Your search keyword '"Chandran L"' showing total 556 results

1. Two Results on LPT: A Near-Linear Time Algorithm and Parcel Delivery using Drones

Author

Chandran, L. Sunil, Gajjala, Rishikesh, Mehra, Shravan, and Rahul, Saladi

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Geometry, Computer Science - Robotics

Abstract

The focus of this paper is to increase our understanding of the Longest Processing Time First (LPT) heuristic. LPT is a classical heuristic for the fundamental problem of uniform machine scheduling. For different machine speeds, LPT was first considered by Gonzalez et al (SIAM J. Computing, 1977). Since then, extensive work has been done to improve the approximation factor of the LPT heuristic. However, all known implementations of the LPT heuristic take $O(mn)$ time, where $m$ is the number of machines and $n$ is the number of jobs. In this work, we come up with the first near-linear time implementation for LPT. Specifically, the running time is $O((n+m)(\log^2{m}+\log{n}))$. Somewhat surprisingly, the result is obtained by mapping the problem to dynamic maintenance of lower envelope of lines, which has been well studied in the computational geometry community. Our second contribution is to analyze the performance of LPT for the Drones Warehouse Problem (DWP), which is a natural generalization of the uniform machine scheduling problem motivated by drone-based parcel delivery from a warehouse. In this problem, a warehouse has multiple drones and wants to deliver parcels to several customers. Each drone picks a parcel from the warehouse, delivers it, and returns to the warehouse (where it can also get charged). The speeds and battery lives of the drones could be different, and due to the limited battery life, each drone has a bounded range in which it can deliver parcels. The goal is to assign parcels to the drones so that the time taken to deliver all the parcels is minimized. We prove that the natural approach of solving this problem via the LPT heuristic has an approximation factor of $\phi$, where $\phi \approx 1.62$ is the golden ratio., Comment: To appear in FSTTCS 2024

Published

2024

2. Krenn-Gu conjecture for sparse graphs

Author

Chandran, L. Sunil, Gajjala, Rishikesh, and Illickan, Abraham M.

Subjects

Quantum Physics, Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

Greenberger-Horne-Zeilinger (GHZ) states are quantum states involving at least three entangled particles. They are of fundamental interest in quantum information theory, and the construction of such states of high dimension has various applications in quantum communication and cryptography. They are of fundamental interest in quantum information theory, and the construction of such states of high dimension has various applications in quantum communication and cryptography. Krenn, Gu and Zeilinger discovered a correspondence between a large class of quantum optical experiments which produce GHZ states and edge-weighted edge-coloured multi-graphs with some special properties called the \emph{GHZ graphs}. On such GHZ graphs, a graph parameter called \emph{dimension} can be defined, which is the same as the dimension of the GHZ state produced by the corresponding experiment. Krenn and Gu conjectured that the dimension of any GHZ graph with more than $4$ vertices is at most $2$. An affirmative resolution of the Krenn-Gu conjecture has implications for quantum resource theory. On the other hand, the construction of a GHZ graph on a large number of vertices with a high dimension would lead to breakthrough results. In this paper, we study the existence of GHZ graphs from the perspective of the Krenn-Gu conjecture and show that the conjecture is true for graphs of vertex connectivity at most 2 and for cubic graphs. We also show that the minimal counterexample to the conjecture should be $4$-connected. Such information could be of great help in the search for GHZ graphs using existing tools like PyTheus. While the impact of the work is in quantum physics, the techniques in this paper are purely combinatorial, and no background in quantum physics is required to understand them., Comment: To appear in MFCS 2024

Published

2024

3. $\chi$-binding functions for squares of bipartite graphs and its subclasses

Author

Chakraborty, Dibyayan, Chandran, L. Sunil, Jacob, Dalu, and Pillai, Raji R.

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics

Abstract

A class of graphs $\mathcal{G}$ is $\chi$-bounded if there exists a function $f$ such that $\chi(G) \leq f(\omega(G))$ for each graph $G \in \mathcal{G}$, where $\chi(G)$ and $\omega(G)$ are the chromatic and clique number of $G$, respectively. The square of a graph $G$, denoted as $G^2$, is the graph with the same vertex set as $G$ in which two vertices are adjacent when they are at a distance at most two in $G$. In this paper, we study the $\chi$-boundedness of squares of bipartite graphs and its subclasses. Note that the class of squares of graphs, in general, admit a quadratic $\chi$-binding function. Moreover there exist bipartite graphs $B$ for which $\chi\left(B^2\right)$ is $\Omega\left(\frac{\left(\omega\left(B^2\right)\right)^2 }{\log \omega\left(B^2\right)}\right)$. We first ask the following question: "What sub-classes of bipartite graphs have a linear $\chi$-binding function?" We focus on the class of convex bipartite graphs and prove the following result: for any convex bipartite graph $G$, $\chi\left(G^2\right) \leq \frac{3 \omega\left(G^2\right)}{2}$. Our proof also yields a polynomial-time $3/2$-approximation algorithm for coloring squares of convex bipartite graphs. We then introduce a notion called "partite testable properties" for the squares of bipartite graphs. We say that a graph property $P$ is partite testable for the squares of bipartite graphs if for a bipartite graph $G=(A,B,E)$, whenever the induced subgraphs $G^2[A]$ and $G^2[B]$ satisfies the property $P$ then $G^2$ also satisfies the property $P$. Here, we discuss whether some of the well-known graph properties like perfectness, chordality, (anti-hole)-freeness, etc. are partite testable or not. As a consequence, we prove that the squares of biconvex bipartite graphs are perfect., Comment: 22 pages, 5 figures

Published

2023

4. Total Domination, Separated Clusters, CD-Coloring: Algorithms and Hardness

Author

Antony, Dhanyamol, Chandran, L. Sunil, Gayen, Ankit, Gosavi, Shirish, and Jacob, Dalu

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Discrete Mathematics

Abstract

Domination and coloring are two classic problems in graph theory. The major focus of this paper is the CD-COLORING problem which combines the flavours of domination and colouring. Let $G$ be an undirected graph. A proper vertex coloring of $G$ is a $cd-coloring$ if each color class has a dominating vertex in $G$. The minimum integer $k$ for which there exists a $cd-coloring$ of $G$ using $k$ colors is called the cd-chromatic number, $\chi_{cd}(G)$. A set $S\subseteq V(G)$ is a total dominating set if any vertex in $G$ has a neighbor in $S$. The total domination number, $\gamma_t(G)$ of $G$ is the minimum integer $k$ such that $G$ has a total dominating set of size $k$. A set $S\subseteq V(G)$ is a $separated-cluster$ if no two vertices in $S$ lie at a distance 2 in $G$. The separated-cluster number, $\omega_s(G)$, of $G$ is the maximum integer $k$ such that $G$ has a separated-cluster of size $k$. In this paper, first we explore the connection between CD-COLORING and TOTAL DOMINATION. We prove that CD-COLORING and TOTAL DOMINATION are NP-Complete on triangle-free $d$-regular graphs for each fixed integer $d\geq 3$. We also study the relationship between the parameters $\chi_{cd}(G)$ and $\omega_s(G)$. Analogous to the well-known notion of `perfectness', here we introduce the notion of `cd-perfectness'. We prove a sufficient condition for a graph $G$ to be cd-perfect (i.e. $\chi_{cd}(H)= \omega_s(H)$, for any induced subgraph $H$ of $G$) which is also necessary for certain graph classes (like triangle-free graphs). Here, we propose a generalized framework via which we obtain several exciting consequences in the algorithmic complexities of special graph classes. In addition, we settle an open problem by showing that the SEPARATED-CLUSTER is polynomially solvable for interval graphs.

