DE102013018569B4 - Apparatus and method for measuring at least partially reflective surfaces - Google Patents

Abstract

Device for measuring at least partially reflecting surfaces of a measurement object (1) located on a positioning unit, which has at least one illumination unit (2) and at least one observation unit (3), characterized in that the positioning unit with the measurement object (1) in one of a hollow body (4), wherein the hollow body (4) has at least one opening for passing a structured illumination beam from the illumination unit (2), the inner and outer hollow body surfaces (4a, 4b) are at least semitransparent, and the observation unit (3) the hollow body (4) is directed.

Description

The present invention relates to an apparatus and a method for optical shape detection glossy smooth freeform surfaces, with which even freeform optics with large inclinations can be absolutely measured and their surface can be reconstructed. The invention is based on the principle of raster reflectometry, in which at least one light pattern is reflected by the at least partially reflecting surface to be examined and is propagated back in space with the aid of a three-dimensional observation unit. The inventive solution presented here can also be used in particular for the simultaneous measurement and reconstruction of the front and rear optically smooth surfaces of a transparent measurement object.

Surfaces with a roughness far below the wavelength of the light are said to be optically smooth. Optically smooth surfaces reflect or transmit incoming light in a directed manner. Examples include flat or curved mirrors, polished metal parts, glass surfaces (lenses), liquid surfaces and transitions of media with different optical refractive index. According to the invention, the object to be measured must be such that its surface when scanning with a light pattern with a diameter d within each surface part is approximately free of curvature. The surface can either be fully mirrored, such as vapor-deposited or polished surfaces (eg mirrors and sheet-metal parts) or even partially mirrored or partially reflective.

For the detection of the shape of optically smooth surfaces, there is a wide range of methods that allow a three-dimensional measurement. To test simple surface shapes, such as flat or spherical surfaces (lenses, mirrors, etc.), mainly interferometric methods are used. It proves disadvantageous that it is difficult to determine the absolute positions since a so-called 2π ambiguity occurs. In addition, the production of a free-form reference represents a major hurdle, both technologically and economically. The necessary vibration and temperature-fluctuation-free ambient conditions are further challenges in the realization of interferometric measuring systems, including a very high and cost-intensive equipment expense. For these reasons, interferometers are usually used for surface and roughness testing. As measuring methods for surface reconstruction, they are rather unsuitable [Hof07].

For more complicated shaped surfaces, such as aspheres, wavefront measurement methods, the Hartmann method, and the Shack-Hartmann test are used (eg, Patent US 7,525,076 B1 ). There, a so-called differential Shack-Hartmann curvature sensor is used to measure a curvature including major curvatures and slopes of a wavefront. However, surfaces with large areas, inclinations or curvatures can not be measured (limited by the size of the imaging optics and / or microlens arrays). In addition, there are limitations with regard to the measurable height difference in the surface profile and the lateral resolution.

Furthermore, in various patents and scientific papers a confocal surface scanning is proposed (eg DE 197 49 974 C2 . DE 10 2005 043 627 A1 ). The disadvantage here is the complicated adjustment of the structure. In addition, these methods are not suitable for surfaces with large inclinations.

Other methods measure a grating pattern which is reflected or transmitted at the specular surface. Depending on their shape, the grid appears more or less deformed. These methods can be summarized under the bullet point of the deflectometric method. Numerous patents and publications have been published (eg WO 97/40367 A1 . WO 2005/031251 A1 . WO 01/23833 A1 . US 2008/0225303 A1 . US 4,912,336 A , [Zha05], [Yam07] and [Seß09]). However, the deflektometric methods are always ambiguous without additional expenditure on software and hardware. The relationship between observation directions and observed monitor points is determined by surface normals, where there are infinitely many hypothetical normals along each line of sight that would lead to the same measurement result. Thus one observes the tangent spaces of hypothetical surfaces [Roz07]. However, these problems can be solved by the so-called stereodeflectometry. Several light sources and several observation units are used at the same time, which in turn leads to a large calibration effort. These methods are not suitable for surfaces with large slopes.

A scanning method using the grid reflection method is explained in the article of [Bey97]. In order to describe the surface geometry, underdetermined systems of differential equations have to be solved, which can lead to an increased measurement uncertainty. Based on this model assumption, the method can not be used reliably and unambiguously for the measurement of complex measurement objects of unknown geometry. Likewise in the DE 10 2005 007 244 A1 one Rectangle reflection method is presented with a lighting pattern that enables the shape detection of reflective surfaces. However, it is not suitable for measuring objects with strongly curved surfaces, since not all reflected rays hit the diffuse screen used. For this, this method has a very limited lateral resolution.

