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.

An information sharing system between a plurality of robot systems includes a plurality of robot systems, communicatably connected with each other through a network, and configured to be capable of presetting a given operation of a robot and repeating a correction of the operation, and a storage device, connected with the network and configured to store corrected information containing corrected operating information that is operating information for causing the robot to execute a given operation corrected in at least one of the robot systems. Each of the plurality of robot systems shares the corrected information stored in the storage device and operates the robot based on the sharing corrected information.

A method of maneuvering a robot includes driving the robot across a surface and turning the robot by shifting a center of mass of the robot toward a turn direction, thereby leaning the robot into the turning direction. The robot includes an inverted pendulum body, a counter-balance body disposed on the inverted pendulum body and configured to move relative to the inverted pendulum body, at least one leg prismatically coupled to the inverted pendulum body, and a drive wheel rotatably coupled to the at least one leg. The inverted pendulum body has first and second end portions and defines a forward drive direction. The method also includes turning the robot by at least one of moving the counter-balance body relative to the inverted pendulum body or altering a height of the at least one leg with respect to the surface.

In a remote control robot system including a plurality of slave arms, slave arm has a plurality of control modes of an automatic mode in which slave arm is operated based on a task program, a manual mode in which slave arm is operated based on an operator's operation received by a master device, and correctable automatic mode in which slave arm is operated based on task program while operation is sequentially corrected by the operator's operation received by master device. Operation sequence information includes an automatic part in which slave arm performs a work in the automatic mode, and a selected part in which slave arm performs a work in one selected from plurality of control modes, and the selected parts do not overlap with each other in time among the plurality of slave arms. Based on the operation sequence information, the plurality of slave arms are operated.

A manipulating device is provided, which includes a first parallel linkage mechanism having a pair of first links and a pair of second links, a second parallel linkage mechanism having a pair of third links and a pair of fourth links, and a support member supporting one of the third links. The first parallel linkage mechanism and the second parallel linkage mechanism commonly use one of the second links and one of the fourth links and an armrest member to which a manipulating member is attached at a tip-end part thereof is disposed in a lower-end part of the first parallel linkage mechanism.

An input control device is disclosed. The input control device includes a central portion coupled to a multi-axis force and torque sensor, which is configured to receive input control motions from a surgeon. The central portion is flexibly supported on a base. The input control device also includes a rotary joint coupled to a rotary sensor. The input control device is configured to provide control motions to a robotic arm and/or a robotic tool based on input controls detected by the multi-axis force and torque sensor and the rotary sensor.

In some embodiments, a hand controller apparatus for controlling a tool in a robotic surgery system can include a body configured to be moved to generate a first operator input to cause a tool to move corresponding to the movement of the body. The hand controller apparatus can also include an input control interface formed on a surface of the body and configured to sense one or more of a plurality of second operator inputs associated with a plurality of tool functions, the plurality of second operator inputs being different from the first operator input. The hand controller apparatus can also include a processor configured to control the tool to perform one or more of the plurality of tool functions in response to the sensed one or more second operator inputs.

A mobile character control system that includes a platform, a character assembly, a control system, and a transportation assembly. The platform is configured to support an operator. The character assembly is engaged with the platform and includes actuatable features configured to simulate movement of a creature. The control system is configured to control activation of the actuatable features of the character assembly in response to signals received from control features controlled by the operator. The transportation assembly is configured to direct movement of the platform, and the transportation assembly is configured to support the character assembly.

A teleoperated robotic system that utilizes a graphical user interface (GUI) to perform work on a workpiece(s) using a robot. A coordinate system of the GUI is correlated to the tool center point (TCP) of the robot and the TCP or workspace of a teleoperated member, such as a haptic joystick. Operable manipulation of the teleoperated member is correlated to a movement at a particular location in the robot station, such as movement of the TCP of the robot. The GUI can also provide digital representations of the workpiece, which is based on inputted and/or scanned information relating to a reference workpiece and/or the particular workpiece on which the robot is performing work. The GUI can further provide indications of the various stages of assembly of the workpiece, as well as an indication of work already, or to be, performed on the workpiece.

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.