EP1226942B1 - Method for adjusting printing and other job parameters in a printing machine - Google Patents

Abstract

A method for setting machine settings for a printing machine at a time selected from before and during printing of a printed product on a printing machine, includes providing for one of an operator of the printing press and a pressman to evaluate a printed result of a printed product produced in one of a production printing and a proof printing, and resetting the machine settings, if necessary; in dependence upon an enabling signal, storing prescribed input variables and machine settings, which define a print job, in a control system belonging to the printing machine; and applying the stored values for influencing future settings of the printing machine, even for other print jobs; a printing machine for performing the method; and a material for printing with the printing machine.

Description

The present application is concerned with a method for setting printing-related and other job-dependent parameters of a printing press. The visual impression of a printed image, which may also contain text, is influenced by many factors. These include the condition and type of paper used, the type of colors and fountain solutions used and their admixtures, the color density required by the subject, color distribution, the order of the overprinted colors, and the environmental conditions, such as e.g. Humidity and air temperature. In the case of planographic printing, especially the offset rotary printing, the color guide and the water guide also play a role which strongly influence each other. The mentioned influencing variables are referred to below as input values.

Part of the listed values (input variables) are assigned to the material used or can be read via labeling and taken into account in the settings of a printing press. This includes, for example, the color used or the paper used. Other predefined input variables are, for example, the color distribution based on the given subject, the order of the colors printed on one another or the preselected printing speed. Such input variables are taken into account at the beginning of the proof or print run in the machine settings of the printing press (such as, for example, ink-zone openings, moisture setting, sheet-guiding blowing air, dryer output).
Result parameters such as the printed color and the achieved color density can be measured with some effort and readjusted on the press. Here, however, often the subjective impression of the operator on the printing press is more important than the measurement result. One reason for this is that the totality of said parameters is subject to certain tolerances, so that the trained eye of the operator for producing an optimum printing result is more important than the results of predetermined machine settings.

Settings on the press do not only have to be made once, but often become. Necessary is a setting, for example, to produce a pressure on a printing machine used especially for this purpose, which is then presented to the customer to assess and determine the desired printing result. The readings resulting from measurements on the proof (original) approved by the customer then serve as a basis for the means of production or printing. Although a number of measured input variables are made available in such a device of a printing press, the establishment of a printing press for the printing is still very expensive. On the one hand, the tolerances of the measured input variables can add up in the direction of an unfavorable print result, so that the operator (printer) must intervene for this reason alone. Furthermore, it may happen that the printer wants to print at a speed that deviates from the intended graded characteristic values. Again, the machine settings must be changed accordingly to achieve an optimal print result.

Finally, in the case of planographic printing and in particular in the case of offset rotary printing, the water supply and the color distribution must be adjusted until the printing result for the printer is satisfactory. To achieve a good print result, a stable balance between color and water must be achieved (color-water balance). While, as already described above, the printing of the color and its resting on the sheet can be measured by the printer in the form of measuring the color density, the optimal humidity can not currently be measured directly with justifiable effort and sufficient accuracy, but only indirectly judge the print result. If too little water is transferred to the surface of the printing plate, then it comes to a fuller pressure of the grid points (smearing) or to a clogging of grid points. The surface of the plate thus assumes more color than desired, because no adequate wetting is done by the dampening unit. Conversely, if the water supply is too strong, this can lead to a pale print result and thus to a sometimes strong displacement of the printing ink.

With regard to the color distribution must be taken to ensure that over the entire width of the printed product, ie transverse to the direction of rotation printing, the color is distributed according to the requirement of the subject. This can be the transfer of color from Set the color boxes on the ductor in strips, so that the color on the ductor is distributed according to the subject.

It thus turns out that the process of setting up a machine is very time consuming and therefore expensive. In order to shorten the set-up times, individual printing machines are assigned tables (or characteristic curves) on the basis of which the color distribution on a specific machine can be adjusted as a function of the printing speed. Furthermore, paper data (format, thickness), the color assignment of the printing units and the color distribution from the plate reader or the precursor are entered or read in some printing presses. Characteristics are used to control color and humidity at different speeds, but these were determined for mean values of ink-zone openings.

