Results are presented that demonstrate the effectiveness of using polarization discrimination to improve visibility when imaging in a scattering medium. The study is motivated by the desire to improve visibility depth in turbid environments, such as the sea. Most previous research in this area has concentrated on the active illumination of objects with polarized light. We consider passive or ambient illumination, such as that deriving from sunlight or a cloudy sky. The basis for the improvements in visibility observed is that single scattering by small particles introduces a significant amount of polarization into light at scattering angles near 90°: This light can then be distinguished from light scattered by an object that remains almost completely unpolarized. Results were obtained from a Monte Carlo simulation and from a small-scale experiment in which an object was immersed in a cell filled with polystyrene latex spheres suspended in water. In both cases, the results showed an improvement in contrast and visibility depth for obscuration that was due to Rayleigh particles, but less improvement was obtained for larger scatterers.
© 2003 Optical Society of America
(100.2980) Image processing : Image enhancement
(110.7050) Imaging systems : Turbid media
(120.2130) Instrumentation, measurement, and metrology : Ellipsometry and polarimetry
(290.4210) Scattering : Multiple scattering
(290.7050) Scattering : Turbid media
Peter C. Y. Chang, Jonathan C. Flitton, Keith I. Hopcraft, Eric Jakeman, David L. Jordan, and John G. Walker, "Improving Visibility Depth in Passive Underwater Imaging by Use of Polarization," Appl. Opt. 42, 2794-2803 (2003)