Sufficient Conditions for a Graph \(kG\) Admitting all \([1,k]\)-factors

Jie Wu1
1School of Economic and management, Jiangsu University of Science and Technology, Zhenjiang, Jiangsu 212100, China.

Abstract

Let \(g,f:V(G)\rightarrow\{0,1,2,3,\cdots\}\) be two functions satisfying \(g(x)\leq f(x)\) for every \(x\in V(G)\). A \((g,f)\)-factor of \(G\) is
defined as a spanning subgraph \(F\) of \(G\) such that \(g(x)\leq d_F(x)\leq f(x)\) for every \(x\in V(G)\). An \((f,f)\)-factor is simply called
an \(f\)-factor. Let \(\varphi\) be a nonnegative integer-valued function defined on \(V(G)\). Set
\[
D_{g,f}^{even}=\Big\{\varphi: g(x)\leq\varphi(x)\leq f(x) \text{ for every } x\in V(G) \text{ and } \sum\limits_{x\in V(G)}\varphi(x) \text{ is even}\Big\}.
\]
If for each \(\varphi\in D_{g,f}^{even}\), \(G\) admits a \(\varphi\)-factor, then we say that \(G\) admits all \((g,f)\)-factors. All \((g,f)\)-factors
are said to be all \([1,k]\)-factors if \(g(x)\equiv1\) and \(f(x)\equiv k\) for any \(x\in V(G)\). In this paper, we verify that for a connected multigraph
\(G\) satisfying \(N_G(X)=V(G) \text{ or } |N_G(X)|>\Big(1+\frac{1}{k+1}\Big)|X|-1\) for every \(X\subset V(G)\), \(kG\) admits all \([1,k]\)-factors, where
\(k\geq2\) is an integer and \(kG\) denotes the graph derived from \(G\) by replacing every edge of \(G\) with \(k\) parallel edges.

Keywords: Graph, Spanning subgraph, \(\varphi\)-factor, \([1,k]\)-factors

1. Introduction

The graphs discussed here are multigraphs, which may admit multiple edges but do not admit loops. A graph is called a simple graph if it admits neither multiple edges nor loops. For convenience, we simply call a multigraph a graph when we show notations and definitions. Let \(G\) be a graph. We use \(V(G)\) and \(E(G)\) to denote the vertex set and the edge set of \(G\), respectively. For \(x\in V(G)\), we write \(d_G(x)\) for the degree of \(x\) in \(G\), and \(N_G(x)\) for the set of the vertices adjacent to \(x\) in \(G\). We write \(N_G(X)=\bigcup\limits_{x\in X}N_G(x)\) for any \(X\subseteq V(G)\). We denote by \(I(G)\) the set of isolated vertices of \(G\), and by \(\omega_{\geq k}(G)\) the number of components of \(G\) with order at least \(k\). Specially, we write \(i(G)=|I(G)|\) and \(\omega(G)=\omega_{\geq1}(G)\). Let \(kG\) denote the graph derived from \(G\) by replacing every edge of \(G\) with \(k\) parallel edges.

Let \(g,f:V(G)\rightarrow\{0,1,2,3,\cdots\}\) be two functions satisfying \(g(x)\leq f(x)\) for every \(x\in V(G)\). A \((g,f)\)-factor of \(G\) is defined as a spanning subgraph \(F\) of \(G\) such that \(g(x)\leq d_F(x)\leq f(x)\) for every \(x\in V(G)\). An \((f,f)\)-factor is simply called an \(f\)-factor. If \(g(x)\equiv1\) and \(f(x)\equiv k\) for any \(x\in V(G)\), then a \((g,f)\)-factor is called a \([1,k]\)-factor, where \(k\geq1\) is a fixed integer. A \([1,1]\)-factor is simply called a \(1\)-factor.

Let \(\varphi\) be a nonnegative integer-valued function defined on \(V(G)\). In the following, we write \[\begin{aligned} D_{g,f}^{even}&=&\Big\{\varphi: g(x)\leq\varphi(x)\leq f(x) \ for \ every \ x\in V(G)\\ &&and \ \sum\limits_{x\in V(G)}\varphi(x) \ is \ even\Big\}. \end{aligned}\] If for each \(\varphi\in D_{g,f}^{even}\), \(G\) admits a \(\varphi\)-factor, then we say that \(G\) admits all \((g,f)\)-factors. All \((g,f)\)-factors are said to be all \([1,k]\)-factors if \(g(x)\equiv1\) and \(f(x)\equiv k\) for any \(x\in V(G)\).

