DE29819954U1 - Device for the optical inspection of holograms - Google Patents

Description

Device for optical testing of holograms

Description

The invention relates to a device for optically testing holograms or kinegrams with a holder for the carrier having the hologram, a camera for recording at least the light diffracted by the hologram and at least one lighting device for illuminating the hologram.

Holograms, such as white light holograms, have, among other things, the property that the optically perceived appearance changes with different lighting and/or viewing directions. Depending on the lighting direction, the light is diffracted in different ways, which causes this effect. Such holograms are applied, for example, to check or credit cards, banknotes and the like in order to make them forgery-proof. Such holograms are also used to optically enhance objects, such as packaging, CDs or the like.

It is necessary to examine such holograms and their different optical appearances. Devices are known in which the camera 0 is moved relative to a light source in order to be able to record the hologram with different angles of incidence of the light. The camera is connected to an evaluating data processing system in which the images obtained are compared with target images. It is obvious that the realization of such a

mechanical relative movement with sufficient accuracy and reproducibility is very complex. It is also not possible to illuminate the same hologram from several directions in a short space of time, since the camera has to be readjusted relative to the light source after each shot. The complete test therefore takes a relatively long time. However, this is not always possible in view of the short test time that can be available when manufacturing such a mass product.

The invention is based on the object of

To create a device that allows a fast optical

Testing a hologram is also possible from different lighting directions.

The object is achieved according to the invention in that the lighting device has at least one light line with a plurality of light sources that are arranged above the hologram plane in such a way that the light sources illuminate the hologram from different directions, whereby the light sources can be switched on and off individually or in groups. This arrangement has the advantage that the camera no longer has to be moved relative to the light source. Instead, it can be provided that the hologram is illuminated in only one position by switching one or the other light source or light sources on and off with light from different angles of incidence. The camera then records the corresponding appearance of the hologram.

Furthermore, the device can be set up in advance for the hologram to be tested. The preferred illumination directions and their temporal sequence are

preset using a corresponding programming device. The camera then records the corresponding appearances of the hologram in succession in the assigned direction of illumination.
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It can be arranged that the light line runs along a circular arc section on a spherical surface around the hologram. This allows the hologram to be illuminated from any spatial angle.

It is useful if the line of light runs essentially in a plane perpendicular to the hologram. The line of light then runs along any spatial circular arc section around the hologram. This means that each light source is at the same distance from the hologram, so that the hologram can be evenly illuminated by each individual light source. The circular arc section can enclose an angle of up to 180°, preferably from 10° to 90°. Such an angle range is usually sufficient to illuminate the hologram so that the individual appearances can be optimally recognized.

In principle, it is possible to provide several such light lines that run along spaced or angled spatial arc sections on the sphere surface. This increases the possibilities for adjusting the illumination of the device in relation to the hologram to be tested.

It can also be useful if the entire light line can be spatially pivoted around the hologram. This allows the angular range that can be illuminated by the individual light sources in relation to the 5 hologram plane to be roughly set in advance.

It is advantageous if the light sources in the light line are arranged as close to each other as possible. This allows the different angles of incidence of light to be varied in small steps. It can be particularly useful if at least two parallel light lines are provided that are close to each other, with their respective light sources offset from each other. This allows the angle of incidence of light to be adjusted almost continuously. This is advantageous because even small changes in angle can cause one or the other appearance of the hologram to appear and disappear again.

In principle, it is of course also possible to have several

Light sources in a light line one behind the other or in

to switch on several rows of lights next to each other. This can increase the light intensity.

In principle, it is advisable if the distance and the light intensity of the light sources are such that the light from the light source(s) assigned to a direction of illumination illuminates the entire surface of the hologram section to be tested with almost parallel light. The light sources are located at a relatively large distance from the hologram. This means that the desired diffraction effect can be achieved essentially without being influenced by differently aligned light.

The light line can be equipped with light-emitting diodes (LEDs), for example. Such LEDs have sufficient light intensity and can be mounted close together with very little distance between them.

