightly different form by Homentcovschi in [9.211.
376
THE STEADY TRANSONIC FLOW
9.2.3
The Lift Coefficient
From (9.2.18) we deduce the following formula for the lift coefficient +1
1
c
+I V=x
1 fKl-te(x)dy
t+( )dt
' +t 1+ t
r
l+z .!_t
dx- ;2/ k J
+t v=1
x
l+x
i-t (9.2.30)
We have
J
R3u2(frn)5
[(t-t)2+
n21dfdtl
u2(f,8tn)t-( '( 1-t--( 1)dtdn
2i1 JJ .2 1
-2i J2
(9.2.31)
u2(f.n)-u2(f,-n)df do
(t-()2
From (B.5.1), derivating, it results:
l+t
t
1
dt
1
1-t (t-f)2
it
1
(9.2.32)
f-1 (2_1
Using these results we obtain cp
7K 1
2i
9.2.4
j k
I-t
hf (t)d t(9.2.33)
rJ u2(f+n) - u2(f, -n) d f do S-1
JJets
f-1
.
The Symmetric Wing
If the wing is symmetric, then the equations (9.2.1) have the form
y = ±h(x)
(9.2.34)
377
THE PLANE FLOW
From the boundary conditions (9.2.2) we have the relation
v(x, +0) = -v(x, -0) which suggests that the solution of the system (9.2.6) has the property
v(x, y) = -v(x, -y) . (9.2.35) We easily check that if u(x, y), v(x, y) is a solution of the system (9.2.6), then u(x, -y), -v(x, -y) also have this property. By virtue of u(x, y) = u(x, -y),
the uniqueness theorem it results (9.2.35) whence u2(x, rj) = u2(t, The integral equation (9.2.29) receives the form +1
ff(t)
-To
d4+ (9.2.36)
+2
Z
if
dn-u2(x,y),
JJ00
given for the first time by Oswatitsch (9.491. Obviously, the lift coefficient vanishes. The result is natural because the angle of attack of the wing is zero.
9.2.5 The Solution in Real We shall present a solution which is different from Hamentcovschi's solution which utilizes the complex velocity. Using the formulas (3.1.19) and (3.1.20), one obtains from the general solution (9.2.14): u(x, ±0) =
±-t(x) + Zx I
(ssd s +
J
v(x,f0) = f2m(x) - 2R ,r+t
k I (X, ±0), T7r
ds+ 2 J(x, ±0),
(9.2.37)
-1<s<1, where
I(x, t0)
.2
J(x, ±0) = 2JJu
2- Z
0° + n2)2 d t d it
- iru2(x, f0)
,
dri, -00 < ,n < 00. (9.2.38)
378
THE STEADY TRANSONIC FLOW
We obtain the formula (9.2.18), and from the boundary conditions (9.2.2)
m(x) = h- (x) 1
e(s)
JJ
s-x
7r
(9.2.39)
d s = h+(x) - kJ(z, 10), w
1xI < 1.
(9.2.40)
By means of the formula (C.1.9) we deduce
r+
£(z) - -V1:11 x
l+x
n
+ t h+(t)d
1-tt-x
t+ (9.2.41)
1+ t J(t, f0)
+as 1+z
1-i t-x
1
dt
.
For obtaining the integral equation of the problem, we shall replace m and t in (9.2.14)1. We shall denote by s the superposition variable from the first integrals (9.2.14) and xt = x - s. Changing the order of integration, we deduce
1+t 1&+(t)N(3, t)d t-
+1
u(x, y) = 27ra
J-1i
y
-27r y T2
,
f
1
± t J(t, ±0)N(x, y, t)d t+
(9.2.42)
k +2R I+1x2+ 2ds+2-I(x,y), x1 r -- s, 1
I
1
where we denoted
N(x, y, t) =
f+i V1 -s 1+s J 1
Since 1
x
I
ds
y2 s-t
(9.2.43)
1 fl is 1J + s-t z-z t- s-z t-z s-x 1
1
1
1
1
1
(x-t)2+y2 s-t' taking the formulas (B.5.3) and (B.5.4) into account, we deduce
N
n
x-z
(
1
t-I
'z-1+1
t
1 `+111. z -x
(9.2.44)
379
THE PLANE FLOW
Let us calculate nw the term
T =1
i + J(t, f0)N(x, y, t)d t . t
i
(9.2.45)
To this aim we shall specify J(t, f0). Taking into account (9.2.13) and the identity 2h7
1
t-C - t
(t-w +
1
we deduce
J(x, ±0) =
- JJ
rlLe2(F,
18 iT 3i 1
1+I
2i
1C-t C)dCdq=
f
_
and then I
ldfdq=
v))!
IL
ifm
(9.2.46)
u2(Cn)-UU(E,-11)ded+l=
t-(
u2(E,11)
- U'(C, -WdC dq
( t-C)2
dil} (t- u2(e,-17)dt - C)2iy
l +t VI u2(F,17)
1-t
1
,
x
.
(9.2.47)
s
1
l
1
1
t -z z+l t--l+1
cit.
Changing the order of integration and denoting
IPTE
To(C, Z) = El N 1
1
t, t (t i()2 t zd
(9.2.48)
we deduce
T
If 4Y
JJ*3
[ j2((, +1)
- U2(t, -n)1 [To((z)J4_ (9.2.49)
-To(CIT) FT 711
3+1 jddti
380
THE STEADY TRANSONIC FLOW
for specifying the function To we notice that I
t
1
(t-C)2 j---Z 1
+[Z
1
_
1
(t
((Z
1
- ()2 1
1
1
z-( (z-S)2 t-C+(z-()2
Taking (B.5.1) into account , one obtains
1+1 -
A To(C,z) _ (z - ()2
,r
-
1
-
z+1
n (z - C)2
z
1
- 1
-
1+S
d
z-C dC C-1' (9.2.50)
The term T which intervenes in the integral equation (9.2.42) has therefore the form (9.2.49) where To It is given by the formula (9.2.50). Using the expression (9.2.41) for the lift coefficient cL =
JJt(x)dx
(9.2.51)
one obtains the formula 1
CL
k +i
ai
-VrJ1
FI+- ft+(t)dt+7Vn f
i+tJ(t,±0)dt.
1
(9.2.52)
The function J(t, f0) is given in (9.2.46). For calculating the last term we change the order of integration and we take the formula (9.2.32) into account. One obtains the formula (9.2.33).
9.2.6
The Symmetric Wing
We gave in (9.2.36) the equation of Oswatitsch for the symmetric wing. We obtained this equation from the general theory presented in (9.2.2). We present here the direct deduction based on the equation of the potential cpn + lpyy = lops
which may be obtained from (9.1.13) or (9.2.6).
(9.2.53)
381
THE PLANE FLOW
The fundamental solution is defined by the equation
Eu+EI,o, =k
49 E.3
+m6(x,y).
(9.2.54)
Applying the Fourier transform it results
(a2+a4)E=iaikF-m, F- 9e ], whence
ia1F
al
m
aFI+ a
and then
-F rl -k 2 ax
F
f f
ll
- mF-1 [-
]
.
(9.2.55)
1
al +a2 -71+072 Applying the convolution theorem (A.6.13) and taking (A.7.11) into account, we obtain 8
F-l
r. (_ '
[-'r
a14J
s
47r
(+
+ao
--4, f f E=(t,q)ln(xo+14)dCdn, -00
such that +*0 E
= + 7r JJ
-6. 2(4, n)
ax
f d f d n + 4n ln(x2 + y2).
(9.2.56)
-00
Replacing the wing with a continuous distribution of perturbation sources defined on the chord of the profile (only in the symmetric case
the sources distribution is sufficient), from (9.2.56) it results, in the domain occupied by the fluid, the following general representation of the solution of the equation (9.2.53):
'P(z,y) = I
fl
m(f)ht{so+y2}dC +
j;
ffR?u2(t,n)
X0
PO +
y dt dn, (9.2.57)
where in(k) is a function which has to be determined by the shape of the profile, i.e. by the boundary condition
v(x, f0) = ±h'(x), x E [0, 1],
(9.2.58)
382
THE STEADY TRANSONIC FLOW
which is imposed by (9.2.34). From (9.2.57) we deduce
1+1 0 + y2 (9.2.59)
f+1
v=SPY= 2rr
xo
y2
where
I = ff
po d 4' d ii
u2 (4, n) x2
(9.2.60)
.
The singular integral I has the shape (E.9). Applying the formula (E.10) we deduce
1= fju2(f,rl)8x (x o+ f2fR2 x2
-
u2(4, 11)
Jdt;dn-aru2(x,y) o
2
/
(xd {
d *1- 7ru2(x, y)
+ y02)2
(9.2.61)
,
I=-2 ffzu2(t,,1)(xo Hence we have the following representation of the solution
u(x, y) =
1
+1
/-1
xo
z0 + y2 d
2 f fR2 u2 v, r+t
v(x, y) = T
!-1
- +y 2
rl)
(x o
z
d Cd +1-
k
d t- fJ uz
m(C) xo
2uz(x, y)
,
x2y2 n) (xo + y02)2 d
dn
(9.2.62)
which is also given in (9.2.14). The boundary values of the first integrals are given in (3.1.19) and (3.1.20). We obtain therefore
v(xi f 0) = f2rn(x) +
11 ir
u2(f,rl)
2
(xz + 2)2dt d>l. o
(9.2.63)
383
THE THREE-DIMENSIONAL FLOW
Imposing the boundary conditions (9.2.58) we find +oo
II
u2V,77)
22'°'1d d drl> (ro+r1)
(9.2.64)
u2(x, y) = u2(x, -y)
(9.2.65)
whence we deduce 17) = u2(s, -+l)
Taking into account (9.2.63) and the previous relation, it results
m(x) = 2h'(x).
(9.2.66)
In this way we determine the distribution m. Coming back to (9.2.62), we obtain the equation: u(x, y) + k u2(x, y) +
2 11.2
2_ 2 (xUO+ y02)2
+i
d
d j?
(9.2.67)
rr -1 which coincides with (9.2.36).
9.3 9.3.1
The Three-Dimensional Flow The Fundamental Solution
In the last 40 years, a great number of papers was devoted to the steady transonic flow past thin bodies. Usually one assumes that the flow is irrotational, the potential satisfying a non-linear equation having the form (9.1.13). For deducing the integral equations of the problem, we apply Green's formula to the equation of Poisson and we assume that a vortices layer is present downstream the wing. Derivating, we obtain the non-linear integral system for the components of the velocity (see for example [9.36]). In the case of the symmetric profiles the system reduces to a single
equation for the component u(x, y, z). In this sense, after the initial paper of Oswatitsch [9.50] where one defines a principal value for the singular integral which intervenes in the representation, it followed the paper of Heaslet and Spreiter [9.17] where one gives a general representation which in the symmetric case reduces to an equation. The
384
THE STEADY TRANSONIC FLOW
representation is valid both for the flow with shock waves and the flow without shock waves.
For the lifting wings the forms of Norstrud [9.41] and Nixon [9.39] are available. In this case, the problem reduces to a system of two nonlinear integral equations. At last, we mention the paper of Ogana [9.471 where one shows how the integral equations depend on the definition given to the principal value of the singular integrals. A new point of view, belonging to D. Homentcovschi [9.20], [9.21] and L. Dragog [9.8] ]9.9] does not assume that the flow is potential. Utilizing the system of equations of motion it is necessary to assume the existence of the vortices layer downstream. In the sequel we shall utilize the method of fundamental solutions [9.8]. The system which determines the perturbation is (9.1.42) and (9.1.46). Performing the change of variables
u`=
,
(9.3.1)
and omitting the marks * and A, the system becomes
uy-v==0 U,-w2=O (9.3.2)
us + vy + w. = k(u2)s,
where k has the same significance like in (9.2.6). We shall see further that employing a fundamental solution similar to the fundamental solution of the system
uy-uz=eo(x,y,z), us-ws=0 (9.3.3)
u. +vy+w2 = k(u2)=+mb(x,y,z) we may satisfy all the conditions of the problem. This solution will be determined in the manner described in 2.3. Applying the Fourier transform, solving the algebraic system just obtained and considering the inverse Fourier transform, on the basis of the formulas from appendix
385
THE THREE-DIMENSIONAL FLOW
A, we obtain: u(x,y,z)
)r
41r (m&x + t
v(x,y,z) - 4w 8z k
4w 8y
r 82
_ M 49
-4w 8
r,
8zsuz
r
8
as
8z
alai
1
4w 8xOy w(z, y, z)
82
4w
8 I_ m 8 1+
t
_
__
us
r, k
2
02 2
1
(r} ^18z [ate, - 4 8x8zu * r, 1
(9.3.4)
where r =
+ y + z and,
-.
I 8, C) dv , (9.3.5) u r Iffits I z - 41 with the notation dv = d£ d, d(. This integral is called the aonvolntion of the functions u2 and 1/r. TaIdng M = 0, from the formulas (2.3.11), (2.2.6) and (2.3.27) it results us
al l = -.f`1 8 1 J i alas
[ala2J
= (9.3.6)
4Ir 8y
r
j.
4w y2 + z2 11
+r
and a similar formula. In fact one obtains the following form of the fundamental solution:
u(2,y,z)_-4w (mf +e ) r 1
v(x, y, z) = 4w
K
jr02 w(z,y,z) =
8 r 8z
[y2+z2 (i. +
r
Io,
r-
-m
1
4
t
8 + 4w 8a
r), r 4w 8xjo' y
+z
(1
x) +w
k 8K° 47r 8x, (9.3.7)
386
THE STEADY TRANSONIC FLOW
where we denoted
lo= au2*1, r Jo= ay TX
au2#1, Ko= aZ r
r
(9.3.8)
P. and m being constants. 9.3.2
The Study of the Singular Integrals
The integral (9.3.5) has a weak (integrable) singularity. The integral exists, (it is convergent) (u2 is zero far away) and it may be derived (the convolution, if it exists may be derived (A.3.7)), such that we have
I° = u2 * -
-u2 * Ix13 = J u2(4) 14 - I3dv
-r=
and similar expressions for J0 and Iio. Since the integral has the form (E.3), it is convergent. With the notation
E -- xl, x
f __ IC
has the form (E.9) and may be derived according to the formula (E.10). For calculating the last term one utilizes the spherical coordinates with the center in the point having the vector of position x: 1°
-x=sin9c s rl - y=sinOsinV
( -z=cos9. One obtains
Jfces(n,x)dn =
Ir
whence it follows the formula
8xlo = J ul()FZ (::,1) dv - 43 u2(x) _ (9.3.9) U2(t)2=02
0
"°dv - 4xu2(x) 3
.
THE THREE-DIMENSIONAL FLOW
387
Analogously one demonstrates that
J a to = 1, 49X
u2(,) Ix?o lsdv, (9.3.10)
K = ±Ko =JR3 u2(F)Ixxo{Isdv, where xo = x - t, yo = y- rt, zo =z-(. The integrals we have obtained are convergent if u2 satisfies Holder's condition and if its behaviour at infinity is u2(C) = O(ItI-`) with I > 1.
9.3.3
The General Solution
Denoting by D the projection of the wing on the xOz plane and by
y = h(x, z) ± hl(x, z),
(x, z) E D
(9.3.11)
the equations of the wing (which is assumed to be thin), we shall be able to satisfy the conditions of the problem with a continuous superposition of solutions having the form (9.3.7), defined on D. It results the following general representation:
(1R)
u(x,y,z) =-4a JJ [M(C 0ax
dt dC
(9.3.12)
-4 J(x,y,z), v(x,y,z) = 47r
11D
[e(C) ax
-
(R)
d d(-
{2:
47rf
(9.3.13)
k
ir- Ax' Y, z), u !(x, Y, Z)
(R) +
T" AD
f
(9.3.14) 1
D
K
I y +:.p Y
dt d(,
THE STEADY TRANSONIC FLOW
zo=z-(, R- xo+y2+zo.
(9.3.15)
Taking the formulas (5.1.16), (5.1.18) and (5.1.24) into account, it results
u(x,10,z) =±t(x,z)+4Ao,, m(E,() D
v(x,±0, z) = f1m(z,
z) + 4-r
no dEdC- 4x1(x't0,Z)
(9.3.16)
1.
(z((,C)2
(i + x0)d{ d(-
- 4 J(x, ±0, z) (9.3.17)
where
Ro= zo+zo
(9.3.18)
and the mark * indicates the Finite Part like in (5.1.24). From (9.1.42) and (9.3.16) we deduce the significance of the function
t(x, z) : t(x, z) = p(x, -0, z) - p(x, +0, Z).
(9.3.19)
Hence, t(x, z) gives the jump of the pressure. This function will be utilized for calculating the aerodynamic action. From the expression of v(x, ±0, z) and from the boundary condition
v(x, f0, z) = h'(x,z) ± h' (x, z) (x, z) E D,
(9.3.20)
where the mark "prime" indicates the derivative with respect to the x variable, it results after subtracting and adding m(x, z) = 2h' (x, z),
4ir,1Dt(
(9.3.21)
(1+)dd(+
+ 2k s u2(4) (xo + q2
+
Z02
T,,-, d v = h'(x, z), (x, z) E D. (9.3.22)
389
THE THREE-DIMENSIONAL FLOW
The formula (9.3.21) determines directly the unknown m(x, z). In the equation for t(x, z) it intervenes the values of u2 in R3. They are obtained from (9.3.12) after replacing m by (9.3.21). We deduce
u(x)- 3u2(x) +
k
4I
U2(4)2xix MI5 -o d v(9.3.23)
-41T f t((,()R3d(dq
2,1
D
f Dh'(k,()R3dCd(
Hence, for determining the unknown f(x, z) on D we have to solve the system consisting of the equations (9.3.22) and (9.3.23) where u(x) is defined on R3. For u(x, f0, z) we shall utilize the values (9.3.16). The mathematical problem is extremely difficult and there are not known any attempts for solving it. For the symmetric wing (h = 0), the solution is obtained for t = 0
and u(x, y, z) = u(x, -y, z) if k
u(x2)- u2(x) + 4 /
2x x05 d v =
U 3
(9.3.24)
3
= 21r JDhi((,()Rd(d
9.3.4
Flows with Shock Waves
In the case of the flow with shock waves, the general solution has also the form (9.3.12)-(9.3.14). We can see it in the simplest way if we utilise
the notion of Fburier transform for bounded domains, introduced by D.Homentcovschi 19.191. Indeed, in the fluid domain D the equations
vx-uy=0, wz-uz=0, (9.3.25)
uz + vy + w: = k(u2). , with the notations from (9.3.2) have to be satisfied. On the shock waves E one imposes the relations OvOnz
- OuOny = 0,
llwOn: -
0, (9.3.26)
uOnz + [lvjny + Uu'Qn: = kjJu21nz,
THE STEADY TRANSONIC FLOW
390
deduced from (9.1.49), and on the borders S+ (upper surface) and S_ (lower surface), the conditions (9.3.20). Applying the Fourier transform for bounded domains, we shall utilize the formulas of the type (A.8.1). From (9.3.25) we deduce
-iaiv+ia2u=S1+T1i -iaiw+ia3u=S2+T2,
(9.3.27)
-ialu - ia2v - ia3w+kialu2 = S3 +T3i where, taking into account that on S+ we have n = (0, 1, 0), and on S_, n = (0, -1, 0) (vnz - uny)e' a'xd a =
S1 = s++s_
I Juleiaxda = -JDt(x,z)e'("'+"'s)da,
_-
D
S2 = J S3=
; +s_
s++s_
(wns - un=)e' a'Zd a = 0,
(9.3.28)
f(urn+vny+wn;-ku2nr)e'c.'da=
=f OvOe1a xda _
fom(x,z)e'(",+"':)da.
t(x, z) and m(x, z) having the signification from (9.3.19) and (9.3.21). The integrals
Ti =
J (OvOn. - Julnw) T3 =
JE
T2 = f£ (OwOn.=
(Duin. - Ovlny + Owonz
- Juln=)
et°r'ada
- klu2Onz)
vanish because of the relations (9.3.26). Hence, the system (9.3.27) reduces to
-ia1v+ia2u=S1
-ialw+ia3u=0 -i&- ia2i;-ia3w= S3-kialu2,
(9.3.29)
391
THE THREE-DIMENSIONAL FLOW
which has the solution
u= `ia2sas al Ss + i a2 S3
V=
op, +
10 S1+ka t
W=
where a2 = ari + d
u2,
3s
u,
(9.3.30)
a S1 + ka y-
i
1
+ &23.
Considering the inverse Fourier transform and utilizdng the formulas (A.6.9) we obtain 1
[83]
- k-t-r-I [a,] (9.3.31)
Cf2
f is a2]
+8 -k.Ozox jr8a
1
us
8°
-
u2
1
i-k_
8
air
By direct calculations, we deduce
.F-1
f
(2703 OY J22
=
t la {atE+wt)d dC L_ L f
e '(a1x+a*v+o*z)d a
da]dt ds fD[(211)3mnhJP.3 47s
f
a
_
O R ()dd(. (9.3.32)
where, with the notation
R= V;i.
,
(9.3.33)
THE STEADY TRANSONIC FLOW
392
we utilized the formula (A.7.10). From (2.3.11) and (9.3.27), it also results a 'r- j (
I_ 1 8 1-
1
iata2
t?z
1 47r
4ir Oz J
oo V2.2
ao
+ y2 + z-2
_
zd x
1
f
dx
(x3 + y2 + z2)3/2
1
z
4-x y= + z2 (1 +
x) r (9.3.34)
'On the basis of this formula we deduce
_
1
8 jI
(27r)3 Vz st3
I
e't(alx-+a,y+ass)da=
P
i0la2
OZ .3
(2n)3
1L
4;r
i
ala2
dct]d d( =
'y2+z2 (1+)ded(. (9.3.35)
At last, taking into account the definition of the convolution product, it results u2 i u2(t) d (9.3.36) a2
4:r a3 Ix - f 1
With these formulas and with the similar ones it is not difficult to see that in (9.3.31) we have just the solution (9.3.12)-(9.3.14).
9.4 9.4.1
The Lifting Line Theory The Velocity Field
The lifting line theory in the transonic flow is studied in (9.55) and [9.$). In the last reference, it is obtained, as it is natural to do, from the Lifting surface theory. This method is also utilized herein.
We shall deduce the equations of the lifting line theory from the lifting surface equations using the assumptions 10,V,3" (Prandtl's
393
THE LIFTING LINE THEORY
hypotheses) from 6.1. Hence we shall take hl = 0 and we shall consider that the unknown is the circulation
C(c) = +
(9.4.1)
e(4, ()d
C(±c)=0
(9 .4.2)
and we shall utilize the formula tim
=
f
()k(x, y, z, 4, ()d e d ( =
fJ
s-(()-O-s+(()
(9.4.3) }r.
C(C)k(x, y, z, 0, <)d
2c representing the span of the wing on the direction of the Oz axis. On the basis of the first hypothesis (hi = 0), from (9.3.21) it results m = 0 and the representation u(x, y, z) = T"
fJ
C) R3
d d(
T-
I (x,
y, z)
v(x,y,z) =- 1 ID f t 4sr
(1+
j)]ded(-
- J(x,y,z),
y (i+ az y2 + s02
R) ,did( -
I(x,y,z)
a ly +
AD f
0
ev,oa[
1 ffD
w(x, y, z) = 4z
(9.4.4)
or, using also the formulas (9.4.1) and (9.4.3):
u(x, y, z) =
1
4zr
+`
J
k
C(() R3 d _4 I (x, y, z) , 1
v(x, y, z) _ -
c
C(S)
d
I - 4?r
-C
C`(C) yz
zo
(1
+
+C
w(x,y,z)-:i!. f
C(S) 2+x2 y o
Ri) d(
4 J(x, y, z)
,
k
(1+R )dC- K(x,y,z), 1
(9.4.5)
THE STEADY TRANSONIC FLOW
394
where we denoted
x2 +y2+; 2.
R.1 =
(9.4.6)
The Integral Equations
9.4.2
Using the identity
I(1+xo\^8 xo+Ro Ro J
8z
(9.4.7)
rozo
where Ro is (9.3.18), we deduce for (9.3.22)
JJn
1+'0
r(io
RD / d
d
td (=
8z
AD e(c o
X0 0ze
td C =
FC(C)Zd
-d
Using the calculations (6.1.11) - (6.1.13) we deduce in the sequel
T
-j
C'() d C az ff4;)s)flzOd t d ( = e
+(1) t(co )d( 10
Je
' +` C(() d
Lc
zp
L(()
e
a(z-S)d(
(9.4.8)
2 , _+(_) t(F, z) d
J=-(z)
xo
Substituting this in (9.3.22), multiplying the obtained equation by
x - x_ (z)
Vx+(z) - x and, integrating with respect to x on the interval (x- (z), x+ (z)), one obtains the following equation:
C(z) =
a(2)
'
'((z d(+
is u2(C)S(=, F, n, ()d v+ H(z) , (9.4.9)
THE LIF"TINC LINE THEORY
395
where
x - x_(z)
j_+(`)
3xogdx
S(z, , , C) = flV x+(z) - x (xo +, 2 + 4)512 , (9.4.10)
H(z) = 2
s+(_
- x-(Zh (x, z)dx . x
77
The equation (9.3.23) for the unknown C(z) is
u(z) - 3 u2(x) +
4J [
y +`
-^ 4
2X.2 U
-
x
2
y
2
zo is
dv (9.4.11)
C(C)d C
, (x2 + y2 + 40)3/2
We have therefore the equations (9.4.9) and (9.4.11) for the unknowns C(z) and u(x, y, z), C being defined on [-c, +c], and it, on R3. The continuation of this reasoning may be found in (9.8). Obviously, we have to consider only numerical solutions.
Chapter 10 The Unsteady Flow
10.1 10.1.1
The Oscillatory Profile in a Subsonic Stream The Statement of the Problem
As we have already mentioned (see Chapter 2), the general problem of aerodynamics, i.e. the problem concerning the determination of the perturbation produced by an arbitrary moving body, in a fluid whose state is known, is very difficult. A presentation of this subject can be found in the papers of Kiissner [10.37], [10.38), [10.39]. We consider in this chapter, the particular case of the wing which is oscillating harmonically in an uniform stream. The problem is important in the flutter theory. For the incompressible fluid the plane problem was investigated by Theodorsen (10.75). For the compressible, subsonic fluid in a plane flow, the problem was studied at first by Possio [10.59) and then by Dietze [10.14) and Haskind 110.30). These authors used the potential of accelerations i1', replacing the body by a doublets distribution defined on the chord of the profile. The integral equation which was obtained made the object of many researches [10.22], [10.23]. In [1.1], [1.3], [1.8], [1.18] one may find syntheses and references. Considering that the replacement of the wing by a doublets distribution has no physical justification, in [10.15] we deduced the integral equation starting from the idea that the wing must be replaced according to Cauchy's principle by a distribution of forces. In the same paper, we gave a solution for the integral equation for small values of the frequency (w K 1). The present' section is written on the basis of this paper.
