Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Rotational and Cyclic Cycle Systems 聯 合 大 學 吳 順 良.

Published byTimothy Haynes Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Rotational and Cyclic Cycle Systems 聯 合 大 學 吳 順 良."— Presentation transcript:

1 1 Rotational and Cyclic Cycle Systems 聯 合 大 學 吳 順 良

2 2 Outline: Part 1: Cyclic m-cycle systems 1.1. Introduction 1.2 Known results 1.3. Essential tools 1.4 Constructions 1.5. Extension Part 2: 1-rotational m-cycle systems 2.1. Introduction 2.2 Known results 2.3. Essential tools 2.4 Constructions

3 3 Part 3: Resolvability 3.1. Introduction 3.2 Known results Part 4: Problems

4 4 An m-cycle, written (c 0, c 1, , c m-1 ), consists of m distinct vertices c 0, c 1, , c m-1, and m edges {c i, c i+1 }, 0  i  m – 2, and {c 0, c m-1 }. An m-cycle system of a graph G is a pair (V, C) where V is the vertex set of G and C is a collection of m-cycles whose edges partition the edges of G. If G is a complete graph on v vertices, it is known as an m- cycle system of order v. Part 1. Cyclic m-cycle systems 1.1. Introduction

5 5 The obvious necessary conditions for the existence of an m- cycle system of a graph G are: (1) The value of m is not exceeding the order of G; (2) m divides the number of edges in G; and (3) The degree of each vertex in G is even. For any edge {a, b} in G with V(G) = Z v, By  |a - b| we mean the difference of the edge {a, b}.

6 6 Example K 9 : V = Z 9 ±1 ±2 ±3 ±4 (0,1) (0,2) (0,3) (0,4) (1,2) (1,3) (1,4) (1,5) (2,3) (2,4) (2,5) (2,6) (3,4) (3,5) (3,6) (3,7) (4,5) (4,6) (4,7) (4,8) (5,6) (5,7) (5,8) (5,0) (6,7) (6,8) (6,0) (6,1) (7,8) (7,0) (7,1) (7,2) (8,0) (8,1) (8,2) (8,3)

7 7 Given an m-cycle system (V, C) of a graph G = (V, E) with |V| = v, let  be a permutation on V. For each cycle C = (c 0, , c m-1 ) in C and a permutation  on V, let C  = {(c 0 , , c m-1  )  C  C }. If C  = {C   C  C} = C, then  is said to be an automorphism of (V, C).

8 8 If there is an automorphism  of order v, then the m-cycle system is called cyclic. For a cyclic m-cycle system, the vertex set V can be identified with Z v. That is, the automorphism  can be represented by  : (0, 1, , v  1) or  : i  i + 1 (mod v) acting on the vertex set V = Z v.

9 9 An alternative definition: An m-cycle system (V, C) is said to be cyclic if V = Z v and we have C + 1 = (c 0 + 1, , c m-1 + 1) (mod v)  C whenever C  C. The set of distinct differences of edges in K v is Z v \ {0}.

10 10 Example. K 9 : V = Z 9 ±1 ±2 ±3 ±4 (0,1) (0,2) (0,3) (0,4) (1,2) (1,3) (1,4) (1,5) (2,3) (2,4) (2,5) (2,6) (3,4) (3,5) (3,6) (3,7) (4,5) (4,6) (4,7) (4,8) (5,6) (5,7) (5,8) (5,0) (6,7) (6,8) (6,0) (6,1) (7,8) (7,0) (7,1) (7,2) (8,0) (8,1) (8,2) (8,3)

11 11 Example. K 9 : (0, 1, 5, 2) (1, 2, 6, 3) (2, 3, 7, 4) (3, 4, 8, 5) (4, 5, 0, 6) (5, 6, 1, 7) (6, 7, 2, 8) (7, 8, 3, 0) (8, 0, 4, 1)

12 12 The cycle orbit of C is defined by the set of distinct cycles C + i = (c 0 + i, , c m-1 + i) (mod v) for i  Z v. The length of a cycle orbit is its cardinality, i.e., the minimum positive integer k such that C + k = C. A base cycle of a cycle orbit Ò is a cycle in Ò that is chosen arbitrarily. A cycle orbit with length v is said to be full, otherwise short.

