Time Regulation and Stage Concatenation for Optimized Probabilistic Dynamic Movement Primitives

Haocun Wu; Di Hua Zhai; Yuhan Xiong; Yuanqing Xia

doi:10.1109/TIE.2025.3647913

Time Regulation and Stage Concatenation for Optimized Probabilistic Dynamic Movement Primitives

Haocun Wu
, Di Hua Zhai^*
, Yuhan Xiong
, Yuanqing Xia

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

This article enhances the multitrajectory imitation learning algorithm through three aspects: data sources, model performance, and generalization expansion. To address the challenge of temporal misalignment in demonstrated trajectories from multiple sources, a hybrid approach integrating dynamic time warping and template matching algorithms is adopted to guarantee congruent temporal traits. Subsequently, a modified regular system is incorporated into the probabilistic dynamic movement primitives framework, enhancing trajectory fitting within specified time intervals. Additionally, a concatenation mechanism is devised to mitigate discontinuities stemming from sequential strategy implementation, enhancing the smoothness and stability of trajectories at junction points. Experimental evaluations conducted on robotic systems demonstrate the effectiveness of the proposed methods in improving motion fidelity, minimizing fitting errors, and maintaining computational efficiency. These findings contribute to advancing imitation learning strategies for complex robotic motion tasks.

Original language	English
Journal	IEEE Transactions on Industrial Electronics
DOIs	https://doi.org/10.1109/TIE.2025.3647913
Publication status	Accepted/In press - 2026
Externally published	Yes

Keywords

Dynamic time warping (DTW)
imitation learning
movement primitives
robot
trajectory planning

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10.1109/TIE.2025.3647913

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title = "Time Regulation and Stage Concatenation for Optimized Probabilistic Dynamic Movement Primitives",

abstract = "This article enhances the multitrajectory imitation learning algorithm through three aspects: data sources, model performance, and generalization expansion. To address the challenge of temporal misalignment in demonstrated trajectories from multiple sources, a hybrid approach integrating dynamic time warping and template matching algorithms is adopted to guarantee congruent temporal traits. Subsequently, a modified regular system is incorporated into the probabilistic dynamic movement primitives framework, enhancing trajectory fitting within specified time intervals. Additionally, a concatenation mechanism is devised to mitigate discontinuities stemming from sequential strategy implementation, enhancing the smoothness and stability of trajectories at junction points. Experimental evaluations conducted on robotic systems demonstrate the effectiveness of the proposed methods in improving motion fidelity, minimizing fitting errors, and maintaining computational efficiency. These findings contribute to advancing imitation learning strategies for complex robotic motion tasks.",

keywords = "Dynamic time warping (DTW), imitation learning, movement primitives, robot, trajectory planning",

author = "Haocun Wu and Zhai, \{Di Hua\} and Yuhan Xiong and Yuanqing Xia",

note = "Publisher Copyright: {\textcopyright} 1982-2012 IEEE.",

year = "2026",

doi = "10.1109/TIE.2025.3647913",

language = "English",

journal = "IEEE Transactions on Industrial Electronics",

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T1 - Time Regulation and Stage Concatenation for Optimized Probabilistic Dynamic Movement Primitives

AU - Wu, Haocun

AU - Zhai, Di Hua

AU - Xiong, Yuhan

AU - Xia, Yuanqing

PY - 2026

Y1 - 2026

N2 - This article enhances the multitrajectory imitation learning algorithm through three aspects: data sources, model performance, and generalization expansion. To address the challenge of temporal misalignment in demonstrated trajectories from multiple sources, a hybrid approach integrating dynamic time warping and template matching algorithms is adopted to guarantee congruent temporal traits. Subsequently, a modified regular system is incorporated into the probabilistic dynamic movement primitives framework, enhancing trajectory fitting within specified time intervals. Additionally, a concatenation mechanism is devised to mitigate discontinuities stemming from sequential strategy implementation, enhancing the smoothness and stability of trajectories at junction points. Experimental evaluations conducted on robotic systems demonstrate the effectiveness of the proposed methods in improving motion fidelity, minimizing fitting errors, and maintaining computational efficiency. These findings contribute to advancing imitation learning strategies for complex robotic motion tasks.

AB - This article enhances the multitrajectory imitation learning algorithm through three aspects: data sources, model performance, and generalization expansion. To address the challenge of temporal misalignment in demonstrated trajectories from multiple sources, a hybrid approach integrating dynamic time warping and template matching algorithms is adopted to guarantee congruent temporal traits. Subsequently, a modified regular system is incorporated into the probabilistic dynamic movement primitives framework, enhancing trajectory fitting within specified time intervals. Additionally, a concatenation mechanism is devised to mitigate discontinuities stemming from sequential strategy implementation, enhancing the smoothness and stability of trajectories at junction points. Experimental evaluations conducted on robotic systems demonstrate the effectiveness of the proposed methods in improving motion fidelity, minimizing fitting errors, and maintaining computational efficiency. These findings contribute to advancing imitation learning strategies for complex robotic motion tasks.

KW - Dynamic time warping (DTW)

KW - imitation learning

KW - movement primitives

KW - robot

KW - trajectory planning

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DO - 10.1109/TIE.2025.3647913

M3 - Article

AN - SCOPUS:105028169440

SN - 0278-0046

JO - IEEE Transactions on Industrial Electronics

JF - IEEE Transactions on Industrial Electronics

ER -

Time Regulation and Stage Concatenation for Optimized Probabilistic Dynamic Movement Primitives

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Keywords

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