The inhomogeneous Gibbs model (IGM) (Liu et al., 2001) is an effective maximum entropy model in characterizing complex high-dimensional distributions. However, its training process is so slow that the applicability of IGM has been greatly restricted. In this paper, we propose an approach for fast parameter learning of IGM. In IGM learning, features are incrementally constructed to constrain the learnt distribution. When a new feature is added, Markov-chain Monte Carlo (MCMC) sampling is repeated to draw samples for parameter learning. In contrast, our approach constructs a closed-form reference distribution using approximate information gain criteria. Because our reference distribution is very close to the optimal one, importance sampling can be used to accelerate the parameter optimization process. For problems with high-dimensional distributions, our approach typically achieves a speedup of two orders of magnitude compared to the original IGM. We further demonstrate the efficiency of our approach by learning a high-dimensional joint distribution of face images and their corresponding caricatures.
[1]
Harry Shum,et al.
Learning Inhomogeneous Gibbs Model of Faces by Minimax Entropy
,
2001,
ICCV.
[2]
Adam L. Berger,et al.
A Maximum Entropy Approach to Natural Language Processing
,
1996,
CL.
[3]
J. Darroch,et al.
Generalized Iterative Scaling for Log-Linear Models
,
1972
.
[4]
Song-Chun Zhu,et al.
Learning in Gibbsian Fields: How Accurate and How Fast Can It Be?
,
2002,
IEEE Trans. Pattern Anal. Mach. Intell..
[5]
Harry Shum,et al.
Example-based caricature generation with exaggeration
,
2002,
10th Pacific Conference on Computer Graphics and Applications, 2002. Proceedings..
[6]
John D. Lafferty,et al.
Inducing Features of Random Fields
,
1995,
IEEE Trans. Pattern Anal. Mach. Intell..
[7]
Song-Chun Zhu,et al.
Minimax Entropy Principle and Its Application to Texture Modeling
,
1997,
Neural Computation.
[8]
Timothy F. Cootes,et al.
Active Appearance Models
,
1998,
ECCV.