13 13 Example. K 15 : V = Z 15 ±1 ±2 … ±7 (0, 1, 4) (0, 2, 8) (0, 5, 10) (1, 2, 5) (1, 3, 9) (1, 6, 11) (2, 3, 6) (2, 4,10) (2, 7, 12) (3, 8, 13) (4, 9, 14) (14, 0, 3) (14, 1, 7) m = 3

14 14 1.2. Known results (1) A cyclic 3-cycle system. (1938, Peltesohn) (2) For even m, there exists a cyclic m-cycle system of order 2km + 1. (1965 and 1966, Kotzig and Rosa) (3) Cyclic m-cycle systems where m = 3, 5, 7. (1966, Rosa) (4) For any integer m with m  3, there exists a cyclic m-cycle system of order 2km + 1. (2003, Buratti and Del Fra, Bryant, Gavlas and Ling, Fu and Wu)

15 15 (5) A cyclic m-cycle system of order 2km + m, where m is an odd integer with m  15 and m  p  where p is prime and  > 1. (2004, Buratti and Del Fra) (6) A cyclic m-cycle system of order 2km + m, where m is an odd integer with m = 15 and m = p .. (2004, Vietri)

16 16 Theorem For any integer m with m  3, there exists a cyclic m-cycle system of order 2km + 1. Theorem Given an odd integer m  3, there exists a cyclic m-cycle system of order 2km + m.

17 17 Note that the above theorems give a complete answer to the existence question for cyclic q-cycle systems with q a prime power. (7) Cyclic m-cycle systems where m = 6, 10, 12, 14, 15, 18, 20, 21, 22, 24, 26, 28, 30. (Fu and Wu) (8) For cyclic 2q-cycle systems with q a prime power. ( Fu and Wu)

18 18 1.3. Essential tools Spectrum: a set, Spec(m), of values of v for which the necessary conditions of an m-cycle system are met. Proposition If m = ab with a odd and gcd(a, b) = 1, then v = 2pm + ax 0, where p  0 and x 0 is the least positive integral solution of the linear congruence ax  1 (mod 2b) satisfying ax 0  m.

19 19 If m has n distinct odd prime factors, then |Spec(m)| = + + … + = 2 n. Example. m = 180 = 2 2  3 2  5 m = 1  180 x 0 = 361 v = 361 m = 3 2  (2 2  5) x 0 = 49 v = 441 m = 5  (3 2  2 2 ) x 0 = 101 v = 505 m = (3 2  5)  (2 2 ) x 0 = 5 v = 225 Spec(180) = {v  v  1, 81, 145, or 225 (mod 360)}

20 20 Skolem sequences and its generalization.  A Skolem sequence of order n is a collection of ordered pairs {(s i, t i ) | 1  i  n, t i  s i = i} with = {1, 2, , 2n}. Example. {(1, 2), (5, 7), (3, 6), (4, 8)}.

21 21  A hooked Skolem sequence of order n is a collection of ordered pairs {(s i, t i ) | 1  i  n, t i  s i = i} with = {1, 2, , 2n  1, 2n + 1}. Example. {(1, 2), (3, 5), (4, 7)}

22 22 Theorem (1) A Skolem sequence of order n exists if and only if n  0 or 1 (mod 4). (2) A hooked Skolem sequence of order n exists if and only if n  2 or 3 (mod 4).

23 23 How to construct a short m-cycle ?  The number of distinct differences in an m-cycle C is called the weight of C.  Given a positive integer m = pq, an m-cycle C in K v with weight p has index v/q if for each edge {s, t} in C, the edges {s + i  v/q, t + i  v/q } ( mod v) with i  Z q are also in C.

24 24 Example m = 15 = 5  3 and v = 75 The 15-cycle C = (0, 1, 5, 7, 12, 25, 26, 30, 32, 37, 50, 51, 55, 57, 62) in K 75 with weight 5 (differences  1,  2,  4,  5, and  13) has index 25.

