Title :
Scheduling latency-critical traffic: a measurement study of DRR+ and DRR++
Author :
Zhang, C. ; MacGregor, M.H.
Author_Institution :
Dept. of Comput. Sci., Alberta Univ., Edmonton, Alta., Canada
Abstract :
Efficient fair queuing using deficit round-robin, DRR, proposed by Shreedhar and Varghese (1996) is a low-complexity packet scheduler that has several commercial implementations. DRR has also been extended as DRR+ to accommodate latency-critical flows. DRR+, however, assumes that a latency-critical flow exhibits very smooth arrivals whereas most network flows are very bursty in nature, either as the result of source bursts, or as a result of the dynamics of multihop network paths. When DRR+ encounters a burst, it reverts back to the behavior of DRR, providing no preference or latency bound for latency critical traffic. This is a fatal flaw that prevents DRR+ from being useful in scheduling bursty latency-critical flows. We present a different extension to DRR that has much lower delay and delay jitter than DRR+ and is capable of handling bursty latency-critical flows.
Keywords :
delays; jitter; packet switching; queueing theory; telecommunication traffic; DRR; bursty latency-critical flows; bursty network flows; deficit round-robin; delay; delay jitter; efficient fair queuing; latency bound; latency critical traffic; latency-critical traffic scheduling; low-complexity packet scheduler; measurement; multihop network paths; source bursts; Bandwidth; Delay; Jitter; Processor scheduling; Regulators; Round robin; Scheduling algorithm; Spread spectrum communication; Telecommunication traffic; Traffic control;
Conference_Titel :
High Performance Switching and Routing, 2002. Merging Optical and IP Technologies. Workshop on
Print_ISBN :
4-88552-184-X
DOI :
10.1109/HPSR.2002.1024247
