Data-Driven Fine-Grained Epidemic Modeling via Graph Neural Networks Público
Qin, Muran (Spring 2023)
Abstract
Fine-grained epidemic modeling is crucial for controlling the spread of diseases such as COVID-19. While many graph-based deep learning frameworks for pandemic forecasting achieved powerful performance, seldom use other relevant data sources besides the disease case surveillance data. This paper presents a framework for using the publicly available Social Connectedness Index (SCI) and Social Vulnerability Index (SVI) to enhance the baseline model. These datasets provide valuable insights into the social interactions and socioeconomic status of each location, both potentially significant factors for epidemic spreading dynamics. Experiments were conducted on the U.S. county-level granularity over three datasets with different time frames and geographical scales. We found that SCI and SVI both improve the performance over the original model on some prediction horizons while having comparative performance on other prediction horizons, demonstrating the promising effectiveness of using social- related data sources on pandemic forecasting. Finally, we suggested potential future research directions on data-driven pandemic forecasting.
Table of Contents
1 Introduction 1
2 Related Work 4
2.1 Graph Neural Networks .................... 4
2.2 Multivariate Time Series Forecasting .................... 5
2.3 Epidemic Modeling .................... 6
3 Problem Definition 7
4 Comparative Study 8
4.1 Background .................... 8
4.1.1 StemGNN .................... 8
4.1.2 Cola-GNN .................... 9
4.1.3 STAN .................... 9
4.1.4 CausalGNN .................... 10
4.2 Qualitative Comparison .................... 10
4.3 Quantitative Comparison .................... 12
4.3.1 Dataset .................... 13
4.3.2 Setup .................... 13
4.3.3 Evaluation Metric .................... 14
4.3.4 Results .................... 15
4.4 Analysis .................... 16
5 Enhancement Study 17
5.1 Dataset .................... 17
5.1.1 Geographical Adjacency .................... 17
5.1.2 Social Connectedness Index .................... 17
5.1.3 Social Vulnerability Index .................... 18
5.2 Cola-GNN: A Closer Look .................... 19
5.2.1 Directed Spatial Influence Learning .................... 20
5.2.2 Multi-Scale Dilated Convolution .................... 21
5.2.3 Graph Message Passing -- Propagation .................... 22
5.2.4 Output Layer -- Prediction .................... 22
5.2.5 Optimization .................... 23
5.3 Proposed Method .................... 23
5.4 Experiment .................... 25
5.5 Analysis .................... 26
6 Conclusion 30
Appendix A Dataset 32
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