Marginalizable Density Models
- URL: http://arxiv.org/abs/2106.04741v1
- Date: Tue, 8 Jun 2021 23:54:48 GMT
- Title: Marginalizable Density Models
- Authors: Dar Gilboa, Ari Pakman, Thibault Vatter
- Abstract summary: We present a novel deep network architecture which provides closed form expressions for the probabilities, marginals and conditionals of any subset of the variables.
The model also allows for parallelized sampling with only a logarithmic dependence of the time complexity on the number of variables.
- Score: 14.50261153230204
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Probability density models based on deep networks have achieved remarkable
success in modeling complex high-dimensional datasets. However, unlike kernel
density estimators, modern neural models do not yield marginals or conditionals
in closed form, as these quantities require the evaluation of seldom tractable
integrals. In this work, we present the Marginalizable Density Model
Approximator (MDMA), a novel deep network architecture which provides closed
form expressions for the probabilities, marginals and conditionals of any
subset of the variables. The MDMA learns deep scalar representations for each
individual variable and combines them via learned hierarchical tensor
decompositions into a tractable yet expressive CDF, from which marginals and
conditional densities are easily obtained. We illustrate the advantage of exact
marginalizability in several tasks that are out of reach of previous deep
network-based density estimation models, such as estimating mutual information
between arbitrary subsets of variables, inferring causality by testing for
conditional independence, and inference with missing data without the need for
data imputation, outperforming state-of-the-art models on these tasks. The
model also allows for parallelized sampling with only a logarithmic dependence
of the time complexity on the number of variables.
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