WO2001058139A1 - Method and device for digitally detecting a photographic film - Google Patents

Abstract

The invention relates to a method for digitally detecting a photographic film (12) comprising a number of frames. The inventive method comprises the following steps: during a pre-scanning, at least one film pre-scanning section is projected onto a scanning element (18) used for carrying out the pre-scanning, whereby data of the film scanning section is detected by the scanning element (18). To this end, at least one characteristic quantity which is relevant to a subsequent principal scanning is ascertained from the detected data. During a principal scanning, at least one film principal scanning section is projected onto the scanning element (18), which was already used during the pre-scanning, while taking the at least one characteristic quantity into account. During pre-scanning, the film (12) is gradually advanced independent of the position of the frames and is scanned when at rest. During the pre-scanning, positioning data permanently assigned to the frames is detected for the principal scanning.

Description

Method and device for digitally capturing a photographic original

The invention relates to a method for digitally capturing a photographic original, in particular a method according to the preamble of patent claim 1 and a corresponding device according to the preamble of patent claim 20.

Such a generic method and such a generic device are known from the publication DE 198 05 048 A1. This document describes a method and an apparatus for digitally capturing photographic films which have a large number of individual images. A film is first scanned with a first resolution in a prescan. The positions of the individual images on the film and other parameters for a subsequent main scanning with a second higher resolution are then determined from the acquired scanning values. This main scanning takes place in a phase in which the frame to be scanned is in the rest position.

A so-called pre-scanner is used for the pre-scan with the lower resolution. While the film is being transported through the pre-scanner at a relatively high speed, three lines of the film arranged perpendicular to the direction of movement of the film are projected onto three sensor lines of the pre-scanner. The sensor lines are each covered with a color filter to obtain extracts from the film in the colors red, green and blue. In this way, film-specific data can also be determined in addition to the image positions. Alternatively, however, there is also the possibility of dividing a line of the film arranged perpendicular to the direction of movement of the film into a red, green and blue line using a color divider and then projecting it onto the three sensor lines. As a result, each cellular section of the film is simultaneously imaged on the three sensor lines.

The sampled values flow to a computing unit in which the positions of the individual images and other film-specific parameters are determined from the color separations of the entire film. For the main scan with the higher resolution, the film is positioned by a positioning unit in such a way that there is one frame in each case in the imaging beam path of a main scanner. This main scanner has, for example, a surface CCD array on which each frame of the film is scanned in the rest position. To do this, the area CCD array must have a size that ensures that the entire individual image is captured. The imaging can be done either directly or via a lens. The light for this main scan can be dyed using a suitable filter unit and the exposure can be carried out sequentially in the three colors red, green and blue. In the exposure control for the main scan, the parameters determined in the pre-scan are also taken into account.

However, a disadvantage of the device and the method is that two scanning devices must be used in order to carry out the two scans with the different resolutions. Already due to the necessary circuits, it is not possible to arrange the three sensor lines for the pre-scanning and the surface CCD array for the main scanning directly next to each other. The consequence of this is that, for example, two lighting units must also be used for the preliminary and main scanning. There are also two Electronic systems for evaluating and controlling the surface CCD array or the three sensor lines are necessary.

A device and a method for digitally capturing photographic films are also known from US Pat. No. 5,157,482. A pre-scan and a main scan are also carried out in the method described there. The pre-scan is also used to determine the image positions on a photographic film, in particular in addition to the marking notches used for this purpose on the film. However, it is assumed that at least one of these marking notches is present on the film, without which the image positions cannot be determined using this method. In the pre-scan, other parameters can also be determined, which are used in the main scan. Both the preliminary scanning and the main scanning are carried out section by section, the section to be scanned being in the rest position. One and the same scanning element can be used for the pre-scan and for the main scan. In order to obtain digital images with low resolution with the high-resolution scanning element, the radiation impinging on the individual pixels of the scanning element is first recorded and digitized. The resolution within the computing unit is then reduced by spatial integration of the digital image data. In the case of a scanning element used both for the preliminary scanning and for the main scanning, it is disadvantageous in the described device or the described method that the preliminary scanning is extremely time-consuming, since the film sections to be scanned are each positioned at the image positions for preliminary scanning and then scanned in the rest position must, which takes a long time, especially because the presampling is initially carried out in high resolution. Furthermore, this process is unsuitable for notchless films.

