Cybernetics and Systems Analysis, Vol. 36, No. 4, 2000
3-QUASIPERIODIC
FUNCTIONS
ON GRAPHS
AND
HYPERGRAPHS
UDC 519...
6 downloads
925 Views
250KB Size
Report
This content was uploaded by our users and we assume good faith they have the permission to share this book. If you own the copyright to this book and it is wrongfully on our website, we offer a simple DMCA procedure to remove your content from our site. Start by pressing the button below!
Report copyright / DMCA form
Cybernetics and Systems Analysis, Vol. 36, No. 4, 2000
3-QUASIPERIODIC
FUNCTIONS
ON GRAPHS
AND
HYPERGRAPHS
UDC 519.1
O. G. Rudenskaya
Sets of solutions of the equation f (x) - f (y) = k in N -~ are described, where f is a 3-quasiperiodic and strictly monotone function in N. The descriptions are used in studying the coarseness of a complete bipartite graph.
Keywords: quasiperiodic functions, 3-quasiperiodic functions on graphs and hypergraphs, complete bipartite graph, coarseness of complete bipartite graphs, solution of equations with 3-quasiperiodic functions.
Many problems of discrete programming, combinatorics, and automaton theory are reduced to the study of coarseness of a complete bipartite graph Km, n [1 ], the achromatic and pseudoachromatic number of a graph [2], the chromatic number of the partial hypergraph generated by the set of nodes of the clique of rank 4 [3], the greatest cardinality of matching in a hypergraph [3], and a number of other characteristics of graphs [4] and hypergraphs. For their description, a class, of functions can be selected that have the property described by the definition given below. We call a function f (x) specified on a set D 3-quasiperiodic in D if (3 T)(V x ~ D ) ' [ x + 3~ D ~
f (x + 3) = f (x) + T].
T H E O R E M . The set of all discrete functions 3-quasiperiodic in N 0 can be given by the formula
f(n)=an+b(-l)
Lql 7
I
+c(-1)
Lq,,+21
+d(-1)
3
,
(1)
where a, b, c, d ~ R and q - 2 or 4 (mod 6) (in this case, T = 3a). For q - 2 (mod 6), we have a = [ f (3) - f (0)] / 3, c = [ f (3) - f (2) - f (1) - f (0)] / 2,
(2)
b =[ - f (3) + 3 f (1) + 4 f (0)] / 6, d =[ - 2 f (3) + 3 f (2) + 5 f (0)] / 6, and, for q - 4 ( m o d
6), we have (2) and b =[ - 2 f (3) + 3 f (2) + 5 f (0)] / 6, d = [ - f (3) + 3 f (1) + 4 f (0)] / 6.
r'!
As is easily verified, the relation f (n + 3) = f (n) + 3a is satisfied for function (1) and T = 3a in this case. On the other hand, if four values f (0), f (1), f (2), and f (3) are known for a function f (n) 3-quasiperiodic in N 0, then, for any q - 2 or q - 4(mod 6), the coefficients of representation (1) are found from the system that is obtained as the result of successive substitution of n = 0,1, 2, 3 in (1). 9 When T = 0 (a special case of 3-periodic functions), we have f ( 3 ) = f (0). Example 1. Since any constant is a 3-quasiperiodic function, the following identity is valid in N 0 when q is even: 1 -(-1)
-(-1)
Lq+lJ 3
+(-1)
l
3
.
9
i n N -, "~ we consider the equation f ( x ) - f ( y ) = k,
(3)
Cybernetics Institute, National Academy of Sciences of Ukraine, Kiev, Ukraine. Translated from Kibernetika i Sistemnyi Analiz, No. 4, pp. 165-168, July-August, 2000. Original article submitted April 5, 1999.
