Approximate Inference in Continuous Time Gaussian-Jump Processes
Abstract
We present a novel approach to inference in conditionally Gaussian continuous time stochastic processes, where the latent process is a Markovian jump process. We first consider the case of jump-diffusion processes, where the drift of a linear stochastic differential equation can jump at arbitrary time points. We derive partial differential equations for exact inference and present a very efficient mean field approximation. By introducing a novel lower bound on the free energy, we then generalise our approach to Gaussian processes with arbitrary covariance, such as the non-Markovian RBF covariance. We present results on both simulated and real data, showing that the approach is very accurate in capturing latent dynamics and can be useful in a number of real data modelling tasks.
Cite
Text
Opper et al. "Approximate Inference in Continuous Time Gaussian-Jump Processes." Neural Information Processing Systems, 2010.Markdown
[Opper et al. "Approximate Inference in Continuous Time Gaussian-Jump Processes." Neural Information Processing Systems, 2010.](https://mlanthology.org/neurips/2010/opper2010neurips-approximate/)BibTeX
@inproceedings{opper2010neurips-approximate,
title = {{Approximate Inference in Continuous Time Gaussian-Jump Processes}},
author = {Opper, Manfred and Ruttor, Andreas and Sanguinetti, Guido},
booktitle = {Neural Information Processing Systems},
year = {2010},
pages = {1831-1839},
url = {https://mlanthology.org/neurips/2010/opper2010neurips-approximate/}
}