EP0700853A1 - Method for driving and controlling, with application in the further treatment of printed products - Google Patents

Abstract

The control system is used for processing previously printed products for assembly into a magazine, brochure, or newspaper etc., using control pulses provided by comparing an image of each printed product with a reference image. A number of image processing modules (1) are used for respective momentary processing stages, each allowing a scanned image, provided by an image scanner (2), to be compared with a reference image. Each module has image inputs and outputs (Ii,Oi) and control pulse inputs and outputs (I1,I4,I4',O1), with interconnection of the modules via their inputs and outputs, to obtain the required control system configuration.

Description

The invention relates to a method according to the preamble of the independent method claim for checking and controlling processes for the further processing of printed products. The invention further relates to an arrangement according to the preamble of the corresponding independent claim for performing the method.

Printed products are processed further, for example by folding, cutting, collating, binding, stapling, addressing, packaging, etc. In the course of such processing, printed products from the printing press, intermediate products and finished products are manipulated and transported in continuous product streams, if possible. Both the various printed products resulting from the printing press and the finished printed products resulting from further processing steps, such as newspapers, magazines, brochures etc. or corresponding intermediate products, do not necessarily differ in their shape or other easily measurable physical properties, but they do differ in the printing, that is means in its optical appearance. For this reason, control procedures for the control of printed products and printed products are increasing applied on the basis of image processing, especially since image processing methods have become sufficiently quick and easy to use. Such control methods are then also described, for example in patent application CH-01748 / 94-8 (F383) by the same applicant or in publication US-4953841.

For these described methods, images of products conveyed one after the other into the area of the recording device are recorded in a clocked sequence with the aid of a recording device, for example with the aid of a camera or a line-reading device, the recorded images are compared with a target image and the comparison results used to generate corresponding signals (alarm signals or control signals), which usually initiate a reaction to an irregular product (image comparison shows no match), either a reaction by an alarmed operator or a reaction by one or more downstream arranged, appropriately controlled device parts, for example, diverters.

The use of the known control methods on the basis of the image processing always perform an island-like control function in the further processing of printed products, which has to be adapted accordingly as soon as the resulting product and / or the type of processing changes. In further processing processes in which several different printed products are processed at the same time, i.e. for example when gathering different printed sheets for the production of a magazine, several such control functions are also used in parallel with one another, these controlling the feed of the different sheets independently of one another, for example these, also independently of one another, have to be adapted to the manufacture of each specific product. For the production of frequently changing products and in particular for the production of so-called individualized products, the known control methods with image processing are still quite complex for the reasons mentioned, in particular if a plurality of different image processing operations are necessary for a satisfactory control of the entire further processing.

The invention therefore makes it its task to provide a control and control method based on image processing applicable for processes of further processing of printed products, which control and control method can be used simply and safely not only with frequent product changes and / or with the production of individualized products but that can also be used as a control procedure for such production changes. Furthermore, it is the object of the invention to provide an arrangement for carrying out the method, which arrangement can be adapted in a simple manner to the most varied of printed products, to the most varied of further processing steps and to the most varied combinations of further processing steps.

This object is achieved by the method and the arrangement as defined in the patent claims.

The invention is based on the idea of functionally networking a plurality of image processing modules to form a monitoring and control system for the monitoring and control of a further processing process of printed products. Each image processing module is primarily a functional, procedural unit, not necessarily a device-based unit. In each image processing module, images read into the module are compared with a stored target image, essentially in a chronological sequence of comparison steps, and control pulses are generated generated, not only depending on the corresponding comparison result, but also depending on the current processing state of the image processing module in question. The control pulses generated are used to control processing and / or transport devices (for example, diversion points) and in addition to change the current processing state of the relevant image processing module and / or the current processing state of further image processing modules and / or their stored target images. Furthermore, the functionally networked system of image processing modules can also be subordinate to a higher-level intelligence, which in turn act on individual or all of the image processing modules, so that their current processing state and / or their target image can also be changed by the higher-level intelligence. This higher-level intelligence can also have access to an image library in which images from external sources or from image processing modules are stored. The current processing state of individual or all image processing modules can also be changed by operating personnel via corresponding input elements (operating elements).

