A comparison of approaches for finding minimum identifying codes on graphs

Horan, Victoria; Adachi, Steve; Bak, Stanley

doi:10.1007/s11128-016-1240-0

Cited by 3 publications

(2 citation statements)

References 28 publications

(47 reference statements)

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“…In [18], Xiao et al formulated the problem using an integer program and developed a genetic algorithm to solve it. Recently, Horan et al [19] compared three approaches for finding minimum identifying codes on Brujin graphs using quantum annealing.…”

Section: Introductionmentioning

confidence: 99%

A Population-Based Local Search Algorithm for the Identifying Code Problem

Lara-Caballero,

González-Moreno

2023

Mathematics

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The identifying code problem for a given graph involves finding a minimum subset of vertices such that each vertex of the graph is uniquely specified by its nonempty neighborhood within the identifying code. The combinatorial optimization problem has a wide variety of applications in location and detection schemes. Finding an identifying code of minimum possible size is a difficult task. In fact, it has been proven to be computationally intractable (NP-complete). Therefore, the use of heuristics to provide good approximations in a reasonable amount of time is justified. In this work, we present a new population-based local search algorithm for finding identifying codes of minimum cost. Computational experiments show that the proposed approach was found to be more effective than other state-of-the-art algorithms at generating high-quality solutions in different types of graphs with varying numbers of vertices.

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Section: Introductionmentioning

confidence: 99%

A Population-Based Local Search Algorithm for the Identifying Code Problem

Lara-Caballero,

González-Moreno

2023

Mathematics

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“…The design and fabrication of several generations of quantum annealing computers (QACs) to solve hard optimization problems has aroused interest in their expected speedup [8,14,26], real-world applications [1,2,4,9,21,22,25], and benchmarks [14 -16]. Current research is focused on framing old problems to quantum annealing [10,18,30], embedding problems into quantum bits and their connections [5,13], suppressing errors due to the nature of the apparatus [11,21,24], scaling large data to fit QACs [23], and comparing quantum annealers with thermal annealers [19,21]. The above list of topics and [32] indicate that we are working in an interdisciplinary field.…”

Section: Introductionmentioning

confidence: 99%

Mathematical Methods for a Quantum Annealing Computer

Warren¹,

Corporation-Retired²

2018

JAAM

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This paper describes the logic and creativity needed in order to have high probability of solving discrete optimization problems on a quantum annealing computer. Current features of quantum computing via annealing are discussed. We illustrate the logic at the forefront of this new era of computing, describe some of the work done in this field, and indicate the distinct mindset that is used when programming this type of machine. The traveling salesman problem is formulated for solving on a quantum annealing computer, which illustrates the methods for this computer.

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Implementation of Quantum Annealing: A Systematic Review

Yulianti

Surendro

2022

IEEE Access

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Quantum annealing is a quantum computing approach widely used for optimization and probabilistic sampling problems. It is an alternative approach designed due to the limitations of gate-based quantum computing models. The method is observed to have a significant impact on different fields such as machine learning, graphics, routing, scheduling, computational chemistry, computational biology, security, portfolio, and others despite the fact that it is relatively new. This research provides a systematic review of research development trends in the field of quantum annealing and analyzes how it has been implemented in different problem domains. The results are expected to serve as the basis to identify the opportunities and challenges of research related to its implementation. The main contribution of this systematic review is to summarize different implementations of quantum annealing. It is also to analyze the prospect and opportunities in one of the problem domains with the greatest interest which is machine learning.

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A comparison of approaches for finding minimum identifying codes on graphs

Cited by 3 publications

References 28 publications

A Population-Based Local Search Algorithm for the Identifying Code Problem

A Population-Based Local Search Algorithm for the Identifying Code Problem

Mathematical Methods for a Quantum Annealing Computer

Implementation of Quantum Annealing: A Systematic Review

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