Quantum-inspired optimization algorithm with adaptive correction of energy position: Methodology and a case study

Efficient and stable global optimizers constitute a noteworthy arena of academic study and real-world applications. Since Multi-scale Quantum Harmonic Oscillator Algorithm inspired by the quantum motion for solving optimization problems was proposed, considerable contributions regarding this algorit...

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Bibliographic Details
Published in:Applied soft computing Vol. 145; p. 110560
Main Authors: Mu, Lei, Wang, Peng
Format: Journal Article
Language:English
Published: Elsevier B.V 01.09.2023
Subjects:
Energy position
Evolutionary algorithms
Optimization problem
Quantum Monte Carlo
Quantum Monte Carlo
Energy position
Evolutionary algorithms
Optimization problem
ISSN:1568-4946, 1872-9681
Online Access:Get full text
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Summary:Efficient and stable global optimizers constitute a noteworthy arena of academic study and real-world applications. Since Multi-scale Quantum Harmonic Oscillator Algorithm inspired by the quantum motion for solving optimization problems was proposed, considerable contributions regarding this algorithm have been achieved in recent years. Nevertheless, issues such as the aggregation effect during sampling as well as recurrence and blindness in random searches hinder the performance of the algorithm. Motivated by this situation, a variant of Multi-scale Quantum Harmonic Oscillator Algorithm is put forward to improve the efficiency of the system convergence while maintaining the solution diversity. The measurement of the solution position through the collapse of the quantum state to the classical state is realized by means of quantum Monte Carlo simulations, and the energy position is established as a metric for energy observation. Then, the adaptive correction of the energy position is explored to improve algorithm performance. The core idea of our mechanism is to adaptively guide the candidate solutions toward convergence to the ground state by means of attractive factors based on the relationship among the energy positions of several reference points. Experimental results obtained on the CEC2013 benchmark functions and a real-world application indicate that the performance of our scheme is competitive and that it achieves prominence among the compared algorithms as the dimensionality increases. •We propose a general framework for a class of quantum-inspired algorithms.•A MQHOA variant with adaptive balance utilizing attractive factors is present.•Our scheme is analyzed in various aspects, such as wave functions•The scheme is validated on CEC2013 benchmark functions and a real-world case study.•The results show prominent scheme performance with increasing dimensionality.
ISSN:1568-4946
1872-9681
DOI:10.1016/j.asoc.2023.110560