10.1.2
The Fundamental Solution
We utilize the dimensionless variables x, y, z, t introduced by (2.1.1), and for the velocity field V 1 and pressure P1 resulting from the super-
398
THE UNSTEADY FLOW
position of the perturbation over the basic flow, we set
V1 =UO +V), Pi = P.+p,0U;pP.
(10.1.1)
Like in the previous sections Umi is the velocity of the unperturbed stream, and p,,. and pa, the pressure and the density in that stream. Imposing the condition that these fields verify the equations of motion, it results (see the equations (2.1.26) and (2.1.27)) the system
oV /at + 9V/Ox + grad P = F,
A2(aP/at + OP/ax) + div V = 0,
(10.1.2)
lim (V, P) = 0,
ixl
where F is the force density assumed to be small (the system is the result of a linearization), and M is Mach's number for the unperturbed stream. If the uniform flow of the fluid is perturbed by harmonic forces having the form f Cos (iwt), f Bill (iwt),
applied in the origin of the axes of coordinates, then we shall put in (10.1.2)
F=
(10.1.3)
f5(x)ek'Ji
.
Solving the system, we shall obtain that the real part of the solution is determined by the force f eos(iwt) , and the imaginary part by f Bin(iwt)
.
The perturbation produced by (10.1.3) will obviously have the shape
V = v(x)ei"' P = P(x)e"
(10.1.4)
Replacing in 10.1.2 one obtains the system iwv + av/ax + grad p = f 5(x) M2(iwp + ap/ax) + div v = 0,
,
(10.1.5)
lim (v, p) = 0.
Ixi-. Q
The solutions of this system are given in 2.4 (they are the solutions of the system (2.4.3)).
399
THE OSCILLATORY PROFILE IN A SUBSONIC STREAM
In the case of the subsonic, two-dimensional flow, assuming that f has the form (0, f) , it results from (2.4.6) (10.1.6)
P(x,y) _ -fly Go(x,y), and from (2.4.16) and (2.4.21)
v(x, y) = f e-"' [2iwG - f32G= + w21 x
G(7-, y) d 71
.
(10.1.7)
00
We denoted
Go (x, y)
- 4I
G (x, y) =
4if3
)
H
°
( k/ x2 + My2) e»
H(2) (k
(10.1.8)
x2 + /32y 2) e1
where
k=wM, 0 =w/$2, a=kM
(10.1.9)
Hoe) being Hankel's function.
10.1.3 The Integral Equation Assuming that the perturbation of the fluid is determined by an oscillatory wing having the equation y = h(x)e'`'t , 1x1:51,
(10.1.10)
from (2.1.29) it results the following boundary condition
v(x, 0) = h(x) + iwh(x) = H(x), jx) < 1,
(10.1.11)
Let us replace the action of this wing against the fluid by the action of a continuous forces distribution having the form (0, f) defined on the interval (-1,+i] . From (10.1.6) and (10.1.7) it results the following general representation of the perturbation P(x, y) = -
J
+1
v(x,y) = f f(t)e
11
f (t)
Go (xo, y) d
r.,xo(2LG(xo,y)
,
(10.1.12)
- f32GX(xo,y)+ (10.1.13)
+w2J
G(r,y)dr]d,
THE UNSTEADY FLOW
400
where xo = x - f
.
The function f has to be determined from the
condition (10.1.11).
For obtaining the limit values p(x, 0) and v(x, 0) , we shall take into account that Hankel's functions H0(2)(u) and H12)(u) satisfy the relation (10.1.14) Hoe) (u) = (u) , du and have the following asymptotic behaviour for small values of the
argument [1.16], [1.40]:
H421(u) . I - 1n u , r = 1 -
(10.1.15)
?l 2(C- 1n 2) ,
Hi2l() _i u ,
(10.1.16)
where C(= In y) is Euler's constant (= 0.577215) . We deduce y
P(x, y) =
i::' f
+ p2y2)
(k
exp (iaxo)
o + 2y
d£
.
When we calculate p(x, 0) we observe that, because of the presence of the factor y, the product y f+1 vanishes excepting the vicinity (x - e, x + t) where the integrand becomes infinite (for t = x ). If a is (iaxo) may be apsmall enough, in this vicinity the function f proximated by its value in the middle of the interval (we assume that f (C) is continuous), i.e. with f (x). It results rte , f (x) P(x, ±0) = y 1 Hill(k xo + [32y2) vlli
4i
x+y
_e
-+ t :
and, performing the substitution into account,
dt
+C
AX, f0) _
f (x)Y--+O limy 2w
J
-x = t , and taking (10.1.16)
t2 + /32y2
1 f (x). 2
(10.1.17)
Hence we obtain the significance of the function f (x) . We have P(-T' + 0) - P(x, - 0) = f (x) .
(10.1.18)
The component v(x, y) is the sum of three terms vi , V2, V3, which are represented as follows +i v1 (x, y) =
J
f
j f We-
G(xo,
y)d
""r° Hoe) (kx2 +/32y2)ei0xo d
401
THE OSCILLATORY PROFILE IN A SUBSONIC STREAM r+1
1
VI (X'0) =
H(21
4iQ 1-1 f (
(kjxol)e0'0 dE,
(10.1.19)
the singularity from j 2) being integrable. We have also, v2 (s, Y)-
J
+1
f(e)e-I° 8 G(xo, II) d t =
k 4iQ
+i
f
1
(k
xq + Qom)
x
-07
0
°d t+
f+1
+ 4Q3
fl f
(k
and taking (10.1.16) into account 1
k V2 (x, 0)
Q J-1
f
(klxol) f!l e i2-0 d E
OHo (k1xo1)e
f+' f(t)-
Odd,
[JZ0G(r,y)dr] 0
00
1
V3 (r,0)
(10.1.20)
I
From
one obtains
,
,
(f)e-6-0 H(2)
+403 f-+1
v3(x,U)=
xo + Q2y2)e'D*° d
dt,
1 f(t)e- '-O [JXOJ;42)(kfrI)ev1d1] dt,
_!_ f
where one performs the change of variable r -+ u : for = u and one takes into account the formula J
J
Hoe) ( M [u1) eh'd u
=
2 n 1 Mf I
,
(10 . 1 . 21)
given in [1.2[. One obtains V3(X,0)
26;
If(4)e!
0 [! 1M6
+ Zr o
(M1u[)ej"duJd
J
(10.1.22)
After all, from (10.1.13) it results I
v(x,0) = T f(C)Ni(xo)dC+J
11
f(F2(xo)dt,
(10.1.23)
402
THE UNSTEADY FLOW
where we denoted
'
Nk(xo) = nk(xo) e'
nl ( xo ) =
4 pM
k''X0
,
k=1,2
(10.1.24)
wr0 Hi2)(k (xoI) } o_ e
n 2 ( Xo ) = A`-'A HO(2) (kl xol)e °''z0
fQC)
4
- 2W-
In
1+,3
(10.1.25)
M
H2)(MIuI)eudu.
Imposing the boundary condition 10.1.11 it results the following singular integral equation r
I
i
f
d
H(x) , IxI < 1
(10.1.26)
where
N(xo) = N,(xo) + N2(xo)
(10.1.27)
In fact the kernel N depends on the variable xo and on the parameters M and w. We deduce therefore that the kernel has the following explicit expression (a = kM)
N(xo,
_iw
M'w)
e_
-- --Hi2)(klxol) Ixol etQTp +
°r
QHQ2)(klxol)e' O-
e'i'' 0 In (10.1.28)
The equation (10.1.26) is Possio's equation [10.591. There are a lot of papers devoted to the kernel (10.1.28) in the literature 110.5], [10.22), [10.301.
10.1.4
Considerations on the Kernel
Taking (10.1.16) and (10.1.16) into account, we deduce
N(xo, M, 0) = urn N(xo, M, w) =
2
n
403
THE OSCILLATORY PROFILE IN A SUBSONIC STREAM
which is the kernel for the steady flow. With this kernel the integral equation (10.1.26) reduces to (3.1.15). The kernel for the incompressible fluid is obtained from (10.1.28) calculating (10.1.29) N(xo, 0, w) Mhm.(xo, M, w) .
Integrating by parts we transform the formula (10.1.28) into
et '° {Mi42)(kIxoI)
N(xo. Al, w) =
- iHi2)(k(xol) (X(, +
4A + t!ft e-6'0 lim Hoe) (Maul) 4
- W4M e-6'0-
Utilizing now the relations (10.1.15) and (10.1.16) the notations (1.16) 00
J;
Ci(z) =lnyz+
u-Idu =lnryz+-1)"(
JJ
Si(z) =
1sill u u
n)t
,
n-1 °O du = > (-1)r (
n=O
2n+1
+ 1)(2n + 1)! ' (10.1.30)
called, the first, integral cosine, and the second integral sine, we obtain N(xo' 0, W)
2
2 + Si(wxo), }
.
(10.1.31)
This is the kernel for the incompressible fluid. One demonstrates in (10.15] that for small values of the frequency (w a 1), the integral equation (10.1.26) has the form
a
xd w
+
mQJ_11f(t)(In (lx-t(+r))dt=2H(x),
(10.1.32)
where r is a constant. This kind of equations are solved in (A.16). We leave to the reader the task of writing explicitly the solution. In (10.22) one shows that the general kernel (10.1.28) has the form
N(xo,Af,w) = Ao(xo)+Ai(xo,M,w)In(lxol)+A2(xo,M,w), (10.1.33)
404
THE UNSTEADY FLOW
where
Ao =
_0 2,
A,=- 2 CBI(xc,M,w)e ,mxo (10.1.34)
A2
-iwxo
2. B2 (xo, M, w)e
,
A, and A2 being analytic functions with respect to x0.
10.2 10.2.1
The Oscillatory Surface in a Subsonic Stream The General Solution
The problem presented in this subsection was studied in many papers (10.86], (10.87), (10.45], (10.35], (10.83] where the integral equation was obtained by means of the potential of accelerations, replacing the wing by a distribution of doublets. A slightly different investigation was given in (10.12]. We studied this problem in (10.6] utilizing the fundamental solutions method which will be presented in the sequel. The problem is the following-, an uniform stream having the velocity
the pressure p and density po , is perturbed by a surface, oscillating according to one of the laws
z = ho(x, y) coo (wt), z = ho sin (wt), (x, y) E D.
(10.2.1)
One requires to determine the perturbation. One utilizes the dimensionless variables introduced in (2.1.1) and the notations (10.1.1). The problem is simplified if we replace the laws (10.2.1) by
z = ho(x, y)e"" ,
(x, y) E D .
(10.2.2)
In this case the real part of the solution will give the perturbation produced by (10.2.1) and the imaginary part the perturbation produced by (10.2.1b). The boundary condition (2.1.20) and the linearized system (10.1.2) lead to solutions having the form (10.1.4) where the functions v and p are determined by the system (10.1.5) and by the boundary conditions w(x, y, 0) =
8
ho(x, y) + iwho(x, y) = H(x, y), (x, Y) E D. (10.2.3)
The solution of the system (10.1.5) under the assumptions that f = _ (0, 0, f) and the unperturbed stream is subsonic (M < 1) is obtained from (2.4.7) and (2.4.17) as follows a (10.2.4) P( x,Y,z _ - f 8z 0o(x,Y,z),
405
TILE OSCILLATORY SURFACE IN A SUBSONIC STREAM
w(x, y, z) = f e
i"x
l
-2 . ) G + (w2
[(2i
) f G(T, Yz) d r 00
J
where
1 exp [io(x - M RI )l
(10.2.5)
R,
x +
RI(x,y,z) =
(y T .
As we already know, the formulas (10.2.4) define the perturbation produced in the uniform stream by the force (0, 0, f) exp(iwt) applied in the origin of the axes of coordinates. Replacing the wing with a continuous distribution of such forces, defined on the domain D, we obtain the following general representation of the perturbation
P(x,y,z) _ w(x, y, z) =
J J°
f(f,rr)
a8 G
(10.2.6)
G(xo, yo, z)+ f (t, -T) e-'"' [(2iw - 021) ox 0-2
(10.2.7)
+(w2-a-y2)
where, as usually, xo = x-t, yo = y-7) .The function f is the unknown.
10.2.2
The Integral Equation
In order to determine the unknown f , we shall impose the conditions (10.2.3). At first we shall prove that if f (x, y) is a continuous function, then
Zlim0JJ f(E,rr)a Go(xo,yo,z)dfdi' = r2f(x,y),
(10.2.8)
D
Indeed, we have
j f fl) iwM + Ro j )q aik(Mx°-RO) d e d >) rJ° a
P(x, y, f0) =
4Z
J
z = 0, the integrand will be zero excepting the point Q(x, y) E D. Denoting by DE the disk where Ro = Rt (xo, yo, z) . We notice that if we
/set
having the center Q and the radius E and assuming that t is small
406
THE UNSTEADY FWW
enough in order to approximate f t)) with f (x, y) (this is possible if f is continuous) and the exponential with the unity, it results P(x, y, ±0)
4lymo
Jf 4 (ic?vf +
)ddr
.
Performing the change of variables t, q -* r, 0:
-x = Qrcos0, r/- y = rsin0,
0
P(x, y, ±0) = 2p f (x, y) zluuo z
i
(iwM +
r .8 z } r2+
r
z2 =
/!
=fif(x,y), (10.2.9) and then
P(x, y, +0) - p(x, Y. -0) = f (x, y) , (10.2.10) The formula (10.2.9) proves (10.2.8) and (10.2.10) gives the significance of the function f (x, y) . In (10.2.7) we may interchange the limit and the derivations (with
respect to x and y). It results therefore
w(x,y,0) =
nj
' fj f
26 -,62
x
(,)enw [n+n2]ddtl,
(10.2.11)
eR ,
(10.2.12) oo e(1iEl=d,,
F00
E
=j
R,
d
dT
,02X = (xo R,. =
=J
T2 +
MR), R = xo + /yo ya
(10.2.13)
407
THE OSCILLATORY SURFACE IN A SUBSONIC STREAM
In E1 we perform the substitution r
A:
r + AIRT = /32A ,
(10.2.14)
Using the notation Iyot = r, we deduce
dr
dA
7,\T+:+
vrr2 -+#2r2
(10.2.15)
7,
and then
r
El =
00
a-WA
Mr/ A +r
a wA +r
00
da = fo
Mr
lp
dA
A
a-iWA
A +r
o
r
M
lo
= Ko(wr) - 2 [Io(wr) - Lo(wr)] - f
dA
dµ,
el + µ2
(10.2.16)
Ko and to being Bessel functions, and Lo the Struve function [1.16]. The expression of El may be derived taking into account that 02/0y2 = c72/c')r2 . Using the relations between Bessel's functions and their derivar tives, we deduce
-w2
rtir/$
1 + µze''wrs`dµ .
0
In E2 we make the notation iIyoj = u and then the change of variables
r--# B . r=usinh9.
(10.2.17)
Observing that 82/8y2 = (3282/&u2 , we deduce
8
e&oRX
=7 W2 1 /32 u2
+ j92 T3 e x + iwM R2 e-x - yo R2 e wx K2-
/'s0 (r - MR,)2efr-Mx.) dr J0 Rr
where
/ 2X = ao - MX, R =
xo + u2 ,
Rr =
r2 -+U2.
408
THE UNSTEADY FLOW
Performing inside the integral the change of variable T --- A::
r - MR. = Q2A ,
(10.2.18)
we notice that the formula (10.2.15) remains valid because it depends only on A,12. One obtains the identity 1
I
F2+ (j4
s0 {r -
dT
R
yo Jo
= (10.2.19)
1
z/Q'
A2+yoe'"'xdA, Y6
-Mlyoi/$
Taking these results into account we obtain
xoe ,x
n(xo,yo)=ni+n2=-Q2 R +iw R-xoM R K1(wr)
2
w,x #2y02e
-
III (wr) - L1(wr)) +W2
-w2 jJ11/1)
1 + µ2ek`'r0dp
f ar s
A, A2 + r2e d (10.2.20)
where, for the sake of simplicity we maintain the notation r = 1yol, and X and R are given in (10.2.13). Obviously the line yo = 0 is singular.
Employing this form of the expression nl + n2 in (10.2.11) and imposing the boundary condition (10.2.3) we get the following integral equation
4a jf f
n)N(xo, ?ro)d d r) = H(x, y) , (x, y) E D,
(10.2.21)
where
N(xo, yo) = e-"n(xo, yo)
(10.2.22)
is the kernel. Since w 4z 1 we have the asymptotic expansions
Ki(wr) = 1-, +O(w), Il(wr) = O(w), Ll(wr) = W
7r
+O(w) (10.2.23)
we deduce
limn=-4(1+...), t/0 R
(10.2.24)
409
THE OSCILLATORY SURFACE IN A SUBSONIC STREAM
i.e. just the kernel from the steady case. In the case of the incompressible fluid one obtains the kernel setting M = 0 in (10.2.20). From (10.2.13) it results
X=r0, R= xo+yo,
(10.2.25)
whence,
n(xo,yo) =-XoeR +iw y-'e4'0 - iKI(wr)2
-2w
(I1(wr)
- LI (wr')) + Uf ;07 J
0 so
,\2
+ r2eWX d A, (10.2.26)
This is the kernel for the ineompressible fluid
10.2.3
Other Expressions of the Kernel Function
Because of the Bessel functions, the expression (10.2.20) is considered to be complicated. However it does not contain divergent integrals. The
idea concerning the introduction of these functions may be found in [10.86] and it was also taken into consideration in (10.17J. We obtain another expression of the kernel function, starting from the fundamental solution (2.4.13). Indeed, with this one, the component w(x, y, z) is written as follows
w(x,?!,z) = a
fj f (.,?1)n(xo,yo,z)d dn,
where 2
,2
n(xo,yo,z) = a
f
=o 000
R1T
dr
(10.2.27)
( 10.2.28 )
with the notation
Rir = Vr2 + /32(y02 + z2) .
(10.2.29)
The passage to the limit and the derivation with respect to z do not interchange (only the passage to the limit and the derivations with respect to y interchange; for this reason we gave the expression (2.4.23)).
Therefore we shall derivate at first with respect to z. The expression
410
THE UNSTEADY FLOW
(10.2.28) may be found at Watldns [10.87], Williams [10.89], Dowell and others. Performing the change of variable r --t A : ,Q2A = T
- MRir,
(10.2.30)
we deduce as we have already seen, dT
dA
'
A' +s'
s2yp+z2.
(10.2.31)
Hence,
E(xoyo, a)
110
eMR,) R11.
0o
/X1
dr=J
dA
el"
(10.2.32)
A+
oo
where 32X1 = xo - M xo + p2s2.
(10.2.33)
Derivating we obtain
8E _ _ 8z
ek'X,
Me R /X+
(10.2.34)
iwX1
:-.0 8z2
dA
I+s
xo +
E
fim
Ma
ewa
JA1 0
dA
W (A2 + y02)3/2
where
R
V xo+/32Uo, A2X1
=xo--MR.
(10.2.35)
Imposing the boundary condition (10.2.3), we get the integral equation (10.2.21), where
M ew'X1 R Xl +
n(xo, yo)
x, J-oo (A2 + g2)3/2
d A,
(10.2.36)
Obviously the line yo = 0 is singular. This expression of n(xa, yo) is simpler than the expression (10.2.20), but here the integral is no longer convergent. We must therefore consider the Finite Part. The expression (10.2.36) is utilized by Ueda and Dowell (10.80), Ando [10.3], etc. Utilizing the identity 1
X?+yo
Mxo + R
M
xo+yo -x0 -X1,
(10.2.37)
411
THE OSCILLATORY SURFACE IN A SUBSONIC STREAM
one obtains two other expressions for n(xo, yo) . For the incompressible fluid (M = 0), we deduce eirra
1XO
n(xo.ieo)=- J
(,\2 + y02)3/2
To
d a.
(10.2-38)
If the unperturbed flow has the sound velocity, we obtain the kernel considering M - 0. Since Al
lim X = lim x° -
At--1
Xo +
yo
02
AM-1
= xo - yo _X1
(10.2.39)
2r
it results
xl,
xo 2+ 2 e
a nw
N(xo, yo) = -e
a
'
' + J oo (A2 + y 2)3/2
dA
1 .
J
(10.2.40)
This is the kernel for the sonic flow. One may verify the similarity of the representations (10.2.20) and (10.2.40), if we employ the relation
eiA
X
e"
J1 =
Ix j,\2 + yo)3/2 d J1 + Kl (wr) + r
(10.2.41)
+i 2 r ill (wr) - Li (wr)J which can be easily proved if we take into account the formulas
1 °°
( t 2 CD s 2r ) 3 / 2
d t = r KI wr) , (10.2.42)
sill Wt
Joy
ir W
(t2 + ,.2)s/2 d t = - 2 r
[11
- Ll (fir)]
given in the tables dedicated to Fourier transforms [1.16]. From the integral representation of the function Ko we deduce the identity rX
ei'.3(r-MRjT)
1-,0 (t2 + r2)3/2
dT
2Ko(w
yo + z2)
jf
oo
R1,.
d T' (10.2.43)
with the notation (10.2.25). Putting this in 10.2.24) and deriving according to the formula
8z2 82
X32 8
s 8s '
(10.2.44)
THE UNSTEADY FLOW
412
we obtain to the limit 2w
-iWxo
K t (wr) -
/x
(iWN1 +
eo(r-rlRa.)
Q2
dT
Ix (10.2.45)
where r2 + 012
Ror =
(10.2.46)
This is another expression of the kernel.
The Structure of the Kernel
10.2.4
The identity (10.2.41) makes possible to deduce from (10.2.32) the structure of the kernel in the vicinity of the singular line yo = 0. Indeed for a small r we have (1.40] 1
K1(wr) =
1+
wr 2
In r + ...
,
Ii (wr) = wr + ... , Lt(wr) =
2
a
(10.2.47)
+ ... ,
such that
X
eiWX
sadA+iI - Jo (ACos Jo + yo) /2
J'00 (A + yo)
3/2dA=
+72 -
tr
(A2
tn AdA+ 3/0)3/2
+
2
+ 2 IAr + ... , (10.2.48)
the points representing series of integer powers of r. If X > 0 the last two integrals have no singularities. Indeed, using the expansion formulas for
LA
d a .. . (A2 + yo2)v+1/2
given by Ueda (10.81], we deduce X
°T
(A 10
)3/2 d
x sinwA J0
00
(A2 + r2)3/2
A =E (
(2n)1 2n
n=0
00 (_1)nw"+i d A - nL-.o
(2n + 1)! 12n+1,
(10.2.49)
413
THE OSCILLATORY SURFACE IN A SUBSONIC STREAM
where
=1rX (A2 + r2)3/2 d A = Atm
Im
Xm-I
1))(,-3 X2 + r2 - (m - 1)(m - 3)J,.-4.
(M
X +*
(10.2.50)
Using the notations
Jm=
o 0
+r2dA=X--i(X2+r2)312-(m-1)r2Jm-2,
Am/A2
(10.2.51)
we may calculate the coefficients I,,, step by step, noticing that
IX
1 r2=rs +
0=
11 = VTr+--r-l -r. The formulas (10.2.48) and (10.2.49) give the structure of the kernel.
10.2.5
The Sonic Flow
If the velocity of the stream equals the sound velocity (U. = ca ), then one obtains the solution of the problem from (10.2.6), (10.2.7) and (10.2.12) setting M --# 1. We have shown in (10.2.27), that in this case there are perturbations only in the x > 0 zone. When we shall pass to limit we shall consider therefore x0 > 0. We have limp Go (xo, Spin, z) =
exp 4
[iW
Jim M2x0 _MR,1
z0exp-iw
2
+2xo
=
i - Go (10.2.52)
Z2
X02
lime G(x0, y0, z) =
4
lim X = lim
M-.1
M-.1
exp I
-i.
w J
z0-MR =
hml E2 = 110 exp
T-
u.
2(
(xo 2
= Gl ,
- 14),
)T
(10.2.53)
414
THE UNSTEADY FLOW
From (10.2.16) it obviously results lim E1 = 0 . Hence, the representation obtained from (10.2.6), (10.2.7) and (10.2.52), gives the perturbation in the sonic flow and (10.2.12) gives the kernel of the integral equation. This is s
r
nl+n3 = oexp 1 2 (x0 -
zo
92
J
L
10.2.6
iW 1
2 (T -
y02
)1
dT .
(10.2.54)
The Plane Flow
Acting like in 5.1 we obtain the formulas for the plane flow from the formulas which characterize the three - dimensional flow. We assume that in the equation of the perturbing surface (10.2.2), ho(x, y) has the
form ho(x), i.e. it has the same form for every y. With a suitable choice of the reference length Lo, the domain D will be rectangular with -1 < x < 1, -b < y < b. In (10.2.6) and (10.2.7) we shall have f = f (r;) . Considering b - oo we obtain +00
go (X0,
z) =
J
Go(xo, yo, z)d r1= 00
eik(Mxo-Ro)
1
=97r ED
dr1=
Ro
e
QHoe)(k Vxo+ 62z2)=
00
G(xo, yo, z)d r1=
g(xo, z) = f
xo +
Q
e(xo, z) = r-00 (E1 + E2)d r1= roo g(r, z)d r , +00 02 81/2G(xo, yo, z)d q = co
+oo 02
J
G(xo, yo, z)d r1= 0 . ao
X7
(10.2.55)
22
(10.2.56)
Using these results we obtain from (10.2.6) and (10.2.7) the representations (10.1.12) and (10.1.13). Taking into account the formulas of Fresnel
1 sin x2d x = fo
0
00
oos x2d x
YY
OSCILLATORY PROFILE IN A SUPERSONIC STREAM
we deduce
415
r+ e-In"'du= Vjj(1-i),
/ .
(10.2.57)
o0
and then, with (10.2.54) +00
=
it
-oo
(ni + rn)d q _
+ i)
Trw
OX-0
iw exp(xo) - wi2
JL Zo
iw
exp(2 r)
d7
r
(10.2.58)
This is the kernel of the two-dimensional sonic flow.
10.3 10.3.1
The Theory of the Oscillatory Profile in a Supersonic Stream The General Solution
One considers that Carrick and Rubinow 110.241 have investigated for the first time this problem. They have utilized the method of the pulsating sources potential. The presentation which follows relies on the fundamental solutions method [10.17]. The integral equation is solved explicitly. One obtains finite formulas for the lift and moment coefficients. One utilizes the dimensionless variables (x, y) defined like in (2.1.1) and the representations (2.1.3) for the velocity and the pressure, in order
to deduce that in (2.4.8), (2.4.18) and (2.4.21) the perturbation pressure and velocity determined by the action of an oscillatory force having the
form felt, applied in the origin of the axes of coordinates, have the form (10.1.4), where
P(x,y) = _(f V)Go(x,y),
v(x, y)
=f
(10.3.1)
1e-k.% [G(r, y)d r] + (10.3.2)
r] +f2e-k''x [2k4G + k2Cr + w2 f C(r, y)d r]
Utilizing the notations W = w1k2 , v = wAf and H for the function of
THE UNSTEADY FLOW
416
Heaviside, in (10.3.1) and (10.3.2) we have
Go(x, y) = H(x - klyi)so(x, y), (10.3.3)
G(x, y) = H(x - klyl)g(x, y), where
a = vM 2kgo(x, y) = Jo
(''- k2y2) e`ia"
2k9(x, y) = Jo (vVx2 -
k
)
(10.3.4)
e-k:,x.
