A multi-axis control adjustment apparatus includes adjustment axis selection circuitry configured to select a plurality of target axes among a plurality of axes each of which represents a combination of a motor and a motor control device configured to control the motor according to a control parameter of the motor control device, adjustment operation execution circuitry configured to perform adjustment operations in each of which the control parameter is adjusted with respect to each of the plurality of target axes, and first control parameter setting circuitry configured to change, according to the adjustment operations, timing at which the control parameter is set with respect to each of the plurality of target axes.

A method for determining an adapted master value of a master axis, wherein a setpoint slave value for a slave axis is derivable from the adapted master value via a synchronism function and a drive on the slave axis is operated in synchronism with the master axis based on the setpoint slave value, where the adapted master value is determined based on a base master value of the master axis and a time difference of operative times of determinable events on the master axis and slave axis.

A motor control system includes motor control devices and a controller. The controller generates and transmits a communication signal including an operation command to the respective motor control devices. The motor control devices include two motor control devices in a first group, each of which includes a data transceiver, a motor controller, a corrector, and a synchronous timing generator, and a motor control device in a second group. The data transceiver receives an operation command issued to the motor control device, and receives operation information in the motor control device in the second group. Based on the operation command, the motor controller generates a torque command signal. The corrector generates a torque correction signal based on the operation information, and corrects the torque command signal. The synchronous timing generator generates a timing signal that matches pieces of process timing of the motor controllers in the first group with each other.

A numerical controller, which reciprocates a parent axis and a child axis according to a predetermined synchronization ratio by multi-axis synchronization control, is provided with a command decoding unit configured to decode a command including a plurality of command blocks, a distribution processing unit configured to generate a distribution movement amount, which is an amount of movement for each control period of a motor, based on the command blocks, an end-point correction unit configured to perform first correction processing for correcting the distribution movement amount so that a feedback position of the child axis reaches an end point, which is a turning point of the reciprocating motion, and second correction processing for recovering synchronization destroyed by the first correction processing, and a motor control unit configured to drivingly control the motor based on the corrected distribution movement amount.

A servo controller 20 includes: an oscillation command generating unit 23 that generates an oscillation command for causing the workpiece W and the tool 14 to relatively oscillate; at least one of a position control unit 22 that generates a position command for causing the workpiece W and the tool 14 to relatively move, a speed control unit 24 that generates a speed command for causing the workpiece W and the tool 14 to relatively move, and a current control unit 25 that generates a torque command for driving the plurality of axes; and a gain changing unit 21 that changes a control gain, in which the oscillation command generating unit 23 transmits a signal outputted when oscillating operation is started to the gain changing unit 21, and the gain changing unit 21 changes the control gain.

An automatic control method and an automatic control device are provided. The automatic control device includes an automatic joint mechanism and a processor. The automatic joint mechanism includes a first motor and a second motor. The processor is adapted to perform a force adjustment on the first motor and the second motor. When a first motor state parameter of the first motor is different from a second motor state parameter of the second motor, the processor adjusts at least one of a first target position parameter of the first motor and a second target position parameter of the second motor, so that a degree of force of at least one of the first motor and the second motor is automatically and correspondingly adjusted.

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 numerical controller for performing axis synchronous control between a plurality of units in a master-slave mode performs speed-based synchronous control in a predetermined section and performs position-based synchronous control in another section.

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 numerical controller, which reciprocates a parent axis and a child axis according to a predetermined synchronization ratio by multi-axis synchronization control, is provided with a command decoding unit configured to decode a command including a plurality of command blocks, a distribution processing unit configured to generate a distribution movement amount, which is an amount of movement for each control period of a motor, based on the command blocks, an end-point correction unit configured to perform first correction processing for correcting the distribution movement amount so that a feedback position of the child axis reaches an end point, which is a turning point of the reciprocating motion, and second correction processing for recovering synchronization destroyed by the first correction processing, and a motor control unit configured to drivingly control the motor based on the corrected distribution movement amount.