DE19838070A1 - Device for exposing image information on light sensitive material for photographic copier has mask arranged between light source and light-sensitive material to cover part of each light emitter - Google Patents

Abstract

The device has a light source which consists of independently controllable light emitters, such as green/blue LEDs (2b,c), arranged in several lines. A controller drives the light emitters based on a signal corresponding to the image information. The light source and the light-sensitive material (1) are movable relative to each other, perpendicular to the line direction. A mask is arranged between the light source and the light-sensitive material and is structured so that predetermined part of each light emitter is covered. The mask has openings which are mutually displaced from line to line to produce a skew column arrangement. An Independent claim is included for an exposure device.

Description

The invention is based on a device according to the preamble of An saying 1.

In EP-OS 0 713 330 A2 an imaging device is disclosed, the three has different colored exposure lines on which photo paper during moving past the exposure. For the green and blue color separation each used a vacuum fluorescence line, in front of which a yellow or blue filter is set. The red color separation is on the with the help of a red LED line Exposed photo paper.

The brightness of the vacuum fluorescent lines requires a certain exposure Duration that stands in the way of a high transport speed of the photo paper. The performance of one is therefore equipped with a corresponding print head th photographic copier severely limited. A higher performance would be achieve if for the blue and green color separation in this spectrum rich emitting LED lines would be used. Blue and green stan dard LED chips have edge lengths of about 350 microns, so that the required resolution for photographic prints with such LED lines is not is achievable.  

A high-performance print head is described in US Pat. No. 5,754,217. Here will A digital micromirror device (DMD) is used, which emits the light of a light source is modulated according to the image information. To the with this print To increase the achievable resolution between the light source and the DMD Mask provided, each only a part of the area of each individual mirror releases. This section shifts from line to line. With this, as the photo paper moves past the print head, one line of the Expose photo paper with a variety of mirror lines of the DMD. The on solution can be multiplied accordingly in this way.

However, it has been shown that when using such a print head grayscale resolution suffers, d. H. that brightness gradations in the picture are not are clearly recognizable.

It was therefore the object of the invention to provide a device for exposing Form image information on light-sensitive material so that the requirement to a photographic copier with regard to the location and the Grayscale resolution and print performance can thus be met.

The task is solved by a device with the features of An saying 1. By arranging the mask between the light source and the photosensitive material is the part of the mask which is not absorbed by the mask Reflect light in the opposite direction to the light-sensitive material animals. Because the mask does not emit any light in the direction of the light-sensitive Ma terials reflected, as in the device described in US Pat. No. 5,754,217, the amount of scattered light can be reduced to such an extent that the grayscale resolution solution meets the requirements.

With this arrangement it was possible for the first time to achieve the high performance blue and green LEDs, whose light emission lies in the spectral range in which  Photo paper has its sensitivity maxima, with the high resolution (Spatial and grayscale resolution) to unite today by a fotogra fishing copier is required.

There are several LED rows arranged one behind the other for each exposure color intended. The openings in the mask are arranged so that each LED only a fraction of the light it emits can pass through. From the first LED line will consequently be only a section of a line on the photo paper thins out. In the next line of the mask, the openings are offset from the openings arranged against the first line of mask. As the paper advances, consequently the same line of paper exposed by the second LED line, the exposed pixels but - according to the mask openings - offset to the Arranged pixels that were exposed by the first LED line.

To ensure that each pixel in the image is of the same Be an LED is richly exposed in order to achieve a uniform and reproducible brightness in the picture are not just the mas openings, but also the LEDs themselves in the same way as the mas key openings offset line by line.

Such a line arrangement is especially for the blue and the green Exposure provided. The blue and green LED lines can turn on one carrier, but can also be distributed over two carriers. The Mask is advantageously applied directly to the LED array, so that too a one-part or two-part mask is to be provided here accordingly.

Of course, the invention is not limited to LED lines, but rather is applicable to all light emitters where a line-wise arrangement is not the required high resolution enables.  

