A servo movement control method, device, and terminal device are provided. The method includes: controlling an output shaft of the servo to rotate according to a first motion instruction; detecting whether a second motion instruction is received within a first preset time period, and re-planning a second target motion curve to a second target end position from a corresponding target position on a first target motion curve when receiving the second motion instruction; and controlling the output shaft to rotate from an actual position when receiving the second motion instruction to the second target end position according to the second target motion curve. When the second motion instruction is received, the servo is controlled to rotate from the target position to the second target end position according to the second motion instruction, so that the servo is switched from the first motion instruction to the second motion instruction smoothly.

A servo movement control method, device, and terminal device are provided. The method includes: controlling an output shaft of the servo to rotate according to a first motion instruction; detecting whether a second motion instruction is received within a first preset time period, and re-planning a second ideal motion curve to a second ideal end position from a corresponding ideal position on a first ideal motion curve when receiving the second motion instruction; and controlling the output shaft to rotate from an actual position when receiving the second motion instruction to the second ideal end position according to the second ideal motion curve. When the second motion instruction is received, the servo is controlled to rotate from the ideal position to the second ideal end position according to the second motion instruction, so that the servo is switched from the first motion instruction to the second motion instruction smoothly.

A motor control device includes: a position command section configured to generate a position command for a control object; a position detecting section configured to detect a position of the control object or a position of a motor configured to drive the control object; and a position control section configured to control a position of the motor based on the position command and the detected position of the control object or the motor, in which at least one of the position command section and the position control section includes a vibration suppression filter configured to approximate a reverse characteristic of a vibration characteristic generated between the motor and the control object, and the vibration suppression filter changes a vibration suppression frequency according to at least one of the position and a mass of the control object.

A device for transporting containers comprises at least two transport devices for the containers, at least two servo motors, at least two position sensors, and at least one control unit. The at least one control unit is to control the at least two servo motors, by closed-loop control, based on a comparison of positions determined by respective position sensors of the at least two position sensors and respective target positions. The at least one control unit is further to bring the at least two servo motors to a standstill in the event of a fault of a position sensor, wherein: a) a servo motor is brought to a standstill in a closed-loop manner using the position if it is determinable by the position sensor, or b) the servo motor is brought to a standstill in an open-loop manner based on the target position if the position is not determinable.

A device comprises: a calculation unit calculating, based on a model on a calculator, a response path along which a target actually operates when an instruction path is given; a determiner determining a target path along which the target operates; a generation unit regenerating a temporary instruction path based on the target path and a temporary instruction response path obtained when the calculation unit is given the temporary instruction path; a determiner determining a convergence determination condition; and a comparator determining whether error between the temporary instruction response path and the target path is converged, based on the condition. Regenerating the path and calculating the temporary instruction response path are repeated until the comparator determines that the condition is met, and, when the comparator determines so, the temporary instruction path is output to a controller controlling the target, as the path for operating the target.

One embodiment of the present invention can be characterized as a method for controlling a multi-axis machine tool that includes obtaining a preliminary rotary actuator command (wherein the rotary actuator command has frequency content exceeding a bandwidth of a rotary actuator), generating a processed rotary actuator command based, at least in part, on the preliminary rotary actuator command, the processed rotary actuator command having frequency content within a bandwidth of the rotary actuator and generating a first linear actuator command and a second linear actuator command based, at least in part, on the processed rotary actuator command. The processed rotary actuator command can be output to the rotary actuator, the first linear actuator command can be output to a first linear actuator and the second linear actuator command can be output to a second linear actuator.

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.

One embodiment of the present invention can be characterized as a method for controlling a multi-axis machine tool that includes obtaining a preliminary rotary actuator command (wherein the rotary actuator command has frequency content exceeding a bandwidth of a rotary actuator), generating a processed rotary actuator command based, at least in part, on the preliminary rotary actuator command, the processed rotary actuator command having frequency content within a bandwidth of the rotary actuator and generating a first linear actuator command and a second linear actuator command based, at least in part, on the processed rotary actuator command. The processed rotary actuator command can be output to the rotary actuator, the first linear actuator command can be output to a first linear actuator and the second linear actuator command can be output to a second linear actuator.

An instruction value generation device comprises: an instruction response calculation unit (102) that predictively calculates, on the basis of a model on a calculator, a response path along which a control target is actually operated when an instruction path is given; a target path determination unit (104) that determines a target path along which the control target is operated; an instruction path generation unit (105) that regenerates a temporary instruction path on the basis of the target path and a temporary instruction response path obtained when the temporary instruction path is given to the instruction response calculation unit (102); a convergence-determination-condition determination unit (103) that determines a convergence determination condition used in a determination processing of determining whether an error between the temporary instruction response path and the target path is converged; and a path comparison unit that performs the determination processing on the basis of the convergence determination condition. The regeneration of the temporary instruction path and the calculation of the temporary instruction response path are repeated until the path comparison unit determines that the convergence determination condition is met, and the temporary instruction path is output to a control device (700) controlling the control target, as the instruction path for operating the control target when the path comparison unit determines that the convergence determination condition is met.