Scalable Spectrum Allocation for Large Networks Based on Sparse Optimization
Abstract
Joint allocation of spectrum and user association is considered for a large cellular network. The objective is to optimize a network utility function such as average delay given traffic statistics collected over a slow timescale. A key challenge is scalability: given Access Points (APs), there are ways in which the APs can share the spectrum. The number of variables is reduced from to , where is the number of users, by optimizing over local overlapping neighborhoods, defined by interference conditions, and by exploiting the existence of sparse solutions in which the spectrum is divided into segments. We reformulate the problem by optimizing the assignment of subsets of active APs to those segments. An constraint enforces a one-to-one mapping of subsets to spectrum, and an iterative (reweighted ) algorithm is used to find an approximate solution. Numerical results for a network with 100 APs serving several hundred users show the proposed method achieves a substantial increase in total throughput relative to benchmark schemes.
Cite
@article{arxiv.1702.05679,
title = {Scalable Spectrum Allocation for Large Networks Based on Sparse Optimization},
author = {Binnan Zhuang and Dongning Guo and Ermin Wei and Michael L. Honig},
journal= {arXiv preprint arXiv:1702.05679},
year = {2017}
}
Comments
Submitted to the IEEE International Symposium on Information Theory (ISIT), 2017