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: Systems and methods for instrument disturbance compensation include a computer-assisted device. The computer-assisted device includes an articulated arm having a plurality of joints and a control unit coupled to the articulated arm. The control unit is configured to detect a disturbance to the articulated arm caused by a release of one or more brakes of the plurality of joints and maintain a position of a point of interest associated with the articulated arm by compensating for the disturbance using one or more joints of the plurality of joints. In some embodiments, the point of interest is a tip of an end effector of the articulated arm. In some embodiments, the control unit is configured to determine a predicted motion for the point of interest based on the disturbance and send a drive command to move the point of interest in a direction opposite to the predicted motion.

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 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 for integrated table motion includes a device. The device includes an articulated arm having joints and a distal portion distal to the joints and a control unit. To support integrated motion with a separate table, the control unit is configured to receive a table movement request from the table, determine whether allowing the table movement request would result in a first joint of the joints being at a range of motion limit, allow the table to perform the table movement request based on determining that allowing the table to perform the table movement request would not result in the first joint being at the range of motion limit, track movement of the table due to performing the table movement request, and maintain, using the joints and based on the tracked movement, a position and/or an orientation of the distal portion relative to the table.

Abstract: Robotic and/or surgical devices, systems, and methods include kinematic linkage structures and associated control systems configured to facilitate preparation of the system for use. One or more kinematic linkage sub-systems may include joints that are actively driven, passive, or a mix of both, and may employ a set-up mode in which one or more of the joints are actively driven in response to manual articulation of one or more other joints of the kinematic chain. In an exemplary embodiment, the actively driven joints will move a platform structure that supports multiple manipulators in response to movement of one of the manipulators, facilitating and expediting the arrangement of the overall system by moving those multiple manipulators as a unit into alignment with the workspace. Manual independent positioning of the manipulator can be provided through passive set-up joint systems supporting the manipulators relative to the platform.

Abstract: A computer-assisted medical device including a first joint set on an articulated arm, a second joint set on the articulated arm, and a control unit coupled to the first joint set and second joint set. The control unit determines a disturbance to the first joint set caused by a release of one or more brakes and compensates for the disturbance using the second joint set to reduce motion to a position of a point of interest. In some embodiments, the control unit compensates for the disturbance by determining an initial position for the point of interest with respect to a reference point, determining a predicted motion for the point of interest based on the disturbance to the first joint set, and sending a drive command to the second joint set to move the point of interest in a direction opposite to the predicted motion.

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: Systems and methods are provided for the elimination/mitigation of vibration arising from a mode transition during robotic operation include a moveable robotic mechanism and a processor configured to control the robotic mechanism. The processor is configured to detect a request for a mode transition, wherein the request for the mode transition designates a new mode that is different than a current mode, determine initial parameters of the robotic mechanism, calculate a smoothing curve, and move the robotic mechanism according to the smoothing curve. The initial parameters include a position and a velocity of the robotic mechanism. The smoothing curve transitions between the current mode and the new mode and is C3 continuous. In some embodiments, to calculate the smoothing curve, the processor is configured to establish a first command position, calculate a step value, and set a second command position based on the first command position and the step value.

Abstract: A system includes manipulators and a controller. The controller is configured to detect mounting of an imaging device to a first manipulator of the manipulators, determine a first reference frame for the imaging device based on the mounting of the imaging device to the first manipulator, control a tool relative to the first reference frame by controlling a relative position and orientation of a tip of the tool relative to the imaging device in the first reference frame by correlating movement of a master input control to movement of the tool in the first reference frame, detect mounting of the imaging device to a second manipulator of the manipulators, the second manipulator being different from the first manipulator, determine a second reference frame for the imaging device based on the mounting of the imaging device to the second manipulator, and control the tool relative to the second reference frame.

Abstract: A system and method for an integrated surgical table includes a medical device including an articulated arm having one or more first and second joints and a control unit. The articulated arm has at least a cannula, an endoscope, or an instrument mounted distal to the first and second joints, which is inserted into a patient at a body opening. The control unit unlocks the first joints, receives a surgical table movement request, determines whether the surgical table movement request should be granted, allows the surgical table to perform the requested movement based on the determining, uses the first joints to allow the articulated arm to track movement of the body opening based on forces applied by a body wall at the body opening, and compensates for changes in a pose of the cannula, endoscope, or instrument due to the tracked movement by performing compensating motions in the second joints.

Abstract: A system and method of collision avoidance includes determining first positions of first joints of a first repositionable arm and second positions of second joints of a second repositionable arm. Distal ends of the first and second repositionable arms are configured to support first and second instruments, respectively. The system and method further include determining first and second virtual boundaries around the first and second repositionable arms, determining an overlap between the first and second virtual boundaries, determining an overlap force on the first repositionable arm due to the overlap, mapping the overlap force to virtual torques on the first joints proximal to the overlap, determining a tip force on a distal end of the first instrument, and applying the tip force as feedback on the first instrument.

