Your search keyword '"Kuenzel, Kirsti"' showing total 19 results

1. A characterization of well-dominated Cartesian products

Author

Kuenzel, Kirsti and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C69, 05C75, 05C76

Abstract

A graph is well-dominated if all its minimal dominating sets have the same cardinality. In this paper we prove that at least one factor of every connected, well-dominated Cartesian product is a complete graph, which then allows us to give a complete characterization of the connected, well-dominated Cartesian products if both factors have order at least $2$. In particular, we show that $G\,\Box\,H$ is well-dominated if and only if $G\,\Box\,H = P_3 \,\Box\,K_3$ or $G\,\Box\,H= K_n \,\Box\,K_n$ for some $n\ge 2$., Comment: 17 pages

Published

2023

2. Graphs with equal Grundy domination and independence number

Author

Bacsó, Gábor, Brešar, Boštjan, Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C69, 05C75

Abstract

The Grundy domination number, ${\gamma_{\rm gr}}(G)$, of a graph $G$ is the maximum length of a sequence $(v_1,v_2,\ldots, v_k)$ of vertices in $G$ such that for every $i\in \{2,\ldots, k\}$, the closed neighborhood $N[v_i]$ contains a vertex that does not belong to any closed neighborhood $N[v_j]$, where $j

Published

2022

3. Loop zero forcing and grundy domination in planar graphs and claw-free cubic graphs

Author

Domat, Alex and Kuenzel, Kirsti

Subjects

Mathematics - Combinatorics, 05C69, 05C10

Abstract

Given a simple, finite graph with vertex set $V(G)$, we define a zero forcing set of $G$ as follows. Choose $S\subseteq V(G)$ and color all vertices of $S$ blue and all vertices in $V(G) - S$ white. The color change rule is if $w$ is the only white neighbor of blue vertex $v$, then we change the color of $w$ from white to blue. If after applying the color change rule as many times as possible eventually every vertex of $G$ is blue, we call $S$ a zero forcing set of $G$. $Z(G)$ denotes the minimum cardinality of a zero forcing set. Davila and Henning proved in \cite{zerocubic} that for any claw-free cubic graph $G$, $Z(G) \le \frac{1}{3}|V(G)| + 1$. We show that if $G$ is $2$-edge-connected, claw-free, and cubic, then $Z(G) \le \left\lceil\frac{5n(G)}{18}\right\rceil+1$. We also study a similar graph invariant known as the loop zero forcing number of a graph $G$ which happens to be the dual invariant to the Grundy domination number of $G$. Specifically, we study the loop zero forcing number in two particular types of planar graphs.

Published

2022

4. Orientable domination in product-like graphs

Author

Anderson, Sarah, Brešar, Boštjan, Klavžar, Sandi, Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Mathematics - Combinatorics

Abstract

The orientable domination number, ${\rm DOM}(G)$, of a graph $G$ is the largest domination number over all orientations of $G$. In this paper, ${\rm DOM}$ is studied on different product graphs and related graph operations. The orientable domination number of arbitrary corona products is determined, while sharp lower and upper bounds are proved for Cartesian and lexicographic products. A result of Chartrand et al. from 1996 is extended by establishing the values of ${\rm DOM}(K_{n_1,n_2,n_3})$ for arbitrary positive integers $n_1,n_2$ and $n_3$. While considering the orientable domination number of lexicographic product graphs, we answer in the negative a question concerning domination and packing numbers in acyclic digraphs posed in [Domination in digraphs and their direct and Cartesian products, J. Graph Theory 99 (2022) 359-377].

Published

2022

5. Power domination in cubic graphs and Cartesian products

Author

Anderson, Sarah E. and Kuenzel, Kirsti

Subjects

Mathematics - Combinatorics, 05C69, 05C70

Abstract

The power domination problem focuses on finding the optimal placement of phase measurement units (PMUs) to monitor an electrical power network. In the context of graphs, the power domination number of a graph $G$, denoted $\gamma_P(G)$, is the minimum number of vertices needed to observe every vertex in the graph according to a specific set of observation rules. In \cite{ZKC_cubic}, Zhao et al. proved that if $G$ is a connected claw-free cubic graph of order $n$, then $\gamma_P(G) \leq n/4$. In this paper, we show that if $G$ is a claw-free diamond-free cubic graph of order $n$, then $\gamma_P(G) \le n/6$, and this bound is sharp. We also provide new bounds on $\gamma_P(G \Box H)$ where $G\Box H$ is the Cartesian product of graphs $G$ and $H$. In the specific case that $G$ and $H$ are trees whose power domination number and domination number are equal, we show the Vizing-like inequality holds and $\gamma_P(G \Box H) \ge \gamma_P(G)\gamma_P(H)$.