Published

2023

5. Graph-theoretic insights on the constructability of complex entangled states

Author

Chandran, L. Sunil and Gajjala, Rishikesh

Subjects

Quantum Physics, Computer Science - Discrete Mathematics

Abstract

The most efficient automated way to construct a large class of quantum photonic experiments is via abstract representation of graphs with certain properties. While new directions were explored using Artificial intelligence and SAT solvers to find such graphs, it becomes computationally infeasible to do so as the size of the graph increases. So, we take an analytical approach and introduce the technique of local sparsification on experiment graphs, using which we answer a crucial open question in experimental quantum optics, namely whether certain complex entangled quantum states can be constructed. This provides us with more insights into quantum resource theory, the limitation of specific quantum photonic systems and initiates the use of graph-theoretic techniques for designing quantum physics experiments., Comment: 18 pages. Accepted in Quantum Journal

Published

2023

6. Total Domination, Separated-Cluster, CD-Coloring: Algorithms and Hardness

Author

Antony, Dhanyamol, Chandran, L. Sunil, Gayen, Ankit, Gosavi, Shirish, Jacob, Dalu, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Soto, José A., editor, and Wiese, Andreas, editor

Published

2024

7. s-Club Cluster Vertex Deletion on Interval and Well-Partitioned Chordal Graphs

Author

Chakraborty, Dibyayan, Chandran, L. Sunil, Padinhatteeri, Sajith, and Pillai, Raji. R.

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics

Abstract

In this paper, we study the computational complexity of \textsc{$s$-Club Cluster Vertex Deletion}. Given a graph, \textsc{$s$-Club Cluster Vertex Deletion ($s$-CVD)} aims to delete the minimum number of vertices from the graph so that each connected component of the resulting graph has a diameter at most $s$. When $s=1$, the corresponding problem is popularly known as \sloppy \textsc{Cluster Vertex Deletion (CVD)}. We provide a faster algorithm for \textsc{$s$-CVD} on \emph{interval graphs}. For each $s\geq 1$, we give an $O(n(n+m))$-time algorithm for \textsc{$s$-CVD} on interval graphs with $n$ vertices and $m$ edges. In the case of $s=1$, our algorithm is a slight improvement over the $O(n^3)$-time algorithm of Cao \etal (Theor. Comput. Sci., 2018) and for $s \geq 2$, it significantly improves the state-of-the-art running time $\left(O\left(n^4\right)\right)$. We also give a polynomial-time algorithm to solve \textsc{CVD} on \emph{well-partitioned chordal graphs}, a graph class introduced by Ahn \etal (\textsc{WG 2020}) as a tool for narrowing down complexity gaps for problems that are hard on chordal graphs, and easy on split graphs. Our algorithm relies on a characterisation of the optimal solution and on solving polynomially many instances of the \textsc{Weighted Bipartite Vertex Cover}. This generalises a result of Cao \etal (Theor. Comput. Sci., 2018) on split graphs. We also show that for any even integer $s\geq 2$, \textsc{$s$-CVD} is NP-hard on well-partitioned chordal graphs.

Published

2022

8. List recoloring of planar graphs

Author

Chandran, L. Sunil, Gupta, Uttam K., and Pradhan, Dinabandhu

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics

Abstract

A list assignment $L$ of a graph $G$ is a function that assigns to every vertex $v$ of $G$ a set $L(v)$ of colors. A proper coloring $\alpha$ of $G$ is called an $L$-coloring of $G$ if $\alpha(v)\in L(v)$ for every $v\in V(G)$. For a list assignment $L$ of $G$, the $L$-recoloring graph $\mathcal{G}(G,L)$ of $G$ is a graph whose vertices correspond to the $L$-colorings of $G$ and two vertices of $\mathcal{G}(G,L)$ are adjacent if their corresponding $L$-colorings differ at exactly one vertex of $G$. A $d$-face in a plane graph is a face of length $d$. Dvo\v{r}\'ak and Feghali conjectured for a planar graph $G$ and a list assignment $L$ of $G$, that: (i) If $|L(v)|\geq 10$ for every $v\in V(G)$, then the diameter of $\mathcal{G}(G,L)$ is $O(|V(G)|)$. (ii) If $G$ is triangle-free and $|L(v)|\geq 7$ for every $v\in V(G)$, then the diameter of $\mathcal{G}(G,L)$ is $O(|V(G)|)$. In a recent paper, Cranston (European J. Combin. (2022)) has proved (ii). In this paper, we prove the following results. Let $G$ be a plane graph and $L$ be a list assignment of $G$. $\bullet$ If for every $3$-face of $G$, there are at most two $3$-faces adjacent to it and $|L(v)|\geq 10$ for every $v\in V(G)$, then the diameter of $\mathcal{G}(G,L)$ is at most $190|V(G)|$. $\bullet$ If for every $3$-face of $G$, there is at most one $3$-face adjacent to it and $|L(v)|\geq 9$ for every $v\in V(G)$, then the diameter of $\mathcal{G}(G,L)$ is at most $13|V(G)|$. $\bullet$ If the faces adjacent to any $3$-face have length at least $6$ and $|L(v)|\geq 7$ for every $v\in V(G)$, then the diameter of $\mathcal{G}(G,L)$ is at most $242|V(G)|$. This result strengthens the Cranston's result on (ii).

Published

2022

9. Edge-coloured graphs with only monochromatic perfect matchings and their connection to quantum physics

Author

Chandran, L. Sunil and Gajjala, Rishikesh

Subjects

Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Mathematical Physics, Mathematics - Combinatorics

Abstract

Krenn, Gu and Zeilinger initiated the study of PMValid edge-colourings because of its connection to a problem from quantum physics. A graph is defined to have a PMValid $k$-edge-colouring if it admits a $k$-edge-colouring (i.e. an edge colouring with $k$-colours) with the property that all perfect matchings are monochromatic and each of the $k$ colour classes contain at least one perfect matching. The matching index of a graph $G$, $\mu(G)$ is defined as the maximum value of $k$ for which $G$ admits a PMValid $k$-edge-colouring. It is easy to see that $\mu(G)\geq 1$ if and only if $G$ has a perfect matching (due to the trivial $1$-edge-colouring which is PMValid). Bogdanov observed that for all graphs non-isomorphic to $K_4$, $\mu(G)\leq 2$ and $\mu(K_4)=3$. However, the characterisation of graphs for which $\mu(G)=1$ and $\mu(G)=2$ is not known. In this work, we answer this question. Using this characterisation, we also give a fast algorithm to compute $\mu(G)$ of a graph $G$. In view of our work, the structure of PMValid $k$-edge-colourable graphs is now fully understood for all $k$. Our characterisation, also has an implication to the aforementioned quantum physics problem. In particular, it settles a conjecture of Krenn and Gu for a sub-class of graphs., Comment: 18 pages and 7 figures

