Power Efficiency and Delay Tradeoff of 10GBase-T Energy Efficient Ethernet Protocol

TL;DR

This paper analyzes the power efficiency and delay tradeoff in IEEE 802.3az Energy Efficient Ethernet, proposing a new queue model that links vacation time to arrival processes, and deriving formulas to optimize protocol parameters.

Contribution

It introduces a novel analytical approach connecting vacation time with arrival processes, providing formulas for delay and power efficiency in EEE systems.

Findings

The { au} and N policies compensate each other to balance delay and power efficiency.

Derived a generalized P-K formula for mean delay considering arrival-dependent vacation times.

Simulation results confirm the accuracy of the analytical models.

Abstract

In this paper, we study the power efficiency and delay performance of the IEEE 802.3az Energy Efficient Ethernet (EEE) protocol. A new approach is proposed to analyze the M/G/1 queue with the vacation time that is governed by the arrival process and the parameter {\tau} and N of the BTR strategy. Our key idea is to establish the connection between the vacation time and the arrival process to account for their dependency. We first derive the distribution of the number of arrivals during a vacation time based on an event tree of the BTR strategy, from which we obtain the mean vacation time and the power efficiency. Next, from the condition on the number of arrivals at the end of a vacation period, we derive a generalized P-K formula of the mean delay for EEE systems, and prove that the classical P-K formula of the vacation model is only a special case when the vacation time is independent of the arrival process. Our analysis demonstrates that the {\tau} policy and N policy of the BTR strategy are compensating each other. The {\tau} policy ensures the frame delay is bounded when the traffic load is light, while the N policy ensures the queue length at the end of vacation is bounded when the traffic load is heavy. These results, in turn, provide the rules to select appropriate {\tau} and N. Our analytical results are confirmed by simulations.