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mmRAPID: Machine Learning assisted Noncoherent Compressive Millimeter-Wave Beam Alignment

Signal Processing 2020-10-06 v1

Abstract

Millimeter-wave communication has the potential to deliver orders of magnitude increases in mobile data rates. A key design challenge is to enable rapid beam alignment with phased arrays. Traditional millimeter-wave systems require a high beam alignment overhead, typically an exhaustive beam sweep, to find the beam direction with the highest beamforming gain. Compressive sensing is a promising framework to accelerate beam alignment. However, model mismatch from practical array hardware impairments poses a challenge to its implementation. In this work, we introduce a neural network assisted compressive beam alignment method that uses noncoherent received signal strength measured by a small number of pseudorandom sounding beams to infer the optimal beam steering direction. We experimentally showcase our proposed approach with a 60GHz 36-element phased array in a suburban line-of-sight environment. The results show that our approach achieves post alignment beamforming gain within 1dB margin compared to an exhaustive search with 90.2 percent overhead reduction. Compared to purely model-based noncoherent compressive beam alignment, our method has 75 percent overhead reduction.

Keywords

Cite

@article{arxiv.2007.12060,
  title  = {mmRAPID: Machine Learning assisted Noncoherent Compressive Millimeter-Wave Beam Alignment},
  author = {Han Yan and Benjamin W. Domae and Danijela Cabric},
  journal= {arXiv preprint arXiv:2007.12060},
  year   = {2020}
}

Comments

Accepted to 2020 the 4th ACM Workshop on Millimeter-Wave Networks and Sensing Systems (mmNets)

R2 v1 2026-06-23T17:21:05.564Z