LEAD: Towards Learning-Based Equity-Aware Decarbonization in Ridesharing Platforms

Ridesharing platforms such as Uber, Lyft, and DiDi have grown in popularity due to their on-demand availability, ease of use, and commute cost reductions, among other benefits. However, not all ridesharing promises have panned out. Recent studies demonstrate that the expected drop in traffic congest...

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Published in:arXiv.org 2024-08
Main Authors: Sahebdel, Mahsa, Zeynali, Ali, Bashir, Noman, Shenoy, Prashant, Hajiesmaili, Mohammad
Format: Article
Language:English
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Algorithms
Car pools
Emissions control
Greenhouse gases
Platforms
Traffic congestion
Vehicle emissions
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Zeynali, Ali
Bashir, Noman
Shenoy, Prashant
Hajiesmaili, Mohammad
description Ridesharing platforms such as Uber, Lyft, and DiDi have grown in popularity due to their on-demand availability, ease of use, and commute cost reductions, among other benefits. However, not all ridesharing promises have panned out. Recent studies demonstrate that the expected drop in traffic congestion and reduction in greenhouse gas (GHG) emissions have not materialized. This is primarily due to the substantial distances traveled by the ridesharing vehicles without passengers between rides, known as deadhead miles. Recent work has focused on reducing the impact of deadhead miles while considering additional metrics such as rider waiting time, GHG emissions from deadhead miles, or driver earnings. Unfortunately, prior studies consider these environmental and equity-based metrics individually despite them being interrelated. In this paper, we propose a Learning-based Equity-Aware Decarabonization approach, LEAD, for ridesharing platforms. LEAD targets minimizing emissions while ensuring that the driver's utility, defined as the difference between the trip distance and the deadhead miles, is fairly distributed. LEAD uses reinforcement learning to match riders to drivers based on the expected future utility of drivers and the expected carbon emissions of the platform without increasing the rider waiting times. Extensive experiments based on a real-world ride-sharing dataset show that LEAD improves fairness by 2\(\times\) when compared to emission-aware ride-assignment and reduces emissions by 70% while ensuring fairness within 66% of the fair baseline. It also reduces the rider wait time, by at least 40%, compared to various baselines. Additionally, LEAD corrects the imbalance in previous emission-aware ride assignment algorithms that overassigned rides to low-emission vehicles.
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subjects Algorithms
Car pools
Emissions control
Greenhouse gases
Platforms
Traffic congestion
Vehicle emissions
title LEAD: Towards Learning-Based Equity-Aware Decarbonization in Ridesharing Platforms
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