Unboxing MAC Protocol Design Optimization Using Deep Learning

• URL: http://arxiv.org/abs/2002.03795v1
• Date: Thu, 6 Feb 2020 03:17:19 GMT
• Title: Unboxing MAC Protocol Design Optimization Using Deep Learning
• Authors: Hannaneh Barahouei Pasandi, Tamer Nadeem
• Abstract summary: We describe how we can leverage a deep reinforcement learning framework to be trained to learn the relation between different parameters in the physical and MAC layer. This paper shows how our learning-based approach could help us in getting insights about protocol design optimization task.
• Score: 1.5469452301122173
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Evolving amendments of 802.11 standards feature a large set of physical and MAC layer control parameters to support the increasing communication objectives spanning application requirements and network dynamics. The significant growth and penetration of various devices come along with a tremendous increase in the number of applications supporting various domains and services which will impose a never-before-seen burden on wireless networks. The challenge however, is that each scenario requires a different wireless protocol functionality and parameter setting to optimally determine how to tune these functionalities and parameters to adapt to varying network scenarios. The traditional trial-error approach of manual tuning of parameters is not just becoming difficult to repeat but also sub-optimal for different networking scenarios. In this paper, we describe how we can leverage a deep reinforcement learning framework to be trained to learn the relation between different parameters in the physical and MAC layer and show that how our learning-based approach could help us in getting insights about protocol design optimization task.

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