The domination number of round digraphs

Xinhong Zhang; Caijuan Xue; Ruijuan Li

doi:10.1515/math-2020-0084

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The domination number of round digraphs

Xinhong Zhang , Caijuan Xue and Ruijuan Li

Published/Copyright: December 30, 2020

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$Open Mathematics$

From the journal Open Mathematics Volume 18 Issue 1

Abstract

The concept of the domination number plays an important role in both theory and applications of digraphs. Let D = ( V , A ) be a digraph. A vertex subset T ⊆ V ( D ) is called a dominating set of D, if there is a vertex t ∈ T such that t v ∈ A ( D ) for every vertex v ∈ V ( D ) \ T . The dominating number of D is the cardinality of a smallest dominating set of D, denoted by γ ( D ) . In this paper, the domination number of round digraphs is characterized completely.

Keywords: domination number; round digraph; local tournament; purely local tournament

MSC 2010: 05C69

1 Introduction

The domination theory of graphs was derived from a board game in ancient India. In 1962, Ore formally gave the definitions of the dominating set and the domination number in [1]. Due to the universality of its applications to both theoretical and practical problems, domination has become one of the important research topics in graph theory. A summary of most important results and applications can be found in [2]. Problems of resource allocations and scheduling in networks are frequently formulated as domination problems on underlying graphs (digraphs). By contrast, domination in digraphs has not yet gained the same amount of attention, although it has several useful applications as well. For example, it has been used in the study of answering skyline query in the database [3] and routing problems in networks [4]. The relationship among domination numbers of different orientations of a graph was studied in [5]. The relevant results about domination numbers of digraphs can be found in [6–10]. Recent studies on domination theory include [11–13].

We refer the reader to [14] for terminology and notation not defined in this paper. Let D = ( V , A ) be a digraph, which means that V and A represent the vertex set and the arc set of D, respectively. The order of D is the number of vertices in D, denoted by | V ( D ) | . If uv is an arc, then we say that u dominates v (or v is dominated by u) and use the notation u → v to denote this. For a vertex v of a digraph D, we define the vertex set N D + ( v ) = { u ∈ V \ { v } | v u ∈ A } , N D − ( v ) = { w ∈ V \ { v } | w v ∈ A } . We also call the vertex set N D + ( v ) , N D − ( v ) and the vertex set N D + ( v ) ∪ N D − ( v ) the out-neighbourhood, the in-neighbourhood and the neighbourhood of the vertex v, respectively. d D + ( v ) is the number of all arcs with tail v, and we call d D + ( v ) the out-degree of v . d D − ( v ) is the number of all arcs with head v, and we call d D − ( v ) the in-degree of v. If each arc of A ( D ) with both end-vertices in V ( H ) is in A ( H ) , we say that H is induced by X = V ( H ) and denote it by H = D 〈 X 〉 . We call H an induced subdigraph of D.

Let D be a digraph. Let v 1 , v 2 , … , v n be a vertex labelling of D. If there is always i < j for every arc v i v j in D, then we often refer to the vertex labelling as an acyclic ordering of D. A walk in D is an alternating sequence W = v 1 a 1 v 2 a 2 v 3 … v k − 1 a k − 1 v k of vertices v i and arcs a j from D such that the tail of a i is v i and the head of a i is v i + 1 for every i = 1 , 2 , … , k − 1 . A walk W is closed if v 1 = v k , and open otherwise. The set of vertices { v 1 , v 2 , … , v k } is denoted by V ( W ) ; the set of arcs { a 1 , a 2 , … , a k − 1 } is denoted by A ( W ) . If the vertices of W are distinct, W is a path. If the vertices v 1 , v 2 , … , v k − 1 are distinct, k ≥ 3 and v 1 = v k , W is a cycle. A walk (path, cycle) W is a Hamiltonian walk (path,cycle) if V ( W ) = V ( D ) . The digraph D is strongly connected (or strong) if, for each pair u and v of distinct vertices in D, there is a ( u , v ) -walk and a ( v , u ) -walk.

A semicomplete digraph is a digraph in which every pair of distinct vertices is adjacent. A tournament is a semicomplete digraph with no cycle of length two. A digraph D is locally in-semicomplete (out-semicomplete) if, for every vertex x of D, the in-neighbours (out-neighbours) of x induce a semicomplete digraph. A digraph D is locally semicomplete if it is both locally in-semicomplete and locally out-semicomplete. A locally semicomplete digraph with no 2-cycle is a local tournament. If a digraph is a locally semicomplete digraph (local tournament) but not a semicomplete digraph (tournament), then the digraph is a purely local semicomplete digraph (purely local tournament). Related surveys about the locally semicomplete digraphs can be found in [15,16].

A digraph on n vertices is round if we can label its vertices v 1 , v 2 , … , v n so that for each i, we have N D + ( v i ) = { v i + 1 , … , v i + d + ( v i ) } and N D − ( v i ) = { v i − d − ( v i ) , … , v i − 1 } (all subscripts are taken modulo n). Let D = ( V , A ) be a digraph, and let T be a subset of the vertices of D. If for every vertex v ∈ V ( D ) \ T , there is a vertex t ∈ T such that t v ∈ A ( D ) , then we say that T is a dominating set of D and denote it by T → D . The dominating number of D is the cardinality of a smallest dominating set of D, denoted by γ ( D ) .

