@misc{901a3321e5064fe58aebe61aad3f1a72,
title = "Teaching Freight Mode Choice Models New Tricks Using Interpretable Machine Learning Methods",
abstract = "Understanding and forecasting the intricate freight mode choice behavior under various industry, policy, and technology contexts is essential in freight planning and policymaking. Numerous models have been developed in prior studies to provide insights into freight mode selection, the majority of which use discrete choice models such as multinomial logit (MNL) models. However, logit models often rely on linear specifications of independent variables, despite potential nonlinear relationships in the data. Moreover, there often lacks a heuristic and efficient approach to identify such complex relationships to define the logit model specifications. To fill this gap, we developed an MNL model for freight mode choice using the insights from state-of-the- art machine learning (ML) models. ML models can capture the nonlinear nature of the complex decision-making process, and recent advances in 'explainable AI' have greatly improved their interpretability. The interpretable ML methods help enhance the performance of MNL models and advance knowledge of freight mode choice. Specifically, the influential factors and their relationship with individual modes are identified using SHapley Additive exPlanations (SHAP) to improve the MNL's performance. The workflow is demonstrated in a case study of Austin, Texas, and the SHAP results reveal multiple nonlinear relationships predicted by ML models. Incorporating those relationships into MNL model specifications improves the interpretability and accuracy of the MNL model compared to a conventional MNL model. Findings from this study can be used to guide freight planning and inform policymakers and practitioners on how key factors affect freight decision-making.",
keywords = "freight mode choice, interpretable machine learning, multinomial logit model, SHapley Additive exPlanations (SHAP)",
author = "Xiaodan Xu and Hung-Chia Yang and Kyungsoo Jeong and William Bui and Srinath Ravulaparthy and Haitam Laarabi and Zachary Needell and Spurlock, {C. Anna}",
year = "2024",
language = "American English",
series = "Presented at the Transportation Research Board (TRB) 103rd Annual Meeting, 7-11 January 2024, Washington, D.C.",
publisher = "National Renewable Energy Laboratory (NREL)",
address = "United States",
type = "Other",
}