It can also be useful if the camera and the light line(s) are arranged on one side of the hologram with respect to the surface normal. This is possible on the one hand because diffracted light is to be recorded. On the other hand, one side of the hologram remains free, e.g. for possible handling devices for the carrier in question.

At least one first light source emitting diffuse light can also be provided in order to illuminate the hologram completely, essentially from the side. This makes it possible to check the surface in the dark field. This arrangement is also suitable for checking certain hologram contents. It is also possible to arrange at least one second light source emitting diffuse light above the hologram in order to illuminate the hologram completely, essentially from above. These light sources can be used to check the surface properties of the hologram and the carrier. The second light source generates bright field illumination, which can be used to detect surface defects, for example. Due to the diffraction properties of the hologram, however, it does not act as an ideal mirror, so that even with a perfect surface and hot field illumination, dark spots can arise. The advantage of the invention is also clear here, since the dark spots caused by diffraction can be eliminated by illuminating the hologram from the side with one or more light sources in the light line. This makes it easier to check the surface quality.

It can be useful if the lighting device, the first and the second light sources emitting diffuse light can be switched independently of one another. This can prevent mutual influences, if not desired. It is provided that the lighting device, the first and second light sources emitting diffuse light and the camera are arranged in relation to the hologram plane in such a way that the light diffracted by the lighting device on the hologram, the light scattered by the first light source emitting diffuse light on the hologram and the light reflected by the second light source emitting diffuse light on the hologram illuminates the camera. However, it can also be provided that the first and second light sources emitting diffuse light are switched together in any combination with the light sources of the light line.

It is obvious that the device according to the invention can be used to quickly check a hologram and always with appropriate illumination. It is possible to illuminate the hologram from different directions in just one position of the carrier in question and the camera relative to the lighting device. The desired appearance of the hologram can always be made visible or at least highlighted by appropriate programming of the various light sources.

The invention is explained in more detail below with reference to the schematic drawing. They show:

Fig. 1 is a schematic side view of the device according to the invention,

Fig. 2 is a plan view of a section of a

Light line according to an embodiment of the

Invention,
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Fig. 3 a plan view of a section of a

Light line according to another embodiment

the invention and

Fig. 4 is a schematic plan view of possible spatial arrangements of the light line in relation to the hologram.

The device shown in the drawing for optically testing a hologram 11 has a holder 12 for the carrier 13 of the hologram. The carrier can be designed as a check or credit card, for example.

0 At a distance from the hologram 11, an illumination device 14 is provided, which consists of at least one light line 15 running in the plane of the drawing, which has a plurality of light sources 16. In detail, the arrangement in the embodiment shown is such that the light sources run along a circular arc section 17 above the hologram plane 23, the center of which corresponds approximately to the center 18 of the hologram. The light sources 16 emit light in the direction of the hologram 0 11.

It can be provided that several parallel light lines 15 and 15' are provided. In the case shown in Fig.

2, the respective light sources 16, 16' are arranged next to each other in order to

to increase the light intensity associated with an angle of incidence. In the embodiment shown in Fig. 3, the adjacent light sources 16, 16' are arranged offset from one another in order to enable an almost continuous adjustment of the angle of incidence of the light. Of course, several arrangements according to Fig. 2 and Fig. 3 can also be combined with one another as desired and arranged, for example, according to Fig. 4. The individual light sources can be, for example, light-emitting diodes, which allow a correspondingly close arrangement to one another and which produce sufficient light intensity. These can work in flash mode, for example. The brightness of the lighting can also be influenced by choosing the exposure time.

The light sources 16 can be switched on and off individually or in groups. A programming device (not shown) can be provided, by which the 0 temporal sequence of switching on and off can be programmed. With this arrangement it is possible to illuminate the hologram from different directions in order to be able to optimally emphasize the different appearances of the hologram.

In particular, the viewing direction and thus the visible appearance can be freely selected.

A camera 19 is provided which is illuminated at least by the light diffracted by the hologram. The camera 19 and the illumination device 14 can be arranged on only one side of the device with respect to a vertical central axis 20 of the hologram, as shown in the drawing. This creates space for further devices of the device.

