DE4123916C2 - Method and device for dynamic detection and classification of surface features and defects of an object - Google Patents

Description

The invention relates to a method for lighting dynamic detection and classifying surface features and defects of an object that is surrounded by a lighting sky according to claim 1 and an apparatus therefor according to claim 3.

In the essay by R. Malz: The use of fast lighting operations for robust feature extraction and segmentation in industrial object recognition and quality inspection, IT reports "Pattern recognition 1988" 10th DAGM Symposium 1988, Springer-Verlag, pages 270 to 276 is one Known lighting arrangement, which consists of four lighting modules:
A reflected light module for shadow-free illumination of diffusely scattering objects, realized with a point light source that is reflected in the observation beam path of the CCD matrix camera via a splitter mirror, a grazing light module for brightening edges and diffusely scattering surface defects, implemented by one or more ring lamps, a transmitted light module for brightening the inner surfaces and edges of object openings, and a reflection light module for uniform, reflective bright-field illumination of flat or slightly curved surfaces, consisting of an illumination array with Fresnel lens and a divider mirror.

Another lighting system is known from the same article, the with the help of a two-dimensionally deflected and electric in intensity modulated semiconductor laser during the exposure time of a single Camera image of the point, cluster, line and area that can be positioned as required generates light sources that can be changed with every image change.

Features with anisotropic scatter and reflection properties, such as edges or Scratches only deliver maximum image contrast if they come from a small space sector can be illuminated and viewed, depending on the Orientation of characteristics changes. Furthermore, lighting technology the entire solid angle will be available, because otherwise not all Features or errors can be optimally illuminated.  

Both of the lighting systems mentioned therefore do not yet meet the requirements that are placed on an inspection system with high cycle rates different in constantly changing object types and object orientations Detect and classify error types with maximum contrast.

DE 35 40 288 A1 also provides an arrangement for carrying it out of controls at solder joints, light under different Incidence angles is directed to the solder joints. Information for the three dimensional properties of the solder joints are derived in order to decide whether this condition is flawless or not. The information about the Texture can be achieved by irradiation with light from at least two places be derived from; control is based on quantitative criteria. DE 38 15 539 A1 describes a device for the automatic testing of Hollow glasses, e.g. B. bottles, known for damage in the mouth area made by illuminating this target area with several, in one the space surrounding the target area in a spherical shape this aligned light transmission lamp, the light-different wavelength send out. The same target area are in different angular positions aligned photocells, which either reflect light reflections from Normal light or from test light in the different wavelength are suitable. The fault light reflections are amplified and processed and transferred to a sorting mechanism. DE 35 34 019 C2 includes a device for optical fault detection in material webs, in which a light source illuminates an illumination pupil and an illumination optics a strip to create a strip-shaped illuminated area shaped concave illumination mirror, which over the illumination pupil maps the material web into the lens of a diode line camera.

Through US 4876455 is a solder inspection system to determine the Quality of a reflective solder joint by checking the shape of the Connection surface became known, being a series of point light swell and neighboring light reflections from the connection surface is used. The device works according to a method for lighting dynamic detection of surface features of the solder joint by is surrounded by a lighting sky within which several differences  lighting sources positioned sequentially and with specified illuminate clear angle and intensity gradation. The light from the point Light sources, which is directed to the solder joint, is emitted by the same a light-sensitive array, for example a camera on a fixed one Headed. By using different intensity values of the light of the array will be used a binary square map of reflections for each Point light source generated. A series of such square cards can be mathema be interpreted in such a way that the soldering surface can be reconstructed. A rule based system evaluated by comparison with acceptable solder joint design the soldered connections according to their quality.

The invention has for its object a method and an apparatus to create the type mentioned, with which objects, such as metal parts, Ceramic disks, sheets, semiconductor chips, hybrid components, SMD circuits conditions, seals etc. Features and defects of the surface, such as edges, textu Ren, kinks, color stains, matt areas, ripples, cracks and the like. a.m., with high Reliability and speed can be detected and classified.

The object is achieved in the features of Claim 1; a device is characterized in claim 3. Further Embodiments of the invention are characterized in the subclaims.

