DE3933854C2 - - Google Patents

Description

The invention relates to a method for reducing or avoiding the effect of Illuminated layer defects in cathode ray tubes during the point or line Exposure to a photosensitive material, taking place during the exposure process the one that is otherwise given in succession on the fluorescent screen from the same place, finally large exposure lines (pixels / strokes), now a cyclically recurring group side by side, finally large and successively controlled exposure lines (Strokes / pixel) for recording in accordance with the translational movement between CRT tube and recording material.

Cathode ray tubes are used as a recording light source for the Reproduction of colored original images and other possible uses since used for a long time for high quality and fast photo setting machines. Here is It is known to write whole letters, characters or figures one after the other on the Display fluorescent screen and using a lens on the light-sensitive material map or record. This material, usually a film, then serves as a print template for various subsequent printing processes.

Due to the further development of these photo typesetting machines to digital imagesetters, it is today possible, in addition to texts in appropriate types and sizes, line art and gra fishing elements to produce snapped images. With small points that can be generated (Pixels) on the film, e.g. B. of about 0.01 mm in diameter, can now be rasterized  High resolution images or even the color separations of a colored image or that colored picture yourself.

If you line up point by point on the screen of the CRT tube, a line is created (stroke). This lower a line that is on the right, that is to say that lights up in the Y direction, is differentiated one after the other light-palpated length. At the same time, the CRT tube is in the X direction relative to the light sensitive material shifted, so by lining up the lines the area to be exposed, for example that between an outside and an inside outline of a letter to be generated, expose. That means that one is always the same The location on the CRT tube finally produced a large line with continuous motion and clocked light keying generate an exposed bar on the light-sensitive material would.

Now it can happen that just within this single line used a flaw, such as. B. there is a hole in the phosphor layer of the CRT tube, as shown in Fig. 1. On a CRT tube 50 , a vertical line 51 is palpated, within which a defect 52 is present. If this CRT tube 50 travels horizontally, that is to say the X direction, over a light-sensitive material 53 , an illuminated bar 54 with an unilluminated fault line 55 would be generated by the stringing together of the light-keyed lines. Such defects can often only become apparent during the operation of a CRT tube, e.g. B. by visible errors in the generated image or text.

As a result, all cathode ray tubes had to be installed in a reproductive area advises to undergo a rather complex quality inspection. This sighting and Sorting process made the usable cathodes significantly more expensive  jet tubes.

In addition, fluorescent screen defects often only appeared during operation a reproducing device, resulting in an expensive replacement of the cathode ray tube led.

The object of the present invention is therefore to create a method with which it is possible, the disadvantages of a cathode ray tube shown in one Bypass reproducing device or even use it a defective tube in the light layer defects have been recognized and the effective life of the CRT tube as a result to increase that instead of a single playback area (stroke) multiple areas can be used simultaneously.

This object is achieved according to the invention by a method according to the features of Pa claim 1 solved.

The method according to the invention has the advantage that instead of a single playback area several, z. B. 8 areas can be used so that luminescent screen defects have less impact, d. that is, such defects are drawn  not as a continuously visible line through a reproduced area but can then just a point on the light as a reduced diameter of the defect produce sensitive material in only a small extent, which is mostly in the white teren treatment methods such as a downstream printing process approaches.

Another advantage in the use of a division at 8 Strokes causes each imaging range (stroke) is loaded only by _^1/8 of the jet stream. This leads to a significant increase in the service life of the CRT tube.

This also has the advantage that the CRT tubes are not included elaborate test methods must be selected, but also with Faulty tubes can be used.

The invention will now be described with reference to an embodiment and with reference took explained in more detail on the corresponding drawings.

The drawing shows

Fig. 1, a CRT tube having a defect as to the prior art,

Fig. 2 is a perspective view of a CRT tube in a digital photo setter

Fig. 3 is a schematic representation of the starting position between the CRT tube and photosensitive material.

Fig. 1 is already explained above as the prior art.

Fig. 2 shows an example of using a cathode ray tube 20 having a defect 21 in the upper region of the phosphor screen 22 in a digital photo setter. Letters "AB", lines, raster images, etc. can be imaged on the light-sensitive material 23 , as indicated by dash-dotted lines. This material 23 is then developed in a photochemical process and can serve as a print template for various subsequent printing processes, such as high pressure, gravure printing, offset printing, etc. By means of lens 24 and deflection mirror 25 , the jewei lig generated on the fluorescent screen 22 lines on the photosensitive material 23 in a reduction scale of about 1:14 are sharply imaged. Each line generated on the CRT tube is approx. 140 micrometers wide and can have a maximum usable height of 55 mm in the Y direction. This results in a resolution on the photosensitive material 23 of approximately 10 micrometers per line or 100 lines per mm when line by line is exposed.

CRT tube 20 , lens 24 and deflecting mirror 25 are moved at a continuous speed in the direction of the arrow "X". The mode of operation of a digital photo setting machine is known and need not be explained in more detail.

