Provided is a numerical control device which makes it possible to improve operating efficiency. The numerical control device according to the present invention controls a machine tool with a manually-operated handle, and is provided with a status identification unit that identifies a state of the numerical control device or the machine tool, and a haptic control unit that causes haptic feedback to be generated in the manually-operated handle on the basis of the status of the numerical control device or the machine tool identified by the status identification unit.

Disclosed are systems and methods for detecting a graphic card that visually describes an operational mode of a rotatable interface component via a plurality of curves for rotationally-varying parameters, determining the operational mode that is visually described on the graphic card, and loading the operational mode to the rotatable interface component, where the operational mode specifies operations for a motor such that the motor generates torque on the interface component based on the curves for the rotationally-varying parameters that are shown on the graphic card.

A method for generating action sequence data for a character to be rendered in a video game is provided. The method includes, during recording of an actor in a performance space, providing a cue to the actor to perform an action that simulates interacting with a virtual object at a location in the performance space. The method also includes instructing a robot to move to the location in the performance space at which the actor is to simulate interaction with the virtual object, and instructing the robot to adjust a physical attribute of the robot when at the location. The physical attribute of the robot, when adjusted, is placed at a three-dimensional location in the performance space to simulate a scale of the virtual object with which the actor is to simulate interaction. The virtual object can be either an animated object or a non-animated object.

A coupling device (16, 116, 216, 316) configured optimally to communicate between a first and a second admittance controller and actuator assembly, the first and the second admittance control and actuator assembly respectively having a first and a second admittance controller (12a, 12b) configured to drive a respective first and a second actuator and each of the first and the second actuator being respectively connected to a first body having a first mass and a second body having a second mass, wherein the coupling device (16, 116, 216, 316) comprises: an input port having a first input for receiving a first input force signal (f1) from the first admittance controller and actuator assembly (12a) and a second input for receiving a second input force signal (f2) from the second admittance controller and actuator assembly (12b), and a processor adapted to derive a first output force signal for output to the first admittance controller and actuator assembly based on a Lagrange multiplier dependent on a comparison of the first input force signal and the second input force signal.

Systems and methods for multi-level closed loop control of haptic effects are disclosed. One illustrative system for multi-level closed loop control of haptic effects includes a haptic output device configured to output a haptic effect, a sensor configured to sense the output of the haptic output device and generate a sensor signal, and a processor in communication with the sensor. The processor is configured to: receive a reference signal, receive the sensor signal, determine an error based at least in part on the reference signal and the sensor signal, generate a haptic signal based at least in part on the reference signal and the error, and transmit the haptic signal to a haptic output device configured to output a haptic effect based on the haptic signal.

An intuitive control system for lifting equipment is described. The intuitive control system translates user defined inputs into machine expressions of movement that are in turn used to control a construction lift or similar piece of construction equipment. Orientation and relative position sensors may be incorporated into the translation and control system for correct user control of the lifting equipment in various operating conditions.

A coupling device (16, 116, 216, 316) configured optimally to communicate between a first and a second admittance controller and actuator assembly, the first and the second admittance control and actuator assembly respectively having a first and a second admittance controller (12a, 12b) configured to drive a respective first and a second actuator and each of the first and the second actuator being respectively connected to a first body having a first mass and a second body having a second mass, wherein the coupling device (16, 116, 216, 316) comprises: an input port having a first input for receiving a first input force signal (f1) from the first admittance controller and actuator assembly (12a) and a second input for receiving a second input force signal (f2) from the second admittance controller and actuator assembly (12b), and a processor adapted to derive a first output force signal for output to the first admittance controller and actuator assembly based on a Lagrange multiplier dependent on a comparison of the first input force signal and the second input force signal.

A gimbal for a robotic surgical system includes a support link, an input link, and a vibration assembly. The input link extends from the support link and the vibration assembly is mounted to the support link. The vibration assembly includes a central support, an end cap, and a voice coil. The end cap is moveable relative to the central support. The voice coil has an inner member that is fixed to the central support and an outer member that is fixed to the end cap. The voice coil is configured to vibrate the gimbal in response to a voltage being applied to one of the inner or outer members.

The present disclosure is directed to a robotic surgical system that includes a robotic surgical device having a robotic arm and an end effector with a pair of jaw members. A handpiece includes a pinch interface to control the arm or end effector, optical marker(s), an accelerometer, and a transmitter to transmit data from the pinch interface or accelerometer to the robotic surgical device. The system further includes a tracking system, to track the marker and provide a position or orientation of the handpiece. A processor receives: (i) the position or orientation of the handpiece from the tracking system; and (ii) the measured acceleration of the handpiece from the accelerometer. The processor integrates the measured acceleration to establish a second position beyond that of the tracking system. The processor controls movement of the robotic arm and end effector based on the received data from the camera or the accelerometer.

Systems and methods for multi-level closed loop control of haptic effects are disclosed. One illustrative system for multi-level closed loop control of haptic effects includes a haptic output device configured to output a haptic effect, a sensor configured to sense the output of the haptic output device and generate a sensor signal, and a processor in communication with the sensor. The processor is configured to: receive a reference signal, receive the sensor signal, determine an error based at least in part on the reference signal and the sensor signal, generate a haptic signal based at least in part on the reference signal and the error, and transmit the haptic signal to a haptic output device configured to output a haptic effect based on the haptic signal.