Abstract
We present a novel computational photography technique for single-shot separation of diffuse/specular reflectance, as well as novel angular domain separation of layered reflectance. We present two imaging solutions for this purpose: two-way polarized light-field (TPLF) imaging and four-way polarized light-field (FPLF) imaging. TPLF imaging consists of a polarized light-field camera, which simultaneously captures two orthogonal states of polarization. A single photograph of a subject acquired with the TPLF camera under polarized illumination then enables standard separation of diffuse (depolarizing) and polarization preserving specular reflectance using light-field sampling. We further demonstrate that the acquired data also enable novel angular separation of layered reflectance including separation of specular reflectance and single scattering in the polarization preserving component, as well as separation of shallow scattering from deep scattering in the depolarizing component. FPLF imaging further generalized the functionality of TPLF imaging under uncontrolled unpolarized or partially polarized illumination such as outdoors. We apply our approach for efficient acquisition of facial reflectance including diffuse and specular normal maps and novel separation of photometric normals into layered reflectance normals for layered facial renderings. We validate our proposed single-shot layered reflectance separation under various imaging conditions and demonstrate it to be comparable to an existing multi-shot technique that relies on structured lighting while achieving separation results under a variety of illumination conditions.
Highlights
Accurate modelling and realistic reproduction of appearance has been widely explored in computer vision and graphics
We present an extended version of the polarized light-field technique, four-way polarized light-field (FPLF) imaging, with higher polarization dimensions and imaging resolution for more general applications of single-shot reflectance acquisition
We describe our acquisition technique for diffuse and specular reflectance based on our novel two-way polarized light-field (TPLF) camera, which addresses the challenge of capturing two different polarization states in a single-shot
Summary
Accurate modelling and realistic reproduction of appearance has been widely explored in computer vision and graphics. Polarization-based separation in conjunction with a sophisticated light stage setup [7] has achieved high quality separation of specular and diffuse reflectance and has been applied as one of the optimal solutions for high-end capture of human faces and objects This approach has traditionally required multi-shot capture with different polarization modes (such as cross- and parallel polarization states) for separate acquisition of reflectance components or optically complicated imaging systems (e.g., multiple cameras sharing an optical axis through a beam-splitter) for multiplexed acquisition of different polarization states. We present an extension of our recent work [9] proposing two novel techniques for efficient single-shot acquisition of surface and subsurface reflectance with novel computational analysis of the polarized light-field data for layered reflectance separation.
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