As it is shown in (2.4.22) the perturbation (10.3.1) and (10.3.2) is zero outside Mach's dihedron with the edge on the Oz axis and the opening 21,t . This is the fundamental solution of the problem.
Let us consider now that the uniform flow having the Mach number M, is perturbed by the presence of a profile whose equation is y = h(x)exp(k it) .
(10.3.5)
Taking the origin of the reference frame on the leading edge and the length of the chord as reference length L0 , the function h(x) will be defined on the interval [0,1] . Replacing the profile by a forces distribution (0, f)(t)e''t defined on [0,1] , one obtains the following general representation of the perturbation P(x,y)
_-/
f o
+1
i
f (f )e
iWxo
L2iwG(xo, y)+
(10.3.6)
-G(xo, Y) + W2 f G(r, y)d rJ d 00
.
J
Taking into account the definition of the function H(xo - kIWI) and the formulas (A.3.15), with the notation X = x - kIyI,
(10.3.7)
417
OSCILLA'T'ORY PROFILE IN A SUPERSONIC STREAM
we deduce
jf()Go(xoiY)d t _ = H(X)
y f t f (E)9o(xo, y)d = H(X) Jo, f W
`""°G(xo, y)d t = H(X) f f
9o(xo, y)d
,
°g(xo, y)d t ,
o
0
f
(xo, y)d =
=f1
f
f
J=
X
f' f A
[H(x) I f (t)9o(xo y)d
(t)e-'.."`og(xo,
ff(t)-iW8 ax (H(xo-kI yI)9(xa, y)ld
y)d(xo - kjyj)d4 + H(X) f f (f )e-k"19. (xo, y)dk, o
:o
= H(X) f to9(r,y)dr.
G(r,y)dr,
kM
00
(10.3.8)
Hence the solution (10.3.6) is
P=O, u=0, ifX<0,
(10.3.9)
X
P(x,y) =
-Jo
u(x,y) = fo f
if X > 0, (e)e-iwxonl(xo,y)dt+ Zf(x)exp(ialy)),
ifX > 0, (10.3.10)
where xo
n i (xo, y) = 2iwg(xo, y) + k29=(xo, y) + a'Z
f 9(r, y)d r .
The formulas (10.3.9) show that the perturbation produced by the profile propagates only in the interior of Mach's angle with the vertex in 0, and (10.3.10) that in a point M(x, y) from the interior of this angle one receives only the perturbation produced by the segment OMo (fig. 10.3.1).
THE UNSTEADY FLOW
418
Fig. 10.3. 1.
The Integral Equation and Its Solution
10.3.2
For 0 < x < 1 we deduce
v(x, 0)
p(x, +0) - p(x, -0) = f (z)
(10.3.11)
= if (x) + 2 I f (t)N(xo)d t,
(10.3.12)
where
N(xo) = e-" =
ym
n1(xo, y) _ s
k
(Jo(vzu) + iMJ1(vxo)J e
+ke
J
Jo(v-r)e rd z ,
0
(10.3.13)
Imposing the boundary condition (10.1.11) one obtains the following integral equation
k f (x) + J f (t)N(xo)d t = 2H(z) ,
0 < x < 1.
(10.3.14)
0
This is a Volternz type integral equation of first order. We solve it using the Laplace transform. One knows (see for example (1.32)) that the Laplace transform of a certain function g(x) is the function g(p), defined by the operator
£(g) = jg(x)e_Pxdz
(10.3.15)
419
OSCILLATORY PROFILE IN A SUPERSONIC STREAM
where p can be a complex number(p = pi + ip2) whose real part is positive.
[JX]
Applying the operator G in (10.3.14) we obtain
kf + fo
aPxdx= 2A(p) .
Here we shall change the order of integration. In figure 10.3.2 we observe that the domain of integration is D (for a given x , C goes from 0 to
x). But D can be also covered integrating at first with respect to x to oo and then with respect to . We have therefore from
k7+
f (t;) [f°°e_P0tN(xo)dx]d C= 2R(p)
.
(10.3.16)
XAK
0 F'ig. 10.3.2.
Using the change of variable z -+ u : x - = u, we deduce from (10.3.16)
(k+R)7=2f1.
(10.3.17)
In order to determine the transformation R we shall utilize the formula 1
(10.3.18)
G(Ja(vx)1 =
which may be found in the tables with Laplace transforms (1.161, [1.32], 11.331. So, using the notations Nl (x)
=
Jo(vx)e-i.x
, N2(x) = Ji (vx)e ix" , (10.3.19)
N3(x) = e-16'" I = J0(vr)e W-dr, 0
THE UNSTEADY FLOW
420
with a = vM , we obtain 00
C(Nl} = f Jo( vx )a- (p+")xd x = (p + ia} + v2 p + is + 00
£(N3) =
(p+ ia)2 + v'j' v
1
G(N2) =
1
e-pie-"[f
dxJ
(p + ia) + v2v2 '
Jo(pT)e-a d r ]
0
=
(10.3.20)
°O
fc*
Jo(vr)e`+E [je
ir-"'i"dxI dr
r00 e-(P+",)udu =
Jo(t r)e_u/M dT
0
0 1
1
(p+ivM) +v P+iw With the notations
iwM '
Pt =
M+1'
UJAf
Af-1'
(10.3.21)
it results
1
(p + ivM) + v =
(P + P1)(P + p2)
k(k+N) [(P+iw) (P+Pt)(P+P2), =k(P+Pi)(P+p2),
A=
+k[p+ivM-Vll»PI)(P+P2),+
P11
+
)(P + P2) w2
1
+ kP+iw} (10.3.22)
and then
OSCILLATORY PROFILE IN A SUPERSONIC STREAM
not
g
_
k
_ p+P2-P2+iw
p+iw
k + N
(p + p1)(p + p2)
M1)1/2(p+
421
(p + P1)(p + p2)
M+M1)-1/2_
(p+
M
1w+1) M -1/2
iw
M - I (p
iwM
1/2
(p+M+1)
M
whence
kf = H+ g.
(10.3.23)
From the tables with Laplace transforms [10.581 it results g = L-1(g) and then with the convolution theorem x
kf (x) = 2 f H (xo)g()d = 2H(x) - 21-w f H(xo) [Jo(ve) + iMJ1(v4)1 a `t d t. 0
(10.3.24)
This is the solution of the integral equation (10.3.14). It was given in [10.171.
10.3.3
Formulas for the Lift and Moment Coefficients
The lift and moment coefficients have the form
CL = cLexp(iwt), CM = cmexp(iwt),
(10.3.25)
where, because of the formula (10.3.11), CL = -2
f
1
1
f (x)d x, cM = -2 fo x f (x)d x .
(10.3.26)
0
We considered that the length of the chord Lo is the reference length and we defined CL =
P ' CAt = (1/2)poU*20Lo (1/2)poU.2Lo '
P being the lift and M the moment on the direction Oz z.
(10.3.27)
422
THE UNSTEADY FLOW
Utilizing ((10.3.24) we find
4iv f1 kAl 0
CL =
-4
CM =
-411 xH(x)dx +
J0
H(x)dx +
1
4iv
e 'a`d
(Jo(vl) - iMJI
,
f 1 G(t) (Jo(vt) - iMJ1(ve)J a '&(d 0
(10.3.28)
where
J
1
it x H(x - )dx
H(x - t)d x,
1
E
(10.3.29)
.
The coefficients (10.3.28) may be calculated numerically on a computer. Another method consists in approximating the function h(x) by polynomials whence one deduces that CL and cAf may be expressed by means of the terms having the form
f" (M, a)
=10
"Jo(vl;)e'°(d
1
(10.3.30)
9n(M,a)=
frJi(z)e'd7
Taking into account that Jj(z) = -Jo(-) and integrating by parts one obtains that
vg, _-Jo(v)eis+nfi_1-isf", n=1,2,..., (10.3.31)
vgo = -Jo(v)e is + 1- lab. These formulas show that g" may be expressed in terms of f,,,. Integrating f by parts, we deduce
laf" = -Jo(v)e-' + of"-1 - v
ivM j '
f
1
0
F"Jlv )e-'f d
,
(10.3.32)
_ -Ji(v)e+ of+ (10.3.33)
+(n - 1)11 0
Substituting (10.3.33) in (10.3.32) we find for f" an expression which contains the last term from (10.3.33). This may be eliminated with the
423
OSCILLATORY PROFILE IN A SUPERSONIC STREAM
aid of the relation (10.3.32) where n was replaced by n - 1. After all one obtains na
+ (n
a
Jo(v)e-i. - 1 Ji(P)e ia+
1)
(10.3.34)
1)2A-2 + 1(1 - 2n)fn-1
This formula shows that all the terms fn may be expressed by means of fo. This result was given for the first time by Schwartz in [10.70]. In the same paper one gives the following expansion for fo 00
[,
fo=e
n=O
IMM1:Jn(a)+iJn.f.1(a)w".
(10.3.35)
2"ni(2n + 11
In [10.701 one gives tables with the numerical values of fo, with eight
exact decimals, for 1 < M < 10 and 0 < a < 5. In [10.33] one gives the numerical values of the functions fn for n = 0,... , 11. 10.3.4
The Flat Plate
For the flat plate having the angle of attack -E (h = -ex) we deduce H = -2E (1 + iu;x) such that it results s
CL = -
E
[ 2 f2 + iw(2 + iw) fi - (1 + 2iw -
s ,
2 2e
CM = -
)f of
(10.3.36)
z
[f3+f2_2+2)f1 - 2(iw - 3 )fo] w2
These formulas are sufficient if we utilize the tables for , f1fo, f2' fs For w -+ 0 one obtains the well known formulas of Ackeret 4e
2E
CL = k , cM= k . Obviously, cL and cm may be expressed only by means of fo if one utilizes (10.3.34).
Noticing that
f = fn + ifn ,
(10.3.37)
where f1
f, = J
1
fn = -f eJo(4)sin(a)de,
424
THE UNSTEADY FLOW
we deduce from (10.3.36) CL = c'L + icL , cAf = (.! + icM
,
(10.3.38)
If the equation of the plate has the form
y = -ex coswt = Re [-ex exp(iwt)J ,
(10.3.39)
then
CL = crL cos wt - CIL sin wt,
(10.3.40) CAS =
cos wt - ciAf sin wt,
these formulas give the variation of the lift and moment coefficients versus the time. For example, for w = 7r and M = 2, we obtain CL = e(-9.2060 cos art + 11.8941 sin zrt)
,
(10.3.41)
CM = e(-6.8779 cos in + 17.5209 sin irt)
10.3.5
,
The Oscillatory Profile in the Sonic Flow
We are interested in the behaviour of the formulas of Nl and N2 when M 1 (k -- 0). It results v -+ oo such that we shall utilize the well known asymptotic expressions Jo(z) =
F2
Coo
7r
(z - )+0(.-,), 4
Jl
(z) =
(10.3.42)
r2z ooe (z - 34) + O(z-1)
for great values of z. In this way, we deduce [Jo(vxo) + iMJI (vxo)J exp(-iaxo)
NJ = _
k 1
=w xo
[(1- iM) cos axo cos vxo + (M - i) sin axo sin vxo-
-i(1 - iM) sin axo cos vxo + i(M - i) oos axo sin vxoJ , (10.3.43)
425
OSCILLATORY PROFILE IN A SUPERSONIC STREAM
and analogously
N2(x) = k
_
10"
Jo(vre)e'du
1-i
coe0(M-1)u+isinW(M- 1)ud u +I,
2fJo
Mu
(10.3.44)
where, with the change of variable u -+ t : u = (M -1)t, we have
_ cosw(M+1)u-isin'(M+1)u duI _ 2l+i two Mu
(10.3.45)
xo
l+i M-1 IMexp(-iwt)dt 2 xrw ft M Jo Taking into account that we also have xo
f
M -1 gyp( Ld)dt slim Ja
- Jo
)d
t = w (1 +
it results that
,
No(xo) = J m1 N(xo)
=(i+1)
we
r 1xoexp(2iwT O ) wi L
YYY
iw
2 Jexp(2 u)
I
du
,
(10.3.46)
he. exactly (10.2.54).
The integral equation (10.2.14) reduces to
fo f (4)No(x - 4)d4 - 2H(x)
(10.3.47)
This is also a Volterra-type equation of first kind. 'Lbt integrating it we shall use again the Laplace transform. Applying this transformation we deduce
(1 + i)% 7 = 2$b0, where § o'=
(P+ 1w
2)
1f2
iwf
+ 2 (P+
iw 2
}`
(10.3.48) 1/2
(10.3.49)
426
THE UNSTEADY FLOW
From tables (see for example [10.581) we have that G
p+iw/2,=exp(-)G[vii=-2exp
(-) (10.3.50)
such that we obtain go
2 Rx(i``' -
x)exp (
i2
x)
(10.3.51)
and using the convolution theorem, from (10.3.48) we deduce
After determining 1(x), the lift and moment coefficients result from (10.3.25) and (10.3.26). We shall give calculation formulas in 10.5.2 when we shall consider again this problem.
10.4 10.4.1
The Theory of the Oscillatory Wing in a Supersonic Stream The General Solution
The theory of the oscillatory wing in a supersonic stream, was conceived according to the model of the theory in the subsonic stream. The papers of Kussner [10.37J, [10.38] represent the starting point of this theory. We mention then, the study of Garrick and Rubinow [10.25] where the potential of the pulsating source is determined, the paper of Miles where one considers the symmetric arrow - like wing, having the leading edges outside Mach's cone [10.53, the paper of Nelson for the triangular wing [10.57], etc. But the fundamental work in this domain is the paper of Watkins and Berman [10.85). Here one may find for the first time the integral equation of the problem and various forms of the kernel. The method is similar to the method from the subsonic case. From the potential of accelerations of a pulsating source, one obtains, deriving with respect to z the potential of accelerations of a pulsating doublet. The potential of the flow is obtained superposing the doublet potentials. The boundary condition gives the integral equation of the
OSCILLATORY WING IN A SUPERSONIC STREAM
427
problem. In the following papers, due to Ashley, Windall and Landahl [10:4], Landahl [10.44), Stark [10.72], Harder and Rodden [10.29], Ueda and Dowell [10.81] the theory was developed and numerical methods for the integrations of the equation of Watkins and Berman were given. We shall indicate in this subsection how one may also solve this problem by means of the fundamental solutions method. Assuming that the equation of the wing is (10.2.2), we shall use distributions having the shape fe".,c
= (0, 0, f)e' .
(10.4.1)
Utilizing (2.4.9)we deduce that the perturbation of the pressure determined by such a force applied in the generic point (t, n, 0) is given by the formula (10.4.2) p(x, y, z) = f azGo(xo, yo, z). For the component w, it results from (2.4.13) w(x, y, z) = - f e "" `0H(xo)b(1M)6(z)+ 82
+f
:o 8z2a-""`O, co
(10.4.3)
G(r,yo,z)dr,
and from (2.4.23) fe",,xa[(2iw+k28x) G(xo,yo,z)+
w(x,y,z) =
8z
02)
+
(10.4.4)
IZO G(7-, yo, z) d r ] , 00
where we denoted Go(xo, yo, z)
G(xo, 3fo, z)
= 2A =
H(xS
s)
H(xSo
s)
cos (LS)e-iaxo , (10.4.5)
cos (vS)e-o"
1
k= M -1, 1=w/k2, v=OM, a=vM, s=k yo+x , S= xo-s , ST= 'r -3 ,
(10.4.6)
H being the function of Heaviside. One may prove, taking into account the formulas (2.3.35) and (2.3.36), that the perturbation given by (10.4.2)-(10.4.5) vanishes in the exterior
428
THE UNSTEADY FLOW
of Mach's cone with the vertex in the point ((, i, 0) and with the axis on the direction of the unperturbed stream (the Ox axis). Using a forces
distribution having the form (10.4.1), applied on the domain D - the projection of the wing on the rOy plane, the perturbation will be given by the formulas p(x, y, z) =1
JD
w(x, y, z) = -6(z)
+21-
f (C OF Go(xo, yo, z) d d rl,
J JD
f (t,
i7)e-'
°H(xo)b(yo)d
(10.4.7)
d q+ (10.4.8)
f f f(e,q)e D
w(x, y, z) = 2 . wh ere nl (xo, yo, z) _
IL f (t, q)e-'"" °n2(xo, yo, z)d t d i
82 f.0 z2
H(T - s)
0o
co$ (vSr) e S
r
(10.4.9)
,
dr= (10.4.10)
82
_ z2 H(xo - s) J n2(xo, yo, z) = (2iw + k2 40)
+[w2-
\
10.4.2
02 2
Cos (VSr)
H(xS- s)
r,
cos (vS)e"'Ww'+
)H(xn-s) r a
°sr)e-OrdT,
Cos
Sr (10.4.11)
The Boundary Values of the Pressure
They may be obtained writing p(x, y, z) =
o - s)
Cos (vS) a ;
, d t d q,
27r C7z S (10.4.12)
and noticing that because of the presence of the factor H (xo - a), the integrand differs from zero only in the domain DI defined by the inequality xo > s for a given M(x, y, z). This inequality is equivalent to
(t -x)2-k2(q-y)2> k2`z2,
429
OSCILLATORY WING IN A SUPERSONIC STREAM
which are solved in 8.3.3. Denoting by M'(x, y, z) the projection of the
point M on the xOy plane and X = t - x, Y = rI - y we deduce that Dl is the foregoing branch of the hyperbola X2 - k2Y2 = k2z2 (fig. 8.3.4). When M' is in D, the hyperbola degenerates into the half-lines X = ±kY (fig. 8.3.5) Since the function f is defined only on D, we shall prolong it in the outer region taking it equal to zero. It follows that in the perturbed region from the fluid we have
I
f (C, n)Go(.To, yo, z) d d q=
Qi
l
J
ly- f()
cos (vk
(Y+-,)(,-(Y+
- 77)(9- Y_) (10.4.13)
where
Yf = y
xok-2
With the change of variable q - 0:
2(Y++Y_)- 2(Y++Y_)cos0 = y-
- z2 .
(10.4.14)
P-
ok-2 - z2cos0, (10.4.15)
we deduce
21rk JO
cos
a-iwco 110 f (C y
-
xpk-2
z2cos0) .
(- z) 2sin 0d BJ d
whence, if f (x, y) is a continuous function,
P(x, y, ±0) _ _]
az I = Tf(x, Y)
(10.4.16)
P(x, y, +0) - P(x, y, -0) = f (x, y) .
(10.4.17)
and then
Hence, like in the previous sections, f represents the jump of the pressure on the wing.
430
THE UNSTEADY FLOW
10.4.3 The Boundary Values of the Velocity. The Integral
Equation For z 0 0 the first term from (10.4.8) vanishes (5(z) = 0). It has to be considered in the same way in the limit values for z - ±0. The remaining term is the kernel given by Watkins and Berman [10.85). Elementary calculations give 0 az
_ k2 z e
82
8s
22
8 k4z2 82 - k2s (1 _ k2z2 -s2-)T. + 2 8s2 .
(10.4.18)
In the cited papers one considers that the terms which contain the factor z2, vanish when z - 0. But this is not always true (see for exampie (3.1.20)). This is true when the factors which multiply z2 remain bounded when passing to the limit. In the following we shall see that for (10.4.10) the form obtained under this assumption is correct. Hence we shall consider the kernel
Cos(1S')e 'dTJ
82
nI(xo, yo, z) °-`
8 {H(xo_s)
(10.4.19)
s
The derivation is performed according to the formula (A.3.15), but we
have to take care that for s = xo the integrand is unbounded. We eliminate this inconvenient writing
(20Cos('1r2 -s')e '''rd7= T -8 is 0 e-0 - e+
/s
T
-s
V7-r- S
Js
d T + CO°
TO
1
e' d-r+
dr
T -8
12
(10.4.20)
After all k2
ni (xo, yo, z) =
s
H(xo - s)1,
(10.4.21)
s ) e "°TdT ,
(10 .4 .22 )
where
0 8s,
=o Cos
(
r
r
the derivation being possible if we utilize the equality (10.4.20), but we have no interest to do it. The integral may be calculated with the
OSCILLATORY WING IN A SUPERSONIC STREAM
431
substitution r - A : r = scoshA. Deriving one obtains 1
- -rpcos(vxo-3 )e S
O
V xp zp
-.%1
-r
e'"''r
s
d
dr [sin (v
r2 - s2)] d r-
esin(v r2 - s2)d r
(10.4.23)
.
We integrate by parts in the second term from the right hand side. Passing to the limit in (10.4.21) we notice that, like in the steady case,
it appears the singular line yo = 0. After eliminating from D the domain D, defined by the inequalities y - E < tj < y+E we shall put in the remaining domain z = 0. One obtains the following singular kernel It 1(ro,yo) = lim nt(xo,I/o,z) _
Yo
+
ff
e-V"o sin (vS) + M
Cos(,S)e_k-xo+
u)
-H(x
J
1X0
e iur sin (vSS)d r =
= H (xo - u)n(xo, yo) , (10.4.24)
where, u = kIyol and
S=
x0-u2,
Sr =
Jr2-u2.
(10.4.25)
For w = 0 one obtains (8.3.23). This will be the kernel of the integral equation. In the sequel we shall give a demonstration where the terms which contain tht factor :2 are not neglected. As we have already noticed, acting in the classical manner, we have to calculate the limits for z --+ f0 of some kernels which contain derivatives with respect to this variable (see Nlangler [10.52] for the subsonic steady flow, Heaslet and Loomax for the supersonic steady flow, Watkins, Runyan and Woolston [10.86} for the oscillatory subsonic flow, Watkins and Berman for the supersonic flow, etc.). Since generally, for performing this calculation we have to evaluate at first the derivatives, the passage to the limit becomes difficult. In
order to avoid this, we gave other expressions to the component w
432
THE UNSTEADY FLOW
((2.3.29), (2.3.37), (2.4.23)). In the general solutions built on the basis of these expressions it appears only the derivatives with respect to y. The passage to the limit interchanges with these derivatives. In the actual case from (10.4.11) we obtain n2(xo, yo) = line n2(xo, yo, z) _ 2-.o _ (2iw + k2)
H(x u) cos (vS)e-'"'%O+
(10.4.26)
cos vS,. ecWrd T,
82
+(w2 - 8y2 )H(xo - u)
S,)
where u = k1yoI . Since we have 02/0y2 = k282/c9u2 , with the notation
J_
cos(vST)e-,,tdT,
49
au
(10.4.27)
r
u
we deduce 1,2
-y2 H(xo - u)J =
k2 82 H(xo - u)J = k2 0 H(xo - u)J
(10.4.28)
where J, calculated like 1 ,is
J = - xo caos (ys)e-'ixo S
u
-!
e
MU
sin (vS)(10.4.29)
2°
W
Mu j
a w''r sin (vST)d r.
For determining H(xo - u)J we take (2.3.35) into account. In this way, from (10.4.25) one obtains rigorously (10.4.24). If the equation of the oscillatory surface is
z = h(x, y)e'
,
(x, y) E D
then one imposes the boundary condition
w(x, y, 0) = 8 h(x, y) + iwh(x, y) _- G(x, y), (x, y) E D
(10.4.30)
One obtains the following integral equation
J
1n,
f
n)e`"n(xo, yo) d 4 d n = 21rG(x, y),
(10.4.31)
DI being the domain marked in figure 8.3.5 (the domain where xo > u).
OSCILLATORY WING IN A SUPERSONIC STREAM
433
Other Expressions of the Ker e1
10.4.4
We have
rro
L =1 e-'
sin (vST )d r = 2i (L_ - L+) .
(10.4.32)
u
where we denoted
Tn
=
(10.4.33) U
In L+ we perform the substitutions r --- A:: T
MS, = kiA.
(10.4.34)
Taking into account that T is positive in both cases we deduce
kT=-uA+uM
1+A2,
(10.4.35)
such that
LT- = tyo(
f/
1
1+A'
e-'+Iyolad A
(10.4.36)
e-i:wlyola d A.
(10.4.37)
whence
L
= -- j (yo'
2i
(=o+MS)/ku
AtA
z o-AjS)/ku
1+A
-1
)
Since, on the other side, (x +MS)/ku
eWroad A =
'
4yo
jxo_MS)/ku
sin (PS)
.
(10.4.38)
from (10.4.24) we deduce Cos (VS) a-iUX0- iw
n(Xo' yo)
yo
S
2Iyo)
=o+MS)/ku
L0MS)/kU
A
e-i&+lYOI-%
dA.
V1--+-A2
(10.4.39)
This is the kernel given by Watkins [10.851. Obviously for w = 0 one obtains the steady kernel.
434
THE UNSTEADY FLOW
Performing the change of variable A -> v : Jyp)a = v and and integrating by parts, we deduce
' _IYoEa (x04-MS) f ku
a
2iyol
=-
1+A
.Y+
1
y2+X+
2y0
-
d.1=
iirJ
JX*
ye-n.rv
+L dt
-
2-y6'
X-
-
e--iwx_
+
TY0127X2
c- iwv
1#
1
e-'wx+
e
-d v'
2
x_ {Up + v2)312
(10.4.40)
where
k2X,=xo± MS.
(10.4.41)
Observing now that
2e-0'0 coss(vS)=e-+e-"'x+
(10.4.42)
utilizing (10.4.40) and the identities xo
yQ + .X+
- SX+ = xo yo + X? + SX_ = Myc'
(10.4.43)
,
we obtain for n(x0, yo) the following form given by Harder and Rodden [10.20)
2YL(xo, IM)
a-iwx..
e--W,x}
M
e-Iwv
.
V7=` 0+
1j,x
+2
(YO-1
+172)3/2
(10.4.44)
Another form of the kernel is obtained if one utilizes the identities
_ yO+X2
Mxo:F S xp+yo
_
Al
xe+X
(10.4.45)
One obtains the relation L12
2n.(ro,rlo)
S
a-ivx«
a swx
o+X_ + xo+X+)
X..
a-iwv
{3lo+tr2)3/2dv, (10.4.46)
utilized by Ueda and Dowell [10.811 for obtaining the numerical solution of the integral equation.
OSCILLATORY WINC IN A SUPERSONIC STREAM
435
One obtains the sonic limit at once from (10.4.44), or (10.4.46) notic-
ing that lim
A!-l
X_=-12 (xOlxo/ -X,
limN--1X=00.
(10.4.47)
One obtains the following kernel
H(ro)
2
2
12g + yo
(xu, Ilo)
+e
iWx
la + J/
oo
e'""
(Jp + t')3/2d vJ (10.4.48)
which coincides with (10.4.26).
