English

Linear dynamical neural population models through nonlinear embeddings

Neurons and Cognition 2016-10-26 v2 Machine Learning

Abstract

A body of recent work in modeling neural activity focuses on recovering low-dimensional latent features that capture the statistical structure of large-scale neural populations. Most such approaches have focused on linear generative models, where inference is computationally tractable. Here, we propose fLDS, a general class of nonlinear generative models that permits the firing rate of each neuron to vary as an arbitrary smooth function of a latent, linear dynamical state. This extra flexibility allows the model to capture a richer set of neural variability than a purely linear model, but retains an easily visualizable low-dimensional latent space. To fit this class of non-conjugate models we propose a variational inference scheme, along with a novel approximate posterior capable of capturing rich temporal correlations across time. We show that our techniques permit inference in a wide class of generative models.We also show in application to two neural datasets that, compared to state-of-the-art neural population models, fLDS captures a much larger proportion of neural variability with a small number of latent dimensions, providing superior predictive performance and interpretability.

Keywords

Cite

@article{arxiv.1605.08454,
  title  = {Linear dynamical neural population models through nonlinear embeddings},
  author = {Yuanjun Gao and Evan Archer and Liam Paninski and John P. Cunningham},
  journal= {arXiv preprint arXiv:1605.08454},
  year   = {2016}
}

Comments

NIPS 2016

R2 v1 2026-06-22T14:10:41.405Z