1 research outputs found
Beam Learning -- Using Machine Learning for Finding Beam Directions
Beamforming is the key enabler for wireless communications in the mmWave
bands. 802.11ad and WiGig are wireless technologies that currently use the 60
GHz unlicensed mmWave spectrum via beamforming techniques. It is likely that 5G
systems will be considered for 60GHz unlicensed spectrum (apart from other
unlicensed bands) deployments and hence must co-exist with 802.11ad and WiGig.
3GPP is taking steps towards achieving the same and the standardization for
this is underway. The first step to achieve this co-existence is to find the
interference-free directions, in other words identify the directions in which
the nodes using these incumbent technologies are communicating and eliminate
those directions from further communications. Such a mechanism can help to
exploit the spatial holes rather than avoid communications even when only a few
spatial directions are used by incumbents. Such a mechanism trivially increases
the throughput of the proposed 5G systems. However, since the incumbent
technologies may be unknown to the 5G mmWave nodes and their behavior may also
be unknown apriori (for instance, parameters such as duty cycle, power levels,
CSMA parameter used by 802.11ad are unknown to the 5G nodes), this spatial
direction finding must be performed in a blind manner. In this paper, we use
multi-armed bandits-based algorithms, a variant of machine learning algorithms,
to blindly detect the beam directions (both along azimuth and elevation i.e.,
3D-beamforming) used for communication by the incumbents. This work paves the
way for combining the powerful of machine learning algorithms into 5G
unlicensed mmWave systems. Numerical results show the superior performance of
these algorithms over techniques that are commonly employed in such blind
settings.Comment: This paper is an extension of the ICC 2017 paper titled "Beam
Learning". It was written before the onslaught of deep learning technique