A New Form
10.4.5
We utilize the formuhas (see for example 11.30], pp. 406, 422) with real parameter O° cos,
cos
"i
(pr)dT = ko(u v2 -12), (10.4.49)
°° cos (vSr )
i-Sr
sin (pr)d r = 0.
For p = 0 we obtain the identity
r°
ST)e-wTd r. _ Ko(wlyol) T
u
00 Cos(VST)e
- f.0
rrrdT,
(10.4.50)
T
as follows 2
fi Cw2 - k2
0' f J
rn Cos (VS_)
u
a lord r =
r
1 Iw--k2ou2/
[Ko(-ku)- f
T7r
.J=f
T
J
In the last part we derive without any difficulty. Deriving, the kernel (10.4.25) becomes
n2(xo, yo) = H(xo - u)n(xo, yo)
n(a'o,yo) _
r
- wM kkt(Au) u T J=°
. Cos(yST)e_Ord
-k.2 To
ST
sin(vST)e-` S2
r,
TdT-
(10.4.51)
'TIE UNSTEADY FLOW
436
where u = kJy I . This is the new form of the kernel. Having in view the behaviour of lit , for small values of the argument, this is 1
-
22
(I,, Iyul + r1) ,
r, = in 2 + -y
2
(10.4.52)
,
yo
-y being Euler's constant. An additive constant r2 also appears from the two integrals (10.4.51).
The kernel of the integral equation in the case Al = 1 is obtained from (10.4.51). We have
illl A2 I\1u) =
1yu1Rt(wIyoI)
Denoting rao
It = 2iJ
Sr -
7)]d T
ao
I2-2i f exp(-i (MSr+r)1S
1117-
we have.
°O sin (yS1) xp
r 2
_rd T = It + I2.
But
It
_
1
exp
2l
-
1
21
nhinl It =
f.0
[1'A12S2 - r2
Al ST + r
r2
exp iw AI
(IT
S; = dr
Aft 2
r2 - k2y + T
T2
,
- k2y0
li
10"exp Pww (r - TA) ] T L.
One obtains after all (10.6.13).
10.4.6
The Plane Problem
such that in the repIn this case, the density f q) becomes f resentation (10.4.7)-(10.4.9) we can calculate the integral with respect
437
OSCILLATORY WING IN A SUPERSONIC STREAM
to r l. We have 90 =
f
00
Co(xo,Uo,z)d9=
+oo
1
J
= 27
H(xo - k r2 + z2)
cos[v xo-k (r +x - k (r + z) zo
)J
dr.
(10.4.53)
Because of the presence of the function H, the integrand differs from zero only for xo > k r + z . This inequality implies zo > 0 and k2r2 < x2 k2z2, whence xo > kizl and -c < kr < c, where c = xo - k z2 . After all
-
oos{v
2-e'H(xo-klzl)f
90
-
C
-k r dr. r
(10.4.54)
Utilizing the formula 11.16] ` Cos (p
c- x-x)
(10.4.55)
gxdx= 2Ja(cjp2+g2),
it results
go =
H(xo - klzl)Jo(v xo - k2z2
(10.4.56)
and analogously 9
Gd q = gH(xo - klzl)Jo(v
roo +00
e
=
J
Edrt = ao
1 jr-a° H(r - kjzj)Jo(v
_ H(xo - kjzj) 2k
k2z2)e'
xo
Jo(v
0,
(10.4.57)
r2 - k2z2)e''O'd r =
r2 - k2z2)e rdr.
fk1Z1
(10.4.58)
For obtaining the results from 10.3 we have to consider the chord of
the profile on the Ox axis (0 < x < Lo) and to take Lo as reference length. Observing that
j
+oc &2 00
OY
2E(xo,yo,z)dq=-J
+00
02
8 Edt =-AEI 00=0,
438
THE UNSTEADY FLOW
we deduce 1
p(x,z) = - I f(e)e sodt, w(x, z) =
f
(10.4.59) 1
f we-k""°
[(2iw+k2)g+,2c]d
which is exactly the solution (10.3.6). We obtain too +00
n(xo) =
J
n2(xo, yo)d tl = +m G(xo,
= 2iw
yo, 0) d >1 + k2
J00
+w2J
a TX
+x G(xo,
y , 0)d n+
100
G(r,yo,0)dil = 2a(xo)Jo(z'xo)eui""`0+ 00
+H(xo)no(xo),
(10.4.60)
where no(xo) =
T-
T
[Jo(vxo) + 121 Jt(aod
e1 .lo(vr)ed T , o
(10.4.61)
i.e. (10.3.13).
10.5 10.5.1
The Oscillatory Profile in a Sonic Stream The General Solution. The Integral Equation
We proved in (10.2.54) that there exists the limit of the subsonic solution for M / 1, and in (10.2.45) that there exists the limit of the supersonic solution for M \ 1, and in addition, the two limits coincide. We shall prove now that there exists also the solution for M = 1, and this one coincides with the two limits. It will result therefore that the flow is continuous to the passage past the sonic barrier, unlike the case of the steady flow. We shall consider therefore the oscillatory profile (fig. 10.5.1) of the equation
y = h(x)exp(iwt),
(10.5.1)
439
OSCILLATORY PROFILE IN A SONIC STREAM Yt
0x
I Fig. 10.5.1.
which perturbs the uniform flow which has the velocity Ua, = cm (M = 1). With the notations (10.1.4), the boundary condition (2.1.27) gives
v(z, t0) = h'(x) + iwh(z), 0 < x < 1.
(10.5.2)
The fundamental solution in the two-dimensional sonic flow is given by the formulas (2.4.32)-(2.4.34). If the profile is reduced to the skeleton like in figure 10.5.1 it is sufficient to replace it by a forces distribution having the form (0, f)exp(iwt). (10.5.3)
It results therefore
P(x, y) = --f
a Go, (10.5.4)
v(x, y) = f ei`''°` [(21&G + w2 T G(r, y)d rj
o
where r
Go(x, U) = H(x)
exp I _ !(X
+s
)J E H(z)So(x, p) , (10.5.5)
1
G(a, Y) = H(x) -OM
[(x -
)}
H(x)9(z, v) ,
with the notation 2f/ = 1. A continuous superposition of forces having the shape (10.5.3) on the segment [0, 11, will give the perturbation
i
P(X, U)
I
v(x, p) =
J0
1
f (() gpGo(xo, y)df ,
f (C)e^'"'° [(2iWG(Xo, y) + w2
Jzo
0
G(r, y)d rJ dl;
440
THE UNSTEADY FLOW
Taking the significance of the function H(x) into account. it results that for x < 0 we have
P=O, v = O,
(10.5.7)
and for x > 0
f 2fV)ryyo(ro.y)d
P(x,y)
To
fr
v(x, t!) =
(10.5.8)
(2iw9(xo y) + w2 f 9(T, y)d r d ti
fWe-ten
I
.
0
(10.5.9)
This is the general solution of the problem. It was given in (10.18. Performing the change of variable F -« u : u = y'/xo one obtains °G
iw1Z Jy2
P(x. ,) =
f (x -
y-'
)exp
;r.
[_!f + u)]
ll
Ou-
and then
P(x, ±O) _ T-iwfl f (x) f exp
-'2 It
`
= +,l f (x )
(10.5.10)
It results therefore
p(x, -0) - p(x, +0) = f (x)
(10.5.11)
.
For 0 < x < 1 we deduce
v(x,±0) =
jj
f(Z;)e-'"`°n(xo)dy.
(10.5.12)
ro
27 [
exp(2 xo) - 2
( } J exp 'T)
1
.
(10.5.13)
Imposing the boundary condition (10.5.2) it results the following integral equation
jf()n(xo)d
A(x)
(10.5.14)
where A(x) = h'(r) + iwh(x). The kernel (10.5.13) coincides with (10.2.54) and (10.3.46).
441
OSCILLATORY PROFILE IN A SONIC STREAM
10.5.2
Some Formulas for the Lift and Moment Coefficients
Taking into iweount that
1-i
=
I
D- 2
(10.5.15)
4 fa-w
the solution (10.3.52) may be written as follows
3(x) = 2iwft
fA
)exp(- Z l;)d 10.5.16)
-2fl J e 12
ex p(-
2 t)u
,
the sign * indicating the Finite Part (Appendix D). Denoting
f
F = Ir A(xo)eXp(- +t)dt
A(,)
2
xo
o
P(_!2xo)df ,
(10.5.17)
with the definition formula (D.4.2), we deduce
1z o
5.7r
[A(')
l so gyp(
_ iw 2
]
xo)d=
dx '
(10.5.18)
and then
-J
exp(
- 2 )d t - iw F+2df .
(10. 5 . 19)
After all the Jforinula (10.5.16) becomes
1(x) = ti
(ii' + dx
(10.5.20)
The lift and moment coefficients are given by the formulas (10.3.29) with (10.3.30). Utilizing (10.5.20) we find cL - SS2 J
1 A(1 - 0 + WB(t)
0
P(- 2 (10.5.21)
c,tt = 80
ri
A{1-
) + iwD(>;)
2 )d
where we denoted I
1
B(4) _ I A(xo)dx, D(t) = J xA(xo)dx.
(10.5.22)
442
THE UNSTEADY FLOW
Approximating the function h(x) by polynomials, we deduce that the integrals from (10.5.21) have the form 1
f(
2exp(-2 )d
,
it = 1, 2, ...
(10.5.23)
Integrating by parts we obtain
-.2 exp(-12)+
2n
1W
n=1,2,...
iW
(10.5.24)
It results that all the integrals from (10.5.21) may be expressed as functions of
Io =
J
exp(-
)
Vq
[c(/) - iS(
=2
11
7r
)]
,
(10.5.25)
where C(x) and S(x) are the integrals of Fresnel [1.30):
C(x) =
fS(x) =
1
2.
j
(10.5.26) -
the notation z = irx2/2. In the case of the flat plate having the angle of attack c (h = -E.r. ) one obtains CG = -4f k(1 + iw) CM
[2exP(_) +(I+ iW)I01
=-aQEK-iw+3tw+e P(12)+(2i
4)i].
+1
(10.5.27)
10.6 The Three-Dimensional Sonic Flow 10.6.1
The General Solution
In the three-dimensional sonic flow the fundamental solution is (2.4.36)
and (2.4.37). A force having the shape (0, 0, f)exp(iwt) , applied in the origin, will produce the perturbation
P = H(x)p, W = H(x)w,
(10.6.1)
where
P(x,y) _ -f8 go, w(x, y) = f e'w,x [2iw9 + (w2
-
z) / JJJ
(10.6.2)
g(r, y, z)d Tl J
TIIE THREE-DIMENSIONAL SONIC FLOW
443
with the notations 1
go (x, y, z) =
, zy)_
9(x,
4;rrexp
1
.rr
(-
2r.' 2
e`priw IL 2
(10.6.3)
y2+z
z-
x
The perturbation produced by a distribution of forces having the form (0, 0, f (s, r1))cxp(iwt) ,
defined on the domain D (the projection of the wing on the xOy plane), will be characterized by the formulas
P(x,y,z) w(x, y, z) =
8
J JD
f (E,
r?}e-"'"`" 1(2iwg(xo,
+(wl - ay ,)J
10.6.2
yo, z)+
(10.6.4)
9(r,yo,z)drJdedr.
The Integral Equation
Assuming that D is such that every parallel to the span (the Oy axis) intersects the boundary OD in at most two points and denoting by y_ and y+ the ordinates of these points (fig. 10.6.1), we obtain
110 With the change of variables
x-
s1=y+l:I v;
f
V}}"'d'1 dC
(10.6.5)
r1) -p u, v :
zJdudv
(10.6.6)
THE UNSTEADY FLOW
444
Fig. 10.6.1.
we deduce
P(x,y,±O) = 47r
iw
lim x
lim
fp
tE) f(c 17)
+ yo + ~ zo
2
/
d
dn
22
Z
47r :-.to 2
(X0 I
xo
7- (F)
exp
f (x - -, y + I= Iv)
I
U
(f)-SI/I=I
exp
iw
z2
2
u
+u(v2+1)]}dudv f /
=
exp [ - Z uv2)dv] du.
Utilizing the integrals of Fresnel 00
I
cosx2dx =2 f
0
20
Cost
dt=
°sinr2dx = 1
f s'n dt = 2
2
(10.6.7)
we deduce
P(x,y,f0)_T2f(x,y)
(10.6.8)
Hence P(-T, y, -0) - P(x, y, +0) = f (x, y) .
(10.6.9)
445
THE THREE-DIMENSIONAL SONIC FLOW
Assuming that the equation of the oscillatory surface is
z = h(x, y)exp(iwt),
(10.6.10)
we obtain the boundary condition w(x, y, ±0) = h'(x, y) + iwh(x, y) _- A(x, y) , (x, y) E D.
(10.6.11)
It results the following integral equation 2n
lID f( t, ri)N(xo, j) d t d 0 = A(x, y),
(x, y) E D ,
(10.6.12)
where
N(xo, yo) = amp
[iw(
2x o
y1 + (10.6.13)
\W2
1
02
'O=p iw
yl
dr
2
We have also obtained this kernel from the kernel corresponding to the
subsonic flow (10.2.58). On this formula we cannot observe yet the singular part of N We shall calculate therefore the last term. Using the formulas
I
0
zo
J
exp
2
Ocein coo
(r -
(ax- z )dx _ {2Ko(2v)
\l LT
(10.6.14)
2K0(11p0D)-1°O exp
f2
(r
}] dr
The last integral may be derived with respect to y interchanging the derivation with the integration. One obtains
b
Texp ( 2r0)8'r' lrexp (
"4 exp
2
In this way we deduce the final form of the kernel
(.r
N(xo,yo)=-1 ! K1(wlllol)+ 2
_)1]J 7d 1, 2
(10.6.15)
446
THE UNSTEADY FLOW
The principal part is in the first term. Taking into account that for small values of the argument we have
+zlnz+...,
K,(z)=
(10.6.16)
it results
N(xo,yo)=----w2(lnlyol+r)+....
(10.6.17)
A
The singularity has therefore the same order like in all the other spatial problems.
10.6.3
The Plane Problem
We remind that one obtains the solution of the plane problem if we assume that D is a rectangle having the dimensions Lo and bL0 and we consider b --+ oo. Moreover we assume that every section with a plane parallel to xOz determines the same profile, hence in (10.6.10) h depends only on x. Taking Lo as a reference length, the domain D will be defined by 0 < x < 1, -b < y < b. Considering b oo we have to obtain +00
n(xo) _ j
N(xo,yo)dri,
(10.6.18)
o0
where n(ro) must be (10.5.13), and N(xn, yo) (10.5.15). Indeed, utilizing the representation 11.30] !OD
J
(t2
C} ``'dt,
(10.6.19)
-2)3/2
we deduce rc+Oht(_u)du=2
w)+'Kt(wlyol)dyl_2w
00
o
lyol
u
0
=2'(r0°coswt-1+Idt-7rw Jo
t2
zrw+2J
o
t
J" coswtdt t.
+2J, t-
2 16 f00dt
+ 10 7rw
2
=
447
THE THREE-DIMENSIONAL. SONIC FLOW
Utilizing Fresnel's fortnulas (10.6.7) and integrating by parts, we obtain exp
T2 011171d"
T
=21 cxp(i"T) [f (1-i)
2 7.ro=
Pxp(
`
2
IIIJII
-10
4:
u2JduJ
tw expTol+
T)dr
+ iw J exp (t2 =27ri+
27-
vfT
- tw
I
exp (t2 T)
vfT-1
(1-i)[ 2 exp(t-xo)-iwJrexp 2TdTr 7x=o
`\'2
o
We deduce therefore
-'.w [
ri(x0)=(1+i
1
yrr-o- x
p
o
iw 2x o1 2
ex
p iw ) d T 1
of
2T sfJ
'
(10.6.20)
i.e. just (10.5.13).
10.6.4
Other Forms of the Kernel
From (2.4.13) and (2.4.35) it results the following representation of the component w of the velocity w(X ,
, z) = 5(`) JJ f(. rt)H(xo)6(yo) d d i+
t f
.{.i-
(10.6.21)
n
Jf
where 2
11(x0. yo.
a'2 J
exp
2 (Ir _ yQ+z2/J T
LT (10.6.22)
One may demonstrate that this integral is convergent. Denoting r = iyol and performing the change of variable r --+ A:
7.
T - - = 2A
dT
-r
dA (10.6.23)
77 7
448
THE UNSTEADY FLOW
one obtains
n(xo,yo,z) =
8 J-.
d.1,
+r
(10.6.24)
where
X=2(TO-xo).
(10.6.25)
Observing that
02 _1 1_z29+za -2 r
Z2
(
r2) th
r2 5r2
we deduce that the line r = 0 is singular. Eliminating a vicinity of this line we obtain lim
82
_
10
r Or
O 0z2
whence
n(xo, yo, z) =:-to lim n(xo, ?b, z) _ 2
fA
(1u.o.lo)
eWA 00pt2+r2)3/2da.
This kernel was obtained in (10.2.36) as a limit of the subsonic kernel and in (10.4.48) as a limit of the supersonic kernel (Ueda and Dowell [10.80]). This fact proves that the oscillatory perturbation is continuous to the passage of the sonic barrier. f0, the first term from (10.6.17) Passing to the limit, when z vanishes because 6(f0) = 0.
Chapter 11 The Theory of Slender Bodies
11.1 11.1.1
The Linear Equations and Their Fundamental Solutions The Boundary Condition. The Linear Equations
In this chapter we study the aerodynamics in the presence of slender bodies (fig. 11.1.1). The axis of the body is considered the Ox axis
and the Oz axis lies in the plane determined by the velocity of the unperturbed stream V. and by the axis of the body. We denote by a the angle of attack of the stream and we assume that a = e, where e characterizes the thickness of the body. We employ the cylindrical coordinates x, r and 0 which are related to the cartesian coordinates x, y, z by the formulas
x=x,y=rcosO,z=rsinO (11.1.1)
xER,rE (0,oo),0E (0,21r).
Fig. 11.1.1.
The equation of the body has the form r = h(x,0) = eh(x,0).
(11.1.2)
450
THE THI3OKY OF SIZNDER BODIES
Denoting by i, j, k the versors of the Ox, Oy and Oz axes and i,., ie (fig. 11.1.2), we shall have the following formulas
i,. = jcos0+ksin8
j = ircos9--ipsin0 (11.1.3)
ie=--jsind+kcos8
k=i,.sin8+iscosO.
Fig. 11.1.2.
The velocity of the unperturbed stream is
V,, - U,,,(i cosa + ksina) = UU(i + ak) + 0(a2).
(11.1.4)
Denoting by
V1 = Uvv,
P1 = Poc + P-U«,P,
P1 = Poo(1 + P)
(11.1.5)
the fields which characterize the perturbed flow and using the cylindrical coordinates
V=Ui+Vi,.+Wi$
(11.1.6)
v=Ui+I ,. +Wie, we deduce
U=1+u, V =asin8+v, W =acoa8+w.
(11.1.7)
THE LINEAR EQUATIONS AND THEIR FUNDAMENTAL SOLUTIONS
451
Obviously, the perturbed flow will be steady because the conditions which determines it do not vary time. On the boundary we shall impose the condition
V grad F = 0,
(11.1.8)
where F = Eh(x, 0) - r. Taking into account that we have
gradF=
5s+
Vii.+Tiei
(11.1.9)
from (11.1.8) we deduce the condition
(1 + u)F as + (a cos 0 + w) r L = a sin 0 + v,
(11.1.10)
which must be satisfied when r = h. Comparing the orders of magnitude we deduce:
v(x, h, 0) = ev(x, h, 0)
.
(11.1.11)
We assume that this structure is valid everywhere in the fluid. We have therefore
v(x,r,9)=e'v(x,r,0).
(11.1.12)
From (11.1.10) and (11.1.11) we deduce the condition
v(x,r,0) +asin0 = hz(x,0),
(11.1.13)
which will be imposed for r = h. In fact, this condition must be imposed
for r = 0, but here v is not defined. In cylindrical coordinates the equations of motion are (1.11]: AP [Up.. + Vp. + (W/r)pg)+ +(1 + ryM2p)(U,+Vr + (1/r)V + (1/r)We] = o
(11.1.14}
(1+p)(UU=+VU.+(W/r)Ue]+p,, = 0 (I + p)[UV + vv. + (W/r)Ve - (W2/r)] +p. = 0
(11.1.15)
(1 + p)[U11=+VW.+(W/r)We+VW/r]+(1/r)pe =0,
(11.1.17)
(11.1.16)
where U, V, W will be replaced by (11.1.7), and P. =00/8x'... With the reasonings from 2.1, the equation (11.1.16) gives
p(x,r,9)=E (x,r,0), v=+pr=0,
(11.1.18)
the equation (11.1.17) w(x, r, 9) = sw(x, r, 9),
rwz + pe = 0 ,
(11.1.19)
452
THE THEORY OF SLENDER BODIES
and the equation (11.1.15)
7t(r,t,B)=SYf{e,r,B),
71r+p. =0.
(11.1.20)
Keeping the terms having the order of E, from (11.1.14) we deduce
AM2pr+u,.+vr+(1/r)v+(1/r)wo
0.
(11.1.21)
One observes that in the linearized system o does not intervene. The system coincides with the system for cr = 0. It. is the system (2.1.32) in cylindrical coordinate:.
One may also obtain the equation of the potential. Indeed. from (11.1.18) -- (11.1.20) it results:
yr - ur = 0, rw;r - uy = 0.
P = --u.
(11.1.22)
The last two equations prove the existence of the function V(:r, r, 0), a.I. 7r. _ (j.,
V = 4'r i
to = (1/r);pe ,
(11.1.23)
and the equation (11.1.21) gives (1 - Al `)
11.1.2
a"-
10
t1:r.2 +
r Or
r
a(pl
C Or
1
+
j92 = 0.
(11.1.24)
Fundamental Solutions
We shall utilize for the solution of the system (2.3.4) the intrinsic form (2.3.8), (2.3.12) which will be written in cylindrical coordinates. From the equality
ft: + f29 + f3k = f1 + frtr + fOZO,
(11.1.25)
taking (11.1.3) into account , we deduce
f2 = frcus0 - fosin0,
fr = f2cas0+ f3 sill 0 (11.1.26)
fi = fr S1118 - fB COS B,
f0 = -12 sin 04- f 1 cos 0 .
Writing the inner product in cylindrical coordinates, in the subsonic ease and Taking (11.1.26) into ac( -ount, from (2.3.4) it results
r) _
-
I
+fri0) ` ) 1
(11.1.27) 1
THE LINEAR EQUATIONS AND THEIR FUNDAMENTAL SOLUTIONS
453
where
R, =
x2 +#2r,2,
(11.1.213)
From (2.3.13) we deduce
_
1
47r
_
/
dx
fr J x
(x2 + #2x2)3/2
2r
f=
R, -
(11.1.29) 1
4:s
fr
Rl -
fr 1 + x
r(R,)
Taking into account the expression of the distribution 6(x) in cylindrical coordinates [A.7J, [A.10). we obtain yr
=
f'.
L. a
H(x)d(r) 21rr
+ 4r, 8r
fr a
1
x
1
(11.1.30)
R, } 4;r 8r r
In the supersonic flow we have
P(x,r) _ -i-. (fr_8x +fr where
E(x. r) _
i
l
J E(x ,r),
(11.1.31)
H( x-kr) x- -k- r
(11.1.32)
Since
a f" H(r-'-r) d r =H (x- kr) 0 8r oo T- k r
dT
=
,r r- - k r
2:E (x,r),
r
from (2.3.13) it results
p(x, r) = 1 (f= - x f,.) E(x, r) (f..
19
+ r fr - r fr5T) E.
(11.1.33) (11.1.34)
Taking into account the formula (2.3.35), p and Vr will be: x Vr
_
- fr
H(x - A-r) r
H(x)b(r) 27rr
x
81
+
27r
h
8
+
1kr, x r2
fr-
(11.1.35)
1
fr 5T x -k r These formulas show that the perturbation propagates only in the interior of the cone x = kr. -r
454
THE THEORY 0FSLENDER BODES
11.2
The Slender Body in a Subsonic Stream
11.2.1
The Solution of the Problem
In the case of slender bodies of revolution, the equation (11.1.2) has the form
r=h(r). 0 < x < 1.
(11.2.1)
Considering that the unperturbed flow has the angle of attack z in the xOz plane, we deduce that. this plane will be the plane of symmetry of the flow. We shall replace the body with a distribution of forces defined on 10.11
with f2 = 0. From (11.1 26) we deduce fr = f sin0 (we
denoted f3 = f). Taking (11.1.27) (11.1.30) into account, we deduce that perturbation produced by this distribution may be represented by means of the formulas
p(.r, r, 0) .
" { f,
Rd
Jx + f (l;) Sin A
J
47r-
(11.2.2)
W(arrtd)=
xj 1
'r(X, r, O) =d(l)
R
sin 0
d
4irr
sin 0
,-TI
'
x0
(1+ R)f(E)d
Jhit(0
0
)
(11.2.3)
sill 0 y rl (1 + x0) d 4 it 8r Jo r R where
R= 4+Ir'r2.
.T.ox-
Imposing the boundary condition (11.1.13), we notice that d(h) = 0 because h does not vanish for 0 < x < 1. Separating the variables we obtain the following integral equations:
f
f
0(I)d
41rh'(x)
(11.2.4)
(11.2.5)
for O < x < 1 and r = h(x). In order to solve the first equation we shall utilize the identity
v fir
1
R)
1
8 ((xol _ 1 5-x
iI_
((xo R} ra(RI
(11.2.6)
455
THE SLENDER BODY IN A SUBSONIC STREAM
Integrating by parts, we obtain: x - 1 47rh(x)h'(x) = ft(l)
x -1) + Q h (11.2.7)
-fi (0)
r2
+
= - [fl(1) + fr(o)] [1 + 0(h2)]
h
where
_ t I=f'
xo
h
xo+
fi(:;)dt.
(11.2.8)
For calculating the principal part of this integral, we notice that we have xo
+
lio' [i + 0(h2)]
h
(11.2.9)
excepting the vicinity of the point £ = x where xp = 0. In [1.1] one utilizes this approximation on the entire interval (0, 1). Correctly, the integral I must be written as follows
(/
I=
+ / 7+1
J
(11.2.10)
In the first and last integrals we may utilize the approximation (11.2.9).
For ,i small enough, in the second integral one may replace fl (t) by f ' (x). We obtain therefore
I = lro
[ r:o
fi (t)d t -
J:+n fi (t)d C]
[1 + 0(h2)] +
1
+ f (x) lim
+''
,j- .0
q
dt
p
+h
We calculate the last integral with the substitution x - = u and we observe that it vanishes. Hence,
I = [fl (x) - fi(0) - ft(1) + fl(x)J [1 + 0(h2)] .
(11.2.11)
Neglecting the terms of order h2 with respect to 1, from (11.2.8) and (11.2.11) we obtain
fi(x) = -27rh(x)h'(x) = -S'(x),
(11.2.12)
with S(x) = 7rh2(x) the area of the crass section a of the body in the point having the abscissa x.