We need the following lemma and theorem in order to prove the main theorems.

Lemma 1.1

[17] Every round digraph is locally semicomplete.

Theorem 1.2

[18] Let D be a strong tournament on n ≥ 3 vertices. For every x ∈ V ( T ) and every integer k ∈ { 3 , 4 , … , n } , there exists a k-cycle through x in D. In particular, a tournament is Hamiltonian if and only if it is strong.

In this paper, the domination number of a round digraph is characterized by studying the round local tournament and the round non-local tournament, respectively.

2 The domination number of a round local tournament

2.1 The domination number of a round purely local tournament which is non-strong

Let D be a round purely local tournament which is non-strong. Let P n = v 0 v 1 … v n − 1 be a directed path of D. If there is an arc v i v j ∈ A ( D ) satisfying | j − i | ≥ 2 for i , j ∈ { 0 , 1 , … , n − 1 } , then the arc v i v j is called a cross arc on P n . If there is no cross arc v i α v j α on P n such that i α < i < j < j α , then the cross arc v i v j is called a maximal cross arc on P n . We call the vertex set { v i , v i + 1 , … , v j } covered by the maximal cross arc v i v j . We call the set G a maximal cross-arc chain on P n , if there is a maximal cross-arc set G = { v i t v j t | v i t v j t } is a maximal cross arc on P n , t ∈ { 0 , 1 , … , k − 1 } } on P n satisfying one of the following conditions:

For k = 1 ,
1. v i 0 v j 0 is a maximal cross arc on P n and there is no set { α , α ′ , β , β ′ } ⊆ { 0 , 1 , … , n − 1 } such that α < i 0 < α ′ and β < j 0 < β ′ , where v α v α ′ , v β v β ′ are two cross arcs on P n ; or
2. v i 0 v j 0 is a maximal cross arc on P n . There is a maximal cross arc v γ v γ ′ on P n such that γ < i 0 < γ ′ (or γ < j 0 < γ ′ ) and i 0 − γ = 1 (or γ ′ − j 0 = 1 ), and there is no cross arc v τ v τ ′ such that τ < i 0 < τ ′ and i 0 − τ ≥ 2 (or τ < j 0 < τ ′ and τ ′ − j 0 ≥ 2 ) (Figure 1(a)).
For k ≥ 2 ,
1. | i 1 − i 0 | > 1 and | j k − 1 − j k − 2 | > 1 , and when i 0 ≠ 0 ( j k − 1 ≠ n − 1 ) , there is at most one vertex v i 0 − 1 ( v j k − 1 + 1 ) such that v i 0 − 1 v β ( v β v j k − 1 + 1 ) is a cross arc on P n , where i 0 < β ( β < j k − 1 ) ;
2. i t < i t + 1 ≤ j t < j t + 1 , t ∈ { 0 , 1 , … , k − 2 } ; and
3. There is no maximal cross arc v i γ v j γ on P n such that i t + 1 < i γ ≤ j t < j t + 1 < j γ for t ∈ { 0 , 1 , … , k − 2 } (Figure 1(b)).

$Figure 1 (a) k = 1 k=1 : G 1 = { v i 0 v j 0 } , G 2 = { v i 2 v j 2 } {G}_{1}=\{{v}_{{i}_{0}}{v}_{{j}_{0}}\},{G}_{2}=\{{v}_{{i}_{2}}{v}_{{j}_{2}}\} are two maximal cross-arc chains on P = v 0 v 1 … v 16 P={v}_{0}{v}_{1}\ldots {v}_{16} . P 1 = v 0 v 1 , P 2 = v 6 v 7 v 8 , P 3 = v 15 v 16 {P}_{1}={v}_{0}{v}_{1},{P}_{2}={v}_{6}{v}_{7}{v}_{8},{P}_{3}={v}_{15}{v}_{16} are all maximal pure subpaths on P; (b) k ≥ 2 k\ge 2 : v 2 v 7 , v 4 v 8 , v 6 v 10 , v 8 v 11 , v 11 v 13 {v}_{2}{v}_{7},{v}_{4}{v}_{8},{v}_{6}{v}_{10},{v}_{8}{v}_{11},{v}_{11}{v}_{13} are all maximal cross arcs on path P = v 0 v 1 … v 14 P={v}_{0}{v}_{1}\ldots {v}_{14} . G = { v i t v j t | t = 0 , 1 , 2 , 3 } G=\{{v}_{{i}_{t}}{v}_{{j}_{t}}\hspace{.25em}|\hspace{.25em}t=0,1,2,3\} is an only maximal cross-arc chain on path P = v 0 v 1 … v 16 P={v}_{0}{v}_{1}\ldots {v}_{16} , in which v i 2 v j 2 {v}_{{i}_{2}}{v}_{{j}_{2}} is an only invalid cross arc in G. P 1 ′ = v 0 v 1 , P 2 ′ = v 14 v 15 v 16 {P}_{1^{\prime} }={v}_{0}{v}_{1},{P}_{2^{\prime} }={v}_{14}{v}_{15}{v}_{16} are all maximal pure subpaths on P.$

