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.

To provide an industrial robot and a method of operating the same which are capable of appropriately handling, when an abnormal state occurs during an automatic operation of the robot, the abnormal state without significantly degrading the work efficiency. The industrial robot includes a robot main body (1) having a robot arm, a robot control device (7) configured to control operation of the robot main body (1) and an abnormal state detecting device (8) configured to detect abnormality in a work state of the robot main body (1). The robot control device (7) includes an automatic operation performing means (9) for controlling the operation of the robot main body (1) to perform an automatic operation based on a given operation program, and an automatic operation correcting means (10) for correcting the operation of the robot main body (1) in the automatic operation based on a manual control performed by an operator according to a detection result of the abnormal state detecting device (8).

Methods are provided for handling collisions of a robotic surgical system. Collision handling may include receiving a first handle input and a second input at a controller. Upon receiving the first and second handle input, a desired position of a robotic arm is calculated. A first output signal to move the robotic arm toward the desired position is transmitted in response to calculating the desired position. As the robotic arm moves toward the desired position, a force measurement is received. If the force measurement is greater than a predetermined threshold, the desired position is recalculated.

A robot system includes a robot including a tactile sensor and a hand having the tactile sensor, a tactile information generator configured to generate tactile information defined by a pressure distribution based on pressures detected by a plurality of pressure sensors and spatial positions of the plurality of pressure sensors, and output the tactile information, a manipulator configured to make an operator sense the pressure distribution according to the tactile information outputted from the tactile information generator, and when the operator manipulates the manipulator, output manipulating information according to the manipulation, and a robot controller configured to control operation of the hand of the robot according to the manipulating information outputted from the manipulator.

The invention relates to a robotic system with at least one robotic arm and a control unit, which is designed so that it can preset at least one predefined operation that can be carried out by the robotic system. In addition, the robotic system comprises at least one input device attached to the robotic arm which is designed so that the predefined operations of the robotic system can be parameterized by means of the input device. In this case, the input device is designed so that it can provide a user-directed feedback to a user of the robotic system when setting the execution of operations, the logical sequence of the operations and/or parameterizing the predefined operations for the robotic system.

A robotic system has a plurality of user selectable operating modes. To select one of the operating modes, a user performs a distinguishing action which uniquely identifies a desired operating mode among the plurality of user selectable operating modes. A method implemented by a processor in the robotic system identifies the distinguishing action and places the robotic system in the user selected operating mode.

Robot main body having robotic arm, remote control device including robotic arm operational instruction input part for operator to control by touching, to input operational instruction for robotic arm, and contactless action detecting part configured to detect contactless action including at least one given operation instructing action of operator, and control device communicably connected to remote control device and configured to control operation of robot main body, are provided. Control device includes memory part configured to store operational instruction content data defining an operation mode of robot main body corresponding to at least one operation instructing action, operational instruction content identifying module to identify operation mode of robot main body of the operation instructing action detected by contactless action detecting part based on operational instruction content data, and motion controlling module configured to control operation of robot main body based on operation mode identified by operational instruction content identifying module.

What is disclosed is an apparatus for enabling privacy for patients undergoing breast cancer screening in a non-clinical setting. One embodiment of the present apparatus comprises an enclosure in which a person can remove one or more garments to expose their breasts to a thermal camera for breast cancer screening. The enclosure is such that at least the breast area of that person is shielded from view by third parties. The apparatus also comprises a thermal camera for capturing thermal images of the exposed breast area. The thermal camera is connected to a robotic arm that changes the camera angle relative to real-world coordinates so that thermal images can be taken of the breast area from any angle between a frontal view and a left/right lateral view. A processor which executes a software interface tool for semi-automated or automated breast cancer screening based on the thermal images of the breast.

A robot system includes an operating device that receives an operation instruction from an operator. The system further includes a real robot that is installed in a work space and performs a series of works constituted of a plurality of steps. The system further includes transmission type display device configured to allow the operator to visually recognize a real world and configured to display a virtual. The system further includes a control device configured to operate the virtual robot displayed on the transmission type display device based on instruction information input from the operating device. The control device is further configured to thereafter operate the real robot while maintaining a state that the virtual robot is displayed on the transmission type display device when operation execution information to execute an operation of the real robot is input from the operating device.

One example non-limiting example provides a full representative part 25 commercial aircraft flight deck with a visual system integrated with a robotic manipulator to provide an immersive simulation environment for training and research purposes. Such technology provides an architecture that provides visual blending-warp adjustment along with visual system integration, including for example Spherical screen design, Structural design and Projectors allocation.