In the DE 10 2006 033 779 B4 Another method for measuring the shape of specular surfaces is proposed. The sample surface is scanned with the laser beam guided by a deflection mirror. The reflected beam from the reflecting surface meets two successive projection screens, with the front part being transparent. The position and inclination of the scanned measuring point on the surface are determined by two projections of the reflected beam on both projection screens. However, since the projection screens have physically limited dimensions, the dynamic tilt range of the surface under test is limited. In addition, the determination of the exact position of the deflection mirror is mechanically difficult. In addition, only a single surface can be scanned with this method.

Ray-tracing methods with a fine scanning laser beam are also known from the prior art (see, for example, [Häu88] or [Mor00]). Due to the limitation of the size of the mirrors, lenses and beam splitters used, these methods are also not suitable for measuring objects with large inclinations.

In addition, the use of three-dimensional umbrellas in the literature and in various patents (eg US 5,912,741 A and US 5,241,369 A ) for light scattering method described. But they are not yet used for the absolute shape measurement of surfaces.

Object of the present invention is therefore to overcome the disadvantages of the prior art and to provide a device and a method with which it is possible to detect the absolute topography of at least partially reflecting surfaces without contact, wherein the surface to be measured in particular aspherical or is formed as a freeform and may have large inclinations or strong bends. At the same time, the method according to the invention is intended to realize a high measuring resolution with the lowest possible costs.

According to the invention this object is achieved on the device side with the features of the first claim and the method side with the features of the eighth claim. Preferred further embodiments of the device according to the invention are characterized in the dependent claims 2 to 7, while a preferred further embodiment of the method according to the invention is specified in the patent claim 9.

Details and advantages of the invention will become apparent from the following description part, in which the invention with reference to the accompanying drawings is explained in more detail. It shows:

1 - A schematic diagram of the device according to the invention

2 - A first embodiment of the illumination of the surface to be measured

3 - A second embodiment of the illumination of the surface to be measured

4 - A third embodiment of the illumination of the surface to be measured

5 - Different embodiments of a cavity forming a hollow body

6 - Section of the device according to the invention with a multilayer hollow body

7 - Section of a structured surface of the hollow body

8th - Partial view of the hollow body with fluorescent coating of its inner and outer surfaces

9 - Partial view of the hollow body with microstructures and microlenses

10 - Schematic representation for the simultaneous measurement of several surfaces of a transparent object to be measured

Described below are an apparatus and a method for the simultaneous, calibration-free, non-contact and absolute optical determination of the 3D coordinates of reflecting surfaces. These surfaces can also have strong inclinations, whereby a light pattern (Gaussian beam, several juxtaposed Gaussian beams, lines, different symmetrical and non-symmetrical light forms together or alone) is used for optical scanning. The surfaces can be either fully mirrored, partially mirrored or partially reflective, such. As polished or sufficiently smooth surfaces, transparent media (for example, glass surfaces), liquid surfaces or transitions of media with different optical refractive index. The A measuring object having such a surface is referred to as a measuring object hereinafter. The device according to the invention consists of at least one illumination unit ( 2 ), a high-precision xy positioning unit, on which the measuring object ( 1 ) and at least one observation unit ( 3 ), which has a three-dimensional screen ( 4 ) and at least one optical sensor (CCD or CMOS camera) with or without optical imaging systems. The three-dimensional screen ( 4 ) is formed as a cavity forming a hollow body, wherein according to the invention the xy positioning unit with the measurement object (see FIG. 1 ) is arranged in the cavity. Accordingly, the measurement object ( 1 ) with its surfaces to be measured by the three-dimensional screen ( 4 ). The three-dimensional screen (hollow body) ( 4 ) has one or more small openings. Through these openings, according to the invention, a light pattern in the direction of the measurement object (FIG. 1 ). The light pattern is reflected by the surface and hits the screen ( 4 ), wherein a portion of the reflected light directly on the first (inner) surface of the screen ( 4a ) is made visible. The remaining portion is further transmitted through the hollow body wall and only on the second (outer) surface of the screen ( 4b ) made visible. (please refer 1 ). According to the proposed method according to the invention, the course of a light pattern reflected on the measurement object is traced back in the measurement space. From the intersections of the scanning and reflected beams and the position of the reflected beams on the inner and outer surfaces of the three-dimensional screen ( 4 ) of the observation unit ( 3 ), the surface normal of the surface segments of the measurement object ( 1 ) and determine the absolute position of the scanned partial area in the room. From these data and by means of a created reconstruction algorithm, the surface shape of the entire object to be measured is calculated.