Figure 1

(a) k = 1 : G 1 = { v i 0 v j 0 } , G 2 = { v i 2 v j 2 } are two maximal cross-arc chains on P = v 0 v 1 … v 16 . P 1 = v 0 v 1 , P 2 = v 6 v 7 v 8 , P 3 = v 15 v 16 are all maximal pure subpaths on P; (b) k ≥ 2 : v 2 v 7 , v 4 v 8 , v 6 v 10 , v 8 v 11 , v 11 v 13 are all maximal cross arcs on path P = v 0 v 1 … v 14 . G = { v i t v j t | t = 0 , 1 , 2 , 3 } is an only maximal cross-arc chain on path P = v 0 v 1 … v 16 , in which v i 2 v j 2 is an only invalid cross arc in G. P 1 ′ = v 0 v 1 , P 2 ′ = v 14 v 15 v 16 are all maximal pure subpaths on P.

The vertex set ⋃ t = 0 k − 1 { v i t , v i t + 1 , … , v j t } is covered by the maximal cross-arc chain G. If there exists an arc v i τ v j τ ∈ G satisfying | i τ + 1 − j τ − 1 | = 1 , then we call the maximal cross arc v i τ v j τ an invalid cross arc of G, where 1 ≤ τ ≤ k − 2 . In addition to the invalid cross arcs in G, the remaining maximal cross arcs are called the valid cross arcs of G. Let P m be a subpath of P n . If all the vertices on P m are not covered by any maximal cross-arc chain, then P m is called a pure subpath of P n . If there is no v α ∈ V ( P n ) such that D 〈 V ( P m ) ∪ { v α } 〉 is a pure subpath of P n , then call P m a maximal pure subpath of P n and all vertices in V ( P m ) covered by P m . Figure 1 illustrates these definitions.

Subsequently, we show the partition problem of the vertices of a round purely local tournament which is non-strong. Let D be a round purely local tournament which is non-strong. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. Since D is a round purely local tournament which is non-strong, P = v 0 v 1 … v n − 1 is the only Hamilton path in D. If there exists a cross arc on P, then it can only be forward arc (that is, from the vertex with a small subscript to the vertex with a large subscript). Thus, V ( D ) can form a partition. It means V ( D ) = ⋃ i = 0 m B i , B i ∩ B j = ∅ for any i ≠ j ∈ { 0 , 1 , … , m } , where B i is covered by either some maximal pure subpath or some maximal cross-arc chain (Figure 2).

$Figure 2 The vertex set partition of a round purely local tournament D which is non-strong. V ( D ) = ⋃ i = 0 6 B i V(D)={\bigcup }_{i=0}^{6}{B}_{i} , where B 0 = { v 0 } , {B}_{0}=\{{v}_{0}\}, B 1 = { v 1 , v 2 , v 3 } , B 2 = { v 4 } , B 3 = { v 5 , v 6 , v 7 } , B 4 = { v 8 } , B 5 = { v 9 , v 10 , v 11 , v 12 , v 13 , v 14 } , B 6 = { v 15 , v 16 } . {B}_{1}=\{{v}_{1},{v}_{2},{v}_{3}\},{B}_{2}=\{{v}_{4}\},{B}_{3}=\{{v}_{5},{v}_{6},{v}_{7}\},{B}_{4}=\{{v}_{8}\},{B}_{5}=\{{v}_{9},{v}_{10},{v}_{11},{v}_{12},{v}_{13},{v}_{14}\},{B}_{6}=\{{v}_{15},{v}_{16}\}.$

Figure 2

The vertex set partition of a round purely local tournament D which is non-strong. V ( D ) = ⋃ i = 0 6 B i , where B 0 = { v 0 } , B 1 = { v 1 , v 2 , v 3 } , B 2 = { v 4 } , B 3 = { v 5 , v 6 , v 7 } , B 4 = { v 8 } , B 5 = { v 9 , v 10 , v 11 , v 12 , v 13 , v 14 } , B 6 = { v 15 , v 16 } .

According to the partition about the vertex set above, the following conclusions can be obtained.

Lemma 2.1

Let D be a round purely local tournament which is non-strong on n vertices. Let P = v 0 v 1 … v n − 1 be a Hamilton path in D. If P m = v i 0 v i 0 + 1 … v i 0 + ( m − 1 ) is a maximal pure subpath on P, then γ ( P m ) = m 2 .

Proof

Since P m is a directed path, v j → v j + 1 for j ∈ { i 0 , i 0 + 1 , … , i 0 + ( m − 2 ) } .

When m is even, let T = { v i 0 , v i 0 + 2 , v i 0 + 4 , … , v i 0 + ( m − 2 ) } . Since v j → v j + 1 for j ∈ { i 0 , i 0 + 1 , … , i 0 + ( m − 2 ) } , we have T → P m . Thus, γ ( P m ) ≤ | T | = m 2 . Choosing any vertex set M = { v k 1 , v k 2 , … , v k m 2 − 1 } ⊆ V ( D ) , there must exist a vertex v τ ∈ V ( P m ) such that { v τ , v τ + 1 } ⊈ M . By maximal pure subpath P m , we see that v ↛ v τ + 1 for any vertex v ∈ M since N D − ( v τ + 1 ) = { v τ } . Therefore, M is not a dominating set of P m . For the arbitrariness of M, we have γ ( P m ) ≥ m 2 . Thus, γ ( P m ) = m 2 = m 2 .