Accordingly, it is an object of the invention to develop a method and a device of the type mentioned in the introduction such that a Only a minimum number of equipment elements must be used and at the same time a fast pre-scanning is made possible.

The object is achieved by a method having the characterizing features of patent claim 1 and a device having the characterizing features of patent claim 20.

This object is achieved according to the invention in that during the preliminary scanning of the original - independently of the image positions - one preliminary scanning section after the other is projected onto the scanning element, so that all image data are recorded, but additionally positioning data of the original are also recorded which correspond to the image positions are permanently assigned. After the individual image positions have been determined from the prescanning, this positioning data is used to position the original at the main positions on the image positions by being rescanned during the main scanning.

For the preliminary scanning, the original is first divided into template preliminary scanning sections, which can then be scanned one after the other or simultaneously. A template pre-scanning section is to be understood, for example, as a template line which is arranged perpendicular to a direction of movement of a template within the device according to the invention. However, it can also be image sections, whole images or any part of the template.

Among other things, the sections of a template which are to be subjected to the subsequent main scanning are determined in the preliminary scanning. These sections are therefore referred to as master main scanning sections. Such a template main scanning section can, for example, represent a single image on a template. In contrast to the device described in US Pat. No. 5,157,482 or the method described therein, the master main scanning sections can be determined in the preliminary scanning here without marking aids on the master. The individual extracts which were obtained during the scanning of the template pre-scanning sections must then be combined again to form an overall image which reproduces the entire template. It is important that the individual separations are positioned exactly in relation to one another, so that the edges corresponding to the edges of the template pre-scanning sections fit together exactly, so that no image information is lost, but none is received twice. The prerequisite for this is that the template can be transported between the projection steps and aligned precisely with the scanning device.

It can also be advantageous to transport the original further by less than the original pre-scanning section. As a result, an edge area of each template pre-scanning section is scanned twice, and when the individual separations are put together, overlap areas are created in the overall pre-scanning image. The overlap areas are determined by a computing unit and taken into account and corrected in the composition of the individual extracts to form the overall picture. As a result, it is no longer necessary to align the original too precisely, and it is possible to accept a slight offset between the preliminary scanning sections after or during transport.

The summary of an overall picture can include the entire template or only a part of it. Summarizing only part of the template is particularly advantageous if first parameters for the main scanning are already determined during the preliminary scanning in order to accelerate the method.

Image bridges can be found from the overall image data by identifying density jumps. These provide information about the positions of the individual images. The individual image positions are then correlated with the positioning data determined in parallel.

During the subsequent main scanning, the positioning data are recorded again so that the individual images can be assigned to the scanning element as master main scanning sections on the basis of these.

In addition, it is advantageous to determine the density range of the original as a parameter for the main scanning from the data of the preliminary scanning. The sensitivity of the scanning element can thus be adjusted accordingly in the main scanning.

It is also advantageous to derive important information for image processing from the data of the prescan. These include e.g. B. Color cast of the original and underexposure.

The positioning data to be recorded during the scanning can be recorded particularly advantageously by a part of the scanning element provided for this purpose. This is particularly recommended if the scanning element is large enough so that the edge areas of the original can also be imaged on it.

