Low-Delay High-Rate Operation of 802.11ac WLAN Downlink: Nonlinear Controller Analysis & Design

TL;DR

This paper introduces a nonlinear control-based traffic shaping method for 802.11ac WLANs that maintains low delay and high throughput by adjusting client send rates, supported by theoretical analysis and experimental validation.

Contribution

It presents a novel nonlinear feedback controller for WLAN traffic shaping that ensures robust low-delay operation across diverse network conditions.

Findings

Controller maintains target packet aggregation effectively.

System remains stable under various network loads.

Experimental results confirm improved delay and throughput.

Abstract

In this paper we consider a next generation edge architecture where traffic is routed via a proxy located close to the network edge (e.g. within a cloudlet). This creates freedom to implement new transport layer behaviour over the wireless path between proxy and clients. We use this freedom to develop a novel traffic shaping controller for the downlink in 802.11ac WLANs that adjusts the send rate to each WLAN client so as to maintain a target number of packets aggregated in each transmitted frame. In this way robust low-delay operation at high data rates becomes genuinely feasible across a wide range of network conditions. Key to achieving robust operation is the design of an appropriate feedback controller, and it is this which is our focus. We develop a novel nonlinear control design inspired by the solution to an associated proportional fair optimisation problem. The controller compensates for system nonlinearities and so can be used for the full envelope of operation. The robust stability of the closed-loop system is analysed and the selection of control design parameters discussed. We develop an implementation of the nonlinear control design and use this to present a performance evaluation using both simulations and experimental measurements.