Maximum-Likelihood Detection With QAOA for Massive MIMO and Sherrington-Kirkpatrick Model With Local Field at Infinite Size
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Date
2024
Authors
Burhan Gulbahar
Journal Title
Journal ISSN
Volume Title
Publisher
Institute of Electrical and Electronics Engineers Inc.
Open Access Color
HYBRID
Green Open Access
Yes
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No
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Average
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Abstract
Quantum-approximate optimization algorithm (QAOA) is promising in Noisy Intermediate-Scale Quantum (NISQ) computers with applications for NP-hard combinatorial optimization problems. It is recently utilized for NP-hard maximum-likelihood (ML) detection problem with challenges of optimization simulation and performance analysis for n × n multiple-input multiple output (MIMO) systems with large n. QAOA is recently applied by Farhi et al. on infinite size limit of Sherrington-Kirkpatrick (SK) model with a cost model including only quadratic terms. In this article we extend the model by including also linear terms and then realize SK modeling of massive MIMO ML detection. The proposed design targets near ML performance while with complexity including O 16p initial operations independent from problem instance and size n for optimizing QAOA angles and On2\p quantum operations for each instance. We provide both optimized and extrapolated angles for p ϵ [1 14] and signal-to-noise (SNR) < 12 dB achieving near-optimum ML performance with p ≥ 4 for 25 × 25 and 12 × 12 MIMO systems modulated with BPSK and QPSK respectively. We present two conjectures about concentration properties of QAOA and near-optimum performance for next generation massive MIMO systems covering n < 300. © 2024 Elsevier B.V. All rights reserved.
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Keywords
Maximum-likelihood Detection, Mimo, Quantum Approximate Optimization, Sherrington-kirkpatrick Model, Combinatorial Optimization, Maximum Likelihood Estimation, Mimo Systems, Signal Detection, Approximate Optimization, Maximum- Likelihood Detection, Multiple Inputs, Multiple Outputs, Multiple-input Multiple Output, Multiple-input Multiple- Output Systems, Np-hard, Optimization Algorithms, Quantum Approximate Optimization, Sherrington-kirkpatrick Models, Signal To Noise Ratio, Combinatorial optimization, Maximum likelihood estimation, MIMO systems, Signal detection, Approximate optimization, Maximum- likelihood detection, Multiple inputs, Multiple outputs, Multiple-input multiple output, Multiple-Input Multiple- Output systems, NP-hard, Optimization algorithms, Quantum approximate optimization, Sherrington-Kirkpatrick models, Signal to noise ratio, Quantum Approximate Optimization, Costs, Modulation, Sherrington-Kirkpatrick Model, Cost Function, Massive MIMO, Maximum-Likelihood Detection, Computational Modeling, MIMO, Binary Phase Shift Keying, Wireless Communication
Fields of Science
Citation
WoS Q
Scopus Q
OpenCitations Citation Count
6
Source
IEEE Transactions on Wireless Communications
Volume
23
Issue
9
Start Page
11567
End Page
11579
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CrossRef : 2
Scopus : 9
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