Confidence-Aware Object Capture for a Manipulator Subject to Floating-Base Disturbances

Ruoyu Xu; Zixing Jiang; Beibei Liu; Yuquan Wang; Huihuan Qian

doi:10.1109/TRO.2024.3463476

Confidence-Aware Object Capture for a Manipulator Subject to Floating-Base Disturbances

Ruoyu Xu, Zixing Jiang, Beibei Liu, Yuquan Wang, Huihuan Qian^*

^*Corresponding author for this work

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

Abstract

Capturing stationary aerial objects on unmanned surface vehicles (USVs) is challenging due to quasiperiodic and fast floating-base motions caused by wave-induced disturbances. It is hard to maintain high motion prediction accuracy due to the stochastic nature of these disturbances, and perform object capture through real-time tracking due to the limited active torque. We introduce confidence analysis in predictive capture. To address the inaccuracy predictions, we calculate a real-time confidence tube to evaluate the prediction quality. To overcome tracking difficulties, we plan a trajectory to capture the object at a future moment while maximizing the confidence of the capture position on the predicted trajectory. All calculations are completed within 0.2 s to ensure a timely response. We validate our approach through experiments, where we simulate disturbances by executing real USV motions using a servo platform. The results demonstrate that our method achieves an 80% success rate.

Original language	English
Pages (from-to)	4396-4413
Number of pages	18
Journal	IEEE Transactions on Robotics
Volume	40
Early online date	1 Jan 2024
DOIs	https://doi.org/10.1109/TRO.2024.3463476
Publication status	Published - 2024

Keywords

Confidence analysis
floating-base manipulator
motion planning
object capture

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10.1109/TRO.2024.3463476

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title = "Confidence-Aware Object Capture for a Manipulator Subject to Floating-Base Disturbances",

abstract = "Capturing stationary aerial objects on unmanned surface vehicles (USVs) is challenging due to quasiperiodic and fast floating-base motions caused by wave-induced disturbances. It is hard to maintain high motion prediction accuracy due to the stochastic nature of these disturbances, and perform object capture through real-time tracking due to the limited active torque. We introduce confidence analysis in predictive capture. To address the inaccuracy predictions, we calculate a real-time confidence tube to evaluate the prediction quality. To overcome tracking difficulties, we plan a trajectory to capture the object at a future moment while maximizing the confidence of the capture position on the predicted trajectory. All calculations are completed within 0.2 s to ensure a timely response. We validate our approach through experiments, where we simulate disturbances by executing real USV motions using a servo platform. The results demonstrate that our method achieves an 80% success rate.",

keywords = "Confidence analysis, floating-base manipulator, motion planning, object capture",

author = "Ruoyu Xu and Zixing Jiang and Beibei Liu and Yuquan Wang and Huihuan Qian",

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doi = "10.1109/TRO.2024.3463476",

language = "English",

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T1 - Confidence-Aware Object Capture for a Manipulator Subject to Floating-Base Disturbances

AU - Xu, Ruoyu

AU - Jiang, Zixing

AU - Liu, Beibei

AU - Wang, Yuquan

AU - Qian, Huihuan

PY - 2024

Y1 - 2024

N2 - Capturing stationary aerial objects on unmanned surface vehicles (USVs) is challenging due to quasiperiodic and fast floating-base motions caused by wave-induced disturbances. It is hard to maintain high motion prediction accuracy due to the stochastic nature of these disturbances, and perform object capture through real-time tracking due to the limited active torque. We introduce confidence analysis in predictive capture. To address the inaccuracy predictions, we calculate a real-time confidence tube to evaluate the prediction quality. To overcome tracking difficulties, we plan a trajectory to capture the object at a future moment while maximizing the confidence of the capture position on the predicted trajectory. All calculations are completed within 0.2 s to ensure a timely response. We validate our approach through experiments, where we simulate disturbances by executing real USV motions using a servo platform. The results demonstrate that our method achieves an 80% success rate.

AB - Capturing stationary aerial objects on unmanned surface vehicles (USVs) is challenging due to quasiperiodic and fast floating-base motions caused by wave-induced disturbances. It is hard to maintain high motion prediction accuracy due to the stochastic nature of these disturbances, and perform object capture through real-time tracking due to the limited active torque. We introduce confidence analysis in predictive capture. To address the inaccuracy predictions, we calculate a real-time confidence tube to evaluate the prediction quality. To overcome tracking difficulties, we plan a trajectory to capture the object at a future moment while maximizing the confidence of the capture position on the predicted trajectory. All calculations are completed within 0.2 s to ensure a timely response. We validate our approach through experiments, where we simulate disturbances by executing real USV motions using a servo platform. The results demonstrate that our method achieves an 80% success rate.

KW - Confidence analysis

KW - floating-base manipulator

KW - motion planning

KW - object capture

U2 - 10.1109/TRO.2024.3463476

DO - 10.1109/TRO.2024.3463476

M3 - Article

SN - 1552-3098

VL - 40

SP - 4396

EP - 4413

JO - IEEE Transactions on Robotics

JF - IEEE Transactions on Robotics

ER -

Confidence-Aware Object Capture for a Manipulator Subject to Floating-Base Disturbances

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Keywords

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