A control device of a machine tool includes a position controller and a model of a position-controlled axis. The position controller receives a position setpoint value, a corresponding actual position value and a compensation value; determines therefrom a resulting value; determines based on the resulting value an actuating signal; and outputs the actuating signal to the position-controlled axis. The position and/or the orientation of the tool relative to the workpiece are adjusted based on the actuating signal. A sequence of successive control errors is stored, in a storage device and read out sequentially in accordance with a sequence of the position setpoint values and supplied to the model. The model determines from the read-out control error a respective compensation value which is then supplied to the position controller, while simulating the mechanically dynamic behavior of the position-controlled axis.

A method for operating an electric or fluidic actuator, for which a setpoint position is predefined, includes the steps: provision of the setpoint position to a path planning unit and calculation of movement values from the setpoint position, provision of the movement values by the path planning unit to an open-loop control circuit and a closed-loop control circuit, calculation of a first manipulated variable component dependent on the movement values in the open-loop control circuit and calculation of a second manipulated variable component dependent on the movement values and on position signals of a position sensor assigned to the actuator in the closed-loop control circuit, combining of the first and the second manipulated variable component in an control unit and provision of a control signal resulting from the manipulated variable components to the actuator.

The invention relates to a method of controlling a drive, in particular an electric drive, of an industrial machine, in which method a drive control controls a drive motor and the drive motor drives a mechanical system having one or more coupled components. The method is characterized in that the drive control carries out a simulation of the mechanical system of the machine by means of a simulation model and performs a feedforward control of the drive motor based on the simulation.

A method of controlling a drive, in particular an electric drive, of an industrial machine, in which method a drive control controls a drive motor and the drive motor drives a mechanical system having one or more coupled components. The drive control carries out a simulation of the mechanical system of the machine with a simulation model and performs a feedforward control of the drive motor based on the simulation.

A control device of a machine tool includes a position controller and a model of a position-controlled axis. The position controller receives a position setpoint value, a corresponding actual position value and a compensation value; determines therefrom a resulting value; determines based on the resulting value an actuating signal; and outputs the actuating signal to the position-controlled axis. The position and/or the orientation of the tool relative to the workpiece are adjusted based on the actuating signal. A sequence of successive control errors is stored, in a storage device and read out sequentially in accordance with a sequence of the position setpoint values and supplied to the model. The model determines from the read-out control error a respective compensation value which is then supplied to the position controller, while simulating the mechanically dynamic behavior of the position-controlled axis.

A method for operating an electric or fluidic actuator, for which a setpoint position is predefined, includes the steps: provision of the setpoint position to a path planning unit and calculation of movement values from the setpoint position, provision of the movement values by the path planning unit to an open-loop control circuit and a closed-loop control circuit, calculation of a first manipulated variable component dependent on the movement values in the open-loop control circuit and calculation of a second manipulated variable component dependent on the movement values and on position signals of a position sensor assigned to the actuator in the closed-loop control circuit, combining of the first and the second manipulated variable component in an control unit and provision of a control signal resulting from the manipulated variable components to the actuator.

An embodiment provides a control method for controlling a mechatronic system. The method comprises providing a model of the mechatronic system, the model comprising a disturbance compensation parameter and modifying the disturbance compensation parameter by: obtaining a servo-error of the mechatronic system, obtaining a setpoint of the mechatronic system and determining, based on the setpoint and the model of the mechatronic system comprising the disturbance compensation parameter, a predicted servo-error of the mechatronic system, such that the disturbance compensation parameter is based on a correlation between the servo-error and the predicted servo-error. The method further comprises updating a feedforward transfer function of the mechatronic system based on the modified disturbance compensation parameter and continuously determining a control signal to control the mechatronic system using the updated feedforward transfer function.