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Telecommunication Systems

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10-02-2021

Enhanced target detection using a new combined sonar waveform design

Authors: Omid Pakdel Azar, Hadi Amiri, Farbod Razzazi

Published in: Telecommunication Systems | Issue 2/2021

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Abstract

In this paper, a method for combining wideband and narrowband waveforms is proposed to improve target detection in shallow water environments. In this regard, a sonar waveform design suitable for target speed has been proposed too. The method uses a wideband frequency-modulated waveform for high range resolution in a reverberation environment and the Doppler-sensitive (DS) waveform to improve the detection of moving targets. The proposed combined waveform is mathematically modeled, and the Calculating of ambiguity function (AF) is performed. The AF and autocorrelation function (ACF) of the designed waveform indicate both DS and fair range resolution features simultaneously exist. So the initial range resolution for target detection is preserved. The Peak to Sidelobe level (PSL) ratio of the proposed waveform is at least 25 dB more than the previous state of the art waveforms. Calculating the Q-function criterion for the designed waveform reveals the superior reverberation suppression and detection performance with respect to the state of the art waveforms. After calculating the reverberation channel model, waveform echo, and detection of the target, the probability of detection (Pd) versus signal-to-reverberation ratio (SRR) was simulated by the Monte Carlo method. It was shown that the proposed waveform improved the probability of target detection by 20 dB, comparing to the base waveforms.

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Hodges, R. P. (2011). Underwater acoustics analysis, design, and performance of SONAR (1st ed.). Hoboken: Wiley.

Li, Q. (2012). Digital sonar design in underwater acoustic. Heidelberg: Springer.CrossRef

Blunt, S. D., & Mokole, E. L. (2016). An overview of radar waveform diversity. IEEE Aerospace and Electronic Systems Magazine, 31(11), 2–42.CrossRef

Yao, Y., Zhao, J., & Wu, L. (2019). Cognitive design of radar waveform and the receive filter for multitarget parameter estimation. Journal of Optimization Theory and Applications, 181, 684–705.CrossRef

Zhang, Y.-X., et al. (2017). Frequency-domain range sidelobe correction in stretch processing for wideband LFM radars. IEEE Transactions on Aerospace and Electronic Systems, 53(1), 111–121.CrossRef

Nusenu, S. Y., Chen, H., & Wang, W.-Q. (2018). OFDM chirp radar for adaptive target detection in low grazing angle. IET Signal Process, 12(5), 613–619.CrossRef

Levanon, N., Cohen, I., & Itkin, P. (2017). Complementary pair radar waveforms–evaluating and mitigating some drawbacks. IEEE A&E Systems Magazine, 32, 40–50.CrossRef

Hague, D. A., & Buck, J. R. (2019). An experimental evaluation of the generalized sinusoidal frequency-modulated waveform for active sonar systems. The Journal of the Acoustical Society of America, 145, 3741.CrossRef

Alaie, M. B., & Olamaei, S. A. (2020). Waveform design for TDM-MIMO radar systems. IEEE, Signal Processing, 167, 107307.CrossRef

10.

He, H., Li, J., & Stoica, P. (2012). Waveform design for active sensing systems: A computational approach (pp. 88–102). New York, NY: Cambridge University Press.CrossRef

11.

Song, J., Babu, P., & Palomar, D. P. (2016). Sequence design to minimize the weighted integrated and peak side lobe levels. IEEE Transactions on Signal Processing, 64(8), 2051–2064. https://doi.org/10.1109/TSP.2015.2510982.CrossRef

12.

Fan, W., Liang, J., Yu, G., So, H. C., & Lu, G. (2020). Minimum local peak side lobe level waveform design with correlation and/or spectral constrains. Signal Processing, 171, 107450.CrossRef

13.

Sankuru, S. P., & Babu, P. (2020). Designing the unimodular sequence with good auto-correlation properties via block majorization-minimization method. Signal Processing, 176, 107707.CrossRef

14.

Waite, A. D. (2001). Sonar for practising engineers (3rd ed.). Hoboken: Wiley.

15.

Wang, F., Du, S., Sun, W., Huang, Q., & Su, J. (2017). A method of velocity estimation using composite hyperbolic frequency-modulated signals in active sonar. The Journal of the Acoustical Society of America, 141, 3117.CrossRef

16.

Polak, L., & Milos, J. (2020). Performance analysis of LoRa in the 2.4 GHz ISM band: Coexistence issues with Wi-Fi. Telecommunication Systems, 74, 299–309. https://doi.org/10.1007/s11235-020-00658-w.CrossRef

17.

Yin, J., Men, W., Han, X., & Guo, L. (2020). The integrated waveform for continuous active sonar detection and communication. IET Radar, Sonar & Navigation, 14(9), 1382–1390.CrossRef

18.

Zhang, Q., Lu, G., Zhang, C., et al. (2020). Development of arbitrary waveform torsional vibration signal generator. Telecommunication Systems. https://doi.org/10.1007/s11235-020-00692-8.CrossRef

19.

Deferrari, H., & Wylie, J. (2013). Ideal signals and processing for continuous active sonar. In Proceedings of the meetings on acoustics (pp. 55–58). Montreal, QC, Canada.

20.