It has been demonstrated that light emitters, especially LEDs, during their duty cycle both the brightness changes and the emis shift spectral bands. This means that during the one switching time of an LED changes the range in which its emission spectrum overlaps the spectral range in which the corresponding sensitivity maximum of the photo paper is. Even if the operating current during the Duty cycle by the control device, for example after a look-up Table is adjusted so that the brightness remains constant, this makes itself Spectral shift noticeable due to density fluctuations in the image.

With LEDs, this spectral shift can be up to 6 nm during the duty cycle wear. When exposing Agfa-CN photo paper with a GaAIAs LED ver the emission spectrum shifts, for example, in the direction of the red emp sensitivity maximums. At the same time, the intensity of the LED drops.

If you want to achieve a uniform density distribution on the photo paper, the LED must also be controlled taking into account the spectral shift. Only when both the brightness and the wavelength shift of the emitted light determined and the light emitter taking into account the spec central position of the sensitivity maxima of the light-sensitive material correct exposure of the light-sensitive material can take place gene.

According to the invention, photo sensors are therefore provided on the mask. In front each LED two sensors are assigned, each under measure different spectral components of the light emitted by the LED. The The control device can thus determine how the corresponding LED is readjusted must be so that the light intensity acting on the paper remains constant.  

The regulation is in the not yet published application DE 198 36 337.0 described in detail.

As this regulation always takes the current conditions into account occurring aging effects of the LEDs as well as environmental influences that affect their Radiation behavior, automatically compensated. Substitutions too of the LED units can be made without re-calibration would be required.

Further details and advantages of the invention result from the Unteran sayings in connection with the description of an exemplary embodiment, which is explained in detail using the drawing.

Show it:

FIG. 1 shows the schematic structure of an inventive LED arrays imagesetter,

Fig. 2 shows the schematic structure of a standard LED-chip with a chip disposed in front of the mask,

Fig. 3 shows the structure of Fig. 2, wherein the LEDs are offset row by row,

Fig. 4 shows the arrangement of light source, mask with lens array and photo paper and

Fig. 5 shows another embodiment with light source, lens array and photo paper.

In Fig. 1, the image information is exposed on photographic paper 1 , which is moved along the transport direction A, the image information. LED arrays are used as light sources, the individual rows of which are arranged perpendicular to the transport direction. Red, green and blue LED lines are used to expose colored image information. A high-resolution, red LED line 2 a with a front, red color filter 3 a exposes the red portion of the image information on the photo paper according to the control by means of the control device 4 . To expose the green and blue portions of the image information, several rows of green LEDs 2 b and blue LEDs 2 c are provided, which are preceded by a yellow color filter 3 b and a blue color filter 3 c. In both the green and the blue LED lines, a mask 5 b or 5 c is arranged between the LED lines and the photographic paper.

Instead of LEDs, light sources can also be switched very quickly LCD lines used in combination with a lamp illuminating the lines become.

In principle, one can also be used for the red LEDs instead of the high-resolution line Arrangement with several lines and a mask can be selected. In this case it would also be possible instead of connecting the three color arrays in series arrange one red, one green and one blue row one after the other.

Fig. 2 shows schematically the structure of the green or blue LED rows 2 b or 2 c seen from paper 1 . The individual LEDs 2 are arranged in five rows, each with 6 LEDs in one row. In front of the LEDs is the mask 5 (hatched), which has an opening 6 for each LED with an edge length of 1/5 of the LED edge length.

In order to expose an image line on the photo paper, the LEDs of the first LED line 21 are first individually controlled depending on the image information.

As soon as the first LED line 21 has exposed the photo paper, this is moved one line further in the transport direction A, so that the openings 6 of the second line 22 come to lie exactly next to the image information exposed through the openings of the first line. The second line is then exposed through the openings in the mask. Then the paper is again transported one line in direction A. This process continues until all five LED lines have exposed the photo paper. The fully exposed image line of one color now appears on the photo paper.

If a continuous color separation is to be created on the photo paper, the photo paper may only be moved by the edge length of the mask openings. During the first five exposure steps, 21 partial exposures of the first five image lines are carried out by the first LED line. In the next exposure step, the sixth image line is under the openings of the first LED line 21 , while the first image line is under the openings of the second LED line 22 , with which the second partial exposure of this image line is now carried out. If the first image line is below the mask openings of the fifth LED line, this image line is completed with a final exposure.