The problem of the long times to set up a printing machine aggravated by the fact that a once selected device must be adapted many times, for example, if the press is longer time, if the plates have to be replaced or the blanket was washed. To remedy this situation it is from the DE-U-29612159 It is known to record individual of the set values in suitable memories, from where they can be output, if necessary, for re-establishment of the printing press. In this case, individual operations such as the washing of a blanket or the printing of registration marks special programs are assigned, which then start when the program in question is to be performed. Appropriate programs can be provided for refreshing the color profile after a machine stop or adjusting the dampening unit. The individual memories are freely programmable and can thus be adapted to the previously set state.

Further times for setting the individual machine parameters are required if the required machine parameters to be set change during the printing, in particular the print run. This can happen, for example, that the amount of ink in the ink boxes decreases and thus change the amount of ink delivered at the set color zone opening or that the ambient temperature in the environment of the Printing machine changes or other set values of the printing machine change, so that readjustment is necessary. Since a part of the printing result parameters described can be measured automatically with corresponding measuring devices, a number of printing machines are now equipped with control systems which compare actual values measured on a control strip of the printed sheet with predetermined nominal values and readjust the printing press accordingly. Since such control processes are relatively slower compared to the now achievable machine speeds, attempts have been made to shorten the control process. For example, in the EP-A 922 581 Control method described in which due to predetermined output states abruptly in the printing press, a new state is set. In this case, a so-called fuzzil logic is used, in which the functional units of the symbolism of fuzzy human thinking are approximated and thus fault-tolerant but also faster and easier to create than the usual scheme. With conventional control algorithms, even a small error can lead to a complete failure of the control. In contrast, a small error will hardly be noticeable in fuzzilogic. The control operations described in the cited reference relate exclusively to the color guide during printing.

From the DE 44 39 986 A1 is an online control for a three-color roller press known. A neural network-implemented process optimization model is used to generate for predicted control settings or states predicted process results that are compared to actual process results to determine if there is a mismatch between the actual results and the desired results. If an inequality does not exist on a known or predicted cause, the process optimization model is adjusted.

From the DE 44 39 961 A1 a process control unit for a printing press is known. It is automatically defined by means of a process control system, a control room, the initial Presensteuever conditions determines. A local mapper responds Color attributes of a product printed according to the global control room, wherein an optimum value control unit is provided with an artificial neural network to control the rotational speed of the moistening motor and the zone screw settings according to a feedforward process model.

Furthermore, the beats DE 198 22 662 A1 a method for operating a printing press over three stages using an expert system. The basic calibration, imaging and color density control steps are performed. This idea serves the adaptation of the different processes, basic calibration, imaging and color density control and optimizes the different processes to each other.

The known control devices provide some help in the automatic adjustment of printing presses before printing or during printing. The values determined by the machine over a large number of characteristic fields, however, can only represent approximate guide values for the printer an optimal print result must be changed by hand. This applies both to setting up the press before starting the print run and to setting the machine during the printing process. In practice, the printer is thus often confronted with settings in the color distribution or with disturbances that make one of the predetermined characteristics very different setting of the printing press necessary, so that sometimes a complex and considerable waste paper resulting readjustment of color or moisture required is. This sometimes results in setting-up and fine-tuning times becoming a major part of machine times. Although a certain remedy can be achieved by a particularly dense network of Farbevoreinstellungskennlinien. But this is a high cost to Characteristic determination necessary. Furthermore, almost every case is deviating from the characteristic special case, which must be readjusted by hand.

The input values described in the beginning can be divided into the predefined values of the input variables and special settings of the machine values by the printer, which the printer has to adjust on the basis of his subjective experience in order to improve the printed result of the printed product. The input variables are measured objectively or announced to the printer by appropriate description of the materials used for printing (paper, color), which then adjusts the machine accordingly. In this context, input variables are defined by material (eg paper, color), environment (eg, temperature, atmospheric humidity) and original (for example color distribution) defined objectively measurable quantities which influence the setting of the printing press. Machine settings are understood to be the settings made by the printer on the printing machine which it performs to achieve an optimum result, in particular also the special settings which the printer autonomously carries out, as described above.

