A Branch-and-Price Algorithm for the Electric Autonomous Dial-A-Ride Problem

TL;DR

This paper introduces a highly-efficient Branch-and-Price algorithm with a novel labeling approach for solving the Electric Autonomous Dial-A-Ride Problem, optimizing routes with electric vehicles, ride time, and recharging constraints.

Contribution

It presents a new labeling algorithm and graph abstraction techniques to efficiently solve the E-ADARP, handling excess ride time and partial recharging in electric autonomous vehicle routing.

Findings

Achieved optimal solutions for 71 out of 84 instances.

Solved 50 instances optimally at the root node without branching.

Generated 42 new best solutions and improved bounds on large-scale instances.

Abstract

The Electric Autonomous Dial-A-Ride Problem (E-ADARP) consists in scheduling a fleet of electric autonomous vehicles to provide ride-sharing services for customers that specify their origins and destinations. The E-ADARP differs from the classical DARP in two aspects: (i) a weighted-sum objective that minimizes both total travel time and total excess user ride time; (ii) the employment of electric autonomous vehicles and a partial recharging policy. This paper presents a highly-efficient labeling algorithm, which is integrated into Branch-and-Price (B&P) algorithms to solve the E-ADARP. To handle (i), we introduce a fragment-based representation of paths. A novel approach is invoked to abstract fragments to arcs while ensuring excess-user-ride-time optimality. We then construct a new graph that preserves all feasible routes of the original graph by enumerating all feasible fragments, abstracting them to arcs, and connecting them with each other, depots, and recharging stations in a feasible way. On the new graph, partial recharging (ii) is tackled exactly by tailored Resource Extension Functions (REFs). We apply strong dominance rules and constant-time feasibility checks to compute the shortest paths efficiently. These methods construct the first labeling algorithm that can deal with minimizing (excess) user ride time. In the computational experiments, the B&P algorithm achieves optimality in 71 out of 84 instances. Remarkably, among these instances, 50 were solved optimally at the root node without branching. We identify 26 new best solutions, improve 30 previously reported lower bounds, and provide 17 new lower bounds for large-scale instances with up to 8 vehicles and 96 requests. In total 42 new best solutions are generated on previously solved and unsolved instances.