A Comparison of Approaches for Solving Hard Graph-Theoretic Problems

In order to formulate mathematical conjectures likely to be true, a number of base cases must be determined. However, many combinatorial problems are NP-hard and the computational complexity makes this research approach di cult using a standard brute force approach on a typical computer. One sample...

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Hauptverfasser:	Horan, Victoria, Adachi, Steve, Bak, Stanley
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Sprache:	eng
Schlagworte:	COMBINATORIAL ANALYSIS COMPARISON COMPUTATIONS COMPUTERS GRAPHS QUANTUM THEORY Statistics and Probability
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creator	Horan, Victoria Adachi, Steve Bak, Stanley
description	In order to formulate mathematical conjectures likely to be true, a number of base cases must be determined. However, many combinatorial problems are NP-hard and the computational complexity makes this research approach di cult using a standard brute force approach on a typical computer. One sample problem explored is that of finding a minimum identifying code. To work around the computational issues, a variety of methods are explored and consist of a parallel computing approach using Matlab, a quantum annealing approach using the D-Wave computer, and lastly using satisfiability modulo theory (SMT) and corresponding SMT solvers. Each of these methods requires the problem to be formulated in a unique manner. In this paper, we address the challenges of computing solutions to this NP-hard problem with respect to each of these methods.
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subjects	COMBINATORIAL ANALYSIS COMPARISON COMPUTATIONS COMPUTERS GRAPHS QUANTUM THEORY Statistics and Probability
title	A Comparison of Approaches for Solving Hard Graph-Theoretic Problems
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