When m is odd, let T = { v i 0 , v i 0 + 1 , v i 0 + 3 … , v i 0 + ( m − 2 ) } . It is easy to see that T → P m and | T | = m 2 . So γ ( P m ) ≤ m 2 . Choosing any vertex set M ′ = { v j 1 , v j 2 , … , v j m 2 − 1 } ⊆ V ( D ) , there must exist a vertex v τ ∈ V ( P m ) such that { v τ , v τ + 1 } ⊈ M ′ . By maximal pure subpath P m , we have v ↛ v τ + 1 for any vertex v ∈ M ′ . Then M ′ is not a dominating set of P m . It implies γ ( P m ) ≥ m 2 . Thus, γ ( P m ) = m 2 .□

Lemma 2.2

Let D be a round purely local tournament which is non-strong on n vertices. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. P = v 0 v 1 … v n − 1 is the Hamiltonian path in D. If B = ⋃ t = 0 k − 1 { v i t , v i t + 1 , … , v j t } ⊆ V ( D ) is covered by the maximal cross-arc chain G = { v i t v j t | t = 0 , 1 , 2 , … , k − 1 } , then γ ( D 〈 B 〉 ) = τ , where τ is the number of all valid arcs in G, and all subscripts are ordered in the round ordering.

Proof

Now we distinguish two cases to prove this lemma.

Case 1. There is no invalid cross arc in G.

According to the definitions of the maximal cross arc and the round digraph, there must be v i t → v l where l ∈ { i t + 1 , i t + 2 , … , j t } for t ∈ { 0 , 1 , 2 , … , k − 1 } . Since i t < i t + 1 ≤ j t < j t + 1 for t ∈ { 0 , 1 , … , k − 2 } , we have { v i t | t = 0 , 1 , … , k − 1 } → D 〈 B 〉 . Thus, γ ( D 〈 B 〉 ) ≤ k = τ .

For arbitrary t ∈ { 1 , 2 , … , k − 2 } , v i t v j t is a valid cross arc of G. By the definition of a valid cross arc, | i t + 1 − j t − 1 | ≥ 2 . Since G is a maximal cross-arc chain, | i 1 − i 0 | ≥ 2 and | j k − 1 − j k − 2 | ≥ 2 . Thus, there is at least a vertex v i t 0 in the vertex set { v i t , v i t + 1 , … , v j t } such that v i t 0 is only covered by the maximal cross arc v i t v j t in G, where t ∈ { 0 , 1 , 2 , … , k − 1 } . Let A t = { v i t , v i t + 1 , … , v i t 0 } , t ∈ { 0 , 1 , … , k − 1 } . It is easy to see A i ∩ A j = ∅ , i , j ∈ { 0 , 1 , … , k − 1 } . For any vertex set M ⊆ B for | M | = k − 1 , there exists α ∈ { 0 , 1 , … , k − 1 } such that A α ∩ M = ∅ . By the round purely local tournament D which is non-strong, we have v ↛ v α ∈ A α for any v ∈ A β with β ∈ { α + 1 , α + 2 , … , k − 1 } . Since v α 0 ∈ A α is only covered by the maximal cross arc v i α v j α , we have v γ ↛ v α 0 for γ ∈ { i 0 , i 0 + 1 , … , i α − 1 } . Thus, M ↛ v α 0 . According to the arbitrariness of M, γ ( D 〈 B 〉 ) ≥ k = τ . So γ ( D 〈 B 〉 ) = k = τ (Figure 3(a)).

Case 2. There is at least one invalid cross arc in G.

Let v i α v j α be any invalid cross arc of G. According to the definition of an invalid cross arc, | i α + 1 − j α − 1 | = 1 . It implies that { v i α , v i α + 1 , … , v j α − 1 } is covered by the maximal cross arc v i α − 1 v j α − 1 and { v j α − 1 + 1 , v j α − 1 + 2 , … , v j α } is covered by the maximal cross arc v i α + 1 v j α + 1 . By the definitions of the cover and the round digraph, we obtain { v i α − 1 , v i α + 1 } → { v i α , v i α + 1 , … , v j α } .

For the arbitrariness of v i α v j α , all vertices covered by the invalid cross arcs in G can be covered by the valid cross arcs in G. This means γ ( D 〈 B 〉 ) ≤ τ , where τ is the number of valid arcs in G. According to Case 1, γ ( D 〈 B 〉 ) ≥ τ can be proved similarly. Then, γ ( D 〈 B 〉 ) = τ (Figure 3(b)).□

Lemma 2.3

Let D be a round purely local tournament which is non-strong on n vertices. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. Let P = v 0 v 1 … v n − 1 be the Hamilton path in D, P i = v i 0 v i 0 + 1 … v i 1 − 1 ( P j = v j t − 1 + 1 v j t − 1 + 2 … v j t ) be a maximal subpath on P, and G i = { v i k v j k | k = 1 , 2 , … , t } ( G j = { v i k v j k | k = 0 , 1 , … , t − 1 } ) be a maximal cross-arc chain on P adjacent to P i ( P j ) . If B and C represent the set of vertices covered by P i ( P j ) and G i ( G j ) , respectively, then γ ( D 〈 B ∪ C 〉 ) = γ ( D 〈 B 〉 ) + γ ( D 〈 C 〉 ) .