25 25 Proposition Let m = pq. Then there exists an m-cycle C = (c 0, , c m-1 ) in K v with weight p and index v/q if and only if each of the following conditions is satisfied: (1) For 0  i  j  p  1, c i ≢ c j (mod v/q); (2) The differences of the edges {c i, c i-1 } (1  i  p) are all distinct; (3) c p  c 0 = t  v/q, where gcd (t, q) = 1; and (4) c ip+j = c j + i  t  v/q where 0  j  p  1 and 0  i  q  1.

26 26 Example. m = 15 = 5  3 and v = 75 The 15-cycle C = (0, 1, 5, 7, 12, 25, 26, 30, 32, 37, 50, 51, 55, 57, 62) = [0, 1, 5, 7, 12] 25 in K 75 with weight 5 (i.e.,  C =  {1, 2, 4, 5, 13}) has index 25, and the set {C, C + 1, , C + 24} forms a cycle orbit of C with length 25 in K 75.

27 27  Given a set D = {C 1, , C t } of m-cycles, the list of differences from D is defined as the union of the multisets  C 1, ,  C t, i.e.,  D =. Theorem A set D of m-cycles with vertices in Z v is a set of base cycles of a cyclic m-cycle system of K v if and only if  D = Z v \ {0}.

28 28 Example K 15 : V = Z 15 ±1 ±2 … ±7 m = 3 (0, 1, 4) (0, 2, 8) (0, 5, 10) (1, 2, 5) (1, 3, 9) (1, 6, 11) (2, 3, 6) (2, 4,10) (2, 7, 12) (3, 8, 13) (4, 9, 14) (14, 0, 3) (14, 1, 7)

29 29 1.4. Constructions ( 一 ) Odd cycles: Lemma Let a, b, c, and r be positive integers with c = a + b and r > c. Then there exists a cycle C of length 4s + 3 with the set of differences  {a, b, c, r, r + 1, , r + 4s - 1}.

30 30 Example. A 15-cycle with the set of differences  {1, 2, 3, 6, , 17} and a = 2, b = 1, c = 3, r = 6, and s = 3. 2 3 6810121416 1 17151311 9 7

31 31 Lemma Let a, b, c, and r be positive integers with c = a + b  1 and r > c. (1) There exists a cycle C of length 4s + 1 with the set of differences  {a, b, c, r, r + 1, , r + 4s - 3}. (2) There exists a cycle C of length 4s + 1 with the set of differences  {a, b, c, r, r + 1, r + 2k + 3, r + 2k + 4, , r + 2k + 4s - 2} where k  0.

32 32 Example. A 13-cycle with the set of differences  {1, 2, 4, 5, , 14} and a = 1, b = 2, c = 4, r = 5, and s = 3. 0 13-45-67 4 18616813 1 2791113 6 4 1412108 5

33 33 Example. m = 15 and v = 81. C 1 = [0, 21, 61, 25, 64] 27 C 2 = [0, 22, 60, 25, 33] 27  C 1   C 2 =  {6, 8, 21, 22, 35, …., 40} Z 81 - {0} - (  C 1   C 2 ) =  {1, 2, 3, 4, 5, 7, 9, …, 20, 23, …, 34}.

34 34 ( 二 ) Even cycles: Example. m = 18 and K 81. C 1 = [0, 10] 9 and C 2 = [0, 28] 9  C 1   C 2 =  {1, 10, 19, 28} C3:C3:

35 35 C4:C4:  C 3   C 4 =  {2, …, 9, 11,…, 18, 20, …, 27, 29, …, 40}  C 1   C 2 =  {1, 10, 19, 28} Z 81 – {0} =  C 1   C 2   C 3   C 4

36 36 1.5. Extension:  If v is even, then there does not exist a cyclic m-cycle system of K v.  K v - I, where I is a 1-factor.  Example. K 8 - I, where I = {(0, 4), (1, 5), (2, 6), (3, 7)}.  Cyclic 4-cycle system of K v – I.

