A machining program creating device for a wire electric discharge machine creates a machining program for machining a keyway on the side surface of a round hole in a workpiece, based on a previously specified diameter of the round hole, a center position of the round hole measured by bringing a wire electrode into contact with the workpiece, and a previously defined shape of the keyway.

A coordinate measuring machine revises its original measurement trajectory, prior to completing its measurement of a work piece, upon detecting misalignment between its original measurement trajectory and the orientation of the work piece.

Systems and methods are disclosed for automated inspection and part enrollment. In one implementation, a selection of an area of a part is received within a graphical user interface depicting a representation of the part. Based on the selection of the area of the part, a location of the selected area is determined. Image capture parameter(s) are determined based on the determined location. Based on (a) the determined image capture parameters and (b) the location of the selected area, an inspection path is computed with respect to the part. The computed inspection path is executed with respect to the part via an inspection system.

A control apparatus for controlling a machine tool on the basis of a machining program is provided with: a storage unit which stores an inspection item list for a workpiece, said inspection item list being associated with the machining program; and a display unit which, when the machining program is executed, displays the stored inspection items associated with the machining program.

A method and apparatus for measuring an object using a CMM receives nominal geometry data relating to the object, and produces a set-up path based on the received nominal geometry data. The method also conducts a set-up measurement of the object using a CMM probe. The CMM probe conducts the set-up measurement by following the set-up path, and the set-up measurement of the object produces scan path information. The method generates a scan path using the scan path information, and controls the CMM probe to conduct a fine measurement of the object by causing the CMM probe to move along the generated scan path.

A coordinate measuring machine revises its original measurement trajectory, prior to completing its measurement of a work piece, upon detecting misalignment between its original measurement trajectory and the orientation of the work piece.

A method for nominal scanning measurement includes allowing a user to select a shape of an object to be measured from a geometric shape menu prepared in advance, allowing the user to input, according to the selected geometric shape, a parameter to specify the geometric shape, allowing the user to select a measurement path from a measurement path menu prepared in advance, allowing the user to input, according to the selected measurement path, a parameter to specify the measurement path, calculating, based on the selected geometric shape, the input parameter of the geometric shape, the selected measurement path, and the input parameter of the measurement path, measurement points on a workpiece and a normal line direction at each of measurement points using a calculation formula prepared in advance, and calculating a path for scanning measurement to move while scanning a sequence of the measurement points.

Systems and methods are disclosed for automated inspection and part enrollment. In one implementation, a selection of an area of a part is received within a graphical user interface depicting a representation of the part. Based on the selection of the area of the part, a location of the selected area is determined. Image capture parameter(s) are determined based on the determined location. Based on (a) the determined image capture parameters and (b) the location of the selected area, an inspection path is computed with respect to the part. The computed inspection path is executed with respect to the part via an inspection system.