Tracking disease outbreaks from sparse data with Bayesian inference
- URL: http://arxiv.org/abs/2009.05863v1
- Date: Sat, 12 Sep 2020 20:37:33 GMT
- Title: Tracking disease outbreaks from sparse data with Bayesian inference
- Authors: Bryan Wilder, Michael J. Mina, Milind Tambe
- Abstract summary: The COVID-19 pandemic provides new motivation for estimating the empirical rate of transmission during an outbreak.
Standard methods struggle to accommodate the partial observability and sparse data common at finer scales.
We propose a Bayesian framework which accommodates partial observability in a principled manner.
- Score: 55.82986443159948
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The COVID-19 pandemic provides new motivation for a classic problem in
epidemiology: estimating the empirical rate of transmission during an outbreak
(formally, the time-varying reproduction number) from case counts. While
standard methods exist, they work best at coarse-grained national or state
scales with abundant data, and struggle to accommodate the partial
observability and sparse data common at finer scales (e.g., individual schools
or towns). For example, case counts may be sparse when only a small fraction of
infections are caught by a testing program. Or, whether an infected individual
tests positive may depend on the kind of test and the point in time when they
are tested. We propose a Bayesian framework which accommodates partial
observability in a principled manner. Our model places a Gaussian process prior
over the unknown reproduction number at each time step and models observations
sampled from the distribution of a specific testing program. For example, our
framework can accommodate a variety of kinds of tests (viral RNA, antibody,
antigen, etc.) and sampling schemes (e.g., longitudinal or cross-sectional
screening). Inference in this framework is complicated by the presence of tens
or hundreds of thousands of discrete latent variables. To address this
challenge, we propose an efficient stochastic variational inference method
which relies on a novel gradient estimator for the variational objective.
Experimental results for an example motivated by COVID-19 show that our method
produces an accurate and well-calibrated posterior, while standard methods for
estimating the reproduction number can fail badly.
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