A Quantum-Statistical-Mechanical Extension of Gaussian Mixture Model

A Quantum-Statistical-Mechanical Extension of Gaussian Mixture Model Kazuyuki Tanaka Graduate School of Information Sciences, Tohoku University, Sendai, Japan http://www.smapip.is.tohoku.ac.jp/~kazu/ In collaboration with Koji Tsuda Max Planck Institute for Biological Cybernetics,Germany IW-SMI2007, Kyoto

Contents • Introduction • Conventional Gaussian Mixture Model • Quantum Mechanical Extension of Gaussian Mixture Model • Quantum Belief Propagation • Concluding Remarks IW-SMI2007, Kyoto

Information Processing by using Quantum Statistical-Mechanics • Quantum Annealing in Optimizations • Quantum Error Correcting Codes etc... Massive Information Processing by means of Density Matrix IW-SMI2007, Kyoto

Motivations How can we construct the quantum Gaussian mixture model? How can we construct a data-classification algorithm by using the quantum Gaussian mixture model? IW-SMI2007, Kyoto

Prior of Gauss Mixture Model One of three labels 1,2 and 3 is assigned to each node. 3 labels Label xi is generated randomly and independently of each node. Histogram 2 3 1 xi=2 xi=3 xi=1 IW-SMI2007, Kyoto

Date Generating Process Data yi are generated randomly and independently of each node. xi=1 xi=2 xi=3 IW-SMI2007, Kyoto

Gauss Mixture Models Prior Probability Data Generating Process Marginal Likelihood for Hyperparameters m,s and a IW-SMI2007, Kyoto

Conventional Gauss Mixture Models a, m, s r(yi) Labels IW-SMI2007, Kyoto

Quantum Gauss Mixture Models IW-SMI2007, Kyoto

Quantum Gauss Mixture Models Quantum Representation IW-SMI2007, Kyoto

Quantum Gauss Mixture Models IW-SMI2007, Kyoto

Maxmum Likelihood Estimation in Quantum Gauss Mixture Model Linear Response Formulas IW-SMI2007, Kyoto

Quantum Gauss Mixture Models a, m, s r(yi) IW-SMI2007, Kyoto

Image Segmentation g = 0.4 g = 0.2 Conventional Gauss Mixture Model Original Image Quantum Gauss Mixture Model Histogram 0 255 0 255 0 255 IW-SMI2007, Kyoto

Image Segmentation g = 1.0 g = 0.5 Conventional Gauss Mixture Model Original Image Quantum Gauss Mixture Model Histogram 0 255 0 255 0 255 IW-SMI2007, Kyoto

= > = 4 labels Image Segmentation by Combining Gauss Mixture Model with Potts Model Potts Model Belief Propagation IW-SMI2007, Kyoto

Image Segmentation Gauss Mixture Model Gauss Mixture Model and Potts Model Original Image Histogram Belief Propagation IW-SMI2007, Kyoto

j i Density Matrix and Reduced Density Matrix Reduced Density Matrix Reducibility Condition IW-SMI2007, Kyoto

Reduced Density Matrix and Effective Fields i j All effective field are matrices i IW-SMI2007, Kyoto

Belief Propagation for Quantum Statistical Systems Propagating Rule of Effective Fields j i Output IW-SMI2007, Kyoto

Summary • An Extension to Quantum Statistical Mechanical Gaussian Mixture Model • Practical Algorithm  Linear Response Formula Future Problem Application of Potts Model and Quantum Belief Propagation Applications to Data Mining Extension to Quantum Deterministic Annealing IW-SMI2007, Kyoto

A Quantum-Statistical-Mechanical Extension of Gaussian Mixture Model

A Quantum-Statistical-Mechanical Extension of Gaussian Mixture Model

Presentation Transcript

Improved Adaptive Gaussian Mixture Model for Background

Quantum Mechanical Model

Quantum Mechanical Model of the Atom

Quantum Mechanical Model

Quantum Mechanical Model

Quantum Mechanical Model

Speaker Identification using Gaussian Mixture Model

Gaussian Mixture Model

Gaussian Mixture Models

Univariate Gaussian Mixture Model

Quantum Mechanical Model

Quantum Mechanical Model of the Atom

Quantum Mechanical Model Systems

Quantum Mechanical Model

The Quantum Mechanical Model

Quantum Mechanical Model of the Atom

Quantum Mechanical Model

Gaussian Mixture Models

The Quantum Mechanical Model

Quantum Mechanical Model of the Atom

Quantum mechanical model of the atom