Published

2022

6. Graphs which satisfy a Vizing-like bound for power domination of Cartesian products

Author

Anderson, Sarah E., Kuenzel, Kirsti, and Schuerger, Houston

Subjects

Mathematics - Combinatorics, 05C69, 05C70

Abstract

Power domination is a two-step observation process that is used to monitor power networks and can be viewed as a combination of domination and zero forcing. Given a graph $G$, a subset $S\subseteq V(G)$ that can observe all vertices of $G$ using this process is known as a power dominating set of $G$, and the power domination number of $G$, $\gamma_P(G)$, is the minimum number of vertices in a power dominating set. We introduce a new partition on the vertices of a graph to provide a lower bound for the power domination number. We also consider the power domination number of the Cartesian product of two graphs, $G \Box H$, and show certain graphs satisfy a Vizing-like bound with regards to the power domination number. In particular, we prove that for any two trees $T_1$ and $T_2$, $\gamma_P(T_1)\gamma_P(T_2) \leq \gamma_P(T_1 \Box T_2)$.

Published

2022

7. On independent domination in direct products

Author

Kuenzel, Kirsti and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C69, 05C76

Abstract

In \cite{nr-1996} Nowakowski and Rall listed a series of conjectures involving several different graph products. In particular, they conjectured that $i(G\times H) \ge i(G)i(H)$ where $i(G)$ is the independent domination number of $G$ and $G\times H$ is the direct product of graphs $G$ and $H$. We show this conjecture is false, and, in fact, construct pairs of graphs for which $\min\{i(G), i(H)\} - i(G\times H)$ is arbitrarily large. We also give the exact value of $i(G\times K_n)$ when $G$ is either a path or a cycle., Comment: 14 pages, 2 figures, 2 tables

Published

2022

8. On well-edge-dominated graphs

Author

Anderson, Sarah E., Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C69, 05C76, 05C75

Abstract

A graph is said to be well-edge-dominated if all its minimal edge dominating sets are minimum. It is known that every well-edge-dominated graph $G$ is also equimatchable, meaning that every maximal matching in $G$ is maximum. In this paper, we show that if $G$ is a connected, triangle-free, nonbipartite, well-edge-dominated graph, then $G$ is one of three graphs. We also characterize the well-edge-dominated split graphs and Cartesian products. In particular, we show that a connected Cartesian product $G\Box H$ is well-edge-dominated, where $G$ and $H$ have order at least $2$, if and only if $G\Box H = K_2 \Box K_2$., Comment: 18 pages, 2 figures, 18 references

Published

2021

9. Domination in digraphs and their products

Author

Brešar, Boštjan, Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C20, 05C69, 05C76

Abstract

A dominating (respectively, total dominating) set $S$ of a digraph $D$ is a set of vertices in $D$ such that the union of the closed (respectively, open) out-neighborhoods of vertices in $S$ equals the vertex set of $D$. The minimum size of a dominating (respectively, total dominating) set of $D$ is the domination (respectively, total domination) number of $D$, denoted $\gamma(D)$ (respectively,$\gamma_t(D)$). The maximum number of pairwise disjoint closed (respectively,open) in-neighborhoods of $D$ is denoted by $\rho(D)$ (respectively,$\rho^{\rm o}(D)$). We prove that in digraphs whose underlying graphs have girth at least $7$, the closed (respectively,open) in-neighborhoods enjoy the Helly property, and use these two results to prove that in any ditree $T$ (that is, a digraph whose underlying graph is a tree), $\gamma_t(T)=\rho^{\rm o}(T)$ and $\gamma(T)=\rho(T)$. By using the former equality we then prove that $\gamma_t(G\times T)=\gamma_t(G)\gamma_t(T)$, where $G$ is any digraph and $T$ is any ditree, each without a source vertex, and $G\times T$ is their direct product. From the equality $\gamma(T)=\rho(T)$ we derive the bound $\gamma(G\mathbin{\Box} T)\ge\gamma(G)\gamma(T)$, where $G$ is an arbitrary digraph, $T$ an arbitrary ditree and $G\mathbin{\Box} T$ is their Cartesian product. In general digraphs this Vizing-type bound fails, yet we prove that for any digraphs $G$ and $H$, where $\gamma(G)\ge\gamma(H)$, we have $\gamma(G \mathbin{\Box} H) \ge \frac{1}{2}\gamma(G)(\gamma(H) + 1)$. This inequality is sharp as demonstrated by an infinite family of examples. Ditrees $T$ and digraphs $H$ enjoying $\gamma(T\mathbin{\Box} H)=\gamma(T)\gamma(H)$ are also investigated., Comment: 22 pages and 5 figures

Published

2020

10. On well-dominated graphs

Author

Anderson, Sarah E., Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C69, 05C76