The scanning of the measurement object ( 1 ) can be performed by using at least one light pattern or even multiple light patterns. The patterns may differ in both color and shape. According to the invention, the course, the position and the geometry of each scanning beam are precisely defined in the measuring space on the basis of a pre-calibration. With the help of optical components z. B. diffraction optical beam splitter, -former (DOEs), lenses, achromats, or free-form optics, the divergence of the beam can be minimized so that a high depth of focus is achieved. The scanning can be performed at any position and angle in the measuring room (see 2 . 3 and 4 ).

The measuring object to be measured ( 1 ) is scanned by the light patterns described above, the reflected beam being directed onto the three-dimensional screen ( 4 ) meets.

This screen covers the 3D half space above the measurement object ( 1 ). It can be in the shape of a hemisphere or pyramid or as a combination of different geometric shapes (see 5 ). This screen can be made of different light or semi-permeable materials, eg. As glass, PMMA, are manufactured. In a preferred embodiment, it may consist of several transparent or partially transparent layers, each layer having the same or different refractive indices (see 6 ).

In a further embodiment of the invention, the surfaces of the three-dimensional screen ( 4a . 4b ) be structured. These structural elements ( 6 ) the light on the surfaces of the screen ( 4a . 4b ) so that some of the light on the first surface ( 4a ) and the rest of the light (between the structural elements ( 6 ) meets unscrupulous propagated in the hollow body wall, taking into account the law of refraction. These structural elements ( 6 ) may be micro, nano or macrostructures. They can have different geometrical shapes and can be produced using different technologies (eg lithographic, chemical or mechanical processes). However, the distances d between two neighboring structural elements ( 6 ) should not be larger than the diameter D of the light pattern. Thus, the position of the beam on the surface is always visible and thus the center of gravity of the light spot positions can be accurately determined with the help of the camera used (see 7 ). The outer (second) surface of the screen ( 4b ) can be completely matt, but can also be provided with the previously described possible structuring.

Furthermore, it is within the scope of the invention that one or both (or more) surfaces of the three-dimensional screen ( 4a . 4b ) with fluorescence materials ( 7 ), whereby the light spots on both (or more) surfaces have different intensities and colors. As a result, the beam path between the two (or more) surfaces can be determined exactly with a color camera. (please refer 8th ). This is particularly advantageous in the measurement of strongly curved surfaces, in which an overlap of the two light spots on the observation unit occurs.

In a further embodiment of the device according to the invention, the inner surface of the three-dimensional screen ( 4a ) as a combination of microlenses ( 8th ) and already mentioned microstructure elements ( 6 ) (see 9 ), wherein the distance between the inner and outer surface of the screen ( 4a . 4b ) (Hollow body wall) of the focal length of the microlenses ( 8th ) corresponds. The goal of using microlenses ( 8th ) is a possible focusing of the transmitted beam on the second (outer) surface of the three-dimensional screen ( 4b ). Thus, one or more focus points are observed on the outer surface, resulting in a better recognition of the center of gravity of the light spot on the outer surface. This position is also dependent on the angle of incidence of the light on the microlenses ( 8th ) dependent. As a result, the object to be measured ( 1 ) reflected beam can be traced more accurately. A combination of microlenses ( 8th ) with nano, micro or macrostructure elements ( 6 ) and fluorescent layers ( 7 ) is also possible.

The on the surfaces of the three-dimensional screen ( 4a . 4b ) are recorded directly with a detector. With a lens or other suitable optical components, the light spots can also be deposited on a storage unit of the detector.

In order to be able to observe the complete screen surfaces at the same time, according to the invention one or more detectors which can record both individual pictures and video films are used. With these detectors, the position of the screen in the measuring space is precisely determined after a pre-calibration. For this purpose, visible markings are applied on the inner and outer screens, with which the position of the reflected beam on the screen is better classified in the measuring space.

The evaluation of the data obtained takes place in a computer unit with a suitable software, so that at any time the focus of the two light spots and their positions can be determined in the measuring room. With the determined focal points of the light spots on the inner and outer surfaces of the three-dimensional screen and the additional knowledge about the geometry and the position in the measurement space as well as the material properties (eg refractive index, etc.) of the observation unit, a backpropagation of the reflected beam in the measurement space calculated.

