Your search keyword '"HASABNIS, MIHIR"' showing total 13 results

1. Colorful Hamilton cycles in random graphs

Author

Chakraborti, Debsoumya, Frieze, Alan, and Hasabnis, Mihir

Subjects

Mathematics - Combinatorics

Abstract

Given an $n$ vertex graph whose edges have colored from one of $r$ colors $C=\{c_1,c_2,\ldots,c_r\}$, we define the Hamilton cycle color profile $hcp(G)$ to be the set of vectors $(m_1,m_2,\ldots,m_r)\in [0,n]^r$ such that there exists a Hamilton cycle that is the concatenation of $r$ paths $P_1,P_2,\ldots,P_r$, where $P_i$ contains $m_i$ edges of color $c_i$. We study $hcp(G_{n,p})$ when the edges are randomly colored. We discuss the profile close to the threshold for the existence of a Hamilton cycle and the threshold for when $hcp(G_{n,p})=\{(m_1,m_2,\ldots,m_r)\in [0,n]^r: m_1+m_2+\cdots+m_r=n\}$., Comment: fixed minor typos

Published

2021

2. Minimizing the number of edges in $K_{s,t}$-saturated bipartite graphs

Author

Chakraborti, Debsoumya, Chen, Da Qi, and Hasabnis, Mihir

Subjects

Mathematics - Combinatorics

Abstract

This paper considers an edge minimization problem in saturated bipartite graphs. An $n$ by $n$ bipartite graph $G$ is $H$-saturated if $G$ does not contain a subgraph isomorphic to $H$ but adding any missing edge to $G$ creates a copy of $H$. More than half a century ago, Wessel and Bollob\'as independently solved the problem of minimizing the number of edges in $K_{(s,t)}$-saturated graphs, where $K_{(s,t)}$ is the `ordered' complete bipartite graph with $s$ vertices from the first color class and $t$ from the second. However, the very natural `unordered' analogue of this problem was considered only half a decade ago by Moshkovitz and Shapira. When $s=t$, it can be easily checked that the unordered variant is exactly the same as the ordered case. Later, Gan, Kor\'andi, and Sudakov gave an asymptotically tight bound on the minimum number of edges in $K_{s,t}$-saturated $n$ by $n$ bipartite graphs, which is only smaller than the conjecture of Moshkovitz and Shapira by an additive constant. In this paper, we confirm their conjecture for $s=t-1$ with the classification of the extremal graphs. We also improve the estimates of Gan, Kor\'andi, and Sudakov for general $s$ and $t$, and for all sufficiently large $n$., Comment: Reflected minor suggestions from reviewers

Published

2020

3. Isomorphism for Random $k$-Uniform Hypergraphs

Author

Chakraborti, Debsoumya, Frieze, Alan, Haber, Simi, and Hasabnis, Mihir

Subjects

Mathematics - Combinatorics

Abstract

We study the isomorphism problem for random hypergraphs. We show that it is solvable in polynomial time for the binomial random $k$-uniform hypergraph $H_{n,p;k}$, for a wide range of $p$. We also show that it is solvable w.h.p. for random $r$-regular, $k$-uniform hypergraphs $H_{n,r;k},r=O(1)$., Comment: fixed typos and added explanations

Published

2020

4. The threshold for the full perfect matching color profile in a random coloring of random graphs

Author

Chakraborti, Debsoumya and Hasabnis, Mihir

Subjects

Mathematics - Combinatorics

Abstract

Consider a graph $G$ with a coloring of its edge set $E(G)$ from a set $Q = \set{c_1,c_2, \ldots, c_q}$. Let $Q_i$ be the set of all edges colored with $c_i$. Recently, Frieze defined a notion of the perfect matching color profile denoted by $\mcp(G)$, which is the set of vectors $(m_1, m_2, \ldots, m_q) \in [n]^q$ such that there exists a perfect matching $M$ in $G$ with $|Q_i \cap M| = m_i$ for all $i$. Let $\a_1, \a_2, \ldots, \a_q$ be positive constants such that $\sum_{i=1}^q \a_i = 1$. Let $G$ be the random bipartite graph $G_{n,n,p}$. Suppose the edges of $G$ are independently colored with color $c_i$ with probability $\alpha_i$. We determine the threshold for the event $\mcp(G) = \set{(m_1, \ldots, m_q) \in [0,n]^q : m_1 + \cdots + m_q = n}$, answering a question posed by Frieze. We further extend our methods to find the threshold for the same event in a randomly colored random graph $G_{n,p}$., Comment: Minor corrections