The function of the image processing modules is clocked, whereby the clock can be given by a central or individual clock generator, so that the function is rigid and regularly clocked, or the clock is given on the basis of the measurement of an appropriately arranged sensor, which gives each product of a product stream an individual Clock is assigned.

The image processing modules are designed in such a way that they can be functionally connected on the one hand to image recording devices and on the other in various ways to one another, with a higher level of intelligence, with input elements and / or with processing and / or transport devices used for further processing of the printed products. The image processing modules can represent software-based units or can be implemented in part in software or in part in hardware. An arrangement according to the invention for carrying out the control and control method according to the invention then has a plurality of image recording devices, for example video cameras, and a plurality of image processing modules, connections being implemented between the image processing modules, by means of which control pulses and / or image data can be transmitted from module to module. For particularly simple applications, it may happen that only one image capture device is sufficient.

The expression “image” used in the above description of the method according to the invention (also in image recording device, image processing, image comparison) is to be understood in the broadest sense as optically detectable information or digitized form of optically detected or optically detectable information. The "image" can thus be, for example, a printed pattern (graphic, text), an image in the narrower sense or a code (e.g. bar code). Depending on the type of "image" that is to be processed, various devices known per se, such as video cameras or laser reading heads, can be used as image recording devices.

Figuren 1 bis 3

Funktionsschemata von beispielhaften Bildverarbeitungsmodulen;

Figuren 4 und 5

die Anwendung des erfindungsgemässen Verfahrens zum Sortieren von Druckprodukten (Figur 4) und im Detail ein für diese Anwendung eingerichtetes Bildverarbeitungsmodul (Figur 5);

Figur 6

die Anwendung des erfindungsgemässen Verfahrens zum Sortieren mit Rückführung;

Figuren 7 und 8

die Anwendung des erfindungsgemässen Verfahrens zur Herstellung individualisierter Druckprodukte durch gesteuertes Zusammentragen verschiedener Teilprodukte (Figur 7) und im Detail ein für diese Anwendung eingerichtetes Bildverarbeitungsmodul (Figur 8);

Figur 9

die Anwendung des erfindungsgemässen Verfahrens für eine beispielhafte Kombination verschiedener Weiterverarbeitungsschritte zur Herstellung von Druckprodukten.

The method according to the invention and the arrangement according to the invention for carrying out the method, in particular the image processing module and possible functional connections between image processing modules, and applications of the method according to the invention in the area of further processing of printed products are now to be described in detail with reference to the following figures. Show:

Figures 1 to 3

Functional diagrams of exemplary image processing modules;

Figures 4 and 5

the use of the method according to the invention for sorting printed products (FIG. 4) and in detail an image processing module set up for this application (FIG. 5);

Figure 6

the application of the method according to the invention for sorting with return;

Figures 7 and 8

the application of the method according to the invention for the production of individualized printed products by controlled collation of different partial products (FIG. 7) and in detail an image processing module set up for this application (FIG. 8);

Figure 9

the use of the method according to the invention for an exemplary combination of various further processing steps for the production of printed products.

FIG. 1 shows an exemplary functional diagram of an image processing module on which the method and the arrangement according to the invention are essentially based.

The central functional element of the image processing module 1 is a comparison unit (B _i = B _s ?) For comparing a captured image (B _i or actual image) with a target image (B _s ) or for comparing digitized data of an actual image with digitized data of a target image. The actual image B _i (or corresponding digitized data) is read into an actual image memory S _i from an external image, that is to say by an image recording device, by a further image processing module or by a higher-level intelligence (not shown in the figure), via an actual image input I _i . whereby an image already stored in the actual image memory is overwritten. An override of the actual image memory S _i initiates a comparison step of the comparison unit (B _i = B _s ?).

The target image B _s (or digitized image data of a target image) is written externally, for example from another module or by a higher-level intelligence from an image library via a target image input I _s into a target image memory S _s , where it is sent to the comparison unit (B _i = B _s ?) is available. However, the target image memory S _s can also be overwritten with the actual image B _i from the actual image memory S _{i of the} same module.

The comparison unit (B _i = B _s ?) Initiates the generation of control signals which, if the actual image and the target image (output "yes") match at the outputs O 1, if the actual image and target image (output "no") do not match at the outputs O 2 can be tapped with different delays. The image processing module has at least one group of outputs O 1 and at least one group of outputs O 2.

