A method of using inverse kinematics to control a robotic system includes receiving an input pose from a user interface to move an arm of the robotic system, calculating a remote center of motion for a desired pose from the input pose in a tool center-point frame, checking when the desire pose needs correction, correcting the desired pose of the arm, and moving the arm to the desired pose in response to the input pose. The arm of the robotic system including a tool having a jaw disposed at an end of the arm. Checking when the desired pose needs correction includes verifying that the remote center of motion is at or beyond a boundary distance in the desired pose. Correcting the desired pose of the arm occurs when the remote center of motion is within the boundary distance.

A robot system which includes a manipulator configured to receive a manipulating instruction from an operator, a slave arm having a plurality of joints, and a control device configured to control operation of the slave arm. The control device is configured, while the slave arm is operating at a speed equal to or higher than a first given the threshold, even when an operational instruction value for correcting the operation of the slave arm is inputted from the manipulator during an automatic operation of the slave arm, to prevent the correction of the operation of the slave arm.

Implementations relate to control switch position sensing across a rotational joint. In some implementations, a control input device includes a base member and a roll member rotatable about a central axis with respect to the base member in a roll degree of freedom. A switch contact portion is rotatable with the roll member and moveable to multiple positions in a switch degree of freedom. A first sensor element is coupled to and moveable with the switch contact portion and can be a passive element. A base sensor element is coupled to the base member and configured to sense a proximity of the first sensor element to the base sensor element, and to output a signal indicative of a current position of the switch contact portion in the switch degree of freedom independently of a rotational orientation of the roll member in the roll degree of freedom.

Systems and methods of the present disclosure provide a control solution for a robotic actuator. The actuator can have one or two degrees of freedom of control, and can connect with a platform using an arm. The arm can have at least two degrees of freedom of control, and the platform can have at least two degrees of freedom of control. The platform can be subjected to unpredictable forces requiring a control response. The control solution can be generated using operational space control, using the degrees of freedom of the arm, platform and actuator.

Disclosed herein are techniques including a robotic manipulator including a surgical tool to interface with and rotate the screw about a rotational axis. A haptic device includes an actuator and a rotational interface coupled to the actuator and the rotational interface is manually manipulatable by a hand of an operator. One or more controllers control movement of the robotic manipulator to maintain the rotational axis of the surgical tool along a planned trajectory; autonomously control the surgical tool to rotate the screw at a rotational rate about the rotational axis and to linearly advance the screw at an advancement rate according to a known thread geometry of the screw; obtain a measurement indicative of a present interaction between the screw and the target site; and control the actuator of the haptic device to enable the rotational interface to emulate the present interaction between the screw and the target site.

Remote control robot system includes a master device, slave arm having plurality of control modes including automatic and manual mode, control device configured to operate slave arm, an entering-person sensing device configured to detect entering person into operational area of slave arm, entering-person identifying information acquisition device configured to acquire entering-person identifying information for identifying whether entering person is operator who carries master device, and operation regulating device configured to regulate operation of slave arm based on information acquired from entering-person sensing device and information acquisition device. In automatic mode, operation regulating device regulates operation of slave arm when entering person is detected. In manual mode, operation regulating device allows operation of slave arm to continue when entering person is detected and entering person is operator, and regulates operation of the slave arm when entering person is other than operator.

There is provided a tactile sensation presenting device (100) including: a plurality of tactile sensation presenting units (130) configured to present a tactile sensation based on control information; and a control unit (120) configured to generate the control information which is different for each of the plurality of tactile sensation presenting units, based on information which is generated by an operation tool and is related to contact between the operation tool and an object, and to provide the control information to each of the plurality of tactile sensation presenting units.

A teleoperative system includes an input device and a controller. The controller is configured to receive input associated with movement of the input device, determine a commanded pose of an instrument coupled to the teleoperative system based on the received input, determine a first preferred pose of the instrument based on at least one parameter selected from a group consisting of: a type of the instrument and an operating mode of the instrument, determine a first feedback force command based on a difference between the commanded pose and the first preferred pose, and actuate the input device based on the first feedback force command.

A hand controller for enabling a user to perform an activity and method for controlling a robotic arm is provided. The hand controller includes a bar with a grip and a plurality of motors to provide a force feedback to the user in response to the movement of the plurality of mechanical arms. The method involves receiving input corresponding to the manipulation of a bar and providing a force feedback in response to the movement of the plurality of mechanical arms.

A system and method of providing feedback during manual joint positioning includes a computer-assisted device having an articulated structure including a joint and a control unit coupled to the articulated structure. To provide feedback to a user during manual positioning of the joint by the user, the control unit is configured to provide first haptic feedback indicating that the joint is moving in a correct direction when the joint is moving toward a first target position, provide second haptic feedback indicating that the joint is not moving in the correct direction when the joint is moving away from the first target position, and provide third haptic feedback indicating that motion of the joint should stop when the joint is at the first target position.