Published

2022

10. Variants of the Gy\`arf\`as-Sumner Conjecture: Oriented Trees and Rainbow Paths

Author

Basavaraju, Manu, Chandran, L. Sunil, Francis, Mathew C., and Murali, Karthik

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C15, G.2.2

Abstract

Given a finite family $\mathcal{F}$ of graphs, we say that a graph $G$ is "$\mathcal{F}$-free" if $G$ does not contain any graph in $\mathcal{F}$ as a subgraph. A vertex-colored graph $H$ is called "rainbow" if no two vertices of $H$ have the same color. Given an integer $s$ and a finite family of graphs $\mathcal{F}$, let $\ell(s,\mathcal{F})$ denote the smallest integer such that any properly vertex-colored $\mathcal{F}$-free graph $G$ having $\chi(G)\geq\ell(s,\mathcal{F})$ contains an induced rainbow path on $s$ vertices. Scott and Seymour showed that $\ell(s,K)$ exists for every complete graph $K$. A conjecture of N. R. Aravind states that $\ell(s,C_3)=s$. The upper bound on $\ell(s,C_3)$ that can be obtained using the methods of Scott and Seymour setting $K=C_3$ are, however, super-exponential. Gy\'arf\'as and S\'ark\"ozy showed that $\ell(s,\{C_3,C_4\})=\mathcal{O}\big((2s)^{2s}\big)$. For $r\geq 2$, we show that $\ell(s,K_{2,r})\leq (r-1)(s-1)(s-2)/2+s$ and therefore, $\ell(s,C_4)\leq\frac{s^2-s+2}{2}$. This significantly improves Gy\'arf\'as and S\'ark\"ozy's bound and also covers a bigger class of graphs. We adapt our proof to achieve much stronger upper bounds for graphs of higher girth: we prove that $\ell(s,\{C_3,C_4,\ldots,C_{g-1}\})\leq s^{1+\frac{4}{g-4}}$, where $g\geq 5$. Moreover, in each case, our results imply the existence of at least $s!/2$ distinct induced rainbow paths on $s$ vertices. Along the way, we obtain some results on related problems on oriented graphs. For $r\geq 2$, let $\mathcal{B}_r$ denote the orientations of $K_{2,r}$ in which one vertex has out-degree or in-degree $r$. We show that every $\mathcal{B}_r$-free oriented graph $G$ having $\chi(G)\geq (r-1)(s-1)(s-2)+2s+1$ and every bikernel-perfect oriented graph $G$ with girth $g\geq 5$ having $\chi(G)\geq 2s^{1+\frac{4}{g-4}}$ contains every $s$ vertex oriented tree as an induced subgraph., Comment: 21 pages, 1 figure

Published

2021

11. Weakening Total Coloring Conjecture: Weak TCC and Hadwiger's Conjecture on Total Graphs

Author

Basavaraju, Manu, Chandran, L. Sunil, Francis, Mathew C., and Naskar, Ankur

Subjects

Mathematics - Combinatorics

Abstract

Hadwiger's conjecture is one of the most important and long-standing conjectures in graph theory. Reed and Seymour showed in 2004 that Hadwiger's conjecture is true for line graphs. We investigate this conjecture on the closely related class of total graphs. The total graph of $G$, denoted by $T(G)$, is defined on the vertex set $V(G)\sqcup E(G)$ with $c_1,c_2\in V(G)\sqcup E(G)$ adjacent whenever $c_1$ and $c_2$ are adjacent to or incident on each other in $G$. We first show that there exists a constant $C$ such that, if the connectivity of $G$ is at least $C$, then Hadwiger's conjecture is true for $T(G)$. The total chromatic number $\chi"(G)$ of a graph $G$ is defined to be equal to the chromatic number of its total graph. That is, $\chi"(G)=\chi(T(G))$. Another well-known conjecture in graph theory, the total coloring conjecture or TCC, states that for every graph $G$, $\chi"(G)\leq\Delta(G)+2$, where $\Delta(G)$ is the maximum degree of $G$. We show that if a weaker version of the total coloring conjecture (weak TCC) namely, $\chi"(G)\leq\Delta(G)+3$, is true for a class of graphs $\mathcal{F}$ that is closed under the operation of taking subgraphs, then Hadwiger's conjecture is true for the class of total graphs of graphs in $\mathcal{F}$. This motivated us to look for classes of graphs that satisfy weak TCC. It may be noted that a complete proof of TCC for even 4-colorable graphs (in fact even for planar graphs) has remained elusive even after decades of effort; but weak TCC can be proved easily for 4-colorable graphs. We noticed that in spite of the interest in studying $\chi"(G)$ in terms of $\chi(G)$ right from the initial days, weak TCC is not proven to be true for $k$-colorable graphs even for $k=5$. In the second half of the paper, we make a contribution to the literature on total coloring by proving that $\chi"(G)\leq\Delta(G)+3$ for every 5-colorable graph $G$.

Published

2021

12. New bounds on the anti-Ramsey numbers of star graphs via maximum edge q-coloring

Author

Chandran, L. Sunil, Hashim, Talha, Jacob, Dalu, Mathew, Rogers, Rajendraprasad, Deepak, and Singh, Nitin

Published

2024

13. s-Club Cluster Vertex Deletion on interval and well-partitioned chordal graphs

Author

Chakraborty, Dibyayan, Chandran, L. Sunil, Padinhatteeri, Sajith, and Pillai, Raji R.

Published

2024

14. Upper Bounding Rainbow Connection Number by Forest Number

Author

Chandran, L. Sunil, Issac, Davis, Lauri, Juho, and van Leeuwen, Erik Jan

Subjects

Mathematics - Combinatorics, 05C15

Abstract

A path in an edge-colored graph is rainbow if no two edges of it are colored the same, and the graph is rainbow-connected if there is a rainbow path between each pair of its vertices. The minimum number of colors needed to rainbow-connect a graph $G$ is the rainbow connection number of $G$, denoted by $\text{rc}(G)$. A simple way to rainbow-connect a graph $G$ is to color the edges of a spanning tree with distinct colors and then re-use any of these colors to color the remaining edges of $G$. This proves that $\text{rc}(G) \le |V(G)|-1$. We ask whether there is a stronger connection between tree-like structures and rainbow coloring than that is implied by the above trivial argument. For instance, is it possible to find an upper bound of $t(G) -1$ for $\text{rc}(G)$, where $t(G)$ is the number of vertices in the largest induced tree of $G$? The answer turns out to be negative, as there are counter-examples that show that even $c\cdot t(G)$ is not an upper bound for $\text{rc}(G))$ for any given constant $c$. In this work we show that if we consider the forest number $f(G)$, the number of vertices in a maximum induced forest of $G$, instead of $t(G)$, then surprisingly we do get an upper bound. More specifically, we prove that $\text{rc}(G) \leq f(G) + 2$. Our result indicates a stronger connection between rainbow connection and tree-like structures than that was suggested by the simple spanning tree based upper bound.

