4-cycle Designs

1. 4-cycle Designs Hung-Lin Fu (傅恆霖) 國立交通大學應用數學系

2. Motivation • The study of graph decomposition has been one of the most important topics in graph theory and also play an important role in the study of the combinatorics of experimental designs (combinatorial designs). • Graph theorist can obtain more applications in combinatorial designs than graph decomposition its own.

3. Preliminaries • A graph G is an ordered pair (V,E) where V the vertex set is a nonempty set and E the edge set is a collection of subsets of V. In the collection E, a subet (an edge) is allowed to occur many times, such edges are called multi-edges. • A complete simple graph on v vertices denoted by Kv is the graph (V,E) where E contains all the 2-element subsets of V. Hence, Kvhas v(v-1)/2 edges. • We shall use Kv to denote the complete multi-graph with multiplicity  , i.e. each edge occurs  times.

4. Graph Decomposition • We say a graph G is decomposed into graphs in H if the edge set of G, E(G), can be partitioned into subsets such that each subset induces a graph in H. For simplicity, we say that G has an H-decomposition. If H = {H}, then G has an H-decomposition or an H-design. We shall focus on H a 4-cycle.

5. Balanced Incomplete Block Designs (BIBD) • A BIBD or a 2-(v,k,) design is an ordered pair (X,B) where X is a v-set and B is a collection of k-element subsets (blocks) of X such each pair of elements of X occur together in exactly  blocks of B.

6. A Famous Example ! • The existence of an STS(v) is equivalent to the existence of a K3-decomposition of Kv, i.e. decomposing Kv into triangles.

7. More General • The existence of a 2-(v,k,) design can be obtained by finding a Kk-decomposition of Kv. • Example: 2K4 can be decomposed into 4 triangles (1,2,3), (1,2,4), (1,3,4) and (2,3,4). • A 2-(4,3,2) design exists and its blocks are: {1,2,3}, {1,2,4}, {1,3,4} and {2,3,4}.

8. Cycle Systems • A cycle is a connected 2-regular graph. We use Ck to denote a cycle with k vertices and therefore Ck has k edges. • If G can be decomposed into Ck’s, then we say G has a k-cycle design and denote it by Ck | G. • If Ck | Kv, then we say a k-cycle system of order v exists. • A 3-cycle system of order v is in fact a Steiner triple system of order v.

9. Necessary conditions • If G has a K3-decomposition, then the graph must have 3t edges for some t and each vertex is of even degree (even graph). • Definition (x-sufficient): A graph G is said to be x-sufficient if x | |E(G)| and G is an even graph. • If G has a K3-decomposition, then G is 3-sufficient. • If G has a decomposition into k-cycles, then G is k-sufficient !

10. Known Results • Ck | Kv if and only if Kv is k-sufficient. • Let v be even and I is a 1-factor of Kv. Then Ck | Kv – I if and only if Kv – I is k-sufficient. • After more than 40 years effort, the above two theorems have been proved following the combining results of B. Alspach et al. (2001, JCT(B)

11. A 4-cycle design of the complete graph of order v is also known as a 4-cycle system of order v. Example : v = 9. (0,1,5,3), (1,2,6,4), … . 4-cycle Designs

12. Group Divisible Designs • A graph G is a complete m-partite graph if V(G) can be partitioned into m partite sets such that E(G) contains all the edges uv where u and v are from different partite sets. If the partite sets of G are of size n1, n2, …, nm, then the graph is denoted by K(n1,n2,…,nm). In case that all partite sets are of the same size n, then we have a balanced complete m-partite graphs denoted by Km(n). • A Kk-decomposition of Km(n) is a k-GDD and a -fold k-GDD can be defined accordingly.(See it?)

13. A Beautiful 4-cycle Design A 4-cycle design of the complete multipartite graph G exists if and only if G is 4-sufficient. In fact, finding the maximum packing with maximum number of 4-cycles in the complete multipartite graph is also possible. (Billington, Fu, and Rodger, JCD 9)

14. H Kv – H Problem For which H Kv – H has a 4-cycle decomposition?

15. Kv – H H How about this kind of H when |V(H)|  v ?

16. Nash-Williams Conjecture(1970) Let G be a 3-sufficient graph of order n and the minimum degree of G is not less than 3n/4. Then G has a K3-decomposition for sufficiently large n. Why 3n/4? ((H) < n/4 where G = Kn – H.)

17. Example: A graph G of order 24m+12 and valency 18m+8. O6m+3 • O6m+3 G can not be decomposed into K3’s. K6m+3,6m+3 Gc = • O6m+3 • O6m+3

18. Known Results • Theorem(C. Colbourn and A. Rosa, 1986) Let H be a 2-regular subgraph of Kv such that v is an odd integer not equal to 9 and v(v-1)/2 - |E(H)| is a multiple of 3. Then Kv – H has a K3-decomposition. Note: We can also consider the above theorem as packing Kv with K3’s such that the leave is H. Let H = C4 C5. Then K9 – H can not be decomposed into K3’s. (See it?)

19. Continued … • Theorem(Gustavsson, Ph.D. thesis 1991) Nash-Williams’ conjecture holds for the graphs which are 3-sufficient and minimum degree not less than (1 – 10-24)n. Note : I am not able to locate the reference of this result at this moment, the proof is very difficult to check. P.S. 這個問題應該有進展的空間.

