Geometric Deep Learning for Autonomous Driving: Unlocking the Power of Graph Neural Networks With CommonRoad-Geometric

• URL: http://arxiv.org/abs/2302.01259v2
• Date: Mon, 24 Apr 2023 08:30:35 GMT
• Title: Geometric Deep Learning for Autonomous Driving: Unlocking the Power of Graph Neural Networks With CommonRoad-Geometric
• Authors: Eivind Meyer, Maurice Brenner, Bowen Zhang, Max Schickert, Bilal Musani, and Matthias Althoff
• Abstract summary: Heterogeneous graphs offer powerful data representations for traffic, given their ability to model the complex interaction effects. With the advent of graph neural networks (GNNs) as the accompanying deep learning framework, the graph structure can be efficiently leveraged for various machine learning applications. Our proposed Python framework offers an easy-to-use and fully customizable data processing pipeline to extract standardized graph datasets from traffic scenarios.
• Score: 6.638385593789309
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Heterogeneous graphs offer powerful data representations for traffic, given their ability to model the complex interaction effects among a varying number of traffic participants and the underlying road infrastructure. With the recent advent of graph neural networks (GNNs) as the accompanying deep learning framework, the graph structure can be efficiently leveraged for various machine learning applications such as trajectory prediction. As a first of its kind, our proposed Python framework offers an easy-to-use and fully customizable data processing pipeline to extract standardized graph datasets from traffic scenarios. Providing a platform for GNN-based autonomous driving research, it improves comparability between approaches and allows researchers to focus on model implementation instead of dataset curation.

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