Abstract: A computer-assisted teleoperated system includes a pre-load assembly in an instrument manipulator that is under the control of a controller. The controller can automatically cause the preload assembly to engage and disengage a preload. A surgical apparatus includes an instrument manipulator assembly and a sterile adapter assembly. The sterile adapter assembly is mounted in the distal face of the instrument manipulator assembly. When the preload assembly configures the instrument manipulator assembly to apply a preload force on the sterile adapter assembly, the sterile adapter assembly is removable from the distal face of the instrument manipulator. The sterile adapter assembly includes a mechanical sterile adapter assembly removal lockout and a mechanical instrument removal lockout.

Abstract: A computer-assisted medical system includes a robotic manipulator arm configured to support an instrument. The instrument includes an instrument shaft and jaws disposed at a distal end of the instrument shaft. The computer-assisted medical system further includes a controller coupled to the manipulator arm. The controller includes a computer processor and is configured to track a movement of the instrument along an insertion axis of the instrument, and coordinate a size of a jaw aperture defined by the jaws with the movement of the instrument along the insertion axis to reach a target aperture.

Abstract: Techniques for determining an ergonomic center for an input control include an input control and a control unit including one or more processors. Movement of the input control during teleoperation is usable to command corresponding movement of an end effector. One or more control points are associated with the input control. The control unit is configured to detect a start of a repositioning movement for the input control, detect an end of the repositioning movement, determine one or more corresponding end positions, each corresponding end position being a position of a control point of the one or more control points at the end of the repositioning movement, determine an input control reference point based on the one or more corresponding end positions, and aggregate the input control reference point with at least one previously obtained input control reference point to determine an ergonomic center for the input control.

Abstract: Systems and methods of recentering an input control include a control unit configured to suspend teleoperated control of an end effector by the input control in response to a recentering request, determine a recentering move for the input control to provide positional and orientational harmony between the input control and the end effector, execute the recentering move, and reinstate teleoperated control of the end effector by the input control. In some embodiments, to determine the recentering move the control unit is configured to determine one or more first positions associated with the end effector, map the first positions to a view coordinate system, map the first positions from the view coordinate system to a console workspace coordinate system, and determine one or more second positions for one or more control points on the input control, the control points corresponding to the mapped first positions in the console workspace coordinate system.

Abstract: A cart for supporting one or more instruments for a computer-assisted, remote procedure can include a base and a support structure extending from the base and adjustable to different configurations, the support structure being configured to support one or more instruments to perform a remote procedure. The cart can further include a steering interface configured to be grasped by a user and a sensor mechanism configured to detect a force applied to the steering interface. The cart also can include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and information about a configuration of the support structure, the control module operably coupled to output a movement command based on the received input from the sensor mechanism and the information about the configuration of the support structure.

Abstract: Devices, systems, and methods for providing commanded movement of an end effector of a manipulator while providing a desired movement of one or more joints of the manipulator. Methods include augmenting a Jacobian so that joint movements calculated from the Jacobian perform one or more auxiliary tasks and/or desired joint movements concurrent with commanded end effector movement, the one or more auxiliary tasks and/or desired joint movements extending into a null-space. The auxiliary tasks and desired joint movements include inhibiting movement of one or more joints, inhibiting collisions between adjacent manipulators or between a manipulator and a patient surface, commanded reconfiguration of one or more joints, or various other tasks or combinations thereof. Such joint movements may be provided using joint velocities calculated from the pseudo-inverse solution of the: augmented Jacobian. Various configurations for systems utilizing such methods are provided herein.

Abstract: A system includes a manipulator arm configured to support an instrument having an end effector, the manipulator arm including a distal portion, a proximal portion coupled to a base, and a multitude of joints between the distal portion and the base, the multitude of joints providing sufficient degrees of freedom to allow a range of differing joint states of the multitude of joints for a state of the distal portion. The system also includes a processor coupled to the manipulator arm. The processor is configured with a manipulation mode and a clutch mode, the clutch mode selected from the group consisting of: an arm-null-perpendicular-clutch mode, a port-null-perpendicular-clutch mode, and an arm-port-null-perpendicular-clutch mode. The processor is configured to operate the multitude of joints in accordance with at least one of the manipulation mode and the various clutch modes.

Abstract: A method for moving a manipulator arm. The manipulator arm includes a movable distal portion, a proximal portion coupled to a base, and joints between the distal portion and the base. The method involves calculating a first movement of the joints in accordance with a first objective. The method further involves calculating a second movement of the joints in accordance with a second objective. The first and the second movements are in a null-space of a Jacobian of the manipulator arm. The method also involves determining a combined movement of the joints by combining the first and second movements while limiting an overall magnitude of the combined movement without changing a direction of the combined movement, and/or combining the first and second movements while limiting a magnitude of the combined movement degree-of-freedom by degree-of-freedom. The method further involves driving the joints to effect the combined movement of the joints.

Abstract: A cart for supporting one or more instruments for a computer-assisted, remote procedure can include a base and a support structure extending from the base and adjustable to different configurations, the support structure being configured to support one or more instruments to perform a remote procedure. The cart can further include a steering interface configured to be grasped by a user and a sensor mechanism configured to detect a force applied to the steering interface. The cart also can include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and information about a configuration of the support structure, the control module operably coupled to output a movement command based on the received input from the sensor mechanism and the information about the configuration of the support structure.

Abstract: A method of operating a robotic system involves servoing a multitude of joints of the robotic system in a first joint velocity space. The movement of the multitude of joints in the first velocity space moves a remote center or an end effector of the robotic system. The method further involves floating the multitude of joints in a second velocity space. The movement of the multitude of joints in the second velocity space moves the end effector or the remote center, respectively. The method further involves controlling motion of the multitude of joints in a third velocity space. The movement of the multitude of joints in the third velocity space does not move the end effector and does not move the remote center.