37 37 Theorem (2003, Wu) Suppose that m 1, m 2, , m r are positive even (odd) integers with = 2 k for k  2. Then there exist cyclic (m 1, m 2, , m r )-cycle systems of K n if and only if n is odd and the value of divides the number of edges in K n. Theorem (2004, Fu and Wu) Suppose that = n. Then there exists a cyclic (m 1, m 2, , m r )-cycle system of order 2n + 1.

38 38 Part 2. 1-rotational m-cycle systems 2.1. Introduction K v is the graph on v vertices in which each pair of vertices is joined by exactly edges.

39 39 Given an m-cycle system of G with |V| = v, if there is an automorphism  of order v – 1 with a single fixed vertex, then the m-cycle system is said to be 1-rotatinal. For a 1- rotational m-cycle system, the vertex set V can be identified with {  }  Z v-1. That is, the automorphism  can be represented by  : (  ) (0, 1, , v  2) or  :   , i  i + 1 (mod v - 1) acting on the vertex set V.

40 40 An alternative definition: An m-cycle system (V, C) is said to be 1-rotational if V = {  }  Z v-1 and we have C + 1 = (c 0 + 1, , c m-1 + 1) (mod v - 1)  C whenever C  C.

41 41 Example. K 9 : V = {  }  Z 8 ±1 ±2 ±3 ±4 (0,1) (0,2) (0,3) (0,4) (1,2) (1,3) (1,4) (1,5) (2,3) (2,4) (2,5) (2,6) (3,4) (3,5) (3,6) (3,7) (4,5) (4,6) (4,7) (5,6) (5,7) (5,0) (6,7) (6,0) (6,1) (7,0) (7,1) (7,2)

42 42 Example. 2K 9 : V = {  }  Z 8 ±1 ±1 ±2 ±2 ±3 ±3 ±4 (0,1) (0,1) (0,2) (0,2) (0,3) (0,3) (0,4) (1,2) (1,2) (1,3) (1,3) (1,4) (1,4) (1,5) (2,3) (2,3) (2,4) (2,4) (2,5) (2,5) (2,6) (3,4) (3,4) (3,5) (3,5) (3,6) (3,6) (3,7) (4,5) (4,5) (4,6) (4,6) (4,7) (4,7) (0,4) (5,6) (5,6) (5,7) (5,7) (5,0) (5,0) (1,5) (6,7) (6,7) (6,0) (6,0) (6,1) (6,1) (2,6) (7,1) (7,0) (7,1) (7,1) (7,2) (7,2) (3,7)

43 43 2.2. Known results Theorem [2001, Phelps and Rosa] There exists a 1-rotational 3-cycle system of order v if and only if v  3 or 9 (mod 24).

44 44 Theorem [2004, Buratti] (1) A 1-rotational m-cycle system of K 2pm+1 exists if and only if m is an odd composite number. (2) A 1-rotational m-cycle system of K 2pm+m exists if and only if m is odd with the only definite exceptions: (m, p) = (3, 4t + 2) and (m, p) = (3, 4t + 3).

45 45 Theorem [2003, Mishima and Fu] If v  0 (mod 2k), then there exists a 1-rotational k-cycle system of K v. Theorem [Wu and Fu] Let q be a prime power and let k be an integer with k = 0 or 1. Then there exist 1-rotational 2 k q-cycle systems of 2K v if and only if 2 k q divides the number of edges in 2K v.

46 46 2.3. Essential tools Proposition If m = ab with gcd(a, b) = 1, then v = pm + ax 0, where p  0 and x 0 is the least positive integral solution of the linear congruence ax  1 (mod b) satisfying ax 0  m. Given a positive integer m, what is Spec(m) for 2K v ?

47 47 Proposition [2003, Buratti] Let d i (1  i  m  2) be distinct positive integers with d 1 < d 2 <  < d m-2. Then there exists an m-cycle containing  with difference set  { , , d 1, d 2, , d m-2 }. Proof. Let C m be a full m-cycle defined as C m = ( , 0, a 1, a 2, , a m-2 ), where a i =.

