DE19824709A1 - Producing luminance distribution array from rays projected onto medium using digital array radiation processors - Google Patents

Abstract

Several (N) array radiation processors (23 to 25) deflect and/or modulate X beams (1 to 22), where N and X are greater than or equal to one. The deflection or modulation is used to produce a multicolor image, or a pattern of gray scales with X pixels, on a projection surface (34). Computer generated holograms may be produced in a suitable medium, each pixel storing XN grating shapes.

Description

The present invention relates to a method and a Device for generating array-shaped Luminance distributions when projecting radiation onto a medium by using digital array Radiation processors (DASP's). With the present invention can, among other things, single and multi-colored images, so like images with different shades of gray and holograms be generated.

Color displays can display colors either in parallel or sequentially produce. In the case of parallel color generation, a colored one Pixel is generated by either the primary colors at the same time projected on top of each other, or by side by side arranged pixels that reflect the primary colors.  

A sequential color display, however, is achieved that in quick succession, that is in time Sequence, the basic colors of the pixel on the Projection surface is projected. Merging for the eye the basic colors due to its inertia to the mixed color. In In this context the company Texas Instruments offers the term "DIGITAL LIGHT PROCESSING" (DLP) with the use of Digital Mirror Device (DMD) projectors.

Individual pixels of images are shown using white Light emitted by a rotating filter disc accordingly is processed, in chronological order on a Projection screen projected. Through a variety of individual The correspondingly projected image is created in this way.

With the sequential display, only one light modulator array is necessary, which projects the individual primary colors one after the other, which are generated by a color filter wheel from white light. It should be noted, however, that with the sequential display of the image pixels, the primary color 1 can only be exposed in the period in which this is made available by the filter wheel. During the period in which the primary color 2 is projected, this image pixel must remain dark.

However, this requirement is not necessary for the parallel projection of images. This results in the advantage for the parallel display that each pixel can be represented in the basic color 1 , basic color 2 or in any mixed color during the entire image interval. This means that the colors can be displayed at least twice as bright as in sequential projection.

For the basic definition of terms, here are the following Comments given. As a radiation processor electronic component indicates that the beam direction incident radiation changes. As an array radiation processor is called a radiation processor that consists of an array  components changing the beam direction. A digital one Array Radiation Processor (DASP) is an array Radiation processor whose array components determine the beam direction change in X discrete angular steps.

Three types of such digital are known Radiation processors. The Digital Mirror Device (DMD) from Texas Instruments, with X = 2 by distraction in + PHI or -PHI. The Pioneer Reflective Liquid Crystal Array (RLCA) with X = 2 by back reflection or transmission. And the lithium niobate Prism array (LPA) with X <= 2 beam deflection through acousto-optical effect.

The advantage is when several light modulators are used the parallel projection versus the sequential Projection no longer as pronounced as with the projection only one modulator, since even when using sequential Technology a greater luminance is achieved. A the same bright display as with the parallel projection however not possible, which at least in the image brightness Advantage of the parallel projection over the sequential one represents.

It should also be noted that due to the use of the Filter wheel a great deal of effort must be made to Represent pixels accordingly. Here are mechanical Components in use that move at high speed move, and therefore inevitably subject to wear.

Regarding the term rays, rays and Partial rays should be noted that an exact definition is difficult because a single beam viewed in isolation is always composed of several rays, and thus always forms a ray bundle. The at the beam splitting described in the present invention thus primarily relates to the distribution of the injected rays through the individual mirrors and / or Modulators of the arranged DASPs.  

The object of the present invention is a method and a device for projecting and modulating beams describe that a higher yield of the fed Cause radiation. Furthermore, it is desirable without mechanical and Control-technically complex components such as B. the Unit with the color filter wheel represents, and additionally a better alignment and stabilization of the components used to achieve each other.

According to the invention serve to solve the problem characterizing features of independent claims 1 and 9.

It is essential here to generate an array-shaped luminance distribution with N digital array radiation processors, each pixel of this distribution X ^{N being able to} assume different modulation states. The modulation states can be: different colors, positions, beam directions, phase fronts, polarizations, intensity distributions or the like.

By means of the present invention it is possible to use multi-colored Images or images with multiple grayscale as well Expose holograms. Here is a resolution of Images according to the pixel density used up to razor-sharp images possible.

It is also possible to hide or latent images encode. In this case, you can use any coding be performed.

Another possible application of the present invention arises for use in display applications because the Technology is easy to use and the light output is larger than in known methods.

For this purpose, N DASPs are used, which are arranged in such a way that the deflected and / or modulated beams each in  Hit the nearest DASP in the beam direction and from it in desired modulation type can be modulated.

The advantage with the present invention is that the process does not require a rotating color filter, and the associated synchronization problems and the mechanical Components are eliminated.

Another advantage of the present invention results from the fact that the display of X ^N full colors is possible at the same time. It is therefore not necessary that the radiation has to be interrupted or masked again and again for a corresponding period of time during the modulation process. As a result, the present invention achieves a higher luminance when projecting the corresponding motif.

Another advantage arises with the present invention due to higher stability of the projection during use, compared to the previously known methods, because by the monolithic structure changes the position of the projection and Modulation elements can be easily compensated.

Based on the drawings, the one embodiment of the device for generating register-accurate color changes, as well as for Represents exposure of computer generated holograms, be that Invention described in more detail.

Show it:

Fig. 1 shows an arrangement of DASPs with a number of additional modulators, the possible course of a beam during modulation is shown.

