FAULT-TOLERANT OPERATION OF KINEMATICALLY REDUNDANT MANIPULATORS FOR LOCKED JOINT FAILURES

This paper studies the degree to which the kinematic redundancy of a m anipulator may be utilized for failure tolerance. A redundant manipula tor is considered to be fault tolerant with respect to a given task if it is guaranteed to be capable of performing the task after any one o f its joints has failed and is locked in place. A method is developed for determining the necessary constraints which insure the failure tol erance of a kinematically redundant manipulator with respect to a give n critical task. This method is based on estimating the bounding boxes enclosing the self-motion manifolds for a given set of critical task points. The intersection of these bounding boxes provides a set of art ificial joint limits that may guarantee the reachability of the task p oints after a joint failure. An algorithm for dealing with the special case of 2-D self-motion surfaces is presented. These techniques are i llustrated on a PUMA 560 that is used for a 3-D Cartesian positioning task.