Learning Biological Dynamics From Spatio-Temporal Data by Gaussian Processes

被引:0
作者
Lifeng Han
Changhan He
Huy Dinh
John Fricks
Yang Kuang
机构
[1] University of Colorado,Department of Mathematics
[2] University of California,Department of Mathematics
[3] New York University,Courant Institute of Mathematical
[4] Arizona State University,School of Mathematical and Statistical Sciences
来源
Bulletin of Mathematical Biology | 2022年 / 84卷
关键词
Spatio-temporal data; Gaussian processes; Forecasting;
D O I
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中图分类号
学科分类号
摘要
Model discovery methods offer a promising way to understand biology from data. We propose a method to learn biological dynamics from spatio-temporal data by Gaussian processes. This approach is essentially “equation free” and hence avoids model derivation, which is often difficult due to high complexity of biological processes. By exploiting the local nature of biological processes, dynamics can be learned with data sparse in time. When the length scales (hyperparameters) of the squared exponential covariance function are tuned, they reveal key insights of the underlying process. The squared exponential covariance function also simplifies propagation of uncertainty in multi-step forecasting. After evaluating the performance of the method on synthetic data, we demonstrate a case study on real image data of E. coli colony.
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