Modeling Virus Transmission Risks in Commuting with Emerging Mobility Services: A Case Study of COVID-19

TL;DR

This study develops a probabilistic model to estimate COVID-19 infection risks during various commuting modes, incorporating data-driven trip trajectories and uncertainty quantification, with a case study in the MIT community.

Contribution

The paper introduces a novel probabilistic framework for quantifying infection risks in commuting, considering multiple travel modes and uncertainty, which was not previously addressed comprehensively.

Findings

Most individuals have near-zero infection probability.

Maximum infection risk during commute is about 0.8%.

Longer trips and transit during peak hours increase infection risk.

Abstract

Commuting is an important part of daily life. With the gradual recovery from COVID-19 and more people returning to work from the office, the transmission of COVID-19 during commuting becomes a concern. Recent emerging mobility services (such as ride-hailing and bike-sharing) further deteriorate the infection risks due to shared vehicles or spaces during travel. Hence, it is important to quantify the infection risks in commuting. This paper proposes a probabilistic framework to estimate the risk of infection during an individual's commute considering different travel modes, including public transit, ride-share, bike, and walking. The objective is to evaluate the probability of infection as well as the estimation errors (i.e., uncertainty quantification) given the origin-destination (OD), departure time, and travel mode. We first define a general trip planning function to generate trip trajectories and probabilities of choosing different paths according to the OD, departure time, and travel mode. Then, we consider two channels of infections: 1) infection by close contact and 2) infection by touching surfaces. The infection risks are calculated on a trip segment basis. Different sources of data (such as smart card data, travel surveys, and population data) are used to estimate the potential interactions between the individual and the infectious environment. The model is implemented in the MIT community as a case study. We evaluate the commute infection risks for employees and students. Results show that most of the individuals have an infection probability close to zero. The maximum infection probability is around 0.8%, implying that the probability of getting infected during the commuting process is low. Individuals with larger travel distances, traveling in transit, and traveling during peak hours are more likely to get infected.