Title :
Continuous Inference in Graphical Models with Polynomial Energies
Author :
Salzmann, Mathieu
Author_Institution :
NICTA, Canberra, ACT, Australia
Abstract :
In this paper, we tackle the problem of performing inference in graphical models whose energy is a polynomial function of continuous variables. Our energy minimization method follows a dual decomposition approach, where the global problem is split into sub problems defined over the graph cliques. The optimal solution to these sub problems is obtained by making use of a polynomial system solver. Our algorithm inherits the convergence guarantees of dual decomposition. To speed up optimization, we also introduce a variant of this algorithm based on the augmented Lagrangian method. Our experiments illustrate the diversity of computer vision problems that can be expressed with polynomial energies, and demonstrate the benefits of our approach over existing continuous inference methods.
Keywords :
computer vision; graph theory; minimisation; polynomials; augmented Lagrangian method; computer vision problems diversity; continuous inference method; continuous variables polynomial function; dual decomposition approach; energy minimization method; graph cliques; graphical models; polynomial energies; polynomial system solver; Approximation methods; Belief propagation; Computer vision; Convergence; Graphical models; Minimization; Polynomials;
Conference_Titel :
Computer Vision and Pattern Recognition (CVPR), 2013 IEEE Conference on
Conference_Location :
Portland, OR
DOI :
10.1109/CVPR.2013.228
