NeurIPS 2022 Competition: Driving SMARTS

• URL: http://arxiv.org/abs/2211.07545v1
• Date: Mon, 14 Nov 2022 17:10:53 GMT
• Title: NeurIPS 2022 Competition: Driving SMARTS
• Authors: Amir Rasouli, Randy Goebel, Matthew E. Taylor, Iuliia Kotseruba, Soheil Alizadeh, Tianpei Yang, Montgomery Alban, Florian Shkurti, Yuzheng Zhuang, Adam Scibior, Kasra Rezaee, Animesh Garg, David Meger, Jun Luo, Liam Paull, Weinan Zhang, Xinyu Wang, and Xi Chen
• Abstract summary: Driving SMARTS is a regular competition designed to tackle problems caused by the distribution shift in dynamic interaction contexts. The proposed competition supports methodologically diverse solutions, such as reinforcement learning (RL) and offline learning methods.
• Score: 60.948652154552136
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Driving SMARTS is a regular competition designed to tackle problems caused by the distribution shift in dynamic interaction contexts that are prevalent in real-world autonomous driving (AD). The proposed competition supports methodologically diverse solutions, such as reinforcement learning (RL) and offline learning methods, trained on a combination of naturalistic AD data and open-source simulation platform SMARTS. The two-track structure allows focusing on different aspects of the distribution shift. Track 1 is open to any method and will give ML researchers with different backgrounds an opportunity to solve a real-world autonomous driving challenge. Track 2 is designed for strictly offline learning methods. Therefore, direct comparisons can be made between different methods with the aim to identify new promising research directions. The proposed setup consists of 1) realistic traffic generated using real-world data and micro simulators to ensure fidelity of the scenarios, 2) framework accommodating diverse methods for solving the problem, and 3) baseline method. As such it provides a unique opportunity for the principled investigation into various aspects of autonomous vehicle deployment.

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