DE2617683A1 - Non-grainy raster for half-tone printing plate - has straight lines running broken or unbroken right across the plate - Google Patents

Abstract

Square cells of a gravure plate each have three straight line-segments as printing elements. The width of the line-segments is varied to give the tone density required at that cell. Co-linear elements from different cells form broken lines of variable density stretching right across the page. With this form of rater. Moire effects are avoided when line segments of different colours run in slightly different directions. An angular separation of 1 deg. can be enough. In another form, a half-tone original is photographed through a screen consisting of a set of parallel lines (450-1000 per inch) at right angles to which the tone density varies sinusoidally, with a maximum at each of the parallel lines.

Description

Raster image and process for its production.

The present invention relates to raster images and methods their manufacture.

With the known halftone printing, be it gravure printing or offset printing, can consider the printing plate and the final print made with it as in Think of elementary areas or cells divided. In the known case, each contains Cell of the final print image only a single raster point. In appropriate Each cell of the printing plate contains only a single ink-absorbing cell (Depression) or other pressure element. Furthermore, the grid points as well as the ink-absorbing cells or other printing elements to form the raster points generally a square, diamond, round, or other convex shape and the size of the halftone dots as well as cells or other printing elements (i.e.

in the case of a well, its area and / or depth depend on the desired tone density of the print at the location of the cell in question.

However, this creates a number of problems. For example occurs in areas of great brightness, where the amount of on the surface to be printed The ink to be applied is small, often one exposure, i.e. that out of many Cup no printing ink at all on the surface to be printed is applied. This danger exists especially with worn gravure printing plates. The cells in the highlight areas, which were not deep from the start, are then too flat to hold enough ink for reliable printing can. Exposure to pressure occurs particularly in both the highlight areas in gravure printing as well as in offset printing, and often as a result of irregularities of the paper to be printed and the like. Even if no suspension occurs, appears the print is often grainy, as the individual color points appear in the highlight areas a relatively large unprinted area (or, if you are printing in color, a relatively large differently colored area) and the point structure becomes common with the The screen rulings used are also visible to the normal naked eye.

The present invention addresses these problems to avoid and in particular a raster image element of new and highly effective form as well as an engraving, autotype and halftone printing process and facilities, which are suitable for both black and white printing and color printing and printing considerably facilitate; in particular, the risk should be avoided that in high light areas There is a break in printing or the printing appears grainy, as in the case of the known autotype processors and autotypes is the case.

This object is achieved by the raster image according to claim 1 or the method according to claim 11 or 16 solved.

In a grid according to the invention, the image is therefore discrete Elements formed that have multiple lines or strokes changeable or changeable Width included.

Such "modulated sound lines" ensure better distribution the printing ink on the surface to be printed and a significant improvement in Quality of the print.

The dashes or lines preferably have a high individually and substantially uniform tone density. The lines can be essentially extend continuously or uninterruptedly across the image, or the image can be in a plurality of cells can be divided into a substantially uniform area, wherein the lines are broken and each cell contains several such lines, or the image can be divided into a plurality of cells of substantially equal area be, with the lines broken and the cells depending on the Tone density of the image at the location of the cell concerned a different number of such Lines included.

In intaglio printing, a number of superimposed raster images, each of which corresponds to a different primary color of the same colored image template, produced by means of a corresponding number of color separation printing plates.

In each printing plate there is each unit cell with a number of Depressions for receiving ink and the width of each depression depends on the desired tone value of the relevant color separation at the location of the cell away.

In order to avoid moiré effects, the depressions in the various Color separation printing plates have different structures or screen angles or the cells the color separation printing plates have different sizes. However, there the tone lines # are modulated independently of each other in the different color channels are sufficient generally angular distances of only 10 to prevent the occurrence of moiré patterns. This is where the invention differs significantly from the known color autotypes, which normally work with angular distances of at least 150.

With color offset printing, several, overlaid, modulated tone value lines are used containing color separation images by means of a corresponding number of printing plates, each of which corresponds to the different primary color components of the same colored image template, manufactured. In every printing plate every tone line goes in essential continuously from one side of the printed image to the other and their width is from point to point according to the desired tone value of the to be printed Area to be formed color separation or partial image changed.

