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Autori principali: Long, Keke, Sheng, Zihao, Shi, Haotian, Li, Xiaopeng, Chen, Sikai, Ahn, Sue
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2309.15284
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author Long, Keke
Sheng, Zihao
Shi, Haotian
Li, Xiaopeng
Chen, Sikai
Ahn, Sue
author_facet Long, Keke
Sheng, Zihao
Shi, Haotian
Li, Xiaopeng
Chen, Sikai
Ahn, Sue
contents In vehicle trajectory prediction, physics models and data-driven models are two predominant methodologies. However, each approach presents its own set of challenges: physics models fall short in predictability, while data-driven models lack interpretability. Addressing these identified shortcomings, this paper proposes a novel framework, the Physics-Enhanced Residual Learning (PERL) model. PERL integrates the strengths of physics-based and data-driven methods for traffic state prediction. PERL contains a physics model and a residual learning model. Its prediction is the sum of the physics model result and a predicted residual as a correction to it. It preserves the interpretability inherent to physics-based models and has reduced data requirements compared to data-driven methods. Experiments were conducted using a real-world vehicle trajectory dataset. We proposed a PERL model, with the Intelligent Driver Model (IDM) as its physics car-following model and Long Short-Term Memory (LSTM) as its residual learning model. We compare this PERL model with the physics car-following model, data-driven model, and other physics-informed neural network (PINN) models. The result reveals that PERL achieves better prediction with a small dataset, compared to the physics model, data-driven model, and PINN model. Second, the PERL model showed faster convergence during training, offering comparable performance with fewer training samples than the data-driven model and PINN model. Sensitivity analysis also proves comparable performance of PERL using another residual learning model and a physics car-following model.
format Preprint
id arxiv_https___arxiv_org_abs_2309_15284
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A Physics Enhanced Residual Learning (PERL) Framework for Vehicle Trajectory Prediction
Long, Keke
Sheng, Zihao
Shi, Haotian
Li, Xiaopeng
Chen, Sikai
Ahn, Sue
Machine Learning
In vehicle trajectory prediction, physics models and data-driven models are two predominant methodologies. However, each approach presents its own set of challenges: physics models fall short in predictability, while data-driven models lack interpretability. Addressing these identified shortcomings, this paper proposes a novel framework, the Physics-Enhanced Residual Learning (PERL) model. PERL integrates the strengths of physics-based and data-driven methods for traffic state prediction. PERL contains a physics model and a residual learning model. Its prediction is the sum of the physics model result and a predicted residual as a correction to it. It preserves the interpretability inherent to physics-based models and has reduced data requirements compared to data-driven methods. Experiments were conducted using a real-world vehicle trajectory dataset. We proposed a PERL model, with the Intelligent Driver Model (IDM) as its physics car-following model and Long Short-Term Memory (LSTM) as its residual learning model. We compare this PERL model with the physics car-following model, data-driven model, and other physics-informed neural network (PINN) models. The result reveals that PERL achieves better prediction with a small dataset, compared to the physics model, data-driven model, and PINN model. Second, the PERL model showed faster convergence during training, offering comparable performance with fewer training samples than the data-driven model and PINN model. Sensitivity analysis also proves comparable performance of PERL using another residual learning model and a physics car-following model.
title A Physics Enhanced Residual Learning (PERL) Framework for Vehicle Trajectory Prediction
topic Machine Learning
url https://arxiv.org/abs/2309.15284