If the edge information of the template is to be used as positioning data, although the scanning element can only capture the image data, then a separate scanning element must be provided. This can be arranged on the stage for the template and can be designed, for example, as a small sensor line with its own lighting. However, it can also be illuminated with the radiation source for scanning the original. A further advantageous possibility is to arrange the further scanning element in the imaging plane of the original with the scanning element (18). It must be ensured that no stray light falls on the scanning element (18) when the further scanning element is illuminated. The detection of the position coordinates can take place during the preliminary scanning of the original or during the transport of the original between the scanning steps.

If there is sufficient computing and storage capacity, it is advantageous to determine the positioning data directly from the image data of the template or from data derived therefrom. For this purpose, a density or intensity profile of the original can be recorded during the preliminary scanning, which profile is then tracked again during the main scanning.

It is very time-consuming to save individual image lines yourself and to compare them with those scanned again during the main scanning. However, this can be advantageous if only the scanning element (18) is available and it cannot detect any edge areas.

In an advantageous embodiment, a density line (eg CCD line) can be provided which scans the density curve of the original. From this, the positions of the individual images can be determined on the one hand using detected jumps in density. B. a template line can be used to position the template in the main scan.

In a further advantageous embodiment, the edge information of the template is used as positioning data. The perforations of the photographic template or the DX code are suitable for this.

A further advantageous development of the invention provides that the magnification scale of the optics imaging the template on the scanning element can be selected such that not only the individual images of the template can be mapped onto the scanning element, but also any characteristic edge information that may be present - such as the perforation edges and the like in film templates DX code - with are projectable. This data is easy to analyze and enables simple positioning in the main scanning and very simple identification of the overlap areas of the pre-scanning sections and thus a less complex assembly of the scanned template sections to form a complete image.

A further, particularly advantageous development of the invention provides that the template can be projected during the pre-scanning in the rest position and can be moved between the scanning steps. During the pre-scanning, it is necessary to combine sensor elements into macro sensor elements in order to achieve the fast speeds customary today for pre-scanning of originals. This can be achieved, for example, by summing up the charges of individual pixels, preferably before the A / D conversion.

It is particularly advantageous to add up the charges on the sensor element (CCD) even during the readout process. This can be done on a CCD sensor, for example, by shifting the charges of several sensor lines into the readout line before it is read out pixel by pixel. The reading out pixel by pixel of this line then only takes place after the charge of a specified number of sensor lines has been added up there.

In contrast to the scanning method described in US Pat. No. 5,157,482, it is not necessary in the pre-scanning according to the invention to position the original in such a way that exactly one image of the original is imaged on the scanning element. There is no need for a sensor, through which marking notches in the film required for image positioning can be recognized. Accordingly, notchless films or originals that extend beyond the surface of the scanning element can also be processed. According to the invention, the template can be positioned independently of the image positions relative to the scanning element in such a way that in each case a template scanning section of this template can be projected one after the other or simultaneously in at least three colors, regardless of whether there is an image, part of an image, a film web, two images or any part of the original in the beam path. Between the projections of the template scanning sections, the template can be transported by a maximum of the extent of the currently projected template scanning section, so that the next section can be projected. In this way, the original can be scanned step by step by projecting and scanning one original scanning section after another on the scanning unit.

A device for carrying out the method according to the invention has a radiation source for illuminating the original, a scanning element for scanning the original, a computing unit for processing the data acquired during the scanning and a further scanning unit for scanning data which can be used for positioning the original during the main scanning are on.

The further scanning element can be a defined part of the scanning unit (18). For example, it can be designed as a density line of a surface CCD or can include the edge regions of the CCD.

However, since it makes sense to use the scanning element (18) completely for scanning the image data in order to record it with the highest possible resolution, it is particularly advantageous to provide a separate, further scanning element.

This can be designed as a sensor line on the template stage and can scan the template or parts thereof using the illumination of the radiation source or its own lighting. It is advantageous here that the sensor line has no influence on the preliminary and main scanning.

The further scanning element can also be arranged in the imaging plane of the original near the scanning element (18), it having to be constructed in such a way that no scattered light falls on the scanning element during the scanning of the positioning data. Although this light barrier is not very easy, this solution is advantageous because positioning data and image data are mapped using the same optics and lighting.