On the basis of the above-mentioned imaging ratios of a digital photo setting machine named as an example, the method according to the invention and its sequence will now be explained below. On the light-sensitive material 23 , the capital letters A and B are shown with a dash-dotted contour as an example of areas which a digital photosetter has to produce. A group of 8 lines 0-7 is initially shown on the fluorescent screen 22 , it being irrelevant whether 4 or 12 are used instead of 8 lines. Each individual line is individually light-keyed one after the other, the 8 lines of this group being shown in the drawing according to FIG. 2 as if they would light up together. This will be explained in more detail in the further course of the description. The line shows a defect 21 , ie in the area of this reproduction point there is a tiny non-luminous point, which would thus correspond to a non-exposed point on the light-sensitive material in a reduction of 1:14. It is pointed out here that both the lines 0-7 and the adequate lines 0'-7 ' in the latent image of the letter "A" on the light-sensitive material 23 are exaggerated in their dimensions and position for better clarity and explanation are. If, according to the conventional exposure method, that is to say only with a single exposure line in the case of the line 4 with the defect, the letters “A” and “B” would be generated, the letters generated with the film material 23 would develop a narrow unexposed strip (not shown), which would further impair all further letters or parts of the image in the line direction.

The image sequence to be exposed is stored in the computer / memory 32 as digital data information, here for the letter sequence AB and is specified as contour information in the form of a matrix of the number and length of the lines, etc. of the CRT tube controller 31 . This controller 31 now generates the line 7 on the fluorescent screen 22 first, so that this is mapped via lens 24 and deflecting mirror 25 on the light-sensitive material 23 as line 7 ' . At the same time, the CRT tube now moves in the direction of the arrow X, in this case in the direction of the line. In line with the driving speed, lines 6, 5, 4, 3, 2, 1 and line 0 are now more lightly keyed on the tube and mapped line-by-line on the photosensitive material 23 . As soon as line 0 has lit up, the next cycle repeats itself in such a way that line 15 now appears in its corresponding extent on the illuminated screen 22 at the location of the former line 7 and the cycle of the next lines decreases again to line 8 during the continuous movement of the CRT tube 20 takes place. The direction of travel of the CRT tube and the cyclical direction of the individual lines on the light-sensitive material are in opposite directions. A cycle of a group of 8 lines runs within 240 microseconds.

It can be seen that the phosphor screen defect 21 shown as an example can only very rarely appear within a 10 micron wide line on the photosensitive material 23 if this defect is still within the line lying in the Y direction.

It should also be pointed out that in the display area of the CRT tube 20, the smallest possible dots (pixels) with a diameter of approximately 140 micrometers and smaller can also be generated within the maximum line image. The method according to the invention is thus not limited to the production of letters, line templates or rasterized black and white reproductions, but is also suitable for the color reproduction of images if corresponding color fields and another light sensitive material are used.

Fig. 3 shows schematically again the position of the CRT tube 20 to the photosensitive material 23 , in this case also the starting position. The 8 Figure 0-7 places on the tube 20 are preferably positioned so that an unused area of the same width as the picture type is present between the locations 0-7 respectively 0-7, currency rend on the photosensitive material 23, the lines 0 ' 7 ' lie directly next to each other.

These unused areas result from the fact that groups of 8 strokes are always exposed opposite to the X direction of movement of the tube. So z. B. first of stroke 7 as Figure 7 ' exposed. Stroke 6 is then exposed as image 6 ' . Since the picture tube plus optics has now moved a stroke width over the photo-sensitive material, the stroke 6 must be offset by 2 stroke widths to 7 on the picture tube 20 to lie side by side to 7 ' .

Claims (6)

1. A method for reducing or avoiding the effect of luminescent layer defects in a cathode ray tube used for reproduction, wherein on the tube along a single, always in the same place imaging line, successively points and finite large lines can be generated, which by means of an objective on photosensitive material are focused, and that a translational movement takes place between the tube and the photosensitive material, characterized in that instead of a single usable lighting location (line) on the tube, there is now a cyclically recurring group ( 0-7 ) of adjacent, finally large and sequentially controlled (brightly-keyed) exposure points and lines (strokes / pixels) in accordance with the translational movement and the location to be exposed on the photosensitive material ( 23 ) on the cathode ray tube ( 20/22 ) can be displayed. 2. The method according to claim 1, characterized in that a group of eight loading locations ( 0-7 ) on the fluorescent screen ( 22 ) is provided, in each of which points or finally large exposure lines ( 0-7 ) can be formed, one after the other beginning in the direction of movement (X) with the exposure location "O" and ending with exposure location "7" are light-keyed and imaged on a lens ( 24 ) as exposure strokes ( 0-7 ' ) on a photosensitive material ( 23 ). 3. The method according to claim 1, characterized in that consecutively callable exposure lines are assigned to the respective loading locations ( 0-7 ) in the figure eight cycle. 4. The method according to claim 1, characterized in that the usable exposure locations on the fluorescent screen ( 22 ) and the associated exposure cycle consist of groups and are formed by any number. 5. Process according to claims 1-4, characterized in that the usable exposure locations ( 0-7 ) on the luminescent screen ( 22 ) are arranged in a grid-like manner, the distance between the imaging locations in each case the width of the exposure lines ( 0-7 ) corresponds. 6. The method according to claim 1, characterized in that the group of exposure locations ( 0-7 ) are used non-cyclically and the subsequent exposure location on the fluorescent screen ( 22 ) is determined by a random generator.