DE3428593C2 - - Google Patents

Description

The invention relates to an optical surface measurement advises (Profilometer) in the generic term of the patent Proof 1 described type.

In addition to their macroscopic shape, mechanical surfaces are characterized by the state of finishing, which is indicated by roughness values (finishing). Many of the functional properties of the finished part are related to this fine machining. It is expressed by a number of parameters, for example R _a , rms , the autocorrelation function, the Fourier spectrum and others. These values can be determined by integrated measurements on surface areas or derived from knowledge of the three-dimensional topography of the surface.

The one for the reconstruction of the three-dimensional topogra Devices used record the surface in Reality along linear sections and thus deliver a height profile from which the desired parameters who extrapolates based on statistical criteria that can. Preserves the true three-dimensional profile one by scanning along parallel sections. The are various devices used for this purpose principally through the sensitivity, the lateral  Resolution and the measuring interval marked.

The measurement of interest in mechanical applications strument usually ranges from fractions of a mi kron up to a few dozen microns.

In addition to devices that use the Moir´ technology or the Pro use fringe or lines and the Perform surface measurements up to a limit that less than a few microns exist for the area mechanically of interest, two families of devices, namely the devices working with stylus needles and the optical profilometer.

The devices working with scanning needles are very ver spreads. Your vertical resolution is in the sizes order of about 10 Å, while the lateral resolution is a few microns.

Optical surface measuring devices (profilometers) are devices for non-contact measurement. The achievable resolution is a fraction of a micron vertically and approximately one micron in the lateral direction. There are also well-bred optical (superimposition and interferometric) profilometers with higher resolution known, cf. For this:
GE Sommargren, Applied Optics, Vol. 20, No. 4 (1981), pp, 610-618;
JE Wyant, Laser Focus, May 1982, pp. 65-71;
JM Bennet, Applied Optics, Vol. 15, No. 11 (1976), pp. 2705-2721.

An optical surface measuring device of the generic type is known from FR-PS 15 34 762. With this device it is however, the lens optics required during the measurement to shift so that the focal point is the lower altitude the measuring surface is tracked. It follows thereby a time-consuming and error-prone measurement process.  

From DE-OS 14 73 780 is an optical surface measurement device known in which a fo on the measuring surface kissed bundle of rays only from two by means of filters filtered out color components, e.g. B. there is red and green, the two dis one behind the other in the beam direction Form focal points. The reflected light will two receptors selectively sensitive to the color components gladly fed, and from the intensity ratio of The position of the measuring surface becomes the two receiver signals determined relative to the focal points. This is true no movement of the measuring device or the measuring surface required during measurement, however the device is relatively faint due to the use of color filters, and since the measuring surface is normally between the two the focal point is in particular the side Resolution very limited.

From IBM Technical Disclosure Bulletin Vol. 16, No. 2, July 1973, pp. 433-434 is an optical surface measurement device known, in which two coaxial measuring beams with different pulse identification are checked, in two Beam direction of successive focal points fo be kissed. From the reflecting from the measuring surface th light are transmitted to the receiver by means of a closed logic circuit the intensities of through different marked pulse components determined and thereby the position of the measuring surface relative determined to the focal points. Here too is the lateral Resolution is not optimal and it becomes a moving part, namely the chopper disc, needed.

The invention has for its object a without moving Liche parts working optical surface measuring device specified type, which with simple construction, high light intensity and good lateral resolution the con Continuous and quantitative recording of altitude levels allow different measurement surface.  

The achievement of the object is in the pronounced 1. The subclaims relate on further advantageous refinements.

Through the inventive idea, by means of longitudinal dis persion of the measuring beam a continuous sequence of To generate focal points along the beam axis, and through transverse dispersion of the reflected light beam each of these focal points a focal point at the receiver clearly assign, the advantage is achieved that simply query the get the reflection maximum the location of the measurement surface relative to the receiver be quantitative to the focal points of the measuring beam can be voted. The device does not require any moving Parts, except possibly means for moving the measuring surface if several areas are to be measured. Since the spectral is mainly used for the measurement contributes to the part of the measuring beam, in its focal point the measuring surface is also a very good la receive teral resolution.

An embodiment of the invention is based on the Drawing explained in more detail.  

Fig. 1 shows a schematic representation of a profilometer according to the prior art.

Fig. 2 shows a schematic representation of a professional lometer according to the invention.