After overwriting the actual image memory S _i , the actual image B _i is also accessible at the image outputs O _i with various delays for external use.

Shown as switches A₁ to A₅ are those positions in the functional diagram, each of which can take on two different configurations, the current processing state of the image processing module being defined by the sum of the current configurations of these configurable positions. The configurable points or switches A₁ to A₅ are configurable via the inputs I₁ to I₅ by means of control pulses, wherein they are switched from one configuration to another by a control pulse will. The control pulses for the configuration of the switches A₁ to A₅ can come from outputs of the same image processing module or from outputs of other image processing modules, from a higher-level intelligence or from corresponding operating elements. In order to stay with the selected picture of the (functional) switch for the configurable positions A₁ to A₅, the expressions closed (symbol: ---) and open (symbol: - -) are used for their config configurations in the following description.

At the point A₁ is decided whether the Istbildspeicher S _i to be overwritten with an _i present at the actual image Istbildeingang I B _i or not, and therefore whether a comparison operation is performed (A₁ closed) or not (A₁ open). At the switching point A 1, a decision is also made as to whether the actual image B _{i should} be available to the target image memory S _s and the image output O _i or not. A₁ is functionally the main switch of the module. If A₁ is open, no image comparison is carried out in the module and no control pulse is generated.

At position A₂, a decision is made as to whether the actual image memory S _{i should} also be used to overwrite the target image memory S _s (A₂ closed: yes; A₂ open: no).

At point A₃, a decision is made as to whether control pulses should be available at the outputs O₁ with corresponding delays if the actual image and target image match (A₃ closed: yes; A₃ open: no). At the switching point A₄, a decision is made as to whether control pulses should be tapped at the outputs O₂ with corresponding delays if the actual image and the target image do not match (A₄ closed: yes; A₄ open: no).

At point A₅, a decision is made as to whether or not the actual image is available after overwriting the actual image memory (A₅ closed) or not (A₅ open) with various delays at the image outputs O _i .

• Konfigurationswechsel von konfigurierbaren Stellen durch auf diesen Takt verzögerte Steuerimpulse;
• Istbildspeicher mit externem Bild (Istbild) überschreiben, Bildvergleich durchführen und Steuerimpulse erzeugen;
• Konfigurationswechsel von konfigurierbaren Stellen durch Steuerimpulse ohne Verzögerung;
• Sollbildspeicher mit Istbild überschreiben.

As already mentioned, the processes in an image processing module are clocked. The following routines are processed in each cycle, provided that they are possible in the current processing state:

• Configuration change of configurable points by control pulses delayed on this clock;
• Overwrite the actual image memory with an external image (actual image), carry out an image comparison and generate control pulses;
• Change of configuration of configurable positions by control impulses without delay;
• Overwrite the target image memory with the actual image.

For a person skilled in the art, it is possible without difficulty to implement a software-based or a partially hardware-partially software-based embodiment of the image processing module according to the functional diagram of FIG. 1 and for the above, clocked work routine. The person skilled in the art will also recognize without difficulty that the functional diagram can be varied in an obvious manner without its essential function being changed thereby. For example, it is easy to see that the function of the configurable location A 1 with an image comparison initiated by overwriting the actual image memory could also be taken over by a configurable location between the actual image memory and the comparison unit (as well as in the other outputs of the actual image memory). The functional diagram shown is therefore to be understood as an exemplary functional diagram. The inputs and outputs mentioned are necessary for universal use of the image processing module, some of them may be missing for specific applications.

The type of image data that is compared in the comparison unit is not important for the method according to the invention, that is, in other words, any type of image recording device that delivers an automatically comparable image can be used with a correspondingly equipped comparison unit, whereby any necessary digitization of the images in the recording device, between the recording device and the image processing module or in the image processing module can be provided. In particular, it is also possible, in a manner known per se, to use only a small image section with a given position in the overall image as a target image and to search for the target image within a tolerance range in the actual image in order to compensate for tolerable position differences of the products to be checked.

