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Optimal and adaptive methods of processing hydroacoustic signals (review)

  • Acoustic Signal Processing and Computer Simulation
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Abstract

Different methods of optimal and adaptive processing of hydroacoustic signals for multipath propagation and scattering are considered. Advantages and drawbacks of the classical adaptive (Capon, MUSIC, and Johnson) algorithms and “fast” projection algorithms are analyzed for the case of multipath propagation and scattering of strong signals. The classical optimal approaches to detecting multipath signals are presented. A mechanism of controlled normalization of strong signals is proposed to automatically detect weak signals. The results of simulating the operation of different detection algorithms for a linear equidistant array under multipath propagation and scattering are presented. An automatic detector is analyzed, which is based on classical or fast projection algorithms, which estimates the background proceeding from median filtering or the method of bilateral spatial contrast.

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  1. OAO Concern CSRI Elektropribor, ul. Malaya Posadskaya 30, St. Petersburg, 197046, Russia

    G. S. Malyshkin & G. B. Sidel’nikov

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  1. G. S. Malyshkin
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  2. G. B. Sidel’nikov
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Correspondence to G. S. Malyshkin.

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Original Russian Text © G.S. Malyshkin, G.B. Sidel’nikov, 2014, published in Akusticheskii Zhurnal, 2014, Vol. 60, No. 5, pp. 526–545.

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Malyshkin, G.S., Sidel’nikov, G.B. Optimal and adaptive methods of processing hydroacoustic signals (review). Acoust. Phys. 60, 570–587 (2014). https://doi.org/10.1134/S1063771014050091

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