In the embodiments of the invention in which with uninterrupted modulated tone lines are not required to take special precautions required to prevent moiré patterns, as neither a grid of crossed Lines still an electronically generated equivalent are required for this. There are so there are no artificially generated patterns that can interfere.

In the following, exemplary embodiments of the invention are referred to explained in more detail on the drawing; They show: FIGS. 1A and 1B greatly enlarged schematic Top views of a sheet of paper or a printing plate, for example typical Halftone dots or halftone dot printing elements according to the known autotype printing techniques, those with grid points of constant area and variable depth (Fig. 1A) or variable area of constant depth (Fig. 1B); Fig. 2 is a greatly enlarged schematic top view of, for example, a sheet of paper or a printing plate, which is a first embodiment of modulated tone lines or elements for Printing modulated tone lines according to the invention, which are particularly useful suitable for gravure printing; show additional views on an even larger scale A sequence of different tone values with tone value lines starting at the top in a clockwise direction from highlight to shadow; FIGS. 3A to 3D are schematic, greatly enlarged and in Partial views seen from above, for example a sheet of paper or a The other examples of modulated tone lines or elements for printing plate Include printing modulated tone lines in accordance with the invention; Fig. 4A and 4B are schematic, greatly enlarged, partial views seen from above; the use of two forms of modulated tone lines or elements for printing modulated tone value lines according to the invention for color printing in particular for represent a gravure printing process; FIGS. 5A to 5E are schematic, greatly enlarged Top views showing the relation between the geometric figures, for example engraved by an electron beam in a copper plate or photographically by means of recorded by a laser, and the resulting printing elements or modulated tone lines; Figures 6A to 6C and 6E to 6G are schematic plan views and FIG. 6D shows a schematic, sectional side view, in each case on a greatly enlarged scale Scale, different parts of a facility and successive steps a method according to the invention for making the dot-forming elements; 7A is a schematic, greatly enlarged sectional view seen from the side various parts of a facility used in a different photographic process used to manufacture the halftone dot-forming elements according to the invention; 7B is a greatly enlarged schematic plan view of tone value lines or elements to print the tonal lines that will be found in the setup and procedure of Fig. 7A; 8 shows a schematic, greatly enlarged plan view, for example a part of a sheet of paper or a printing plate that modulated an idealized one Tone line according to the invention on a printing plate, a film for manufacture the plate, or an ink-receiving surface printed by the plate is, with different tonal values from highlight to shadow, with the structure can be seen generated by scanning a dissolution gauge; Fig. 9 is a schematic, greatly enlarged plan view of a printing plate for printing a final print or picture or photographic film for manufacture such a printing plate, with the same structure as in Fig. 8 but more so, how this structure will actually be created in the final print or image; Fig. 10 is a greatly enlarged, schematic plan view of, for example, a sheet of paper or film or a printing plate, which is an example of a modulated tone line according to the invention corresponding to a certain scanned part of an original image correspond; 11 is a schematic, greatly enlarged plan view of a part for example a sheet of paper or a film or a printing plate that corresponding to another example of a modulated tone line according to the invention the same part of the original image as in FIG. 10 and FIG. 12 a sequence on half sine curves showing the change in tone density in a modified form of a Line gray raster for the production of the modulated tone value line according to FIG. 10 represents.

In Fig. 1A, four conventional raster points are schematically shown in plan view 10a to 10d or elements for printing halftone dots are shown. Such grid points or printing elements for halftone dots are in practice quite small and close together, since they are supposed to give the illusion of a halftone image. Because of practical reasons the grid dots on most commercial car types are large enough and wide enough apart to be seen individually with the normal, unarmed eye to be able to. The image thus reproduced is therefore grainy Appearance that degrades image quality To explain and facilitate the Description, the elements 10a to 10d are much larger than shown in reality.

The figure is partially broken away to indicate that they both (in the flat part of the representation) as a representation of grid points on a sheet Paper, plastic or another printing ink-receptive surface or (in the broken away Part in the upper left corner) as a representation of elements for printing grid points as cells or depressions in a printing plate can be understood. The figure should first with regard to the printing elements and then with regard to the raster points to be discribed.

