Abstract
The covertness of the active sonar is a very important issue and the sonar signal waveform design problem was studied to improve covertness of the system. Many marine mammals produce call pulses for communication and echolocation, and existing interception systems normally classify these biological signals as ocean noise and filter them out. Based on this, a bio-inspired covert active sonar strategy was proposed. The true, rather than man-made sperm whale, call pulses were used to serve as sonar waveforms so as to ensure the camouflage ability of sonar waveforms. A range and velocity measurement combination (RVMC) was designed by using two true sperm whale call pulses which had excellent range resolution (RR) and large Doppler tolerance (DT). The range and velocity estimation methods were developed based on the RVMC. In the sonar receiver, the correlation technology was used to confirm the start and end time of sonar signals and their echoes, and then based on the developed range and velocity estimation method, the range and velocity of the underwater target were obtained. Then, the RVMC was embedded into the true sperm whale call-train to improve the camouflage ability of the sonar signal-train. Finally, experiment results were provided to verify the performance of the proposed method.
Highlights
By sending out signals for target detection, an active sonar system [1,2,3,4,5] unavoidably risks being detected and identified by the others too
For frequency-hopping signals, each pulse could be continuous-wave (CW) or linear frequency modulated (LFM); the CW pulses have the feature of being of rectangle in the time domain and single frequency in the frequency domain, while LFM pulses are of both rectangle in the time domain and linearly changed frequency in the frequency domain [10]
This paper does not utilize the low probability-of-detection (LPD) design, which is used by conventional covert sonar design methods, but instead uses the camouflage to accomplish covert detection, when detecting targets in a small distance range, the underwater platform with active sonar can transmit the sonar signal pulses with low signal noise ratio (SNR), which is very beneficial to improve concealment ability from a low probability of detection (LPD) perspective
Summary
By sending out signals for target detection, an active sonar system [1,2,3,4,5] unavoidably risks being detected and identified by the others too. Studied how bats detect and recognize the faint echoes generated by their own calls when many individuals emit bio-sonar calls simultaneously, and obtained an important and novel achievement: the bats’ response aimed to increase the signal-to-noise ratio and not to avoid spectral overlap [26]. In their study, they utilize the original bat call pulses or those man-made call pulses, which are generated by changing the distribution of spectral energy of the original bat call pulses, and artificial. Their distribution demonstrates that the sonar system using their call pulses to serve as the sonar waveforms can be used widely in any open sea area and has good generality
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