The method has the advantage that the features and defects of the Surface of an object, such as edges, textures, kinks, color spots, matt Spots, ripples, cracks, etc. a.m., with the maximum possible signal noise ratio or detected with maximum contrast and regardless of the pixel by pixel, d. H. separate for each surface point, can be classified because the information received in each case temporal gray scale sequence is included. Through full deployment All lighting angles are achieved in an advantageous manner that the features can be extracted with optimal filters or matched filters.

With ring, sector or ring sector-shaped distributions of the lighting radio tion and if as a feature analysis a Fourier or similar transform mation is used, a rotation-invariant classification is advantageous  of the features preserved. The result can then be obtained with an evaluation program the DFT operation and the different ones Error classes in π-periodic (D1 <D2) or 2π-periodic (D1 <D2) or non-periodic with slight changes in the gray value sequence (large D0, small D1 + D2) or continuously dark (all spectral values low) gray value sequences can be distinguished.

If the surface scatters isotropically, circular-symmetrical lighting sequences ( FIG. 2) are useful for the rotation-invariant classification of directed features. However, if the surface structure is no longer rotationally symmetrical, for example due to directional processing, such as grinding, then the use of elliptical lighting functions can be advantageous for optimal signal separation of the surface and the sought-after feature. The structure orientation for the alignment of the main ellipse axes must be known, which can be determined beforehand with test lighting functions.

Advantageously, the individual light sources within the Lighting sky, (which is preferably spherical and on which any point, line or area light sources can be), by Color light sources can be replaced, preferably by three color light sources green, red and blue. In this way, the effort of image acquisition can be at least around be reduced by a factor of 3 because a color image of a sequence of at least corresponds to three gray images.

To carry out the method, the zero point of the Illumination coordinate system placed in the point light source that over the object plane intended as a mirror is imaged in the camera pupil and thus leads to the bright field. Smaller tilting of the object level can be caused by a relative translation of the lighting configuration with little effort be corrected because the lighting arrangement is Cartesian and therefore is translation invariant.

To understand the procedure, consider the generalized Illumination image matrix I (x, y, x, j) helpful, the relationship between the luminance matrix L (x, j) and the image matrix B (x, y) describes and the  contains all of the photometric information about the object, which with the inventive device can be obtained at all. The lighting array allows the 4-dimensional lighting image space I (x, y, x, j) in one to generate discrete form I (x, y, i, j). Light point for light point is indicated controls and the resulting image is stored in the image memory. With a User interface can have different projections or cutting planes of this 4-dimensional data space can be considered.

For the pixel-by-pixel examination of the object surface of an object, the local, d. H. for fixed x and y coordinates scatter, reflection and Shadow characteristics play a crucial role. A matt stain that the Spreading lobe widened, has a uniform spreading characteristic without before direction (isotropic scattering characteristic). Points of a directional dependent surface feature are characterized by an anisotropic scatter characteristic and differ from those with isotropic Streucha characteristics. For example, a surface point scatters to a directed one Surface characteristics (scratches or edges) primarily include the light in the Video camera that arrives perpendicular to its orientation. A point that the The inclination of the reflective surface changes, preferably from scattered light a particular sector of the luminance matrix. If there is an error with tilted reflecting surface creates a single point of light of the Illumination sky a light gray value in the video camera.

By means of the method according to the invention, images can now be made with low redundancy and maximum informative value. Here In the simplest case, brightfield and darkfield lighting are suitable as Concepts for extracting the surface features, with that illuminating tion function is selected, which is a maximum contrast for the error source delivers. An optimal lighting filter is obtained by using the scattered macaw teristik is understood as a lighting function. For example, the Bright field lighting with a point source is an optimal filter for one ideal reflecting surface point where the gray value result of a The maximum camera fails, however, with any other surface structure sinks. For surface points with strongly anisotropic scattering properties, like scratches or edges, usually with different orientations  occur from a direction perpendicular to the orientation of the Object feature illuminated so that the brightness signal in the camera clearly is stronger than with lighting from other directions. Because of the The directionality of the scattering characteristics is therefore an optimal one Illumination filter only capable of anisotropically scattering features in one to detect a certain direction. Therefore, in this case, there will be lighting tion sequences from a variety of solid angles. For this, the Luminance matrix divided into sectors that are controlled one after the other will. This makes rotation invariant or of the orientation of the Obtain independent results because of different types of object can be distinguished from scattering characteristics.