The elements 10a to 10d for printing halftone dots are essentially square and all have the same area.

They are contained in cells 12a, 12b, 12c and 12d, respectively square and slightly larger than the wells or depressions. The length one side of a cell is proportional to the reciprocal of the grid division or Grid width.

For example, with a screen ruling of 200 lines per inch the length of each side of a cell 1/200 of an inch. The cells 12a to 12d are not physically but only limited by imaginary lines 13 and the elements 10a to 10d for printing the halftone dots are centered with respect to the cells. In gravure printing, which represents one of the printing processes for which the invention is particularly suitable, are the elements for printing the halftone dots with respect to the surface of the printing plate deepened. The depressions or wells have a depth that is accordingly changes to the desired tone value (tone density). The deeper a given cell is, the more ink it absorbs and the larger and denser the printed one Grid point. The cells determine the resolution of the image, i.e. the resolution of the The smaller the cells, the larger the image.

If one looks at the figure as a representation of grid points so has the displayed part of the image has a constant tone value because the halftone dots all have the same size and density.

Fig. 1B is a schematic plan view of another type of four conventional halftone dots or elements 14a, 14b, 14c and 14d for printing Raster points which are arranged in cells 12a to 12d. Also Fig. 1B can either as a representation of grid points or of elements for printing grid points and is first viewed as a representation of elements for printing halftone dots and then described as a representation of grid points themselves.

The elements 14a to 14d for printing halftone dots are also recessed with respect to the printing surface if it is a gravure printing plate. The elements or cells for printing the halftone dots are round and have a uniform depth, but its area depends on the desired tonal value of the image at the point shown by the grid points. The bigger the cells are, the more ink they take up and the more ink is on the deposited area to be printed. The size of the resulting grid points increases with the area of the cells.

If Fig. 1B is viewed as a representation of halftone dots, so the displayed part of the image has a constant tonal value because all the raster points have the same size and density.

There are also gravure printing processes in which the cells are used for printing the grid points have a variable area and depth, so that the grid points accordingly be different both in area and in clay density can.

All three conventional halftone dot structures have substantial ones Defects, especially in the highlight areas where the tone density is low. In the Structure according to FIG. 1A, for example, is often used for printing in highlight areas due to depressions in the paper, as these may not be close enough to the Reach printing plate in order to be able to absorb printing ink. When the pressure plate wears out can also use the Cups in the highlight areas of the printing plate practically disappear and absorb little or no more ink.

In the grid type according to FIG. 1B, the grid points have 14a to 14d a relatively small one in the highlight areas and one in the shadow areas relatively large area. The printing elements are stored depending on the size or area of the Cups of different amounts of printing ink on the paper or

another area to be printed. In the highlight areas, where the cells are small, there is a particular risk of exposure to pressure large, since it is very easily possible that the small cups do not come into contact with the corresponding point of the area to be printed.

FIG. 2 shows a schematic top view of an embodiment of FIG new printing elements or modulated tone value lines according to the invention.

In rotogravure printing, the printing elements are with respect to the top or Recessed outer surface of the pressure plate. The cells are square and for a given They have the same grid size as the cells in FIGS. 1A and 1B. To the Area 16 around which is a photographic film for making a printing plate, the surface of a printing plate or the surface of a recording medium can represent several cells and the tone lines they contain shown on an enlarged scale. Starting at the top center are clockwise successive groups of cells and the cells they contain for the clay densities or values of 2%, 4%, 6%, 8%, 10%, 12%, 14%, 16%, 50% or 100% are shown. at In the illustrated embodiment of the invention, there are three tone lines per cell intended. The lines have a constant length and a width that is proportional increases with increasing tone density or tone value.

The lines are "hard", meaning that they are each the maximum possible Have dense and well-defined margins. At the same time, as a result of them, they are extreme elongated shape over spreads the surface of the cell, so that overall a tonal value range from 2% to 100% is covered.

As is known in the graphic arts industry, the cells are a grid even in the areas of deep shadows according to the tone density 100% never completely filled in, as some paper has to remain unprinted in every cell to prevent smudging or to avoid ink bleeding. When referring to tone value (or tone density) 100% "is a nominal value. The other tonal values correspond accordingly are graded, these are also nominal values.

