Refining Outdoor Photometric Stereo Based on Sky Model
スポンサーリンク
概要
- 論文の詳細を見る
We propose an outdoor photometric stereo method, which considers environmental lighting for improving the performance of surface normal estimation. In the previous methods, the sky illumination effect has been either assumed to be constant throughout the scene, or to be removed by pre-processing. This paper exploits a sky model which can derive the entire sky luminance from a sky zenith image; then, sky illumination effect on a surface can be correctly calculated by iteratively refining its normal direction. This paper also extends a two-source photometric stereo method by introducing RANSAC, so that the input images of this method can be taken in a day. Experimental results with real outdoor objects show the effectiveness of the method.
著者
-
Mukaigawa Yasuhiro
The Institute of Scientific and Industrial Research, Osaka University
-
Ikeuchi Katsushi
Interfaculty Initiative In Information Studies The University Of Tokyo
-
Kawakami Rei
The Institute of Scientific and Industrial Research, Osaka University
-
Inose Kenji
Graduate School of Interdisciplinary Information Studies, The University of Tokyo
-
Shimizu Shota
Graduate School of Information Science and Technology, The University of Tokyo
関連論文
- Robust and Real-time Estimation of Camera Rotation with Translation-invariant Features
- Acquisition and Rectification of Shape Data Obtained by a Moving Range Sensor(Special Section Theses for a Doctorate and a Graduation)
- Illumination Recovery and Appearance Sampling for Photorealistic Rendering(Special Section on Theses for a Doctorate and a Graduation)
- Refining Outdoor Photometric Stereo Based on Sky Model
- Full-dimensional Sampling and Analysis of BSSRDF
- Synthesis of Dance Performance Based on Analyses of Human Motion and Music
- Synthesis of Dance Performance Based on Analyses of Human Motion and Music
- Full-dimensional Sampling and Analysis of BSSRDF
- Acquisition and Rectification of Shape Data Obtained by a Moving Range Sensor
- Acquisition and Rectification of Shape Data Obtained by a Moving Range Sensor