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Autores principales: Chen, Yanjia, Li, Xiangfei, Zhao, Huan, Hong, Yiyuan, Xia, Guanxiao, Zhang, Jiexin, Ding, Han
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2605.04809
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author Chen, Yanjia
Li, Xiangfei
Zhao, Huan
Hong, Yiyuan
Xia, Guanxiao
Zhang, Jiexin
Ding, Han
author_facet Chen, Yanjia
Li, Xiangfei
Zhao, Huan
Hong, Yiyuan
Xia, Guanxiao
Zhang, Jiexin
Ding, Han
contents This article proposes a general optimization framework for solving hand-eye calibration problem. Unlike traditional methods, an iterative algorithm based on Lie algebra that achieves approximately global optimal solutions is developed. During the optimization process, the method strictly preserves the structural constraints of the calibration parameters and enables synchronized updates between calibration parameters. Recognizing that data used in real-word hand-eye calibration often contain uncertainty, especially in over-loading and large workspace industrial robot scenarios, which can significantly degrade accuracy, and accurately modeling such uncertainty is inherently difficult, this article avoids explicit uncertainty modeling. Instead, an uncertainty metric to evaluate the relative uncertainty between data sources is introduced and used to dynamically refine the iterative process. To further enhance convergence efficiency, an effective initial solution generation method that improves overall stability and accuracy is designed. Numerical simulations and real-world experiments validate the effectiveness of the proposed approach, and in synthetic datasets, the proposed approach improves the estimation accuracy by at least 67\% under high-uncertainty conditions compared with the existing methods.
format Preprint
id arxiv_https___arxiv_org_abs_2605_04809
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Optimal Uncertainty-Aware Calibration for the AX=YB Problem
Chen, Yanjia
Li, Xiangfei
Zhao, Huan
Hong, Yiyuan
Xia, Guanxiao
Zhang, Jiexin
Ding, Han
Robotics
This article proposes a general optimization framework for solving hand-eye calibration problem. Unlike traditional methods, an iterative algorithm based on Lie algebra that achieves approximately global optimal solutions is developed. During the optimization process, the method strictly preserves the structural constraints of the calibration parameters and enables synchronized updates between calibration parameters. Recognizing that data used in real-word hand-eye calibration often contain uncertainty, especially in over-loading and large workspace industrial robot scenarios, which can significantly degrade accuracy, and accurately modeling such uncertainty is inherently difficult, this article avoids explicit uncertainty modeling. Instead, an uncertainty metric to evaluate the relative uncertainty between data sources is introduced and used to dynamically refine the iterative process. To further enhance convergence efficiency, an effective initial solution generation method that improves overall stability and accuracy is designed. Numerical simulations and real-world experiments validate the effectiveness of the proposed approach, and in synthetic datasets, the proposed approach improves the estimation accuracy by at least 67\% under high-uncertainty conditions compared with the existing methods.
title Optimal Uncertainty-Aware Calibration for the AX=YB Problem
topic Robotics
url https://arxiv.org/abs/2605.04809