Sameh Sorour scite author profile

In this paper, we consider the problem of minimizing the mean completion delay in wireless broadcast for instantly decodable network coding. We first formulate the problem as a stochastic shortest path (SSP) problem. Although finding the packet selection policy using SSP is intractable, we use this formulation to draw the theoretical properties of efficient selection algorithms. Based on these properties, we propose a simple online selection algorithm that efficiently minimizes the mean completion delay of a frame of broadcast packets, compared to the random and greedy selection algorithms with a similar computational complexity. Simulation results show that our proposed algorithm indeed outperforms these random and greedy selection algorithms.

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Completion Delay Minimization for Instantly Decodable Network Codes

Sorour

Valaee

2015

IEEE/ACM Trans. Networking

107

117

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In this paper, we consider the problem of minimizing the completion delay for instantly decodable network coding (IDNC), in wireless multicast and broadcast scenarios. We are interested in this class of network coding due to its numerous benefits, such as low decoding delay, low coding and decoding complexities and simple receiver requirements. We first extend the IDNC graph, which represents all feasible IDNC coding opportunities, to efficiently operate in both multicast and broadcast scenarios. We then formulate the minimum completion delay problem for IDNC as a stochastic shortest path (SSP) problem. Although finding the optimal policy using SSP is intractable, we use this formulation to draw the theoretical guidelines for the policies that can efficiently reduce the completion delay in IDNC. Based on these guidelines, we design a maximum weight clique selection algorithm, which can efficiently reduce the IDNC completion delay in polynomial time. We also design a quadratic time heuristic clique selection algorithm, which can operate in real-time applications. Simulation results show that our proposed algorithms efficiently reduce the IDNC completion delay compared to the random and maximum-rate algorithms, and almost achieve the global optimal completion delay performance over all network codes in broadcast scenarios.

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Indoor Tracking and Navigation Using Received Signal Strength and Compressive Sensing on a Mobile Device

Feng

Valaee

et al. 2013

IEEE Trans. on Mobile Comput.

165

110

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Sameh Sorour

Deep Learning for IoT Big Data and Streaming Analytics: A Survey

Minimum Broadcast Decoding Delay for Generalized Instantly Decodable Network Coding

On Minimizing Broadcast Completion Delay for Instantly Decodable Network Coding

Completion Delay Minimization for Instantly Decodable Network Codes

Indoor Tracking and Navigation Using Received Signal Strength and Compressive Sensing on a Mobile Device

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