Abstract: A system and method of breakaway clutching in a device includes an arm including a first joint and a control unit coupled to the arm. The control unit includes one or more processors. The control unit switches the first joint from a first state of the first joint to a second state of the first joint in response to an external stimulus applied to the arm exceeding a first threshold, wherein movement of the first joint is more restricted in the first state of the first joint than in the second state of the first joint, switches the first joint from the second state to the first state in response to a speed associated with the first joint falling below a speed threshold, and prevents the switching of the first joint from the first state to the second state when the arm is in a predetermined mode.

Abstract: A cart for supporting one or more instruments during a computer-assisted remote procedure can comprise a base; a steering interface having a portion configured to be grasped by a user; a sensor mechanism configured to detect a force applied to the steering interface by a user; and a switch operable between an engaged position and a disengaged position. The cart may further include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and, on the condition that the switch is in the engaged position, to output a movement command based on the received input from the sensor mechanism. A driven wheel mounted to the base of the cart may be configured to impart motion to the cart in response to the movement command.

Abstract: A system and method of breakaway clutching in a device includes an arm including a first joint and a control unit coupled to the arm and including one or more processors. The control unit switches the first joint from a first state of the first joint to a second state of the first joint in response to an external stimulus applied to the arm exceeding a first threshold and switches the first joint from the second state to the first state in response to a speed associated with the first joint falling below a speed threshold. Movement of the first joint is more restricted in the first state of the first joint than in the second state of the first joint. In some embodiments, the external stimulus applied to the arm is a stimulus detected on the first joint or a stimulus detected on a second joint of the arm.

Abstract: A system, e.g., a computer-aided medical system, includes a first link, a second link, a joint, and a dual brake assembly. The first link has a first end portion and a second end portion. The second link has a first end portion and a second end portion. The joint is connected to the second end portion of the first link and to the first end portion of the second link. The dual brake assembly is coupled to the first link and to the second link. The dual brake assembly includes a first brake and a second brake. Braking provided by the dual brake assembly reduces relative motion between the first and second links.

Abstract: A cart for supporting one or more instruments during a computer-assisted remote procedure can comprise a base; a steering interface having a portion configured to be grasped by a user; a sensor mechanism configured to detect a force applied to the steering interface by a user; and a switch operable between an engaged position and a disengaged position. The cart may further include a drive system comprising a control module operably coupled to receive an input from the sensor mechanism in response to the force applied to the steering interface and, on the condition that the switch is in the engaged position, to output a movement command based on the received input from the sensor mechanism. A driven wheel mounted to the base of the cart may be configured to impart motion to the cart in response to the movement command.

Abstract: A method of operating a robotic system involves servoing a multitude of joints of the robotic system in a first joint velocity space. The movement of the multitude of joints in the first velocity space moves a remote center or an end effector of the robotic system. The method further involves floating the multitude of joints in a second velocity space. The movement of the multitude of joints in the second velocity space moves the end effector or the remote center, respectively. The method further involves controlling motion of the multitude of joints in a third velocity space. The movement of the multitude of joints in the third velocity space does not move the end effector and does not move the remote center.

Abstract: Devices, systems, and methods for positioning an end effector or remote center of a manipulator arm by floating a first set of joints within a null-perpendicular joint velocity sub-space and providing a desired state or movement of a proximal portion of a manipulator arm concurrent with end effector positioning by driving a second set of joints within a null-space orthogonal to the null-perpendicular space. Methods include floating a first set of joints within a null-perpendicular space to allow manual positioning of one or both of a remote center or end effector position within a work space and driving a second set of joints according to an auxiliary movement calculated within a null-space according to a desired state or movement of the manipulator arm during the floating of the joints. Various configurations for devices and systems utilizing such methods are provided herein.

Abstract: Devices, systems, and methods for reconfiguring a surgical manipulator by moving the manipulator within a null-space of a kinematic Jacobian of the manipulator arm. In one aspect, in response to receiving a reconfiguration command, the system drives a first set of joints and calculates velocities of the plurality of joints to be within a null-space. The joints are driven according to the reconfiguration command and the calculated movement so as to maintain a desired state of the end effector or a remote center about which an instrument shaft pivots. In another aspect, the joints are also driven according to a calculated end effector or remote center displacing velocities within a null-perpendicular-space of the Jacobian so as to effect the desired reconfiguration concurrently with a desired movement of the end effector or remote center.

Abstract: A method for moving a manipulator arm. The manipulator arm includes a movable distal portion, a proximal portion coupled to a base, and joints between the distal portion and the base. The method involves calculating a first movement of the joints in accordance with a first objective. The method further involves calculating a second movement of the joints in accordance with a second objective. The first and the second movements are in a null-space of a Jacobian of the manipulator arm. The method also involves determining a combined movement of the joints by combining the first and second movements while limiting an overall magnitude of the combined movement without changing a direction of the combined movement, and/or combining the first and second movements while limiting a magnitude of the combined movement degree-of-freedom by degree-of-freedom. The method further involves driving the joints to effect the combined movement of the joints.

Abstract: Methods, apparatus, and systems for controlling a plurality of manipulator assemblies of a robotic system. In accordance with a method, a first plurality of sensor signals are received at a plurality of joint space interface elements from a plurality of connector input elements via a first mapping between the joint space interface elements and joints of the first manipulator assembly. The connector input elements are operable to couple to only one manipulator assembly at a time. The received first sensor signals are then processed with a joint controller so as to control the first manipulator assembly. A second plurality of sensor signals are then received from the connector input elements at the joint space interface elements via a second mapping different than the first mapping. The received second sensor signals are then processed with the joint controller so as to control a second manipulator assembly different than the first manipulator assembly.