Communication scheduling in data gathering networks of heterogeneous sensors with data compression: Algorithms and empirical experiments

•Investigated a communication scheduling problem to address data compression and data communication together.•Proposed a pseudo-polynomial time exact algorithm based on dynamic programming.•Proposed a fully polynomial time approximation scheme.•Extensive numerical experiments conducted to examine th...

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Vydáno v:European journal of operational research Ročník 271; číslo 2; s. 462 - 473
Hlavní autoři: Luo, Wenchang, Gu, Boyuan, Lin, Guohui
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier B.V 01.12.2018
Témata:
Algorithm
Data compression
Performance analysis
Scheduling
Wireless sensor network
Wireless sensor network
Scheduling
Performance analysis
Algorithm
Data compression
ISSN:0377-2217, 1872-6860
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Shrnutí:•Investigated a communication scheduling problem to address data compression and data communication together.•Proposed a pseudo-polynomial time exact algorithm based on dynamic programming.•Proposed a fully polynomial time approximation scheme.•Extensive numerical experiments conducted to examine the practical performance of the algorithms. We consider a communication scheduling problem to address data compression and data communication together, arising from the data gathering wireless sensor networks with data compression. In the problem, the deployed sensors are heterogeneous, in that the data compression ratios, in terms of size reduction, the compression time, and the compression costs, in terms of energy consumption, on different sensors are different. The bi-objective is to minimize the total compression cost and to minimize the total time to transfer all the data to the base station. The problem reduces to two mono-objective optimization problems in two separate ways: in the original problem a time bound is given and the mono-objective is to minimize the total compression cost, and in the complementary problem a global compression budget is given and the mono-objective is to minimize the makespan. We present a unified exact algorithm for both of them based on dynamic programming; this exact algorithm is then developed into a fully polynomial time approximation scheme for the complementary problem, and a dual fully polynomial time approximation scheme for the original problem. All these approximation algorithms have been implemented and extensive computational experiments show that they run fast and return the optimal solutions almost all the time.
ISSN:0377-2217
1872-6860
DOI:10.1016/j.ejor.2018.05.047