3A to 3D are other configurations of line-forming Depicted intaglio elements or modulated tone lines according to the invention.

Fig. 3A shows linear depressions sloping towards the edges of the Cells run. This makes it easier to rub the non-printing surface of the Printing plate with a schematically shown doctor blade B. It is important that the Squeegee slides evenly over the printing plate, which is promoted when the indentations are elongated in a direction oblique to the direction of movement of the doctor blade runs. In Fig. 3A, the squeegee B can move over the pressure plate in the direction of the arrow, for example move so that the unsupported part of the squeegee is between the edges of a The recess over which the squeegee slides is not excessively long and the squeegee extends does not bend, dips into the recess and removes too much ink.

Fig. 3B shows depressions, which in terms of the shape of the effective Line or line structure are designed in the print image. The resulting strokes or lines give a better feature delimitation, since it is in the invention in In contrast to the conventional halftone dot shapes as shown in FIGS. 1A and 1B are, it is easier, the outline of the effective T # nvalues in correspondence with the Bring the edges of image features.

Fig. 3C shows another example of the shape of the strokes in a grid element according to the invention.

Fig. 3D shows cells arranged at a screen angle of 450 are, with the dashes or lines parallel to one and perpendicular to the other The cells run diagonally.

Also in this figure are five lines per cell instead of just three shown, so that this embodiment is a particularly effective distribution of the Results in printing ink on the surface of the cells.

In all of the embodiments described above, the lines are like this distributed that the geometrical figure with the shortest perimeter that the lines in of a given cell includes an area that is substantially is larger than the area of the lines themselves.

The relevant geometric figure is for the examples according to FIG. 1A, 1B and 3B represented by a dashed line 18. In Figs. 1A and 1B, the correspond to the state of the art, the geometric figure 18 is the smallest circumference, which can be paraphrased to the conventional elements that form halftone dots, a square or circle and has an area practically equal to the area of the halftone dot forming element 10a and 14a, respectively. In Fig. 3B, which is an exemplary Representing embodiment of the invention, the geometric figure includes 18 smallest Extent, which include the new tone value lines or elements for their formation can, an area that is much larger than that of the tone lines themselves covered area.

FIG. 4A shows an embodiment of FIG. 4 suitable for color printing Invention. In this case, strokes or lines are used which are different Form screen angle. In Figure 4A there are four cells from four different channels or color separations, for example yellow, magenta, cyan or

can be black. The cells correspond to each other, i.e.

they are all at least partially assigned to the same part of the picture, however, they are on different printing plates or color separation images. The occurrence of moiré patterns can according to the invention by a number of different Measures are prevented. In Fig. 4A, the grid points take different Screen angle, e.g. 00, 50, 100 or 150. In rotogravure printing, the Invention screen angle differences down to 1 ° can be used without Moiré effects occur. This is where the invention differs significantly from State of the art in which the screen angles for the various color channels must differ by at least 150.

Figure 4B shows another way in which moiré patterns are prevented can be. In this case the screen angles are the same, but the cell sizes are the same different from channel to channel. This will prevent interference between the various extract images avoided.

Another possibility, not shown, is to use different line structures. For example, the one shown in Fig. 3A shown structure for the yellow channel, the structure according to FIG. 3B for the magenta channel, the structure according to FIG. 3C for the cyan channel and the structure according to FIG Use Fig. 3D for the black channel.

The formation of the line-shaped printing elements can be different Way to be generated. For example, one can get latent images of the strokes through electronically using guided or controlled lasers on a photosensitive film of a facility as it is described elsewhere (US-Ser.No. 414 798 of November 12, 1973). The developed film serves as a partial mask, the one Copper plate covers and a selective etching of the plate in the places of the. respective Strokes enabled. Because of the side etching, the lines in areas of the plate the full shadow correspond, merge. Figs. 5A to 5E show some possible relationships that exist between the photographic Emulsion generated images and the depressions made in the copper plate for can exist in full shade.

In Figure 5A, the three straight lines in the film are side by side and the depressions in the copper plate merge to form a rectangle as the copper plate is laterally eroded by the etchant.