456
THE THEORY OF SLENDER BODIES
Deriving in (11.2.5), we find
j' (1 + R)
f(E)d F + f32h2
"' f J. 1T4
-4iah2 .
(11.2.13)
Calculating the integrals by means of the formula (11.2.10), we have
J1(1+ O)f(:)dF=21 f(t)dF[1+0(h2)] Hence, neglecting 0(h2) with respect to 1, we obtain
f(e)d t = -2Tah2 = -2nS(x) 10
or, deriving,
f (x) = -2aS'(x) .
(11.2.14)
For the profile with zero angle of attack (a = 0) we deduce f = 0 whence
N(x,r) _ -4 0,
xo+
r
dF.
(11.2.15)
This representation of the potential is known in the literature [1.11, (1.38]. We have also, from (11.2.2) (for r # 0), (11.2.16)
P(x, I') = -4r, Vr = SFr
11.2.2
The Calculus of Lift and Moment Coefficients
We shall calculate at first the pressure for r = h. It can be obtained from (11.2.2), (11.2.12) and (11.214). Utilizing the identity (11.2.6) and the calculations (11.2.8) - (11.2.11), we deduce
jf(0
.
d
(R)
(11.2.17)
[1 + O(e2)]
.
Hence, sin 0
P(x, h(x), e) = pi (x, h(x)) - a Wh(x) S`(x),
(11.2.18)
157
THE SLENDER BODY IN A SUBSONIC STREAM
where
r fl (E)' (1?)
P1 (X. h(.r)) _ - 1
J
1r,,iid E
(11.2.19)
1f1 4r
:rOS'(E)d E (%2+132,12)3/'2
Taking into account that fr = O(V2), we calculate the principal part of pl as follows: I
4;rP1(x, h(x))
W) r_I,d
fl (S)3
_
11(1)
(x11-)
f1(0) x'-+f32h2
-j3 h=
9 r,
+J fl(E) I-E
S'(1) + S'(0)
+f
d
z*F7
+ fi(x) lim
r.
1-x
T
J0 x -
-
01 S"(r)
Er
>
r0+th`
+O(Fd)-
- S"(E)d
x-E
x
t
J
S"(x.)
E--x
1
+ S(x) In
1-c r.
+ O(c4) ,
the principal part which was written being O(_2). The lift coefficient may be calculated with the formula
cL=
(11.2.21)
- As
where S is the surface of the body, and n, the outer normal and with the notation F = r - h(x), given by the formula grad F - -h'i + i, (11.2.22)
n =
Egrad FI
V1-1+ h'2(a)
Taking into account the element of area on the surface S, and the relation (11.2.13), we obtain r1
A
CL =- / / ,r p(x, h(x), O)h(x) sin 0d rd 0 = o
=(I Es(1)-s(0)j.
(11.2.23)
458
THE THEORY OF SLENDER BODIES
For the drag coefficient one obtains
CD =- Jjpn id a =
jj(x, 1
h(x), O)h(x)W (x)d xd 0 = (11.2.24)
pl(x, h(x))S'(x)d x = O(E4) .
The drag coefficient does not depend on a. At last, the moment coefficients are the scalar components of the product
-2 /f xxpnda, S
where x = xi + h(x)ir. Taking into account (11.2.2) and (11.2.22), we obtain
cr =0, cs=0, (x + hh')h(x)p(x, h(x), 0) sin Od x d 0 =
f1I
-2a / o
1
Lx +'
(11.2.25)
S'(x)d x = O(E3) . J
Obviously, for a = 0 one obtains cy = 0. Neglecting the term (S')2, for the moment coefficient c, we obtain the approximate value
ri
c, = -2a J xS'(x)d x = 2aV, 0
b ecause S(1) = 0 and the term
of the body.
11.3 11.3.1
j
S(x)dx represents the volume V
The Thin Body in a Supersonic Stream The General Solution
In this subsection we consider the same problem like in the previous subsection, but now the unperturbed (free) flow is supersonic (M > 1).
459
THE THIN BODY IN A SUPERSONIC STREAM
titre consider again that in this case the xOz plane is a symmetry plane, such that we have f; = 0 whence fr = f sin 0. The fundamental solution is (11.1.31), (11.1.34). and the corresponding potential is (11.1.33). For a continuous superposition of forces on the segment [1).11. the perturbation will be given by 1
+f w sin ©J E(.,ro, r)d
P(x. r, 0) = - T f p(x, r, 0) =
[f=w
2-r J0
- rl f (5) sin 0] E(r(j, r)d i
X
t'r(X, r, 0) = (5(1') in0
2'r
JU
.E(xa)d ,r
+
sin0
ff U
1
err f0 roI
0Y
.
l - J)F(xor)d r
9r,
(11.3.1)
The derivatives may interchange with the integrals and. taking (A.3.15) into account, we have for example
f 1 f W E(xo, r)d t= ax f
_
a
x-kr
H(.r-kr) o
f x
1
f
E(xo, r)(1 _
FL-r H(x-k'')r3
4.
`I
f (4) ==
zo
k-12-7-11
Hence, the solution (11.3.1) maybe written as follows
_
2r TX o =
r-kr
1
r
_ yr
x-kr
8
1
P
x
sin 0_ 8 d42z Or x2 - k r(4)
dE-
in
xo - k 2 rI
sin 0 2rrr
f()cI+ 2 r
b(r)
+siI 0 27tr
1
Of
sin 0
8
f V) dC xo - k2r2
o
r-kr xQ
2,rr Jo 1
r
r-kr
fx (50)
ro
r-
d
jr-kr x xo
xo-k'r
k2r2
d (11.3.2)
460
THE THEORY OF SLENDER BODIES
valid for x > kr and
p=W=vr=0 forx
(11.3.3)
Imposing the boundary condition (11.1.13) we shall notice again that
6(h) = 0, because h # 0. Separating the variables we deduce the following integral equations
8r 0 1 Cr
r
x0 _
Vd t)
rah
= 27rh'(x)
x-kr a x0 ar} Jo xo - k ref (t)dtIrah = -27rah(x) .
(11.3.4)
(11.3.5)
In order to put into evidence the principal part of the integrals for r = h = O(e), we must notice that we cannot derive directly the integrals, because the integrands become infinite for { = r - kr. For avoiding this situation, we shall perform the change of variable 4 -- u:
x - a=krcoshu.
(11.3.6)
One obtains a of=-kr
a'
8
fr (S)
xo - k r
d = 8r
x r
x -k r
x
f:(0)
fx(0)
x- k r
,
-kJ
f. (x
UCh fi(x - kr cosh u)cosh u d u
o
_
_r
1
r f'(0) [1 + O(ff)]
- krcashu)du =
rx-kr 1 0
-r
0
xo
' xo - k r f (t)d -kr
f=(t) [1 + o(e2)] d. (11.3.7)
Neglecting O(e) with respect to 1, we deduce that the principal part of the integral from (11.3.4) is - f=(x)/r. Hence, from (11.3.4) we deduce
ff(x) = -2whh' = -S(x),
(11.3.8)
S(x) giving the area of the cross section of the body in the point x.
TILE THIN BODY IN A SUPERSONIC STREAM
461
Similarly we obtain
0
r-Ar
xO
Or Jo
t-tr
1
r
X0
r \/x - 1 1
r2
z-kr
0
1f(01d --1
x -
0
+
f(0)
:c2
f(c do :c3 - k2r2
r
ra
u
f'(Od (11.3.9)
Neglecting O(r-2) with respect to 1 we find at first 1
(7
z-kr
xp
.r
f,-Ir
f
f (E)d
-r-kr rx`t
-rI 1
x-kr
f ()d + r
f (0)
fz_kr
f'(e)d
r1-jZkr
Ja
f(4)d4.
The equation (11.3.5) becomes S kr
kr f (x - kr) + 0
f
-2-xnrh.
(11.3.10)
where we put r = h. In the left hand part of the equality, we expand into series for obtaining the principal part. We have r kr f (:x) + 0(r2) + kr f (x) + 0(r2) = -2 rorh . f 0
Hence,
s
J
f
--2riS(x)
whence
f (x) = -2aS'(x),
(11.3.11)
the analogy with the subsonic case being obvious.
11.3.2
The Pressure on the Body. The Lift and Moment Coefficients
In order to put into evidence the principal part and the expression of the pressure, we notice that utilizing the change of variable (11.3.6), we
TILE THEORY OF SLENDER BODIES,
462
deduce x-kr
8
o -krx
f=(t)
Ox
x -k r r-kr
+f=(x)
xo-k r
o
f=(a)
o-k r
0
x +f:(x)arccosh kr
__
rs
-
x
x - f., t
to
2s
= fs(x)ln kr
xo -kr
Jo
f'(C) - fr(x)d4+
df
f
ff(t)d t
r=-kr
-k r
+
f=(0)
+
f1(0)
d t=
-J
+
Jo
r f.'W - f.'W d t +
x-
d t+fx(x) In
x + x- k r e kr
fi(x) - fY(0dt.
x-t
Taking into account the calculation performed at (11.3.7), we deduce
p(x, h, 0) = pi (x, h) - a sin 0 S'(x),
(11.3.12)
where
pi (x, h) = -
S"(x) 21r
kh _
2x
1
S"(x) - S"(4)
27r fo
X-
d
(11.3.13)
The lift, drag and moment coefficients may be calculated with the formulas (11.2.23) - (11.2.25). We have therefore, like in the subsonic case,
CL =a [S(1) - S(0)1 = 0(e3)
CD =Ji p,(x,h)S'(x)dx=0(e4) 4
(11.3.14)
Gr=az=0, cy = - Cr f ' 0
Ix +
2(x) J
S'(x)d x = O(s3) .
THE, THIN BODY IN A SUPERSONIC S1'IREAAI
11.3.3
463
The wing at zero angle of attack
For a = 0, we deduce f = 0 whence P('r., r) =
9(r,
r)
t'r(x, 7.)
a
1
S'()
/'x-rrr
2;, Tx Jo
zo ` J. r d
=-kr S
-o
xo - kr'
1 of r-kr
2
j
S (e)d o
d
S'(S)dS
.4-k r'
x-kr
1
2rr J0
Sit ( )d k2r2 (11.3.15)
This is the solution between the wave from the louring edge and the wave from the trailing edge i.e. in the region denoted by II, where a > kr (fig. 11.3.1). In I (:c < kr) p = yr = 0, and in IN the solution is
p(x, r) _
1
oz-kr
2r,
2irr
(11.3.16)
z-kr
1
Vr(x,I-) -- -
S"()d t xo-k-r'2
0
dc. x _ 13-1
1A w 1
Fig. 11.:3.1.
This explicit manner of representing the solution is also valid in the general case.
11.3.4
Applications
At first we shall consider the thin body having the shape of a cone (fig.
11.3.2) of equation r = ex, 0 < t < 1. We deduce S = 1re2x2
THE THEORY OF SLENDER BODIES
464
whence 2 CL = JrE at cy = -
21u E2 3
ti
,
CD = -7rE' ln(k/2).
(11.3.17)
Fig. 11.3.3.
Fig. 11.3.2.
For cy and CD we have retained only the principal part. If the angle of attack is zero, then in II we have
d _d C = 62 arccosh j _
z kr
p(x, r) = E2
E2 In
yr (x, r) = -
xo - k"jr
Jo
x+ x2-k r x-kr
EZ
r
(11.3.18)
kr
o
x0
xkr-d t _ -8
2
:r - k r r
We notice that on the radius vectors r = cx, c < 1/k, the pressure and the velocity are constants. The flow is conical.
The second example
the double cone from figure
is
11.3.3
Since Ex,
h(x) =
0 < x < 1/2
(11.3.19)
r(1-x), 1/2<x<1,
it results that S' has a discontinuity in the point x = 1/2. We suggest to the reader to establish the formulas of derivation for fW dta rx-kr
xo-k r and to write the solution.
' arJ10
xo -k'r
d
(11.3.20)
Appendix A
Fourier Transform and Notions of the Theory of Distributions
A.1
The Fourier Transform of Functions
The following definitions will be given in R3. Their expressions in R1, R2 or RI will be easily deduced. The Fourier transform of a function f : R3 --+ R is denoted .F[f], or f and it is defined by the formula (A.1.1)
F[f](a) = f(a) = j3 where
x = (x, y, z),
a = (al, a2, 03) (A.1.2)
a.x=alx+a2y+a3z,
dx =dxdydz. The operation F is called the Fourier transform. We notice that i f (x) is absolutely integrable on R3, he. if
3 (f )d x < oo,
(A.1.3)
then the Fourier transform exists. Moreover, if f satisfies certain conditions of regularity, for example, if f E C0(R3), or if f is piecewise smooth with respect to every variable [A.10], then f may be obtained from f using the following inversion formula
(2;r)3 f (x) _ (2-,,)3-F-1 [j(x) f
a= (A.1.4)
_ F[fl(-x) _ [f (-a)J(x) , where ci a = d a1 d 02 d a3. The last two expressions show that the inverse of a Fourier transform may be obtained by a direct transformation.
466
FOURIER TRANSFORM. THEORY OF DISTRIBUTIONS
One proves (Lebesque's theorem [A.9], (A.51) that j tends to zero when ICkI -+ .x}.
The condition (A.1.3) is restrictive enough. For example, the function f = 1 does not verify this condition. The theory of distributions allows to enlarge the class of the functions which admit a Fourier transform.
Notions of the Theory of Distributions A.2 The Spaces D and S The theory of distributions relies on the notion of space of the test functions. The space V = D(R3) consists of the set of functions W(x) infinitely derivable, with compact support in R3. We say that a sequence of functions {V,} from D, converges to a function S' E D, if for every multi-index k = (k1, k2, k3), k1, k2, k3 being non-negative integers, we have: DkW11 rya Dkcp,
(A.2.1)
where, with the notation IkI = k1 + k2 + k3, we have put Dk
-0jkj
= --,-
k,
(A.2.2)
The set D endowed with this convergence law is a linear space-
Ale may we that the Fourier transform of a function from D is not a function from D. Indeed, the Fourier transform is an analytical function [A.12), but the support of an analytical function which cannot be compact. There exists another space which is invariant to the Fourier transform and plays a basic role in the definition of the Fourier transform
of a distribution. This is the space S = S(R3), i.e. the space of the rapidly decreasing test functions. We call rapidly decreasing function an infinitely derivable function V(z) in R3 which, together with its derivatives decreases when Ixl - oo faster then every power of Exl`t. This means that (A.2.3) IxkD'v(x)i < CL-j,
for every nmlti-indices k and 1. We denoted xk = xklyk'2zka. The convergence in S is defined in the following manner: the sequence of
467
DISTRIBUTIONS
functions {V } from S converges to the function cp E S if for every multi-indices k and 1 , we have: X,
xkD'pn(X)
xkDrv(x).
(A.2.4)
The set of the rapidly decreasing functions, endowed with this convergence law. is a linear space. The convergence in D implies the conver-
gence in S. We have D C S. but S does not coincide with D; For example. the function exp. (-x2) E S, but
A.3
D.
Distributions
The distributions are linear and continuous functionals on D or on
S. This means that a distribution f detennines the correspondence between a test function V and a number denoted by (f, q) and we have:
(A.3.1) (f,Anpi +A 2) = an (f,Sit) +A2(f,p2) , for every two real or complex numbers an, A2 and that if P>s I V in D (or S), then
(f, °Pn) - (f, (P)
.
(A.3.2)
One denotes by D' the set of the distributions defined on D and by S' the set of the distributions defined on S. S' is the space of the temperate distributions. Obviously, S' C D'.
We say that the distribution f is equal to zero in the domain f2 (it is denoted by f = 0) if (f, gyp) = 0 for every p from D (or S) with the support in 11. The distributions fn and f2 are equal in n if fl - f2 = 0 in 11. i.e. if (f1, 0 = (f2. (P)
,
(A.3.3)
for every v E D.
We call the support of the distribution f and we denote it by supp f the set of the points which have a vicinity where j is not equal to zero. Every locally integrable function f (x) defines a distribution by means of the functional
U. P) = j f (x)4%(x)d x .
(A.3.4)
A distribution f is it regular function-type distribution if it may have the form (A.3.4). Every other distribution is singular. The best known
468
FOURIER TRANSFORM. THEORY OF DISTRIBUTIONS
example of singular distribution is the distribution of Dirac. The distribution of Dirac with the support in 4 is denoted by bo(x) or b(x and is defined by the functional (b(x -
V, (x)) = rW .
(A.3.5)
Formally, it may be written as follows
J
v(x)6(x - 01 x = pW .
(A.3.6)
If rn(x) is an infuiitely derivable function, then mv is infinitely the distribution f and the function m., denoted by tnf, by means of the formula
derivable and we may define the product
rnv)
(inf, 4,)
(A.3.7)
It results
m(x)b(x - ) =
(A-3.8)
whence,
ni(x)b(x) = 0,
if rn(0) = 0.
(A.3.9)
For the existence (A.3.8) the continuity of the function is sufficient in in t;.
We shall consider the three-factor c and the homothety cx = c3z). If h(x) is a locally integrable function, then h(cz) is also locally integrable, such that the distribution corresponding to h(ex) is defined by the functional
_ (cix.
(h((x), 4"(x))
=f
h.(cx)p(x)d x
Setting cm = and observing that the integration limits interchange when c; is negative, we deduce, with notation lei = (clc-2cy) IcC (h(cz), 5'(x)) - j
h(E),p(k/c)d
_ (h(x). 4p(x/c))
For o distribution f (x), one defines the distribution f (cx) by means of the formula ICI (f (cx) s'(x)) = (f (x), cp(xl (:))
.
(A.3.10)
The definition may be extended to a non-singular linear transformation. As a particular case, it results: Ic16(cI x. C 2Y, car) = b(x ah z) .
(A.3.11)
469
DISTRIBUTIONS
f
The derivative of the distribution determined by the formula
is denoted by
f'
and is (A.3.12)
(f', V) _ - (f, ) . Defining the function of Heaviside H(x) by the formula
x<0 H{r.) = 10, 1,
(A.3.13)
x > 0,
it results 00
(x)dx=5P(0)
i
0
Taking into account (A.3.5) we deduce
H'(x) = 6(x).
(A.3.14)
Let us establish now the formula
(m(x)H(x)' = m(0)6(x) + in'(x)H(x) for a function E C'(R). We have ((mH)'. y,) =
= m(0M0) + f
- (mH. vp')
x
(A.3.15)
r
x=
m'(x)cp(x)d x = (m(0)6(x) + m'(r)H(x), v')
.
0
On the basis of (A.3.8) and (A.3.15) we deduce that the solution of the differential equation
Lu = 6(x),
(A.3.16)
where Lu = u("')(x) + O, (X)u('"-I)(x) + ... + am(x)u(x). is
u(x) = H(x)v(x),
(A.3.17)
where v verifies the equation Lv = 0 and the conditions v(O) = v'(0) ...
= v,(m-2)(0) =
1
0,
We call the direct product of the distributions f(x) E D'(R") and g(y) E D'(Rm) the distribution f (x) g(y) E D'(R"+') defined by the functional
(f (x) g(y), r'(x, y)) = (f (x), (g(y), W(x, y)))
,
(A.3.18)
470
FOURIER TRANSFORM. THEORY OF DISTRIBUTIONS
where V E D(R"+'"). The definition is valid also and when D' is replaced by S. The direct product is commutative, i.e. f (x) g(y) _ = g(y) f (x). As an application, we shall prove that in R2, we have (A.3.19)
b(x) = a(x) - a(y) Indeed, applying the definition, we have: (OX), AX, y)) = 4'(0, 0)
.
But we have also, (a(x) a(y), Ox, y)) = (a(x), (a(y), (x, y))) _
= (6(x),;?(x,0)) = V(0,0)
A.4 The Convolution. Fundamental Solutions For two functions mi(x) and m2(x) absolutely integrable in R3, we define the convolution m(x) = (ini * in2)(z) by the formula (ml * MAX) =
=1
3
J pa
"11)mx - t)d : =
m( m2(x - t)dt = (in2 * ni)(x)
The function m(x) is absolutely integrable, such that it generates a function-type distribution (A.3.4). Writing explicitly that functional, we are determined (A.51 to define the convolution 0= fi * f2, of two
distributions fi and f2 by means of the formula
(fi * f2, ') = (fi (x) f2(O, V(x + f)) ,
(A.4.1)
fi(x) f2(4) representing the direct product of the distributions fi and f2. The convolution (A.4.1) exists if, for example, one of the distributions have a compact support (A.5j. The equality f j *f2 = f2 *fi results from the commutativity of the direct product. As an application, we shall calculate b * f. We have
(6 * f, P) = (6(x) . f W,'?(x + 0) = (f (0, (6(x),'P(x + i)))
_(fW"PW)
THE CONVOLUTION. FUNDAMENTAL SOLUTIONS
Hence,
a*f=f*6=f.
471
(A.4.2)
We shall establish now the formula
D(fi*f2)=Df,*f2=fi*Df2,
(A.4.3)
the operator D being defined in (A.2.2). We have (D(f1 * f2), Sp) = (-1)Ikl (fh * ff, DW) _
= (_ 1)lkl (fi (x) - ME), Dpp(z E)) _ (-1)Ikl (f2(E), (fi(x), Dip(x + i))) _ _ (f2(E), (Dfh(x), D& + F))) = (Dfi * f2, sp) , and the result proves the first equality from (A.4.3). The second equality results from the commutativity of the convolution. We shall consider now the linear differential operator of order m, M
L = E a*Dk , Ikl-O
where ak are constant. We call fundamental solution of this operator, the distribution t E D' which verify the equation
LE = 6(c).
(A.4.4)
Obviously, the fundamental solution is defined with the approximation
of an arbitrary solution of the homogeneous equation. We have the following theor_mr. If f e D' and there exists in ?Y the convolution f s E, then the solution of the equation
Lu = f
(A.4.5)
exists in D', is given by the formula u = f *.C
(A.4.6)
and it is unique in the set of distributions from D', for which there exists the convolution (A.4.6). Indeed, utilizing (A.4.2) and (A.4.3), we deduce
Lu=L(f*E)
a1Dk(f*E)=f*LE= f$6= f. lkI-O
472
FOURIER TRANSFORM. THEORY OF DISTRIBUTIONS
In order to demonstrate the uniqueness, we denote by u another so. lution. Obviously, no = u - u satisfies the homogeneous equation Luo = 0, such that we have:
uo=uo*6=uo*Le=L(uo*e)=(Luo)*e=0.
A.5 The Fourier Transform of the Functions from S Since the functions from S are absolutely integrable, they have Fourier transforms F[ pj defined by (A.1.1) and these are bounded continuous functions on R3. Integrating by parts and taking into account (A.2.3), we deduce:
-F(VACt) = (-ial)FIVJ(a).
(A.5.1)
On the basis of the same condition, we may derive inside the integral, such that it results
(O/Oai).('PJ(a) = .F(ixtipj(a).
(A.5.2)
By recurrence, it results:
.F(Dk(pJ(a) = (-(a)k.F(V](a),
f((ix)'4 j(a),
(A.5.3) (A.5.4)
for every multi - indices k and L. The last relation show that F(VI is infinitely derivable.
We shall prove in the following F(cpJ E S. To this aim we replace cp with (ix)rcp tin (A.5.3) and taking into account (A.5.4), we deduce
F(Dk((ix)`p)J(a) = (-ia)k.F[(zx)l ,](a) = = (-i)IkjakDI,F[Wj(a) whence
]akD'F('j(a)I <_ fx$ IDk(xt4o)IdZ < 00, i.e. Y[w] satisfies (A.2.3).
Taking into account that the Fourier transform F(spj is integrable and continuously differentiable, we deduce that cp may be obtained from cp sing a formula like (A.1.4).
THE FOURICR TRANSFORM OF THE TEMPERATE DISTRIBUTIONS
473
A.6 The Fourier Transform of the Temperate Distributions The Fourier transform of the distribution and it is defined by formula
f = .F[ f l
f E S' is denoted by
(f, 0) = (f. y i) , for every V E S. Since
(A.6.1)
E S. it results [A.121 that the Fourier
transform of a temperate distribution is also it temperate distribution.
For f E S' we define the inverse Fourier transform F--I, by the formula(27r)'-F-' [f (x)1 = -F[f (-x)] .
(A.6.2)
We shall prove that
f
j:-- I [.[fl]
(A.6.3)
.
Indeed, taking (A.3.10) into account, we deduce for c = -1 (27r)3 (,F-1[.[f]h
(.F[.F[f](--c )l,
F-'
(-a)) = (2r)3 (27r)3
(f,.Fp,-' [.,III)
_ (f )
Similarly we prove the second equality. We shall establish now the operations (A.5.3) and (A.5.4) for temperate distributions. We have:
(F[f=], } = (f=, ) _ - (f, a,.F[pl) =
[iaip]) _ (F[f].-iniy,) _ and we deduce, whence
(_iaiJ,)
.F[f] =-iaif,
(A.6.4)
T[grad f) = -i a f , F[div f ] = -i a f (A.6.5)
.F[rotfl=-iax f. From (A.6.4) we obtain by recurrence a similar formula to (A.5.3). Analogously, we have:
(
0 _771fl, V(a)
Ylfb
f..F
an.,
474
FOURIER TRANSFORM. THEORY OF DISTRIBUTIONS
(f, i x.F[d) = (i xf, Y[w)) = (f [i xf ], io) hence, (A.6.6) .F[i:rf) and, by recurrence, a similar formula to (A.5.4). From the definition (A.6.2), it results that relations similar to (A.5.3) and (A.5.4) are available for the inverse transformation too. Hence,
f-1
(i x)" f (x)
ia)!f](x) = D'f(x).
(A.6.7)
(A.6.8)
We shall frequently utilize relations of the form
.F-t[--t«tf1 = f:, F-t[cto2f) _ -f=y.
(A.6.9)
We shall prove in the following the formula (A.6.10) 17-t(f(ca))(x) = ICIf 1 cl c representing a three-factor. Performing the change of variable a =
= cf3, we have for a function
lip\alJ (x)=,l
(
cxd A = lclw(cx).
lei
For a distribution f we shall utilize the formula (A.3.10). We have lei (F-t [f(Ca)1 P) (f(a),F-tso(a/c))
lei (f(ca), -F- 1,P)
_
(f(x), 0(cx)) = (f (x/c), w) whence (A.6.10).
For the direct product f (x - g(y)) we have: (A.6.11) F[f(x) - 9(y)] = Y[f)(a) - F[9)(0) , and for the convolution, if one of the distributions has a compact sup-
port, we deduce .Fff * 9) _ F[f).F[9] .
From (A.6.11) it results f-I
[f (a) 4(/3)) = f (x) . g(y) .
