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Auteurs principaux: Lee, Daegyu, Nam, Hyunwoo, Ryu, Chanhoe, Nah, Sungwon, Moon, Seongwoo, Shim, D. Hyunchul
Format: Preprint
Publié: 2023
Sujets:
Accès en ligne:https://arxiv.org/abs/2308.07173
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author Lee, Daegyu
Nam, Hyunwoo
Ryu, Chanhoe
Nah, Sungwon
Moon, Seongwoo
Shim, D. Hyunchul
author_facet Lee, Daegyu
Nam, Hyunwoo
Ryu, Chanhoe
Nah, Sungwon
Moon, Seongwoo
Shim, D. Hyunchul
contents This paper introduces an approach that enhances the state estimator for high-speed autonomous race cars, addressing challenges from unreliable measurements, localization failures, and computing resource management. The proposed robust localization system utilizes a Bayesian-based probabilistic approach to evaluate multimodal measurements, ensuring the use of credible data for accurate and reliable localization, even in harsh racing conditions. To tackle potential localization failures, we present a resilient navigation system which enables the race car to continue track-following by leveraging direct perception information in planning and execution, ensuring continuous performance despite localization disruptions. In addition, efficient computing is critical to avoid overload and system failure. Hence, we optimize computing resources using an efficient LiDAR-based state estimation method. Leveraging CUDA programming and GPU acceleration, we perform nearest points search and covariance computation efficiently, overcoming CPU bottlenecks. Simulation and real-world tests validate the system's performance and resilience. The proposed approach successfully recovers from failures, effectively preventing accidents and ensuring safety of the car.
format Preprint
id arxiv_https___arxiv_org_abs_2308_07173
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Enhancing State Estimator for Autonomous Racing : Leveraging Multi-modal System and Managing Computing Resources
Lee, Daegyu
Nam, Hyunwoo
Ryu, Chanhoe
Nah, Sungwon
Moon, Seongwoo
Shim, D. Hyunchul
Robotics
This paper introduces an approach that enhances the state estimator for high-speed autonomous race cars, addressing challenges from unreliable measurements, localization failures, and computing resource management. The proposed robust localization system utilizes a Bayesian-based probabilistic approach to evaluate multimodal measurements, ensuring the use of credible data for accurate and reliable localization, even in harsh racing conditions. To tackle potential localization failures, we present a resilient navigation system which enables the race car to continue track-following by leveraging direct perception information in planning and execution, ensuring continuous performance despite localization disruptions. In addition, efficient computing is critical to avoid overload and system failure. Hence, we optimize computing resources using an efficient LiDAR-based state estimation method. Leveraging CUDA programming and GPU acceleration, we perform nearest points search and covariance computation efficiently, overcoming CPU bottlenecks. Simulation and real-world tests validate the system's performance and resilience. The proposed approach successfully recovers from failures, effectively preventing accidents and ensuring safety of the car.
title Enhancing State Estimator for Autonomous Racing : Leveraging Multi-modal System and Managing Computing Resources
topic Robotics
url https://arxiv.org/abs/2308.07173