1 research outputs found
Distributed Learning over Markovian Fading Channels for Stable Spectrum Access
We consider the problem of multi-user spectrum access in wireless networks.
The bandwidth is divided into K orthogonal channels, and M users aim to access
the spectrum. Each user chooses a single channel for transmission at each time
slot. The state of each channel is modeled by a restless unknown Markovian
process. Previous studies have analyzed a special case of this setting, in
which each channel yields the same expected rate for all users. By contrast, we
consider a more general and practical model, where each channel yields a
different expected rate for each user. This model adds a significant challenge
of how to efficiently learn a channel allocation in a distributed manner to
yield a global system-wide objective. We adopt the stable matching utility as
the system objective, which is known to yield strong performance in
multichannel wireless networks, and develop a novel Distributed Stable Strategy
Learning (DSSL) algorithm to achieve the objective. We prove theoretically that
DSSL converges to the stable matching allocation, and the regret, defined as
the loss in total rate with respect to the stable matching solution, has a
logarithmic order with time. Finally, simulation results demonstrate the strong
performance of the DSSL algorithm.Comment: A short version of this paper was presented at the 2019 57th Annual
Allerton Conference on Communication, Control, and Computin