Published

2019

5. The game chromatic number of a random hypergraph

Author

Chakraborti, Debsoumya, Frieze, Alan, and Hasabnis, Mihir

Subjects

Mathematics - Combinatorics

Abstract

We consider the following game, played on a $k$-uniform hypergraph $H$. There are $q$ colors available and two players take it in turns to color vertices. A partial coloring is proper if no edge is mono-chromatic. One player, A, wishes to color all the vertices and the other player, B, wishes to prevent this. The {\em game chromatic number} $\chi_g(H)$ is the minimum number of colors for which A has a winning strategy. We consider this in the context of a random $k$-uniform hypergraph and prove upper and lower bounds that hold w.h.p., Comment: arXiv admin note: text overlap with arXiv:1201.0046

Published

2019

6. The Game Chromatic Number of a Random Hypergraph

Author

Chakraborti, Debsoumya, Frieze, Alan, Hasabnis, Mihir, Pardalos, Panos M., Series Editor, Thai, My T., Series Editor, Du, Ding-Zhu, Honorary Editor, Belavkin, Roman V., Advisory Editor, Birge, John R., Advisory Editor, Butenko, Sergiy, Advisory Editor, Giannessi, Franco, Advisory Editor, Kumar, Vipin, Advisory Editor, Nagurney, Anna, Advisory Editor, Pei, Jun, Advisory Editor, Prokopyev, Oleg, Advisory Editor, Rebennack, Steffen, Advisory Editor, Resende, Mauricio, Advisory Editor, Terlaky, Tamás, Advisory Editor, Vu, Van, Advisory Editor, Vrahatis, Michael N., Associate Editor, Xue, Guoliang, Advisory Editor, Ye, Yinyu, Advisory Editor, Raigorodskii, Andrei M., editor, and Rassias, Michael Th., editor

Published

2020

7. Colorful Hamilton Cycles in Random Graphs

Author

Chakraborti, Debsoumya, primary, Frieze, Alan M., additional, and Hasabnis, Mihir, additional

Published

2023

8. Topics in Extremal Structures and Random Graphs

Author

Hasabnis, Mihir Abhay

Subjects

FOS: Mathematics, 10104 Combinatorics and Discrete Mathematics (excl. Physical Combinatorics)

Abstract

We mainly studied several problems in random graphs. Random graphs is one of the biggest fields in Probabilistic combinatorics with applications to various fields in Mathematics and Computer Science. We will look at a variety of problems in this area such as the Game Chromatic Number for Hypergraphs, Rainbow matching, Colorful Hamiltonian Cycles and Random Graph Isomorphism. Extremal combinatorics studies how large or how small a collection of finite objects can be, if it has to satisfy certain restrictions. We will look at a problem of saturation in bipartite graphs in that context. In Chapter 2, we generalize the notion of game chromatic number of a graph to hypergraphs. There are q colors available and two players Alice (A) and Bob (B) take turns to color vertices of a graph. A partial coloring is proper if no edge is monochromatic. One player, A, wishes to color all the vertices and the other player, B, wishes to prevent this. The game chromatic number χg(H) is the minimum number of colors for which A has a winning strategy. We consider this in the context of a random k-uniform hypergraph and prove upper and lower bounds that hold w.h.p. In Chapter 3, we study a question posed by Prof. Frieze in [35] related to the existence of a patterned perfect matching in a randomly colored graph. In Chapter 4, we study the isomorphism problem for random hypergraphs. We show that it is polynomially time solvable for the binomial random k-uniform hypergraph Hn,p;k, for a wide range of p, and for random r-regular, k-uniform hypergraphs where r is a constant. In Chapter 5, we study a similar problem as in chapter 3 but for Hamilton cycles. Finally in Chapter 6, we study the problem of edge saturation in Bipartite graphs. One of the most interesting and natural questions in this area is to determine the saturation number for the complete bipartite graph. When s = t, the saturation number and its extremal structures were determined long ago but nothing else is known for the general case. Half a decade ago, Gan, Kor´andi, and Sudakov [37] gave an asymptotically tight bound that was only off by an additive constant. We show that with some additional techniques, how the bound can be improved to achieve tightness for the case when s = t − 1.

