TY - JOUR
T1 - Multiview stereo and silhouette consistency via convex functionals over convex domains
AU - Cremers, Daniel
AU - Kolev, Kalin
N1 - Funding Information:
The authors thank Reinhard Klein and Dirk Koch for support with indoor image acquisition. They thank Svetlana Matiouk for helping with outdoor image acquisition and camera calibration, Carlos Hernandez and Yasutaka Furukawa for providing the data sets in Figs. 6 and 7, Sudipta Sinha for sharing his results for Fig. 6, and Antonin Chambolle and Thomas Pock for fruitful discussions on projection methods and convex optimization. This research was supported by the German Research Foundation, grant # CR250/1-2.
PY - 2011
Y1 - 2011
N2 - We propose a convex formulation for silhouette and stereo fusion in 3D reconstruction from multiple images. The key idea is to show that the reconstruction problem can be cast as one of minimizing a convex functional, where the exact silhouette consistency is imposed as convex constraints that restrict the domain of feasible functions. As a consequence, we can retain the original stereo-weighted surface area as a cost functional without heuristic modifications of this energy by balloon terms or other strategies, yet still obtain meaningful (nonempty) reconstructions which are guaranteed to be silhouette-consistent. We prove that the proposed convex relaxation approach provides solutions that lie within a bound of the optimal solution. Compared to existing alternatives, the proposed method does not depend on initialization and leads to a simpler and more robust numerical scheme for imposing silhouette consistency obtained by projection onto convex sets. We show that this projection can be solved exactly using an efficient algorithm. We propose a parallel implementation of the resulting convex optimization problem on a graphics card. Given a photoconsistency map and a set of image silhouettes, we are able to compute highly accurate and silhouette-consistent reconstructions for challenging real-world data sets. In particular, experimental results demonstrate that the proposed silhouette constraints help to preserve fine-scale details of the reconstructed shape. Computation times depend on the resolution of the input imagery and vary between a few seconds and a couple of minutes for all experiments in this paper.
AB - We propose a convex formulation for silhouette and stereo fusion in 3D reconstruction from multiple images. The key idea is to show that the reconstruction problem can be cast as one of minimizing a convex functional, where the exact silhouette consistency is imposed as convex constraints that restrict the domain of feasible functions. As a consequence, we can retain the original stereo-weighted surface area as a cost functional without heuristic modifications of this energy by balloon terms or other strategies, yet still obtain meaningful (nonempty) reconstructions which are guaranteed to be silhouette-consistent. We prove that the proposed convex relaxation approach provides solutions that lie within a bound of the optimal solution. Compared to existing alternatives, the proposed method does not depend on initialization and leads to a simpler and more robust numerical scheme for imposing silhouette consistency obtained by projection onto convex sets. We show that this projection can be solved exactly using an efficient algorithm. We propose a parallel implementation of the resulting convex optimization problem on a graphics card. Given a photoconsistency map and a set of image silhouettes, we are able to compute highly accurate and silhouette-consistent reconstructions for challenging real-world data sets. In particular, experimental results demonstrate that the proposed silhouette constraints help to preserve fine-scale details of the reconstructed shape. Computation times depend on the resolution of the input imagery and vary between a few seconds and a couple of minutes for all experiments in this paper.
KW - Image-based modeling
KW - convex optimization
KW - silhouette and stereo fusion
UR - http://www.scopus.com/inward/record.url?scp=79955474995&partnerID=8YFLogxK
U2 - 10.1109/TPAMI.2010.174
DO - 10.1109/TPAMI.2010.174
M3 - Article
C2 - 20820076
AN - SCOPUS:79955474995
SN - 0162-8828
VL - 33
SP - 1161
EP - 1174
JO - IEEE Transactions on Pattern Analysis and Machine Intelligence
JF - IEEE Transactions on Pattern Analysis and Machine Intelligence
IS - 6
M1 - 5567114
ER -