In the arrangement shown in Fig. 2, however, it is difficult to prevent the light from adjacent LEDs from being imaged onto the paper through the mask opening of an LED, since here the LEDs must be very close to one another so that there are no webs on the paper the pixels of an image line arise. In addition, since the luminous areas of the LEDs are not homogeneous due to the bond points, it is disadvantageous if the openings of the mask are located at a different location on the luminous area of the respective LED in each row.

To eliminate these disadvantages, an arrangement of the LED, as shown in Fig. 3, is advantageous. Here the LEDs are always arranged at a distance of one LED width within one line. The LEDs are offset from line to line by the width of an opening 6 of the mask perpendicular to direction A. With an opening of 1/5 of the LED edge length, ten lines must now be arranged in succession so that a complete image line can be exposed on the paper. In this arrangement, the opening 6 of the mask can be located at the same point in relation to the LED luminous area, so that it never coincides with a bonding point 7 . In order to prevent the light of adjacent LEDs from being imaged through the mask opening of an LED, partition walls can additionally be provided between the LEDs in this arrangement.

A corresponding arrangement is shown in detail in FIG. 4. The LEDs 2 of a row are attached to a carrier 8 . Between adjacent LEDs there is a partition 9 , which prevents the light cones of two LEDs from overlapping. The light emitted by the LEDs passes through the openings of the mask 5 and is imaged onto the photo paper 1 via a lens array 10 . A self-lens array can be used as the lens array or an etched lens array in which the mask is vapor-deposited on the back. Of course, the mask can also be applied to its own carrier, which is arranged between the lens array and the LEDs. On the side of the mask which faces the LEDs, photodiodes can be attached which measure the light intensity of the LEDs and are connected to the control device, so that the intensity emitted by the LEDs can be regulated continuously.

Instead of the lens array with the mask - as shown schematically in FIG. 5 - a lens array or light guide array can also be used, which is arranged and constructed in such a way that the luminous areas of the LEDs are reproduced on paper in a reduced form.

So with an exposure of 6 "wide photo paper a resolution of 500 dpi is reached, the LEDs are arranged in 20 rows with 150 LEDs per row net, whereby the individual LEDs are in a 1 mm column grid.

Claims (12)

1. Apparatus for exposing image information to light-sensitive material with a light source which has arranged in several rows, independently controllable light emitters, with a control device for controlling the light emitter with a signal corresponding to the image information, the light source and the light-sensitive material being perpendicular to Row direction are movable relative to each other, characterized in that a mask is arranged between the light source and the photosensitive material, which is constructed so that a fixed part is covered with each light emitter. 2. Device according to claim 1, characterized in that the mask Has openings that are staggered from line to line, so that an oblique column arrangement arises. 3. Apparatus according to claim 1, characterized in that several ver different colored light sources are provided, each with several lines. 4. The device according to claim 1, characterized in that the light with ter are formed as LEDs. 5.. Apparatus according to claim 4, characterized in that the LEDs in emit green and / or blue spectrum. 6. The device according to claim 4, characterized in that the LEDs with Are spaced from each other.   7. The device according to claim 4, characterized in that the openings the mask and the LEDs are offset from line to line. 8. The device according to claim 7, characterized in that the offset each corresponds to the width of a mask opening. 9. The device according to claim 1, characterized in that the mask in arranged in a plane parallel to the plane of the photosensitive material is not. 10. The device according to claim 1, characterized in that between the Light source and the light-sensitive material pre-selected a lens matrix is seen and the mask on the side facing the light source Lens matrix is applied. 11. The device according to claim 1, characterized in that on the Light sensor side of the mask photo sensors are provided which are connected to the control device. 12. Device for exposing image information to photosensitive material rial with a light source, arranged in several rows, independently has controllable light emitters, with a control device for on control the light emitter with one corresponding to the image information Signal, with the light source and the light-sensitive material perpendicular can be moved relative to one another in relation to the row direction, records that between the light source and the photosensitive material a lens matrix is arranged, which is designed so that each light emitter is scaled down onto the light-sensitive material.