Proof

Let T B and T C be the minimum dominating set of D 〈 B 〉 and D 〈 C 〉 , respectively. It implies γ ( D 〈 B 〉 ) = | T B | , γ ( D 〈 C 〉 ) = | T C | . It is easy to see T B ∪ T C → D ( 〈 B ∪ C 〉 ) . Thus, we have γ ( D 〈 B ∪ C 〉 ) ≤ | T B | + | T C | . Without loss of generality, suppose that all the cross arcs in G i ( G j ) are valid. Choose any vertex set M ⊆ V ( D ) satisfying | M | = | T B | + | T C | − 1 . According to the proof of Lemma 2.2 and the structure of the round purely local tournament which is non-strong, the minimum dominating set of D 〈 C 〉 must be E = { v τ k | k = 1 , 2 , … , t } ( E = { v τ k | k = 0 , 1 , … , t − 1 } ) , where v τ k ∈ { v i k , v i k + 1 , … , v i k + m } , v i k + m is a vertex in C with the smallest subscript which is only covered by the valid cross arc v i k v j k . It is not difficult to see that | E | = | T C | . Thus, if | M ∩ E | ≤ | T C | − 1 , then M cannot dominate D 〈 C 〉 , which means M is not a dominating set of D. Otherwise, M contains | T B | − 1 vertices in B at most. As we know from Lemma 2.1, there exists v α ∈ { v i 0 , v i 0 + 1 , … , v i 1 − 2 } ( { v j t − 1 + 1 , v j t − 1 + 2 , … , v j t − 1 } ) such that { v α , v α + 1 } ∩ M = ∅ . By the structure of D and the pure subpath D 〈 B 〉 , we have M ↛ v α + 1 , i.e. M is not a dominating set of D 〈 B ∪ C 〉 . Due to the arbitrariness of M, γ ( D 〈 B ∪ C 〉 ) ≥ | T B | + | T C | . Thus, γ ( D 〈 B ∪ C 〉 ) = | T B | + | T C | = γ ( D 〈 B 〉 ) + γ ( D 〈 C 〉 ) (Figure 4).□

According to the aforementioned results, we can get the following result about the dominating number of a round purely local tournament which is non-strong.

$Figure 4 An example for Lemma 2.3.$

Figure 4

An example for Lemma 2.3.

$Figure 3 (a) An example for Case 1 in Lemma 2.2, where there is no invalid cross arc; (b) an example for Case 2 in Lemma 2.2, where there is an invalid cross arc v 3 v 5 {v}_{3}{v}_{5} .$

Figure 3

(a) An example for Case 1 in Lemma 2.2, where there is no invalid cross arc; (b) an example for Case 2 in Lemma 2.2, where there is an invalid cross arc v 3 v 5 .

Theorem 2.4

Let D be a round purely local tournament which is non-strong on n vertices. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. P = v 0 v 1 … v n − 1 is the Hamiltonian path of D. If there exist k maximal cross-arc chains G i ( i = 1 , 2 , … , k ) and l maximal pure subpaths P j ( j = 1 , 2 , … , l ) on P, then γ ( D ) = ∑ i = 1 k τ i + ∑ j = 1 l n j 2 , where l ∈ { k − 1 , k , k + 1 } , τ i is the number of valid cross arcs in G i , and n j is the number of vertices contained in P j .

Proof

According to the structure of D, we obtain the vertices of D are either covered by a maximal cross-arc chain or covered by a maximal pure subpath. According to the definition of the maximal cross-arc chain and the maximal pure subpath, one can get γ ( D ) ≤ ∑ i = 1 k τ i + ∑ j = 1 l ⌈ n j 2 ⌉ by Lemmas 2.1 and 2.2.

We give a proof for γ ( D ) ≥ ∑ i = 1 k τ i + ∑ j = 1 l ⌈ n j 2 ⌉ as follows. Choose any vertex set M ⊆ V ( D ) for | M | ∑ i = 1 k τ i + ∑ j = 1 l ⌈ n j 2 ⌉ , then one of the following two cases holds at least:

Case 1. There is a maximal cross-arc chain G α = { v i t v j t | t = 1 , 2 , … , τ α } such that | M ∩ { v β | β = i 1 , i 1 + 1 , … , j τ α } | ≤ τ α − 1 .

By the proof of Case 1 in Lemma 2.2, there must be v α 0 ∈ { v β | β = i 1 , i 1 + 1 , … , j τ α } such that M ↛ v α 0 . Then M cannot dominate D.

Case 2. There is a maximal pure subpath P β such that | M ∩ V ( P β ) | ≤ n β 2 − 1 , where n β = | V ( P β ) | .

According to Lemma 2.1, there must be a vertex set { v i β , v i β + 1 } ⊆ V ( P β ) such that M ∩ { v i β , v i β + 1 } = ∅ . Due to the structure of D, it is obvious N D − ( v i β + 1 ) = { v i β } , which means M ↛ v i β + 1 . Then M cannot dominate D.

