A control system for a surgical robot is provided. The control system includes a first embedded computer and a second embedded computer configured to receive status information from the first embedded computer. The status information includes a status of zero-return for a surgical tool driving module or an imaging tool driving module. The control system also includes a host computer configured to receive the status information from the second embedded computer. The surgical tool driving module or the imaging tool driving module includes a controller, a motor connected with a first coupling and configured to drive the surgical tool or an imaging tool, and a zero point switch configured to detect whether the first coupling is at a zero position. The controller is configured to transmit the status of zero-return to the first embedded computer based on whether the first coupling is at the zero position.

An exemplary embodiment relates to an end effector (1), in particular a robot end effector, a device (20) with an operating element (25) for controlling an end effector (1), a robot with at least one end effector (1) and a medical telemanipulation system.

A robotic surgical system for treating a patient comprises a first robotic arm configured to remotely control a surgical instrument that is positionable within a cavity of the patient; a second robotic arm configured to remotely control a device that is passable through an orifice of the patient; and a control circuit communicatively couplable to the first and second robotic arm. The first and second robotic are each attached to a surgical platform. The control circuit is configured to determine a position of the arms; cause each of the first and second robotic arm to change their respective position and orientation based on an adjustment of a platform position of the surgical platform; and control the first robotic arm and the second robotic arm to cooperatively interact to perform a surgical operation.

In a robotic surgical system, a controller is configured or programmed to change at least one of a level of an operation start assisting force, a level of an in-operation assisting force, or a level of a braking force based on a level change operation of an operator received by a level change receiver.

A technique allows efficient registration of an accurate gripping position of a robot hand with an auxiliary view appearing on a screen in accordance with the robot hand. A user selects a hand type to be used in gripping a gripping target and designates an auxiliary view to be rendered in accordance with the hand. In response to a two-finger hand being selected (step S11), a plane (step S13), a cylinder (step S14), or a rectangular prism (step S15) is rendered based on the view designated by the user (step S12). In response to a suction hand being selected, a plane is rendered (step S16).

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 am to the desired pose in response to the input pose. The am 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.

The technology is directed to providing pick and place instructions to a robot. Sensor data including an image feed of a picking container in which at least one product is located may be output. An input indicating a selected product including at least one of the products located in the picking container may be received. A representation of the selected product and at least one image of the order container may be output for display. The representation of the product may be scaled relative to the at least one image of the order container. A place input corresponding to the position of the representation of the product at a packing location within the at least one image of the order container may be received and transmitted to a robot control system.

Manipulator devices are used for computer-assisted tele-operated surgery. In some embodiments, the manipulator devices described herein include an arm with a proximal end that is configured to releasably couple with a set-up structure of a computer-assisted tele-operated surgery system. A first ring is rotatably coupled to a distal end portion the arm and is rotatably driven by a first gear motor within the arm. A second ring that is concentric with the first ring is also rotatably coupled to the distal end portion of the arm. Rotations of the second ring are driven by a second gear motor within the arm. An instrument actuator coupling is pivotably coupled to the second ring. The instrument actuator coupling is configured to releasably couple with a computer-assisted tele-operated surgical instrument actuator, and defines a surgical instrument insertion axis.

A production device including an isolator housing to receive functional components of the production device and products in an interior of the production device and to hermetically seal the components from the surroundings. The production device includes at least one robot received in the isolator housing, wherein the robot is one or more of operable to carry out specific tasks or operable to be remotely controllable by means of a remote controller. The production device includes at least one linear movement unit received in the isolator housing and configured to move the at least one robot long a linear movement axis. The production device includes at least one control unit to control one or more of a movement or an operation of the at least one robot.

A system receives data from a submersible remote operated vehicle (ROV), the data being about the operation of an arm of the ROV. The system automatically controls, based on the data, movement of the arm in docking the arm to a tool holder. In certain instances, the system implements an image based control. In certain instances, the system implements a force accommodation control. In certain instances, the system implements both.