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Main Authors: Kim, Taekyung, Majd, Keyvan, Okamoto, Hideki, Hoxha, Bardh, Panagou, Dimitra, Fainekos, Georgios
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.06261
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author Kim, Taekyung
Majd, Keyvan
Okamoto, Hideki
Hoxha, Bardh
Panagou, Dimitra
Fainekos, Georgios
author_facet Kim, Taekyung
Majd, Keyvan
Okamoto, Hideki
Hoxha, Bardh
Panagou, Dimitra
Fainekos, Georgios
contents Generating safe, kinodynamically feasible, and optimal trajectories for complex robotic systems is a central challenge in robotics. This paper presents Safe Model Predictive Diffusion (Safe MPD), a training-free diffusion planner that unifies a model-based diffusion framework with a safety shield to generate trajectories that are both kinodynamically feasible and safe by construction. By enforcing feasibility and safety on all samples during the denoising process, our method avoids the common pitfalls of post-processing corrections, such as computational intractability and loss of feasibility. We validate our approach on challenging non-convex planning problems, including kinematic and acceleration-controlled tractor-trailer systems. The results show that it substantially outperforms existing safety strategies in success rate and safety, while achieving sub-second computation times.
format Preprint
id arxiv_https___arxiv_org_abs_2512_06261
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Safe Model Predictive Diffusion with Shielding
Kim, Taekyung
Majd, Keyvan
Okamoto, Hideki
Hoxha, Bardh
Panagou, Dimitra
Fainekos, Georgios
Robotics
Generating safe, kinodynamically feasible, and optimal trajectories for complex robotic systems is a central challenge in robotics. This paper presents Safe Model Predictive Diffusion (Safe MPD), a training-free diffusion planner that unifies a model-based diffusion framework with a safety shield to generate trajectories that are both kinodynamically feasible and safe by construction. By enforcing feasibility and safety on all samples during the denoising process, our method avoids the common pitfalls of post-processing corrections, such as computational intractability and loss of feasibility. We validate our approach on challenging non-convex planning problems, including kinematic and acceleration-controlled tractor-trailer systems. The results show that it substantially outperforms existing safety strategies in success rate and safety, while achieving sub-second computation times.
title Safe Model Predictive Diffusion with Shielding
topic Robotics
url https://arxiv.org/abs/2512.06261