A robotic device includes a kinematic chain of a plurality of components, movable relative to each other; a sensor device configured to capture a force and/or moment exerted on at least one of the mobile components; a control device configured to control a movement of the at least one of the mobile components, in the direction of the force that is exerted, as a function of the force captured by the control device and/or of the moment captured by the control device; and a first capture device coupled to the control device and provided for the purpose of contactlessly capturing an operating action of an operator. In a normal operating mode, the control device is configured to specify a mobility of at least one of the mobile components as a function of the captured operating action, improving accuracy and reliability of the device in interaction with a human operator.

A method of operating a robotic control system comprising a master apparatus in communication with an input device having a handle and a slave system having a tool having an end effector whose position and orientation is determined in response to a position and orientation of the handle. The method involves producing a desired end effector position and a desired end effector orientation of the end effector, in response to a current position and a current orientation of the handle. The method further involves causing the input device to provide haptic feedback that impedes translational movement of the handle, while permitting rotational movement of the handle and preventing movement of the end effector, when a rotational alignment difference between the handle and the end effector meets a first criterion. The method further involves re-enabling translational movement of the handle when the rotational alignment difference meets a second criterion.

Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. Axial motion can include insertion and/or retraction of the instrument. For example, a robotic medical system can include a medical instrument comprising an instrument base and a flexible shaft configured for insertion into a patient, and a first robotic arm attachable to the instrument base of the medical instrument. The system also includes a drive device configured to engage the flexible shaft, and a second robotic arm attachable to the drive device. The second robotic arm is configured to operate the drive device to drive axial motion of the flexible shaft, and the first robotic arm is configured to move in coordination with operation of the drive device.

A medical manipulator system including: a medical manipulator having a joint; an operating section having an operating system; and a control unit controlling the medical manipulator according to an operation applied to the operating section. The operating section includes a switch enters or releases a command. The control unit determines whether a deviation between the joint and the operating system exceeds a threshold while the command is entered, carries out a first motion for moving the joint by a displacement corresponding to the displacement of the operating system if the deviation is equal to or smaller than the threshold, carries out a second motion for approaching the joint to the operating system angle if the deviation exceeds the threshold, and stops the motion for approaching the joint to the operating system angle when the command is released when the deviation exceeds the threshold.

A method for a robotic surgical system includes displaying a graphical user interface on a display to a user, wherein the graphical user interface includes a plurality of reconfigurable display panels, receiving a user input at one or more user input devices, wherein the user input indicates a selection of at least one software application relating to the robotic surgical system, and rendering content from the at least one selected software application among the plurality of reconfigurable display panels.

A method includes obtaining an implant plan, defining a range of motion for a surgical tool based on the implant plan, adjusting, by an actuator and based on the range of motion, a passive joint coupled between the actuator and the surgical tool, and allowing manual movement of the surgical tool through the range of motion via rotation at the passive joint.

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 surgical method is provided for use with a teleoperated surgical system (surgical system), the method comprising: recording surgical instrument kinematic information indicative of surgical instrument motion produced within the surgical system during the occurrence of the surgical procedure; determining respective kinematic signatures associated with respective surgical instrument motions; producing an information structure in a computer readable storage device that associates respective kinematic signatures with respective control signals; comparing, during a performance of the surgical procedure surgical instrument kinematic information during the performance with at least one respective kinematic signature; launching, during a performance of the surgical procedure an associated respective control signal in response to a match between surgical instrument kinematics during the performance and a respective kinematic signature.

Provided is a control apparatus configured to control a parallel wire mechanism.

The control apparatus for a parallel wire apparatus configured to pull a movable portion with a plurality of wires decomposes a control model in which the movable portion is driven by a pair of opposed motors with use of the wires to a center of gravity mode in which a motor C is controlled to make the movable portion achieve desired acceleration and a relative mode in which a motor R is controlled to make an elastic force that acts on the wires constant, by mode decomposition, and performs coordinate transformation on an acceleration reference value for the motor C determined in the center of gravity mode and an acceleration reference value for the motor R determined in the relative mode, to thereby obtain an acceleration reference value for the pair of motors.

An arm device includes a joint portion configured to be rotated to thereby change a position and/or a posture of a surgical tool, and an actuator configured to generate a driving force that rotates the joint portion, and to allow a rotation of the joint portion in accordance with an externally applied force. Moreover, the arm device is configured to estimate an external force applied to the surgical tool, to obtain a value of a driving force of the actuator based on a weight of the surgical tool and the external force, and to control the actuator based on a value of the driving force.