Fig. 2 The creation of a computer-generated hologram.

The DASP method from FIG. 1 can be generalized for any N and X. For X = 2 (deflection in two different directions) and N = 3 (3 DASP's), each image pixel can assume 8 different modulation states.

In the arrangement according to FIG. 1 with corresponding DASP's 23-25 for (X = 2; N = 3), a beam ( 1 ) is directed onto DASP 23 , each pixel (pixel) of the beam being deflected in one of X directions and / or is modulated. All X rays are aimed at DASP 24 . Each pixel can be deflected and / or modulated in X new directions. All X rays are directed onto DASP 25 and each pixel can be deflected and / or modulated in X new directions. The beams then pass through X ³ modulators 26-33 according to their deflection, and in this way experience between one and X ³ modulation states. These can be colors, lateral offsets, intensities, phase distributions, beam directions, polarizations or the like. The beams are imaged one on top of the other or distributed at different positions, depending on the requirements of the projection object.

By time multiplexing the X ^N mirrors and / or modulators of the DASPs, all mixed forms of the X ^N modulation states can be achieved. In particular, all mixed colors can be displayed.

Another possible application is represented by the creation of computer-generated holograms with 4 lattice parameters by 2 DASPs in FIG. 2. Beam 39 falls on DASP 35 and, depending on the position of the modulator, is deflected in the beam direction of beam 40 onto mirror 37 or in the beam direction of beam 41 onto mirror 38 . The mirrors 37 and 38 direct the beam onto the DASP 36 whose tilt direction 47 is expediently perpendicular to the tilt direction 46 of DASP 35 . Depending on the state of the array mirrors in DASP 35 and DASP 36 , the partial beam assigned to each pixel array is deflected in one of the four directions 42 , 43 , 44 or 45 . The four beams 42 , 43 , 44 or 45 are directed from four different directions onto a holographic recording medium illuminated by a vertical reference beam. Each pixel can thus be exposed with one of four grating structures, the parameters of which are given by the angle of incidence and the wavelength. Suitable beam geometries are used to produce intermodulation gratings.

Another possible application is the exposure of an image with 8 shades of gray. The structure of the invention is implemented as shown in FIGS. 1 and 2. The beams 42 , 43 , 44 or 45 (from FIG. 2) are directed onto DASP 25 (in FIG. 1 ) and, depending on the state of the array mirrors of DASP 23 , DASP 24 and DASP 25, are directed in eight different directions. Each of these beams passes through one of 8 grayscale filters. All rays are then projected onto a projection surface 34 . Each pixel can take on one of 8 gray levels.

In a development of the arrangement described in FIG. 1, instead of combining the partial beams on a DASP 23 , 24 , 25, the beams can be split up with an additional DASP. Instead of beam deflection elements in the form of modulators 26 to 33 as well as 37 and 38 N-1 DASPs are required. The modulation of the partial beams is variable and takes place according to the value of certain parameters. So z. B. the modulation can be influenced by a checksum. By multiple exposure each pixel can get X ^N types of modulation. In particular, in the case of computer-generated holograms, each pixel can store X ^N grid shapes.

To the DASP's and the associated optics to each other exactly it is useful to align the structure of the system in perform monolithic form. As an example is a Quartz glass block listed, on the end faces of the DASP's and the beam surfaces are arranged.

In the previously known applications such. B. DASP's from Texas Instruments will use other modulation schemes for DASP's describe the basic idea of dividing an image Frames in color window. The modulation of the  Grayscale and the basic colors by time-multiplexing reached.  

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Claims (11)

1. A method for generating array-shaped luminance distributions in the projection of radiation onto a medium by using digital array radiation processors, characterized in that a number of N array radiation processors ( 23-25 ) a number of X incident rays ( 1-22 ) deflect and / or modulate, where N and X ≧ 1. 2. The method according to claim 1, characterized in that by the deflection and / or modulation of the projected rays ( 1-22 ) multi-colored images and / or images that have one or more gray levels in a grid with X pixels on the projection surface ( 34 ) will. 3. The method according to any one of claims 1 or 2, characterized in that computer-generated holograms are generated in a grid with X pixels in a suitable medium, wherein each pixel can store X ^N grid shapes. 4. The method according to any one of claims 1-3 featured hidden pictures, in or on Valuables and / or security products, in a grid with X Pixels are generated and / or encoded. 5. The method according to any one of the preceding claims characterized in that a grid of X pixels at least one display is projected to information make visible. 6. The method according to any one of claims 1-5 characterized that the modulation of each one Pixel depending on variable parameters is computer generated.   7. The method according to any one of claims 1-6 characterized in that the modulation states are different Colors, positions, beam directions, phase fronts, Polarizations, intensity distributions or the like can. 8. The method according to any one of claims 1-7, characterized in that all the mixed forms of the X ^N modulation states can be achieved by temporal multiplexing of the X ^N array radiation processors ( 23-33 ). 9. Device for generating array-shaped luminance distributions in the projection of radiation onto a medium by using digital array radiation processors, characterized in that N array radiation processors ( 23-33 ) are arranged so that the beams ( 1-22 ) all N array radiation processors (23- 33) pass through on their path of radiation, said X-rays (1- 22) deflected and / or modulated, where N and X ≧ 1, respectively. 10. The device according to claim 9, characterized in that the arrangement of the array radiation processors ( 23- 25 ) is carried out in monolithic form. 11. Device according to one of claims 9 or 10, characterized in that mirrors ( 37 , 38 ) deflect the rays ( 40 , 41 ).