Related papers: Unifying Epidemic Models with Mixtures

Unifying Epidemic Models with Mixtures

URL: http://arxiv.org/abs/2201.04960v1
Date: Fri, 7 Jan 2022 19:42:05 GMT
Title: Unifying Epidemic Models with Mixtures
Authors: Arnab Sarker, Ali Jadbabaie, Devavrat Shah
Abstract summary: The COVID-19 pandemic has emphasized the need for a robust understanding of epidemic models. Here, we introduce a simple mixture-based model which bridges the two approaches. Although the model is non-mechanistic, we show that it arises as the natural outcome of a process based on a networked SIR framework.
Score: 28.771032745045428
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The COVID-19 pandemic has emphasized the need for a robust understanding of epidemic models. Current models of epidemics are classified as either mechanistic or non-mechanistic: mechanistic models make explicit assumptions on the dynamics of disease, whereas non-mechanistic models make assumptions on the form of observed time series. Here, we introduce a simple mixture-based model which bridges the two approaches while retaining benefits of both. The model represents time series of cases and fatalities as a mixture of Gaussian curves, providing a flexible function class to learn from data compared to traditional mechanistic models. Although the model is non-mechanistic, we show that it arises as the natural outcome of a stochastic process based on a networked SIR framework. This allows learned parameters to take on a more meaningful interpretation compared to similar non-mechanistic models, and we validate the interpretations using auxiliary mobility data collected during the COVID-19 pandemic. We provide a simple learning algorithm to identify model parameters and establish theoretical results which show the model can be efficiently learned from data. Empirically, we find the model to have low prediction error. The model is available live at covidpredictions.mit.edu. Ultimately, this allows us to systematically understand the impacts of interventions on COVID-19, which is critical in developing data-driven solutions to controlling epidemics.

Related papers

Modeling, Inference, and Prediction in Mobility-Based Compartmental Models for Epidemiology [5.079807662054658]
We introduce individual mobility as a key factor in disease transmission and control. We characterize disease dynamics using mobility distribution functions for each compartment. We infer mobility distributions from the time series of the infected population.
arXiv Detail & Related papers (2024-06-17T18:13:57Z)
Metapopulation Graph Neural Networks: Deep Metapopulation Epidemic Modeling with Human Mobility [14.587916407752719]
We propose a novel hybrid model called MepoGNN for multi-step multi-region epidemic forecasting. Our model can not only predict the number of confirmed cases but also explicitly learn the epidemiological parameters.
arXiv Detail & Related papers (2023-06-26T17:09:43Z)
Seq2Seq Surrogates of Epidemic Models to Facilitate Bayesian Inference [0.6524460254566905]
We show that deep sequence-to-sequence (seq2seq) models can serve as accurate surrogates for complex epidemic models. Once trained, our surrogate can predict scenarios a several thousand times faster than the original model.
arXiv Detail & Related papers (2022-09-20T11:23:19Z)
On the Generalization and Adaption Performance of Causal Models [99.64022680811281]
Differentiable causal discovery has proposed to factorize the data generating process into a set of modules. We study the generalization and adaption performance of such modular neural causal models. Our analysis shows that the modular neural causal models outperform other models on both zero and few-shot adaptation in low data regimes.
arXiv Detail & Related papers (2022-06-09T17:12:32Z)
EINNs: Epidemiologically-Informed Neural Networks [75.34199997857341]
We introduce a new class of physics-informed neural networks-EINN-crafted for epidemic forecasting. We investigate how to leverage both the theoretical flexibility provided by mechanistic models as well as the data-driven expressability afforded by AI models.
arXiv Detail & Related papers (2022-02-21T18:59:03Z)
Modelling COVID-19 Pandemic Dynamics Using Transparent, Interpretable, Parsimonious and Simulatable (TIPS) Machine Learning Models: A Case Study from Systems Thinking and System Identification Perspectives [1.4061680807550718]
The present study proposes using systems engineering and system identification approach to build transparent, interpretable, parsimonious and simulatable (TIPS) dynamic machine learning models. TIPS models are developed based on the well-known NARMAX (Nonlinear AutoRegressive Moving Average with eXogenous inputs) model, which can help better understand the COVID-19 pandemic dynamics.
arXiv Detail & Related papers (2021-11-01T08:42:37Z)
Beyond Trivial Counterfactual Explanations with Diverse Valuable Explanations [64.85696493596821]
In computer vision applications, generative counterfactual methods indicate how to perturb a model's input to change its prediction. We propose a counterfactual method that learns a perturbation in a disentangled latent space that is constrained using a diversity-enforcing loss. Our model improves the success rate of producing high-quality valuable explanations when compared to previous state-of-the-art methods.
arXiv Detail & Related papers (2021-03-18T12:57:34Z)
An Optimal Control Approach to Learning in SIDARTHE Epidemic model [67.22168759751541]
We propose a general approach for learning time-variant parameters of dynamic compartmental models from epidemic data. We forecast the epidemic evolution in Italy and France.
arXiv Detail & Related papers (2020-10-28T10:58:59Z)
Generative Temporal Difference Learning for Infinite-Horizon Prediction [101.59882753763888]
We introduce the $gamma$-model, a predictive model of environment dynamics with an infinite probabilistic horizon. We discuss how its training reflects an inescapable tradeoff between training-time and testing-time compounding errors.
arXiv Detail & Related papers (2020-10-27T17:54:12Z)
A General Framework for Survival Analysis and Multi-State Modelling [70.31153478610229]
We use neural ordinary differential equations as a flexible and general method for estimating multi-state survival models. We show that our model exhibits state-of-the-art performance on popular survival data sets and demonstrate its efficacy in a multi-state setting.
arXiv Detail & Related papers (2020-06-08T19:24:54Z)

This list is automatically generated from the titles and abstracts of the papers in this site.