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Main Authors: Zhou, Xingyuan, Paik, Peter, Atashzar, S. Farokh
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.04994
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author Zhou, Xingyuan
Paik, Peter
Atashzar, S. Farokh
author_facet Zhou, Xingyuan
Paik, Peter
Atashzar, S. Farokh
contents Maintaining system stability and accurate position tracking is imperative in networked robotic systems, particularly for haptics-enabled human-robot interaction. Recent literature has integrated human biomechanics into the stabilizers implemented for teleoperation, enhancing force preservation while guaranteeing convergence and safety. However, position desynchronization due to imperfect communication and non-passive behaviors remains a challenge. This paper proposes a two-port biomechanics-aware passivity-based synchronizer and stabilizer, referred to as TBPS2. This stabilizer optimizes position synchronization by leveraging human biomechanics while reducing the stabilizer's conservatism in its activation. We provide the mathematical design synthesis of the stabilizer and the proof of stability. We also conducted a series of grid simulations and systematic experiments, comparing their performance with that of state-of-the-art solutions under varying time delays and environmental conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2511_04994
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Encoding Biomechanical Energy Margin into Passivity-based Synchronization for Networked Telerobotic Systems
Zhou, Xingyuan
Paik, Peter
Atashzar, S. Farokh
Robotics
Maintaining system stability and accurate position tracking is imperative in networked robotic systems, particularly for haptics-enabled human-robot interaction. Recent literature has integrated human biomechanics into the stabilizers implemented for teleoperation, enhancing force preservation while guaranteeing convergence and safety. However, position desynchronization due to imperfect communication and non-passive behaviors remains a challenge. This paper proposes a two-port biomechanics-aware passivity-based synchronizer and stabilizer, referred to as TBPS2. This stabilizer optimizes position synchronization by leveraging human biomechanics while reducing the stabilizer's conservatism in its activation. We provide the mathematical design synthesis of the stabilizer and the proof of stability. We also conducted a series of grid simulations and systematic experiments, comparing their performance with that of state-of-the-art solutions under varying time delays and environmental conditions.
title Encoding Biomechanical Energy Margin into Passivity-based Synchronization for Networked Telerobotic Systems
topic Robotics
url https://arxiv.org/abs/2511.04994