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Joint Pilot Design and Uplink Power Allocation in Multi-Cell Massive MIMO Systems

This paper considers pilot design to mitigate pilot contamination and provide good service for everyone in multi-cell massive multiple-input-multiple-output systems. Instead of modeling the pilot design as a combinatorial assignment problem, as in prior works, we express the pilot signals using a pi...

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Published in:	IEEE transactions on wireless communications 2018-03, Vol.17 (3), p.2000-2015
Main Authors:	Van Chien, Trinh, Bjornson, Emil, Larsson, Erik G.
Format:	Article
Language:	English
Subjects:	Contamination Fading channels Geometric Programming Hardware Hardware Impairments Massive MIMO MIMO communication Optimization Pilot Design Resource management Signomial Programming Uplink
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cited_by	cdi_FETCH-LOGICAL-c381t-b6fa3549a9b1663ac7cfa2a35fc449f8f78c74467aeba8faa1fd770c0b645ff13
cites	cdi_FETCH-LOGICAL-c381t-b6fa3549a9b1663ac7cfa2a35fc449f8f78c74467aeba8faa1fd770c0b645ff13
container_end_page	2015
container_issue	3
container_start_page	2000
container_title	IEEE transactions on wireless communications
container_volume	17
creator	Van Chien, Trinh Bjornson, Emil Larsson, Erik G.
description	This paper considers pilot design to mitigate pilot contamination and provide good service for everyone in multi-cell massive multiple-input-multiple-output systems. Instead of modeling the pilot design as a combinatorial assignment problem, as in prior works, we express the pilot signals using a pilot basis and treat the associated power coefficients as continuous optimization variables. We compute a lower bound on the uplink capacity for Rayleigh fading channels with maximum ratio detection that applies with arbitrary pilot signals. We further formulate the max-min fairness problem under power budget constraints, with the pilot signals and data powers as optimization variables. Because this optimization problem is non-deterministic polynomial-time hard due to signomial constraints, we then propose an algorithm to obtain a local optimum with polynomial complexity. Our framework serves as a benchmark for pilot design in scenarios with either ideal or non-ideal hardware. Numerical results manifest that the proposed optimization algorithms are close to the optimal solution obtained by exhaustive search for different pilot assignments and the new pilot structure and optimization bring large gains over the state-of-the-art suboptimal pilot design.
doi_str_mv	10.1109/TWC.2017.2787702
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source	IEEE Electronic Library (IEL) Journals
subjects	Contamination Fading channels Geometric Programming Hardware Hardware Impairments Massive MIMO MIMO communication Optimization Pilot Design Resource management Signomial Programming Uplink
title	Joint Pilot Design and Uplink Power Allocation in Multi-Cell Massive MIMO Systems
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