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Main Authors: Singh, Abhishek Kumar, Jamieson, Kyle, Venturelli, Davide, McMahon, Peter
Format: Preprint
Published: 2021
Subjects:
Online Access:https://arxiv.org/abs/2105.10535
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author Singh, Abhishek Kumar
Jamieson, Kyle
Venturelli, Davide
McMahon, Peter
author_facet Singh, Abhishek Kumar
Jamieson, Kyle
Venturelli, Davide
McMahon, Peter
contents Optimal MIMO detection has been one of the most challenging and computationally inefficient tasks in wireless systems. We show that the new analog computing techniques like Coherent Ising Machines (CIM) are promising candidates for performing near-optimal MIMO detection. We propose a novel regularized Ising formulation for MIMO detection that mitigates a common error floor problem and further evolves it into an algorithm that achieves near-optimal MIMO detection. Massive MIMO systems, that have a large number of antennas at the Access point (AP), allow linear detectors to be near-optimal. However, the simplified detection in these systems comes at the cost of overall throughput, which could be improved by supporting more users. By means of numerical simulations, we show that in principle a MIMO detector based on a hybrid use of a CIM would allow us to add more transmitter antennas/users and increase the overall throughput of the cell by a significant factor. This would open up the opportunity to operate using more aggressive modulation and coding schemes and hence achieve high throughput: for a $16\times16$ large MIMO system, we estimate around 2.5$\times$ more throughput in mid-SNR regime ($\approx 12 dB$) and 2$\times$ more throughput in high-SNR regime( $>$ 20dB) than the industry standard, Minimum-Mean Square Error decoding (MMSE).
format Preprint
id arxiv_https___arxiv_org_abs_2105_10535
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Ising Machines' Dynamics and Regularization for Near-Optimal Large and Massive MIMO Detection
Singh, Abhishek Kumar
Jamieson, Kyle
Venturelli, Davide
McMahon, Peter
Networking and Internet Architecture
Information Theory
Optimal MIMO detection has been one of the most challenging and computationally inefficient tasks in wireless systems. We show that the new analog computing techniques like Coherent Ising Machines (CIM) are promising candidates for performing near-optimal MIMO detection. We propose a novel regularized Ising formulation for MIMO detection that mitigates a common error floor problem and further evolves it into an algorithm that achieves near-optimal MIMO detection. Massive MIMO systems, that have a large number of antennas at the Access point (AP), allow linear detectors to be near-optimal. However, the simplified detection in these systems comes at the cost of overall throughput, which could be improved by supporting more users. By means of numerical simulations, we show that in principle a MIMO detector based on a hybrid use of a CIM would allow us to add more transmitter antennas/users and increase the overall throughput of the cell by a significant factor. This would open up the opportunity to operate using more aggressive modulation and coding schemes and hence achieve high throughput: for a $16\times16$ large MIMO system, we estimate around 2.5$\times$ more throughput in mid-SNR regime ($\approx 12 dB$) and 2$\times$ more throughput in high-SNR regime( $>$ 20dB) than the industry standard, Minimum-Mean Square Error decoding (MMSE).
title Ising Machines' Dynamics and Regularization for Near-Optimal Large and Massive MIMO Detection
topic Networking and Internet Architecture
Information Theory
url https://arxiv.org/abs/2105.10535