48 48 Example. Set m = 10 and 1 < 2 < 4 < 5 < 8 < 10 < 12 < 15. Taking -1, 2, -4, 5, -8, 10, -12, 15, C 10 = ( , 0, -1, 1, -3, 2, -6, 4, -8, 7).

49 49 A Skolem sequence of order n is an integer sequence (s 1, s 2, , s n ) such that = {1, 2, , 2n}. Example. n = 4. {s 1, s 2, s 3, s 4 } = {1, 5, 3, 4}.

50 50 A hooked Skolem sequence of order n is an integer sequence (s 1, s 2, , s n ) such that = {1, 2, , 2n  1, 2n + 1}. Example. n = 2. {s 1, s 2 } = {1, 3}.

51 51 2.4. Constructions Example. m = 7 and 2K 21. {s 1, s 2 } = {1, 3}. C 1 = (0, -1, 1, -5, 6, -7, 8) C 2 = (0, -3, 2, -5, 7, -7, 9)  C 1   C 2 =  {1, 2, 3, 4, 5, 5, 6, 6, 7, 7, 8, 8, 9, 9} Z 20 – {0} – (  C 1   C 2 ) =  {1, 2, 3, 4, 10} C 3 = ( , 0, -1, 1, -2, 2, -8)

52 52 Example. m = 10 and 2K 25 C 1 = [0, 5, 1, 4, 2] 12 C 2 = (0, -1, 1, -2, 2, -4, 3, -5, 4, 5)  C 1   C 2 =  {1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 7, 8, 9, 10} Z 24 – {0} – (  C 1   C 2 ) =  {6, 7, …., 13}.

53 53 Example. 2K 8 :  1  1  2  2  3  3  4 (0, 4, 6, 2) (0, 2, 4, 6) (0, 1, 4, 5) (0, 1, 4, 5) (1, 5, 7, 3) (1, 3, 5, 7) (2, 3, 6, 7) (2, 3, 6, 7) (2, 6, 0, 4) (1, 2, 5, 6) (1, 2, 5, 6) (3, 7, 1, 5) (3, 4, 7, 0) (3, 4, 7, 0)

54 54 Part 3. Resolvability 3.1. Introduction A parallel class of an m-cycle system (V, C) of a graph G is a collection of t (= v/m) vertex disjoint m-cycles in C. The m-cycle system is called resolvable if C can be partitioned into parallel classes R 1, , R s such that every vertex of V is contained in exactly one m-cycle of each class.

55 55 The set R = {R 1, , R s } is called a resolution of the system. A cyclic (1-rotational) m-cycle system is called cyclically (1-rotationally) resolvable if it has a resolution.

56 56 Example. m = 4 and 2K 28 R 1 : (0,12,25,11) (1,9,2,10) (3,7,4,8) (5,15,6,16) (17,23,18,24) (19,21,20,22) ( ,13,14,26) R 2 : (1,13,26,12) (2,10,3,11) (4,8,5,9) (6,16,7,17) (18,24,19,25) (20,22,21,23) ( ,14,15,27) R 27 : (26,11,24,10) (0,8,1,9) (2,6,3,7) (4,14,5,15) (16,22,17,23) (18,20,19,21) ( ,12,13,25)

57 57 3.2. Known results  For m even, 1-rotationally resolvable m-cycle systems of K v. (2003, Mishima and Fu)  A cyclically resolvable 4-cycle system of the complete multipartite graph. (Wu and Fu)  A cyclically resolvable 4-cycle system of K v.

58 58 Part 4. Problems Problem 1: For all even integers m, there exist 1-rotational m-cycle systems of 2K v. Problem 2: For all odd integers m, there exist 1-rotational m-cycle systems of 2K v.

59 59 Problem 3: For all even integers m, there exist cyclic m-cycle systems of K v. Problem 4: For all odd integers m, there exist cyclic m-cycle systems of K v.

60 60 Thanks!