Abstract

A graph is \emph{well-dominated} if all of its minimal dominating sets have the same cardinality. We prove that at least one of the factors is well-dominated if the Cartesian product of two graphs is well-dominated. In addition, we show that the Cartesian product of two connected, triangle-free graphs is well-dominated if and only if both graphs are complete graphs of order $2$. Under the assumption that at least one of the connected graphs $G$ or $H$ has no isolatable vertices, we prove that the direct product of $G$ and $H$ is well-dominated if and only if either $G=H=K_3$ or $G=K_2$ and $H$ is either the $4$-cycle or the corona of a connected graph. Furthermore, we show that the disjunctive product of two connected graphs is well-dominated if and only if one of the factors is a complete graph and the other factor has domination number at most $2$., Comment: 16 pages, 2 figures

Published

2019

11. Graphs in which all maximal bipartite subgraphs have the same order

Author

Goddard, Wayne, Kuenzel, Kirsti, and Melville, Eileen

Subjects

Mathematics - Combinatorics, 05C69

Abstract

Motivated by the concept of well-covered graphs, we define a graph to be well-bicovered if every vertex-maximal bipartite subgraph has the same order (which we call the bipartite number). We first give examples of them, compare them with well-covered graphs, and characterize those with small or large bipartite number. We then consider graph operations including the union, join, and lexicographic and cartesian products. Thereafter we consider simplicial vertices and 3-colored graphs where every vertex is in triangle, and conclude by characterizing the maximal outerplanar graphs that are well-bicovered.

Published

2019

12. Graphs with a unique maximum open packing

Author

Brešar, Boštjan, Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C70, 05C69, 05C05

Abstract

A set $S$ of vertices in a graph is an open packing if (open) neighborhoods of any two distinct vertices in $S$ are disjoint. In this paper, we consider the graphs that have a unique maximum open packing. We characterize the trees with this property by using four local operations such that any nontrivial tree with a unique maximum open packing can be obtained by a sequence of these operations starting from $P_2$. We also prove that the decision version of the open packing number is NP-complete even when restricted to graphs of girth at least $6$. Finally, we show that the recognition of the graphs with a unique maximum open packing is polynomially equivalent to the recognition of the graphs with a unique maximum independent set, and we prove that the complexity of both problems is not polynomial, unless P=NP., Comment: 16 pages, 4 figures

Published

2019

13. On well-covered direct products

Author

Kuenzel, Kirsti and Rall, Douglas F.

Subjects

Mathematics - Combinatorics, 05C69, 05C76

Abstract

A graph $G$ is well-covered if all maximal independent sets of $G$ have the same cardinality. In 1992 Topp and Volkmann investigated the structure of well-covered graphs that have nontrivial factorizations with respect to some of the standard graph products. In particular, they showed that both factors of a well-covered direct product are also well-covered and proved that the direct product of two complete graphs (respectively, two cycles) is well-covered precisely when they have the same order (respectively, both have order 3 or 4). Furthermore, they proved that the direct product of two well-covered graphs with independence number one-half their order is well-covered. We initiate a characterization of nontrivial, connected well-covered graphs $G$ and $H$, whose independence numbers are strictly less than one-half their orders, such that their direct product $G \times H$ is well-covered. In particular, we show that in this case both $G$ and $H$ have girth 3 and we present several infinite families of such well-covered direct products. Moreover, we show that if $G$ is a factor of any well-covered direct product, then $G$ is a complete graph unless it is possible to create an isolated vertex by removing the closed neighborhood of some independent set of vertices in $G$.

Published

2019

14. Graphs with equal Grundy domination and independence number

Author

Bacsó, Gábor, Brešar, Boštjan, Kuenzel, Kirsti, and Rall, Douglas F.

Published

2023

15. On Well-Covered Direct Products

Author

Kuenzel Kirsti and Rall Douglas F.

Subjects

well-covered graph, direct product of graphs, isolatable vertex, 05c69, 05c76, Mathematics, QA1-939

Abstract

A graph G is well-covered if all maximal independent sets of G have the same cardinality. In 1992 Topp and Volkmann investigated the structure of well-covered graphs that have nontrivial factorizations with respect to some of the standard graph products. In particular, they showed that both factors of a well-covered direct product are also well-covered and proved that the direct product of two complete graphs (respectively, two cycles) is well-covered precisely when they have the same order (respectively, both have order 3 or 4). Furthermore, they proved that the direct product of two well-covered graphs with independence number one-half their order is well-covered. We initiate a characterization of nontrivial connected well-covered graphs G and H, whose independence numbers are strictly less than one-half their orders, such that their direct product G × H is well-covered. In particular, we show that in this case both G and H have girth 3 and we present several infinite families of such well-covered direct products. Moreover, we show that if G is a factor of any well-covered direct product, then G is a complete graph unless it is possible to create an isolated vertex by removing the closed neighborhood of some independent set of vertices in G.