The stored values defined as being successful on the basis of the enable signal form a data record which describes a successful setting of the printing press with regard to the underlying input variables. In principle, the invention consists in providing the input variables and the machine settings, which are successful from the printer's point of view, to the controller in such a way that these stored data sets can be used to derive suitable machine settings for later print jobs.

The special settings of the machine values by the printer are made autonomously by the printer because they are either difficult or impossible to measure or because the printer wants or has to deviate from the machine settings suggested or preset in order to improve the printing result.

The input variables are the parameters of the printing material, the parameters of the subject, given by the parameters of the environment and certain machine parameters. With regard to the parameters for the printing material, mention may be made, for example, of the paper format, the grammage, the paper thickness or the impact behavior of the paper. With regard to the parameters of the subject, the color distribution, the color assignment or the contrasts or rasters must be mentioned. An input parameter for a parameter of the printing press is, for example, the intended printing speed. With regard to the input parameters for the parameters of the environment, for example, there are the temperature and the humidity. The input variables are communicated to the printer by descriptions of the materials used for printing and then entered by the printer into the machine or automatically read in by it.

The special settings of the machine values by the printer (machine settings) relate to i. d. R. The humidity (moisture management) and the color distribution (color guide) and the air adjustment for the paper transport. (However, the special settings may also relate to predetermined input variables which the printer itself modifies to improve the printing result of a printed product in the form of a machine setting, if that is possible at all.)

Earlier, the known efforts were made to speed up or improve the settings on printing presses by keeping the machine settings in memory available for retrieval or by speeding up the control processes for readjusting the color guide by fuzzilogics. It is also an object of the present invention to shorten the duration of the setting operations and to make the quality of the printed product more independent of the experience and qualification of the machine operator. The present invention is based on the basic idea that certain settings can be carried out very quickly (possibly automatically) because they are clearly conditioned by input variables. On the other hand, the special settings of the machine values (machine settings) to be carried out by a printer take a comparatively long time and are often associated with a great deal of waste. These special attitudes also require a great deal of expertise and experience from special forces that are not always sufficiently available.

The invention is therefore based on a method resulting from the preamble of claim 1 resulting class and solves the problem by the resulting from the characterizing parts of this claim combination of features. In this context, input variables are defined by material (eg paper, color), environment (eg, temperature, atmospheric humidity) and original (for example color distribution) defined objectively measurable quantities which influence the setting of the printing press. Machine settings are understood to be the settings made by the printer on the printing machine which it performs to achieve an optimum result, in particular also the special settings which the printer autonomously carries out, as described above.

The stored values defined as being successful on the basis of the enable signal form a data record which describes a successful setting of the printing press with regard to the underlying input variables. In principle, the invention consists in making the input variables and the machine settings that are successful for this purpose from the printer's perspective available to the controller, so that these stored values can be used in subsequent print jobs with corresponding input variables. This creates the prerequisite that the values or correction values created by the printer at considerable cost to achieve a good printing result are also available for later comparable printing units.

In order to obtain a release signal in the simplest possible way, the feature combination according to claim 2 is recommended. Thereafter, the printer either gives a signal by which it releases the machine values (machine settings) autonomously set by it for further treatment by the controller , The other possibility is that the controller declares the machine specific values set by the printer to be authentic after the printer has not entered new stand-alone special machine values for a sufficient number of prints or printed sheets. Also in this case, the obviously successful machine settings of the controller are then made available for further use on future new printed products. As often smoothly acceptable input variables, the parameters have been found according to claim 1. Typical machine settings set or changed autonomously by the printer are specified therein, which are then made available to the controller in response to an enable signal.

An important development of the invention provides that the control in the establishment of the printing machine for a new printed product, the machine settings in consideration of the previously proven successful as machine settings in a suitable manner or makes at least the setting-up operator appropriate proposals. In this way, the wealth of experience that was gained by the successful machine settings for comparable previous printed products at considerable cost, is also available for newer machine settings.