Published

2020

15. Combinatorial lower bounds for 3-query LDCs

Author

Bhattacharyya, Arnab, Chandran, L. Sunil, and Ghoshal, Suprovat

Subjects

Computer Science - Computational Complexity, Mathematics - Combinatorics

Abstract

A code is called a $q$-query locally decodable code (LDC) if there is a randomized decoding algorithm that, given an index $i$ and a received word $w$ close to an encoding of a message $x$, outputs $x_i$ by querying only at most $q$ coordinates of $w$. Understanding the tradeoffs between the dimension, length and query complexity of LDCs is a fascinating and unresolved research challenge. In particular, for $3$-query binary LDCs of dimension $k$ and length $n$, the best known bounds are: $2^{k^{o(1)}} \geq n \geq \tilde{\Omega}(k^2)$. In this work, we take a second look at binary $3$-query LDCs. We investigate a class of 3-uniform hypergraphs that are equivalent to strong binary 3-query LDCs. We prove an upper bound on the number of edges in these hypergraphs, reproducing the known lower bound of $\tilde{\Omega}(k^2)$ for the length of strong $3$-query LDCs. In contrast to previous work, our techniques are purely combinatorial and do not rely on a direct reduction to $2$-query LDCs, opening up a potentially different approach to analyzing 3-query LDCs., Comment: 10 pages

Published

2019

16. Improved Approximation for Maximum Edge Colouring Problem

Author

Chandran, L Sunil, Lahiri, Abhiruk, and Singh, Nitin

Subjects

Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms

Abstract

The anti-Ramsey number, $ar(G, H)$ is the minimum integer $k$ such that in any edge colouring of $G$ with $k$ colours there is a rainbow subgraph isomorphic to $H$, i.e., a copy of $H$ with each of its edges assigned a different colour. The notion was introduced by Erd{\"{o}}s and Simonovits in 1973. Since then the parameter has been studied extensively in combinatorics, also the particular case when $H$ is a star graph. Recently this case received the attention of researchers from the algorithm community because of its applications in interface modelling of wireless networks. To the algorithm community, the problem is known as maximum edge $q$-colouring problem. In this paper, we study the maximum edge $2$-colouring problem from the approximation algorithm point of view. The case $q=2$ is particularly interesting due to its application in real-life problems. Algorithmically, this problem is known to be NP-hard for $q\ge 2$. For the case of $q=2$, it is also known that no polynomial-time algorithm can approximate to a factor less than $3/2$ assuming the unique games conjecture. Feng et al. showed a $2$-approximation algorithm for this problem. Later Adamaszek and Popa presented a $5/3$-approximation algorithm with the additional assumption that the input graph has a perfect matching. Note that the obvious but the only known algorithm issues different colours to the edges of a maximum matching (say $M$) and different colours to the connected components of $G \setminus M$. In this article, we give a new analysis of the aforementioned algorithm leading to an improved approximation bound for triangle-free graphs with perfect matching. We also show a new lower bound when the input graph is triangle-free. The contribution of the paper is a completely new, deeper and closer analysis of how the optimum achieves a higher number of colours than the matching based algorithm, mentioned above., Comment: 13 pages, 4 figures

Published

2019

17. On Graphs whose Eternal Vertex Cover Number and Vertex Cover Number Coincide

Author

Babu, Jasine, Chandran, L. Sunil, Francis, Mathew, Prabhakaran, Veena, Rajendraprasad, Deepak, and Warrier, J. Nandini

Subjects

Computer Science - Discrete Mathematics

Abstract

The eternal vertex cover problem is a variant of the classical vertex cover problem where a set of guards on the vertices have to be dynamically reconfigured from one vertex cover to another in every round of an attacker-defender game. The minimum number of guards required to protect a graph $G$ from an infinite sequence of attacks is the eternal vertex cover number of $G$, denoted by $evc(G)$. It is known that, given a graph $G$ and an integer $k$, checking whether $evc(G) \le k$ is NP-hard. However, it is unknown whether this problem is in NP or not. Precise value of eternal vertex cover number is known only for certain very basic graph classes like trees, cycles and grids. For any graph $G$, it is known that $mvc(G) \le evc(G) \le 2 mvc(G)$, where $mvc(G)$ is the minimum vertex cover number of $G$. Though a characterization is known for graphs for which $evc(G) = 2 mvc(G)$, a characterization of graphs for which $evc(G) = mvc(G)$ remained open. Here, we achieve such a characterization for a class of graphs that includes chordal graphs and internally triangulated planar graphs. For some graph classes including biconnected chordal graphs, our characterization leads to a polynomial time algorithm to precisely determine $evc(G)$ and to determine a safe strategy of guard movement in each round of the game with $evc(G)$ guards. The characterization also leads to NP-completeness results for the eternal vertex cover problem for some graph classes including biconnected internally triangulated planar graphs. To the best of our knowledge, these are the first NP-completeness results known for the problem for any graph class., Comment: Preliminary version appeared in CALDAM 2019

Published

2018

18. Template-driven rainbow coloring of proper interval graphs

Author

Chandran, L. Sunil, Das, Sajal K., Hell, Pavol, Padinhatteeri, Sajith, and Pillai, Raji R.

Published

2023

19. New bounds on the anti-Ramsey numbers of star graphs

Author

Chandran, L. Sunil, Hashim, Talha, Jacob, Dalu, Mathew, Rogers, Rajendraprasad, Deepak, and Singh, Nitin

Subjects

Computer Science - Discrete Mathematics, Mathematics - Combinatorics, 05C15, 68W25, G.2.2

Abstract

The anti-Ramsey number $ar(G,H)$ with input graph $G$ and pattern graph $H$, is the maximum positive integer $k$ such that there exists an edge coloring of $G$ using $k$ colors, in which there are no rainbow subgraphs isomorphic to $H$ in $G$. ($H$ is rainbow if all its edges get distinct colors). The concept of anti-Ramsey number was introduced by Erd\"os, Simanovitz, and S\'os in 1973. Thereafter several researchers investigated this concept in the combinatorial setting. Recently, Feng et al. revisited the anti-Ramsey problem for the pattern graph $K_{1,t}$ (for $t \geq 3$) purely from an algorithmic point of view due to its applications in interference modeling of wireless networks. They posed it as an optimization problem, the maximum edge $q$-coloring problem. For a graph $G$ and an integer $q\geq 2$, an edge $q$-coloring of $G$ is an assignment of colors to edges of $G$, such that edges incident on a vertex span at most $q$ distinct colors. The maximum edge $q$-coloring problem seeks to maximize the number of colors in an edge $q$-coloring of the graph $G$. Note that the optimum value of the edge $q$-coloring problem of $G$ equals $ar(G,K_{1,q+1})$. In this paper, we study $ar(G,K_{1,t})$, the anti-Ramsey number of stars, for each fixed integer $t\geq 3$, both from combinatorial and algorithmic point of view. The first of our main results presents an upper bound for $ar(G,K_{1,q+1})$, in terms of number of vertices and the minimum degree of $G$. The second one improves this result for the case of triangle-free input graphs. For a positive integer $t$, let $H_t$ denote a subgraph of $G$ with maximum number of possible edges and maximum degree $t$. Our third main result presents an upper bound for $ar(G,K_{1,q+1})$ in terms of $|E(H_{q-1})|$. All our results have algorithmic consequences., Comment: 19 pages, 3 figures

Published

2018

20. On Eulerian orientations of even-degree hypercubes

Author

Levit, Maxwell, Chandran, L. Sunil, and Cheriyan, Joseph

Subjects

Mathematics - Combinatorics, 05C40, 68R10

Abstract

It is well known that \textit{every} Eulerian orientation of an Eulerian $2k$-edge connected (undirected) graph is strongly $k$-edge connected. An important goal in the area is to obtain analogous results for other types of connectivity, such as node connectivity and element connectivity. We show that \textit{every} Eulerian orientation of the hypercube of degree $2k$ is strongly $k$-node connected.

