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Auteurs principaux: Kliniewski, Mikolaj, Morris, Jesse, Wang, Yiduo, Manchester, Ian R., Ila, Viorela
Format: Preprint
Publié: 2026
Sujets:
Accès en ligne:https://arxiv.org/abs/2605.12897
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author Kliniewski, Mikolaj
Morris, Jesse
Wang, Yiduo
Manchester, Ian R.
Ila, Viorela
author_facet Kliniewski, Mikolaj
Morris, Jesse
Wang, Yiduo
Manchester, Ian R.
Ila, Viorela
contents DynoJEPP is a factor-graph-based framework that jointly formulates and simultaneously optimizes estimation, prediction, and planning in dynamic environments. In conventional factor-graph-based approaches that jointly formulate estimation, prediction, and planning, information from prediction and planning feeds back into state estimation, yielding corrupted estimates, undesired behaviors, and unsafe plans. To address this, DynoJEPP introduces a novel directed factor that enforces directional information flow within the factor graph, preventing prediction and planning from corrupting state estimation. We evaluate the impact of directed factors on inter-module interactions during navigation in both static and dynamic environments. Our results demonstrate that these factors are critical for safe operation, as without them, the robot collides in the majority of experiments. Building on this, we further introduce Cooperative DynoJEPP, which enables the ego robot to incorporate cooperative object behavior into its prediction and trajectory planning.
format Preprint
id arxiv_https___arxiv_org_abs_2605_12897
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle DynoJEPP: Joint Estimation, Prediction and Planning in Dynamic Environments
Kliniewski, Mikolaj
Morris, Jesse
Wang, Yiduo
Manchester, Ian R.
Ila, Viorela
Robotics
DynoJEPP is a factor-graph-based framework that jointly formulates and simultaneously optimizes estimation, prediction, and planning in dynamic environments. In conventional factor-graph-based approaches that jointly formulate estimation, prediction, and planning, information from prediction and planning feeds back into state estimation, yielding corrupted estimates, undesired behaviors, and unsafe plans. To address this, DynoJEPP introduces a novel directed factor that enforces directional information flow within the factor graph, preventing prediction and planning from corrupting state estimation. We evaluate the impact of directed factors on inter-module interactions during navigation in both static and dynamic environments. Our results demonstrate that these factors are critical for safe operation, as without them, the robot collides in the majority of experiments. Building on this, we further introduce Cooperative DynoJEPP, which enables the ego robot to incorporate cooperative object behavior into its prediction and trajectory planning.
title DynoJEPP: Joint Estimation, Prediction and Planning in Dynamic Environments
topic Robotics
url https://arxiv.org/abs/2605.12897