Multipath TCP Scheduling for Thin Streams: Active Probing and One-Way Delay-Awareness

Froemmgen, Alexander; Heuschkel, Jens; Koldehofe, Boris

doi:10.1109/icc.2018.8422950

Cited by 14 publications

(7 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the following, we discuss our MACI experiences. We greatly benefited from MACI during the development and evaluation in recent research projects on Multipath TCP scheduling [11,12,10,33], DASH video streaming [31], topology graph pattern matching algorithms [28], and the supervision of student theses. We further reproduced the results of a notable Multipath TCP experimental design study [22].…”

Section: Experiences and Resultsmentioning

confidence: 99%

“…We used MACI for the development of five novel Multipath TCP (MPTCP) schedulers. While the MPTCP specific details and evaluations are published in [12,10], we discuss the contribution of MACI on the design of one exemplary scheduler in the following.…”

Section: Mptcp Scheduler Developmentmentioning

confidence: 99%

“…We discuss the benefits of MACI based on our experience with three research projects: i) an extensive DASH video streaming study [31], ii) the development of various Multipath TCP packet schedulers [12,10], and iii) the tuning of a distributed topology graph pattern matching protocol [28].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Don't Repeat Yourself: Seamless Execution and Analysis of Extensive Network Experiments

Frömmgen¹,

Stohr²,

Koldehofe³

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

This paper presents MACI, the first bespoke framework for the management, the scalable execution, and the interactive analysis of a large number of network experiments. Driven by the desire to avoid repetitive implementation of just a few scripts for the execution and analysis of experiments, MACI emerged as a generic framework for network experiments that significantly increases efficiency and ensures reproducibility. To this end, MACI incorporates and integrates established simulators and analysis tools to foster rapid but systematic network experiments.We found MACI indispensable in all phases of the research and development process of various communication systems, such as i) an extensive DASH video streaming study, ii) the systematic development and improvement of Multipath TCP schedulers, and iii) research on a distributed topology graph pattern matching algorithm. With this work, we make MACI publicly available to the research community to advance efficient and reproducible network experiments.

show abstract

Section: Experiences and Resultsmentioning

confidence: 99%

Section: Mptcp Scheduler Developmentmentioning

confidence: 99%

See 1 more Smart Citation

Don't Repeat Yourself: Seamless Execution and Analysis of Extensive Network Experiments

Frömmgen¹,

Stohr²,

Koldehofe³

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Pokhrel and Choi [23] focused on the multipath transmission in high packet-loss rate and time-varying wireless networks and used the load balancing and forward error correction (FEC) to solve the out-of-order problem. e authors of [24] identified the limitations of MPTCP schedulers for thin streams and presented a MPTCP scheduling algorithm which can actively probe unused subflows and timely update the one-way delay information.…”

Section: Multipath Scheduling Schemesmentioning

confidence: 99%

“…Update W i according to equation ( 22) (9) if packet loss occurs in subflow i then (10) Get new swnd i ; (11) Update φ i with the feedback of Algorithm 1 (12) Update W i according to equation ( 22) (13) for each i ∈ R do (14) Calculate T i according to equation ( 23) (15) Find the subflow i with minimum T (16) if q i < swnd i then (17) if undistributed segments <swnd i − q i then (18) Allocate all undistributed segment to VQ i (19) else (20) Allocate swnd i − q i segments to VQ i (21) Update q i (22) else (23) if undistributed segments <swnd i then (24) Allocate all undistributed segment to VQ i (25) else (26) Allocate swnd i segments to VQ i (27) Update q i e network parameters were firstly fixed by setting the receiver buffer as 128 kB and WiMAX loss rate as 0.1.…”

Section: Mobile Information Systemsmentioning

confidence: 99%

Failure-Aware and Delay-Predicted Multipath Virtual Queue Scheduling for Multimedia Transmission in Edge IoT

Qin

Wang

Gao

et al. 2020

Mobile Information Systems

View full text Add to dashboard Cite

The spread of Edge Internet of Things (IoT) radically changes our lifestyle. However, the multimedia services in edge IoT are still stuck by inefficiency. The dynamic typologies perplex the transmission of massive real-time data. To solve this problem, multipath transmission control protocol (MPTCP) which has a natural advantage in transmission robustness and bandwidth aggregation is becoming a good choice. In this paper, failure-aware and delay-predicted multipath virtual queue scheduling (FD-MVQS) is proposed to optimize the MPTCP performance in edge IoT. FD-MVQS constructs a two-plane cooperative scheduling system. In the control plane, the transmission failure estimation and chaos theory-based arrival delay prediction methods are introduced to provide the foundation for prescheduling. In the data plane, the multipath virtual queue scheduling is designed to allocate segments to different subflows. Simulation results showed that the proposed FD-MVQS performed better than standard and typical multipath transmission solutions in throughput, delay, and segment disorder.

show abstract

Exploiting stream scheduling in QUIC: Performance assessment over wireless connectivity scenarios

Fernández,

Khan,

Zverev

et al. 2024

Ad Hoc Networks

View full text Add to dashboard Cite

Multipath TCP Scheduling for Thin Streams: Active Probing and One-Way Delay-Awareness

Cited by 14 publications

References 21 publications

Don't Repeat Yourself: Seamless Execution and Analysis of Extensive Network Experiments

Don't Repeat Yourself: Seamless Execution and Analysis of Extensive Network Experiments

Failure-Aware and Delay-Predicted Multipath Virtual Queue Scheduling for Multimedia Transmission in Edge IoT

Exploiting stream scheduling in QUIC: Performance assessment over wireless connectivity scenarios

Contact Info

Product

Resources

About