Published

2018

21. Spanning Tree Congestion and Computation of Generalized Gy\H{o}ri-Lov\'{a}sz Partition

Author

Chandran, L. Sunil, Cheung, Yun Kuen, and Issac, Davis

Subjects

Computer Science - Data Structures and Algorithms, Computer Science - Computational Complexity, Computer Science - Discrete Mathematics

Abstract

We study a natural problem in graph sparsification, the Spanning Tree Congestion (\STC) problem. Informally, the \STC problem seeks a spanning tree with no tree-edge \emph{routing} too many of the original edges. The root of this problem dates back to at least 30 years ago, motivated by applications in network design, parallel computing and circuit design. Variants of the problem have also seen algorithmic applications as a preprocessing step of several important graph algorithms. For any general connected graph with $n$ vertices and $m$ edges, we show that its STC is at most $\mathcal{O}(\sqrt{mn})$, which is asymptotically optimal since we also demonstrate graphs with STC at least $\Omega(\sqrt{mn})$. We present a polynomial-time algorithm which computes a spanning tree with congestion $\mathcal{O}(\sqrt{mn}\cdot \log n)$. We also present another algorithm for computing a spanning tree with congestion $\mathcal{O}(\sqrt{mn})$; this algorithm runs in sub-exponential time when $m = \omega(n \log^2 n)$. For achieving the above results, an important intermediate theorem is \emph{generalized Gy\H{o}ri-Lov\'{a}sz theorem}, for which Chen et al. gave a non-constructive proof. We give the first elementary and constructive proof by providing a local search algorithm with running time $\mathcal{O}^*\left( 4^n \right)$, which is a key ingredient of the above-mentioned sub-exponential time algorithm. We discuss a few consequences of the theorem concerning graph partitioning, which might be of independent interest. We also show that for any graph which satisfies certain \emph{expanding properties}, its STC is at most $\mathcal{O}(n)$, and a corresponding spanning tree can be computed in polynomial time. We then use this to show that a random graph has STC $\Theta(n)$ with high probability.

Published

2018

22. Improved approximation for maximum edge colouring problem

Author

Chandran, L. Sunil, Lahiri, Abhiruk, and Singh, Nitin

Published

2022

23. On graphs whose eternal vertex cover number and vertex cover number coincide

Author

Babu, Jasine, Chandran, L. Sunil, Francis, Mathew, Prabhakaran, Veena, Rajendraprasad, Deepak, and Warrier, Nandini J.

Published

2022

24. Upper bounding rainbow connection number by forest number

Author

Sunil Chandran, L., Issac, Davis, Lauri, Juho, and van Leeuwen, Erik Jan

Published

2022

25. Algorithms and Bounds for Very Strong Rainbow Coloring

Author

Chandran, L. Sunil, Das, Anita, Issac, Davis, and van Leeuwen, Erik Jan

Subjects

Computer Science - Data Structures and Algorithms, Mathematics - Combinatorics

Abstract

A well-studied coloring problem is to assign colors to the edges of a graph $G$ so that, for every pair of vertices, all edges of at least one shortest path between them receive different colors. The minimum number of colors necessary in such a coloring is the strong rainbow connection number ($\src(G)$) of the graph. When proving upper bounds on $\src(G)$, it is natural to prove that a coloring exists where, for \emph{every} shortest path between every pair of vertices in the graph, all edges of the path receive different colors. Therefore, we introduce and formally define this more restricted edge coloring number, which we call \emph{very strong rainbow connection number} ($\vsrc(G)$). In this paper, we give upper bounds on $\vsrc(G)$ for several graph classes, some of which are tight. These immediately imply new upper bounds on $\src(G)$ for these classes, showing that the study of $\vsrc(G)$ enables meaningful progress on bounding $\src(G)$. Then we study the complexity of the problem to compute $\vsrc(G)$, particularly for graphs of bounded treewidth, and show this is an interesting problem in its own right. We prove that $\vsrc(G)$ can be computed in polynomial time on cactus graphs; in contrast, this question is still open for $\src(G)$. We also observe that deciding whether $\vsrc(G) = k$ is fixed-parameter tractable in $k$ and the treewidth of $G$. Finally, on general graphs, we prove that there is no polynomial-time algorithm to decide whether $\vsrc(G) \leq 3$ nor to approximate $\vsrc(G)$ within a factor $n^{1-\varepsilon}$, unless P$=$NP.

Published

2017

26. Variants of the Gyárfás–Sumner conjecture: Oriented trees and rainbow paths.

Author

Basavaraju, Manu, Chandran, L. Sunil, Francis, Mathew C., and Murali, Karthik

Subjects

*INTEGERS, *LOGICAL prediction, *TREES, *FAMILIES

Abstract

Given a finite family ℱ ${\rm{ {\mathcal F} }}$ of graphs, we say that a graph G $G$ is “ℱ ${\rm{ {\mathcal F} }}$‐free” if G $G$ does not contain any graph in ℱ ${\rm{ {\mathcal F} }}$ as a subgraph. We abbreviate ℱ ${\rm{ {\mathcal F} }}$‐free to just “F $F$‐free” when ℱ={F} ${\rm{ {\mathcal F} }}=\{F\}$. A vertex‐colored graph H $H$ is called “rainbow” if no two vertices of H $H$ have the same color. Given an integer s $s$ and a finite family of graphs ℱ ${\rm{ {\mathcal F} }}$, let ℓ(s,ℱ) $\ell (s,{\rm{ {\mathcal F} }})$ denote the smallest integer such that any properly vertex‐colored ℱ ${\rm{ {\mathcal F} }}$‐free graph G $G$ having χ(G)≥ℓ(s,ℱ) $\chi (G)\ge \ell (s,{\rm{ {\mathcal F} }})$ contains an induced rainbow path on s $s$ vertices. Scott and Seymour showed that ℓ(s,K) $\ell (s,K)$ exists for every complete graph K $K$. A conjecture of N. R. Aravind states that ℓ(s,C3)=s $\ell (s,{C}_{3})=s$. The upper bound on ℓ(s,C3) $\ell (s,{C}_{3})$ that can be obtained using the methods of Scott and Seymour setting K=C3 $K={C}_{3}$ are, however, super‐exponential. Gyárfás and Sárközy showed that ℓ(s,{C3,C4})=O((2s)2s) $\ell (s,\{{C}_{3},{C}_{4}\})={\mathscr{O}}({(2s)}^{2s})$. For r≥2 $r\ge 2$, we show that ℓ(s,K2,r)≤(r−1)(s−1)(s−2)∕2+s $\ell (s,{K}_{2,r})\le (r-1)(s-1)(s-2)\unicode{x02215}2+s$ and therefore, ℓ(s,C4)≤s2−s+22 $\ell (s,{C}_{4})\,\le \,\frac{{s}^{2}-s+2}{2}$. This significantly improves Gyárfás and Sárközy's bound and also covers a bigger class of graphs. We adapt our proof to achieve much stronger upper bounds for graphs of higher girth: we prove that ℓ(s,{C3,C4,…,Cg−1})≤s1+4g−4 $\ell (s,\{{C}_{3},{C}_{4},\ldots ,{C}_{g-1}\})\le {s}^{1+\frac{4}{g-4}}$, where g≥5 $g\ge 5$. Moreover, in each case, our results imply the existence of at least s!∕2 $s!\unicode{x02215}2$ distinct induced rainbow paths on s $s$ vertices. Along the way, we obtain some new results on an oriented variant of the Gyárfás–Sumner conjecture. For r≥2 $r\ge 2$, let ℬr ${{\rm{ {\mathcal B} }}}_{r}$ denote the orientations of K2,r ${K}_{2,r}$ in which one vertex has out‐degree or in‐degree r $r$. We show that every ℬr ${{\rm{ {\mathcal B} }}}_{r}$‐free oriented graph having a chromatic number at least (r−1)(s−1)(s−2)+2s+1 $(r-1)(s-1)(s-2)+2s+1$ and every bikernel‐perfect oriented graph with girth g≥5 $g\ge 5$ having a chromatic number at least 2s1+4g−4 $2{s}^{1+\frac{4}{g-4}}$ contains every oriented tree on at most s $s$ vertices as an induced subgraph. [ABSTRACT FROM AUTHOR]

