| Riga 8: | Riga 8: | ||
Controlling Queuing Delays for Real-Time Communication: Interplay of E2E and AQM Algorithms | Controlling Queuing Delays for Real-Time Communication: Interplay of E2E and AQM Algorithms | ||
</paper> | </paper> | ||
| − | + | ''' '''ACM SIGCOMM Newsletter: [https://ccronline.sigcomm.org/2016/controlling-queuing-delays-for-real-time-communication-the-interplay-of-e2e-and-aqm-algorithms/ Link] | |
}} | }} | ||
This paper considers the case of real-time communication between web browsers (WebRTC) and we focus on the interplay of an end-to-end delay-based | This paper considers the case of real-time communication between web browsers (WebRTC) and we focus on the interplay of an end-to-end delay-based | ||
congestion control algorithm with delay-based AQM algorithms, namely '''CoDel''' and '''PIE''', and flow queuing schedulers, i.e. '''SFQ''' and '''Fq Codel'''. | congestion control algorithm with delay-based AQM algorithms, namely '''CoDel''' and '''PIE''', and flow queuing schedulers, i.e. '''SFQ''' and '''Fq Codel'''. | ||
Delay sensitive applications require not only congestion control but also minimization of queuing delays to provide interactivity.
This paper considers the case of real-time communication between web browsers (WebRTC) and we focus on the interplay of an end-to-end delay-based
congestion control algorithm with delay-based AQM algorithms, namely CoDel and PIE, and flow queuing schedulers, i.e. SFQ and Fq Codel.
Delay sensitive applications require not only congestion control but also minimization of queuing delays to provide interactivity.
This paper considers the case of real-time communication between web browsers (WebRTC) and we focus on the interplay of an end-to-end delay-based
congestion control algorithm with delay-based AQM algorithms, namely CoDel and PIE, and flow queuing schedulers, i.e. SFQ and Fq Codel.