In FIG. 5B, the lines that are fully offset from one another form a chain-like pattern on the film in the copper plate.

FIGS. 5C, 5D and 5E show parallelogram-shaped, cross-shaped or H-shaped patterns, which are in the copper plate among many others by corresponding Arrangement and dimensioning of the lines from the film can be generated. In Figure 5C the lines are slightly offset so that they run obliquely or diagonally Form rows. In Figure 5D, the middle line is longer than the other two and centered on these.

In Fig. 5E the middle line is shorter than the other two and centered on these.

Referring to Figs. 6A to 6E, there is a photographic method of manufacture represented by images according to the invention, that without lasers and complicated electronics gets by. Figure 6A shows a commercial square cell position grid 12a, 12b, 12c, 12d and so on, which are formed by intersecting lines 20 and 22. The lines 20 and 22 are transparent, while the square lines they delimit Cells are opaque. Fig. 6B shows the latent or undeveloped image created by means of of the cross-grid positive according to FIG. 6A by contact copying of the positive grid on photosensitive paper, polymer, or lithographic film 28. In this case, the bar-like lines 20 and 22 after developing (the followed by a further exposure, as explained in connection with FIG. 6D becomes) opaque, while cells 12a, 12b. . are transparent.

6C shows a gray bar grid 30 through which the cells 12a, 12b etc. are divided. This grid has parallel vertical lines 24 passing through a sinusoidal change in the tone density of the emulsion can be formed. The tone density ranges from fairly transparent (between lines 24) to almost opaque (on the Lines 24) and changes sinusoidally across the film in the direction of the arrow. Such Screens are commercially available (e.g. from Polychrome, Dainippon Screen, etc.). A Raster with a line density (PXspace frequency) of 300 lines per inch, which is the finest Represents the screen ruling that is currently commercially available, with a cross-lattice grid, that has 100 squares to the inch is fine.

In Fig. 6D is a stack of film 28, line screen 30, and an Iialbton film 6; 2 on which the input image is formed. Of the Film 28 is at the bottom of the stack and includes a substrate 34 and a top emulsion layer 36 disposed thereon. The emulsion layer 36 contains the latent cross-grating image according to FIG. 6B. The line screen film 30 in the center of the Felt includes a substrate 38 and an emulsion layer disposed on its underside 40.

The halftone film 32 dzr to be reproduced is on top in the stack and includes a substrate 42 and an emulsion layer 44 facing down shows. The halftone film 32 is a typical autotype positive film with a maximum Clay density range from 0.06 to 1.85.

When the arrangement shown in Fig. 6D is exposed to light, the halftone image (input image 3 is set by the film 30 into a line screen image and this image is according to the initial image with the square cells Fig. 6B combined. The combined picture is partly in enlarged schematic Top view shown in the broken away part of Fig. 6E. When the photosensitive If film is a dichromated sole fabric for engraving or gravure printing, then it is he's ready for applying on that later too corrosive copper surface. In Fig. 6E, any parts of the modulated lines 46 represent a relatively have uniform width, image areas represent in which the tonal value is proportionate is constant while the parts of the lines 46 in which the line width changes, Show image areas in which the tone value is not constant. The line width changes across the image (is modulated across the image) while the density changes of the image changes between high and low values.

In the example of FIGS. 6A to 6E, one was used Cross-grating positive has been assumed, but the procedure can be reversed will. When the film emulsion is a silver halide gelatin emulsion, the image obtained in FIG. 6E is a negative. For direct autotype engraving which is marked with a light-sensitive anti-etching varnish (etching primer) that works on the copper surface sprayed or otherwise applied as a coating, one must, as in Fig. 6E as shown, form a positive film by conventional contact copying. In all cases the print, i.e. the ink on the paper, is the reverse of Fig. 6E. I.e. that the white areas are etched out and cells for receiving printing ink in the etched copper area. What is dark in Figure 6E represents the non-printing or unetched portions of the printing plate. Fig. 6F shows those in the printing plate and Fig. 6G shows the lines or dashes 47 'which are formed by the depressions are formed.

