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Auteurs principaux: Dinh, Van Nam, Phan, Van Vy, Dang, Thai Son, Phan, Van Du, Mai, The Anh, Le, Van Chuong, Ho, Sy Phuong, Duong, Dinh Tu, Ta, Hung Cuong
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2510.21751
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author Dinh, Van Nam
Phan, Van Vy
Dang, Thai Son
Phan, Van Du
Mai, The Anh
Le, Van Chuong
Ho, Sy Phuong
Duong, Dinh Tu
Ta, Hung Cuong
author_facet Dinh, Van Nam
Phan, Van Vy
Dang, Thai Son
Phan, Van Du
Mai, The Anh
Le, Van Chuong
Ho, Sy Phuong
Duong, Dinh Tu
Ta, Hung Cuong
contents This paper proposes a novel methodology for trajectory planning in autonomous vehicles (AVs), addressing the complex challenge of negotiating speed bumps within a unified Mixed-Integer Quadratic Programming (MIQP) framework. By leveraging Model Predictive Control (MPC), we develop trajectories that optimize both the traversal of speed bumps and overall passenger comfort. A key contribution of this work is the formulation of speed bump handling constraints that closely emulate human driving behavior, seamlessly integrating these with broader road navigation requirements. Through extensive simulations in varied urban driving environments, we demonstrate the efficacy of our approach, highlighting its ability to ensure smooth speed transitions over speed bumps while maintaining computational efficiency suitable for real-time deployment. The method's capability to handle both static road features and dynamic constraints, alongside expert human driving, represents a significant step forward in trajectory planning for urban
format Preprint
id arxiv_https___arxiv_org_abs_2510_21751
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Real-time Mixed-Integer Quadratic Programming for Driving Behavior-Inspired Speed Bump Optimal Trajectory Planning
Dinh, Van Nam
Phan, Van Vy
Dang, Thai Son
Phan, Van Du
Mai, The Anh
Le, Van Chuong
Ho, Sy Phuong
Duong, Dinh Tu
Ta, Hung Cuong
Robotics
This paper proposes a novel methodology for trajectory planning in autonomous vehicles (AVs), addressing the complex challenge of negotiating speed bumps within a unified Mixed-Integer Quadratic Programming (MIQP) framework. By leveraging Model Predictive Control (MPC), we develop trajectories that optimize both the traversal of speed bumps and overall passenger comfort. A key contribution of this work is the formulation of speed bump handling constraints that closely emulate human driving behavior, seamlessly integrating these with broader road navigation requirements. Through extensive simulations in varied urban driving environments, we demonstrate the efficacy of our approach, highlighting its ability to ensure smooth speed transitions over speed bumps while maintaining computational efficiency suitable for real-time deployment. The method's capability to handle both static road features and dynamic constraints, alongside expert human driving, represents a significant step forward in trajectory planning for urban
title Real-time Mixed-Integer Quadratic Programming for Driving Behavior-Inspired Speed Bump Optimal Trajectory Planning
topic Robotics
url https://arxiv.org/abs/2510.21751