Published

2024

27. Algorithms and Complexity of s-Club Cluster Vertex Deletion

Author

Chakraborty, Dibyayan, Chandran, L. Sunil, Padinhatteeri, Sajith, Pillai, Raji R., Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Flocchini, Paola, editor, and Moura, Lucia, editor

Published

2021

28. Template-Driven Rainbow Coloring of Proper Interval Graphs

Author

Chandran, L. Sunil, Das, Sajal K., Hell, Pavol, Padinhatteeri, Sajith, Pillai, Raji R., Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Mudgal, Apurva, editor, and Subramanian, C. R., editor

Published

2021

29. List Distinguishing Number of Power of Hypercube and Cartesian Powers of a Graph

Author

Chandran, L. Sunil, Padinhatteeri, Sajith, Ravi Shankar, Karthik, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Changat, Manoj, editor, and Das, Sandip, editor

Published

2020

30. On Induced Colourful Paths in Triangle-free Graphs

Author

Babu, Jasine, Basavaraju, Manu, Chandran, L. Sunil, and Francis, Mathew C.

Subjects

Mathematics - Combinatorics, 05C15, G.2.2

Abstract

Given a graph $G=(V,E)$ whose vertices have been properly coloured, we say that a path in $G$ is "colourful" if no two vertices in the path have the same colour. It is a corollary of the Gallai-Roy-Vitaver Theorem that every properly coloured graph contains a colourful path on $\chi(G)$ vertices. We explore a conjecture that states that every properly coloured triangle-free graph $G$ contains an induced colourful path on $\chi(G)$ vertices and prove its correctness when the girth of $G$ is at least $\chi(G)$. Recent work on this conjecture by Gy\'arf\'as and S\'ark\"ozy, and Scott and Seymour has shown the existence of a function $f$ such that if $\chi(G)\geq f(k)$, then an induced colourful path on $k$ vertices is guaranteed to exist in any properly coloured triangle-free graph $G$., Comment: 8 pages, 3 figures

Published

2016

31. Hadwiger's Conjecture for squares of 2-Trees

Author

Chandran, L. Sunil, Issac, Davis, and Zhou, Sanming

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics

Abstract

Hadwiger's conjecture asserts that any graph contains a clique minor with order no less than the chromatic number of the graph. We prove that this well-known conjecture is true for all graphs if and only if it is true for squares of split graphs. This observation implies that Hadwiger's conjecture for squares of chordal graphs is as difficult as the general case, since chordal graphs are a superclass of split graphs. Then we consider 2-trees which are a subclass of each of planar graphs, 2-degenerate graphs and chordal graphs. We prove that Hadwiger's conjecture is true for squares of $2$-trees. We achieve this by proving the following stronger result: for any $2$-tree $T$, its square $T^2$ has a clique minor of order $\chi(T^2)$ for which each branch set induces a path, where $\chi(T^2)$ is the chromatic number of $T^2$., Comment: 18 pages, 3 figures

Published

2016

32. s-Club Cluster Vertex Deletion on Interval and Well-Partitioned Chordal Graphs

Author

Chakraborty, Dibyayan, primary, Chandran, L. Sunil, additional, Padinhatteeri, Sajith, additional, and Pillai, Raji R., additional

Published

2022

33. Sublinear Approximation Algorithms for Boxicity and Related Problems

Author

Adiga, Abhijin, Babu, Jasine, and Chandran, L. Sunil

Subjects

Computer Science - Discrete Mathematics

Abstract

Boxicity of a graph G(V, E) is the minimum integer k such that G can be represented as the intersection graph of axis parallel boxes in $\mathbb{R}^k$. Cubicity is a variant of boxicity, where the axis parallel boxes in the intersection representation are restricted to be of unit length sides. Deciding whether boxicity (resp. cubicity) of a graph is at most k is NP-hard, even for k=2 or 3. Computing these parameters is inapproximable within $O(n^{1 - \epsilon})$-factor, for any $\epsilon >0$ in polynomial time unless NP=ZPP, even for many simple graph classes. In this paper, we give a polynomial time $\kappa(n)$ factor approximation algorithm for computing boxicity and a $\kappa(n)\lceil \log \log n\rceil$ factor approximation algorithm for computing the cubicity, where $\kappa(n) =2\left\lceil\frac{n\sqrt{\log \log n}}{\sqrt{\log n}}\right\rceil$. These o(n) factor approximation algorithms also produce the corresponding box (resp. cube) representations. As a special case, this resolves the question paused by Spinrad about polynomial time construction of o(n) dimensional box representations for boxicity 2 graphs. Other consequences of our approximation algorithm include $O(\kappa(n))$ factor approximation algorithms for computing the following parameters: the partial order dimension of finite posets, the interval dimension of finite posets, minimum chain cover of bipartite graphs, threshold dimension of split graphs and Ferrer's dimension of digraphs. Each of these parameters is inapproximable within an $O(n^{1 - \epsilon})$-factor, for any $\epsilon >0$ in polynomial time unless NP=ZPP and the algorithms we derive seem to be the first o(n) factor approximation algorithms known for all these problems., Comment: arXiv admin note: substantial text overlap with arXiv:1201.5958

Published

2015

34. On Graphs with Minimal Eternal Vertex Cover Number

Author

Babu, Jasine, Chandran, L. Sunil, Francis, Mathew, Prabhakaran, Veena, Rajendraprasad, Deepak, Warrier, J. Nandini, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Pal, Sudebkumar Prasant, editor, and Vijayakumar, Ambat, editor

Published

2019

35. Weak Total Coloring Conjecture and Hadwiger’s Conjecture on Total Graphs

Author

Basavaraju, Manu, primary, Chandran, L. Sunil, additional, Francis, Mathew, additional, and Naskar, Ankur, additional

Published

2024

36. Separation dimension of bounded degree graphs

Author

Alon, Noga, Basavaraju, Manu, Chandran, L. Sunil, Mathew, Rogers, and Rajendraprasad, Deepak