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In the embodiment shown in the drawing, a first light source 21 emitting diffuse light is provided to the side of the carrier 13 of the hologram 11. Furthermore, a second light source 22 emitting diffuse light is provided above the carrier 13. The arrangement is such that the camera can also be illuminated by the light scattered on the hologram from the first light source 21 emitting diffuse light and by the light reflected on the hologram from the second light source 22 emitting diffuse light. This allows the surface properties of the carrier 13 and also of the hologram to be checked. It is expedient if these light sources 21, 22 can be switched on and off independently of the lighting device 14 or in combination.

Fig. 4 shows schematically possible arrangements of the light line on a spherical surface 24 around the hologram. In addition to the arrangement according to Fig. 1, further light lines 25, 26 and 27 can be provided. The light line 25 also runs along a circular arc section around the center of the hologram, but at a different angle than the light line 15. The light line 26 runs along a circular arc section whose center is not in the hologram. The light line 27 runs in a plane parallel to the hologram. The light sources of each light line are aligned with the hologram. With these arrangements it is possible to provide a wide variety of lighting from a wide variety of spatial angles. Of course, several such light lines 15, 25, 26, 27 can also be provided in combination with one another.

Claims (15)

10 Device for optically testing holograms Claims 5 1. Device for optically testing holograms (11) with a holder for the carrier (13) containing the hologram, at least one camera (19) for recording at least the light diffracted by the hologram and at least one lighting device (14) for illuminating the hologram, characterized in that the lighting device has at least one light line (15, 25, 26, 27) with a plurality of light sources (16) that are arranged above the hologram plane (23) in such a way that the light sources illuminate the hologram from different directions, wherein the light sources can be switched on and off individually or in groups. 2. Device according to claim 1, characterized in that the light line (15, 25, 26, 27) runs along a circular arc section on a spherical surface (24) which extends around the hologram (11). 3. Device according to claim 1 or 2, characterized in that the light line (15, 25) runs along a spatial circular arc section (17) centrically to the hologram (11). 4. Device according to claim 2 or 3, characterized in that the circular arc section (17) has an angle of up to 180°, preferably from 30° to 90
includes. 5. Device according to one of claims 1 to 4, characterized in that the entire light line can be pivoted around the hologram. 6. Device according to one of claims 1 to 5, characterized in that the light sources (16) of a light line (15) are arranged with the smallest possible distance from one another. 7. Device according to one of claims 1 to 6, characterized in that at least two parallel light lines (15, 15') are provided, the respective light sources (16, 16') of which are offset from one another. 8. Device according to one of claims 1 to 7, characterized in that the distance and the light intensity of the light sources are dimensioned such that the light from a light source(s) assigned to an illumination direction illuminates the hologram section to be tested essentially over its entire surface. 9. Device according to one of claims 1 to 8, characterized in that the light line is an LED line. 10. Device according to one of claims 1 to 9, characterized in that the light sources operate in flash mode. 11. Device according to one of claims 1 to 10, characterized in that the camera (19) and the light line (15) are arranged on one side of the surface normal (20) of the hologram (11) with respect to the same. 12. Device according to one of claims 1 to 11, characterized in that at least one first light source (21) emitting diffuse light is provided in order to completely illuminate the hologram essentially from the side. 13. Device according to one of claims 1 to 12, characterized in that at least one second light source (22) emitting diffuse light is arranged above the hologram in order to illuminate the hologram completely essentially from above. 14. Device according to one of claims 1 to 13, characterized in that the lighting device (14) and the first and second light sources (21, 22) emitting diffuse light can be switched independently of one another and/or in combination with one another. 15. Device according to one of claims 1 to 14, characterized in that the lighting device, the first and second light sources emitting diffuse light and the camera are arranged in relation to the hologram plane in such a way that the light diffracted by the lighting device on the hologram, the light scattered by the first light source emitting diffuse light on the hologram and the light reflected by the second light source emitting diffuse light on the hologram exposes the camera.