Reformulation and Solution Algorithms for Absolute and Percentile Robust Shortest Path Problems

To model a driver's route choice behavior under inherent traffic system stochasticity and to further provide better route guidance with travel-time reliability guarantees, this paper examines two models to evaluate the travel-time robustness: absolute robust shortest path (ARSP) and α -percentile robust shortest path (PRSP) problems. A Lagrangian relaxation approach and a scenario-based representation scheme are integrated to reformulate the minimax and percentile criteria under day-dependent random travel times. The complex problem structure is decomposed into several subproblems that can be efficiently solved as standard shortest path problems or univariate linear programming problems. Large-scale numerical experiments with real-world data are provided to demonstrate the efficiency of the proposed algorithms.

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