Used as a device to form the dome-shaped lighting sky Concave mirror, in particular parabolic mirror, used, this has the Advantage that due to the mapping laws the parabolic mirror more or less horizontally reflected light rays, as for a location-independent Scattering required, in the direction of the focal point and the object parallel or run more or less parallel, so that the virtual distance of the diffuse illuminating light sources from the object is very large and as a first approximation can apply practically infinitely. The more or less vertically on the object incident beam of rays is convergent, however, so that light sources over the object surface thought of as a reflective plane in the plane of the camera pu pill are shown. With this (as with the specially realized Reflection light module) reflecting surfaces evenly in the bright field be illuminated. The virtual distance can be used for this special adjustment the light sources are varied: the distance of the lower light sources, such as LED arrays, from the parabolic mirror is critical to the radiation formation that occurs on the object in focus, so whether it is convergent, divergent or parallel light, which is why the distance is advantageous is variable. The geometric location of the point light source that is in focus parallel light is a paraboloid or similar shape. Convergent or divergent light is generated in the focal point when the Light source is located below or above the geometric location; parallel Light to the focal point is generated when the light source is on it geometric location.  

Another advantage is that the device is extremely compact. Of the Concave mirror can also preferably be made in one piece from transparent glass or plastic without a recess and in its uppermost area be non-mirrored to form a passage for the reflecto light used by the lighting device.

Brief description of the drawing, in which:

Fig. 1 shows a schematic cross section through a lighting device for performing the method on a lighting sky in the form of a hemisphere and

Fig. 2 is a plan view of the lighting sky showing the various selectable sectors in which may be located one or a plurality of light sources, respectively,

Fig. 3 is an algorithm of a flow chart for pixel classification with (N + 2) Lighting,

Fig. 4 is a schematic cross section through a lighting device consisting of a two-dimensionally curved lighting sky with a lighting arrangement and

Fig. 5 shows another illumination device having two-dimensionally curved lighting sky and a creatively different illumination arrangement and object delivery.

About a base 8 ( Fig. 1) bulges a hemispherical lighting sky, in which a plurality of light sources 2 are arranged, preferably divided into different sectors sm, n according to FIG. 2, the intensity of the light sources are individually programmable. Furthermore, there is a lighting module 3 in the lighting sky, which has a plurality of light sources 4 , which are preferably arranged as a Cartesian array. In front of the lighting module 3 there is an optic 5 which bundles the light emitted by a single or a few light sources 4 in such a way that it is suitable for uniform bright field illumination of flat, reflecting surfaces of an object. The lighting module 3 is used in particular for ripple and kink testing on reflecting surfaces and thus for classifying surface inclinations. The light sources 2 are used for diffuse lighting.

The light thrown by the light sources 2 and 4 onto the object 1 and scattered and reflected by it is collected by a lens 6 of a video camera and directed to a CCD matrix of the video camera; the CCD matrix 7 of the video camera is connected to an image storage device 9 which stores the gray image sequences. After a specific, predeterminable number of images or color images have been stored within an image storage device 9 of the video camera, the image contents are subjected to a Fourier transformation, preferably a 2D Fourier transformation, with regard to the illumination coordinates, in order to determine the amount and phase of the illumination angle dependency of the individual image point.

This classification method builds on the basic peculiarities of gray sequence of values obtained when the sectoral illuminations are run through will. The gray value sequence is used as a finite section of a periodic, time and value discrete function viewed in its basic components can be disassembled; The amount and phase of the components are discrete Fourier transform (DFT) of the number N gray values of the sequence obtained.

The sector number N should be a power of 2 for the Fourier transform and depends on the period of the most complicated according to the sampling theorem relevant scatter characteristics from:

N 2x 2π / Tmin.