By calculating the crossing points of the course of the reflected beam and the stored course of the scanning light patterns, the absolute position S (x; y; z) of the scanned portion of the measuring object in the measuring space, as well as its local inclination, can be determined with high accuracy.

With the device according to the invention and the associated method, a specular or partially mirrored object to be measured without prior knowledge of its surface even with a highly curved surface, as defined above, absolute and with high accuracy. With the observation unit according to the invention a virtually unlimited measurement of targets with surfaces with strong inclinations is possible. The measured object to be measured can be placed in the measuring room without further presetting. The course of the scanning beam from the illumination unit in the measuring space is known based on a pre-calibration of the illumination unit with the observation unit. It can be carried out before final assembly. Additional calibration measures are no longer required. During the actual measurement, the observation unit and / or the illumination unit remains stationary, however, the measurement object located on the high-precision x-y positioning unit must be moved along the x and y axes, whereby a positioning accuracy in the micron range can be ensured. In order to be able to measure any inclination of the measurement object, according to the invention a three-dimensional projection screen is used, with which all reflected rays in the cavity are detected.

Another aspect of the present invention is its use for the simultaneous measurement of multiple (front and back) optically smooth surfaces of a transparent target (e.g., lenses, free-form optical parts). This is achieved by the use of the back reflection of the incident on the rear surface of the measurement object scanning beam, which is a disturbing factor in the known from the prior art method (s. 10 ).

Simultaneous measurement of the front and back surfaces of a transparent object to be measured ( 1a . 1b ) can be realized by the acquisition of two reflected beams, wherein a first part of the scanning beam directly from the front surface of the transparent measuring object ( 1a ) and the remaining, second part of the scanning beam on the front surface of the transparent measuring object ( 1a ), then on the rear surface of the transparent measurement object ( 1b ) and then on the front surface of the transparent measuring object ( 1a ) is broken again. The determination of the shape of the front and rear surfaces of the transparent object to be measured ( 1a . 1b ) takes place as follows: The incident beam, the transparent measuring object ( 1 ) is scanned to a part on the front surface of the transparent measurement object ( 1a ) and broken to the other part (s. 10 , Point c). The reflected portion of the scanning beam strikes at point b directly on the first (inner) surface of the three-dimensional observation screen ( 4a ) is refracted there and hits the second (outer) surface of the three-dimensional observation screen at point a ( 4b ). The at point c on the front surface of the measurement object ( 1a ) broken beam component passes through the test object ( 1 ) through to its rear surface ( 1b ) (Point d), where it is again reflected and finally at the point e of the front surface of the measurement object ( 1a ). There it is again broken and arrives at the point f on the first (inner) surface of the three-dimensional observation screen ( 4a ). At this point it is refracted again and hits the second (outer) surface of the observation screen at point g ( 4b ). A color camera simultaneously records all four points (a, b, f, and g) on the three-dimensional observation screen ( 4 ). The assignment of the origins of the points is ensured by a spectral division and intensity distribution, wherein one or both surfaces of the observation screen ( 4 ) with different fluorescent media ( 7 ) are coated. As a result, the pairs of points b and f and a and g appear in different colors and can be assigned by detecting their very different intensity. (Intensity at point a is greater than at point g, intensity at point b is greater than at point f). In a memory unit, all coordinates of the three-dimensional observation screen ( 4 ) visible points a, b, f and g stored. The height z and the increase of the front surface facets of the measurement object ( 1 ) are determined by ray tracing using points a and b. Due to the lateral scanning, these individual facets can form an entire front surface of the measurement object (FIG. 1a ) Are joined together. The height z and the increase in the surface facets of the rear side of the measurement object are determined by ray tracing, starting from the points g and f, by determining the intersection point d with the ray of the corresponding point pair a and b. The basis for this method is the knowledge of the refractive index of the measurement object and its homogeneity. The entire rear surface of the measurement object is also determined by lateral scanning along the x and y axes.

