DE3309231A1 - Method for offset/deep printing conversion - Google Patents

Abstract

The invention relates to a method for offset/deep printing conversion, the raster image being transformed by Fourier transformation into the local frequency space, the local frequencies corresponding to the raster being filtered out in a narrow band fashion, and the local frequency spectrum thereby produced being transformed back into a real image. This method facilitates conversion to a non-raster image with minimum loss of image sharpness.

Description

Process for offset / gravure conversion

The invention relates to a method for offset / gravure conversion.

It is known to descreen offset lithographs with the help of a Carry out scatter film (DE-AS 24 32 993). The main disadvantage of this procedure lies in the loss of sharpness associated with this "blurring test".

Another known method (Hell, Klischograph 1982, p.24) causes the descreening by means of a scanner using a so-called.

Surrounding panel. Even with this method, however, there is a certain loss of image sharpness inevitable.

The invention is therefore based on the object of an offset / gravure conversion, i.e. the descreening of a screened image in offset with a minimal loss of image sharpness to reach.

This task is according to the invention by the in the characterizing part of claim 1 mentioned features solved.

As is known from communications engineering, non-periodic can also be used Signals by way of the so-called.

Fourier transform can be represented by a frequency distribution. An image can therefore also be analyzed by evaluating the fluctuations in color density contained therein in the form of a spectral distribution of the Image frequencies (the so-called spatial frequencies) represent.

In the method according to the invention, the rasterized image is offset in an analog or digital way through a Fourier transformation into the spatial frequency space transformed. The spatial frequency spectrum obtained in this way then becomes the grid corresponding spatial frequencies are filtered out in a narrow band. By reverse transformation the freed from the grid spatial frequencies spatial frequency spectrum is then a obtained de-screened real image, which is characterized by high image sharpness, in particular also the image frequencies contained above the raster spatial frequencies contains.

The invention is further illustrated by the description of two exemplary embodiments explained in more detail. In the drawing, FIG. 1 shows an example of a spectral distribution the image frequencies, Figure 2 is a very schematic representation of a diffraction image of the grid, Figure 3 is a schematic diagram of a device for implementing the invention Procedure (with transformation in an analogous way).

Fig. 1 illustrates a spectral distribution of the image frequencies, where in the abscissa the local frequency and in the ordinate the Frequency is applied.

The solid curve 1 shows the spectral distribution of the image frequencies of the rasterized image in offset. This spectral distribution contains at the frequency #fR a spatial frequency corresponding to the grid with a high peak value. If it succeeds, to filter out this spatial frequency fR corresponding to the raster in a narrow band (i.e. to remove the hatched area from the spectral distribution), so is A descreening of the image is achieved with minimal loss of image sharpness.

3 illustrates a device with which the inventive O / T conversion can be carried out in an analogous way.

The device contains a laser 1 as a source of monochromatic, coherent light. An expansion optics 2 is used to expand the laser beam so that that a slide 3 to be arranged in level E1 is fully illuminated. The attachment also contains lenses 4 and 5. The focal plane of lenses 4 and 5 is with E2 denotes, the imaging plane with E3.

The first step is to use level E1 instead of slide 3 A screen film is inserted that has the same screen frequency and screen angle as the rasterized image has an offset (slide 3), but a constant area coverage (e.g. 50%).

A diffraction image of this grid is created in the E2 plane, which is illustrated schematically in Fig.2. If one classifies in this level E2 Lithfilmnegativ, a screen filter is produced that uses this diffraction pattern wearing.

This diffraction pattern represents a Fourier T transformation of the grid represent.

In a second step, the rasterized image is created in level E1 in the offset, i.e. the slide 3 arranged. This is now on level E2 Raster filters produced in the first step.

This creates a back-transformed from the grid in level E3 exempted image, for example with the interposition of a gravure contact grid 6 can be recorded on a lith film 7. The one arranged in level E2 Raster filter is identified by the reference number 8.

The diffraction pattern of the grid generated in the first step is independent of any translational movement of the original. The raster filter 8 filters therefore also the screen frequencies off if the image to be descreened (slide 3) is moved.

The one used in the method of the invention for O / T conversion Fourier transformation is therefore particularly suitable for the descreening of images, because the grid structure is different in terms of periodicity and spatial frequency distribution differs in a striking way from the other picture elements. The selective filtering this local frequencies in the Fourier space also contains the image content, which correspond to very high spatial frequencies (i.e. the part of the spectral range in Fig. 1, which lies above fR) and thus preserves the image contrast.

In the context of the method according to the invention, the Fourier transformation can also be carried out digitally using an image computer. To this end, will by digitally scanning the rasterized image in offset, first a matrix of Brightness values generated and from this by Fourier transformation of this matrix the spatial frequency spectrum of the rasterized image (i.e. curve 1 according to Figure 1) is established.

Then, in this spatial frequency spectrum, the one corresponding to the grid is used Spatial frequency fR determines what with regard to the pronounced peak value of this Frequency is not a problem. Then this local frequency is narrow-banded removed from the spatial frequency spectrum. This can expediently be done in such a way that only the peak value contained above the dashed line 2 (FIG. 1) cut off, the spectral distribution is thus freed from this peak. That Spatial frequency spectrum modified in this way is then digitally converted into a de-rasterized, real image transformed back.

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Claims (3)

Claims: @ Method for offset / gravure conversion, characterized through the following process steps: a) the rasterized image is offset by Fourier Tc transformation transformed into the spatial frequency space; b) from the spatial frequency spectrum are the the spatial frequencies corresponding to the grid are filtered out in a narrow band; c) that of the spatial frequency spectrum corresponding to the grid is freed transformed back into a real image. 2. The method according to claim 1, characterized in that the analog Conversion with the help of monochromatic, feces running light a) in a first Work step a diffraction pattern of a grid with the same grid frequency and angle like the rasterized image in offset, but with constant area coverage and a screen filter is produced with this diffraction pattern, b) and in a second step the rastered image is offset into the beam path brought, the screen filter arranged in the diffraction plane of the screened image and thereby a real image freed from the grid is generated. 3. The method according to claim 1 for digital conversion, characterized in that that a) by digitally scanning the rasterized image in offset a matrix of Brightness values generated and from this by Fourier transformation of this matrix the spatial frequency spectrum of the rasterized image is produced, b) then the spatial frequency corresponding to the grid is determined in this spatial frequency spectrum and is removed from the spatial frequency spectrum, c) after which that of this the grid corresponding spatial frequency freed spatial frequency spectrum digitally in a real image is transformed back.