If you are dealing with π-periodic phenomena, you must have at least four Sectors are illuminated. For N = 4, for example, the gray can value sequences obtained by lighting from four room sectors and are then subjected to a Fourier transformation. The results this process for three error classes are shown below and leave describe themselves as follows:

• (A) The gray value sequence of a scratch is π-periodic (2 maxima), because the light from 2 lights lying perpendicular to its orientation sectors is scattered into the camera. The range of amounts points a large 2nd component that gives phase of the 2nd component Φ2 the orientation direction of the feature.  
• (B) The gray value sequence of a point is 2π-periodic because it is the light scattered into the camera from a certain lighting sector. The Amount spectrum has a large 1st component.
• (C) An isotropically scattering object material (mirror, stain) has a con constant gray scale sequence. Its range of amounts consists of only one Direct component, which is a measure of the scattering intensity.

The following is a spectral analysis of three exemplary gray value sequences shown, the horizontal coordinate being the azimuthal illumination angle describes.

With the help of the Fourier transformation, a surface point or a can now Pixels of the image of the video camera are classified, followed by a  possible algorithm according to the invention in the form of a flow chart for the rapid hierarchical classification into, for example, four idealized ones Defect classes such as mirror, dot, scratch and stain are shown. An un the very point of the surface (mirror point) can be removed immediately, by taking light and dark field images into account. In this case the classification is ended without the Fourier transformation.

According to FIG. 4, a BL LEVEL arches over a plane 35 or base tung sky, which is preferably an internally mirrored parabolic mirror or a coating on the inside mirror having about paraboloidischer form or is curved similarly two-dimensionally and, preferably at the top of the buckle, an opening 12 for Has light passage; this opening can also consist of an unmirrored, transparent material field of the mirror.

The lighting sky can be used for less precise feature extraction hemispherical, two-dimensional adapted for best feature extraction be curved.

Below the opening 12 of the mirror 11 there is an object 10 to be analyzed on a transparent support 13 . Below the carrier 13 is on level 35 an illumination device 14 , which consists of a plurality of Cartesian light source fields 15 , 15 ', 15 '', each light source field having a plurality of individual light sources 17 , 17 '. The light source fields 15 , 15 ', 15 ''are preferably LED arrays, the individual light sources 17 , 17 ' can be controlled individually or in groups sequentially. Directly above the light source fields 15 , 15 ', 15 '', a diffuser covering the same can be arranged, which is a low-pass filter and is used for the light sources to be continuous in order to satisfy the scanning theorem.

The lighting device 23 above the mirror 11 and the opening 12 consists of at least one reflection light source 23 and is preferably also an LED array, which is preceded by optics for reflective illumination of the object 10 from a limited solid angle and in front of which there is also a diffuser 24 can be. The optics located in the beam path of the light beams 32 emitted by the illumination device 23 is, for example, a collimation lens 25 , followed by a splitter mirror 20 . A video camera 21 with an image storage device, which can have an optical aperture device 22 , is arranged on the side of the divider mirror. The illuminating device 23 and the video camera 21 are matched to one another in such a way that the convergence of the light bundle 32 is equal to the convergence of the observation light bundle 32 '.

The lighting device 23 is used for the more or less vertical illumination of flat, reflecting objects, the light beam 32 occurring through the collimation lens 25 and after passing through the splitter mirror 20 and the opening 12 within the mirror 11 as a convergent light beam onto the object 10 , reflecting from there and is thrown onto the video camera 21 by the splitter mirror 20 . The lighting device 23 works analogously to the lighting device 3 described in FIG. 1.

From the individual light sources 17 , 17 'of the light source fields 15 , 15 ', 15 '' light bundles 19 are sent to the mirror 11 , which fall from there as a parallel light bundle 19 'onto the object 10 , which is at the focal point or approximately at the focal point of the mirror 11 is located. This more or less horizontally a falling light beam 19 'are scattered and directed by the splitter mirror 20 onto the video camera 21 . Conversely, converging light strikes the object 10 from above, so that the device meets the theoretical requirements for the simultaneous presence of horizontal, parallel illuminating light beams and vertical, convergent illuminating light beams.