20. Problems • Let v be an even integer and H be an odd spanning forest of Kv such that Kv – H is 3-sufficient. Then Kv – H has a K3-decomposition. (我最想解決的問題.) • Let v be an even integer and H be an odd spanning subgraph of Kv such that (H) is at most 3 and Kv – H is 3-sufficient. Then Kv – H has a K3-decomposition.

21. More 4-cycle Designs • Let H be a 2-regular subgraph of Kv where v is odd. Then Kv – H has a C4-decomposition if and only if v(v-1)/2 - |E(H)| is a multiple of 4 (Kv – H is 4-sufficient). (Fu and Rodger, GC 2001) • Surprisingly: If H is a spanning forest of Kv where v is even, then Kv – H has a C4-decomposition iff Kv – H is 4-sufficient. (Fu and Rodger, JGT 2000)

22. Continued … • Let H be an odd graph with (H) not greater than 3. Then Kv – H has a C4-decomposition if and only if Kv – H is 4-sufficient except two special cases when v = 8. (C.M. Fu, Fu, Rodger and Smith, DM 2004) • Conjecture(Fu) Let H be a subgraph of Kv with (H) < v/4 and 3  k  v. Then Kv – H has a Ck-decomposition if and only if Kv – H is k-sufficient. Why v/4?

23. An example for k = 4 K8 – H can not be decomposed into 4-cycles. H :

24. Another Evidence • Let H be a 2-regular subgraph of Kv. Then Kv – H has a C6-decomposition if and only if Kv – H is 6-sufficient. (Ashe, Fu and Rodger, Ars Combin.) • Let H be a spanning odd forest of Kv where v is even. Then Kv – H has a C6-decomposition if and only if Kv – H is 6-sufficient. (Ashe, Fu and Rodger, DM 2004)

25. Pentagon Designs • Compare to 4-cycle systems or 3-cycle systems, the study of 5-cycle systems is harder. • It takes a long while to find the necessary and sufficient conditions to decompose a complete 3-partite graph into C5’s. (Billington et al.) Problem: Let H be a 2-regular subgraph of Kv such that v is and odd integer, v  5 and v(v-1)/2 - |E(H)| is a multiple of 5. Then Kv – H has a C5-decomposition. (Kv – H is 5-sufficient.)

26. How many 4-cycles in a graph? • If we have a 4-cycle design of G, then we have a bunch of 4-cycles in G. • Even if G does not have a 4-cycle design, G many have some 4-cycles in there. • So, it is interesting to know for which G with size e(G) as large as possible and G contains no 4-cycles !

27. Extremal Graphs • Fixed the number of vertices “n”. A graph G of order n with maximum number of edges such that G contains no subgraph H is an extremal graph with forbidden graph H. • If H is 3-cycle, then the extremal graph is the “balanced” complete bipartite graph of order n. If H is the complete graph of order k+1, then the extremal graph is the “balanced” complete k-partite graph of order n. For example, if n = 20 and k is 6, then the graph is K(4,4,3,3,3,3).

28. Tougher Case : 4-cycle • Let ex(n,H) denote the size of an extremal graph with forbidden graph H. • If H is a 3-cycle, then ex(n,H) is about n2/4. • If H = Kr,r, then ex(n,H) is about cn 2 – 1/r where c is a suitable constant (who knows?) • Now, how about r = 2?

29. Partial Results • Let q be a prime power. Then ex(n,C4) is equal to n(1 + (4n-3)1/2)/4 where n = q2 + q + 1. (From the existence of a projective plane of order q.) • How about the cases n is not of this form?

30. Zarankiewicz Problem • Let G2(m,n) denote the set of all bipartite graphs with partite sets A and B such that |A| = m and |B| = n. • Let z(m,n;s,t) denote the maximum size of graphs in G2(m,n) which contains no subgraph Ks,t. • Can we solve the case when s = t = 2?

31. C4 – Saturated Graphs • A graph G is C4 – saturated if any proper supergraph defined on V(G) contains a 4-cycle, i.e. adding any edge to G creates a 4-cycle. • C5 is C4 – saturated. • Km,n contains a C4 – saturated subgraph of size m+n-1. • We need a C4 – saturated graph of maximum size!

32. Partial 2-Designs • A partial 2-design is a pair (X,B) where X is a nonempty finite set and B is a collection of subsets(blocks) of X such that each pair of two distinct elements occur together in at most one block in B. • Let m  n. Then a C4 – saturated subgraph of Km,n corresponds to a partial 2-design. (?)

33. z(n,n;2,2) • Theorem(Reiman,1958) z(n,n;2,2) is not greater than n[1+(4n-3)1/2]/2 and the equality holds if n = q2 + q + 1 where q is a prime power. • The projective plane of order q corresponds to an extremal graph. See it? • ProblemIs this the only situation that we have the equality? (n)

34. z(m,n;2,2) • Theorem (Bryant and Fu) Let (X,B) be a partial 2-design such that |X| = n and B = {B1, B2, . . ., Bm}. Then the corresponding graph of (X,B) is a C4 – saturated subgraph of Km,n with maximum size if the blocks in B contain either k or k+1 elements and

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