Transparent Object Reconstruction via Coded Transport of Intensity

Author

Chenguang Ma ; Xing Lin ; Jinli Suo ; Qionghai Dai ; Wetzstein, Gordon

Author_Institution

Dept. of Autom., Tsinghua Univ., Beijing, China

fYear

2014

fDate

23-28 June 2014

Firstpage

3238

Lastpage

3245

Abstract

Capturing and understanding visual signals is one of the core interests of computer vision. Much progress has been made w.r.t. many aspects of imaging, but the reconstruction of refractive phenomena, such as turbulence, gas and heat flows, liquids, or transparent solids, has remained a challenging problem. In this paper, we derive an intuitive formulation of light transport in refractive media using light fields and the transport of intensity equation. We show how coded illumination in combination with pairs of recorded images allow for robust computational reconstruction of dynamic two and three-dimensional refractive phenomena.

Keywords

computer vision; image capture; image coding; image reconstruction; light refraction; computational reconstruction robustness; computer vision; dynamic two-dimensional refractive phenomena; gas; heat flows; imaging aspects; intensity coded transport; light fields; light transport intuitive formulation; liquids; media refraction; refractive phenomena reconstruction; solids transparency; three-dimensional refractive phenomena; transparent object reconstruction; turbulence; visual signals; Equations; Image reconstruction; Lighting; Mathematical model; Optical imaging; Optical refraction; Refractive index;

fLanguage

English

Publisher

ieee

Conference_Titel

Computer Vision and Pattern Recognition (CVPR), 2014 IEEE Conference on

Conference_Location

Columbus, OH

Type

conf

DOI

10.1109/CVPR.2014.420

Filename

6909810