LIST OF REFERENCE NUMBERS

1

measurement object

1a

front surface of a transparent measuring object

1b

rear surface of a transparent measuring object

2

lighting unit

3

observation unit

4

Hollow body (three-dimensional screen)

4a

first (inner) surface of the three-dimensional screen

4b

second (outer) surface of the three-dimensional screen

5

lighting point

6

structural element

7

fluorescent layer

8th

microlens

• [Hof07] - Hoffmann, Jörg: Handbuch der Messtechnik: With 93 tables. 3. Munich: Hanser, 2007. - ISBN 9783446407503
• [Zha05] - S. Zhang: High-resolution, Real-time 3-D Shape Measurement. Dissertation, Stony Brook University, Stony Brook, NY, 2005.
• [Yam07] - M. Yamazaki, S. Iwata and G. Xu: "Dense 3D Reconstruction of Specular and Transparent Objects Using Stereo Cameras and Phase-Shift Method". ACCV 2007, Part II, LNCS 4844 pp. 570-579, 2007.
• [Seß09] - R. Sessner: Direction-coded deflectometry by telecentricity. Dissertation, University Erlangen-Nürnberg, 2009.
• [Roz07] - S. Rozenfeld, I. Shimshoni and M. Lindenbaum: Dense mirroring surface recovery from 1D homographies and sparse correspondences. In: IEEE Conference on Computer Vision and Pattern Recognition, 2007.
• [Bey97] - J. Beyerer and D. Perard "Automatic Inspection of Reflecting Freeform Surfaces Based on Grid Reflections", Technisches Messen 64, 1997 1O, pages 394 to 400
• [Häu88] - G. Häusler, G. Schneider: Testing optics by experimental ray tracing with a lateral effect photodiode, in: Applied Optics, Vol. 27, no. 24, 1988, pp. 5160-5164
• [Mor00] - E. Moreno-Barriuso, R. Navarro, "Laser Ray Tracing versus Hartmann Shack sensor for measuring optical aberrations in the human eye." J. Opt. Soc. At the. A, vol. 17, i. 6, p. 974 (2000)

Claims (10)

Device for measuring at least partially reflecting surfaces of a measuring object located on a positioning unit ( 1 ), the at least one lighting unit ( 2 ) and at least one observation unit ( 3 ), characterized in that the positioning unit with the measurement object ( 1 ) in one of a hollow body ( 4 ) is arranged, wherein the hollow body ( 4 ) at least one opening for passing a structured illumination beam from the illumination unit ( 2 ), the inner and outer Hollow body surface ( 4a . 4b ) is at least semitransparent and the observation unit ( 3 ) on the hollow body ( 4 ). Apparatus according to claim 1, characterized in that the inner and / or outer hollow body surface ( 4a . 4b ) has a semicircular or semi-polygonal cross-section. Device according to one of claims 1 to 2, characterized in that the inner and / or outer hollow body surface ( 4a . 4b ) are structured macro-, micro- or nanostructured, wherein the distances between adjacent structural elements ( 6 ) are not larger than the diameter of the illumination beam. Apparatus according to claim 3, characterized in that on the inner hollow body surface ( 4a ) Microlenses ( 8th ) whose focal length is the distance between the inner and outer hollow body surface ( 4a . 4b ) corresponds. Device according to one of claims 1 to 4, characterized in that the inner and / or outer hollow body surface ( 4a . 4b ) with fluorescence material ( 7 ) are coated. Device according to one of claims 1 to 5, characterized in that the inner and / or outer hollow body surfaces ( 4a . 4b ) a combination of microlenses ( 8th ), Structural elements ( 6 ) and fluorescent layers ( 7 ) exhibit. Device according to one of claims 1 to 6, characterized in that the hollow body ( 4 ) is formed multi-layered, wherein the individual layers have the same or different refractive indices. Method for measuring at least partially reflecting surfaces of a measuring object located on a positioning unit ( 1 ) with a device according to one of claims 1 to 7, characterized in that the structured illumination beam through the at least one opening in the hollow body ( 4 ) impinges on an at least partially reflecting surface of the measurement object, from there onto the inner and outer hollow body surface ( 4a . 4b ) and made visible and from the determined coordinates of the illumination points ( 5 ) on the inner and outer hollow body surface ( 4a . 4b ) the at least partially reflective surfaces of the measurement object ( 1 ) by changing the position of the measurement object ( 1 ) are reconstructed point by point during the measurement. Method according to claim 8, characterized in that the coordinates of the illumination points ( 5 ) on the inner and outer hollow body surface ( 4a . 4b ) with several detector units ( 3 ) be determined. Use of a device according to one of claims 1 to 7 for simultaneous measurement of a plurality of optically smooth surfaces of a transparent test object ( 1 ).

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