An advantageous embodiment of the further scanning element provides that the perforation or the DX code of the template can thus be scanned. This scanning is very simple and can be carried out with little effort.

In a further advantageous embodiment, the image data of the original itself or its intensity or density profile can be scanned with the further scanning element. The advantage of this is that this data can be derived from the image data itself, but large amounts of data have to be processed here.

The positions of the individual images of the original can be determined on a computing unit from the preliminary scanning. These image positions can then be correlated with the positioning data, and the correlations can be stored in a storage unit. The image positions are thus clearly assigned to the positioning data, the images can be positioned using the positioning data. The computing or storage unit is connected to the transport unit for the template, so that the template can be transported in accordance with the positioning data.

During transport, the original can also be scanned by means of the further scanning element, so that the transport can be carried out exactly to the position of the individual images for the main scanning.

A further advantageous exemplary embodiment provides that a part of the sensor elements is combined in the pre-scanning in such a way that at least two sensor elements are assigned to a macro sensor element and the radiation impinging on the macro sensor elements can be detected per macro sensor element. It has proven to be particularly advantageous to use the same scanning element for the preliminary scanning as for the main scanning. In order to increase the scanning speed, it is ideal if some of the sensor elements of the scanning element are pre-scanned to form macro sensor elements and a reduction in resolution is achieved in this way. The fact that only one scanning element can be used for both scans greatly simplifies the construction of the apparatus for the digital acquisition of a template. Only an electronic system for evaluating and controlling the scanning element is now necessary. In addition, one radiation source can be used for both scans. A further great advantage is that the dynamics of the scanning element are increased by the combination of the sensor elements, the factor of the dynamics increase being equal to the root of the number of sensor elements combined. This leads to the fact that the prescan can be carried out even with short exposure times or even at low exposure intensity and has a low sensitivity to noise. Due to the combination of the sensor elements into macro sensor elements, the preliminary scanning can be carried out extremely quickly.

In a further, extremely advantageous development of the invention, the macro sensor elements can be assigned to macro sensor sections, it being possible for one template pre-scanning section to be projectable onto at least three macro sensor sections in succession or simultaneously. This is particularly advantageous if the respective one preliminary scanning section is to be examined with respect to at least three different criteria.

A further advantageous development of the invention provides that the respective one preliminary scanning section can also be projected onto at least one sensor section which has sensor elements, the radiation impinging on the sensor elements being detectable per sensor element. That way you can information about the respective one preliminary scanning section is also obtained, which requires a higher resolution

Such a sensor section can be a density sensor section, by means of which brightness values of the one pre-scanning section in each case can be detected. In particular, if the exact limitations of individual images on a film are to be determined, a high resolution is necessary when recording the brightness values of the one pre-scanning section in each case

Advantageously, the device can have a beam splitter, by means of which the respective one preliminary scanning section can be projected onto the macro sensor sections and / or the sensor section at the same time. In this way, the information about a preliminary scanning section can be determined in a single projection phase

One of the macro sensor sections can be a density macro sensor section, by means of which the lightness values of the respective one preliminary scanning section can be detected. Furthermore, the density macro sensor section can have at least one macro sensor element, which, in a sensor element arrangement arrangement that corresponds to a transport direction of the original during preliminary scanning, has a higher number of sensor elements than the macro sensor elements of the remaining macro sensor sections in the sensor element arrangement, in particular if the remaining macro sensor sections in the sensor element arrangement have a relatively large number of sensor elements in the macro sensor elements, this development is extremely advantageous since the image limitations of the individual images on the original are perpendicular to the transport direction of the Template, can be recorded precisely in this way

A further, particularly advantageous development of the invention provides that the device has at least one color-dividing element through which the one template pre-scanning section can be projected onto three macro sensor sections in a red separation, a blue separation and a green separation. In this way, three different color separations can be obtained from one original prescanning section each.

