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Autores principales: Shehadeh, Samir, Kutsch, Lukas, Dengler, Nils, Pan, Sicong, Bennewitz, Maren
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2603.07126
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author Shehadeh, Samir
Kutsch, Lukas
Dengler, Nils
Pan, Sicong
Bennewitz, Maren
author_facet Shehadeh, Samir
Kutsch, Lukas
Dengler, Nils
Pan, Sicong
Bennewitz, Maren
contents Trajectory optimization is a central component of fast and efficient autonomous racing. However practical optimization pipelines remain highly sensitive to initialization and may converge slowly or to suboptimal local solutions when seeded with heuristic trajectories such as the centerline or minimum-curvature paths. To address this limitation, we leverage expert driving behavior as a initialization prior and propose a learning-informed initialization strategy based on real-world Formula~1 telemetry. To this end, we first construct a multi-track Formula~1 trajectory dataset by reconstructing and aligning noisy GPS telemetry to a standardized reference-line representation across 17 tracks. Building on this, we present a neural network that predicts an expert-like raceline offset directly from local track geometry, without explicitly modeling vehicle dynamics or forces. The predicted raceline is then used as an informed seed for a minimum-time optimal control solver. Experiments on all 17 tracks demonstrate that the learned initialization accelerates solver convergence and significantly reduces runtime compared to traditional geometric baselines, while preserving the final optimized lap time.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07126
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Efficient Trajectory Optimization for Autonomous Racing via Formula-1 Data-Driven Initialization
Shehadeh, Samir
Kutsch, Lukas
Dengler, Nils
Pan, Sicong
Bennewitz, Maren
Robotics
Trajectory optimization is a central component of fast and efficient autonomous racing. However practical optimization pipelines remain highly sensitive to initialization and may converge slowly or to suboptimal local solutions when seeded with heuristic trajectories such as the centerline or minimum-curvature paths. To address this limitation, we leverage expert driving behavior as a initialization prior and propose a learning-informed initialization strategy based on real-world Formula~1 telemetry. To this end, we first construct a multi-track Formula~1 trajectory dataset by reconstructing and aligning noisy GPS telemetry to a standardized reference-line representation across 17 tracks. Building on this, we present a neural network that predicts an expert-like raceline offset directly from local track geometry, without explicitly modeling vehicle dynamics or forces. The predicted raceline is then used as an informed seed for a minimum-time optimal control solver. Experiments on all 17 tracks demonstrate that the learned initialization accelerates solver convergence and significantly reduces runtime compared to traditional geometric baselines, while preserving the final optimized lap time.
title Efficient Trajectory Optimization for Autonomous Racing via Formula-1 Data-Driven Initialization
topic Robotics
url https://arxiv.org/abs/2603.07126