A computer-assisted medical system includes a manipulator arm and a controller. The controller includes a computer processor. The controller is configured to servo at least one joint associated with at least one manipulator arm segment of the manipulator arm, the servoing including executing a servo loop. Executing the servo loop includes obtaining an actual state of the manipulator arm, computing a difference between a commanded state and the actual state, where the commanded state is used for the servoing the at least one joint, and determining whether the difference exceeds an error threshold. Based on determining that the difference does exceed the error threshold, the commanded state is updated using an offset to reduce the difference, and. Based on determining that the difference does not exceed the error threshold, the commanded state is not updated. The controller is further configured to apply the commanded state to control the actual state.

A control apparatus includes a processor that is configured to control a robot, and receive an object coordinate system set for an object not an end effector and not moving or rotating with the end effector. The processor is configured to execute a first control mode in which the end effector is moved and rotated according to a detected force while the force is detected by a force detector, and execute a second control mode in which, when a relative angle between a predetermined first axis of a moving coordinate system moving and rotating with the end effector and a predetermined second axis of the object coordinate system is smaller than an angle threshold value, the end effector is rotated to make magnitude of the relative angle closer to zero.

A robot system includes a robot, a teach pendant having an operator interface, and a robot controller with a computer and associated hardware and software containing a virtual representation of the robot and the environment. The system employs a method for avoiding collisions including moving a manipulator arm along an actual path in an environment containing objects constituting collision geometry. Operator input is entered into the teach pendant, whereby the operator is able to directly control motion of the robot along the actual path. A recent history of the motion of the robot is recorded, and a predicted path of the robot is developed based on the input entered into the teach pendant and the recent history of the motion of the robot. Real-time collision checking between the predicted path and the collision geometry is performed while the operator manually controls the robot using the teach pendant.

An industrial robot system including a dual arm robot having two arms independently movable in relation to each other, and a hand-held control device for controlling the robot and provided with a visual display unit for displaying information about the arms. The control device is provided with a measuring device for measuring the orientation of the control device, and the control device is configured to display information about one of the arms in a first area on the display unit and to display information about the other arm in a second area on the display unit, and to change the positions of the first and second areas in dependence on the orientation of the control device in relation to the robot so that the positions of the first and second area on the display unit reflects the orientation of the control device in relation to the positions of the arms.

A control apparatus includes a processor that is configured to control a robot, and receive an object coordinate system set for an object not an end effector and not moving or rotating with the end effector. The processor is configured to execute a first control mode in which the end effector is moved and rotated according to a detected force while the force is detected by a force detector, and execute a second control mode in which, when a relative angle between a predetermined first axis of a moving coordinate system moving and rotating with the end effector and a predetermined second axis of the object coordinate system is smaller than an angle threshold value, the end effector is rotated to make magnitude of the relative angle closer to zero.

An industrial robot system including a dual arm robot having two arms independently movable in relation to each other, and a hand-held control device for controlling the robot and provided with a visual display unit for displaying information about the arms. The control device is provided with a measuring device for measuring the orientation of the control device, and the control device is configured to display information about one of the arms in a first area on the display unit and to display information about the other arm in a second area on the display unit, and to change the positions of the first and second areas in dependence on the orientation of the control device in relation to the robot so that the positions of the first and second area on the display unit reflects the orientation of the control device in relation to the positions of the arms.

A portable apparatus for controlling a robot and a method therefor. The portable apparatus includes: an orientation sensor adapted for measuring orientation of the portable apparatus; an HMI device adapted for detecting two-dimensional manual motion relative to the HMI device; and a processing unit adapted for receiving a first signal representing the measured orientation of the portable apparatus and a second signal representing the detected two-dimensional manual motion relative to the HMI device and controlling a part of the robot to move in a direction in consideration of the measured orientation of the portable apparatus and the detected two-dimensional manual motion relative to the HMI device. By having the portable apparatus and the method therefor as explained herein, the two-dimensional manual movement on touch panel is integrated with orientation of the portable apparatus and an integration of these is mapped by the robot, which makes it possible to define a path in three dimensional space for jogging/teaching robot's movements in three dimension.

A robot system includes a robot, a teach pendant having an operator interface, and a robot controller with a computer and associated hardware and software containing a virtual representation of the robot and the environment. The system employs a method for avoiding collisions including moving a manipulator arm along an actual path in an environment containing objects constituting collision geometry. Operator input is entered into the teach pendant, whereby the operator is able to directly control motion of the robot along the actual path. A recent history of the motion of the robot is recorded, and a predicted path of the robot is developed based on the input entered into the teach pendant and the recent history of the motion of the robot. Real-time collision checking between the predicted path and the collision geometry is performed while the operator manually controls the robot using the teach pendant.

A computer-assisted medical system includes a manipulator arm and a controller. The controller includes a computer processor. The controller is configured to servo at least one joint associated with at least one manipulator arm segment of the manipulator arm, the servoing including executing a servo loop. Executing the servo loop includes obtaining an actual state of the manipulator arm, computing a difference between a commanded state and the actual state, where the commanded state is used for the servoing the at least one joint, and determining whether the difference exceeds an error threshold. Based on determining that the difference does exceed the error threshold, the commanded state is updated using an offset to reduce the difference, and. Based on determining that the difference does not exceed the error threshold, the commanded state is not updated. The controller is further configured to apply the commanded state to control the actual state.

A method and apparatus for controlling an industrial robot relative to an intuitive motion coordinate system. The current 3D position of a touch-screen teach pendant relative to the robot is sensed, and an operator-centric frame of reference is developed relative to the robot-centric frame of reference. A simulacra of the robot is generated, oriented so as to correspond with an operator view of the robot from the current position of the controller, and displayed on the pendant. A motion-control construction, generated and displayed on the pendant, is adapted to receive jog commands from the operator indicative of a respective incremental movement of the simulacra in the operator-centric frame of reference. Each jog command is transformed from the operator-centric frame of reference to the robot-centric frame of reference, and the robot moved in accordance with the transformed jog command. Movement of the pendant relative to the robot is sensed and, in response, the displayed simulacra is reoriented to correspond to the new position of the pendant relative to the robot as viewed by the operator.