The machine for obtaining said system is also object of the present invention.

The innovation finds particular even if not exclusive application in the field of high resolution images as for example in the making of films.

In this high resolution field the resolution is meant to be considerable, therefore of the professional type and may be rightly considered, even if not in a limitative way, as comprised within the value of 10 pixel pitch microns that is the distance between one pixel and another. Obviously by pixel is meant, in computer language, the known points which, together, compose an image.

This value is also commonly defined as raster <10.

The process itself for the transfer of the digitized image in pixel from the computer to the machine that carries out the reproduction is here defined as process of rasterization.

One of the main purposes, even if not exclusive, is that of production of printed circuits However nothing prevents the system and the machine from being used in any other field in which a photographic film is required, as for example the typographical field, etc.

Background Art In prior art, machines for sensitizing camera films with different

photosensitive materials and for a variety of purposes, are known.

The high resolution machines are substantially based on the use of a luminous head which sensitizes the photosensitive material or, in the technically more advanced solutions of a laser head.

The machine includes a cylindrical support for the photosensitive material or a flat support.

When a cylindrical support is used there are two solutions, either the drum is rotating and the head moves transversely in a to-and- fro movement, or the cylinder is fixed and is hollow, the photosensitive sheet is inserted inside it and the head is axially placed in it and moves not only alternatively in a to-and-fro movement but also rotates.

In this way with the respective movements suitably co-ordinated the digitized image is reconstructed by carrying the respective points one behind the other on the basis of the respective co- ordinates, up to the complete reconstruction of the image.

The solution on flat support is less used because it is considered complex and expensive, if compared to the previous ones and utilizes substantially the same principle, with the difference that it works as a plotter in which the plotting head moves on said surface along the respective co-ordinates, just like a drawing plotter in a computer.

All these solutions are expensive and difficult and in any case, require lengthy reproduction times.

The resolution is obviously higher in the laser versions, but the time and costs for the purchase and maintenance of the machine remain very high, also because of the presence of substantial mechanical parts in movement.

Analyzing these types of machines in all of them can be noticed the presence of only one operating head that can send one or more points at a time, in logic succession up to completion of the entire image on the surface chosen for the exposure, starting for example from an upper angle until reaching the lower diametrically opposite angle.

The logic succession of these steps makes practically impossible to increment considerably the operative speeds.

The aim of this invention is that of avoiding the above- mentioned drawbacks, and in particular of making an inexpensive, reliable, fast machine, that requires minimum maintenance and is easy to use and in which the resolution level can be the highest, that is without endangering in any way a necessary suitable resolution level as mentioned above.

This and other aims are reached as claimed by a system for the transfer of digitized images from a computer to a photosensitive support or vice-versa, characterised in that it comprises: - active flat plate means for the exposure or detection of an image, on which can be placed the sheet which must be exposed or subjected to detection, which involves a plurality of (n) illuminable sources of punctiform exposure or detectors, arranged in a fixed way in a raster of (n) squares, connected/connectable to the digital system of the computer image, and able, by means of suitable software, the one of the other to be activated, but operating only on one point, corresponding only to one pixel for square at a time, each square (n) of the raster being able to include a plurality of pixels or points of the image equal to (x), and in such a way that the total of pixels or points of the entire image is equal

to (nx).

- support means of said sheet on said active plate means, and - means for moving said active plate and/or said sheet, able to move one and/or the other of the one in respect to the other, according to digitized co-ordinates corresponding to at least said portion (n) of the entire image to be digitized, and activate for successive points one adjacent to the other illuminable sources of punctiform exposure or detectors, each time and step by step for the exposure on said photosensitive material, so that illuminable sources of punctiform exposure or detectors, sensitize/detect the entire surface corresponding to its own square (n) of the sheet to be treated, and this in order to obtain the entire image sensitized in an exact reproduction of the original with the aid of the (n) luminous sources /detectors, for this purpose each displaced in connection with each square of the raster.

In this way there is the immediate advantage to increase the transfer and sensitizing speed as many times as the sections of the raster (n) times.

This obviously considering the theoretic side and the fact that the electronic transfer operation moves at the speed of light.

Considering further, that there is a more complex processing and calculation, the operative times are reduced by more than 70%, with the further advantage of an important simplification of the system, lower manufacturing costs (for the active plate, common "LED" suffice ) etc.

Advantageously the movement is communicated to the photosensitive sheet that is kept suspended among the active plate and counter-plate in a cushion of air.

In this way the movement is very slight, fast and quick and does not involve considerable moving masses.

Furthermore the photosensitive material does not touch the surface of the active plate and is not damaged.

Advantageously said air bearing is made by means of a plurality of punctiform air-jets made in the opposite plates so that the sheet is kept suspended between the two surfaces, while the movement mechanism will clamp the sheet only on one side for its simple and limited movement.

These and other advantages will appear from the following embodiments with the aid of the included drawings whose details are not to be considered limitative but only supplied as an example.

Figure 1 is a schematic front view of the sensitizing active plate; Figure 2 is an enlarged view of an "n" portion of the sub-division raster that theoretically is made up of the image to be copied, including a plurality "x" of points or pixels that make up the image.

Figure 3 is a cross sectional schematic view of the machine involving the active plate, its counter-plate and the mechanism with the respective sensitizing sheet suspended and moved between the two plates.

Figure 4 is a schematic view of the movement scheme for the transfer of the image from the computer to the sensitive support, the inverse operation in a like and symmetric way being possible.

With regard to the above mentioned Figures, it is disclosed that: With 1, the active plate is indicated which includes in it a reticulation of "n" squares, each involving an illuminable LED

according to program (11) able to sensitize in a punctiform way a photosensitive film to be exposed (3) that is placed between said active plate 1 and a counter-plate 2.

