Abstract

This article develops a quantum bacterial foraging optimization (QBFO) algorithm, a quantum intelligence algorithm based on quantum computing and bacterial foraging optimization (BFO), with application in MIMO system optimization designs. In QBFO, a multiqubit is used to represent a bacterium, and a quantum rotation gate is used to mimic chemotaxis. Because the quantum bacterium with multiqubit has the advantage that it can represent a linear superposition of states (binary solutions) in search space probabilistically, the proposed QBFO algorithms shows better performance on solving combinatorial optimization problems than its classical counterpart BFO and Quantum Genetic Algorithm (QGA), especially for parallel non-gradient optimization. A sparse channel estimation scheme based on QBFO with adaptive phase rotation (AQBFO) in 3D MIMO system is proposed, and simulation results show that AQBFO achieved a better performance than existing algorithms including least squares (LS), iteratively reweighted least squares (IRLS), matching pursuit (MP), and orthogonal matching pursuit (OMP). We further improve some critical aspects such as reproduction and dispersal processes of AQBFO, propose an improved IQBFO algorithm, and apply it for interference coordination in 3D multi-cell multi-user MIMO systems, aiming to maximize the spectral efficiency. It considers user fairness and jointly optimizes cell-center and cell-edge user specific antenna downtilts and power to maximize each user's sum rate. This problem is a combinatorial non-convex optimization problem that cannot be solved by the traditional Karush-Kuhn-Tucker Lagrangian algorithm whereas the IQBFO algorithm solves it effectively.

Highlights

  • T HREE-DIMENSIONAL (3D) multiple-input multipleoutput (MIMO) [1], [2]. is a promising candidate technology for 5G and beyond

  • AQBFO is highly adaptive to different types of test functions in low dimensionality, and its convergence probability is higher than bacterial foraging optimization (BFO), Quantum Genetic Algorithm (QGA) and quantum bacterial foraging optimization (QBFO)

  • The QBFO and AQBFO algorithms are applied to real-world application scenarios, especially the complex optimization problems encountered in 5G systems and beyond

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Summary

INTRODUCTION

T HREE-DIMENSIONAL (3D) multiple-input multipleoutput (MIMO) [1], [2]. is a promising candidate technology for 5G and beyond. Because the quantum bacterium with multiqubit has the advantage that it can represent a linear superposition of states (binary solutions) in search space probabilistically, the proposed QBFO algorithms shows better performance on solving combinatorial optimization problems than its classical counterpart BFO and Quantum Genetic Algorithm (QGA), especially for parallel non-gradient optimization. We further improve some critical aspects such as reproduction and dispersal processes of AQBFO, propose an improved QBFO (IQBFO) algorithm, and apply IQBFO for interference coordination in 3D multi-cell multi-user MIMO systems, aiming to maximize the spectral efficiency. It considers user fairness and jointly optimizes cell-center and cell-edge user specific antenna downtilts and power to maximize each user’s sum rate.

SIMULATIONS AND RESULT ANALYSIS OF QBFO
3) PERFORMANCE RESULTS AND ANALYSIS
CONCLUSION

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