Published

2022

9. COLORFUL HAMILTON CYCLES IN RANDOM GRAPHS.

Author

CHAKRABORT, DEBSOUMYA, FRIEZE, ALAN M., and HASABNIS, MIHIR

Subjects

RANDOM graphs, HAMILTONIAN graph theory, PATHS & cycles in graph theory, GRAPH coloring

Abstract

Given an n vertex graph whose edges have colored from one of τ colors C = {ci, C2,..., cr}, we define the Hamilton cycle color profile hcp(G) to be the set of vectors (mi, m2,..., mr) ∈ [0, n}r such that there exists a Hamilton cycle that is the concatenation of τ paths Pi, P2, ∙.., Pr, where Pi contains rΠι edges of color cι. We study hcp(Gn p) when the edges are randomly colored. We discuss the profile close to the threshold for the existence of a Hamilton cycle and the threshold for when ∕icp(Gnjf>) = {(mι, m2,..., mr) ∈ [0,n]r: mi + m2 + ∙ ∙ ∙ + mr = n}. [ABSTRACT FROM AUTHOR]

Published

2023

10. Isomorphism for random k-uniform hypergraphs

Author

Chakraborti, Debsoumya, primary, Frieze, Alan, additional, Haber, Simi, additional, and Hasabnis, Mihir, additional

Published

2021

11. The Threshold for the Full Perfect Matching Color Profile in a Random Coloring of Random Graphs

Author

Chakraborti, Debsoumya, primary and Hasabnis, Mihir, additional

Published

2021

12. Minimizing the Number of Edges in $K_{(s,t)}$-Saturated Bipartite Graphs

Author

Chakraborti, Debsoumya, primary, Chen, Da Qi, additional, and Hasabnis, Mihir, additional

Published

2021

13. MINIMIZING THE NUMBER OF EDGES IN K(a,t)-SATURATED BIPARTITE GRAPHS.

Author

CHAKRABORTI, DEBSOUMYA, DA QI CHEN, and HASABNIS, MIHIR

Subjects

BIPARTITE graphs, COMPLETE graphs, EDGES (Geometry), PROBLEM solving

Abstract

This paper considers an edge minimization problem in saturated bipartite graphs. An n by n bipartite graph G is H-saturated if G does not contain a subgraph isomorphic to H but adding any missing edge to G creates a copy of H. More than half a century ago, Wessel and Bollob'as independently solved the problem of minimizing the number of edges in K(s,t)-saturated graphs, where K(s,t) is the "ordered"" complete bipartite graph with s vertices from the first color class and t from the second. However, the very natural "unordered"" analogue of this problem was considered only half a decade ago by Moshkovitz and Shapira. When s = t, it can be easily checked that the unordered variant is exactly the same as the ordered case. Later, Gan, Kor'andi, and Sudakov gave an asymptotically tight bound on the minimum number of edges in K(s,t)-saturated n by n bipartite graphs, which is only smaller than the conjecture of Moshkovitz and Shapira by an additive constant. In this paper, we confirm their conjecture for s = t 1 with the classification of the extremal graphs. We also improve the estimates of Gan, Kor'andi, and Sudakov for general s and t, and for all sufficiently large n. [ABSTRACT FROM AUTHOR]

Published

2021