Lots of authors studied factors [1-16] and all factors [17-20] of graphs. The neighborhood conditions for graphs having factors were derived by many authors [21-27]. Lu, Kano and Yu [18] characterized a graph \(G\) such that \(kG\) admits all \([1,k]\)-factors. Lu, Kano and Yu’s results generalized Tutte’s 1-factor theorem [28].

Theorem 1.([18]). Let \(k\geq2\) be an integer, and let \(G\) be a connected multigraph. Then \(kG\) admits all \([1,k]\)-factors if and only if \[k\cdot i(G-X)+\omega_{\geq k+1}(G-X)\leq|X|+1\] for any \(X\subseteq V(G)\).

Using Theorem 1, we verify some results related to all \([1,k]\)-factors in graphs. Our main results will be shown in Section 2.

2. Next section

In this section, we discuss the relationship between neighborhood and all \([1,k]\)-factors, and verify two results related to all \([1,k]\)-factors.

Theorem 2.Let \(k\) be an integer with \(k\geq2\), and let \(G\) be a connected multigraph. If \(G\) satisfies \[N_G(X)=V(G) \ or \ |N_G(X)|>\Big(1+\frac{1}{k+1}\Big)|X|-1\] for every \(X\subset V(G)\), then \(kG\) admits all \([1,k]\)-factors.

 Assume that \(G\) satisfies the hypothesis of Theorem 2, but \(kG\) does not admit all \([1,k]\)-factors. Then by Theorem 1, we derive \[k\cdot i(G-X)+\omega_{\geq k+1}(G-X)\geq|X|+2\tag{1}\] for some subset \(X\subset V(G)\). The following proof will be divided into two cases by the value of \(i(G-X)\).

Case 1. \(i(G-X)=0\).

According to (1), we get \[\omega_{\geq k+1}(G-X)\geq|X|+2,\] which implies that \(G-X\) has at least \(|X|+2\) components with order at least \(k+1\). We denote by \(Y\) the set of vertices of any \(|X|+1\) components of \(G-X\) with order at least \(k+1\). It is clear that \(N_G(Y)\neq V(G)\). Thus, we derive \[|N_G(Y)|>\Big(1+\frac{1}{k+1}\Big)|Y|-1.\tag{2}\]

On the other hand, we easily see that \(|N_G(Y)|\leq|X|+|Y|\). Combining this with (2), we have \[|X|+|Y|\geq|N_G(Y)|>\Big(1+\frac{1}{k+1}\Big)|Y|-1,\] namely, \[|X|>\frac{1}{k+1}|Y|-1.\tag{3}\]

Note that \(|Y|\geq(k+1)(|X|+1)\). Then using (3), we admit \[|X|>\frac{1}{k+1}|Y|-1\geq(|X|+1)-1=|X|,\] this is a contradiction.

Case 2. \(i(G-X)>0\).

Obviously, \(N_G(V(G)\setminus X)\neq V(G)\). Thus, we have \[|N_G(V(G)\setminus X)|>\Big(1+\frac{1}{k+1}\Big)|V(G)\setminus X|-1=\Big(1+\frac{1}{k+1}\Big)(|V(G)|-|X|)-1.\tag{4}\] Using (4) and \(|N_G(V(G)\setminus X)|\leq|V(G)|-i(G-X)\), we obtain \[|V(G)|-i(G-X)\geq|N_G(V(G)\setminus X)|>\Big(1+\frac{1}{k+1}\Big)(|V(G)|-|X|)-1,\] that is, \[|V(G)|+(k+1)\cdot i(G-X)<(k+2)\cdot|X|+k+1.\tag{5}\]

On the other hand, we easily see that \[|V(G)|\geq i(G-X)+|X|+(k+1)\cdot(|X|+2)=i(G-X)+(k+2)\cdot|X|+2(k+1).\tag{6}\]

It follows from (5) and (6) that \[\begin{aligned}&(k+2)\cdot|X|+k+1>|V(G)|+(k+1)\cdot i(G-X)\\ &\geq(G-X)+(k+2)\cdot|X|\\ &+2(k+1)+(k+1)\cdot i(G-X)\\ &=(k+2)\cdot i(G-X)+(k+2)\cdot|X|+2(k+1)\end{aligned}\] which implies \[(k+2)\cdot i(G-X)+k+1<0,\] which is a contradiction. Theorem 2 is proved. \(\Box\)

Theorem 3. For any positive integer \(k\) with \(k\geq2\), there exist infinitely many graphs \(G\) that satisfy \[N_G(Y)=V(G) \ or \ |N_G(Y)|\geq\Big(1+\frac{1}{k+1}\Big)|Y|-1\] for every \(Y\subset V(G)\), but \(kG\) does not admit all \([1,k]\)-factors.

