A robot system according to the present disclosure includes a robot installed in a work area, a manipulator configured to be gripped by an operator and manipulate the robot, a sensor disposed at a manipulation area and configured to wirelessly detect positional information and posture information on the manipulator, and a control device which calculates a locus of the manipulator based on the positional information and the posture information on the manipulator detected by the sensor, and operates the robot on real time.

A surgical robotic system includes a robotic arm having at least one surgical instrument and a control device coupled to the robotic arm and configured to control the robotic arm, the control device including one or more components. The surgical robotic system also includes a power supply having: a tower power supply chassis configured to supply first direct current to the robotic arm; a power distribution unit configured to supply second direct current to the one or more components; a first uninterruptable power supply device coupled to the tower power supply chassis and configured to receive a first alternating current from a first alternating current input; and a second uninterruptable power supply device coupled to the power distribution unit and configured to receive a second alternating current from a second alternating current input.

A method includes receiving sensor data for an environment about the robot. The sensor data is captured by one or more sensors of the robot. The method includes detecting one or more objects in the environment using the received sensor data. For each detected object, the method includes authoring an interaction behavior indicating a behavior that the robot is capable of performing with respect to the corresponding detected object. The method also includes augmenting a localization map of the environment to reflect the respective interaction behavior of each detected object.

A powered user interface for a robotic surgical system operates in accordance with a mode of operation in which the actuators are operated to permit motion of the handle in pitch and yaw motion constrained with respect to a virtual fulcrum in a work space of the user interface, and insertion motion is constrained along an axis passing through the virtual fulcrum. In a virtual fulcrum setting mode, a user is prompted to give input to the system selecting a desired point in space for the virtual fulcrum. The selected point in space is then set as the virtual fulcrum.

To reduce the possibility that a robot will collide with an obstacle during an interference check work and improve the efficiency of the check work at a portion where the interference may occur, an information processing apparatus includes a control unit that controls an operation of a first robot, an acquisition unit that acquires position and orientation of a display apparatus which is attached with a body of an observer, a generation unit that identifies a visual field of the observer including the first robot based on the position and orientation of the display apparatus and an internal parameter of the display apparatus and generate an operation image of a second robot to be displayed in the identified visual field, as an object that may interfere with the first robot, based on operation data of the second robot, and an output unit that outputs the operation image to the display apparatus.

A robot system is provided, which includes a robot body including, robot arm and an end effector attached to robot arm, and operating device, having operating part and configured to output, when operating part is operated, operational information according to operation, a motion controller configured to control operation of robot body according to the operational information outputted from the operating device, a velocity detector configured to detect a velocity at a tip end of the end effector, a virtual reaction-force information generating module configured to output force information containing a first force component having a positive correlation to the velocity at the tip end of the end effector, as virtual reaction-force information, and a force applying device configured to give a force to the operating part in order to make an operator perceive a force according to the virtual reaction-force information outputted from the virtual reaction-force information generating module.

A robot system which includes a manipulator, slave arm, an output device, a storage device and a control device. Control device is configured, after a given first process, to output to the output device an inquiry of asking which operating mode among three operating modes of an automatic operation mode, manual operation mode, and hybrid operation mode the slave arm is to be operated in a second process, and execute first operation processing in which, when selected information for instructing the operating mode selected from the three operating modes is inputted, the selected information is stored in the storage device, and second operation processing in which, when the number of times that first selected information is stored in the storage device becomes equal to or more than a first threshold number of times, the selected operating mode is outputted to the output device after the first process is ended.

A manipulator system configured to perform a work to a workpiece being moved by a moving device, includes a robotic arm, having one or more joints and to which a tool configured to perform the work to the workpiece is attached, an operating device configured to operate the robotic arm, a first imaging means configured to image the workpiece, while following the movement of the workpiece, a second imaging means fixedly provided in a work area to image a situation of the work to the workpiece, a displaying means configured to display an image imaged by the first imaging means and an image imaged by the second imaging means, and a control device configured to control the operation of the robotic arm based on an operating instruction of the operating device, while detecting a moving amount of the workpiece being moved by the moving device and carrying out a tracking control of the robotic arm according to the moving amount of the workpiece.

A remote-control manipulator system includes a manipulator configured to receive a manipulating instruction from an operator, a slave arm configured to perform a series of works comprised of a plurality of processes, a camera configured to image operation of the slave arm, a display device configured to display an image captured by the camera, a storage device configured to store information related to environment in a workspace as an environment model, and a control device. The control device is configured, while operating the slave arm manually or hybridly, to acquire circumference information that is information related to a circumference area of an area imaged by the camera based on the environment model stored in the storage device, and display on the display device so that the image captured by the camera and the circumference information are interlocked.

A robot system includes a robotic arm having an end effector configured to perform a work to a work object, a memory part storing information that causes the end effector to move as scheduled route information, a motion controller configured to operate the robotic arm by using the scheduled route information to move the end effector, a route correcting device configured to generate, by being manipulated, manipulating information to correct a route of the end effector during movement, a camera configured to image the work object, an image generator configured to generate a synthesized image by synthesizing a scheduled route of the end effector obtained from the scheduled route information with a captured image sent from the camera, and a monitor configured to display the synthesized image.