(A.6.12)
(A.6.13)
THE CALCULUS OF SOME INVERSE FOURIER TRANSFORMS
475
A.7 The Calculus of Some Inverse Fburier TSransforms We shall calculate at first the Fourier transform of the distribution of Dirac. For cp E S we have
(716(x - 4)], Sp) _ (a(z - ), r) ='P(A) (A.7.1)
(el a-4, SP)
,
Hence
.F[a(x - a; )] = exp (i a ), b(a: - F) _ '-t [exp {i a }j , whence, for
(A.7.2)
= 0,
7A =1,
_ 1 [1] _
(A.7.3)
It results therefore
F[1](a) = (2a)3d(a) .
(A.7.4)
Hence the temperate distribution I has a Fourier transform. Denoting by F2 the Fourier transform in R2 and by f'1 the transformation in R1, we have on the basis of the formula (A.6.13): .Fz 1 [1/i a] _ .F_ [l/i a1](x) '
t [1]{3l)
(A.7.5)
Applying the Fourier transform to the equation
du/dx = b(x),
(A.7.6)
we deduce -i o1i = 1 whence:
U = -X1[1/ialj(x).
(A.7.7)
The equation (A.7.6) has the form (A.3.16) and its solution has the form (A.3.17). It results s=X(x). (A.7.8) From (A.7.2) - (A.7.8) we deduce
T1 [1/i all = -H(x)6(y).
(A.7.9)
For the determination of the fundamental solution of the equation of Laplace we need the following results (demonstrated, for example, in [A.12], §97, [A. 131, §6.6, or [A.71, §5.3). I
= 4x [ ['
n = 3,
(A.7.10)
476
FOURIER TRANSFORM. THEORY OF DISTRIBUTIONS
YV [i'i'_}
n=2,
2 (ln lxl + C),
(A.7.11)
C being a constant determined in [A.13], but without any importance here. Taking into account (A.6.10) with c = (,3,1,1.) we deduce, on the basis of the formulas (A.7.10) and (A.7.11): 1
Jrz 1
_
1
#2aI+a2+a3 - -]
I FP fl202 t
1
+
4n
(A.7.12)
(J +z )
= - 2n (ln x'- + 02y= + C - In (i) ,
2] 2J
i
1
(A.7.13)
,6
FP representing the symbol for the Finite Part (Appendix E), and p, a positive constant. Also, for determining the fundamental solution of the wave equation we need the formulas
f-1 sinalalt
6(at - Iii), 4,rat
lal
T-I sin aloe lt1 H(at - l xI ) I
Ial
1
21r
a t- -- Ixl
n = 2,
(A.7.15)
demonstrated, for example (A.7.14) in [A.5] Chapter 2, §3.4, and (A.7.15) in (A.12) §9.7. We shall prove in the sequel the following formulas 1
_ 1 H(x - k f2 + z2)
1
[-k2a"i + a2 + a3 J F2 1
-k2
2a
x-k
(y
+ a2, = 2k H(x
+ s)
kl>!i).
,
(A.7.16)
(A.7.17)
In order to prove (A.7.16), one considers the following partial differential equation: k2u." - uyy - u=, = 6(x) . (A.7.18)
Applying the Fourier transform, we deduce (-k2a? + az + a3)i = 1, whence, u
[_ k2al2 +a2+a321 1
.
(A.7.19)
It results therefore that the first member from (A.7.16) is just the solution of the equation (A.7.18). We shall determine in a different manner this solution, namely applying the Fourier transform only with
THE CALCULUS OF SOME INVERSE FOURIER TRANSFORMS
477
From (A.7.18) one obtains the
respect to the variables y and equation
(k2d2/dx2 + w2)ta = d(x) ,
(A.7.20)
where w = + , and u represents the two-dimensional transformation. The equation (A.7.20) is like (A.3.16), and its solution has the form (A.3.17). We deduce
u.-
H(x.) sin(wx/k) k
w
Utilizing (A.7.15) one obtains (A.7.16). Acting similarly, in the two-dimensional case, we find:
u= ii
H(x) sin(a2x/k) k
(Y2
t
being the notation for the Fourier transform with respect to the
variable y. Utilizing the formula F1 sinXax11 7r
(A.7.21)
I(Inl>aa ,
0 given for example in (A.1], p.202, we obtain (A.7.17).
In the unsteady aerodynamics we shall meet the following type of formulas
co alc tl
Mat
ct2
47r Ix
1 - cosalaltl U2
- Iml),
(A.7.22)
a t - Ix+
Ix()
2r
= 3,
(at +
(A.7.23)
IxI
n=2. We shall prove these formulas (following an idea suggested by V.Iftiinie) using the results concerning the Cauchy problem for the non-homogeneous wave equation. To this aiin we shall denote:
v(t, a) =
l - cosalalt Ck2
We deduce u.(0, a) = 0,
u((0, a) = 0 ,
irtc(t, a) = a' arsa.lalt = -(i2a2ii(t. a) + (L2.
478
FOURIER TRANSFORM. T'IIEORY OF DISTRIBUTIONS
Applying the operator F-', we deduce: 11(0, x) = 0,
ut(0. x) = 0
utt = a2Aat + u26(x)
.
For determining u we have therefore to solve a Cauchy problem for the non-homogeneous wave equation. The solution of this problem in the three- and hi-dimensional cases is given by Poisson's formula [A.12]. Utilizing this formula, we find (A.7.22) and (A.7.23). At last, replacing x by x. - t in the formulas (A.7.9), (A.7.14), (A.7.15), (A.7.22) and (A.7.23), we obtain in the three-dimensional Case,
with the notation R = F-I
(c - t) + y' + = 5(x - t) - a(t,.z)
Ceinit. I
sin aIctIt einat
f-I
_
I a5(at. - R), )' = TI-rat
(a1
n247rR
1 - c)sajait
iaIt - II(at
(A.7.24)
R)
and in the two-dimensional case, with the notation I#
F-a ei,«t] f_1 Il
I
b(x - t) - (5(71), I
ial
JI
27
(1 - cosa'aHt dolt I
rte
_
H(at - R)
a' '' --V H(at -- 7) 2-r
In
at +
n."2t2 - f2
R
(A.7.25)
In [1.101 we may find direct. demonstrations of the formulas (A.7.25).
A.8
The Fourier Transform in Bounded Domains
In this last part, we return to the Fourier transform of the functions and we give, following Homentcovschi's idea [A.61, the transformation formulas in case that the function f (x) is defined on a bounded domain D. We assume that D is bounded by a surface S which closes a domain D' and by a surface of discontinuity E . We prolong f in DY, giving
479
THE FOURIER TRANSFORM IN BOUNDED DOMAINS
it the value zero. We make the same thing in the domain D° which closes E. Applying the flux-divergence formula we obtain:
fxID=fx6:' =fTIR3
rrfn - JS
fie'
f,,n
fnleia'xda- J'; Of llnleiaxda.
(A.8.1)
F(grad f[D = -ic"f - 1 fne'o
F[div fJD = -ice f F[rot f]D = -ia x
where (A =f+ -f-.
J
xda- r
f nei°t'xda - J QfIne'a-xda
f f x ne`a'xda- J s
DfOne`a'xda,
E
(A.8.2)
Appendix B
Cauchy-type Integrals. Dirichlet's Problem for the Half-Plane. The Calculus of Some Integrals
B.1
Cauchy-type Integrals
We consider in the z = x + i y complex plane a smooth curve r, i.e. a curve which has the parametric equations
x = x(8), y = y(s), sl
a
82,
(8.1.1)
where x(s) and y(a) are continuously differentiable functions, whose derivatives do not vanish simultaneously in the same point. The curve
r may be closed or open; if it is dosed, then z(81) = z(82); if it is open, then we assume z'(sl) = z'(sl + 0) and z'(s2) = z'(32 - 0). By definition the positive sense on r is the sense corresponding to the increase of the parameter s. The smooth curve is obviously rectifiable, such that we may consider as parameter 8 the length of the arc measured from sl (= 0) to 82(= 1). In this case, we obviously have zi2 + y'2 = 1. Let f(t) be a complex function depending on the complex variable 1, defined on r and Riemann integrable. The integral
F(z) = 2Ai
J
t (t) d t
(B.1.2)
is called Cauchy-type integral. As we lmow from the books of complex analysis, the function F(z) is holomorphic in the interior of the contour
r. if r is at a finite distance, then F(z) behaves at infinity like 1z4'1. We shall investigate, in the following, what happens with the integral (B.1.2) if z = to E r. In this case, the integrand has obviously a nonintegrable singularity in to and generally the integral has no sense. There exists however a large class of functions (we are not interested here in the largest class) for which we may give a definition to the integral,
482
CAUCIIY-TYPE INTECRALS
namely the class of the functions which satisfy the so called Holder's condition.
We say that the function f (t) satisfies Holder's condition on r if there exist two positive constants (different from zero) A and µ(µ < 1), such that, for every two points tl and t2 E r sa we have (B.1.3)
If (ti) - f(t )I < Ajtl - t2VY.
Obviously, the functions f which satisfy Holder's condition are continuous on r. If u = 1, the functions satisfy Lipschitz's condition.
B.2 The Principal Value in Cauchy's Sense We shall give now the definition that we have mentioned before. We assume at first that to does not coincide with any extremity of the arc r (if it is open). We consider the are of circle with the center in to
and the radius s which cuts the curve F in two points tl and t2 and (t) d t we denote by - the are t1t2. If for a -+ 0 the integral Jr-y tf to has a finite limit, then this limit will be called the principal value in Cauchy's sense. We denote
f(t) Iifot--f(t) dt - frto t - d t. Y
to
(B.2.
t.
The principal value is it distribution (A.12], [A.14]. We shall prove in the sequel the following theorem: "If f (t) satisfies Holder's condition in the vicinity of the point to, then the limit (B.2.1) exists and it is unique. For the proof we shall write:
f
f(t) dt=
tto
fr_1,
f(t)-f(to)(I t+f(tu) f t - to
r1F t dt - to
(B.2.2)
Having (B.1.3) in view, the limit of the first integral from the right hand member exists and it equals the usual improper integral on r. The last integral is calculated as follows:
f
tt
-7 t
o
= 111(t - t)la` + ln(l. - to)It = In u
- to+
+ ln(tl - to) - 111(t2 - to) .
Diu tl - to = Iti - tolein, t2 - to = It2 - tole'' and Itl - toI = It2 - tot.
483
PLEMELJ'S FORMULAS
It results In(tt - to) - ln(t.2 - to) = i (a - 0). Passing to limit, when
E-0, ct - W=ir,weget dt
Inn
_
dt
e- 0
= In
b - to
a-t0
+ i a = In
b- to to - a
(B.2.3)
Since the last integral from (B.2.2) has a well determined limit, the theorem is demonstrated. The case when to coincides with one of the extremities of the are F. depends on the behaviour of the function f in that point (,See for extunple [A.27], §29--32). If t9 coincides with an extremity and f (to) = 0, we are in the previously considered case., because we may
extend arbitrarily the contour t beyond to, setting f = 0 on the extension.
B.3
Plemelj's Formulas
We shall investigate the behaviour of the Cauchy-type integral in the vicinity of the curve F. To this aim we shall give at first the following definition [A.271: we say that F(z) is continuously prolongable on r in to (different from the extremities) at left (right), if F(z) tends to
a well determined limit F+(to)(F_(to)) when z - to on every path situated at left (right). With this definition we may give the following fundamental theorem : verifies or, t Holder's condition. then F(z) is continuously
If f (t)
prulongable on rat left and at right, excepting the extremities where f (to) 76 0 and Fi. (to) =
t2f(to) + 2ri I tf (t ndt.
(13.3. 1)
formulas. They have been The formulas (B.3.1) are called given in 1908 [A.29]. Their demonstration may be found for example in [A.18], [A.271.
B.4
The Dirichlet's Problem for the Half-Plane
tine shall solve in the. sequel the following problem: We seek for the function (B.4.1) F(z) = u(x y) + i v(x. y).
484
CAI;CIIY-TYPE, INTEGRALS
holornorphic in the half-plane y > 0 and continuously prolongablct on the Ox, axis. which reduces at infinity, to an imaginary constant i C (C may have the value zero) and whasc ir_al part is imposed on the above mentioned axis, i.e.
u(x,O) = f(x),
(13.4.2)
where f is a function with a compact support compact which satisfies Holders condition. At first we have to mention that there exists a single function with the above mentioned properties. Indeed, assuming that there exists two
functions F1 and r2 with these properties. their difference F = = F1 - F2 is holotnorphic in the superior half -plane and it vanishes at infinity. The real part of the function F is therefore harmonic in the half-plane y > 0. zero on the boundary y = O and zero at infinity. According to the maximum principle for the harmonic functions, the real part of the function is identical zero. F reduces therefore to an imaginary constant which is zero because F is zero at infinity. We shall prove that the function F(z)
7i
f }a
t
(t) d t + i C
(13.4.3)
CO
satisfies the conditions of the problem and it is therefore the solution we are looking for. Indeed. the function F(z) defined by (13.4.3) is holomorphic in the superior half-plane because it is a Cauchy-type integral and it is continuously prolongable on the real axis. At infinity it reduces
to the constant i C because, if we denote by (a, b) the support of
f(x),wehave I-M
t
f (I
f () dt
(t) dt
/-
tl
dt.
The integral is therefore zero at infinity.
Passing to the limit with
z
x a point from the real axis, and
using Plemelj's formulas we obtain: 11(.x..0)+11'(x,0)= f(.1;)+ 11 1
J+x -x ., tf(t)dt+1C.
Taking the real part of this relation we obtain (B.4.2). Hence the problem is solved. The real part of the solution (13.4.3), i.e. UI(X. Y)
y ,or
fa+OC
f(t) (t - T)2 + ry2
dt
(B.4.4)
THE CALCULUS OF CERTAIN INTEGRALS IN THE COMPLEX PLANE. 485
determines the harmonic function in the half-pl.uie y > 0, vanishing at infinity, continuously prolongable on the Or axis and satisfying the condition (13.4.2). This is the solution of Dirichlet's problem for the half-plane concerning the harmonic function u.
B.5
The Calculus of Certain Integrals in the Complex Plane
At first we shall prove that G
1
a tit
t.
a
(B.5.1)
b - tt
where the determination of the radical is the positive one for z = r > b, and (a, b) is an interval on the real axis. Indeed, with the mentioned determination, we have
x
a<:x
rb6
After all.
r
().
Re(i
r-a
b.....
z
a<x
Since the real part of the holomorphic function i 1/: - n is known on G
the real axis, the function will be determined by the formula (13.4.3). We have therefore
Urb-t t.. i
a
-zzz-
b
-t--a dt
-ya'
+C.
Considering z oc it result., C = 1 and then the formula (B.5.1). Analogously we deduce that ' f it 1
b
t
a
at
dt
=
-l + JfT b
(8.5.3)
486
CAUCHY-TYPE INTEGRALS
Passing to the limit and taking into account Plemelj's formulas; (B.5.1) and (B.5.3) we obtain that:
'b fl -a dt
i t- x-
b
:r
1j
V
a t-
t
a
-
b=-t dt
(B-5-4)
-1
We must notice now that the above considered function
i
z-b
Y YYY
reduces to an imaginary constant at infinity (this is i). If we want to apply the same procedure for the function (z - a)(z - b), we must consider the expression
(z-a)(z-b)-z. To this aim we have
x>b, x
n,
Re [i ( (z - a)(z - b) - z)} =
-(x-a)(b-x), a<x
whence
(z - a)(z - b) - z =
+- r
b
(.t
a)(b - t)
d t + C.
The integral becomes zero to the infinite. This imply a+b 2
We have therefore 1
(t - a)(b
7r,"b
t-z
- t) d t = V"(-z-- a) (z - b) - z +
a
+b
(B.5.5)
and, passing to the limit and applying Plemelj's formulas,
rrt x 1
L
(t - a)(b - t)
d t = -x +
a
+
b
z
(B.5.6)
The following example is studied starting from the expression i (z - a)(z - b) '
which vanishes at infinity. Hence, the constant C will be zero. One obtains the integrals rb
V
a
(b - )(t - a)
t tz-
a)(; - b)
(B.5.7)
THE CALCULUS OF CERTAIN INTEGRALS t\ '1'flE COMvLI;Y PLANE 487 6
dt =
1
ir Ja f h - t) (t - a) t -
(B.5.8)
Xt) .
We consider now two intervals (a, b), (c, d) on the real axis. The
method can be extended to an arbitrary number of intervals, or even disjoint arcs from the complex phuie, in the last case the integral being solved in another way in [A.18], p.88. The result is useful in the study of the grids of profiles. Denoting Q(z) = (z - a)(-- - b)(z - c)(z - d),
(B.5.9)
for P(z) and R(z) arbitrary polynomials, we have
P(..)
n<x
- i li'(z)
Q(z)
C<x
The function from square brackets is holomorphic in the half-plane y > 0. Utilizing the formula (B.4.3), we deduce
- R( _ V Q(=)
t
-r J
d tz
PQ(t)I
t
a t4
+C.
-Q(t)I
(B.5.10)
Taking into account. the behaviour of the integrals for z - oc, we deduce that at; infinity we must. have the expansion
P(z) Q(Z)
R(z) C+ a2+....
(B.5.11)
This formula allows to determine R(Z) when P(z) is known. For example, for
P(z) = (z - b)(z - d) it results R = 0 and C = 1. and for P(z) = z(z - b)(z - d)
it results
n+c-b-d 2
CAUCIIY-TYPE INTEGRALS
488
After all, we have the results (b - t))("_t) (1_ (d - t)
°
1
dt
(t - b)(d - ') t) d t
rt
1
(t.
t -z (B.5.12)
-
(z - b)(z - d}
-
(z-a)(z-c) r:
(b - t)(d - t)
1
rr,
_
td t
t-
1
+%r
l
d
1
(t - b)(d - t)
td t
(t-a)(t-c) t -, (B.5.13)
a+c-b-d
(z-b)(z-d)
Passing to the limit for z x E ((L, b), we apply Plemelj's formulas to the first integrals. One obtains:
jd /(t-b)(d-t),t) dt (b-t)(d-t) d t (r- -C.) t-x (t-a)(C-t} t-x}7f
6
1
q
b
tt
JG
(b - t)(d - t) td t
(t - b) (d - t) td t
(tc) t-x
1
(t-a)(c-t) t -
-1
x+
-x- a+c -2 b - d (B.5.14)
and for z - x E (c,d), employing Plemelj's formulas for the integrals on this interval, we obtain from (1.5.12) and (13.5.13):
(t-b)(d-t)
dt _ -1
1' J (t-b)(d-t) (t-a)(t- c) s,f J(t_a)(c-t)t_-x +r,
t _ t-xdt-
1
ti
1
(t-a)(c-t) t-x + r
7r
1
(b-t)(d-t) dt
b
'
`t
(t-a)(t-c) t-x
(b-t)(d-t) tdt
a+c - b - d 2
489
t:LAUERT'S INTEGRAL
B.6
Glaucrt's Integral. Its Generalization and Some Applications
We shall calculate the integral 1
_n
f -do e ne
f
_
27r f r
cos e - 8
os ne
cos 9 - s
do,
(B.6 .1)
where s is a real number. For -1 < s < +1 the integral was calculated by Glauert in [3.19]. The general case is considered in [5.38]. The method consists in passing to the complex variable. Denoting exp (i 0) and noticing that we have
1
+" sin no d8=0, , cos B - s
because the integrand is an even function, it results 1
27r
++
f
x
-J=1_tz2-2sz+1
e ne
oos9-sd
1
9
/'
z"d z
iri
(B.6.2)
z"d z in
where
lsl=1
(z - 0Z - Y)
1
a=s+ s2-1, Q=s -
82-1.
The last integral is calculated with the residue theorem. Since aj3 = 1, It results that the poles of the integrand are situated either one in the interior and the other in the exterior of the circle z = 1, or both of them on the circle.
In the case s < -1, the pole z = a is interior and according to the residue theorem, we have:
I = 2tr1 "
Q'"
1
= (3 +
S - 1)"
MQ
(B.6.3)
and for s > 1, the pole z = j3 is interior and it results
I.
1)"
(B.6.4)
At last, in the case -1 < 3 < 1, using the substitution s = cosa, we have a = exp (i o), 0 = exp (-i a) and from the semi-residue theorem [A.221. p.320 (the poles are situated on the integration path) f (z) d z = ai f (zo),
z - :w
(B.6.5)
490
CAUCIIY-TYPE INTEGRALS
we deduce
In =
an
/i"
sin na
a-,Q
jj-rt
sin a,
Hence, Glauert's formula is
1 r* rr ffff0
Cos no
Sill I
cos 0 - cos a d 0
sin o
n=0,1,2
(B.6.6)
Glauert's formula has many applications in aerodynamics. For example, using the substitutions
t=c+ecosO, x=c+ecoso,
(B.6.7)
2c=a+b, 2r.=b-a,
(B.6.8)
where
one obtains the formulas (8.5.4), (8.5.6), (8.5.8) and other similar ones, like for example
Ft- t Jt/---dt=ir(x+e).
(B.6.9)
b
Using the substitutions
t=c+ecosO, x=r.+es
(8.6.10)
and the formulas (B.6.3) and (13.6.4) we also obtain
l b t-a dt 71'
o
b-t t-x
4b-Xx 1,
l x-a x - b
xb
b-x - 1
1
7rI'.
b
t dt
t-a t-x
I va - x
1
1
n fL a
dt (b--t)(t-a) t - x 1
(a - x)(b - r,) 0.
1
Vf(x etc.
x
491
OTHER INTEGRALS
B.7
Other Integrals
In the boundary elements methods one may encounter the following integrals
cosne+i sin no
1k -1
(B.7.1)
for k = 1, 2. They are also calculated with the residue theorem putting z = ei0. It results
sin8=(z-z) ,oos8(z+z), 21
Ii 12 -
_
z"d z
2
i b + Jc I:(z - zi)(z - z2) ' 4i
(i
z"f 1d z rJi:i_1 (z - zt)2(z - z2)2
where, with the notation r = a - b zi
_
-a+r
b- ic'
z2
_
,
(B.7.2)
, we have.
-a-r b- is
(B.7.3)
Obviously, J--1z21 = 1, such that either a root is in the interior of the
unit circle and the other in the exterior or both of them are on the circle.
We are interested in the case when a2 > b2 + c2 and a > 0. In these conditions, the root z1 is in the interior of the unit circle, such that, utilizing the residue theorem, one obtains:
71= F(r), 12 = G(r),
(B.7.4)
where
F(r) =
27r(-1)" (b+ic\" G(r) = 2w(-1)" a+nr (b+ic)" r3 a+r r r , M IC)
(B.7.5)
Separating the real part from the imaginary one, we obtain a series of
492
CAUCIIY-TYPE INTEGRALS
integrals, like, for example 2a
d0 r A a+bcos0+csin0
I
'"
a+bcos0+csiuO
o
f-
f I
cos 0
r d0
sin 0
cos 20
a+bcos0+csin9
'
=- 2:rr
b
c
d0=-'';r
r a+r'
rr+bcos0+csin0
'T
Jo
2.
d 0 = 2;.
b-'
r
(B.7.6) d0
27ra.
Jo (a+bcos0+csin9)2 - r=s .3T
Jci
(a+bcos0+csin0)2
o
(a+bcos0+csin0)2
'
d0=-rbi
sin 0
2:r
J0
- c2
cos 20
(a+bcos9+csin9)2
c
-; a} 2r r 2+r1 r2 \d0
b2
- c2
(a+r)2.
The case a2 > b2 + c2 and a < 0 is studied in the same manner (in this situation, z2 i3 in the interior of the circle). One obtains
Il = F(-r). 12 = G(-r).
(8.7.7)
If n2 < b' + c2, the two roots are on the unit circle, such that the integrals are calculated by means of the semi-residue theorem. One obtains
21, = F(r) + F(-r), 212 = G(r) + G(-r).
(B.7.8)
At last, if a2 = b2 + c2, the roots coincide and they are situated on the unit circle. The integral will be calculated using the Finite Part (see Appendix D).
If a = -s, b = 1. e = 0 and k = 1, one obtains the re cults from the previous section.
_
Appendix C
Singular Integral Equations
C.1
The Thin Profile Equation
The thin profile equation in a free stream has the form 1
'b
f (t) d t= h(x), 7rt-x
a < x< b,
(C.1.1)
where 1(t) is the unknown, and h(x) is a given function. It is sufficient to assume that f satisfies Holder's condition on the interval (a, b) for deducing the existence of the principal value from (C.1.1). The solution of the equation also depends on the behaviour imposed to the unknown at the extremities of the interval [a, b]. From the expression of
the solution it follows that h also has to satisfy Holder's condition on the interval (a, b). The equation was pointed out by Birnbaum in 1923 [3.5) and solved for the first time by Sohngen in 1939 [A.34]. An ample study devoted to this equation is due to Schroder [A.33]. The solution was found again, with different. methods by many other researchers (Weissinger [3.49], Cheng [A.30], Homentcovschi [A.19], Carabineanu [A.151 etc.). In the sequel we start from the method of C. lacob [A.20]. For solving the equation (C.1.1) we have to determine the function
F(z) = u(x, y) + i v(x, y), z = x+iy,
(C.1.2)
holomorphic in the superior half-plane y > 0, vanishing at infinity and continuously prolongable on the real axis, with the conditions u(x, 0) = 0,
for x E (-oo, a) U (b, oo) (C.1.3)
v(x,0) = -h(x),
for x E (a,b).
In order to ensure the uniqueness of F(z) we have to impose its behaviour
in a and b. The function F may be bounded or not in these points.
494
S1N ULAR IN1 CRAIG l:QU VI`IONS
We w.,sume. for example that F is bounded in b, and it behaves in the
vicinity of a like
F(_)=0
(C.1.4)
where F` is bounded We must notice that if we have determined such a function and if we denote by f (x) the boundary values of a on (a, b), then It results that the function f is just the solution of the equation (C.1.1). Indeed, the function F(:), holomorphic in half-plane y > 0 and vanishing to infinity, whose real part on Ox is
u =0,
for :t E (-nc,a)U(b,x) (C.1.5)
it = f (.r.),
for :r E (a, b),
is given by the formula (8.4.3). i.e.
F(z) =
i
r
I
(t) t -
dt
(C.1.6)
.
Utilizing Pleanelj's formulas %,.-c obtain for ar< :r. < b
it (X, +0) + i v(r. +0) = AX) +
J t, t !
cl
(C.1.7)
t..
Separating the imaginary part and taking (C. 1.3) into account.. Ave obtain (C.1.1) for v We shall solve in the sequel the problem (C.1.2) - (C.1.4). Having (C.1.4) in view, we shall consider the function (8.5.2). With the determination of the radical precised there and with the conditions (C.1.3), we deduc c:
Re
_ tt 1
rE
0..
[r(z) Y-bJ --
T---a
b-x
a) U (b, ;,c)
x E (I a, b)
Hence, we may utilize the formula (13.4.3). It results a
a1tV)
Cit.
tt rri F(`) z-Q`-1 the constant C vanishing because I' must v:uaish for z -- x. We deduce
rz --b
t
(C. 1.8)
495
TIIE THIN PROFILE EQUATION
Applying Plemelj's formulas and separating the real part we obtain
Ax)
1
n
bx-
a a s
_ta b
t
IL (1)
t, - x
d t.