A further advantageous development of the invention provides that the three macro sensor sections have an equal number of macro sensor elements, which are each composed of an equal number of sensor elements. A measurement value can be detected by each macro sensor element, which can then be assigned to a measurement value of a corresponding macro sensor element of another macro sensor section. The different color separations of each template pre-scanning section can therefore be detected by measured values that can be directly assigned to each other.

The at least one color-dividing element can comprise at least three color filters. The at least three color filters can be combined to form a stripe filter.

A further, particularly advantageous development of the invention provides that the at least one color-dividing element comprises a color divider, by means of which the respectively projected template pre-scanning section can be divided into a red separation, a blue separation and a green separation. It is therefore only necessary to expose the respective pre-scanning section in order to obtain three different color separations.

The at least one color-dividing element can be mounted in such a way that it can be moved into at least one position of use and into a storage position, so that it can be pivoted into the beam path for pre-scanning, for example, and can easily be removed again before the main scanning. A further advantageous development of the invention provides that the scanning element is a CCD chip, a line transfer CCD chip or a CMOS chip. These types of scanning elements enable fast clocking, so that new data can be recorded while data which have already been recorded can still be read out. As a result, the preliminary scanning can be accelerated extremely.

A further advantageous development of the invention provides that the radiation used for scanning can be generated by a radiation source which has LEDs. For the scanning of colored originals, it is particularly advantageous that LEDs are provided in at least the three colors red, green and blue. If an infrared scan is additionally required for scratch correction, it is advantageous to provide further LEDs which emit light in the infrared. It is particularly advantageous to provide LEDs as the illuminating radiation source, since LEDs can be switched very quickly, so that dead times caused by the filter changes can be avoided. In addition, LEDs have a very high light output, so that the scanning process is completed quickly. By means of these multicolored LEDs, the original for scanning each original scanning section is illuminated simultaneously or in succession in each of the at least three colors.

An advantageous development of the invention provides that the template in step (a) is transported in a first direction, while the template in step (c), that is to say in the main scan, can be transported in a second direction opposite to the first. This is particularly useful when only one scanning element is used for the pre-scan and the main scan.

A further advantageous development of the invention provides that in step (a) a template pre-scanning section opens in succession or simultaneously at least three macroser.sor sections is projected, which include macro sensor elements.

The projection of the at least one master main scanning section in step (c) can take place in a phase in which the respective main master scanning section being projected is in the rest position.

Steps (a) and (b) can be carried out in parallel in a particularly advantageous manner. In step (b), parameters relevant to the main scanning are determined. Carrying out the two steps (a) and (b) in parallel results in an enormous saving in time during the preliminary scanning.

Further advantages of the invention result from the embodiments of the invention described below. A first embodiment is explained in detail using two figures.

Show it:

1 is a front view of a schematic structure of a film scanner according to the invention for digital detection of a film,

Fig. 2 shows a detail of a plan view of a schematically shown Abtastiement of the film scanner according to the invention and

3 shows a schematic section of a film which is scanned step by step,

4 is a front view of a further schematic structure of a film scanner according to the invention for digitally recording a film. 1 shows the schematic structure of the first embodiment of the invention, a film scanner 10 for digitally recording a film. With this film scanner MO, pre-scanning and main scanning of a film 12 can be carried out in succession. A transport unit 14 first makes the film 12 for pre-scanning in one pass an arrow 16 indicated direction transported and transported back for subsequent main scanning in an opposite direction

