Optimal Parking Planning for Shared Autonomous Vehicles

TL;DR

This paper introduces an analytical model for optimizing parking station density and vehicle fleet size in shared autonomous vehicle systems, considering different urban zones, with a case study in Seoul.

Contribution

It develops a novel analytical parking planning model for SAVs, including solutions for single and multi-zone scenarios, aiding urban transportation planning.

Findings

Optimal parking station densities are much lower than current levels.

The model provides explicit relationships between planning decisions and environment factors.

Sensitivity analysis offers insights into cost impacts on parking and fleet sizes.

Abstract

Parking is a crucial element of the driving experience in urban transportation systems. Especially in the coming era of Shared Autonomous Vehicles (SAVs), parking operations in urban transportation networks will inevitably change. Parking stations will serve as storage places for unused vehicles and depots that control the level-of-service of SAVs. This study presents an Analytical Parking Planning Model (APPM) for the SAV environment to provide broader insights into parking planning decisions. Two specific planning scenarios are considered for the APPM: (i) Single-zone APPM (S-APPM), which considers the target area as a single homogeneous zone, and (ii) Two-zone APPM (T-APPM), which considers the target area as two different zones, such as city center and suburban area. S-APPM offers a closed-form solution to find the optimal density of parking stations and parking spaces and the optimal number of SAV fleets, which is beneficial for understanding the explicit relationship between planning decisions and the given environments, including demand density and cost factors. In addition, to incorporate different macroscopic characteristics across two zones, T-APPM accounts for inter- and intra-zonal passenger trips and the relocation of vehicles. We conduct a case study to demonstrate the proposed method with the actual data collected in Seoul Metropolitan Area, South Korea. Sensitivity analyses with respect to cost factors are performed to provide decision-makers with further insights. Also, we find that the optimal densities of parking stations and spaces in the target area are much lower than the current situations.