Fig. 7A shows another photographic method and apparatus for the production of the novel line or line structures according to the invention. In this case there is a rasterized positive 48 at the top of the stack A negative line screen 50 is located corresponding to the screened positive 48 the line gray grid 30 according to FIGS. 6C and 6D. There's a at the bottom of the stack Film 52 on which a combined image is formed.

The combined image is shown schematically in plan view in FIG. 7B. The parts of the lines of the gray line grid which are reproduced on the film 52, depend on the sizes of the transparent dot areas of the positive screen or film 48 from. Small, transparent halftone dot areas on film 48 enable reproduction only a small number of lines of the grid and only short pieces of it, as shown at 54. Larger transparent halftone dots in film 48 (Fig. 7A) allow a greater number of lines of the gray line screen to appear on film 52 and longer pieces of these lines are displayed as shown at 58. Even larger transparent halftone dots 60 of the positive autotype in film 48 (Fig. 7A) allow an even greater number of lines of the gray raster to be shown on film 52 and reproducing even longer pieces of these lines, as at 62 in Fig. 7A and Figure 7B is shown.

Fig. 8 shows an embodiment of the invention in which an im substantially uninterrupted modulated tone or raster line 64 is used. This embodiment is particularly suitable for offset lithography. The grid line the printing structure can be as you would on the surface of the printing plate sees or printed a printed line on a sheet of paper or other Area. The distance W represents the maximum width of the grid line element. At Electronic imaging can reduce the number of grid lines per inch in the direction perpendicular to the grid lines (i.e. perpendicular to the direction of the fast scanning) between 450 and 1000, for example. Line 64 represents five steps of progressively increasing tone value from top to bottom. The fifth step represents the tone value or tone density 100%.

Starting with an element L, four bits or elements are more uniform Size represented by the scanning of a part of a subdivision, grid or resolution grating can be generated.

Fig. 8 is idealized in that the corners are shown at right angles are. In practice, the image on that for the production of the printing plate will soften serving photographic image, the printing elements of the printing plate and the printed image from the recording medium to some extent from the ideal Shape. Fig. 9, in which the corners are rounded, agrees better with the actual ones Proportions.

10 shows the result of scanning a hypothetical original image. The upper part of the original image has a medium tone value with gradual changes in tone value. At the bottom is an area of sharp contrast and lots of detail. From the one At the end of the tonal value or raster line on the other hand, the printing image structure becomes through determines the image detail in the relevant color channel. In this embodiment there is no vertical moiré pattern as there is no artificially introduced pattern is how it is introduced by cross-hatch grids. The screen angles therefore play a role not matter. As the accuracy and size of the printing structure exactly match the picture detail correspond, the prints are characterized by excellent sharpness and detail resolution the end. Since the printing elements are either black or white, the manufacturing process is important plates and printing as reliable as current autotype processes, however, the results are much better. Moire pattern between the grid line structures are because of the high element density and because of the consistency of the structures with the bit details not visible.

In Fig. 10, the structure is from a right hand baseline modulated to the left. Of course, the invention also includes structures baseline on the left and modulation on the right. Fig. 11 corresponds the same hypothetical template as FIG. 10 and shows an embodiment of the invention in which for modulation a full envelope is used. This means that the structure starts from a baseline in the middle is modulated to the right and left.

The embodiments according to FIGS. 8 to 11 are particularly suitable for offset lithography. When producing the modulated lines according to FIG. 11 by a photographic process one can see the same gray line screen with sinusoidally changing tone density, as described above, in combination operate with a halftone image template and a light-sensitive recording film. The cross grid is of course not used. To manufacture the The modulated lines shown in Fig. 10 can be used instead of the one described above Gray line grid serve a modified form of a gray line grid which is the tone density corresponding to a sequence of half sine waves of one The minimum value changes to a maximum value as shown in FIG. Both Types of grid lines can also be made electronically through a facility of the above type mentioned.

Thus, the present invention is novel and very useful Raster dot structures and printing elements and methods for producing the raster dots specified. The exemplary embodiments described can of course be used modify in various ways without going beyond the scope of the invention.

