Systematic Network Coding with Overlap for IoT Scenarios

Zverev, Mihail; Garrido, Pablo; Agüero, Ramón; Bilbao, Josu

doi:10.1109/wimob.2019.8923213

Cited by 6 publications

(5 citation statements)

References 16 publications

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“…We find that rateless recoding with a finite recoding window size reduces the packet delay and increases the recoding and decoding throughput compared to recoding with a prescribed code rate or infinite recoding window size. Section IV-C compares the three specified SpaRec strategies operating with idle slot utilization, rateless recoding, and a finite window size against conventional recoding [67], [68], systematic RLNC [60]- [66], and a conventional recoding with small buffer benchmark [14]. We find that the proposed SpaRec strategies substantially reduce the packet losses while reducing the mean in-order packet delays down to approximately half of the benchmarks.…”

Section: Contributions and Structure Of This Articlementioning

confidence: 98%

“…Systematic coding is generally preferred for low-latency communication [56]- [59] and there have been extensive studies on low-latency communication schemes employing systematic RLNC, see e.g., [60]- [66]. Therefore, it is important to develop and evaluate sparsity-preserving recoding strategies for sparse systematic RLNC.…”

Section: B Related Workmentioning

confidence: 99%

“…With the systematic Random Linear Network Coding (RLNC) coding scheme for a prescribed code rate c [60]- [66], the source first sends the entire generation of G uncoded packets, followed by p coded packets, whereby c = G/(G+p). Intermediate nodes follow the same scheme for the recoding.…”

Section: ) Systematic Rlncmentioning

confidence: 99%

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SpaRec: Sparse Systematic RLNC Recoding in Multi-Hop Networks

et al. 2021

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Sparse Random Linear Network Coding (RLNC) reduces the computational complexity of the RLNC decoding through a low density of the non-zero coding coefficients, which can be achieved through sending uncoded (systematic) packets. However, conventional recoding of sparse RLNC coded packets at an intermediate node in a multi-hop network increases the density of non-zero coding coefficients. We develop and evaluate sparsity-preserving recoding (SpaRec) strategies that preserve the low density of non-zero coding coefficients of sparse RLNC with systematic packets. We develop SpaRec strategies with and without decoding at the intermediate nodes, with and without a specified coding rate, as well as with finite and infinite recoding window lengths. We evaluate the SpaRec strategies in multi-hop networks in terms of packet loss, packet delivery delay, as well as recoding and decoding (computation) throughput. We find that the SpaRec strategies substantially improve the RLNC performance compared to conventional recoding.

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Section: Contributions and Structure Of This Articlementioning

confidence: 98%

Section: B Related Workmentioning

confidence: 99%

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SpaRec: Sparse Systematic RLNC Recoding in Multi-Hop Networks

et al. 2021

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“…It is noteworthy that in networks with known topologies, e.g., (parallel) line networks, there exists sparse RLNC schemes with low decoding costs and almost zero overhead, e.g., [17,[30][31][32][33][34]. However, we note that these schemes do not apply to our interested scenarios where the network topology may be not known a priori, dynamically changing, and/or has cycles.…”

Section: Related Workmentioning

confidence: 99%

An Irregular Graph Based Network Code for Low-Latency Content Distribution

Yang

2020

Sensors

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To fulfill the increasing demand on low-latency content distribution, this paper considers content distribution using generation-based network coding with the belief propagation decoder. We propose a framework to design generation-based network codes via characterizing them as building an irregular graph, and design the code by evaluating the graph. The and-or tree evaluation technique is extended to analyze the decoding performance. By allowing for non-constant generation sizes, we formulate optimization problems based on the analysis to design degree distributions from which generation sizes are drawn. Extensive simulation results show that the design may achieve both low decoding cost and transmission overhead as compared to existing schemes using constant generation sizes, and satisfactory decoding speed can be achieved. The scheme would be of interest to scenarios where (1) the network topology is not known, dynamically changing, and/or has cycles due to cooperation between end users, and (2) computational/memory costs of nodes are of concern but network transmission rate is spare.

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“…This offers a different view on convolutional codes, where when one of the concurrent generations is finished, it is replaced with a new one. This view was exploited in [26], focusing on concurrent generations rather than on a coding window.…”

Section: B Fec and Network Codingmentioning

confidence: 99%

Robust QUIC: Integrating Practical Coding in a Low Latency Transport Protocol

et al. 2021

Self Cite

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We introduce rQUIC, an integration of the QUIC protocol, and a coding module. rQUIC has been designed to feature different coding/decoding schemes and is implemented in go language. We conducted an extensive measurement campaign to provide a thorough characterization of the proposed solution. We compared the performance of rQUIC with that of the original QUIC protocol for different underlying network conditions as well as different traffic patterns. Our results show that rQUIC not only yields a relevant performance gain (shorter delays), especially when network conditions worsen, but also ensures a more predictable behavior. For bulk transfer (long flows), the delay reduction almost reached 70% when the frame error rate was 5%, while under similar conditions, the gain for short flows (web navigation) was ≈ 55%. In the case of the video streaming the QoE gain (p1203 metric) was, approximately, 50%.

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Systematic Network Coding with Overlap for IoT Scenarios

Cited by 6 publications

References 16 publications

SpaRec: Sparse Systematic RLNC Recoding in Multi-Hop Networks

SpaRec: Sparse Systematic RLNC Recoding in Multi-Hop Networks

An Irregular Graph Based Network Code for Low-Latency Content Distribution

Robust QUIC: Integrating Practical Coding in a Low Latency Transport Protocol

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