A method of altering a rate of executing a motion plan by a computer-numerically-controlled machine can include: receiving, at a control unit of a computer-numerically-controlled machine and from a general purpose computer that is housed separately from the computer-numerically-controlled machine, a motion plan defining operations for causing movement of a moveable component of the computer-numerically-controlled machine; and altering, in response to a command received at the computer-numerically-controlled machine, a first execution rate of the operations to a second execution rate of the operations to change a rate of movement of the movable component. Systems and articles of manufacture, including computer program products, are also provided.

A method of altering a rate of executing a motion plan by a computer-numerically-controlled machine can include: receiving, at a control unit of a computer-numerically-controlled machine and from a general purpose computer that is housed separately from the computer-numerically-controlled machine, a motion plan defining operations for causing movement of a moveable component of the computer-numerically-controlled machine; and altering, in response to a command received at the computer-numerically-controlled machine, a first execution rate of the operations to a second execution rate of the operations to change a rate of movement of the movable component. Systems and articles of manufacture, including computer program products, are also provided.

A method and a trajectory generator are provided which automatically generate a trajectory, which is converted into control signals (sd) for the purpose of controlling a drive system. The control signals (sd) are used to control actuators of the drive system to carry out the movement according to the calculated trajectory. The method is implemented on a microcontroller (μC) and has a very short runtime and a low memory requirement.

A method of altering a rate of executing a motion plan by a computer-numerically-controlled machine can include: receiving, at a control unit of a computer-numerically-controlled machine and from a general purpose computer that is housed separately from the computer-numerically-controlled machine, a motion plan defining operations for causing movement of a moveable component of the computer-numerically-controlled machine; and altering, in response to a command received at the computer-numerically-controlled machine, a first execution rate of the operations to a second execution rate of the operations to change a rate of movement of the movable component. Systems and articles of manufacture, including computer program products, are also provided.

A method and a trajectory generator are provided which automatically generate a trajectory, which is converted into control signals (sd) for the purpose of controlling a drive system. The control signals (sd) are used to control actuators of the drive system to carry out the movement according to the calculated trajectory. The method is implemented on a microcontroller (C) and has a very short runtime and a low memory requirement.

A method of altering a rate of executing a motion plan by a computer-numerically-controlled machine can include: receiving, at a control unit of a computer-numerically-controlled machine and from a general purpose computer that is housed separately from the computer-numerically-controlled machine, a motion plan defining operations for causing movement of a moveable component of the computer-numerically-controlled machine; and altering, in response to a command received at the computer-numerically-controlled machine, a first execution rate of the operations to a second execution rate of the operations to change a rate of movement of the movable component. Systems and articles of manufacture, including computer program products, are also provided.

A method for machine tool motion control which determines a time-optimal motion plan for a hole tapping step preceded by an air cut step. The motion plan for the air cut step is computed so that the tapping tool arrives at the top of the hole to be tapped with the proper axial tapping feed speed and the proper tapping rotational velocity. First, time durations for the air cut step are computed for lateral and axial transit motions and for spindle acceleration under maximum-effort conditions. The longest of the time durations is then used to plan the air cut step, where the time-limiting axis motion is performed at maximum machine effort, and other axes have their motions planned to complete at the same time as the longest-duration axis. The technique is applicable to an air cut step before a tapping step or in between two tapping steps.