PAQMAN: A Principled Approach to Active Queue Management

Kar, Soummya; Alt, Bastian; Koeppl, Heinz; Rizk, Amr

doi:10.48550/arxiv.2202.10352

Cited by 4 publications

(4 citation statements)

References 26 publications

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“…Pan C et al [14] reconfigure the packet drop policy model based on the average queue-length change rate, effectively mitigating the delay jitter problem generated by network traffic changes. Another AQM technique [15] uses a semi-Markov decision process to estimate the probability of dropping an arriving packet before it enters the buffer but requires manual setting of the target delay for various network types. Jakub Szyguła et al [16] proposed an adaptive mechanism, multiplicative increase/reduction (MID), which minimizes the queuing delay by eliminating queues generated by AQM that depend on fixed targets, thereby achieving lower latency and jitter.…”

Section: Related Workmentioning

confidence: 99%

A Sketch-Based Fine-Grained Proportional Integral Queue Management Method

Zhu,

Sun,

Jiang

et al. 2023

Axioms

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The phenomenon “bufferbloat” occurs when the buffers of the network intermediary nodes fill up, causing long queuing delays. This has a significant negative impact on the quality of service of network applications, particularly those that are sensitive to time delay. Many active queue management (AQM) algorithms have been proposed to overcome this problem. Those AQMs attempt to maintain minimal queuing delays and good throughput by purposefully dropping packets at network intermediary nodes. However, the existing AQM algorithms mostly drop packets randomly based on a certain metric such as queue length or queuing delay, which fails to achieve fine-grained differentiation of data streams. In this paper, we propose a fine-grained sketch-based proportional integral queue management algorithm S-PIE, which uses an additional measurement structure Sketch for packet frequency share judgment based on the existing PIE algorithm for the fine-grained differentiation between data streams and adjust the drop policy for a differentiated packet drop. Experimental results on the NS-3 simulation platform show that the S-PIE algorithm achieves lower average queue length and RTT and higher fairness than PIE, RED, and CoDel algorithms while maintaining a similar throughput performance, maintaining network availability and stability, and improving network quality of service.

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Section: Related Workmentioning

confidence: 99%

A Sketch-Based Fine-Grained Proportional Integral Queue Management Method

Zhu,

Sun,

Jiang

et al. 2023

Axioms

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“…It is, however, suitable for infrastructure-based devices with an ample amount of power, but due to the small queue buffer in IoT sensors in 5G, multiple threshold levels will not affect the performance as gaps between thresholds will be minimum. Another AQM technique [36] uses the Semi-Markov Decision Process to estimate the dropping probability of the arriving packets before they can be queued into the buffer. The method provides better results as compared to drop-tail and CoDel but needs to set the target delay manually for various network types.…”

Section: Related Workmentioning

confidence: 99%

Queue-Buffer Optimization Based on Aggressive Random Early Detection in Massive NB-IoT MANET for 5G Applications

2022

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Elements in massive narrowband Internet of Things (NB-IoT) for 5G networks suffer severely from packet drops due to queue overflow. Active Queue Management (AQM) techniques help in maintaining queue length by dropping packets early, based on certain defined parameters. In this paper, we have proposed an AQM technique, called Aggressive Random Early Detection (AgRED) which, in comparison to previously used Random Early Detection (RED) and exponential RED technique, improves the overall end-to-end delay, throughput, and packet delivery ratio of the massive NB-IoT 5G network while using UDP. This improvement has been achieved due to a sigmoid function used by the AgRED technique, which aggressively and randomly drops the incoming packets preventing them from filling the queue. Because of the incorporation of the AgRED technique, the queue at different nodes will remain available throughout the operation of the network and the probability of delivering the packets will increase. We have analyzed and compared the performance of our proposed AgRED technique and have found that the performance gain for the proposed technique is higher than other techniques (RED and exponential RED) and passive queue management techniques (drop-tail and drop-head). The improvement in results is most significant in congested network deployment scenarios and provides improvements in massive Machine Type Communication, while also supporting ultra-low latency and reliable communication for 5G applications.

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“…Zeng et al [17] described the active queue management (AQM) algorithm employed by routers as a more efficient way to relieve congestion. AQM algorithm detects congestion at an early stage and delivers a feedback signal (through dropping of packets) to traffic sources to slow down their transmission rate before the buffer is fully occupied [18]- [20]. AQM algorithms aimed at reducing packet loss rate, keeping average queue size small, increasing throughput and reducing delay [15].…”

Section: Introductionmentioning

confidence: 99%

“…Enhanced congestion control-RED (CoCo-RED) [40] is a refined version of CoCo-RED algorithm in which minTh and maxTh are adjusted depending on the congestion level. Kar et al [20] described the dropping probability as the central part of an AQM algorithm. Also, Koo et al [41] developing an AQM algorithm with a good drop probability was described as the hallmark of congestion control.…”

Section: Introductionmentioning

confidence: 99%

Quadratic exponential random early detection: a new enhanced random early detection-oriented congestion control algorithm for routers

Hassan

Rufai

Nwaocha

et al. 2023

IJECE

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<span>Network congestion is still a problem on the internet. The random early detection (RED) algorithm being the most notable and widely implemented congestion algorithm in routers faces the problems of queue instability and large delay arising from the presence of an ineffectual singular linear packet dropping function. This research article presents a refinement to RED, named quadratic exponential random early detection (QERED) algorithm, which exploits the advantages of two drop functions, namely quadratic and exponential in order to enhance the performance of RED algorithm. ns-3 simulation studies using various traffic load conditions to assess and benchmark the effectiveness of QERED with two improved variants of RED affirmed that QERED offers a better performance in terms of average queue size and delay metrics at various network scenarios. Fortunately, to replace/upgrade the implementation for RED algorithm with QERED’s in routers will require minimal effort due to the fact that nothing more besides the packet dropping probability profile got to be adjusted.</span>

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PAQMAN: A Principled Approach to Active Queue Management

Cited by 4 publications

References 26 publications

A Sketch-Based Fine-Grained Proportional Integral Queue Management Method

A Sketch-Based Fine-Grained Proportional Integral Queue Management Method

Queue-Buffer Optimization Based on Aggressive Random Early Detection in Massive NB-IoT MANET for 5G Applications

Quadratic exponential random early detection: a new enhanced random early detection-oriented congestion control algorithm for routers

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