According to a further development, the controller searches for an earlier combination of input variables that are as similar as possible to the current input variables of a new print job. Based on the previously found most similar combination of input variables, it is concluded that successful current machine settings. Thus, from the stored data records (from input variables and successful machine settings), the current successful machine settings for new constellations of input variables are concluded.

The requirements for the control are thus very diverse when setting the printing press for a new printed product. It must be checked which earlier combination of input variables and the input variables of the new print job to be set up are sufficiently comparable. It must be checked which tolerances are permissible for a deviation of the new combination from the earlier combination and for which input values only minor deviations can be tolerated. Based on the results thus found, the new machine settings are then changed by the controller based on the learned relationships in the stored records or appropriate suggestions are made to the newly established operator.

A printing machine with a control suitable for this purpose is in one Further development of the invention proposed as follows. Neural networks are excellently suited to the present task because they are capable of learning. They thus reflect the growing wealth of experience of a printer.

Preferably, the neural network of the printing machine is configured such that the processors or nodes operating in parallel from the plurality of data records stored over time recognize relationships between specific input variables with successful machine settings. In the process, the neural network learns via a large number of data sets which input quantities in which constellation were of particular importance for specific output variables (machine settings). In addition, it is able to weight certain inputs according to their importance. The increasing expression of central relationships between the input and output variables (= machine settings) represents, so to speak, the growing wealth of experience of the neural network, which simulates the experience of the printer.

According to the feature combination of claim 6, the neural network outputs the most promising machine settings or makes appropriate suggestions depending on the instantaneous combination of input variables compared to similar previous combinations of input variables. The output values are not necessarily identical with previously set machine settings, as there may well be an unprecedented constellation of input variables. In the structure of the neural network are according to claim 7 as input values to be weighted especially the paper parameters (such as format, grammage, thickness, stiffness) and color parameters (such as tack, emulsion ability), dampening solution properties, the environmental parameters (humidity and air temperature) and subject parameters (such Color distribution and area coverage). The output parameters are the machine settings such as ink zone setting, humidity setting, blown air settings, etc.

In a further development of the invention is recommended for the control of the printing machine according to claim 8, that the control is constructed tolerant to small deviations from certain input variables. This means that the combination of input variables also then lead to the output of learned machine settings, if the new combination of input variables with a previous combination is not identical, but compared to this only within certain tolerances.

Another possibility for simplifying the input of the input values, in particular of the input variables in a printing press, are described in claims 9 to 12. The hitherto customary method for inputting the input variables is that the printer reads out the corresponding characteristic values from the description of the delivered materials and transmits them via a input extensive input menu into the controller. Because of this complex input method so far only comparatively few input variables are entered by the printer in the controller, so that the setting of autonomously made machine settings is particularly important. To further solve the problem, the combination of the features of claim 9 is therefore proposed for a printing press. This solution consists, in principle, of reading, by means of a bar code reader, the code which is located on a label of the material concerned and describing the property of the material, and to supply the read values directly as input values to the controller of the printing press. The controller then adjusts the respective devices of the printing press accordingly. However, this method assumes that the material is provided with a suitable barcode. The material can not only affect the color or the paper, but it can also be the type of dampening agent used, blanket or detergent for the machine are described by a corresponding code. The connection of the scanner to the controller can be done by an electrical line but also via a suitable information channel such as an infrared ray, a radio channel or another transmission path.

According to the combination of features according to claim 10 and 11, the code reader can be transportable or permanently installed in the controller or on devices of the printing press. If a portable code reader is present, the printer has the option to go to the material and make the reading there, which is then brought to the controller via a suitable transmission channel. If the code reader is permanently installed, the label with the barcode can be brought to the code reader and read there. A Another possibility is advantageously to arrange the code reader assigned to a specific material to a receptacle for the respective material on the printing press such that when the material or the device of the printing press is fed the respective code reader can read the relevant label without further ado.

It is particularly advantageous if, according to the feature combination according to claim 12, the material is provided with a so-called "smart label". A smart label has the advantage that even changes in the material during the printing process can be taken into account. For example, the reduction of a paper stack during a previous printing operation can be written into the smart label by a suitable code reader and writer. The smart label looks a lot like a credit card, in which the last state of the property of the material is entered. In this way, it is also easy to detect changes in the property of a material from a printing press when the printing press is changed.

