Abstract
Object identification in highly turbid optical media depends mainly on the quality of collected images. Underwater images acquired in a turbid environment are generally of very poor quality. Attenuation and backscattering of light by water, by materials dissolved in the water, and by particulate material are the main causes of the degradation of underwater images. It is therefore essential to improve the quality of such images to facilitate object identification. The focus of this paper is to report the principle and validation of a fast and effective method of improving the quality of underwater images. On the one hand, this method uses a polarimetric imaging optical system to reduce the effect of diffusion on the image acquisition. On the other hand, it is based on an optimized version of the dark channel prior (DCP) method that has received a great deal of attention for image dehazing. Results derived from images obtained in a controlled laboratory water tank environment with different turbidity conditions and images from tests using the proposed method at sea demonstrate an ability to significantly improve visibility and reduce runtime by a factor of about 50 for a 4K image when compared to conventional DCP methods.
Highlights
1.1 BackgroundMost underwater vehicles are equipped with at least one embedded camera to observe and analyze the seabed
Absorption and scattering of light by water, by materials dissolved in the water, and by particulate material are the main causes of the degradation of these images
The method is based on an optimized version of the dark channel prior (DCP) method that has received a great deal of attention for image dehazing
Summary
Most underwater (scientific, industrial or military) vehicles are equipped with at least one embedded camera to observe and analyze the seabed. According to Schechner and Karpel [6], backscattering is the main reason for deterioration of the underwater visibility, forward scattering can be neglected. This assumption is valid when the distance between the scene and the camera is large. Forward scattering causes a blur in the image while backscattering produces a light veil which reduces the contrast and visibility of the observed scene [4]. Using artificial lighting to improve visibility introduces shadows and illuminates the scene in a non-uniform way Both phenomena make it difficult, even impossible, to detect and/or identify objects in strongly turbid optical media
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