A control device of a robot system including a plurality of robots having servo motors of a plurality of axes. The control device includes a plurality of controllers each having a plurality of servo amplifiers that drives the servo motors of the plurality of axes of the robots, and a control unit that controls the plurality of servo amplifiers. The control unit determines a driving number of the servo motors of the plurality of axes in accordance with the robots connected to the controllers, and sets a parameter for the servo amplifiers that drive the axes of the servo motors of a number corresponding to the determined driving number.

This specification describes an adaptive robotic nursing assistant for physical tasks and patient observation and feedback. In some examples, the adaptive robotic nursing assistant includes an omni-directional mobile platform; a footrest on the omni-directional mobile platform; a handlebar located above the footrest such that a user standing on the footrest can grasp the handlebar; a display above the handlebar and at least one user input device; a robot manipulator comprising a robotic arm and an end effector on the robotic arm; and a control system coupled to the omni-directional mobile platform, the control system comprising at least one processor and memory storing executable instructions for the at least one processor to control the omni-directional mobile platform.

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.

A robot manipulating system includes a game terminal having a game computer, a game controller, and a display configured to display a virtual space, a robot configured to perform a work in a real space based on robot control data, and an information processing device configured to mediate between the game terminal and the robot. The information processing device supplies game data associated with a content of work to the game terminal, acquires game manipulation data including a history of an input of manipulation accepted by the game controller while a game program to which the game data is reflected is executed, converts the game manipulation data into the robot control data based on a given conversion rule, and supplies the robot control data to the robot.

An object-collection system is disclosed. The system includes a mechanical arm assembly, a receptacle, an end-effector, and a user input device. The mechanical arm assembly has multiple degrees of freedom and is configured to pick up small objects off of the ground surface. The receptacle holds small objects that are picked up by the mechanical arm assembly. The end-effector is positioned at a proximal end of the mechanical arm assembly. The end-effector grasps and acquires small objects from the ground surface. The user input device provides operator control input from an operator on the ground vehicle to actuate the multiple degrees of freedom of the mechanical arm assembly and to actuate the end-effector. The user input signals from the user input device control electric or hydraulic actuators in the object collection system.

A surgical robot includes: a plurality of manipulator arms; a platform to which the plurality of manipulator arms are coupled; a positioner configured to change the position and posture of the platform; a controller configured to control the positioner; and a user interface. The user interface includes: first manipulation tools each configured to receive an input of manipulation which selects one of a plurality of operating modes for changing the position and posture of the platform; and a single second manipulation tool configured to receive an input of manipulation information regarding the position and posture. The controller generates a command regarding the position and posture of the platform based on the acquired manipulation information and the selected operating mode and operates the positioner based on the generated command.

A method of operating a robotic control system comprising a master apparatus in communication with an input device having a handle and a slave system having a tool having an end effector whose position and orientation is determined in response to a position and orientation of the handle. The method involves producing a desired end effector position and a desired end effector orientation of the end effector, in response to a current position and a current orientation of the handle. The method further involves causing the input device to provide haptic feedback that impedes translational movement of the handle, while permitting rotational movement of the handle and preventing movement of the end effector, when a rotational alignment difference between the handle and the end effector meets a first criterion. The method further involves re-enabling translational movement of the handle when the rotational alignment difference meets a second criterion.

Surgical robotic systems including a user console for controlling a robotic arm or a surgical robotic tool are described. The user console includes components designed to automatically adapt to anthropometric characteristics of a user. A processor of the surgical robotic system is configured to receive anthropometric inputs corresponding to the anthropometric characteristics and to generate an initial console configuration of the user console based on the inputs using a machine learning model. Actuators automatically adjust a seat, a display, or one or more pedals of the user console to the initial console configuration. The initial console configuration establishes a comfortable relative position between the user and the console components. Other embodiments are described and claimed.

Embodiments of the present disclosure provide a robot and a master manipulator thereof. The master manipulator includes: an end control assembly; and an attitude adjustment assembly. The attitude adjustment assembly may include a first mechanism and a second mechanism, the first mechanism and the second mechanism are connected to the end control assembly, and the end control assembly controls the first mechanism and the second mechanism to move through the connection between the first mechanism and end control assembly and the connection between the second mechanism and the end control assembly.

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.