Nonlinear demixed component analysis for neural population data as a low-rank kernel regression problem
Abstract
Many studies of neural activity in behaving animals aim to discover interpretable low-dimensional structure in large-scale neural population recordings. One approach to this problem is demixed principal component analysis (dPCA), a supervised linear dimensionality reduction technique to find components that depend on particular experimental parameters. Here, I introduce kernel dPCA (kdPCA) as a nonlinear extension of dPCA by applying kernel least-squares regression to the demixing problem. I consider simulated examples of neural populations with low-dimensional activity to compare the components recovered from dPCA and kdPCA. These simulations demonstrate that neurally relevant nonlinearities, such as stimulus-dependent gain and rotation, interfere with linear demixing of neural activity into components that represent to individual experimental parameters. However, kdPCA can still recover interpretable components in these examples. Finally, I demonstrate kdPCA using two examples of neural populations recorded during perceptual decision-making tasks.
Cite
@article{arxiv.1812.08238,
title = {Nonlinear demixed component analysis for neural population data as a low-rank kernel regression problem},
author = {Kenneth W. Latimer},
journal= {arXiv preprint arXiv:1812.08238},
year = {2019}
}
Comments
Accepted for publication in Neurons, Behavior, Data Analysis, and Theory