(C.1.9)
This is the solution of the integral equation (C.1.1) which satisfies the boundedness condition in x = b. The solution which is bounded in a and unbounded in b may be
-b
obtained starting from the function We obtain
f(x)=-
'
W
r-a
b
6-x f
7r
.
4 - a
c
v
(C.1.1O)
(txat.
If we wish to obtain an unbounded solution the both end-points, - a)(z - b), we have
using the function
Re [F(z)
e
(z - a)(z - b)j = x E (-oo, a) U (b, oo)
ol
(x-a)(b-x.), xE(a,b)
h(x)
whence
!
f (x)
'b r (x-a)(b-x) Ja
(
1
i (t) d t+ t - a)( b - t ) t-x a
(C.1.11)
C
jr - a)(b - ar) At last, for the solution bounded in the both end-points, we deduce b
(z - a)(z - b) 1.
(t -a)(b -
t)
(C.1.12)
t t,
When z is great enough, this becomes 1
F(")
_
i
(z - a) (z - b)
ri
(1-a)"2 (i_)"jb
/b
Jn
h(t) (t - a)(b - t)
dt
1- t/
_
-
h(t)(1+...)(lt
496
SINGULAR INTEGRAL EQUATIONS
such that imposing the zero value for F at infinity we have
f
h(t) d t = 0. (t - a) (b - t)
(C.1.13)
If this condition is satisfied, the solution of the equation (C.1.1) (bounded at both end-points), is obtained passing to the limit in (C.1.12). Taking into account the determination of the radical, we find
f(x)=-1R (a-a)(b-x)Ja
b
h(t)
(t - a)(b - t)
t dt -r
(0.1.14)
Because of the restriction (C.1.13), this solution cannot be utilized in aerodynamics.
C.2 The Generalized Equation of Thin Profiles This has the form: b
- Ja
(tad t +
f (t)K(t - x)d t = h(x) a < x < b,
(C.2.1)
n
where K is a non-singular kernel. We assume that f (x), K(x) and h(x) satisfy Holder's condition on (a,b). This type of equations are encountered in the theory of thin profiles in ground effects, in the theory of grids of thin profiles, in the theory of grids of thin wings etc. From the mathematical point of view, the equations (C.1.5) are extensively studied in (A.27). In order to ensure the uniqueness of the solution we have to impose the behaviour of the unknown f at the extremities of the intagration interval. The method of investigation consists In their regularization, i.e. they are reduced to Fredholm-type equations for which existence and uniqueness theorems are available. For the equation (C.2.1) this may be performed utilizing the solution (C.1.1). If we are interested by the solution of the equation (C.2.1) which vanishes in the trailing edge b, we shall utilize (C.1.9). Assuming that the last two terms in (C.2.1) are known and knowing that a singular integral interchanges with a non-singular integral (A.27), we obtain the following Frcdholm-type integral equation
f(x) +
! f f (C)M(t, r)dt = H(x), a < x < b,
(C.2.2)
497
THE GENERALIZED EQUATION OF THIN PROFILES
where
b =x f
z) _ -1
t wa k(t - L)dt'
aQ
x
b
-1 bz [
t-a
_x- s,
W
t- x
t
(C.2.3)
h(t)
-C--t t - x
dt.
Sometimes we may specify the kernel M . For example, in the case of the thin profile in ground effects, we have:
k{t -) =
(t
-)l
+
(C.2.4)
mz .
The integrals
t
1_
a
t-t
dt
) (C.2.5)
b-t (t-t)2+m2 t-z
a
may be calculated with the residue theorem [A.20], or considering the integral
_ =
f
b-a m dt b-t (t-4)2+m t-x
8
and noticing that if we denote S = t + i m, we have: 6
t
dt
a
Fa
dt
V=t
t (t-()
l
-
(dt
f n VLb_at
Utilizing (B.5.1) and (B.5.4) it results
1+iJ=z*C
C-b
)b (C.2.6)
t-z
(C.2.7)
whence
1- a J
2
1
S-a+
1
z-C-b x-S x1 C
C-
-a -b c -b
(C.2.9)
498
SINGULAR INTEGRAL EQUATIONS
and con."juently,
b= x
1
1ll(f r) =
- a+
1
1
C/z:).
C.3 The Third Equation We shall consider the equation [A.1G]:
-
b
1
J
f (t)(In it - xj + ro)d t = g(x) ,
(C.3.1)
defined on the interval (a, b), where f is the unknown and r o is a constant. We intend to determine the general solution and to investi. gate the conditions which are necessary for the solution to satisfv the restrictions
f(a) = f(b) = 0.
(C.3.2)
With the change of variables t, x -. 0, a defined by the relations t = c + e cos 9, x = c + e cosa , where
c=
a+b
-2'
e= b-a 2
,
(C.3.3)
(C.3.4)
the equation (C.3.1) becomes 1
-
f
F(9)(lnelcos0-cosaI +1'o)csinOd0=G(o)7T
With the notation
(t - a)(b - t) f (t),
(C.3.5)
'fF'(0)(lncjcm0-cosOl+l'o)d0=G(a),
(C.3.6)
F'(0) = eF(O) sin 9 = this may be written as follows 1
where we have
1 coe m9 cos crier .
In 2l cos O - cos al = -2 m>1
(C.3.7)
499
THE TN1R1) EQUATION
The function F''(6) may be prolonged on the interval (-ir,O) such that the result is an even function on (-pr, +7r) and it may be therefore expanded into a trigonometric series, with the aid of the even functions F' (9) = ao +
an cos no,
(C.3.8)
F` (9) cos nod 0,
(C.3.9)
n>1
where an =
ao
r
ao =
I f,P(O)dOi f F(9)e sin 9d 9= 1Jaf f (t)d t. 7r
o
Analogously, the function G(a) may be expanded into the series
G(a) = bo + E bn aog no,
(C.3.10)
n>1
where
b,, = -
rx G(o) coo nod a = - 21 " G,(0,) I sin nad Q , 0
9(x) dx.. (C.3.11) 4 1o (x a) (b - x) a Substituting these series into the integral equation (C.3.6), it results bo
G(a)da = 1 A
r*
ao+E an coo no x
0
n>I
x
n>1
(_2!cosmOcosmo+F)d9=
(C.3.12)
m>_ 1 m
-aor + n>1
i
a. cos no,
where we denoted
r = ro + In e = ro + I n (b 4 a) .
( C . 3 . 13)
Identifying the coefficients we find:
I
bo = -aor, bn = + an .
(C.3.14)
500
SIN(:ULAIt INTEGRAL EQUATIONS
In the sequel. we have a) (b - t) g,(t)d
T
t..
(t 1 u)(b - 1 1 ( l (
fb
x
77
sin0
1
tt
r Jot COS a -, Cclti 0
_
1
sin a
r
0 COS a - C
ci
sin0 (C(4))
cos a - cos 0
(
(g)d0=
sin n0 d0=
7 cos(n + 1)0 - cos(n - 1)0 d
O
cos or - Cos 0
n
or, utilizing Glauert's integral (B.6.6),
i
(t.-a)(b-t),(t)dt
%b
ra
t -- x
sngit - 1)a
Stn(n + 1)a n>1
n>1
-E a,, cosna+-F'(a)+tatt = V12!1
(x - a)(b - x)f(x) - bo/r,
= --
(C.3.15)
where bo is (C.3.11). From (C.3.15) it results
f (s) =
-
1
rb y/ (t - (z)(G -
1
(x, - (1) (b
t-r
X) JJ4
t)9
(t)d t,(C.3.16)
_
1
r1'
1
(x - a)(b - x)
6
g{t) dt. (t -- -a) (b - t)
This is the first form of the general solution of the equation (C.3.I).
-
T11F,ru1RD EQUATION
501
One obtains another form if one utilizes the identity (t - a) (b - t)
(x - a)(b - x)
(x -- a)(b - x)
(t - a)(b - t)
(C . 3 . 17)
(x-t)(x+t-a-b)
(r. - a)(b - x)(t - a)(b - t) Substituting the first ratio in (0.3.16), it results the final solution
f(x)
(z
g'(t) dt + -a)(b-x.) (t-a (b-t) t-x a 1
1 1
-a)(b-a) J
g(t)1
I'
J
[(.
+ t - a - b)g'(t)-
(C.3.18)
dt
(t-«)(b--t)
We notice that from the relations (C.3.9), (C.3.14) and (0.3.11) it results
1 Jn
bf(t)dt=TJ b
-a)(b-r)clx,
(
(C.3.19)
which is an useful relation in applications.
We shall determine in the sequel the conditions which have to be satisfied by g, such that the relations (C.3.2) are satisfied by the solution (C.3.1). At first we notice that when the parameter r vanishes, a necessary condition for the existence of the solution (C.3.18) is b
L
g(t) d t = 0. (t - a)(b - t.)
(0.3.20)
The last integral from (C.3.18) defines for x real a polynomial of the first degree. f vanishes in a, is this polynomial has the root a
(the first term from (0.3.18) vanishes for x = a). In this case, the last integral has the order of (x - a), while the denominator of the fraction has the order of (x - a) 1/2. Hence, we must have -",)(b
f' [(t - b)g'(t)
grt)J
(t
- t) = 0.
(C.3.21)
502
SINGULAR INTEGRAL EQUATIONS
Analogously, f (b) = 0 implies fb
[(t - u)9'(t) - 9(t) I
(t - u)(b - t)
0.
(C.3.22)
Imposing the both conditions, subtracting and adding, we obtain 91 (t)
L b
J
[(t
a
9rt - - tad
- c)9 (t)
(C.3.23)
(t-a)(b-t)dt __ n,
(
t/b )1
t)
0.
(C.3.24)
This is the answer for the proposed problem.
C.4 The Forth Equation At least in nragnetoaerodynarnics [3.9] [1.9) p.208, in the theory of oscillatory wings [10.15) and in the theory of the wing in fluids with chemical reactions [3.10) [3.24], it intervenes the following singular integral equation [A.16) fb
1
f(t)dt+- j
f(t)(lnt-x)+ro)dt=h(x), a<x
where f is the unknown, ro an arbitrary constant and It, a given function. The solution is unique if one imposes the behaviour of f in one of the end-points of the interval. We shall impose the boundedness
of f sa in b. Denoting
1b
g(x) = -,- f f(t)(ha it - xI + ro)d t,
(C.4.2)
a
we shall notice that
g'(x) =
r
ad t .
t So, the equation (C.4.1) is reduced to the differential equation
(C.4.3)
a
(C.4.4)
whose general solution is
9(x) =
Aee('-`) +go(x),
(C.4.5)
503
THE FOIri'H EQUATION
where A is an undetermined constant, c is (C.3.4), and (C.4.6)
The unknown f may- be found from the equation (C.4.2) which is exactly the equation (C.3.1). Its solution is therefore (C.3.18) where g will be replaced by (C.4.5). For specifying it, one observes that
performing the substitutions (C.3.3), denoting by lo(w), Il (w), .. . Bessel's functions of imaginary argument and taking into account that II(w) = Il (w), one obtains
(
CW(t
T1
)
a)(b -- t)
dt
rr" e
a
,
x
b
T2
'" °d 6 = 7rIo(M)
(t - a)(b - t)
dt
(c+ecosO)e 06Od0
(C.4.7)
o
= irc1o (w) + rrel i (w) .
From the expansion
exp(0cos9) = lo(Z3) +
(C.4.8) n>l
and from Glauert's formula (B.G.6) we deduce e`'(t-c)
b
dt
1
'
-x
-
2-,r
e
Sill it (T
n>1
smo
ejjr
ewcoo0
cos0-cosad8 (C.4.9)
-
2-,r
V-r(b
E 1,, (0) sin laor
- x)(x - a) ,>I
where w = ew. For T; and x we have the parametric representation (C.4.9) and (C.3.3). We deduce therefore
f(.x)=-'A (x-a)(G-x)7'3+ x
[w(x_2c)_]Ti+_ 17
7,-
(x-a)(G-x)
x
--a) (x - (b - x) (C.4. 10)
504
SINGULAR INTEGRAL EQUATIONS
fo being obtained from f by replacing g with go. In aerodynamics f represents the jump of the pressure and we need therefore the integrals
j
rb
b
f x f (x)d x
f (x)d x,
(C.4.11)
4
which may be easily calculated without utilizing (C.4.9). Directly, the first integral is obtained from (C.3.18). In the sequel we shall determine the constant A. Imposing the condition f (b) = 0, we have from (C.3.22) and (C.4.5) A [ (aw
+ ,) Tt - wT2]
(C.4.12)
= GO,
where b
Go
[(t - a)9o(t) - Tgo(t)
(t
u)(b
t)
(C.4.13)
Now the problem is solved.
C.5
The Fifth Equation
In the theory of oscillatory wings [10.20) it intervenes the following integral equation (A.16[:
b(tf(t))2dt+
2
Jf(t)(lnIt-x[+I'o)dt=h(x), a < x < b,
b
(C.5.1)
which has to be solved together with the following conditions
f(a) = f(b) = 0.
(C.5.2)
The sign "' from (C.5.1) shows that. one considers the Finite Part. Introducing the notation (C.4.2) and taking into account the formula (D.3.6), from (C.4.3) we deduce . b o
(t - x)2 d t ,
(C.5.3)
a
such that the integral equation (C.5.1) reduces to the following differential equation g" - w2g = h. (C.5.4)
505
TILE FIFTH EQUATION
The homogeneous equation has the solution g = Aocosh w(x - c) + Bosinh w(x - c) .
Applying Lagrange's method of variation of constants, one obtains for the solution of the differential equation (C.5.4), g = Acosh w(s: - c) + Bsinh w(x - c) + go(x) ,
(C.5.5)
where
h(E)siuhw(x - E)dt;
r(l(x)
(C.5.6)
The solution of the integral equation (C.5.1) may be obtained from (C.3.18) where one replaces (C.5.5). For specifying it we notice that setting
t = c+eu,
u E f-I,+1J,
we deduce (t - a)(b - t) = e2(1 - u2) and then sinhw(t - c) d t = r+1 sinh (Foil)
So n
J
(t - a)(b - t)
1
d u = 0,
(1 -- uu
the integrand being an odd function,
r6 Coshw(t - c)
(t - a)(b - t)
n
b tcosh w(t - c)
C1
(t - a) (b - t)
Ja
ar.
=
Cosh Pu}
_rdu=glo(w)
fJ
J1 - u2
1
dt
(C.5.7) Yt
J Sl
/b
(c+eu)
cosh (Cu)
1-u
tsinhw(t - c)
(t-a)(b-t)
du=crrlo(w) 1 usinh (Ou)
dt=e f-i
1-u
d u = eirl1( ,.r ) .
Also, using the change (C.3.3) and taking into account (C.4.8), Clauert's formula (B.6.6) and the relations
(-1)' I,,(w),
(C.5.8)
SINGULAR INTEGRAL EQUATIONS
506
we deduce ?,s
b
sinh w(t - c)
dt
- a)(b - t)
r' sinh (iv cos 9)
e
o
cos0-cosy
d8
sina
(b - x)(x - a)
f[
1
sinner
=E [1. (0) e n>1
TC
t-x
-
Eli n>1
cashw(t - c)
ner
(C.5.9)
dt
(t-a)(b-t) t-x n
sin nay.
(b - x) (x - a) n>1[1 -
These formulas, together with (C.3.3), give the parametric representation of the integrals T., TT and the variable x. With these results, the solution of the equation (C.5.1) is
f (x) _
+
(x - a)(b - x)(ATT + BTT)+
(x - a)(b -
x)I A(wS1 \\
11,Co)
+wB (x-2c)Co+C1I I, L
(C.5.10) where fo is obtained from (C.3.18), replacing g(t) by go(t) given
by (C.5.6). As we have already mentioned in the case of the equation (C.4.1), in aerodynamics we need the coefficients (C.4.11). They may be obtained easier utilizing the form (C.3.18). For determining the constants A and B we impose the conditions (C.3.23) and (C.3.24) where g' has the expression (C.5.5). One obtains the system wCOA=Gm, (C.5.11)
w(C1- cCo)A+ (wS1 -- r-1Co)B = G2,
507
THE FIFTH EQUATION
where '' C1
-L
9-'o(t)
dt (t-a)(b-t), (C.5.12)
rb
G2 = -
JJ
[(t - 09' W) -
l TYO(t)J
(t.- a)(b - t)
Taking into account (C.5.7), we deduce G1 A- w7rlj1(D) B,
r-110(w)[
(C.5.13)
In many applications we encounter the situation when h = -c (the case of the flat plates with the angle of attack e). In this situation, from (C.5.6) it results w290(r) = e[1 - cosh w(X - c)),
such that G1 = 0, W2G2 = Frr[wl1(i)
- r-`lo(ay) + r-.1[
whence,
A=0;
13= 4
[1+zr11(0)-IQ(W)1
.
(C.5.14)
Appendix D
The Finite Part
D.1
Introductory Notions
The notion of "Finite Part" of a improper integral has been introduced by Hadamard in 1923 [A.39], in order to give a significance to the divergent integrals which appear in applications and to utilize them. Hadamard studied integrals having the form b
f Ja
fW
d
(b-X)*,+1/lr,
(D.1.1)
where n = 1,2,3,.... There exists however many integrands with non-integrable singularities which appear in applications especially in aerodynamics. It exists therefore different manners for treating this problem. In the subsonic aerodynamics one utilizes especially the definition of Mangler [A.45], but we had not the possibility to read this paper. A less cited contribution, but very adequate to aerodynamics belongs to Ch. Fox [A.37]. Here, the notion of "Finite Part" appears like a natural extension of the concept of "Principal Value" in Cauchy's sense. We shall present in the sequel some results of this author. For the integrals having the shape (D.1.1) we shall utilize the paper of Heaslet and Lomax [A.44]. These ones appear in the supersonic aerodynamics. Important results concerning the notion may be found in the papers of Kutt [A.42) and Kaya and Erdogan [A.41]. At lasst, the theory of distributions give an unitary method for the study of this notion [A.5].
D.2 The First Integral We shall consider at first the integral
Il -
fa
dx,
n=0,1.....
(D.2.1)
510
THE FINITE PART
If f admits derivatives up to the order n + 1 in the origin, then we may write =Jara
[f(x) -
(dx
I
yt
fl')(0) + ft'?(o)} d+1+
[.rx)-E
o
ft,,(0)]
-, xi-^ f(i)(0) a i - it
=
i=0
r=0
=
dx
it
14)
xla
+ n!
In 0
The integrated part for x = 0 becomes infinite. Neglecting these infinite constants, one obtains the so called "Finite Part" of the integral 1. Hence, indicating by an "asterisk" the Finite Part, we have:
f(X) xn{i(Ix =
in [1(x)
-
"- t
JO
dx
.n+1 + im0
"
f(i)(O)
(D.2.2) a'
f In) (0)
In a.
i-0
For f = 1, it results
Td'x =lna,I-!+i J
»
1 it a
(n.> 1).
(D.2.3)
D.3 Integrals with Singularities in an Interval We shall consider the integrals having the form 12
rb
I( X) +idx,
11 =0,1,...,
(D.3.1)
where a < u < b. For n;-- 0, we consider the "Principal Value" of the integral in Cauchy's sense.
,(J G-E + c-» u \ , x-u d x = lien
lb
1L f (x)
r1
f (?) d x xu
.
(D.3.2)
511
I? TECRALS WITH SI`CULARITIES IN AX INTERVAL
«Vc know from (B.1.2) that this limit exists if f satisfies Holder's condition in the interval (a, 6). Let us derive now (D.3.2) with respect to the variable u. In the right hand part, the derivation is performed according to the derivation formula for integrals containing the variable in the limits. We have therefore d(,(
b
d r =1im U C-0 d u Jn X - u f 0x)
t. s+
b
f (X)
Ju+E) (:r - fl):.
-
d x-
-f(u-0 _ f(u+=) or, expanding into a Taylor series the functions f (u - E), f (it + E),
,
+
x (xatd x
Tit J
en o
(.1:
L+J (z )2J
(D .3.3)
If the limit from the right hand part exists. we denote it by
Ja T.
f 0-) (T-u)2
(D.3.4)
d X.
and we have
f
d x def
(x - u)2
lim s-'0 l
f u-e + fb l C a
d rh f(x) dA, J du a X - It a
f (X) d (:C - u)2
2--1
x-
(Xf(T) -.11)2 dx.
(D.3.5) E
(D.3.6)
The limit (D.3.5) defines the Finite Part of the integral from the left hand part. The Finite Part is a distribution {A.14]. Ex. 11. One proves [A.37{ that if there exists f'(x) on (a, 6) and this function satisfies holder's condition, then the limit from (D.3.5) exists. We notice that this theorem constitutes the extension of the theorem of existence of the limit (D.3.2). We indicate now how one may reduce the calculation of the integral (D.3.1) to the calculation of an integral with a weaker singularity. We consider the case n = 1. Hence, we demonstrate that in the same conditions like above (f' is defined and satisfies Holder's condition on (a, b) ), we have
f(T) ,
(x-n)2
f(u)
f(6)
a-u 6-it
f'
, :r - u
THE FINITE PART
512
for every of from (a, b). Indeed, employing for the left hand side member the definition (D.3.5) and integrating by parts, we obtain
r f () a
+
ii
(x-u)2 fb
t+
U -C
d x = lim
e-'0
CL
I-
+
Zb +t )
a
f 2f (u)} XU d a - c
f (a)
f f (x), d x+
a; x - rt
-
f (b) +
a-u b-u
f.b
t(x)
f da X-u
.
The extension of the definition (D.3.5) and theorem (D.3.7) to an arbitrary value of n , is performed in (A.37]. In the same paper one gives the respective definitions in the complex plane and also Plemelj's formulas for integrals having the form
F(z)
7ri I 21
(t
1(t +I d t
(D.3.8)
.
Utilizing (D.3.6) we may calculate (by derivation) the Finite Part when we know the Principal Value. So, from (D.4.1) it results the integral often used in Appendix C, 1
7r
(t-a)(b-t)dt=-i, u<s
(D.3.9)
From (B.5.3) we deduce
1`/b ia
dt
1
0
(b - t) (t -a) (t - x)2
(D.3.10) ,
and from (B.6.9),
t
1
it Ja
t
a
b - t (t
x)2
dt = 1,
(D.3.11)
and the sequence of examples may be enlarged (see also (A.41]). We also observe that we have day
(x - u)2
_
1
a - it
- b - it 1
which may he obtained considering f = 1 in (D.3.7).
(D.3.12)
513
HADAMARD-TYPE: INTEGRALS
D.4
Hadamard-Type Integrals
We shall consider the integrals having the form
I3=Ja
a
(s x)'+tf2dx,
n=1,2,...
(D.4.1)
which intervene in the supersonic flow. As we have already seen in (D.2.1), the basic idea in the definition of the Finite Part consists in leaving apart the infinite values from the structure of the integrals. In order to see the significance of the integral denoted by (D.4.1) in the case n = 1, we shall observe that d ds
f'
78
{ (s
s(x)x
d. = sic dds
- e)
f +J
a -C 8 a
f (x)
s-xJ dxJ
a8
.
If f is continuous in a, the first term from the right hand part becomes infinite such that we must leave it apart. We shall consider by definition
B(x)xl d x = ds.
Ja a
I
s(x) d x
(D.4.2)
or
like in (D.3.6). For f = 1 we deduce
dx a
(s-x)3/2
-
2
s-a
(D.4.4)
Let. us prove now that if f is continuous in s and admits bounded first order derivatives on [a, s), then we may give a formula for calculating the member from the right hand part of (D.4.3). Indeed, we have d ds
f f(x))s f(a)dlmf(x)-f(a)+ [1(x)-f(s)dx. ifs s - x Ja as ,/ -x 3-x J (D.4.5)
But, with the above hypotheses, on the basis of Lagrange's formula
f(x) = f(s)+(x-s)f`[s+9(x-s)),
THE FINITE PART
514
we deduce that the limit from (D.4.5) is zero. Hence, d
f(x) dx= ds / s-x
is
f(x)-f(s)dx+
,/Rx
dx R-x J =
!( s ),.
dx
--1JNf(x)-f(s)dx- f(s) f 2 a
(s - x)3/'
(s - x)3/2 (D.4.6)
2
If we also utilize (D.4.4), then (D.4.3) becomes:
' AX)
(s - x)3/2
d x=
fa f(x) - f(s) dx-
2f(s) s --a
(s - x)3/2
(D.4.7) '
this representing the calculation formula for the Finite Part. It is similar with the formula (D.3.5). From (D.4.5) it also results a derivation formula, in fact, the formula analogous to (D.3.7), which reduces the calculation of the integral with a strong singularity to the calculation of an integral whose singularity is weaker with an unity. In the case we had in view (n = 1), the weaker singularity will be integrable. Indeed, taking (D.4.4) into account, we have: ds
f" f (r) - f (s)
fa
s-x
d x=
d
ds
f (x) d x--
s-x d
(D.4.8)
x - 77=7= f (_)
lax V-9 - i
Noticing now that 8/8R = -8/8x, integrating by parts and taking into account (D.4.6), we obtain:
1f(z) - f(s) 8s s-x
dx S^x,
d a
-1NIf(x)-f(s)]dx (7s l a f (g) Z
N
dx 797-77
x
)dx=
+f(a)-f(s)+
s-a
+f8 f'(x) dx. s -x. (D.4.9)
515
GENERALIZATION
Equating the first members from (D.4.8) and (D.4.9) according to the formula (D.4.5), we obtain: d
dx_ f(a) +1fs fI (x) dx,. 8-x 8-at a s - x
f(.T)
as
ds
(D.4.10)
This is the formula of reduction to a weaker singularity, analogous with (D.3.7). It also proves that the term from the right hand part of the
equality (D.4.2) is finite. Analogously one obtains d ds
x(x)8dx =
I'
-
f (b)s
fx(x)sdx, .
+b
(D.4.11)
The generalization of the definition (D.4.2) is performed as follows
I's 88" an [ f(x) s-x ]d, =
dn
(D.4.12)
d8" Q s-x if f is continuous in a, n times derivable and with the derivative of order n bounded in (a, s) (A.40J.
