Cross-Coordinated Control: An Experimentally Verified Technique for the Hybrid Twist and Wrench Control of a Voltage-Controlled Industrial Robot

Abstract

Applications for modern industrial robots have generally been limited to low-precision, non-contact tasks, because in practice, it is generally not possible to adequately engineer even a manufacturing environment to a sufficiently high degree of precision such that position control, alone, is adequate. Cross-coordinated control serves to extend that range by providing a practical, experimentally verified solution to the problem of simultaneously controlling both the motion of and the constraint forces acting upon a robot end-effector, which is in contact with a rigid environment. This work provides a semi-empirical method for the hybrid control of a voltage-controlled industrial robot, such that the geometric constraints are explicitly accounted for. The kinestatic analysis was based on a model of the environment using Ball's reciprocal screws to characterize the nature of the constraints. The resulting theoretical development, combined with a laboratory implementation which employed an instrumented, anisotropic, mechanically complaint wrench sensor, resulted in a system that is kinematically, dynamically and kinestatically stable. Consequently, this approach constitutes a general solution to the problem of performing the commonly encountered industrial tasks which, if automated, would require contact between the robot's end-effector and a rigid environment. This method is well suited for implementation as an augmentation, thus permitting the continued use of most existing motion control hardware and software.

Document Details

Document Type

Technical Report

Publication Date

Dec 30, 1988

Accession Number

ADA203406

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