Global Optimal Travel Planning for Massive Travel Queries in Road Networks

Travel planning plays an increasingly important role in our society. The travel plans, which consist of the paths each vehicle is suggested to follow and its corresponding departure time, influence the traffic conditions naturally. However, existing travel planning algorithms cannot consider the pla...

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Bibliographic Details
Published in:IEEE transactions on knowledge and data engineering 2024-12, Vol.36 (12), p.8377-8394
Main Authors: Xu, Yehong, Li, Lei, Zhang, Mengxuan, Xu, Zizhuo, Zhou, Xiaofang
Format: Article
Language:English
Subjects:
Iterative methods
Massive-Scale route planning
Optimization
Planning
Roads
Routing
shortest path query
Timing
Traffic congestion
traffic-aware road network
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Summary:Travel planning plays an increasingly important role in our society. The travel plans, which consist of the paths each vehicle is suggested to follow and its corresponding departure time, influence the traffic conditions naturally. However, existing travel planning algorithms cannot consider the planning results and their influences simultaneously, so traffic congestion could be created when many vehicles are directed to adopt similar travel plans. In this paper, we propose the Global Optimal Travel Planning (GOTP) problem that aims to minimize traffic congestion by continuously evaluating traffic conditions for a set of planning tasks. Achieving this global optimization goal is non-trivial because travel planning and traffic evaluation are time-consuming and interdependent. To break this dependency, we first propose a GOTP paradigm that interleaves travel planning and traffic evaluation for queries, where the planning consists of departure time planning and travel path planning. To implement the paradigm, we propose the serial model that optimizes travel plans one by one, followed by the batch model that improves processing efficiency, and the iterative model that further optimizes planning quality. Extensive experiments on large real-world networks with synthetic and real workloads validate the effectiveness and efficiency of our methods.
ISSN:1041-4347
1558-2191
DOI:10.1109/TKDE.2024.3439409