Therefore, M is not a dominating set of D anyway. By the arbitrariness of M, γ ( D ) ≥ ∑ i = 1 k τ i + ∑ j = 1 l n j 2 . Thus, γ ( D ) = ∑ i = 1 k τ i + ∑ j = 1 l n j 2 .□

2.2 The domination number of a round purely local tournament which is strong

Theorem 2.5

Let D be a directed cycle v 0 v 1 … v n − 1 v 0 , then γ ( D ) = ⌈ n 2 ⌉ , where all subscripts are taken modulo n.

Proof

Since D is a directed cycle, we have v i → v i + 1 for 0 ≤ i ≤ n − 1 .

When n is even, let T = { v 0 , v 2 , v 4 , … , v n − 2 } . By the condition v i → v i + 1 for 0 ≤ i ≤ n − 1 , we obtain T → D , and then γ ( D ) ≤ n 2 . Choose arbitrary vertex set M = { v i 1 , v i 2 , … , v i n 2 − 1 } , there must exist α ∈ { 0 , 1 , 2 , … , n − 1 } such that { v α , v α + 1 } ⊈ M . Since D is a cycle, we have M ↛ v α + 1 . So M is not a dominating set of D. By the arbitrariness of M, we have γ ( D ) ≥ n 2 . Therefore, γ ( D ) = n 2 .

When n is odd, it is easy to see the vertex set T = { v 0 , v 1 , v 3 , … , v n − 2 } is a dominating set of D because D is a directed cycle. Thus, γ ( D ) ≤ ⌈ n 2 ⌉ . Choose any vertex set M = { v j 1 , v j 2 , … , v j ⌈ n 2 ⌉ − 1 } , there must exist β ∈ { 0 , 1 , 2 , … , n − 1 } such that { v β , v β + 1 } ⊈ M . Since D is a cycle, M ↛ v β + 1 . Therefore, M is not a dominating set of D. For the arbitrariness of M, we get γ ( D ) ≥ ⌈ n 2 ⌉ . Thus, γ ( D ) = ⌈ n 2 ⌉ .□

For the convenience of proof, we define as follows similar to that of Section 2.1. Let D be a round purely local tournament which is strong. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. Let C n = v 0 v 1 … v n − 1 v 0 be the Hamilton cycle in D. The arc connecting any two non-adjacent vertices on the cycle is called a cross arc on C n . Let v i v j be a cross arc on C n . If there is no cross arc v i α v j α on C n such that i α < i < j < j α ( j α < j < i < i α ) , then the cross arc v i v j is called a maximal cross arc on C n . We call the vertex set { v i , v i + 1 , … , v j } covered by the maximal cross arc v i v j . We call the set G a maximal cross-arc chain on C n and the vertex set ⋃ t = 0 k − 1 { v i t , v i t + 1 , … , v j t } covered by the maximal cross-arc chain G, if there is a maximal cross-arc set { v i t v j t | v i t v j t is a maximal cross arc on the cycle C n , t ∈ { 0 , 1 , … , k − 1 } } on C n satisfied:

For k = 1 ,
1. v i 0 v j 0 is a maximal cross arc on C n and there is no set { α , α ′ , β , β ′ } ⊆ { 0 , 1 , … , n − 1 } such that α < i 0 < α ′ and β < j 0 < β ′ , where v α v α ′ , v β v β ′ are two cross arcs on C n ; or
2. v i 0 v j 0 is a maximal cross arc on C n . There is a maximal cross arc v γ v γ ′ on C n such that γ < i 0 < γ ′ (or γ < j 0 < γ ′ ) and i 0 − γ = 1 (or γ ′ − j 0 = 1 ), and there is no cross arc v τ v τ ′ such that τ < i 0 < τ ′ and i 0 − τ ≥ 2 (or τ < j 0 < τ ′ and τ ′ − j 0 ≥ 2 ) (Figure 5(a)).
For k ≥ 2 ,
1. | i 1 − i 0 | > 1 and | j k − 1 − j k − 2 | > 1 , and when i 0 ≠ 0 (or j k − 1 ≠ n − 1 ), there is at most one vertex v i 0 − 1 (or v j k − 1 + 1 ) such that v i 0 − 1 v β (or v β v j k − 1 + 1 ) is a cross arc on C n , where i 0 < β (or β < j k − 1 ); and
2. i t < i t + 1 ≤ j t < j t + 1 , t ∈ { 0 , 1 , … , k − 2 } ; and
3. There is no maximal cross arc v i γ v j γ on C n such that i t + 1 < i γ ≤ j t < j t + 1 < j γ , t ∈ { 0 , 1 , … , k − 2 } (Figure 5(b)).