Download ppt "1 Rotational and Cyclic Cycle Systems 聯 合 大 學 吳 順 良."

Similar presentations

Connectivity - Menger’s Theorem Graphs & Algorithms Lecture 3.

Connectivity - Menger’s Theorem Graphs & Algorithms Lecture 3.
Chun-Cheng Chen Department of Mathematics National Central University 1.

Chun-Cheng Chen Department of Mathematics National Central University 1.
Lecture 5 Graph Theory. Graphs Graphs are the most useful model with computer science such as logical design, formal languages, communication network,

Lecture 5 Graph Theory. Graphs Graphs are the most useful model with computer science such as logical design, formal languages, communication network,
Edge-connectivity and super edge-connectivity of P 2 -path graphs Camino Balbuena, Daniela Ferrero Discrete Mathematics 269 (2003) 13 – 20.

Edge-connectivity and super edge-connectivity of P 2 -path graphs Camino Balbuena, Daniela Ferrero Discrete Mathematics 269 (2003) 13 – 20.
Walks, Paths and Circuits Walks, Paths and Circuits Sanjay Jain, Lecturer, School of Computing.

Walks, Paths and Circuits Walks, Paths and Circuits Sanjay Jain, Lecturer, School of Computing.
Graph-02.

Graph-02.
Recursive Definitions and Structural Induction

Recursive Definitions and Structural Induction
A Separator Theorem for Graphs with an Excluded Minor and its Applications Paul Seymour Noga Alon Robin Thomas Lecturer : Daniel Motil.

A Separator Theorem for Graphs with an Excluded Minor and its Applications Paul Seymour Noga Alon Robin Thomas Lecturer : Daniel Motil.
1 NP-completeness Lecture 2: Jan 11. 2 P The class of problems that can be solved in polynomial time. e.g. gcd, shortest path, prime, etc. There are many.

1 NP-completeness Lecture 2: Jan P The class of problems that can be solved in polynomial time. e.g. gcd, shortest path, prime, etc. There are many.
Applications of Euler’s Formula for Graphs Hannah Stevens.

Applications of Euler’s Formula for Graphs Hannah Stevens.
Some Graph Problems. LINIAL’S CONJECTURE Backgound: In a partially ordered set we have Dilworth’s Theorem; The largest size of an independent set (completely.

Some Graph Problems. LINIAL’S CONJECTURE Backgound: In a partially ordered set we have Dilworth’s Theorem; The largest size of an independent set (completely.
Chapter 3 Relations. Section 3.1 Relations and Digraphs.

Chapter 3 Relations. Section 3.1 Relations and Digraphs.
 Graph Graph  Types of Graphs Types of Graphs  Data Structures to Store Graphs Data Structures to Store Graphs  Graph Definitions Graph Definitions.

 Graph Graph  Types of Graphs Types of Graphs  Data Structures to Store Graphs Data Structures to Store Graphs  Graph Definitions Graph Definitions.
Representing Relations Using Matrices

Representing Relations Using Matrices
The number of edge-disjoint transitive triples in a tournament.

The number of edge-disjoint transitive triples in a tournament.
2k-Cycle Free Bipartite Graph Steven Wu. What is a bipartite graph?

2k-Cycle Free Bipartite Graph Steven Wu. What is a bipartite graph?
Definition 7.2.1 Hamiltonian graph: A graph with a spanning cycle (also called a Hamiltonian cycle). Hamiltonian graph Hamiltonian cycle.

Definition Hamiltonian graph: A graph with a spanning cycle (also called a Hamiltonian cycle). Hamiltonian graph Hamiltonian cycle.
Definition Dual Graph G* of a Plane Graph:

Definition Dual Graph G* of a Plane Graph:
Small Cycle Systems Chris Rodger Auburn University.

Small Cycle Systems Chris Rodger Auburn University.
CTIS 154 Discrete Mathematics II1 8.2 Paths and Cycles Kadir A. Peker.

CTIS 154 Discrete Mathematics II1 8.2 Paths and Cycles Kadir A. Peker.

Similar presentations

Ads by Google