Abstract: Systems and method are provided for the elimination/mitigation of vibration arising from a mode transition during a robotic surgery. The robotic surgery can be performed with a patient side cart, portions of which can be affected by the mode transition. Initial parameters for the portions of the patient side cart that can be affected by the mode transition are identified and are used to create a smoothing curve. The smoothing curve can direct the movement of the portions of the patient side cart to transition between the modes. The smoothing curve can be continuously generated until a new mode transition is requested.

Abstract: Methods, apparatus, and systems for controlling a telesurgical system are disclosed. In accordance with a method, a first tool connected to a first manipulator of the system, and a second tool connected to a second manipulator of the system, are controlled. A swap of the tools such that the first tool is connected to the second manipulator and the second tool is connected to the first manipulator is then detected. The first tool connected to the second manipulator and the second tool connected to the first manipulator are then controlled.

Abstract: A system and method of maintaining a tool position and orientation for a computer-assisted medical device include a device with an articulated structure including a plurality of joints and a control unit. The articulated structure is configured to support a tool distal to the joints. The control unit is configured to determine an initial position and orientation of the tool prior to movement of a first joint, determine, while the first joint is moving, a current position and orientation of the tool, determine a difference between the current and the initial position and orientation, and drive at least a second joint based on the difference to maintain a position and orientation of the tool at the initial position and orientation. In some embodiments, the position and orientation of the tool are maintained relative to a reference coordinate frame based on a cause of the moving of the first joint.

Abstract: A system and method of aligning with a reference target includes a computer-assisted device. The computer-assisted device includes a link, one or more first joints coupled proximally to the link, an articulated arm comprising one or more second joints coupled distally to the link, the articulated arm configured to couple to an instrument, and a control unit. The control unit is configured to position or orient the link, using the one or more first joints, based on at least one reference of the instrument selected from the group consisting of a reference point associated with the instrument and a reference orientation of the instrument. The control unit is further configured to maintain, while positioning or orienting the link and by using the one or more second joints, a position or an orientation of the instrument relative to a workspace in accordance with the at least one reference of the instrument.

Abstract: A patient side cart for a teleoperated surgical system can include at least one manipulator arm portion for holding a surgical instrument, a steering interface, and a drive system. The steering interface may be configured to detect a force applied by a user to the steering interface indicating a desired movement for the teleoperated surgical system. The drive system can include at least one driven wheel, a control module, and a model section. The control module may receive as input a signal from the steering interface corresponding to the force applied by the user to the steering interface. The control module may be configured to output a desired movement signal corresponding to the signal received from the steering interface. The model section can include a model of movement behavior of the patient side cart, the model section outputting a movement command output to drive the driven wheel.

Abstract: Robotic and/or surgical devices, systems, and methods include a robotic device. The robotic device includes a manipulator, a drive unit coupled to the manipulator, and a processor coupled with the drive unit. The processor is configured determine that a cannula is mounted to the manipulator and inhibit, using the drive unit, manual articulation of the manipulator in response to determining that the cannula is mounted to the manipulator. In some embodiments, the robotic device further includes a linkage. The processor is further configured to determine a manual effort against the manipulator; inhibit, using the drive unit, the manual articulation of the linkage in response to the manual effort being below an articulation threshold; and facilitate, using the drive unit and in response to not determining that the cannula is mounted to the manipulator, the manual articulation of the linkage in response to the manual effort exceeding the articulation threshold.

Abstract: A system and method of breakaway clutching in a computer-assisted medical device includes an articulated arm having one or more first joints and a control unit coupled to the articulated arm and having one or more processors. The control unit operates each of the first joints in multiple states. The multiple states include a locked state, wherein movement of respective first joints is restricted, and a float state, wherein movement of the respective first joints is permitted. The control unit further switches one or more second joints selected from the first joints from the locked state to the float state when a stimulus on the second joints exceeds one or more unlock thresholds and switches the second joints from the float state to the locked state when a velocity of each of the second joints is below one or more lock thresholds.

Abstract: Robotic and/or surgical devices, systems, and methods include a manipulator configured to be mounted to a cannula and a processor. The processor is configured to detect a mounting state of the cannula, detect an input indicating the system is to be in a set-up mode, and inhibit transition of the system to the set-up mode in response to the detected mounting state. In some embodiments, detecting the input indicating the system is to be in the set-up mode includes detecting an activation of a dedicated input button. In some embodiments, detecting the input indicating the system is to be in the set-up mode comprises detecting a joint operation of a first kinematic structure coupling the manipulator with a platform that is supported by a second kinematic structure.