For the simplest application of the image processing module, namely for its use as an island-like control body with control, for example, of a transfer switch if the actual image and target image do not match, the processing state of the image processing module is constant as follows: A 1: --- (closed), A 2: - - (open ), A₃: - -, A₄: --- and A₅: - -. The actual image input I _i is connected to an image recording device. The control signal for the diverter gate is tapped at that of the outputs O₂, the delay of which corresponds to the distance (in cycles) between the control point and the diverter gate.

For operation with a control function when the actual image and the target image match, the processing state is also constant: A₁: ---, A₂: - -, A₃: ---, A₄: - - and A₅: - -. At least one output of the output group O 1 is connected to a device to be controlled or to its control.

FIG. 2 shows the same functional diagram for an image processing module as FIG. 1, but the outputs and inputs are internally connected to one another in such a way that the module is additionally capable of automatically generating a new target image when operating with a control function with "actual image equal to target image" give.

The operating state is, as shown: A₁: ---; A₂: - -; A₃ ---; A₄: - -; A₅: - -, so that if the actual image and the target image match, a possibly delayed control pulse for a control function can be tapped through a corresponding connection R at the output O₁. By closing A₄ by means of an external control pulse (arrow E), the image processing module is brought into a ready state in which it reacts to a next product that does not correspond to the target image with a corresponding change in the target image. When A₄ is closed, this product (actual image does not equal the target image) closes the instantaneous connection of O₂ with I₂, A₂ and overwrites the target image memory with the actual image. With a cycle delay are then opened again by the connections from O₂ with I₂ and I₄, A₂ and A₄ and thus the operating state is restored. So that the first product of the new type, which was used to overwrite the target image memory, is not treated as a "bad" product, the output O₂ is also connected without delay to the connection R, so that a control command is passed on as for a "correct" product.

A further overwriting of the target image memory with the actual image is only possible again if the image processing module is previously switched to the ready state again by closing A₄ by means of an external control pulse (arrow E). In a networked system that has a plurality of image processing elements and possibly also additional ones Having such elements, such an external control pulse can be supplied, for example, by another image processing module.

FIG. 3 shows essentially the same functional diagram for an image processing module as FIG. 1, but two functionally identical groups of outputs O₂ and O'₂ with two configurable positions A₄ and A'₄ are provided and the outputs and inputs are interconnected internally in such a way, that the module is capable of automatically giving itself a new target image when operating with a control function in the case of "actual image not equal to target image".

The operating state of the image processing module is: A₁: ---; A₂: - -; A₃: - -; A₄: ---; A'₄: - -; A₅: - -, such that control outputs for a control function (arrow R) can be tapped from outputs O₂.

External control pulses (arrows E and E ') open A₄ and A'₄ close, making the status of the module ready. For the next product, which does not correspond to the target image, the target image memory is overwritten with the actual image via an interconnection of the output O'₂, as has already been described in connection with FIG. 2, and the module is switched back to the operating state in the following cycle.

Figure 4 now shows a simple, networked system of, for example, four image processing modules 1.1 to 1.4 and an image recording device 2. The system is used to control a sorting line, in each of which one type from a fed stream of different types of printed products on four switches W.1 to W.4 of products is excreted while products of other types are further conveyed on the sorting route F. The system is able to automatically adjust to four different product types.

The image recording device 2 is connected to the actual image input I _{i of} the first (1.1) of the image processing modules 1.1 to 1.4 connected to a function series. The image output O _{i of} each module is connected to the actual image input I _i of the following module. The outputs O₁ of the modules are connected to the control of the associated switches and with a delay that corresponds to the respective distance (in cycles) between the image recording device 2 and the switch.

Figure 5 shows the functional diagram of one (1.x) of the modules 1.1 to 1.4 of Figure 4. Like the module according to Figure 3, the module has two groups of outputs O₂ and O'₂ with two corresponding configurable positions A₄ and A'₄. The operating state is: A₁: ---; A₂: - -; A₃: ---; A₄: ---; A'₄: - -; A₅: changing. The actual image input I _{i of} the module is connected to the image output O _i of the front module 1.x-1 or to the image recording device 2. Control pulses for the assigned switch can be tapped via the outputs O 1, so that the switch for a product that corresponds to the target image stored in the module is set for a discharge of the product and is reset after the discharge. The control pulses must be delayed according to the distance between the image recording device and the switch, corrected for the position of the module in the row (for example four cycles). The connections between outputs O₂ and inputs I₅ and between image output O _i and actual image input of the next image processing module (I _i of module 1.x + 1) ensure that the actual image with a clock delay to the actual image input if the actual image and the target image do not match I _{i of} the following image processing module 1.x + 1 is delivered.

