Saved in:
Bibliographic Details
Main Authors: Liao, Xishun, Ma, Haoxuan, Liu, Yifan, Wei, Yuxiang, He, Brian Yueshuai, Stanford, Chris, Ma, Jiaqi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.08871
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909686023847936
author Liao, Xishun
Ma, Haoxuan
Liu, Yifan
Wei, Yuxiang
He, Brian Yueshuai
Stanford, Chris
Ma, Jiaqi
author_facet Liao, Xishun
Ma, Haoxuan
Liu, Yifan
Wei, Yuxiang
He, Brian Yueshuai
Stanford, Chris
Ma, Jiaqi
contents Travel demand models are critical tools for planning, policy, and mobility system design. Traditional activity-based models (ABMs), although grounded in behavioral theories, often rely on simplified rules and assumptions, and are costly to develop and difficult to adapt across different regions. This paper presents a learning-based travel demand modeling framework that synthesizes household-coordinated daily activity patterns based on a household's socio-demographic profiles. The whole framework integrates population synthesis, coordinated activity generation, location assignment, and large-scale microscopic traffic simulation into a unified system. It is fully generative, data-driven, scalable, and transferable to other regions. A full-pipeline implementation is conducted in Los Angeles with a 10 million population. Comprehensive validation shows that the model closely replicates real-world mobility patterns and matches the performance of legacy ABMs with significantly reduced modeling cost and greater scalability. With respect to the SCAG ABM benchmark, the origin-destination matrix achieves a cosine similarity of 0.97, and the daily vehicle miles traveled (VMT) in the network yields a 0.006 Jensen-Shannon Divergence (JSD) and a 9.8% mean absolute percentage error (MAPE). When compared to real-world observations from Caltrans PeMS, the evaluation on corridor-level traffic speed and volume reaches a 0.001 JSD and a 6.11% MAPE.
format Preprint
id arxiv_https___arxiv_org_abs_2507_08871
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Next-Generation Travel Demand Modeling with a Generative Framework for Household Activity Coordination
Liao, Xishun
Ma, Haoxuan
Liu, Yifan
Wei, Yuxiang
He, Brian Yueshuai
Stanford, Chris
Ma, Jiaqi
Machine Learning
Artificial Intelligence
Travel demand models are critical tools for planning, policy, and mobility system design. Traditional activity-based models (ABMs), although grounded in behavioral theories, often rely on simplified rules and assumptions, and are costly to develop and difficult to adapt across different regions. This paper presents a learning-based travel demand modeling framework that synthesizes household-coordinated daily activity patterns based on a household's socio-demographic profiles. The whole framework integrates population synthesis, coordinated activity generation, location assignment, and large-scale microscopic traffic simulation into a unified system. It is fully generative, data-driven, scalable, and transferable to other regions. A full-pipeline implementation is conducted in Los Angeles with a 10 million population. Comprehensive validation shows that the model closely replicates real-world mobility patterns and matches the performance of legacy ABMs with significantly reduced modeling cost and greater scalability. With respect to the SCAG ABM benchmark, the origin-destination matrix achieves a cosine similarity of 0.97, and the daily vehicle miles traveled (VMT) in the network yields a 0.006 Jensen-Shannon Divergence (JSD) and a 9.8% mean absolute percentage error (MAPE). When compared to real-world observations from Caltrans PeMS, the evaluation on corridor-level traffic speed and volume reaches a 0.001 JSD and a 6.11% MAPE.
title Next-Generation Travel Demand Modeling with a Generative Framework for Household Activity Coordination
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2507.08871