A method for measuring a rotation center of a multi-axis processing machine 100 includes: using reference ball 8 and a measurement device 7 which has a probe 71 and measures, as a measurement value 72, a movement amount of the probe 71 when the reference ball 8 contacts the probe 71; executing a measurement process of rotating the rotation axis to measure the measurement value 72 in a state in which the reference ball 8 installed to one of the processing head 2 and the table 62, 63 contacts the probe 71 of the measurement device 71 installed to another of the processing head 2 and the table 62, 63; and executing a rotation center calculation process of calculating a rotation center of the rotation axis from the measurement value 72, a rotation angle of the rotation axis, and a position of a center of the reference ball 8.

An apparatus to assist a machinist in the setup of a remote computer controlled machine tool table has an X-axis electronic gauge block assembly, a Y-axis electronic gauge block assembly, and a Z-axis electronic gauge block assembly each positioned on the machine tool table, to respectively collect X-axis probe position values, Y-axis probe position values, and Z-axis probe position values. Environmental sensors collect environmental values. An electronics processing system establishes a raw X-axis probe position, a raw Y-axis probe position, and a raw Z-axis probe position. A wireless interface transmits the environmental values, the raw X-axis probe position value, the raw Y-axis probe position value, and the raw Z-axis probe position value to the remote computer and receives from the remote computer refined probe position values to assist the machinist in the setup of the machine tool table.

In one embodiment there is a computer numerical control machine implementing a method for measuring and digitizing a cylinder head combustion chamber using a touch probe, wherein the cylinder head combustion chamber includes an intake valve and an exhaust valve. The method includes receiving combustion chamber characteristics of the cylinder head combustion chamber. The method includes receiving probe measurement variables that describe how the touch probe measures the cylinder head combustion chamber. The method includes generating probe measurement lines for each portion of the cylinder head combustion chamber using the combustion chamber characteristics and the probe measurement variables. The method includes measuring, using the touch probe, probe measurement planes for each portion of the cylinder head combustion chamber using the probe measurement lines to generate probe measurements. The method includes digitizing the probe measurement planes for each portion of the cylinder head combustion chamber using the probe measurements.

A method for using a geometrical probe (5) with a spindle (3) of a machine tool (1), wherein a probe fetch waiting state of the machine tool (1), at least one temperature parameter related to a temperature of the spindle (3) of the machine tool (1) is determined by measuring at least one temperature value for the spindle (3), and time for fetching the geometrical probe (5) is determined depending on the at least one temperature parameter.

In one embodiment there is a computer numerical control machine implementing a method for measuring and digitizing a cylinder head combustion chamber using a touch probe, wherein the cylinder head combustion chamber includes an intake valve and an exhaust valve. The method includes receiving combustion chamber characteristics of the cylinder head combustion chamber. The method includes receiving probe measurement variables that describe how the touch probe measures the cylinder head combustion chamber. The method includes generating probe measurement lines for each portion of the cylinder head combustion chamber using the combustion chamber characteristics and the probe measurement variables. The method includes measuring, using the touch probe, probe measurement planes for each portion of the cylinder head combustion chamber using the probe measurement lines to generate probe measurements. The method includes digitizing the probe measurement planes for each portion of the cylinder head combustion chamber using the probe measurements.

In one embodiment there is a computer numerical control machine implementing a method for measuring and digitizing a cylinder head combustion chamber using a touch probe, wherein the cylinder head combustion chamber includes an intake valve and an exhaust valve. The method includes receiving combustion chamber characteristics of the cylinder head combustion chamber. The method includes receiving probe measurement variables that describe how the touch probe measures the cylinder head combustion chamber. The method includes generating probe measurement lines for each portion of the cylinder head combustion chamber using the combustion chamber characteristics and the probe measurement variables. The method includes measuring, using the touch probe, probe measurement planes for each portion of the cylinder head combustion chamber using the probe measurement lines to generate probe measurements. The method includes digitizing the probe measurement planes for each portion of the cylinder head combustion chamber using the probe measurements.

A probe displacement command in a scanning measurement is generated according to a composite speed vector V:
V=Gf.Math.Vf+Ge.Math.Ve+sp(p).Math.Gc.Math.Vc2 wherein Vf is a vector along which a probe is displaced along a scanning path, Ve is a vector maintaining a deflection amount of the probe toward a work piece at a standard deflection amount. Vc2 is represented by (Vc1.Math.q)q, Vc1 is a vector in a direction correcting a probe position such that a stylus tip is oriented along a scanning course, q is a vector given by a vector product of the normal line of a surface of the work piece and Vf, The normal direction of a measured surface is designated as Nw, p is a scalar product of Vc2 and Nw, and sg(p) is a function returning +1 or 1 in accordance with a value of p.

A method is described for measuring an object using a machine tool and a scanning probe. The scanning probe is driven along a scan path relative to the object whilst the scanning probe acquires probe data describing a series of positions on the surface of the object relative to the scanning probe. The scan path includes at least a first scan path segment for producing probe data that can be analysed to measure the object. The scan path is also arranged to impart a plurality of identifiable probe motions to the scanning probe that can be identified from the acquired probe data alone. Each identifiable probe motion is used to define a time stamp. This allows the probe data to be tied to commanded or nominal positions around the scan path.

A method for using a geometrical probe (5) with a spindle (3) of a machine tool (1), wherein a probe fetch waiting state of the machine tool (1), at least one temperature parameter related to a temperature of the spindle (3) of the machine tool (1) is determined by measuring at least one temperature value for the spindle (3), and time for fetching the geometrical probe (5) is determined depending on the at least one temperature parameter.

A method and apparatus for measuring a part with a contact probe mounted on a coordinate positioning machine. The method includes measuring a plurality of points on the part when both the part and contact probe are moving continuously between different positions within the coordinate positioning machine. The probe moves, relative to the part, along a scan path such that substantially coincident points that are closely located together along a curve or surface being measured are measured at relatively far apart positions in the machine and at relatively far apart positions along the scan path.