Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm

Research article (International Journal of Precision Engineering and Manufacturing, 2020) · cited 24× · AI/ML

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Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm

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Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm is a scholarly article^[1].

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Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm's instance of is recorded as scholarly article^[2].

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Authored by 4

Lixin Yang, Meng Xiao, Shouyan Chen, Tie Zhang

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Lixin Yang, Meng Xiao, Shouyan Chen, Tie Zhang

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[2] ↑ Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm — instance of (P31): scholarly article. wikidata.org.

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[1] ↑ Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm is an instance of scholarly article (scholarly article) [P31, primary]. Wikidata. wikidata.org.

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@misc{4ortxyz_robot-grinding-system-trajectory-compensation-based-on-co-kriging-method-and-constant-force-control-based-on-adaptive-it_2026, author = {{4ort.xyz Knowledge Graph}}, title = {{Robot Grinding System Trajectory Compensation Based on Co-Kriging Method and Constant-Force Control Based on Adaptive Iterative Algorithm}}, year = {2026}, url = {https://4ort.xyz/entity/robot-grinding-system-trajectory-compensation-based-on-co-kriging-method-and-constant-force-control-based-on-adaptive-it}, note = {Accessed: 2026-05-24}}

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