The outputs O'₂ and the inputs I₄ and I'₄ are interconnected in the manner already described for the creation of a standby state (A₄: - -; A'₄: ---), a subsequent target image overwriting and a restoration of the operating state .

The modules of the networked system according to FIG. 4 are all switched to the ready state at the start of a sorting process. The target image memory of module 1.1 is overwritten with the image of the first product, the target image memory of module 1.2 with the image of the next different product, and so on. Products belonging to fifth or other types are not removed from the main conveyor line.

FIG. 6 shows a sorting device and the associated control and control method according to FIG. 4 expanded in such a way that after a single pass through all the products to be sorted, the unsorted products (fifth and further types) are returned to the sorting, the device automatically referring to the sorting the next four types of products and sorts them out.

The expansion of the device relates to a product buffer 3 at the end of the sorting line F, a product return 4 to the sorting line F, specifically in front of the control point by the image recording device 2 and a further image processing module 1.5. The target image of module 1.5 is the image of an empty space in the feed stream. The operating state of module 1.5 is A₁: ---; A₂: - -; A₃: changing; A₄: - -; A₅: - -. The actual image input I _{i of} the module is connected to the image recording device 2. Outputs O 1 are with corresponding delays for initializing the return with a control of the output of the buffer 3, for inactivating and reactivating the modules 1.1 to 1.4 between the sorting process and return with their inputs I 1 and to put the modules 1.1 to 1.4 in the ready state with their inputs I 1.4 and I'₄ connected. With a delay of one cycle (to open A₃) and with a delay of as many cycles as are expected from the return empty spaces in the feed stream (for reclosing A₃) an output of the output group O₁ of module 1.5 is also internal connected to the input I₃, so that the control signal necessary for opening the buffer output is only generated at the first empty space in the feed stream and that as soon as the first of the recirculated products has passed the control point, the module 1.5 is returned to its operating state.

FIG. 7 shows a further, exemplary application of the method and the arrangement according to the invention. It is a further processing process in which various printed products (sheets) from feeds Z.6 to Z.9 are gathered into a group on a collating section Z and in which defective groups are removed by a switch W at the end of the collating section Z. The feeds are controlled by a higher-level intelligence 5 in such a way that the groups generated have individual compositions, that is to say that the groups generated contain only selected ones of the sheets that can be fed. An image library 51 can be assigned to the higher-level intelligence, in which, for example, the images of the parts of products produced in succession are stored. Such an arrangement permits on-the-fly production changes in which the target image memory of the modules is overwritten with the target images of the following production, which are read out from the image library for this purpose, by the higher-level intelligence in the corresponding cycles.

Four image processing modules 1.6 to 1.9 are provided for carrying out the method according to the invention, each with an image recording device 2.6 to 2.9 is connected. The image recording devices control the gathering distance depending on a feed, that is to say they control the resulting group after adding each individual sheet.

Figure 8 shows one (1.x) of the modules 1.6 to 1.9 of Figure 7 in detail. The target image of the module corresponds to the last sheet to be checked and comes, for example, from the image library 51, from which it is retrieved by the superordinate intelligence and written into the target image memory of the corresponding module. The operating state of the module is: A₁: changing; A₂: - -; A₃: - -, A₄: ---; A₅: - -. The actual image input I _i is connected to the assigned image recording device 2.x. The input I 1 is for suppressing an image comparison when no sheet has been fed (individual composition), connected to the higher-level intelligence 5. The outputs O₂ are connected with corresponding delays to the controls of the feeders Zx + 1, Zx + 2 etc. assigned to the following modules, in such a way that their control means that no further feed follows a defective feeder. Furthermore, outputs O₂ with the same delays are connected to the inputs I₁ of the following image processing modules 1.x + 1, 1.x + 2 etc., so that the corresponding control steps are also suppressed.

FIGS. 4, 6 and 7 show exemplary applications for the method and the arrangement according to the invention. The applications are relatively simple. The functional diagram of the image processing module allows further simple applications and in particular combinations of functions and applications.

