Linear Latent Force Models Using Gaussian Processes

Author

Alvarez, Mauricio A. ; Luengo, D. ; Lawrence, Neil D.

Author_Institution

Dept. of Electr. Eng., Univ. Tecnol. de Pereira, Pereira, Colombia

Volume

35

Issue

11

fYear

2013

Firstpage

2693

Lastpage

2705

Abstract

Purely data-driven approaches for machine learning present difficulties when data are scarce relative to the complexity of the model or when the model is forced to extrapolate. On the other hand, purely mechanistic approaches need to identify and specify all the interactions in the problem at hand (which may not be feasible) and still leave the issue of how to parameterize the system. In this paper, we present a hybrid approach using Gaussian processes and differential equations to combine data-driven modeling with a physical model of the system. We show how different, physically inspired, kernel functions can be developed through sensible, simple, mechanistic assumptions about the underlying system. The versatility of our approach is illustrated with three case studies from motion capture, computational biology, and geostatistics.

Keywords

Gaussian processes; differential equations; learning (artificial intelligence); Gaussian process; computational biology; data-driven approach; differential equation; geostatistics; kernel function; linear latent force model; machine learning; motion capture; Analytical models; Computational modeling; Data models; Differential equations; Force; Gaussian processes; Mathematical model; Gaussian processes; differential equations; dynamical systems; motion capture data; multitask learning; spatiotemporal covariances; Algorithms; Artificial Intelligence; Computer Simulation; Linear Models; Normal Distribution; Pattern Recognition, Automated; Sample Size;

fLanguage

English

Journal_Title

Pattern Analysis and Machine Intelligence, IEEE Transactions on

Publisher

ieee

ISSN

0162-8828

Type

jour

DOI

10.1109/TPAMI.2013.86

Filename

6514873