Generalization
D.5
In the theory of oscillatory wings one may encounter integrals having
he shape (D.4.1) where f depends also of 8. We shall establish for these ones the derivation formula (i
rb AX'S) dx = - f (b, 8) + J/'b fs (x, 8) + fi (x, 8) {D.5.1) x x-e b-s s Vime from which one obtains (D.4.11) in case that f does not depend on s. d4
Indeed, we have d
dsJ, xx-s
fdx 1 ds[rf(x's
L
+f(8,s)
x fss's)dr.+
X
JJ,I
-
(D.5.2)
sJ
But,
d bf(--, cly
y
s,s)dx=\sf(z,8)x
fs8,d)+
z (D.5.3)
+
/'b 8 [f(x1s)_f(ss)1dx8x-8
J
THE FINITE PART
516
If f (x, s) is continuous in x = s and admits the derivative
f=
bounded in the interval Is, b], then, from
f(x,s) = f(s,s) + (x - s)f [s,s+d(x - s)] we deduce that the limit from (D.5.3) is zero. After all, changing 8/8s
by -a/Ox and integrating by parts, we obtain
f
f (x, s
r
d s J,b
+ Jb ff(x,s)
f"[f(x.s) - f (s,
s) d
- f(s,s))sdx =
-f(x,s) -
x-s +
_
g s'
v
ad x+
x
fb f=(x's)dx+
777-
x-s
J3
Xd-f(s,4) j xs b fi(x, s) + fr(x, 9)
f (b, s) - f (s, s)
+le
b-s
1
s)1849
s
b
e x dx-8sr(s'8) x-s
Replacing in (D.5.2) and taking into account that d
s
TS
dx
x-s
b - s'
we deduce (D.5.1). The established formula (D.5.1) shows that the first member is finite. Hence, we may set by definition
r O f(x ss '
d
ds= ds,f f
(D.5.4)
d x,
for every function f (x, s) continuous in the point (s, s), derivable, with bounded partial derivatives in x and a, where s < x < b. In the general case we shall define I
n f(x,8)dx..
dsb
f
(x,s)dx.
(D.5.5)
Appendix E
Singular Multiple Integrals
In the euclidean space with n dimensions E, one considers a domain D bounded or not ( D may coincide with and a function If F(,c) defined on D. We denote t = (fi, ... , r;,,), a = (XI, ... , 1) is unbounded we shall assuine that F tends to zero when Itl -+ 00 in a certain iuanner which will be precised in the sequel. We admit that there exists a point Q(r) in D, such that in every vicinity D. (having
the diameter E) F is unbounded. while, in D - DE, F is bounded mica integrable in the usual seas. Then we set
E-U D-D, IIDFdC=Urn
If this limits exists, it is finite and does not depend on the shape of D,, then the integral will be convergent. Otherwise the integral will be diverrgeiit.
We consider now a divergent integral. If there exists a certain shape of D, (for example, sphere or cube) for which the limit exists and is finite (hence it is unique for every sequence of spheres or cubes contracting towards Q). then the integral will be called semi-convergent. The limit (which depends on the shape of DE) will be called principal value of the integral.
Utilizing spherical coordinates one demonstrates that the integrals having the form
JD'' f
(E.2)
where r = IC - xi, and is bounded in D, are convergent for a < n and divergent for a > n. The case a = n will be investigated
separately. We shall consider the integral having the form V(X) = JD
(X, M)
where m =
r T,
(E.3)
SINGULAR MIXTIPI.E IN1'E<;RALS
518
where f will be called the characteristic, u will be called the density
and x the pole of the integral. The ratio K(x1) = f /r" will be called kernel. All the integrals that we utilize in this book have the form (E.3). The first who studied this type of integrals was Tricomi [A.351 who gives some results in the case a = 2. An ample presentation, which will guide us in the sequel, of the theory of integrals having the forth (E.3), may be found in the books of Mihlin (A.251 and [A.26]. In this presentation. D, will be spheri cal the convergence of the integral will be investigated with respect to this form. We assume that:
satisfies Holder condition in D; if D is unbounded, we 10 assume that u(t;) = 0(It;l-t), k > 0. Holder's condition means that there exists two positive constants A and a, 0 < a < 1, such that for every two points 1;1 and 42, front D sa we have ju(f1)
-
Ajf 1
- 21' ;
(E.4)
2° The characteristic f (x, in) is hounded and for a fixed x it is continuous in in. Under these assumptions, we have the following theorem: The necessary and sufficient condition for the existence of the inteyrnl
(E.3) is to have '
is f(x,rn)dS=0,
(E.5)
where S is the surface of the unit sphere centered in x. In order to make the demonstration, we isolate the pole with a sphere
included in D, having the radius 6 and the center in x. Obviously,
f
(r, n)d,
1)
1
Litre
r
JII--Ui
u(h)f
r"
(u(E) - u(x)J f (T.t-) d o + u(x) l t o J
t
f (rnm)
The first two integrals from the right hand part of the equality are absolutely convergent. In the third one utilizes spherical coordinates
relative to the pole x. Since d = r" 1 d rd S, we obtain J
Cr"
f (x, err)
iss
f (x, rn) J
= In
r
f f (x. rn)d S.
F fs
It results the necessary and sufficient condition (E.5).
519
SINGULAR MULTIPLE INTEGRALS
if this condition is satisfied, the integral (E.3) may be represented as follows
L v.(o
r" (E.6)
r L - nj u(h)f (x,m)(it + inh Mu(d) - u(x)]f (x,m)dt. r
As an application, we shall consider the integral:
f
0
J p 1(c,n)
(E.7)
1 Ox Rcwhere
I? is (5.1.11). With the change of variables q - y = sin 0, the condition (E.5) gives
-x=
008 0,
21r
X (19
I2-.T
0
=
Ro
J0
cos 8d 9 = 0.
(E.8)
Hence, the integral (E.7) exists. The second important theorem that we utilize (for the transonic flow) is the following: If, in addition to the hypotheses 10 and 20, we assume that grad.K(:r. ) = O(r-"° 1), then the singular integral (E.3) (as a function of x) satisfies Holder's condition, with the same exponent like u, in every domain which is bounded, closed and included in D. The theorem was proved for the first time by Giraud in 1934, and for n = 1 by Privalov in 1916. As we can see in (A.251-and (A.261, the demonstration is not simple. The last theorem refers to the derivation of the integrals with weak singularities having the shape
v(x) =
JD
u(h)f
(E.9)
which lead to integrals of the type (E.3). Like in the previous theory, D may be a domain bounded or not of the space E,,, or it may coincide with the entire space. W e assume that the function f (x, m) is continuous and bounded together with its first derivatives (the first order derivatives with resped to the cartesian codrdiriates of the points x and na). We also assume that u(i:) satisfies Holder's condition and
at infinity (if D is unbounded)
o('t;-'J), t > 1. Under these
520
SINGULAR MULTIPLE INTEGRALS
assumptions, there exist the first derivatives of the integral (E.9), and they are given by the formula axk = ID
xk
[1t]
d
, - u(x)
j
s
f(x, m)
cos(n,
xk)d S, (E.10)
where, like above, S is the surface of the unit sphere centered in x, and n, the outer normal to the sphere. Olviously, the first integral from the right hand part of the equality is singular.
Appendix F Gauss-Type Quadrature Formulas
F.1
General Theorems
This appendix relies on the paper [A.49] and it is completed with some results due to Monegato [A.52). Gauss-type quadrature formulas give exact evaluations for the integrals of polynomial functions, multiplied by a weight function w. In aerodynamics it also meet integrals with singularities. Approximating an arbitrary function (according to Weierstras's theorem) by a polynomial function, we may utilize these evaluations. Practically, the approximation is performed by a Lagrangetype interpolation formula. We shall consider in the sequel that to : 1-1, +11 - R is a positive integrable function. THEOREM 1. We have the exact evaluation
+i 1
n
Af (x.)
f (x)w(:c)d x
(F.1.1)
0=1 if.
10 f is a polynomial of degree < 2n -- 1; 2e the points x = x,,, a = 1, n are the n zeros of the polynomial P,,(x) of degree n from the orthogonal system of the weight w(x) on [-1, +1j
w(x)P,(x)Pj(x)dx = 0,
i 0j;
(F.1.2)
30 Using the notation
Wt) = fP(x)!.Q3dx,
(F.1.3)
the coefficients A. are given by the formulas Qn(2a)
4a = Pn(xa) .
(F.1.4)
CAUSS-TYPE QUADRATURE FORMULAS
522
Proof. Taking into account that f is a polynomial of degree 2n-1, and P is a polynomial of degree n, we may write
f
n
a,
E 27 -xa + Fn_1,
T-
(F.i.5)
where Fi_1 is a polynomial of degree < n - I. We determine the coefficients a° multiplying (F.1.5) with x - x° and putting x = xa. It results (F.1.6)
as = f(z°)/PP(xa)
whence
n __
f
P.
f(xa)
=1 Pn(X-)(Z - xa)
+ A,
Since
dx =
J- 11 n( ) )(x
)
( )`vn(xa) a)
=
and because F,,-, may be written as a linear combination of P0,.. . , Pi_1, such that +1
Pn(x)FF-1(x)w(x)dx = 0, we deduce (F.1.1). THEOREM 2. We have the following exact evaluation:
rt
J- t
x; d x = E A° f (x° n
f (x)
a=1
.
(F.1 (F.1.7)
x
where j = 1, 2, ..., if 10 f is a polynomial of degree < 2n; 2° the points x = x°t a = T-, n are those defined in Theorem 1;
3° the points t = t,, j = 1;2,..., are the zeros of the function Qn defined by (F.1.3);
40 the coefficients A are defined by (F.1.4).
523
GENERAL THEOREMS
Prof. Reasoning like before, we have:
f P_E ac. +Fn, X X0, A-1
where the degree of F, < n. It results that as has the form (F.1.6). Setting F = (x - tj)Fn_1(x) + A, where the degree of Fs_1 < n - I, we deduce
f
P'
L-i
whence
+1
P"(x)f(x0)w(x)
LI f (xa
Pn(x.)(x-xQ)(x-tj)dx__
'(+1 P,(x)w(x)
P., (X-)
A
P (xQ)(x - x.) + (x -
1
A. (:r.) _ QXQ - tj
xQ - tj
[_jdx= 1
1
f (zz)Qn(t5)
1n(xa)(xa-tj)
_ A. f (x,)
xQtj
because Q,, (t,) = 0. THEOREM 3. We have the exact evaluation
I
(f(x)
(F.1.9)
t
where the "asterisk" is for the Finite Part (I).3.5), if.-
10 f is a polynomial of degree < 2n + 1;
20 the points x = x.., a = 1, n are those defined in Theorem 1;
30 The points t = tj, j = 1, 2.... are those defined in Theorem 1; 4e the coefficients An are given by (F.1.4), and A = Qgn(tj) Pn(tj)
(F.i.10)
Proof. We shall notice at first that, on the basis of the definition (D.3.G), we have for t E (-1, +1),
t0adx,
(F.1.11)
524
GAUSS-TYPE QUAUR .ATURE FORMULAS
whence
t
Q;,(tJ) =
jPn(x)(')2dz.
(F.1.12)
We shall write m above is
PA
f - P" LF-
(F.1.13)
)x-)
being a polynomial of degree :5 n - I and B, C, constants. For x = tj it results
I(ti)
C
F&
f(3.-*)
(F.1.14)
0-1 Fnxa)(tj - xa)
P"(tj)
Since
_
1
(x - xn)(x - tj)2 2
1
1
tj)2 x
(rct
1
x,.
1
1
(z _tj)2 x-tj + tj -xo (x-tj)2 Taking into account that
0 and that Ave have (F.1.12),G
we deduce
1+`
P"(x)f(x.)w(x)
f-1 Pn(x.)(x - X.)(x - t j)2
= f(x.) (x.-tj)2( x-x P (x.) (' +1 P"(x)w(x) 1 A 1
dx=
- r. 2- t3/ d x+
' +1
+J-1
(F.I.15)
dx
ty-xo
(x-ti)2
f(xa) Q.(xrx) + Q;z(tj) P.(x0) (x,, - tj)2 tj - Xw Having in view the definitions of the Principal Value and Finite Part,
it results t
T'I
x - tj fl+' P.(r)u'(x)dx
x - tj
4n (tj) = 0
Utilizing (F.1.14) and (F.1.10), we deduce
1Pn(xQ)(tj +!
C
+
_1
P"(x)(xu,(x)
- tj)
2dx = AI(tj) -
y 1{XQ}'^Ln(tj)
- xa)
525
FORMULAS OF INTEREST IN AERODYNAMICS
whence it results (F.1.9). The integrals having the form
wx ( )n :
+1
1 f
(x) (x
n>2
'
(F.1.16)
1
are studied in [A.49] and [A.52].
F.2
Formulas of Interest in Aerodynamics
It is well known that on the interval (-1, +1] Jacobi's polynomials (x) constitute an orthogonal basis with the weight function w(x) _ (1 - x)°(1 + x)' ( see, for example, (A.561). Obviously, the zeros xo and t) from the theorem--, from F.1 do not depend on the factor of normalization of the polynomial P,,. One can simplify this factor in A,,
from (F.1.4) and A from (F.1.10). We shall utilize therefore
Jacobi's polynomials without the constant factor. 1°. For the weight w(x) = (1-x2)-1/2, Jacobi's polynomials reduce to Chebyshev's polynomials x = cos9.
TT(x) = cosn9,
(F.2.1)
F o r 0 < 0 < jr, the polynomials T. (n = 1, 2, ...) vanish when
9° - 2a-1 w , n
2a-lir ' a = Tn.
xQ_
- oos
2
n
Utilizing the notation t = coax
2
and Glauert's integral (B.6.6), we
deduce:
sin or
(F.2.3)
Qn(t) = x sin or
with the zero
a,=? , tj=cos
r(x) _ -
Since
1
-1-,n n
(F.2.4)
sinn9 sin9
dTn
sing dO from (F.1.4) it results that A. = 7r/n. Since n(t))
V
(F.2.2)
d sin na
- -slam do sino'
= nir cos ja cf
sill2
526
GAUSS-TYPE QUADRATURE FORMULAS
from (F.1.10) it results that A = -n7r/(1 - t). We deduce therefore the following formulas: tt
411
f(x) dx = T Ef(xn), it 1-x 0
r J-
i
+I
+1
f (x)
dx
7r c- f (x, )
y:"]X-tj
dz f(x) (x _ tj)2 1-Z
J-1
(F.2.5)
1
n i-.
(F.2.6)
n.Lt f (v)
tt7r
(xa - t;)2
1 --
t=f(tj)
(F.2.7)
for j = -, n- 1, where .r are given by (F.2.2) and tj, by (F.2.4). 211. For the weight function w(x) = (1- x2)1/2, Jacobi's polynomials reduce to Chebyshev's polynomials of second order sin( e1)9 sin
Cyr
+
e"
I'
1
x=
xa - coy re[+ 1 '
(F.2.8)
a = 1, nrt .
(F.2.9)
Using the notation t = cos a and Glauert's integral (B.6.6), we deduce:
-ircos(n j- I)a
(P.2.10)
whence
2, j=1,ri+1.
tj=cvs't
(F.2.11)
1
Utilizing the formulas given in the theorems F.1 for A,, and A, on the basis of Glauert's integral, we obtain:
- n4-1 (1 -" xa),
A = -r (n + 1)
.
Hence, the following quadrature formulas are established: n
+'
1-1`.f(x)dx=n+1E(I-
+1
xt
f(rn),
(P.2.12)
es=1 f(r.)
x -tj
dx=
7r
I - xp f( :ra ),
-t;
(F.2.13)
527
FORMULAS OF INTEREST IN AERODYNAMICS
+1
1- xa
ir
f (x)
1-z (x-tj)2dx=n+1
J-1
(xQ-tj)2f(xo)
awl
(F.2.14)
-ir(n + 1)f (tj), where j = 1, n + I, xa are given by (F.2.9) and tj by (F.2.11). We notice that the numbers tj given by (F.2.4) are the zeros of the and the numbers ti given in (F.2.11) are the zeros of the polynomials Tn i(t). x)1/2(1 + x)''/2, Jacobi's 3°. For the weight function w(x) polynomials
polynomials are [A.56].
Pn(x)
=
with the zeros
sinj(2n + 1)8/2]
_
2aar
x = cos 0,
,
a=1-,n.
(F.2.15)
(F.2.16)
With the aid of Glauert's integral, we deduce
/2j'
-,'[(2n
Qn(t) =
cos(
CO6C
/Z)
whence
9=l .
(F.2.17)
Utilizing (F.1.4) and (F.1.10), it results:
A. =
2n 2n+1(1-xa),
A
_ 2n+1x
1+tj 2'
Hence, we established the following formulas: +1
J-
1
r+i . +1
_0
2w
fin
1f(x)dx 2n+1` a-i
J
- x f (x)
_
(1-x.)f(x.),
27r
+x x-tjdx 2n+1 a-i -a
1-z
f(x)
-I V 1+x (x - tj)2 n
(F.2.18)
(F.2.19) 13
dx= _
(F.2.20)
j 2f(tj)
2n+1r(Q-tj)2f(x.)- +
528
GAUSS-TYPE QUADRATURE FORMULAS
j = 1 n,
for
being given by the formula (F.2.16) and tj by
x,,
(F.2.17).
40. For the weight function w(.r.) = (1 - x)'"112(1 + r)h/2, Jacobi's polynomials are
'n(s) with the zeros
cos((2n + 1)9/2J cos(0/2)
2a -1
r
x = cos9,
o= ln.
2n+1T,
(F.2.21)
(F.2.22)
Utilizing Glauert's integral, we deduce:
Qn(t) _
sin[(2n+ 1)Q/2] s in(a/2)
,
t=CADS a,
polynomials which have the zeros
t'-
(F.2.23)
2n+1'
On the basis of the formulas (F.1.4) and (F.I.10) we obtain 2'7r A"2n+1(1+xn),
2n + I An=-1-t,
ar
such that one establishes the following formula, +1
J
1+x 1
'
n
L(1 +x,,)f(F.2.24) f (x)dx = 2n + 1 27
J1 + x f (x)
21r 1-xx-tjdx=2n+l
1 + x0
1+x
ar 2n+1 it 1-t; ?f(tJ)
s"-tjf(n),
(F.2.25)
1
f
1--x {x-tJ)2 (F.2.26) tar
n
2n+I
owl
(ca-tf)-f(x°)'
for j = 1, n, the zeros xa being given by the formula (F.2.22) and tj by the formula (F.2.23). We have to notice the relations between the formulas from 30 and
40. The points x,, from 3° coincide with the points t1 from 40, and x,,, from 40 with t,, from 3°.
529
TILE MODIFIED MONECATO'S FORMULA
F.3
The Modified Monegato's Formula
It is preferable sometimes to replace the formula (F.1.9) which contains the numbers f (t;) by the formula given by Monegato (A.52] p. 279. t1,(r)
f(r)
dx=>
(F.3.1)
(x - t)2
J-1 where
Q1. (Z.) - Q. (t) - Q/n(t)(x° - t)
Pn(x°)(x° W
(F.3.2)
,
the formula containing only the numbers f (x°). The formula (F.3.1) is exact, i.e. Rn (f) = 0. if f (x) is a polynomial of degree n - 1.
In fact, in applications one utilizes not the formula (F.3.1) [5.10), [6.5], but another one which may be obtained as follows.
In (F.3.1) we isolate the term corresponding to a = j and we pass to the limit, +1
t -.
We find
n,
ut(x) (x f(x) dx = E wa' (xj)f(x°)+ - xj)2 °=1
+wj(xj)f(xj) + Rn(f),
(F.3.3) .
where the mark at F, means. that one excepts the term corresponding to a = j. The factor w'°(xj) is obtained from (F.3.2). Using the rule of I'Hospital u J(xi) we find that q., (xj)
(F.3.4)
In applications one utilizes (F.3.3) for w(x) = (1-x2)1/2. The numbers xo are given therefore by (F.2.9). From an elementary calculation it results Qn(s'a) = -7r(-1)° , Q'n(xj) = 0,
+ 1)(-1)° X'2
,
Qn(xj) = 70 + 1)2 01 s 1-x12
530
GAUSS-TYNE QUADRATURE FORMULAS
whence f(x)
+'
1
_-2
E [1 (-1)j]
(xa -
0=1
2f(:rn) -
n2
1f(xr)+ R,,. (F.3.5)
This is the modified formula. From
f d_
+t
w(x)
1.-t
uwa(t)f (xo) + Rn(f)
a
(F.3.6)
a=1
where (A.50J page 275, ww(t)
Rn (xo)
Qn(T )
- Q.t (t)
(F.3.7)
,
isolating in E the term for which a = j and passing to limit t --+ xj, one obtains the formula ry1
-t
Tl
u
w(x) f (x) d x =
x - xj
',)f (.r.)+
owl
xa)
(F.3.8)
f(x '
For the weight function w(x) = (1 - x2)1/2 we find: +t 1
n
1 - x2 1(x) cl x =
amt
n+1
2 f( X( -xj x° ) (F.3.9)
F.4 A Useful Formula We shall establish the following series expansion:
= -2E(j + 1)Uj(y)Uj(ri)
1
(n
X1)2
1
(F.4.1)
531
A USEFUL FORMULA
where U (x) are Chebyshev's polynomials (F.2.8). The series is divergent, but it has a first Cesaro finite sum: n
(tl
-2
1 y)2
I
U + 1)Ui (y)Ui(q) .
(F.4.2)
Indeed. setting q = ooeO and y = oosa on the basis of Glauert's integral, we deduce
r+1Ua(q)dq=-aoos(n+1)o, (F.4.3)
and deriving and taking (D.3.6) into account, we obtain the formula
J
(q - y)z
d q = -w(n + 1)U*(y).
(F.4.4)
1
Expanding now the function (q - y)'2 on the interval [-1, +11 in a Chebvshev-tvpc polynomial series, we have: 1
aJ(y)Uitq).
(F.4.5)
(q - y)" =
Taking into account (P.4.4), and the orthogonality condition
2!
UJ(1)Uk(q)dq =
10 JiAk J7r
,1 = k,
(F.4.6)
we obtain:
a,(y) = -2(j + 1)UJ(y). Replacing it in (F.4.5), we obtain the formula (F.4.1).
(F.4.7)
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Index
Abel's equation, 320 Acceleration
as material derivative , 2 of the particle, I potential, 9, 397, 404 Ackeret's formulas, 288, 423 Acoustics, equation of, 29 Aerodynamic action drag, 171, 172 lift, 76, 170, 172 moment, 76, 170
gyration, 171, 172 pitching, 171, 172 rolling, 171, 172 Arrow of airfoil, 83 shaped wing, 156 Attached shock waves, 361
Complex velocity, 71, 75, 120, 371, 375 Compressibility effects, 86, 148, 231 Conduction law, 13 Cone body's shape, 463 double. 464 Conical flow, 339-347, 464 Conservation laws, 11 Convolution, 33, 370, 470
Critical velocity, 6, 359 Delta wing, 156 Descartes, folium, 18 Detached shock waves, 19, 360 Distributions, theory of, 465.479 Doublet
Bernoulli's integral, 5-7 Bessel's functions, 407, 503 Biplane, 92
density, 266 flow induced by, 148 potentials, 426 Drag coefficient co, 181, 203, 204, 213, 229, 231, 241, 292, 458, 462,
Body, theory of slender, 449-464 R":rndarv conditions
Duhamel principle, 57
airfoils in tandem, 1:,Y airfoils parallel to the undisturbed stream, 93
grids of profile, 99 ground effects, 83 material surface, 24 rest state, 28 tunnel efects, 88 uniform motion, 25, 70 Boundary conditions (nonlinear case),
464
Energy, 3, 4 Enthalpy, 15 Entropy, 4 Euler -Lagrange criterion, 24 constant, 400 equation, 3 formulas, 146 theorem, 2
111, 112
Flutter, 397 Caloric equation, 4 Cauchy integral, 71 principal value, 482, 510 problem, 61 Characteristics coordinates on, 308 variables on, 318 Chebyshev polynomials, 80, 525, 526 Circulation, 125, 126, 274, 393 Clapeyron's equation, 4 Collocation method, 115, 231, 279 Complex
potential, 121, 146
Flux-divergence formula, 479
Forces, continuous distribution of, 73 Fourier, transform, 465-479 Fredholm integral equation, 209 Fundamental matrices, 61 Fundamental solutions equation of potential fluid at rest, 42
M = I oscillatory, 34 M = 1 unsteady, 41 subsonic oscillatory, 33 subsonic steady, 31 subsonic unsteady, 37 supersonic oscillatory, 34
INDEX
572
Fundamental solutions equation of potential supersonic steady, 31 supersonic unsteady, 38 oscillatory system
pressure formulae, 50 velocity formulae, 52 steady system general form, 45 plane subsonic, 46 plane supersonic, 48 3-D subsonic, 47 3-D supersonic, 48 unsteady system, 57
Causs-type quadrature formulas, 521530
Clauert integral, 489 method, 210 Gothic wing, 156 Green function, 142, 143 Ground effect, 82, 86, 136, 184, 238, 299
Hadamard finite part, 509 type integrals, 513 harmonic forces, 398 Heat, specific c,,, c.,, 4 Helmholtz's equation, 5, 33 Henkel's function, 33 Homentropic motion, 4 Huygens' principle, 42 Ideal fluid, 1 Instable shock, 18 Integral equations steady subsonic flow
lifting line, 201, 209, 219 lifting surface, 165, 167, 187 airfoils in tandem, 103 grids of profiles, 99 ground effect, 84 parallel airfoils, 94 tunnel efect, 90 thin profile, 72 steady supersonic flow lifting surface, 307, 313, 320
Integral equations
steady transonic flow lifting line, 395 lifting surface, 389 unsteady flow sonic profile, 440 sonic wing, 445 subsonic profile, 402
subsonic wing, 408 supersonic profile, 418 supersonic wing. 432
Invariant, 16 Irrotational flow condition, 368 definition, 5 equation of, 109 Isentropic motion, 4 Joukovaky profile, 86
Lagrange
-Cauchy's theorem, 5 interpolation, 223 variation of constants, 218 Leading edge, 62, 156, 301 subsonic, 301 supersonic. 301
Lift coefficient, 129 Lift coefficient CL, 76- 78, 81, 82, 85, 86,90, 96, 100, 104, 107, 171, 180, 183, 193, 195, 202, 204, 213, 229, 231, 237, 241, 287, 288, 291, 293, 298, 299, 350, 354, 357, 380, 421, 423, 441, 457, 462, 464
Mach angle, 40 cone, 31
dihedron, 32 number, 8, 19 Moment coefficient cm, 76-78, 81, 82, 85, 86, 90, 96, 100, 104, 107, 287, 288, 291, 298, 299, 421, 423, 441
Moment coefficient cs, 203, 204, 229, 231, 241, 458, 462
Moment coefficients c1, cv, 171, 181, 183, 19.3, 195, 2(r2, 229, 231, 237, 241, 458, 462. 464
INDEX
573
Plemelj's formulae, 483 Prandtl's theory, 197-205 Prandtl-Mayer fan, 289
Source mass, 43
Pressure coefficient Cp, 120, 129, 148
Swallow wing, 156
Rhombic wing, 156
Thermodynamics, equation of, 3 Trailing edge, 156. 301
Shock waves
Hugoniot's equation, 15 jump equations, 13 Prandtl's formula, 16 shock polar, 18 Sonic barrier, 438, 448 Sonic circle, 18, 19
potential, 36
Kutta-Joukovski, 81, 165, 275,332 subsonic, 301
supersonic, 301 Trapezoidal wing, 156
Vortex, 5, 71
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