Abstract
The matched filtering method and the waveform-tracking method cannot maintain optimal velocity estimation performance all of the time. In order to solve this problem, this paper proposes an improved velocity estimation method for Doppler sonar, based on accuracy evaluation and selection. The echo of Doppler sonar is divided into several segments with the same width as the transmitted pulse, and each segment is regarded as the echo of the corresponding water layer. According to our study’s results, the velocity estimation accuracy of each segment is positively correlated with the ratio of its autocorrelation modulus to its power. Based on this conclusion, a velocity accuracy criterion with high accuracy and low complexity is designed in order to select the optimal velocity estimation for water layers or bottoms. The proposed accuracy selection method flexibly selects the echo interval to be processed according to the accuracy criterion, so as to maintain the optimal estimation of the current’s or bottom’s velocity. Water tank and field experiments using a prototype Doppler sonar device demonstrates that, compared with the matched filtering method and the waveform-tracking method, the average velocity estimation accuracy and bias of the proposed method are superior.
Highlights
Doppler sonar is a popular acoustic technique used for measuring water velocity and profile discharge in natural and man-made waterways
A velocity estimation method based on accuracy evaluation and selection for Doppler sonar was proposed in this paper, in order to resolve the defects in accurate velocity estimation via the matched filtering method or the waveform-tracking method
The Doppler sonar echo is divided into several segments with the same width as the transmitted pulse, and each segment reflects the information of its corresponding water layer
Summary
Doppler sonar is a popular acoustic technique used for measuring water velocity and profile discharge in natural and man-made waterways. (2) Number of code repeats: The purpose of transmitting phase-encoded signals repeatedly in broadband Doppler sonar is to maximize the energy transmitted into the water and increase the signal-to-noise ratio (SNR) of the echoes. This repetition will cause additional echo autocorrelation peaks, and reduce the independence of echo samples [14]; the repetition reduces the proportion of the echo segment that produces selfnoise in the total echo, and decreases the influence of self-noise.
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