Figure 9 shows, again shown as a functional diagram, an example of such a combination, which is a more complex application for the inventive Process and the arrangement according to the invention relates. It is a combination of a collating section Z with a group G of stations for connecting (stapling, gluing, etc.) the assembled partial products and a sorting section F for sorting the partial products of ejected, defective products, with the sorted product parts being returned to the feeders the gathering distance can be returned. Using the example of this more complex application, in particular the control of a change in production by the method according to the invention will be described. In the figure, the product routes are drawn out and the connections for the transmission of data are shown in dashed lines. In order not to overload the figure unnecessarily, only the most important data connections between the image processing modules are shown and their connections to the image processing modules no longer depend on the entry and exit positions of FIGS. 1 to 3.

The collating section Z has four feeds Z.1 to Z.4, the main part of the product to be produced being fed on the feeder Z.1 via a buffer 6 in a quasi-continuous manner, for example from a printing press. At the further feeds Z.2 to Z.4, three further parts are fed, for example from winding or stacking. In order to enable an uninterrupted change of production, two feed paths with corresponding winding or. Stack positions (Z.20 and Z.21 etc.) provided. At the end of the collating section Z there is a discharge switch W, at which defective products are discharged and fed to a separation station 7 for separating the parts and the subsequent sorting section F with sorting switches W.1 to W.4. Via the sorting switches W.1 to W.4 and possibly further switches W.21 to W.41 which follow thereafter, the sorted product parts are again fed to the corresponding feed paths Z.1, Z.20, Z.21 etc. Products assembled correctly in the collating section Z are transferred to a group G fed from connecting stations. This group G includes, for example, a bypass 8 for products that are not to be connected, a stapling station 9 and a gluing station 10 and corresponding switches G.1 and G.2.

The arrangement according to FIG. 9 also has a superordinate intelligence 5 and an image library 51, which contain data relating to images relating to images of main product parts to be processed, identification features of further product parts in the form of wraps and / or stacks, assignments of product parts to main product parts and to feeders Assign a specific connection type to a specific product body. The arrangement further comprises, in the function already described in connection with FIGS. 4, 6 and 7, four image processing modules 1.11 to 1.14 with associated image recording devices 2.11 to 2.14 for checking the collation and another image recording device 2.15 for checking and controlling the sorting section F. and four other image processing modules 1.15 to 1.18 cooperate. In addition to the image processing module 1.11, a further image processing module 1.19 is provided for checking the main part feed Z.1 and a reader 11 for checking and assigning the coils and / or stacks of the other product parts.

The method according to the invention in the application according to FIG. 9 now works in the following manner. In normal operation, that is to say for the processing of a currently supplied main product part, the image processing modules 1.11 to 1.14 control the feed and control the discharge switch W. The modules 1.15 to 1.19 control the sorting and control the sorting switches W.1 to W.4. The further product parts are identified in the form of coils or stacks by the reading device 11 and are assigned to corresponding supply routes (Z.20, Z.21 etc.) by the higher-level intelligence of the identification. According to this assignment the additional points W.21 to W.41 have also been set. The target image of module 1.11 corresponds to the currently processed main product part and comes from image library 51. The target images of modules 1.12 to 1.14 correspond to the other product parts that are assigned to the main product part. The target images of modules 1.15 to 1.18 are the same as the target images of modules 1.11 to 1.14.

For a "flying" production change, the feed paths for the other product parts (e.g. Z.21, Z.31 and Z.41) that are not used in the current production are provided with coils or stacks in accordance with the instructions of the higher intelligence. The target image of the next main part of the product to be processed is written by the higher-level intelligence from the image library into the target image memory of module 1.19. The next position of the switches G.1 and G.2 are predetermined. The module 1.11 further controls the feed Z.1 of the main product part, the actual image being forwarded to the module 1.19 if the actual image and the target image do not match. If the actual image corresponds to the target image of the next main product to be processed (target image of module 1.19), module 1.19 initiates the following steps with corresponding delays: Overwriting the target image memory of module 1.11 with the image of the new product main part, changing the feed paths (e.g. from Z .20 on Z.21) to the feeds Z.2 to Z.4, creating the ready state for overwriting the target image memory of the modules 1.12 to 1.14, setting the switches G.1 and G.2 in the predetermined position.

