A robot control system includes: a robot on which a camera and a hand for gripping a first workpiece are mounted; a displacement generation mechanism disposed between a tip of the robot and the camera; a first control module configured to provide the robot with a control instruction for causing the first workpiece to approach a second workpiece; a vibration calculation module configured to calculate magnitude of vibration caused in the camera when the robot causes the first workpiece to approach the second workpiece; and a second control module configured to provide the displacement generation mechanism with a control instruction for compensating for the vibration calculated by the vibration calculation module.

Provided is a control system that can control the operation of a robot with high accuracy. A control system 1 is provided with a sensor 44 that detects an acceleration that is based on the vibration of a robot 3, an interpolation unit 222 that interpolates a plurality of pieces of sensor data detected by the sensor 44, and a data generation unit 223 that generates combined data having a short sampling period on the basis of a plurality of pieces of interpolation data obtained through interpolation by the interpolation unit 222.

A method performed by one or more processing devices for ensuring that a vehicle seat top is qualified for use with a seat base for a vehicle seat, the method comprising: receiving information that identifies a type of vehicle seat top for coupling to the seat base; verifying that the vehicle seat top is authorized for use with the seat base; and in response to verifying, retrieving, based on the received information that identifies the type of vehicle seat top, pre-determined values of controller parameters of a closed loop control system for isolating vibrations from the vehicle seat top, wherein the predetermined values of the controller parameters are specifically tuned for the vehicle seat top.

A vibration suppression device that suppresses vibration of an operation unit in a mechanical system having a natural vibration mode including the operation unit, an actuator unit that operates the operation unit, and an elastic body that couples the operation unit and the actuator unit, the vibration suppression device including a generation means for generating a drive signal for driving the actuator unit, an estimation means for estimating a measurement amount related to the mechanical system, a correction means for correcting the drive signal generated by the generation means on the basis of the measurement amount estimated by the estimation means, and a change means for changing a gain used by the estimation means so that an influence of an increase in a modeling error becomes small in a period in which the modeling error of the mechanical system increases.

A motor controller according to the present invention includes a position command unit for commanding the position of a driven unit, a compensation filter unit for compensating a position command, and a servo control unit for controlling the operation of a servomotor based on a compensated position command. The compensation filter unit includes an inverse characteristic filter for approximating an inverse characteristic of a transfer characteristic from a motor position to a mechanical position, and a high frequency cutoff filter for reducing a high frequency component of the position command. The inverse characteristic filter is a filter for reducing a gain at a mechanical resonance frequency ω.sub.0. The high frequency cutoff filter has a constant “a” times high frequency cutoff frequency aω.sub.0 using a constant “a” of 1 or more, with respect to the mechanical resonance frequency ω.sub.0 determined in the inverse characteristic filter.

A robot system includes a work apparatus, a robot, and control circuitry. The work apparatus is configured to move a work module relatively to the work apparatus. The work module is configured to perform work. The work apparatus is connected the robot. The control circuitry is configured to control the robot to move so as to reduce a force generated by moving the work module by the work apparatus.

The problem of addressing vibrational disturbances in mechanical positioning systems is addressed by systems and methods that use a combination of active vibration dampening and passive vibration dampening. A system described herein generally comprises a mechanical positioning system; a payload; and a vibration dampening module coupled to the mechanical position system and to the payload. The vibration dampening module generally comprises an active vibration dampener and/or a passive vibration dampener.

Apparatus include a reaction mass and an actuator coupled to the reaction mass. The actuator is configured to couple to a payload and to move the reaction mass in response to a movement error of the payload to reduce the movement error of the payload. Robotic systems using actuated reaction masses, as well as related methods of reducing movement errors, are also disclosed.

The problem of addressing vibrational disturbances in mechanical positioning systems is addressed by systems and methods that use a combination of active vibration dampening and passive vibration dampening. A system described herein generally comprises a mechanical positioning system; a payload; and a vibration dampening module coupled to the mechanical position system and to the payload. The vibration dampening module generally comprises an active vibration dampener and/or a passive vibration dampener.

The present disclosure provides a system for performing interactions within a physical environment, the system including: (a) a robot base; (b) a robot base actuator that moves the robot base relative to the environment; (c) a robot arm mounted to the robot base, the robot arm including an end effector mounted thereon; (d) a tracking system that measures at least one of: (i) a robot base position indicative of a position of the robot base relative to the environment; and, (ii) a robot base movement indicative of a movement of the robot base relative to the environment; (e) an active damping system that actively damps movement of the robot base relative to the environment; and, (f) a control system that: (i) determines a movement correction in accordance with signals from the tracking system; and, (ii) controls the active damping system at least partially in accordance with the movement correction.