Title :
Quantum Memetic Evolutionary Algorithm-Based Low-Complexity Signal Detection for Underwater Acoustic Sensor Networks
Author :
Li, Bin ; Zhou, Zheng ; Zou, Weixia ; Li, Dejian
Author_Institution :
Sch. of Inf. & Commun. Eng., Beijing Univ. of Posts & Telecommun., Beijing, China
Abstract :
Modern communication engineering has brought forward impractical requirements on powerful computation engines as well as simple implementations. Apparently, the two aspects are contradicted in most realistic applications. Because of the dispersive multipath propagation in underwater acoustic channels, traditional coherent and adaptive receivers are computationally intensive and, hence, inapplicable to the large-scale underwater sensor networks. Inspired by quantum computing and nature intelligence that are incorporated with the concept of culture evolution, in this paper, we suggest a novel quantum memetic algorithm (QMA) built with more qualified problem-solving ability. Instead of classical gene representations, the quantum bit structure is employed by chromosomes to enhance the population diversity of genetic searching. The quantum gate rotating is then explored to update chromosomes in an efficiently parallel way. As a hybridization strategy, quantum-rotation-based local search is integrated in the lifetime learning to further refine individuals´ performance and accelerate their convergence toward the global optimality. As a significant real-world application, we develop a noncoherent underwater signal receiver that is based on a QMA framework. From a pattern recognition aspect, the suggested detection scheme includes two sequential phases: Features extraction and pattern classification. Finally, the highly computational optimization problem is elegantly addressed by QMA. Providing favorable robustness to various parameter configurations, QMA can considerably reinforce the search performance and improve the underwater signal detection. It is demonstrated from numerical experiments that QMA is much superior to genetic algorithm (GA) in this high-dimensional optimization. Meanwhile, QMA shows remarkable advantages in search performance, even to the current state-of-the-art quantum-inspired GA and memetic algorithm.
Keywords :
acoustic receivers; acoustic signal detection; convergence; dispersive channels; evolutionary computation; feature extraction; genetic algorithms; geophysical signal processing; learning (artificial intelligence); multipath channels; pattern classification; problem solving; quantum gates; search problems; underwater acoustic communication; underwater acoustic propagation; QMA; adaptive receivers; chromosome update; coherent receivers; communication engineering; computational optimization problem; convergence; dispersive multipath propagation; feature extraction; gene representations; genetic searching; global optimality; high-dimensional optimization; hybridization strategy; lifetime learning; nature intelligence; noncoherent underwater signal receiver; parameter configurations; pattern classification; pattern recognition; population diversity; qualified problem solving ability; quantum bit structure; quantum computing; quantum gate rotation-based local search; quantum memetic evolutionary algorithm-based low-complexity signal detection; sequential phases; underwater acoustic channels; underwater acoustic sensor networks; Acoustic sensors; Genetic algorithms; Memetics; Optimization; Signal detection; Underwater acoustics; High-dimensional optimization; hybridization evolution; noncoherent detection; quantum-inspired memetic algorithm; underwater acoustic communications;
Journal_Title :
Systems, Man, and Cybernetics, Part C: Applications and Reviews, IEEE Transactions on
DOI :
10.1109/TSMCC.2011.2176486
