Related papers: Solving the Perfect Domination Problem by Quantum Approximate Optimization Algorithm with Small Layers

Solving the Perfect Domination Problem by Quantum Approximate Optimization Algorithm with Small Layers

URL: http://arxiv.org/abs/2411.12608v1
Date: Tue, 19 Nov 2024 16:12:36 GMT
Title: Solving the Perfect Domination Problem by Quantum Approximate Optimization Algorithm with Small Layers
Authors: Haoqian Pan, Changhong Lu, Yuqing Zheng,
Abstract summary: The Perfect Domination Problem ( PDP) has significant applications in real-world scenarios, such as wireless and social networks. With the recent advancements in quantum computing, there has been a surge in the development of quantum algorithms aimed at addressing NP-complete problems. This study represents a pioneering effort to apply quantum algorithms to the PDP, as well as their efficacy in solving it.
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Abstract: The Perfect Domination Problem (PDP), a classical challenge in combinatorial optimization, has significant applications in real-world scenarios, such as wireless and social networks. Over several decades of research, the problem has been demonstrated to be NP-complete across numerous graph classes. With the recent advancements in quantum computing, there has been a surge in the development of quantum algorithms aimed at addressing NP-complete problems, including the Quantum Approximate Optimization Algorithm (QAOA). However, the applicability of quantum algorithms to the PDP, as well as their efficacy in solving it, remains largely unexplored. This study represents a pioneering effort to apply QAOA, with a limited number of layers, to address the PDP. Comprehensive testing and analysis were conducted across 420 distinct parameter combinations. Experimental results indicate that QAOA successfully identified the correct Perfect Dominating Set (PDS) in 82 cases, including 17 instances where the optimal PDS was computed. Furthermore, it was observed that with appropriate parameter settings, the approximation ratio could achieve a value close to 0.9. These findings underscore the potential of QAOA as a viable approach for solving the PDP, signifying an important milestone that introduces this problem into the realm of quantum computing.

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