When the film is moved in the direction of arrow 16 via a scanning element 18, which in this first embodiment is formed by a line transfer CCD chip, the preliminary scanning is carried out first, four cell-shaped sections arranged perpendicular to the direction of movement of the film 12 of the film 12 are simultaneously projected in a first projection phase by a light source 20 onto a prescan lens 22 which is mounted so that it can be pivoted in and out. A mirror hood 23 and a mirror shaft 25 serve to focus the radiation emitted by the light source 20 onto the film 12 as a whole In the beam path, a strip filter 24, which can also be swung in and out and consists of three color filters, is arranged in such a way that three of the projected sections of the film 12 are displayed as a red separation, as a blue separation and as a green separation directed a portion of the scanning element 18

2 shows a schematically illustrated section of the scanning element 18 with three macro sensor sections 28 formed by macro sensor elements 26, by means of which the three color separations of the three projected original sections are detected. Alternatively, the macro sensor sections 28 could also be more than in the direction that corresponds to the transport direction of the original have a macro sensor element. However, this alternative is not shown in FIG. 2. A macro sensor element 26 is formed by 40x40 sensor elements not shown in FIG. 2. The fourth projected section is formed by the Prescanning lens 22 is directed onto a density macro sensor section 30 of the scanning element 18. This density macro sensor section 30 has four times as many macro sensor elements 32 as the macro sensor sections 28 described above. At the same time, the macro sensor elements 32 are each formed here by 20 × 20 sensor elements, so that the number of sensor elements per density macro sensor section 30 corresponds to the number of sensor elements per macro sensor section 28. In total, the scanning element has 18 1024x2048 sensor elements. Only a sub-area is used for pre-scanning and combined into macro sensor elements.

The radiation that strikes a macro sensor element 26 or 32 is recorded in each case. While information about the color densities of the respectively projected cellular sections of the film is obtained by the color separations, brightness values of the film section projected thereon are recorded by the density macro sensor section 30. While the film 12 is being continuously moved by the transport unit 14, the brightness values are recorded by the density macro sensor section 30. In a projection phase, the film section is projected onto the macro sensor sections 26-28 in the rest position. A red, a green and a blue separation are recorded one after the other. The film is then transported further while scanning the density until the subsequent film section is projected onto the color macro sensor sections.

The scanning element 18 is connected to a computing unit 34, also shown schematically in FIG. 1, to which the entire data is transmitted. The positions of the individual images on film 12 and other film-specific parameters are determined with the aid of the data. Furthermore, a density profile is formed from the density values, which is correlated and stored with the image positions. After the preliminary scanning has ended, the computing unit 34 can control the transport unit 14 in such a way that the film 12, which is now being transported in the opposite direction of the arrow 16, is stopped when a single image is in the imaging beam path of the film scanner 10. The position of the individual image is determined in that the density profile of the original is recorded again by means of the density macro sensor section during the return transport. This profile is compared with the stored density profile correlated with the image positions so that the individual images can be found.

Another scanning device shown in FIG. 4 has an additional scanning element 48, which consists of a diode row and is illuminated by means of its own radiation source 40. The perforation and DX code of the film 12 are thus scanned so that they can be used as positioning data in accordance with the density profile.

In the main scan initiated in this way, a section of the film 12 - namely a single image in each case - is projected onto the entire sensor surface of the scanning element 18. The scanning element 18 now detects the radiation impinging on the individual sensor elements (not shown) per sensor element. A filter unit 38 is arranged above the mirror shaft 25, so that different color separations, in particular in the colors red, green and blue, can be recorded for each individual image. For this purpose, individual filters of the filter unit 38 which can be swung in and out are brought into the beam path. The three corresponding color separations can thus be imaged on the scanning element 18 by three successive exposures through different filters. The data obtained are read out from the scanning element 18 into the computing unit 34. The image data are modified by the film-specific parameters, which were determined during the pre-scanning, in order to eliminate, for example, special film-specific color casts.