$Figure 5 ( a ) v 2 v 6 (a){v}_{2}{v}_{6} is a maximal cross arc on C = v 0 v 1 … v 11 v 0 C={v}_{0}{v}_{1}\ldots {v}_{11}{v}_{0} , and G = { v 2 v 6 } G=\{{v}_{2}{v}_{6}\} is a maximal cross-arc chain on C; (b) G = { v 2 v 6 , v 5 v 8 , v 7 v 10 } G=\{{v}_{2}{v}_{6},{v}_{5}{v}_{8},{v}_{7}{v}_{10}\} is a maximal cross-arc chain on C = v 0 v 1 … v 11 v 0 C={v}_{0}{v}_{1}\ldots {v}_{11}{v}_{0} , where v 2 v 6 , v 7 v 10 {v}_{2}{v}_{6},{v}_{7}{v}_{10} is a valid cross arc in G, v 5 v 8 {v}_{5}{v}_{8} is an invalid arc in G.$

Figure 5

( a ) v 2 v 6 is a maximal cross arc on C = v 0 v 1 … v 11 v 0 , and G = { v 2 v 6 } is a maximal cross-arc chain on C; (b) G = { v 2 v 6 , v 5 v 8 , v 7 v 10 } is a maximal cross-arc chain on C = v 0 v 1 … v 11 v 0 , where v 2 v 6 , v 7 v 10 is a valid cross arc in G, v 5 v 8 is an invalid arc in G.

$Figure 6 A round purely local tournament D which is strong with k maximal cross-arc chains and k maximal pure subpaths.$

Figure 6

A round purely local tournament D which is strong with k maximal cross-arc chains and k maximal pure subpaths.

$Figure 7 An example for Theorem 2.7.$

Figure 7

An example for Theorem 2.7.

If there is a maximal cross arc v i τ v j τ ∈ G satisfying | i τ + 1 − j τ − 1 | = 1 , then the maximal cross arc v i τ v j τ is an invalid cross arc of G, where 1 ≤ τ ≤ k − 2 . In addition to the invalid cross arcs in G, we call the remaining maximal cross arcs the valid cross arcs of G. Let P m be a subpath on C n . If all the vertices on P m are not covered by any maximal cross-arc chain, then call P m a pure subpath on C n . If there is no vertex v α ∈ V ( C n ) such that D 〈 V ( P m ) ∪ { v α } 〉 is a pure subpath on C n , then P m is a maximal pure subpath of C n and V ( P m ) is covered by P m . Figure 5 illustrates these definitions.

Next, we show the partition problem of the vertices of a round purely local tournament which is strong. Let D be a round purely local tournament which is strong. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. Then C = v 0 v 1 … v n − 1 is the only Hamilton cycle in D. Similar to the round purely local tournament which is non-strong, V ( D ) can form a partition, which means V ( D ) = ⋃ i = 0 m B i , B i ∩ B j = ∅ for any i ≠ j ∈ { 0 , 1 , … , m } , where B i is covered by either some maximal pure subpath or some maximal cross-arc chain (Figure 5).

Theorem 2.6

Let D be a round purely local tournament which is strong on n vertices. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. C = v 0 v 1 … v n − 1 v 0 is a Hamilton cycle in D. If there are k maximal cross-arc chains G i on C, then γ ( D ) = ∑ i = 0 k − 1 ( τ i + ⌈ n i 2 ⌉ ) , where τ i indicates the number of valid cross arcs in G i , n i indicates the number of vertices contained in the maximal pure subpath P i on C for i ∈ { 0 , 1 , … , k − 1 } .

Proof

Obviously, there are k maximal pure subpaths on C. Without loss of generality, let P 0 = v 0 v 1 … v i 0 1 − 1 , G 0 = { v i 0 t v j 0 t | t = 1 , 2 , … , τ 0 } , P 1 = v j 0 τ 0 + 1 v j 0 τ 0 + 2 … v i 1 1 − 1 , G 1 = { v i 1 t v j 1 t | t = 1 , 2 , … , τ 1 } , … , P k − 1 = v j ( k − 2 ) τ k − 2 + 1 v j ( k − 2 ) τ k − 2 + 2 … v i ( k − 1 ) 1 − 1 , G k − 1 = { v i ( k − 1 ) t v j ( k − 1 ) t | t = 1 , 2 , … , τ k − 1 } , where τ k − 1 = n − 1 (Figure 6). Let D ′ = D − v n − 1 v 0 . By Theorem 2.4, we have γ ( D ′ ) = ∑ i = 0 k − 1 ( τ i + ⌈ n i 2 ⌉ ) . Since N D ′ − ( v 0 ) = ∅ , v 0 must be contained in any dominating set of D ′ . Also, owing to N D − ( v 0 ) = { v n − 1 } and the proof of Lemma 2.2, one can obtain that v n − 1 has been dominated by v i ( k − 1 ) τ k − 1 . Thus, γ ( D ) = γ ( D ′ ) = ∑ i = 0 k − 1 ( τ i + ⌈ n i 2 ⌉ ) .□

2.3 The domination number of a round tournament

Theorem 2.7

Let D be a strong round tournament with n vertices. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. Then γ ( D ) = 2 , where all subscripts are taken modulo n.

Proof

Since D is a strong tournament, d + ( v ) ≤ n − 2 for any vertex v ∈ V ( D ) . It implies any vertex in D cannot form a dominating set of D, i.e. γ ( D ) ≥ 2 . Furthermore, we have | V ( D ) | ≥ 3 and v 0 is adjacent to v n − 2 since D is a strong tournament. Then the following two cases will be considered.

