A robotic surgical system includes a linkage, an input handle, and a processing unit. The linkage moveably supports a surgical tool relative to a base. The input handle is moveable in a plurality of directions. The processing unit is in communication with the input handle and is operatively associated with the linkage to move the surgical tool based on a scaled movement of the input handle. The scaling varies depending on whether the input handle is moved towards a center of a workspace or away from the center of the workspace. The workspace represents a movement range of the input handle.

An operation method for a link actuating device provided with a target value input unit having a height direction target value input portion that allows input of a movement amount in a height direction or a coordinate position in the height direction, which causes the distal end posture of the link actuating device to be changed only in the height direction along a central axis of a proximal end side link hub. An input converter is provided to calculate, by using an inputted value, a target distal end posture of the link actuating device. The input converter further calculates a command operation amount of each actuator from the result of the calculation, and inputs the command operation amount to the control device.

A medical system according to one or more embodiments may include a memory, a robotic operation table top, and a controller. The robotic operation table includes a table top and a robot arm supporting the table top. The controller gives the robot arm a command to move the table top to positions corresponding to the medical processes. The robot arm includes a plurality of joints, a plurality of movable elements connected by the plurality of joints to one another, and a plurality of electric actuators and a plurality of position detectors. At least one of the plurality of joints is a horizontally-rotating joint which couples two movable elements among the plurality of movable elements to each other so as to be rotatable about a vertical axis. The positions corresponding to the medical processes include a placement position, an imaging position, and a surgery position.

A method of initializing the layout of one or more robotic arms controllable by an input object, comprising: entering a paused mode, in which control of movement of the robotic arms by the input object is paused; measuring an input object initialization layout, defined by the layout of at least one segment of the input object; actuating at least a portion of the robotic arms to match the input object initialization layout; and entering a controlled mode, in which movements of the input object control the robotic arms.

An unmanned ground vehicle includes a main body, a drive system supported by the main body, and a manipulator arm pivotally coupled to the main body. The drive system comprising right and left driven track assemblies mounted on right and left sides of the main body. The manipulator arm includes a gripper, a wrist motor configured for rotating the gripper, and an inline camera in a palm of the gripper. The inline camera is mechanically configured to remain stationary with respect to the manipulator arm while the wrist motor rotates the gripper.

A universal translator control system for remote control of a robot with a joystick. The system includes a calculation unit for storing translation logic, a control access interface unit electrically connected to the calculation unit, and a joystick which is operated to generate signals that have at least an X-coordinate value, X-direction rotation value, Y-coordinate value, Y-direction rotation value, Z-coordinate value, and Z-direction rotation value. Specifically, a robotic access interface unit is electrically connected to the calculation unit and the robot, whereby the translation logic in the calculation unit is used to translate the signals generated by the joystick as a translated X coordinate value, translated X-direction rotation value, translated Y coordinate value, translated Y-direction rotation value, translated Z coordinate value, and translated Z-direction rotation value, which are transmitted to the robot.

A training processing device manages a training for a robot manipulation using a manipulation terminal. The training processing device communicates information with the manipulation terminal through a communication network, accepts first information that is information on the robot manipulation inputted into the manipulation terminal, while the manipulation terminal executing a computer program for the training of the robot manipulation, and manages the training based on the first information.

Described herein is an inventory management system, and corresponding methods, in which robotic units are configured to execute at least a portion of a set of instructions in an automated manner. During execution of the set of instructions, robotic units may encounter tasks that they are unable to complete in an automated manner. The robotic units, upon encountering these tasks, may submit a request for manual operation to a control unit. In some embodiments, the request may be assigned to an available operator, which may take over control of the robotic unit using a remote manipulation device, to complete the task manually. Once the task has been completed manually, automated execution of the instructions may be resumed.

An operation device for a link actuating device (51) is provided with a target value input unit (57) having a height direction target value input portion (57z) that allows input of a movement amount in a height direction or a coordinate position in the height direction, which causes the distal end posture of the link actuating device (51) to be changed only in the height direction along a central axis of a proximal end side link hub (12). Input converter (58) is provided to calculate, by using an inputted value, a target distal end posture of the link actuating device (51). The Input converter (58) further calculates a command operation amount of each actuator (53) from the result of the calculation, and inputs the command operation amount to the control device (54).

Systems and methods for performing concomitant medical procedures are disclosed. In one aspect, the method involves controlling a first robotic arm to insert a first medical instrument through a first opening of a patient and controlling a second robotic arm to insert a second medical instrument through a second opening of the patient. The first robotic arm and the second robotic arm are part of a first platform and the first opening and the second opening are positioned at two different anatomical regions of the patient.