A robot system control method includes a first step through a fifth step. Particularly in the second step, a second transformation matrix that represents the positional relation between a first slave robot and a second slave robot is generated and stored in a master robot. In the fourth step, based on a second command obtained using a first transformation matrix and the second transformation matrix, the master robot instructs the second slave robot to operate. In the fifth step, the first slave robot and the second slave robot perform a cooperative operation with the master robot. Thus, in the state where a working robot that can perform TCP matching with only part of the other robots is set to a master robot, all of the robots can perform a cooperative operation.

A method of coordinating automated systems, the method includes providing a first automated system that is programmed with a set of predetermined operating instructions that correspond with automated system processing requirements, monitoring an operational status of the first automated system with a second automated system, automatically generating a second system action, with the second automated system, that is complimentary to a first system action of the first automated system, where the first system action corresponds to the set of predetermined operating instructions and the second system action depends on the operational status of the first automated system, and performing the second system action with the second automated system so that the second automated system cooperates with the first automated system to perform a predetermined operation.

A master-slave manipulator according to the present invention includes a remote operation device, serving as a master, that provides operation information corresponding to multiple degrees of freedom, a slave manipulator having a plurality of joints corresponding to multiple degrees of freedom and including a redundant joints among the joints, and a controller that controls the operation of the joints in accordance with the operation information, in which, when it is determined that a distal end of the slave manipulator operates, the controller determines, among the redundant joints, drive ratios α of a joint disposed on a base end side and a joint disposed on a distal end side within a range of 0<α<1, respectively, and drives the joints.

A master-slave manipulator according to the present invention includes a remote operation device, serving as a master, that provides operation information corresponding to multiple degrees of freedom, a slave manipulator having a plurality of joints corresponding to multiple degrees of freedom and including a redundant joints among the joints, and a controller that controls the operation of the joints in accordance with the operation information, in which, when it is determined that a distal end of the slave manipulator operates, the controller determines, among the redundant joints, drive ratios of a joint disposed on a base end side and a joint disposed on a distal end side within a range of 0<<1, respectively, and drives the joints.

A method of coordinating automated systems, the method includes providing a first automated system that is programmed with a set of predetermined operating instructions that correspond with automated system processing requirements, monitoring an operational status of the first automated system with a second automated system, automatically generating a second system action, with the second automated system, that is complementary to a first system action of the first automated system, where the first system action corresponds to the set of predetermined operating instructions and the second system action depends on the operational status of the first automated system, and performing the second system action with the second automated system so that the second automated system cooperates with the first automated system to perform a predetermined operation.