The module pairs 1.11 / 1.18, 1.12 / 1.17, 1.13 / 1.16 and 1.14 / 1.15 are connected to one another in such a way that the overwriting of the target image memory of the module of the feed line initiates a corresponding target image memory overwrite of the module of the sorting line with a corresponding delay.

Based on the above descriptions, countless other applications for the method according to the invention can be designed and corresponding arrangements can be implemented. It should be noted that the method according to the invention can be used in addition to control functions for the detection of errors and their elimination or correction, in particular control functions for controlling individual further processing steps or combinations of further processing steps. For example, the application of the method represented by FIG. 4 is also conceivable at the exit of a printing press which in succession emits a wide variety of printed products which have to be processed in various ways. The switches W.1 to W.4 are then not to be interpreted as simple diverters, but rather as assignments to various further processing methods, whereby in such a case, both the acquisition of the target images and the assignment of a specific product to a specific switch naturally do not constitute a learning process can be transmitted, but must be made available by a higher intelligence.

Claims (13)

Control and control processes for further processing processes in the area of the production of printed products such as newspapers, magazines, brochures etc. from printed preliminary products or product parts, in which process images (B _i ) of preliminary products, intermediate products, product parts and / or of finished printed products are recorded in a timed manner , are compared with target images (B _s ) and control pulses are generated in accordance with the comparison results, characterized in that in a plurality of image processing modules (1), each of which is in a current processing state, images (B _i ) are read in, that the read-in images are compared in the image processing module with a stored target image (B _s ) and that the image processing module generates control pulses in accordance with the result of the comparison and in accordance with the current processing state of the image processing module The control pulses are used in addition to the control of processing and / or transport devices to change the stored target image (B _s ) or to change the current processing state of image processing modules. Control and control method according to claim 1, characterized in that the control pulses generated in an image processing module (1) are used simultaneously to change the stored target image (B _s ) and the current processing state of image processing modules (1). Control and control method according to one of claims 1 or 2, characterized in that the current processing status of image processing modules (1) can also be changed by a higher-level intelligence (5). Control and control method according to one of Claims 1 to 3, characterized in that target images of image processing modules can be replaced by images from an image library (51) by the higher-level intelligence (5). Control and control method according to one of Claims 1 to 4, characterized in that the current processing state of image processing modules (1) can also be changed by operating elements. Control and control method according to one of claims 1 to 5, characterized in that the current processing state of image processing modules (1) determines whether an image comparison is carried out or not, with which comparison result control pulses are generated, whether the stored target image with the read image or an external image is overwritten or not and whether or not the scanned image is made available to other image processing modules. Control and control method according to one of claims 1 to 6, characterized in that the control pulses generated by the image processing modules (1) from the image processing modules Delays corresponding to different numbers of clocks can be made available for control functions. Arrangement for carrying out the control and control method according to one of claims 1 to 7, characterized in that it has at least one image recording device (2) for recording images (B _i ) and a plurality of image processing modules (1) for comparing the recorded images (B _i ) with target images (B _s ) and for generating control pulses and that the image processing modules (1) are at least partially connected to one another in such a way that control pulses and / or image data can be transmitted from one module to another. Arrangement according to claim 8, characterized in that each image processing module (1) has two image memories (S _i and S _s ), a comparison unit (B _i = B _s ?) And conditionable points (A₁ to A₅) and that image processing modules via inputs and Outputs (I _i , O _i ) for pictures, via outputs (O₁, O₂) for generated control pulses and via inputs (I₁ to I₅) for control pulses for controlling the conditionable locations (A₁ to A₅) can be connected to one another. Arrangement according to claim 9, characterized in that inputs and outputs of image processing modules are internally connected to one another. Arrangement according to one of claims 8 to 10, characterized in that at least part of the image processing modules for mutual transmission of control pulses and / or image data are connected to a higher-level intelligence (5). Arrangement according to claim 11, characterized in that the higher-level intelligence (5) is connected to an image library (51). Arrangement according to one of claims 8 or 12, characterized in that at least some of the image processing modules are connected to control elements for inputting control pulses.

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