Published

2022

16. A New Framework to Approach Vizing’s Conjecture

Author

Brešar Boštjan, Hartnell Bert L., Henning Michael A., Kuenzel Kirsti, and Rall Douglas F.

Subjects

cartesian product, total domination, vizing’s conjecture, clark and suen bound, 05c69, 05c76, Mathematics, QA1-939

Abstract

We introduce a new setting for dealing with the problem of the domination number of the Cartesian product of graphs related to Vizing’s conjecture. The new framework unifies two different approaches to the conjecture. The most common approach restricts one of the factors of the product to some class of graphs and proves the inequality of the conjecture then holds when the other factor is any graph. The other approach utilizes the so-called Clark-Suen partition for proving a weaker inequality that holds for all pairs of graphs. We demonstrate the strength of our framework by improving the bound of Clark and Suen as follows: γ (X□Y) ≥ max γ(X□Y)≥max{12γ(X)γt(Y),12γt(X)γ(Y)}\gamma \left( {X \square Y} \right) \ge \max \left\{ {{1 \over 2}\gamma (X){\gamma _t}(Y),{1 \over 2}{\gamma _t}(X)\gamma (Y)} \right\}, where γ stands for the domination number, γt is the total domination number, and X□Y is the Cartesian product of graphs X and Y.

Published

2021

17. Domination in digraphs and their products

Author

Bre��ar, Bo��tjan, Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

Computer Science::Discrete Mathematics, Astrophysics::High Energy Astrophysical Phenomena, 05C20, 05C69, 05C76, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO)

Abstract

A dominating (respectively, total dominating) set $S$ of a digraph $D$ is a set of vertices in $D$ such that the union of the closed (respectively, open) out-neighborhoods of vertices in $S$ equals the vertex set of $D$. The minimum size of a dominating (respectively, total dominating) set of $D$ is the domination (respectively, total domination) number of $D$, denoted $\gamma(D)$ (respectively,$\gamma_t(D)$). The maximum number of pairwise disjoint closed (respectively,open) in-neighborhoods of $D$ is denoted by $\rho(D)$ (respectively,$\rho^{\rm o}(D)$). We prove that in digraphs whose underlying graphs have girth at least $7$, the closed (respectively,open) in-neighborhoods enjoy the Helly property, and use these two results to prove that in any ditree $T$ (that is, a digraph whose underlying graph is a tree), $\gamma_t(T)=\rho^{\rm o}(T)$ and $\gamma(T)=\rho(T)$. By using the former equality we then prove that $\gamma_t(G\times T)=\gamma_t(G)\gamma_t(T)$, where $G$ is any digraph and $T$ is any ditree, each without a source vertex, and $G\times T$ is their direct product. From the equality $\gamma(T)=\rho(T)$ we derive the bound $\gamma(G\mathbin{\Box} T)\ge\gamma(G)\gamma(T)$, where $G$ is an arbitrary digraph, $T$ an arbitrary ditree and $G\mathbin{\Box} T$ is their Cartesian product. In general digraphs this Vizing-type bound fails, yet we prove that for any digraphs $G$ and $H$, where $\gamma(G)\ge\gamma(H)$, we have $\gamma(G \mathbin{\Box} H) \ge \frac{1}{2}\gamma(G)(\gamma(H) + 1)$. This inequality is sharp as demonstrated by an infinite family of examples. Ditrees $T$ and digraphs $H$ enjoying $\gamma(T\mathbin{\Box} H)=\gamma(T)\gamma(H)$ are also investigated., Comment: 22 pages and 5 figures

Published

2020

18. On well-covered direct products

Author

Kuenzel, Kirsti, primary and Rall, Douglas, additional

Published

2020

19. Graphs with a unique maximum open packing

Author

Bre��ar, Bo��tjan, Kuenzel, Kirsti, and Rall, Douglas F.

Subjects

05C70, 05C69, 05C05, FOS: Mathematics, Mathematics - Combinatorics, Combinatorics (math.CO), MathematicsofComputing_DISCRETEMATHEMATICS

Abstract

A set $S$ of vertices in a graph is an open packing if (open) neighborhoods of any two distinct vertices in $S$ are disjoint. In this paper, we consider the graphs that have a unique maximum open packing. We characterize the trees with this property by using four local operations such that any nontrivial tree with a unique maximum open packing can be obtained by a sequence of these operations starting from $P_2$. We also prove that the decision version of the open packing number is NP-complete even when restricted to graphs of girth at least $6$. Finally, we show that the recognition of the graphs with a unique maximum open packing is polynomially equivalent to the recognition of the graphs with a unique maximum independent set, and we prove that the complexity of both problems is not polynomial, unless P=NP., 16 pages, 4 figures

Published

2019