Both the active plate 1 and the counter-plate 2 are equipped with a plurality of holes (12) preferably uniformly distributed that launch an opposite compressed air jet (f), in order to allow the support of a sheet suspended between them, self-centred in a respective air bearing, as schematically visible in Fig.3.

Advantageously the air jet holes are placed in-between the exposure LED 11 of the film 3.

The film or photosensitive sheet to be exposed (3) is introduced between the plates 1 and 2 by a loader as in prior art and clamped by a clamp or suitable clamping means 4, is therein kept suspended.

The plates in particular, are approached in a guide position and the active plate 1 is also in the position with the respective LED (11) to expose the film 3.

The support of the film 4 is movable by using means of the prior art shaped as a plotter to operate by scanner system the transfer of the image.

As disclosed in Fig.4, the image in the computer S, is divided in a plurality of sectors , as on a draughtboard, in which each sector of the respective raster "n" is a portion to be scanned.

The operation may also be carried out digitally by a control software and in this way a specular movement A-B-C-D will be obtained, that by translators, decoders and encoders and processors, will be suitably transmitted on the film of the photosensitive sheet 3 or vice-versa with an inverse process.

Coming back to the inventive concept, as mentioned, the invention relates to a system for the transfer of digitized images from a computer (S) to a photosensitive support (3) or vice-versa, characterised in that it comprises: - active flat plate exposure means (1) of said photosensitive material (3), on which can be placed said photosensitive material (3) that must be exposed, which involves a plurality of (n) illuminable sources of punctiform exposure (11), arranged in fixed way in a raster of (n) squares, connected/connectable to the computer system (S) relative to the digital image, and able, with a suitable software, to be one or the other (11) lighted according to the digitized image to be transferred, but carrying only one point (p), corresponding to only one pixel (p) per square (n) at a time, each square (n) of the raster being able to include a plurality of pixels or points of the image equal to (x), and so that the total of the pixels or points of the entire image is equal to (nx).

- support means (4) of the photosensitive material (3) on said active plate exposure means (1), and - movement means (5) of said active plate (1) and/or of said photosensitive material (3), able to move the one and/or the other of one of them in respect to the other one, according to digitized co-ordinates corresponding to at least said portion (n) of the entire image to be digitized, and to activate by successive points said illuminable sources of punctiform exposure, each time and step by step for the exposure on said photosensitive material (3), so that each source sensitizes the entire surface corresponding to its own square (n) of the material to be sensitized, and this in order to obtain the desired entire image with the aid of the (n) luminous

sources, for this purpose each dislocated in connection with each square (n) of the raster.

The system obviously is embodied in a machine that includes two opposite plates, an active one for the sensitization of the photosensitive sheet and an opposite one.

Both these plates have opposite air jet holes to support the photosensitive sheet (film between them).

A clamping system of the sheet between the plates will provide its movement.

More particularly, referring to the Figures it is disclosed that the photosensitive sheet is simply inserted between the two surfaces, one of which represents the support of the numerous light sources.

The light sources are arranged in order to cover the entire surface of the photosensitive sheet (film).

The relative displacement between film and light sources, allows to light any point of the film and therefore to sensitize it with the digitized image as wished and in the desired resolution level.

The machine consists of a pedestal inside of which is placed a box with the films and the system for their loading (the system is not described but it is of prior art as for example those used in the automatic sheet loaders).

For the transfer of each sheet in the exposition area inside of the said opposite plates.

The film is fixed before the exposure, in a biaxial movement system.

From the nozzles of the plates jets of air come out that keep the sheet always centred preventing its contact with the opposite

surfaces.

The plates are placed one close to the other but avoiding contact so that a cushion of air is obtained between the surfaces in relative movement.

The system may be made operative by a suitable software that will have the onus of giving instructions on the use, that is: - collect the digital data of the image; - prepare them in a way corresponding to the size and resolution required by the exposure device, so that they can be transmitted to the single light modulators, in correlation to the path that they describe in the exposure process.

The input to the exposure process is always given digitally.

The original image can be digitized also starting from a simple photo or similar support, by using scanners or other image digitizers.

If the image is supplied with vectorial data, this is rasterized by using the exposure resolution.

Before beginning the exposure process, it is necessary to adapt the size and the resolution of the image to the size and the variable parameters of the exposure device.

The ratio pixel: pixel is established.

This is determined by the mechanical characteristics of the exposure device, and of the measurement of the original image.

Thus a "bitmap" type image is obtained.

This can reduce the space needed and also be in a compressed shape.

As a result, the image is divided in single sectors corresponding to the square positions (n).

Additionally, the data of each sector are sorted in a sequence corresponding to the movement between exposure device and exposed object.

The data are transmitted to the single modulators (light sources) in synchronism with the relative displacement of position, in order to cover the entire surface of the area to be elaborated.

The displacement of the films occurs on two axes.

The pitch of the displacement also defines the resolution that the machine is able to give, and which can be different for each axis.

The stroke of each of the two axes is determined by the distance between the two adjacent points (spots).

When the path on the first axis ends, the second axis is displaced by one pitch.

The exposure ends when the second axis completes the entire stroke.

It must be highlighted that the solution adopted allows a displacement of the film with masses in minimum movement.

As the stroke is defined by the distance between the luminous beam "spots", this can be reduced to the minimum.

Thus is obtained a highly reduced total time of exposure and a precision certainly higher if compared to the traditional solutions.

Of course the system can also be utilized in an inverse way, that is for transferring a graphic image from a respective external support (e.g. paper) to the computer always as a digitized image.