In the invention, the "grid points" or

in the case of gravure printing, the depressions in the printing plate that receive the printing ink from several, discontinuous or broken lines, modulated or depending on the tone value On the other hand, especially in offset printing, the print image is wide or the printing, fat-free parts of the printing plate from a large number of continuous or uninterrupted tone or grid lines of variable (modulated) width can exist. In both cases the Quality of the final Pressure much better than before.

When the image is broken down into individual grid cells, each cell can contain several lines in the form of more or less elongated rectangles, where the rectangles in a given grid cell have the same widths and the widths the rectangle in the different cells depends on the tone value. The rectangles one Cell can have different lengths, preferably also have corresponding lengths Rectangles in different cells of the same length. The length can, however, also depend on the tone value be.

Claims (21)

Claims 1. An image made up of discrete elements, d u r c h g e -k e n n z it is true that the discrete elements have multiple lines of modulated width contain. 2.) Image according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the individual lines have a high and substantially uniform density to have. 3.) Image according to claim 1, d a d u r c h g e k e n n z e i c hn e t that the lines extend essentially continuously across the image. 4.) Image according to claim 1, which is divided into a plurality of cells essentially equal area is subdivided, d u r c h e k e n n n z e i c h n e t that the lines are broken and each cell contains several lines (18) (Fig. 2). 5.) Image according to claim 1, which is essentially composed of a plurality of cells equal area is subdivided, d u r c h e k e n n n z e i c h n e t that the lines are broken and that the cells vary according to the tone density of the image contain a different number of such lines at the location of the cells concerned. 6.) Image according to one of claims 1 to 5, d a d u r c h g e k e n Note that it is included in photographic film. 7.) Image according to one of claims 1 to 5, d a d u r c h g e k e n Note that it is contained in a printing plate. 8.) Image according to one of claims 1 to 5, d a d u r c h g ek e n It should be noted that it consists of printing ink on a recording medium. 9.) Image according to one of claims 1 to 5, d a d u r c h g e k e n It does not indicate that it is a color separation and that still further corresponding color separation images for the production of a color autotype are provided. 10.) Image according to one of claims 1 to 5, d a d u r c h g e k e It is not stated that there is a color separation sub-image on a recording medium represents and that still further corresponding partial color separation images of other colors are provided, which together form a rasterized color print. 11.) Process for producing an image recording accordingly an image template, that is to say, that the image template illuminates and with it a multitude of lines with changing modulated widths which represent the image recording. 12.) The method according to claim 11, d a d u r c h g e k e n n -z e i c h n e t that the lines with high and substantially uniform tone density are formed. 13.) The method according to claim 11, d a d u r c h g e k e n n -z e i n e t that the lines are essentially continuous across the entire image record extend. 14.) The method according to claim 11, d a d u r c h g e k e n n -z e'i c h n e t that the image is recorded in a multitude of cells essentially equal area is divided so that the lines are discontinuous and that each Cell contains several such lines. 15.) The method according to claim 11, d a d u r c h g e k e n n -z e i c h n e t that the image in a multitude of cells is essentially equal in area that the lines are broken and that the cells are divided according to the Tone density of the image at the location of the cell in question, different numbers of such Lines included. 16.) Method for producing an image recording from discrete Elements that do not indicate that a stack is formed, of an original picture, a photosensitive film and a grid with parallel Strokes, by at least partially continuous or steady Tone density changes are formed, and that the photosensitive film contains is exposed through the original image and the grid so that the discrete Elements of the image recording contain a plurality of lines of modulated width. 17.) The method according to claim 16, d a d u r c h g e k e n n -z e i c h n e t that the density changes are essentially sinusoidal. 18.) The method according to claim 16, d a d u r c h g e k e n n -z e i c h n e t that the photosensitive film is exposed through a cross grating is arranged around the original image in a large number of cells of essentially the same area to subdivide, the size of which is such that they contain multiple lines. 19.) The method according to claim 16, d a d u r c h g e k e n n -z e i c h n e t that the original image is a halftone image. 20.) The method according to claim 16, d a d u r c h g e k e n n -z e i c h n e t that the original image is a rasterized image. 21.) Image according to one of claims 1 to 10, d a d u r c h g e k e n n e i n e i t that the strokes are straight. Read more