Alternatively, the illumination beam path can be used instead of the camera beam path kinked; as an alternative to the lens, a mirror can also be used for collimation to be available. Likewise, the object surfaces brought into the bright field can be spherically curved if the collimation optics are adapted accordingly is.

Fig. 5 shows a modified lighting device 26 , consisting of a plurality of Cartesian light source fields 28 , 28 ', which can be constructed like the light source fields of FIG. 4. The light source fields 28, 28 'are also covered with a diffuser 30 . The lighting device 26 and the diffuser 30 each have a recess 29 or 31 in the center, through which a slide 33 with the object 10 to be detected can be displaced in the vertical direction. The object 10 can thus be corrected vertically and optionally also horizontally with respect to the focal point of the mirror 11 by simple height and side adjustability. Otherwise, the configuration of the mirror 11 as well as the lighting device 23 and the video camera 21 corresponds to that of FIG. 1.

The size and number of optimally required sectors depends on the object function with the lowest half-width. The appropriate number of sectors can can be found by the relationship between feature signal and Surface signal is plotted over the number of sectors. It shows after a steep climb usually a rapid saturation; already with 3 to 8 Powerful error detection can be implemented in images, which over statically illuminated single images are of major advantage.

Reference list

1 , 10 objects
2 light sources
3 lighting module
4 light sources
5 optics
6 lens
7 CCD matrix of the video camera
8 object level
9 Image storage device of the video camera
11 mirrors
12 opening
13 transparent support
14 lighting device
15 , 15 ' , 15'' flat light source fields
16 , 27 , 34 double movement arrows
17 , 17 ' individual light sources
18 , 24 , 30 diffusers
19 light beams from a single light source to the mirror
19 ' reflected from the mirror light beam from a single light source
20 divider mirrors
21 video camera with image storage device
22 Optical aperture device
23 lighting device
25 optics, e.g. B. collimation lens
26 lighting device
28 , 28 ′ flat light source fields
29 , 31 recesses
32 light beams
32 ′ observation light bundle
33 slides
35 level

Claims (11)

1. A method for dynamic detection and classification of surface features and defects of an object ( 1 ), which is surrounded by a lighting sky, within which several differently positioned lighting sources ( 2 , 4 ) for diffuse lighting in a flat arrangement, the object ( 1 ) sequentially illuminate and are freely programmable with predefinable angle and intensity gradation to generate - a variable number of any lighting functions, the light diffusely reflected or reflected by the surface of the object ( 1 ) at any time by means of a CCD matrix ( 7 ), one Video camera, which has an image storage device ( 9 ), is recorded as space-temporally different images, characterized in that the object ( 1 ) additionally from a limited solid angle range with a further programmable, areal lighting module ( 3 ) for reflective lighting via a Ko Limitation optics is illuminated in such a way that the reflection angle condition is fulfilled for all points on a flat object surface and the zero point of the illumination coordinate system is placed in the point light source that is imaged into the camera pupil via the surface of the object ( 1 ) intended as a flat mirror, the resulting images of the CCD matrix ( 7 ), the video camera and recorded in an image storage device ( 9 ) and the gray value sequences of the recorded image stack are subjected to a feature analysis which is a Fourier transformation and thereby a rotation-invariant classification of the features is obtained. 2. The method according to claim 1, characterized in that an algorithm for hierarchical classification in four idealized error classes, namely mirror, point, scratch and spot, with Fourier transformation is used as follows:

• a) a gray value sequence is extracted with the gray value data from the illumination test N sector, bright field, dark field illumination = N + 2 images d _n (n = 0, 1,.., N + 1)
• b) In a preliminary decision, it is checked whether the gray value difference between ring-shaped dark field illumination and bright field illumination at the respective image coordinate is greater than a suitably selected threshold value S₀ according to d _N - d _{N + 1} <S₀, which is due to a reflective, flat surface at the corresponding location The surface closes and further processing is unnecessary
• c) in all other cases, the gray value sequences of the respective image coordinate of a Fourier transformation obtained in rotating dark field sectors are calculated according to d _n (n = 0, 1,..., N-1) → D _k , Φ _k (k = 0, 1, 2) subjected to
• d) the resulting magnitude spectrum D _k is subjected to a classification, a first decision being made to check whether the sum of the spectral coefficients D1 and D2 is smaller than a threshold value S1, if this is the case, the class "stain" output, if this is not the case, then a further decision is made to determine whether the spectral coefficient D2 is greater than the spectral coefficient D1, if this is the case, the "point" class is output, otherwise the "scratch" class.

