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Monte Carlo based channel estimation and evaluation for 5G millimeter-wave systems
Weiss, Alec
Weiss, Alec
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2022
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2023-05-04
Abstract
Current wireless communications systems utilizing frequencies below 6 GHz are quickly becoming unable
to meet consumer needs due to limited bandwidth. The need for ever increasing data throughput for
wireless systems is pushing systems to begin using higher millimeter-wave frequencies to provide frequency
bandwidths that are orders of magnitude larger than those operating at the lower frequencies. Operating at
millimeter-wave frequencies brings along new challenges that do not exist at lower frequencies such as mass
produced hardware that is physically smaller to overcome the larger free space loss which can bring increase
uncertainty in channels and hardware components. The uncertainty increases in these systems must be
corrected by channel estimators to correctly receive data. Channel estimators are e↵ected by the increased
hardware error and their efficacy is therefore reduced. This in turn increases the error in received data and
reduces the throughput of a communications system.
A multitude of channel estimation techniques have been developed in an attempt to reduce bit errors in
the received data and maximize the system throughput. Methods can be as basic as performing division and
averaging of known transmitted values to estimate the channel. Other channel estimators have been designed
using techniques ranging from machine learning to optimization and minimization. None of these estimators
use responses and uncertainties of hardware components that are typically provided by manufacturers. By
directly using known hardware responses and any corresponding uncertainties, a channel estimator can
improve its estimation.
The research outlined here first provides a framework for the consistent evaluation and comparison of
estimators in millimeter-wave systems and second develops an improved channel estimator that leverages
known hardware responses and their uncertainties. The comparison between estimators is important to
select the best estimator for a scenario before deployment of hardware to save time and money. Without a
framework for this comparison, there is no way to directly test channel estimators without implementing and
deploying them into a physical system. The developed framework provides common communications metrics
in phased array architectures and propagation environments to evaluate how di↵erent channel estimators
perform. This framework is then used to evaluate a novel Monte Carlo augmented channel estimator.
This channel estimator uses repeat simulations of the known hardware responses and their uncertainties to
provide an improved channel estimation. This channel estimator is directly compared to other commonly
implemented channel estimators to demonstrate how it can be used in communications systems to reduce
overall bit errors in received data and increase system throughput.
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