In a second, not shown embodiment of the invention is in the

A first cell-shaped section of the film is projected onto a color divider by means of which each section of the film can be divided into a red, green and blue line. These lines are then one on three macro sensor sections Projected scanning element, which may be a CMOS chip in this second embodiment. A two-section section of the film is simultaneously projected onto a density sensor section of the scanning element, the density sensor section having sensor elements by means of which the incident radiation per sensor element is detected. In a subsequent projection phase, two adjacent line-shaped sections of the film are projected onto the three macro sensor sections and the density sensor section. This process is repeated until the entire film has been prescanned.

In a third embodiment of the invention, a pivotably mounted beam splitter is used to project a line-shaped section of the film simultaneously onto three macro sensor sections, which are also covered with pivotable color filters, and onto a density macro sensor section. In this third embodiment, all data of a film section are consequently recorded simultaneously, while in the embodiments described above the data on a film section are collected in at least two projection phases.

In a further embodiment of the invention, not shown, the light source 20, the mirror hood 23, the mirror shaft 25 and the strip filter 24 are replaced by an LED lamp house. LEDs enable short exposure times and avoid dead times that always result from changing the filter.

The LED lamp house can be used particularly advantageously in a further embodiment of the invention. In this exemplary embodiment, the pre-scanning of the film is carried out section by section, with each section being recorded while the film is at rest. After a section has been scanned, the film can be transported further by the extent of the section just scanned, so that the next section can be scanned. With each scan of an original section, a red, a blue and a green extract can be recorded by illuminating the original section in each of these colors. This method is explained in more detail with reference to FIG. 3. In the film 12, which has perforation holes 29 and a DX code 30, individual extracts 31 are obtained by mapping the template pre-scanning sections onto the CCD chip, the next and the previous template scanning section always being arranged such that an overlap area 32 of the Single statements result. An arithmetic unit finally assembles these individual extracts into a pre-scanned image of the entire film. Information from the overlap area is used for the exact alignment of the individual statements. For this purpose, the scanned perforations 29 or the DX code 30, which are identical in each case on the edge of the individual statements, are advantageously covered. Image content can also be assigned to one another using correlation methods.

This low-resolution, pre-scanned image of the entire film contains all the necessary color and density information, as well as the DX code and perforation. Furthermore, on the basis of the detection of density edges, it is now possible to recognize the image webs, so that the image positions can be clearly identified and the images can be precisely positioned during the main scanning.

The features of the individual described embodiments of the invention can be combined as desired.

With 3 sheets of drawings

Claims

claims

1. A method for digitally capturing a photographic template (12) with several individual images, comprising the steps:

a) in at least one preliminary scanning, projecting at least one original preliminary scanning section onto a scanning element (18) used in the preliminary scanning, data of the original scanning section being acquired by means of the scanning element (18), b) determining at least one parameter relevant for a subsequent main scanning from the acquired Data, and c) in a main scan projecting at least one original main scan section onto the scanning element (18) already used in the preliminary scan, taking into account the at least one parameter,

characterized in that the template (12) during the pre-scanning is moved step by step regardless of the position of the individual images and is scanned in the rest position and that during the pre-scanning the

Positioning data assigned to individual images are recorded for the main scanning.

2. The method according to claim 1, characterized in that individual extracts, which result from the scanning of the template scanning sections, into one

Total pre-scan image can be combined.

3. The method according to claim 2, characterized in that the total pre-scan image comprises data of the entire photographic template (12).

4. The method according to claim 2, characterized in that the total pre-scan image comprises data of a part of the entire photographic original (12).

5. The method according to any one of claims 2, 3 or 4, characterized in that the position of the individual images is determined as a parameter from the data of the total pre-scan image.

6. The method according to claim 5, characterized in that in the main scanning the main scanning sections are selected according to the position of the individual images.

7. The method according to any one of claims 2, 3 or 4, characterized in that the density range of the photographic original (12) is determined from the data of the overall scan image as a parameter.

8. The method according to claim 7, characterized in that in the main scanning the control of the scanning element (18) takes into account the density range.

9. The method according to claim 1, characterized in that the positioning data are recorded with a defined part of the scanning element (18).