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C62

Abstract

The 'separation dimension' of a graph $G$ is the smallest natural number $k$ for which the vertices of $G$ can be embedded in $\mathbb{R}^k$ such that any pair of disjoint edges in $G$ can be separated by a hyperplane normal to one of the axes. Equivalently, it is the smallest possible cardinality of a family $\mathcal{F}$ of total orders of the vertices of $G$ such that for any two disjoint edges of $G$, there exists at least one total order in $\mathcal{F}$ in which all the vertices in one edge precede those in the other. In general, the maximum separation dimension of a graph on $n$ vertices is $\Theta(\log n)$. In this article, we focus on bounded degree graphs and show that the separation dimension of a graph with maximum degree $d$ is at most $2^{9log^{\star} d} d$. We also demonstrate that the above bound is nearly tight by showing that, for every $d$, almost all $d$-regular graphs have separation dimension at least $\lceil d/2\rceil$., Comment: One result proved in this paper is also present in arXiv:1212.6756

Published

2014

37. Upper bound on cubicity in terms of boxicity for graphs of low chromatic number

Author

Chandran, L. Sunil, Mathew, Rogers, and Rajendraprasad, Deepak

Subjects

Mathematics - Combinatorics, 05C62

Abstract

The boxicity (respectively cubicity) of a graph $G$ is the minimum non-negative integer $k$, such that $G$ can be represented as an intersection graph of axis-parallel $k$-dimensional boxes (respectively $k$-dimensional unit cubes) and is denoted by $box(G)$ (respectively $cub(G)$). It was shown by Adiga and Chandran (Journal of Graph Theory, 65(4), 2010) that for any graph $G$, $cub(G) \le$ box$(G) \left \lceil \log_2 \alpha \right \rceil$, where $\alpha = \alpha(G)$ is the cardinality of the maximum independent set in $G$. In this note we show that $cub(G) \le 2 \left \lceil \log_2 \chi(G) \right \rceil box(G) + \chi(G) \left \lceil \log_2 \alpha(G) \right \rceil $. In general, this result can provide a much better upper bound than that of Adiga and Chandran for graph classes with bounded chromatic number. For example, for bipartite graphs we get, $cub(G) \le 2 (box(G) + \left \lceil \log_2 \alpha(G) \right \rceil )$. Moreover we show that for every positive integer $k$, there exist graphs with chromatic number $k$, such that for every $\epsilon > 0$, the value given by our upper bound is at most $(1+\epsilon)$ times their cubicity. Thus, our upper bound is almost tight.

Published

2014

38. Boxicity and separation dimension

Author

Basavaraju, Manu, Chandran, L. Sunil, Golumbic, Martin Charles, Mathew, Rogers, and Rajendraprasad, Deepak

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C65, 05C62

Abstract

A family $\mathcal{F}$ of permutations of the vertices of a hypergraph $H$ is called 'pairwise suitable' for $H$ if, for every pair of disjoint edges in $H$, there exists a permutation in $\mathcal{F}$ in which all the vertices in one edge precede those in the other. The cardinality of a smallest such family of permutations for $H$ is called the 'separation dimension' of $H$ and is denoted by $\pi(H)$. Equivalently, $\pi(H)$ is the smallest natural number $k$ so that the vertices of $H$ can be embedded in $\mathbb{R}^k$ such that any two disjoint edges of $H$ can be separated by a hyperplane normal to one of the axes. We show that the separation dimension of a hypergraph $H$ is equal to the 'boxicity' of the line graph of $H$. This connection helps us in borrowing results and techniques from the extensive literature on boxicity to study the concept of separation dimension., Comment: This is the full version of a paper by the same name submitted to WG-2014. Some results proved in this paper are also present in arXiv:1212.6756. arXiv admin note: substantial text overlap with arXiv:1212.6756

Published

2014

39. Separation dimension of sparse graphs

Author

Basavaraju, Manu, Chandran, L. Sunil, Mathew, Rogers, and Rajendraprasad, Deepak

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C62

Abstract

The separation dimension of a graph $G$ is the smallest natural number $k$ for which the vertices of $G$ can be embedded in $\mathbb{R}^k$ such that any pair of disjoint edges in $G$ can be separated by a hyperplane normal to one of the axes. Equivalently, it is the smallest possible cardinality of a family $\mathcal{F}$ of permutations of the vertices of $G$ such that for any two disjoint edges of $G$, there exists at least one permutation in $\mathcal{F}$ in which all the vertices in one edge precede those in the other. In general, the maximum separation dimension of a graph on $n$ vertices is $\Theta(\log n)$. In this article, we focus on sparse graphs and show that the maximum separation dimension of a $k$-degenerate graph on $n$ vertices is $O(k \log\log n)$ and that there exists a family of $2$-degenerate graphs with separation dimension $\Omega(\log\log n)$. We also show that the separation dimension of the graph $G^{1/2}$ obtained by subdividing once every edge of another graph $G$ is at most $(1 + o(1)) \log\log \chi(G)$ where $\chi(G)$ is the chromatic number of the original graph., Comment: This is the full version of a paper to be presented at ICGT 2014. This is a subset of the results in arXiv:1212.6756

Published

2014

40. Rainbow Colouring of Split Graphs

Author

Chandran, L. Sunil, Rajendraprasad, Deepak, and Tesař, Marek

Subjects

Computer Science - Discrete Mathematics, Computer Science - Computational Complexity, Mathematics - Combinatorics, O5C15, 05C85 (Primary), 05C40 (Secondary), G.2.2, F.2.3

Abstract

A rainbow path in an edge coloured graph is a path in which no two edges are coloured the same. A rainbow colouring of a connected graph G is a colouring of the edges of G such that every pair of vertices in G is connected by at least one rainbow path. The minimum number of colours required to rainbow colour G is called its rainbow connection number. Between them, Chakraborty et al. [J. Comb. Optim., 2011] and Ananth et al. [FSTTCS, 2012] have shown that for every integer k, k \geq 2, it is NP-complete to decide whether a given graph can be rainbow coloured using k colours. A split graph is a graph whose vertex set can be partitioned into a clique and an independent set. Chandran and Rajendraprasad have shown that the problem of deciding whether a given split graph G can be rainbow coloured using 3 colours is NP-complete and further have described a linear time algorithm to rainbow colour any split graph using at most one colour more than the optimum [COCOON, 2012]. In this article, we settle the computational complexity of the problem on split graphs and thereby discover an interesting dichotomy. Specifically, we show that the problem of deciding whether a given split graph can be rainbow coloured using k colours is NP-complete for k \in {2,3}, but can be solved in polynomial time for all other values of k., Comment: This is the full version of a paper to be presented at ICGT 2014. This complements the results in arXiv:1205.1670 (which were presented in COCOON 2013), and both will be merged into a single journal submission

Published

2014

41. Approximating the Cubicity of Trees

Author

Babu, Jasine, Basavaraju, Manu, Chandran, L Sunil, Rajendraprasad, Deepak, and Sivadasan, Naveen

Subjects

Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms

Abstract

Cubicity of a graph $G$ is the smallest dimension $d$, for which $G$ is a unit disc graph in ${\mathbb{R}}^d$, under the $l^\infty$ metric, i.e. $G$ can be represented as an intersection graph of $d$-dimensional (axis-parallel) unit hypercubes. We call such an intersection representation a $d$-dimensional cube representation of $G$. Computing cubicity is known to be inapproximable in polynomial time, within an $O(n^{1-\epsilon})$ factor for any $\epsilon >0$, unless NP=ZPP. In this paper, we present a randomized algorithm that runs in polynomial time and computes cube representations of trees, of dimension within a constant factor of the optimum. It is also shown that the cubicity of trees can be approximated within a constant factor in deterministic polynomial time, if the cube representation is not required to be computed. As far as we know, this is the first constant factor approximation algorithm for computing the cubicity of trees. It is not yet clear whether computing the cubicity of trees is NP-hard or not.

