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Joint estimation and prediction of city-wide delivery demand: A large language model empowered graph-based learning approach

Tong Nie, Junlin He, Yuewen Mei, Guoyang Qin, Guilong Li, Jian Sun, Wei Ma

2025Transportation Research Part E Logistics and Transportation Review17 citationsDOIOpen Access PDF

Abstract

The proliferation of e-commerce and urbanization has significantly intensified delivery operations in urban areas, boosting the volume and complexity of delivery demand. Data-driven predictive methods, especially those utilizing machine learning techniques, have emerged to handle these complexities in urban delivery demand management problems. One particularly pressing issue that has yet to be sufficiently addressed is the joint estimation and prediction of city-wide delivery demand, as well as the generalization of the model to new cities. To this end, we formulate this problem as a transferable graph-based spatiotemporal learning task. First, an individual-collective message-passing neural network model is formalized to capture the interaction between demand patterns of associated regions. Second, by exploiting recent advances in large language models (LLMs), we extract general geospatial knowledge encodings from the unstructured locational data using the embedding generated by LLMs. Last, to encourage the cross-city generalization of the model, we integrate the encoding into the demand predictor in a transferable way. Comprehensive empirical evaluation results on two real-world delivery datasets, including eight cities in China and the US, demonstrate that our model significantly outperforms state-of-the-art baselines in accuracy, efficiency, and transferability. PyTorch implementation is available at: https://github.com/tongnie/IMPEL . • City-wide delivery demand joint estimation and prediction problem is formulated. • Modeling region-specific and region-wide patterns in a unified graph representation. • Geospatial knowledge is extracted from the embedding of Large Language Models. • Cross-city transferability is promoted by integrating LLM-based geolocation encoding. • Evaluations using real-world urban delivery datasets containing 8 global cities.

Topics & Concepts

Computer scienceJoint (building)EstimationMachine learningArtificial intelligenceEngineeringCivil engineeringSystems engineeringTraffic Prediction and Management TechniquesHuman Mobility and Location-Based AnalysisTransportation Planning and Optimization