The principle of operation of a conventional profilometer is illustrated in FIG. 1: 1 denotes a monochromatic light source whose rays are bundled and thus run parallel. The beams hit a beam splitter 3 and pass through this to a first objective 5 . This concentrates the light on the surface of the test sample 7 . The lens 5 is movable in the direction of the arrow. The re reflected light penetrates through the lens 5 again , is deflected by the beam splitter 3 to a second lens 9 and is concentrated by this on an arranged in front of a receiver 13 aperture 11 .

The signal of the receiver 13 has a maximum when the surface of the pattern is in the focusing plane of the lens 5 . The Kon time shown is based - as mentioned - on a conventional solution, in which the lens 5 reciprocates in the axial direction and the signal is recorded in the correct phase.

A similar scheme is used in the device according to the invention, but using a sequence of focusing points in the direction of the axis, which are differentiated by the wavelength. This is shown schematically in FIG. 2. The sequence of different focusing points in the longitudinal direction results from the use of polychromatic instead of monochromatic light. All components with the exception of the sample to be tested are stationary. In the axial direction, there are several focussing points that are reversibly and clearly related to a wavelength. The corresponding signals are then passed on to a receiver formed by a row of photodiodes, taking advantage of the properties of the different wavelengths in la teral division. The sequential scanning of the photodiodes provides a maximum that corresponds to the position of the surface of the test pattern relative to the objective.

In FIG. 2 is a functional diagram of the device shown according to the invention. With 21 a polychromatic light source is designated, which is converted by means of an achromatic collimator 23 into a bundle of parallel beams. The collimated polychromatic beam passes through the beam splitter 25 and a longitudinal dispersion and focusing device 27 . As a result, a number of focusing points F 1 to FN form in the area of the pattern 29 to be analyzed, each of which belongs to a specific wavelength, ie to a different monochromatic light. The reflected light again penetrates the dispersion and focusing device 27 and is deflected by the beam splitter 25 to an angle dispersion and focusing device 31 . The beam components broken down into angles are focused along the row 33 of photodiodes, which is connected to an electronic evaluation device 35 . The light source 21 is advantageously delimited by an aperture 37 which is formed by a slot which is arranged at right angles to the direction in which the dispersion takes place, and thus at right angles to the row of photodiodes 33 .

The measuring range is determined by the longitudinal dispersion and determined by the focusing properties. The Angular dispersion and the properties of the second Fo Kissing device are used with the recipient to reconcile. The sensitivity and the lateral resolution depend on the same parameters.

The longitudinal dispersion and focusing device 27 may include two separate components for achieving the longitudinal dispersion effect and the focusing: a simple lens 27 A , which serves as a dispersion device, and a microscope objective 27 B. Alternatively, the dispersion element can also be integrated in the collimator lens or in the focusing lens in the form of a suitable optical unit.

The angle dispersion and focusing device 31 can also contain two elements: the first of these elements can be a prism or a grating, while the second can be formed by a corrected lens.

The light source 21 may be a white light lamp with condenser and slot. The slot simplifies the alignment and extends the possible application of the device to strip-wise scanning (in the manner of a tomography) of entire sections of the measuring surface when using a photodiode matrix as the receiver.

A suitable information is provided when using the device tion processing program.

The signals of the different photodiodes can be for the differential measurement of smallest shifts insert a predetermined position that one specific position of a unique distribution function (Signal peak, curve center, etc.) can be assigned.

Claims (4)

1. Optical surface measuring device with a focus on the lens optics, which focuses a beam generated by a light source onto the measurement surface, and with a beam splitter, which reflects the light from the measurement surface and is deflected by the lens optics onto a receiver optics, which deflects the beams focused a receiver, characterized in that
that the beam is polychromatic,
that the objective optical system (27) includes a longitudinally farbdis pergierendes element (27 A) and generates a sequence of kontinuier Liche lying along the optical axis focal points (F _1, F _N) of the individual wavelengths,
that the receiver optics ( 31 ) contains a color-dispersing element in the transverse direction and on the receiver ( 33 ) generates a continuous sequence of focal points of the individual wavelengths lying next to one another, and
that the receiver ( 33 ) has a multiplicity of photodiodes arranged next to one another and an electronic evaluation device ( 35 ) for determining the photodiode receiving the maximum radiation intensity. 2. Surface measuring device according to claim 1, characterized in that the light source is perpendicular to the deflection plane of the reflected beam de slit diaphragm ( 21 ). 3. Surface measuring device according to claim 1, characterized in that the electronic evaluation device ( 35 ) scans the photodiodes sequentially. 4. Surface measuring device according to claim 1, characterized in that the receiver ( 33 ) has a two-dimensional photodiode matrix.