Racing With ROS 2 A Navigation System for an Autonomous Formula Student Race Car

• URL: http://arxiv.org/abs/2311.14276v1
• Date: Fri, 24 Nov 2023 04:40:26 GMT
• Title: Racing With ROS 2 A Navigation System for an Autonomous Formula Student Race Car
• Authors: Alastair Bradford, Grant van Breda, Tobias Fischer
• Abstract summary: This paper presents an open-source solution using the Robot Operating System 2, specifically its open-source navigation stack. We compare off-the-shelf navigation libraries that this stack comprises of against traditional custom-made programs developed by QUT Motorsport. Our contributions include quantitative and qualitative comparisons of these packages against traditional navigation solutions, aiming to lower the entry barrier for autonomous racing.
• Score: 3.509667406229871
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: The advent of autonomous vehicle technologies has significantly impacted various sectors, including motorsport, where Formula Student and Formula: Society of Automotive Engineers introduced autonomous racing classes. These offer new challenges to aspiring engineers, including the team at QUT Motorsport, but also raise the entry barrier due to the complexity of high-speed navigation and control. This paper presents an open-source solution using the Robot Operating System 2, specifically its open-source navigation stack, to address these challenges in autonomous Formula Student race cars. We compare off-the-shelf navigation libraries that this stack comprises of against traditional custom-made programs developed by QUT Motorsport to evaluate their applicability in autonomous racing scenarios and integrate them onto an autonomous race car. Our contributions include quantitative and qualitative comparisons of these packages against traditional navigation solutions, aiming to lower the entry barrier for autonomous racing. This paper also serves as a comprehensive tutorial for teams participating in similar racing disciplines and other autonomous mobile robot applications.

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