Published

2014

42. On Additive Combinatorics of Permutations of \mathbb{Z}_n

Author

Chandran, L. Sunil, Rajendraprasad, Deepak, and Singh, Nitin

Subjects

Mathematics - Combinatorics, 11A05, 11A07, 11A41, 05E99, 05D05

Abstract

Let $\mathbb{Z}_n$ denote the ring of integers modulo $n$. In this paper we consider two extremal problems on permutations of $\mathbb{Z}_n$, namely, the maximum size of a collection of permutations such that the sum of any two distinct permutations in the collection is again a permutation, and the maximum size of a collection of permutations such that the sum of any two distinct permutations in the collection is not a permutation. Let the sizes be denoted by $s(n)$ and $t(n)$ respectively. The case when $n$ is even is trivial in both the cases, with $s(n)=1$ and $t(n)=n!$. For $n$ odd, we prove $s(n)\geq (n\phi(n))/2^k$ where $k$ is the number of distinct prime divisors of $n$. When $n$ is an odd prime we prove $s(n)\leq \frac{e^2}{\pi} n ((n-1)/e)^\frac{n-1}{2}$. For the second problem, we prove $2^{(n-1)/2}.(\frac{n-1}{2})!\leq t(n)\leq 2^k.(n-1)!/\phi(n)$ when $n$ is odd., Comment: 9 pages

Published

2014

43. Boxicity and Cubicity of Product Graphs

Author

Chandran, L. Sunil, Imrich, Wilfried, Mathew, Rogers, and Rajendraprasad, Deepak

Subjects

Mathematics - Combinatorics, Computer Science - Discrete Mathematics, 05C62, 05C76

Abstract

The 'boxicity' ('cubicity') of a graph G is the minimum natural number k such that G can be represented as an intersection graph of axis-parallel rectangular boxes (axis-parallel unit cubes) in $R^k$. In this article, we give estimates on the boxicity and the cubicity of Cartesian, strong and direct products of graphs in terms of invariants of the component graphs. In particular, we study the growth, as a function of $d$, of the boxicity and the cubicity of the $d$-th power of a graph with respect to the three products. Among others, we show a surprising result that the boxicity and the cubicity of the $d$-th Cartesian power of any given finite graph is in $O(\log d / \log\log d)$ and $\theta(d / \log d)$, respectively. On the other hand, we show that there cannot exist any sublinear bound on the growth of the boxicity of powers of a general graph with respect to strong and direct products., Comment: 14 pages

Published

2013

44. Algorithms and Bounds for Very Strong Rainbow Coloring

Author

Chandran, L. Sunil, Das, Anita, Issac, Davis, van Leeuwen, Erik Jan, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Bender, Michael A., editor, Farach-Colton, Martín, editor, and Mosteiro, Miguel A., editor

Published

2018

45. Pairwise Suitable Family of Permutations and Boxicity

Author

Basavaraju, Manu, Chandran, L. Sunil, Mathew, Rogers, and Rajendraprasad, Deepak

Subjects

Mathematics - Combinatorics, 05C62, 05C65

Abstract

A family F of permutations of the vertices of a hypergraph H is called "pairwise suitable" for H if, for every pair of disjoint edges in H, there exists a permutation in F in which all the vertices in one edge precede those in the other. The cardinality of a smallest such family of permutations for H is called the "separation dimension" of H and is denoted by \pi(H). Equivalently, \pi(H) is the smallest natural number k so that the vertices of H can be embedded in R^k such that any two disjoint edges of H can be separated by a hyperplane normal to one of the axes. We show that the separation dimension of a hypergraph H is equal to the "boxicity" of the line graph of H. This connection helps us in borrowing results and techniques from the extensive literature on boxicity to study the concept of separation dimension., Comment: 28 pages

Published

2012

46. 2-connecting Outerplanar Graphs without Blowing Up the Pathwidth

Author

Babu, Jasine, Basavaraju, Manu, Chandran, L. Sunil, and Rajendraprasad, Deepak

Subjects

Computer Science - Discrete Mathematics, Computer Science - Data Structures and Algorithms, Mathematics - Combinatorics

Abstract

Given a connected outerplanar graph G of pathwidth p, we give an algorithm to add edges to G to get a supergraph of G, which is 2-vertex-connected, outerplanar and of pathwidth O(p). This settles an open problem raised by Biedl, in the context of computing minimum height planar straight line drawings of outerplanar graphs, with their vertices placed on a two dimensional grid. In conjunction with the result of this paper, the constant factor approximation algorithm for this problem obtained by Biedl for 2-vertex-connected outerplanar graphs will work for all outer planar graphs.

Published

2012

47. Template-Driven Rainbow Coloring of Proper Interval Graphs

Author

Chandran, L. Sunil, primary, Das, Sajal K., additional, Hell, Pavol, additional, Padinhatteeri, Sajith, additional, and Pillai, Raji R., additional

Published

2021

48. On induced colourful paths in triangle-free graphs

Author

Babu, Jasine, Basavaraju, Manu, Chandran, L. Sunil, and Francis, Mathew C.

Published

2019

49. Hadwiger’s conjecture for squares of 2-trees

Author

Chandran, L. Sunil, Issac, Davis, and Zhou, Sanming

Published

2019

50. Isoperimetric Sequences for Infinite Complete Binary Trees, Meta-Fibonacci Sequences and Signed Almost Binary Partitions

Author

Chandran, L. Sunil, Das, Anita, and Ruskey, Frank

Subjects

Mathematics - Combinatorics, 05C05, G.2.2

Abstract

In this paper we demonstrate connections between three seemingly unrelated concepts. (1) The discrete isoperimetric problem in the infinite binary tree with all the leaves at the same level, $ {\mathcal T}_{\infty}$: The $n$-th edge isoperimetric number $\delta(n)$ is defined to be $\min_{|S|=n, S \subset V({\mathcal T}_{\infty})} |(S,\bar{S})|$, where $(S,\bar{S})$ is the set of edges in the cut defined by $S$. (2) Signed almost binary partitions: This is the special case of the coin-changing problem where the coins are drawn from the set ${\pm (2^d - 1): $d$ is a positive integer}$. The quantity of interest is $\tau(n)$, the minimum number of coins necessary to make change for $n$ cents. (3) Certain Meta-Fibonacci sequences: The Tanny sequence is defined by $T(n)=T(n{-}1{-}T(n{-}1))+T(n{-}2{-}T(n{-}2))$ and the Conolly sequence is defined by $C(n)=C(n{-}C(n{-}1))+C(n{-}1{-}C(n{-}2))$, where the initial conditions are $T(1) = C(1) = T(2) = C(2) = 1$. These are well-known "meta-Fibonacci" sequences. The main result that ties these three together is the following: $$ \delta(n) = \tau(n) = n+ 2 + 2 \min_{1 \le k \le n} (C(k) - T(n-k) - k).$$ Apart from this, we prove several other results which bring out the interconnections between the above three concepts., Comment: 22 pages, 4 figures

Published

2012