614
1060-0396/00/3604-0614525.00 02000 Kluwer Academic/Plenum Publishers
1 0
1
3
x
Fig. 1
where f is an increasing function 3-quasiperiodic in N O and k > 0. When the function decreases, we pass to the equivalent equation with the increasing function ( - f ) by multiplying both sides of the equation by (-1). When k < 0, we pass to the equation f ( x ) - f ( y ) = - k whose solutions are symmetric about the solutions of (3) with respect to the straight line y = x. Let h be the greatest solution in N O of the inequality f (1 + 3n) - f (1) < k; I L l
in this case, h = ] - ~ [ . [_ I
]
Based on the definition of an increasing 3-quasiperiodic function f , we compile in Table 1 descriptions of the set M of all solutions of Eq. (3) depending on whether the points M0(1,1) and
(4)
M3(i_l)+j(i+ j , ] ) ,
where i = 1 , 2 , j = 1 , 2 , 3 (Fig. 1), are the solutions of the equation
f ( x ) - f (y)=k-Th. We reduce the possible nineteen cases to the eight rows of Table 1. Example 2. For the coarseness ~ (K3r + 2, 3s) of a complete bipartite graph
(5)
K3r +2, 3s when r > 1, we describe the set
P of all positive values of the partial increment A s~ and, for each value, the corresponding increments zXs and arguments s assuming these values. According to (1), the coarseness
In this case, P is the set of all k ~ N for which the equation
~(r, s + As) - ~ ( r , s) = k
(6)
with the unknowns As and s is solvable in N 2. We consider (6) as an equation of the form (3), where x = s + AS, y = s, and f (n) = ~(r, n) is an increasing function" 3-quasiperiodic in N 0 with T = 3r + 1. We rewrite (6) as
(7)
Let M be the set of all its solutions. Then P is the set of all k a N ' M ~: QS. According to Table 1, M ~: ~5 r some points of (4) are solutions of the comparison k - F (x, y)(mod 3r + 1).
(8)
According to (7), we have
615
TABLE 1 The set of all solutions of Eq. (5) for points (4)
No.
(1,1)
The set M of points from NO (for r = h + p , p=0,1 .... ) The points of the straight line y = x - 3h
(i+j,j)
(i+ j + 3r, j + 3p)
(i+j,j), (i+j+l.j+l): j ~ 3
(i+j+3r, j+3p), (i+j+l+3r, j+l+3p): j ~ 3
(i+1,1), (i+2,2), (i+3, 3)
The points of the straight line y = x - 3 h - i
(i+1,1), (i+ 3,3)
(i + 1+ 3r, 1+ 3p), (i + 3 + 3r, 3 + 3p)
(i+l,i), (i+ 3, i+1)
(i+l+3r, i+3p), (i+3+3r, i+l+3p)
(3.1),(4,3)
(3 + 3r, 1+ 3p). (4+ 3r, 3 + 3p)
TABLE 2 No.
As ~=k
s (for p =0. I, ~ ...)
As
p(p~:O)
k -=0 (mod 3r + 1)
3
k =r(mod 3r+1)
k=-r + l(mod 3r + 1) r>l
l+l
3p+l or 3 p + 3
3 w k +1 3r+l
3p+2 3p+2
4
k - 2 (mod 4) 3p+3 k-
2r (mod 3r + 1)
r>l 6
k -=2r + 1(mod 3r + 1)
F (M0)=F
k 3-~-~
+2
3p+3
3
+:
3p+l or 3 p + 2
(1,1)=0,
F ( m 1) = F (2,1) = F (M 3 ) = F (4, 3) = r, F (M2)=F
(9)
(3, 2 ) = r + 1,
F ( M 4 ) = F (3,1) - F ( M s ) = F ( 4 , 2 ) = 2 r
+ 1,
F (M 6) = F (5, 3) = 2r. On the basis of (9), we note six cases of solvability of (8) for an r ~ N. Their representation in Table 2 gives all the sought-for values of A s~; the corresponding values of As and s are described on the basis of (9) and items 1, 5, 2, 6, and 3 of Table 1. REFERENCES
1. 2. 3. 4.
616
F. Harary, Graph Theory [Russian translation], Mir, M o s c o w (1973). G. Chartrand and J. Mitchum, "Graphical theorems of N o r d h a u s and G a d d u m , " in: Theory of Graphs: Coverings, Packings, and Tournaments [Russian translation], Mir, M o s c o w (1974), pp. 204-211. C. Berge, Graphes et Hypergraphes, Dunod, Paris (1970). V . E . Alekseyev, "Hereditary classes and coding of graphs " in: Probl. Ki bem. , No. 39, Nauka, M o s c o w (1982), pp. 151-164.