Huang, T., & Wang, T. (2019). Research on analyzing and processing methods of ocean sonar signals. In D. Gong, H. Zhu, & R. Liu, R. (Eds.), Selected topics in coastal research: Engineering, industry, economy, and sustainable development (pp. 208–212). Journal of Coastal Research, Special Issue No. 94.

21.

Guan, C., Zhou, Z., & Zeng, X. (2019). Optimal waveform design using frequency modulated pulse trains for active sonar. Sensors, 19(1), 4262. https://doi.org/10.3390/s19194262.CrossRef

22.

Baggenstoss, P. M. (2013). Specular decomposition of active sonar returns using combined waveforms. IEEE Transactions on Aerospace and Electronic Systems, 49(4), 2509–2521.CrossRef

23.

Li, C.-X., Guo, M.-F., & Zhao, H.-F. (2020). An iterative deconvolution-time reversal method with noise reduction, a high resolution and sidelobe suppression for active sonar in shallow water environments. Sensors, 20, 2844.CrossRef

24.

Lee, S., & Lim, J. S. (2019). (2019) Reverberation suppression using non-negative matrix factorization to detect low-Doppler target with continuous wave active sonar. EURASIP Journal on Advances in Signal Processing, 1, 1–18. https://doi.org/10.1186/s13634-019-0608-6.CrossRef

25.

Hague, D. A., & Buck, J. R. (2017). The generalized sinusoidal frequency-modulated waveform for active sonar. IEEE Journal of Oceanic Engineering, 42(1), 109–123.

26.

Hague, D. A. (2020). Adaptive transmit waveform design using multi-tone sinusoidal frequency modulation. arXiv preprint https://arxiv.org/abs/2002.10159. Accepted 24 February 2020.

27.

Touati, N., Tatkeu, C., Chonavel, T., & Rivenq, A. (2016). Design and performance evaluation of new costas-based radar waveforms with pulse coding diversity. IET Radar, Sonar & Navigation, 10(5), 877–891.CrossRef

28.

Guan, C., Zhou, Z., & Zeng, X. (2020). A phase-coded sequence design method for active sonar. Sensors, 20, 4659.CrossRef

29.

Trider, R. C. (2012). Signal investigation for low-frequency active (LFA) sonar, defense research, and development. Canada—Atlantic.

30.

Qian, Q., Cui, Y., Wang, H., et al. (2020). REPAIR: fragile watermarking for encrypted speech authentication with recovery ability. Telecommunication Systems. https://doi.org/10.1007/s11235-020-00684-8.CrossRef

31.

Jin, Y., Wang, H. Q., Jiang, W. D., & Zhuang, Z. W. (2013). Complementary based chaotic phase-coded waveforms design for MIMO radar. IET Radar, Sonar & Navigation, 7(4), 371–382.CrossRef

32.

Arora, K., Singh, J., & Randhawa, Y. S. (2020). A survey on channel coding techniques for 5G wireless networks. Telecommunication Systems, 73, 637–663. https://doi.org/10.1007/s11235-019-00630-3.CrossRef

33.

Abraham, D. A. (2019). Underwater acoustic signal processing modeling, detection, and estimation. Berlin: Springer.CrossRef

34.

Coxson, G. E. (2019). Biosonar inspiration for radar waveform design. The Journal of the Acoustical Society of America, 145, 1700.CrossRef

35.

Han, J., Zhan, L., & Leus, G. (2016). Partial FFT demodulation for MIMO-OFDM over time-varying underwater acoustic channels. IEEE Signal Processing Letters, 23(2), 282–286.

36.

Zaytsev, G. V., & Khzmalyan, A. D. (2020). A family of optimal window functions for spectral analysis with the spectrum sidelobe falloff rate multiple of 12 dB per octave. Journal of Communications Technology and Electronics, 65, 502–515.CrossRef

37.

Levanon, N., & Mozeson, E. (2004). Radar signals (1st ed.). Hoboken, NJ: Wiley. https://doi.org/10.1002/0471663085 (ISBN 9780471663089).CrossRef

38.

Etter, P. C. (2013). Underwater acoustic modeling and simulation (4th ed.). London: E&FN SPON.

39.

Chotiros, N. P. (2010). Non-Rayleigh distributions in underwater acoustic reverberation in a patchy environment. IEEE Journal of Oceanic Engineering, 35(2), 236–241.CrossRef

40.

Lee, W.-J., & Stanton, T. K. (2016). Statistics of broadband echoes: Application to acoustic estimates of numerical density of fish. IEEE Journal of Oceanic Engineering, 41(3), 709–723.CrossRef

41.

Mahafza, B. R. (2013). Radar systems analysis and design using Matlab. Boca Raton: CRC Press.

42.

Bessemer, M., Djebbar, A. B., Zouggaret, A., et al. (2020). Joint channel estimation and data detection for OFDM based cooperative system. Telecommunication Systems, 73, 545–556. https://doi.org/10.1007/s11235-019-00622-3.CrossRef

Title: Enhanced target detection using a new combined sonar waveform design
Authors: Omid Pakdel Azar
Hadi Amiri
Farbod Razzazi
Publication date: 10-02-2021
Publisher: Springer US
Published in: Telecommunication Systems / Issue 2/2021
Print ISSN: 1018-4864
Electronic ISSN: 1572-9451
DOI: https://doi.org/10.1007/s11235-021-00761-6

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