10. The device according to claim 1, characterized in that the positioning data are recorded with a separate scanning element (18).

11. The method according to claim 1, characterized in that the positioning data comprise edge information of the template.

12. The method according to claim 11, characterized in that the positioning data comprise the perforation of the template.

13. The method according to claim 11, characterized in that the positioning data comprise the DX code of the template.

14. The method according to claim 1, characterized in that the positioning data comprise image data of the template.

15. The method according to claim 1, characterized in that the positioning data comprise the density profile of the image data of the template.

16. The method according to claim 9, characterized in that the positions of the individual images are assigned to the recorded positioning data.

17. The method according to claim 16, characterized in that the main scanning sections for the main scanning are positioned by means of the positioning data.

18. The method according to any one of the preceding claims, characterized in that a part of the sensor elements of the scanning element (18) is combined in the preliminary scanning such that in each case at least two sensor elements are assigned to a macro sensor element (26, 32) Macro sensor elements (26, 32) incident radiation per macro sensor element (26, 32) is detected.

19. The method according to claim 18, characterized in that the template is illuminated in succession with three colors in the prescan.

20. Device for digitally capturing a photographic original (12) with a plurality of individual images, the device (10) having a radiation source (20), by means of whose radiation at least one is scanned when prescanned

Original pre-scan section, on a subsequent main scan At least one master main scanning section, which can be projected onto a scanning element (18) for the acquisition of data, and a computing unit, by means of which at least one parameter relevant for the main scanning can be determined from the data recorded during the preliminary scanning, characterized in that a further scanning element (48) is provided, through which positioning data for the positioning of the individual images in the main scanning can be recorded in the preliminary scanning.

21. The apparatus according to claim 20, characterized in that the further scanning element (48) with the scanning element (18) for data acquisition

Unity.

22. The apparatus according to claim 20, characterized in that the further scanning element (48) is arranged on the stage for the template, so that the template or a portion thereof can be scanned directly.

23. The device according to claim 20, characterized in that the further scanning element (48) is arranged in the scanning element (18) for data acquisition, so that the scanning of the position data takes place via the same optics as the data scanning.

24. Device according to one of claims 20 to 24, characterized in that the further scanning element (48) is constructed and arranged so that the perforation of the photographic original can be detected.

25. The device according to any one of claims 20 to 24, characterized in that the further scanning element (48) is constructed and arranged so that the DX code of the photographic original can thus be detected.

26. Device according to one of claims 20 to 24, characterized in that the further scanning element (48) is constructed and arranged so that data of the template (12) can be detected.

27. The apparatus according to claim 26, characterized in that the intensity of the data of the template (12) can be recorded.

28. Device according to one of the preceding claims, characterized in that the computing unit is constructed in such a way that data of a template (12) comprising several individual images can thus be stored and edited.

29. The device according to claim 28, characterized in that the computing unit is constructed such that the positions of the individual images can be determined

30. The device according to claim 29, characterized in that the computing unit is constructed such that the positions of the individual images can be assigned to the positioning data detected by the further scanning element (48).

31. The device according to claim 26, characterized in that the further scanning element (48) is connected to the computing unit.

32. Device according to claim 31, characterized in that the further scanning element (48) is constructed and arranged in such a way that the positioning data can be recorded again during the main scanning.

33. Device according to claim 32, characterized in that the transport unit for the original (12) is connected to the further scanning element (48) or the computing unit, so that the image positions correlated therewith can be positioned during the main scanning on the basis of the recorded positioning data.

34. Device according to one of the preceding claims, characterized in that part of the sensor elements of the scanning element (18) is combined in the pre-scanning such that two sensor elements are assigned to a macro sensor element (26, 32) and which are assigned to the macro sensor elements (26, 32) incident radiation per macro sensor element (26, 32) can be detected.

35. Device according to one of the preceding claims, characterized in that the radiation source (20) of the device comprises tricolor LEDs.