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Auteurs principaux: Hussien, Mohamed Manzour, Melo, Angie Nataly, Ballardini, Augusto Luis, Maldonado, Carlota Salinas, Izquierdo, Rubén, Sotelo, Miguel Ángel
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2405.00449
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author Hussien, Mohamed Manzour
Melo, Angie Nataly
Ballardini, Augusto Luis
Maldonado, Carlota Salinas
Izquierdo, Rubén
Sotelo, Miguel Ángel
author_facet Hussien, Mohamed Manzour
Melo, Angie Nataly
Ballardini, Augusto Luis
Maldonado, Carlota Salinas
Izquierdo, Rubén
Sotelo, Miguel Ángel
contents Prediction of road users' behaviors in the context of autonomous driving has gained considerable attention by the scientific community in the last years. Most works focus on predicting behaviors based on kinematic information alone, a simplification of the reality since road users are humans, and as such they are highly influenced by their surrounding context. In addition, a large plethora of research works rely on powerful Deep Learning techniques, which exhibit high performance metrics in prediction tasks but may lack the ability to fully understand and exploit the contextual semantic information contained in the road scene, not to mention their inability to provide explainable predictions that can be understood by humans. In this work, we propose an explainable road users' behavior prediction system that integrates the reasoning abilities of Knowledge Graphs (KG) and the expressiveness capabilities of Large Language Models (LLM) by using Retrieval Augmented Generation (RAG) techniques. For that purpose, Knowledge Graph Embeddings (KGE) and Bayesian inference are combined to allow the deployment of a fully inductive reasoning system that enables the issuing of predictions that rely on legacy information contained in the graph as well as on current evidence gathered in real time by onboard sensors. Two use cases have been implemented following the proposed approach: 1) Prediction of pedestrians' crossing actions; 2) Prediction of lane change maneuvers. In both cases, the performance attained surpasses the current state of the art in terms of anticipation and F1-score, showing a promising avenue for future research in this field.
format Preprint
id arxiv_https___arxiv_org_abs_2405_00449
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle RAG-based Explainable Prediction of Road Users Behaviors for Automated Driving using Knowledge Graphs and Large Language Models
Hussien, Mohamed Manzour
Melo, Angie Nataly
Ballardini, Augusto Luis
Maldonado, Carlota Salinas
Izquierdo, Rubén
Sotelo, Miguel Ángel
Machine Learning
Artificial Intelligence
Computation and Language
Information Retrieval
Neural and Evolutionary Computing
Prediction of road users' behaviors in the context of autonomous driving has gained considerable attention by the scientific community in the last years. Most works focus on predicting behaviors based on kinematic information alone, a simplification of the reality since road users are humans, and as such they are highly influenced by their surrounding context. In addition, a large plethora of research works rely on powerful Deep Learning techniques, which exhibit high performance metrics in prediction tasks but may lack the ability to fully understand and exploit the contextual semantic information contained in the road scene, not to mention their inability to provide explainable predictions that can be understood by humans. In this work, we propose an explainable road users' behavior prediction system that integrates the reasoning abilities of Knowledge Graphs (KG) and the expressiveness capabilities of Large Language Models (LLM) by using Retrieval Augmented Generation (RAG) techniques. For that purpose, Knowledge Graph Embeddings (KGE) and Bayesian inference are combined to allow the deployment of a fully inductive reasoning system that enables the issuing of predictions that rely on legacy information contained in the graph as well as on current evidence gathered in real time by onboard sensors. Two use cases have been implemented following the proposed approach: 1) Prediction of pedestrians' crossing actions; 2) Prediction of lane change maneuvers. In both cases, the performance attained surpasses the current state of the art in terms of anticipation and F1-score, showing a promising avenue for future research in this field.
title RAG-based Explainable Prediction of Road Users Behaviors for Automated Driving using Knowledge Graphs and Large Language Models
topic Machine Learning
Artificial Intelligence
Computation and Language
Information Retrieval
Neural and Evolutionary Computing
url https://arxiv.org/abs/2405.00449