Author
Listed:
- Aritath Siraphatwongkorn
- Thanin Methiyothin
- Kittisak Onuean
- Krisana Chinnasarn
- Athita Onuean
- Insung Ahn
- Suwanna Rasmequan
Abstract
The COVID-19 pandemic significantly disrupted global mobility patterns, with widespread population movement playing a key role in the transmission of the virus. In such a situation, Google introduced the Community Mobility Reports, which use anonymized and aggregated location data to monitor changes in movement across various location categories. These mobility trends provide important insights that help inform timely public health interventions and support data-driven decisions during and after the pandemic. This study aims to forecast human mobility trends in Thailand during the COVID-19 pandemic using data from Google’s reports. Three forecasting models were applied: Facebook Prophet, ARIMA, and Feature Engineered XGBoost. The Granger Causality Test was used to examine the relationship between mobility patterns and COVID-19 case numbers across different phases of lockdown. The results indicated that Feature Engineered XGBoost demonstrated the highest overall accuracy in forecasting mobility trends across all six location categories. In conclusion, this study demonstrates the effectiveness of machine learning models in forecasting mobility movement across various location types while public health restrictions have been implemented. This underscores the importance of understanding mobility patterns as a key factor in disease transmission. The insights gained from this analysis can help formulate strategic and targeted mobility management policies and public health responses for future outbreaks, ultimately helping to contain the spread of disease more effectively.
Suggested Citation
Aritath Siraphatwongkorn & Thanin Methiyothin & Kittisak Onuean & Krisana Chinnasarn & Athita Onuean & Insung Ahn & Suwanna Rasmequan, 2026.
"Forecasting Thailand’s mobility trends using Feature Engineered XGBoost for pandemic crisis movement management,"
PLOS ONE, Public Library of Science, vol. 21(3), pages 1-19, March.
Handle:
RePEc:plo:pone00:0345547
DOI: 10.1371/journal.pone.0345547
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