Abstract
A common problem in underwater side-scan sonar images is the acoustic shadow generated by the beam. Apart from that, there are a number of reasons impairing image quality. In this paper, an innovative algorithm with two alternative histogram approximation methods is presented. Histogram approximation is based on automatically estimating the optimal threshold for converting the original gray scale images into binary images. The proposed algorithm clears the shadows and masks most of the impairments in side-scan sonar images. The idea is to select a proper threshold towards the rightmost local minimum of the histogram, i.e., closest to the white values. For this purpose, the histogram envelope is approximated by two alternative contour extraction methods: polynomial curve fitting and data smoothing. Experimental results indicate that the proposed algorithm produces superior results than popular thresholding methods and common edge detection filters, even after corrosion expansion. The algorithm is simple, robust and adaptive and can be used in automatic target recognition, classification and storage in large-scale multimedia databases.
Highlights
This research deals with the problem of the detection of man-made objects detected in side-scan sonar images
This paper presents an algorithm for contour extraction based on automatically estimating the optimal threshold for converting Side-scan sonar (SSS) grayscale images into binary
Simulation results obtained in Octave and MATLAB indicate that the proposed methods produce superior results compared to popular thresholding methods and common edge detection filters, even after corrosion expansion
Summary
Sonar systems are the best and often the only means to efficiently and accurately create images of large areas of the seafloor. The equipment is used to obtain complete coverage of the specified areas and operates at scales commensurate with line spacing, optimum resolution and 100% data overlap. This coverage is attained by transmitting one beam on each side, broad in the vertical plane and narrow in the horizontal plane (Figure 1). When stitched together along the direction of motion, these slices form an image of the sea bottom within the coverage width of the beam This instrument covers a much larger portion of the seabed away from the surveying vessel, from a few tens of meters to 60 km or more. Today a wide variety of commercial components with excellent capabilities is available on the market for every application
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