 Let \(r\geq1\) be an integer. We construct a graph \(G=K_r\vee((r+2)K_{k+1})\), where \(K_r\) denotes the complete graph of order \(r\), \(K_{k+1}\) denotes the complete graph of order \(k+1\) and \(\vee\) means “join”.

Next, we demonstrate that \[N_G(Y)=V(G) \ or \ |N_G(Y)|\geq\Big(1+\frac{1}{k+1}\Big)|Y|-1\] for every \(Y\subset V(G)\). We shall consider two cases by the value of \(|Y|\).

Case 1. \(|Y|=1\).

In this case, we obviously have that \(|N_G(Y)|\geq k+r>\frac{1}{k+1}=\Big(1+\frac{1}{k+1}\Big)|Y|-1\).

Case 2. \(|Y|\geq2\).

Case 2.1. \(Y\cap V(K_r)\neq\emptyset\).

It is clear that \(N_G(Y)=V(G)\).

Case 2.2. \(Y\cap V(K_r)=\emptyset\).

Let \(K_{k+1}(i)\), \(1\leq i\leq r+2\), denote the disjoint copies of \(K_{k+1}\) in \(G-V(K_r)\). Write \[b_1=\#\{i:|Y\cap V(K_{k+1}(i))|=1\},\] \[b_2=\#\{i:|Y\cap V(K_{k+1}(i))|=2\},\cdots,\] and \[b_{k+1}=\#\{i:|Y\cap V(K_{k+1}(i))|=k+1\}.\] Thus, we derive \(|Y|=b_1+2b_2+\cdots+(k+1)b_{k+1}\) and \(|N_G(Y)|=r+kb_1+(k+1)(b_2+\cdots+b_{k+1})\). If \(|Y|\leq(k+1)(r+1+(k-1)b_1+(k-1)b_2+(k-2)b_3+\cdots+b_k)\), then we admit \[|N_G(Y)|=r+|Y|+(k-1)b_1+(k-1)b_2+(k-2)b_3+\cdots+b_k\geq\Big(1+\frac{1}{k+1}\Big)|Y|-1.\]

In the following, we may assume that \(|Y|>(k+1)(r+1+(k-1)b_1+(k-1)b_2+(k-2)b_3+\cdots+b_k)\). Note that \(Y\cap V(K_r)=\emptyset\). Thus, we have \(|Y|\leq|V(G)|-|V(K_r)|=(r+2)(k+1)\). Hence, we gain \[(k+1)(r+1+(k-1)b_1+(k-1)b_2+(k-2)b_3+\cdots+b_k)<|Y|\leq(r+2)(k+1),\] namely, \[(k-1)b_1+(k-1)b_2+(k-2)b_3+\cdots+b_k<1,\] which implies \(b_1=b_2=\cdots=b_k=0\), and so \(|Y|=(k+1)b_{k+1}\). If \(b_{k+1}=r+2\), then we derive \(Y=V((r+2)K_{k+1})\), and so \(N_G(Y)=V(G)\). Next, we assume that \(b_{k+1}\leq r+1\). Clearly, \(|N_G(Y)|=r+(k+1)b_{k+1}=(k+2)b_{k+1}-1+r+1-b_{k+1}\geq(k+2)b_{k+1}-1=\Big(1+\frac{1}{k+1}\Big)|Y|-1\).

Consequently, we verify that \[N_G(Y)=V(G) \ or \ |N_G(Y)|\geq\Big(1+\frac{1}{k+1}\Big)|Y|-1\] for every \(Y\subset V(G)\).

Set \(X=V(K_r)\). Then \(i(G-X)=0\) and \(\omega_{\geq k+1}(G-X)=r+2\). Thus, we deduce \[k\cdot i(G-X)+\omega_{\geq k+1}(G-X)=r+2=|X|+2>|X|+1.\] Therefore, \(kG\) does not admit all \([1,k]\)-factors by Theorem 1. Theorem 3 is verified. \(\Box\)

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