A control device is connected to a servo mechanism that drives a controlled object and outputs a manipulated variable to the servo mechanism so that a controlled variable tracks a target trajectory. The control device includes a controller and a sensor. The controller acquires a measured value from the sensor and performs model predictive control for each control period using a dynamics model representing a relationship between the manipulated variable and the position of the controlled object to generate the manipulated variable to be output to the servo mechanism. The sensor measures the position of the controlled object. The controller performs model predictive control in a first mode using the measured value when the controlled object has a position within the range, and performs model predictive control in a second mode using an output value of the dynamics model when the controlled object has a position outside the range.

A control device is connected to a servo mechanism that drives a controlled object and outputs a manipulated variable to the servo mechanism so that a controlled variable tracks a target trajectory. The control device includes a controller and a sensor. The controller acquires a measured value from the sensor and performs model predictive control for each control period using a dynamics model representing a relationship between the manipulated variable and the position of the controlled object to generate the manipulated variable to be output to the servo mechanism. The sensor measures the position of the controlled object. The controller performs model predictive control in a first mode using the measured value when the controlled object has a position within the range, and performs model predictive control in a second mode using an output value of the dynamics model when the controlled object has a position outside the range.

The present disclosure relates to a method for controlling zero-return of a servo of a robot, and a servo and a robot with enhanced zero-return. The method includes: outputting an activation command to a motor, and reading a default zero-point of the motor (w1) and a default zero-point of an output shaft of the speed reducer (w2). The output shaft of the motor (w1) is driven to return until the default zero-point of the output shaft of the speed reducer (w2) is the same with the current position of the output shaft of the speed reducer (w4) in response to the default zero-point of an output shaft of the speed reducer (w2) being not the same with the current position of the output shaft of the speed reducer (w4).

The present disclosure relates to a method for controlling zero-return of a servo of a robot, and a servo and a robot with enhanced zero-return. The method includes: outputting an activation command to a motor, and reading a default zero-point of the motor (w1) and a default zero-point of an output shaft of the speed reducer (w2). The output shaft of the motor (w1) is driven to return until the default zero-point of the output shaft of the speed reducer (w2) is the same with the current position of the output shaft of the speed reducer (w4) in response to the default zero-point of an output shaft of the speed reducer (w2) being not the same with the current position of the output shaft of the speed reducer (w4).

A method and a device are used to generate a control command. A resolution base value and a resolution-tick corresponding function are created. A first operation frequency value, a minimal tick value and a resolution value are received to calculate a resolution ratio and a second operation frequency. A conversional tick value is calculated. If or not the conversional tick value is greater than or equal to the minimal tick value is determined. If the conversion tick value is smaller than the minimal tick value, the minimal tick value, the conversional tick value and the second operation frequency are used to calculate a conversional operation frequency. A conversional resolution ratio is calculated according to the first operation frequency and the conversional operation frequency, and also a modified tick value is calculated. The control command is output according to the modified tick value, the first operation frequency and the conversion operation frequency.

An improved system and method for coordinating motion between an external device and independent movers traveling along a linear drive system includes a motion controller generating motion commands for both the external device and for each of the independent movers. Coordinate systems are defined in the motion controller that correspond to a track along which each of the independent movers travels and to the external device. An offset between the coordinate systems is also defined. The motion controller receives a command for coordinated motion and generates motion commands for the independent mover and the external device in one coordinate system to achieve the commanded coordinated motion. The motion command that corresponds to the coordinate system in which the motion commands are generated are transmitted directly, and the motion command associated with the second coordinate system is first transformed to the second coordinate system using the offset.

A method and a device are used to generate a control command. A resolution base value and a resolution-tick corresponding function are created. A first operation frequency value, a minimal tick value and a resolution value are received to calculate a resolution ratio and a second operation frequency. A conversional tick value is calculated. If or not the conversional tick value is greater than or equal to the minimal tick value is determined. If the conversion tick value is smaller than the minimal tick value, the minimal tick value, the conversional tick value and the second operation frequency are used to calculate a conversional operation frequency. A conversional resolution ratio is calculated according to the first operation frequency and the conversional operation frequency, and also a modified tick value is calculated. The control command is output according to the modified tick value, the first operation frequency and the conversion operation frequency.

A moving position control system for a moving apparatus includes an embedded PC, a position control board, a servo driver, a servo motor, and a barcode scanner. The embedded PC sends a positioning instruction to the position control board, which processes the positioning instruction and then sends a signal to the servo driver to drive the servo motor. The barcode scanner collects absolute positions of the moving apparatus on a moving track thereof. The position control board, the servo driver, and the servo motor form a closed-loop control circuit that includes a position loop control circuit, a speed loop control circuit, and a current loop control circuit. Improved operational efficiency is achieved by locating the position loop control circuit at the position control board.

A robot shakes automatically adjusting device includes a parameter optimizing part configured to newly set any one of a plurality of control parameters to a control parameter setter when a shakes evaluation value is above a given threshold, and optimize a combination of the plurality of control parameters by causing the control parameter setter, a robot control part, a shakes acquiring part, and a determining part to repeat the new setting of the control parameters, a linear movement of an end effector, an acquisition of the shakes, and a determination, respectively, until the shakes evaluation value becomes below the given threshold.