3. Device for dynamic detection and classification of surface features and defects of an object ( 1 ), which is surrounded by a lighting sky, within which several differently positioned lighting sources ( 2 , 4 ) for diffuse lighting in a flat arrangement, the object ( 1 ) sequentially illuminate and are freely programmable with predeterminable angle and intensity gradation to generate a variable number of any lighting functions, the light from the surface of the object ( 1 ) diffusely reflected or reflected at any time by means of the CCD matrix ( 7 ) of the video camera An image storage device ( 9 ) has, as space-wise different images, characterized by the following features:

• a) at least one further programmable lighting module ( 3 ) with a lens or mirror optics ( 5 ) for uniform reflective bright-field illumination of flat or slightly curved surfaces, the zero point of the lighting coordinate system being placed in the point light source that is on the plane mirror imaginary surface of the object ( 1 ) is imaged in the camera pupil and
• b) an algorithm generator which is capable of subjecting the image stacks recorded by the video camera ( 21 ) to a transformation, which is a Fourier transformation and thereby a rotation-invariant classification of the features is obtained, with which the surface features and error types sought with a suitable choice of the lighting function can be maximized Signal-to-noise ratio can be detected and classified.

4. The device according to claim 3, characterized in that the lighting module ( 3 ) has a plurality of light sources ( 4 ) which are arranged as a Cartesian array, the lighting functions have elliptical ring, sector or ring sector-shaped distributions and from a number of ring sectors (sm, n) exist, whose generated gray value image sequences are subjected to a 1D or 2D Fourier transformation with respect to the ring sector indices m, n, the rotation-invariant classification of the features being able to be carried out by means of the coefficients obtained. 5. The device according to claim 3, characterized in that each light source ( 2 , 4 ) within the lighting sky consists of a plurality of separately controllable color light sources, preferably green, red and blue, and at the same time an image can be recorded with the different superimposed colors, wherein a color image is able to replace at least three successive gray images. 6. The device according to claim 3, characterized in
that the lighting sky is an internally mirrored, concavely curved hollow mirror ( 11 ), which has an opening ( 12 ) in its uppermost area, above which the reflector-serving lighting device ( 23 ) is located and that the lighting device used for diffuse lighting ( 14, 26 ) consists of flat light source fields ( 15 , 15 ', 15 ''; 28 , 28 '), which are located below the concave mirror, the object ( 10 ) below the opening ( 12 ) and approximately centrally within the plane Light source fields is arranged within the collecting surface of the concave mirror. 7. The device according to claim 6, characterized in that the concave mirror ( 11 ) is a parabolic mirror and the object ( 10 ) is in the focus thereof. 8. The device according to claim 6, characterized in that the concave mirror ( 11 ) is a spherical mirror or an ellipsoid mirror and the object ( 10 ) is in the focus thereof. 9. The device according to claim 6, characterized in that the lighting sources ( 2 ) for diffuse lighting flat LED arrays ( 15 , 15 ', 15 ''), which are arranged on a common plane ( 35 ) below the concave mirror ( 11 ) and are covered with a diffuser ( 18 ). 10. The device according to claim 8 or 9, characterized in that between the lighting sources ( 15 , 15 ', 15 '') for diffuse lighting and the concave mirror ( 11 ), a transparent support ( 13 ) for placing the object ( 10 ) is arranged . 11. The device according to claim 6, characterized in that the lighting module is an LED array ( 23 ), in front of which a diffuser ( 18 ) and above the opening ( 12 ) of the concave mirror ( 11 ) a divider mirror ( 20 ) are arranged, which reflected light on the video camera ( 21 ) conducts.