Case 1. v 0 → v n − 2 .

According to the definition of the round digraph, we have v 0 → v t as well as v n − 2 → v n − 1 , where t ∈ { 1 , 2 , … , n − 2 } . Therefore, { v 0 , v n − 2 } → D , which means γ ( D ) ≤ 2 . Thus, we have γ ( D ) = 2 .

Case 2. v n − 2 → v 0 .

Since D is a strong tournament, at this time we get | V ( D ) | ≥ 4 for v n − 2 → v 0 . If v 0 → v n − 3 , then { v 0 , v n − 2 } is a dominating set of D according to v 0 → { v 1 , … , v n − 3 } and v n − 2 → v n − 1 , i.e. γ ( D ) ≤ 2 . It implies γ ( D ) = 2 . Conversely, if v n − 3 → v 0 , then we consider v n − 4 . Proceeding in this manner, if there exists a vertex v t 0 ∈ { v 2 , … , v n − 2 } such that v 0 → v t 0 , then { v 0 , v t 0 + 1 } is a dominating set of D. Otherwise, there will be v t 0 → v 0 , v t 0 ∈ { v 2 , … , v n − 2 } . If v 2 → v 0 , then v 2 → v u 0 for u 0 ∈ { v 3 , v 4 , … , v n − 1 } according to v 2 → v 3 and the definition of a round digraph. From v 0 → v 1 , we know { v 0 , v 2 } is a dominating set of D, which means γ ( D ) ≤ 2 . Then γ ( D ) = 2 (Figure 7).□

Theorem 2.8

Let D be a non-strong round tournament with n vertices. v 0 , v 1 , … , v n − 1 is a round labelling of D. Then γ ( D ) = 1 , where all subscripts are taken modulo n.

Proof

Since D is a round tournament which is non-strong, v 0 → v i for i ∈ { 1 , 2 , … , n − 1 } . Therefore, γ ( D ) = 1 .□

3 The domination number of a round non-local tournament

If a round digraph D is a non-local tournament, then there is a 2-cycle in D by Lemma 1.1. It implies D is a semicomplete digraph or a purely local semicomplete digraph. According to the definition of the round digraph, one can know that D is strongly connected.

$Figure 8 The two cases corresponding to Theorem 3.1. (a) There exists v i ∈ V ( D ) {v}_{i}\in V(D) such that v i + 1 → v i {v}_{i+1}\to {v}_{i} . (b) There is a vertex set { v α , v β } ⊆ V ( D ) \{{v}_{\alpha },{v}_{\beta }\}\subseteq V(D) such that { v α v β , v β v α } ⊆ A ( D ) \{{v}_{\alpha }{v}_{\beta },{v}_{\beta }{v}_{\alpha }\}\subseteq A(D) .$

Figure 8

The two cases corresponding to Theorem 3.1.

There exists v i ∈ V ( D ) such that v i + 1 → v i .
There is a vertex set { v α , v β } ⊆ V ( D ) such that { v α v β , v β v α } ⊆ A ( D ) .

Theorem 3.1

Let D be a round non-local tournament with n vertices. Let v 0 , v 1 , … , v n − 1 be a round labelling of D. Then

γ ( D ) = 1 , i f t h e r e e x i s i t s v i ∈ V ( D ) s u c h t h a t { v i v i + 1 , v i + 1 v i } ⊆ A ( D ) , 2 , o t h e r w i s e .

Proof

Since D is a strong round digraph, we have v 0 v 1 … v n − 1 v 0 is a Hamilton cycle of D. If there exists v i ∈ V ( D ) such that v i + 1 → v i , then v i + 1 → v j where j ∈ { i + 2 , i + 3 , … , i − 1 , i } according to the definition of the round digraph. Therefore, { v i + 1 } is a dominating set of D. Thus, γ ( D ) = 1 (Figure 8(a)).

Otherwise, there is a vertex set { v α , v β } ⊆ V ( D ) such that { v α v β , v β v α } ⊆ A ( D ) satisfying | α − β | ≠ 1 according to the round non-locally tournament D which is strong. By v α → v β , we have v α → v τ for τ ∈ { α + 1 , α + 2 , … , β − 1 , β } . Similarly, we have v β → v ν because v β → v α for ν ∈ { β + 1 , β + 2 , … , α − 1 , α } . Thus, { v α , v β } is a dominating set for D. Then γ ( D ) ≤ 2 . Choosing any vertex v γ ∈ V ( D ) , we can see that v γ ↛ v γ − 1 by the known conditions, which means that { v γ } cannot form a dominating set of D. For the arbitrariness of v γ , γ ( D ) ≥ 2 . Therefore, γ ( D ) = 2 (Figure 8(b)).□

Acknowledgments

The authors express sincere thanks to the referees for their valuable suggestions and detailed comments. This research was supported partially by the Natural Science Foundation of Shanxi Province (201801D121013) and the Youth Foundation of Shanxi Province (201901D211197).

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Received: 2020-04-01

Revised: 2020-08-06

Accepted: 2020-09-10

Published Online: 2020-12-30

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/math-2020-0084

Keywords for this article

domination number; round digraph; local tournament; purely local tournament

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