An embodiment of the invention will be described below with reference to the drawing. In the drawing, a two-color printing press for offset printing is shown. However, the invention is consistently suitable for all types of modern printing presses. The printing machine 1 according to the drawing will not be explained in detail. Further details on offset printing presses can be found, for example, in the book "Der Offset-Druck", DuMont Buchverlag Köln, 1991.

The printing machine 1 is provided with a number of connections 2, 3 to one central or several decentralized controllers 4. Representative of further connections, the lines 2,3 are shown. Via line 2, information relating to the coloration of a printing unit 13 or 14 is detected via sensors and communicated to the controller 4. This information can describe, for example, the position of the individual ink zones or knives along a ductor roller, which are adjusted according to the color distribution. The information passing through the link 2 may also relate to the height of the ink level in an ink fountain or other data important to the color. For example, information can be transmitted to the controller 4 via the connection 3, which describes the humidity, which is fed to the corresponding rollers during offset printing. It is essential that as a representative of all other data on the connections 2, 3 data run, which describe the setting of individual values in the printing press, which are in particular machine settings that need to be readjusted many times by the printer or from print job to print job have to be changed. The data running over the connections 2,3 are therefore representative of autonomously settable and / or readable data by the printer.

About the lines 8, 9 get information in the controller 4, which affect the nature and quality of the colors used in the inking units 13,14. This may be, for example, the toughness, tackiness, emulsifying ability or the temperature value of the color used in each case. These values can be read from the packaging of the respective color, for example by means of a code, and then entered into the controller 4 either manually or automatically (for example, automatically readable via smart labels). About the lines 10, 11 get information in the controller 4, which describe the nature and properties of the paper used. These may be, for example, the format, the grammage, the stiffness and the impact behavior of the paper. The data which enter the controller 4 via lines 8 to 11 thus relate to input variables which objectively describe the print job and its conditions (for example air humidity in the pressroom or printing unit, air temperature in the printing unit etc.) and are representative of such values.

Finally, in the drawing, a control panel 20 is indicated, via which the printer can operate the printing machine 1 and via which he can read the settings on the printing press 1 but also set in the form of a remote control. This information, such as the printing speed, color zone settings or fan settings of the sheet guide arrive from the control panel 20 via a line 14 in the controller. 4

For example, the printer can read the input variables via the control panel 20 and selects the machine values according to these input variables (eg from tables or also by measuring the original) via the controller. During printing or printing, the printer removes Sample sheets and evaluate the print result. Then he autonomously adjusts the machine values by, for example, adjusting the color zones or the humidity. These set machine values are stored in the controller 4, this storage being done in conjunction with the combination of the present inputs. The stored values, however, can only influence the design of future machine setting values as a successful set of input and output variables if the printer either gives a corresponding command (enable signal) via the control panel 20 or if a predetermined number of sheets have not been re-used since the last setting Change made by the printer.

In order to shorten the time required for setting the machine values by the printer, the controller 4 is provided with an artificial "neural network" (not shown) in which the input values and the output values identified as successful are stored and which determines the meaning of certain input values or learn their combinations for the initial values to be set over a large number of data sets. Suitable neural networks are described, for example, in the following references. " An Introduction to Computing with Neural Nets, IEEE ASSP MAGAZINE, April 1987, pages 4 to 22 and further references there on page 22. It is important that such neural networks are able to recognize the meaning of a constellation of input values for correspondingly successful initial values and to make suggestions or specifications for suitable machine settings from this learned relationship. If, for example, a slight change in an individual input value always has a great significance for certain output values given otherwise constant input values, this relationship is learned as significant and the relevant input value is weighted accordingly. Conversely, for example, despite large fluctuations in a wide range of inputs, a particular input may not require changes in outputs (machine settings), but if a certain threshold is exceeded, even small changes in the input are significant. In this way, within the neural network, there is virtually a wealth of experience in successful machine settings for specific input variables, which results in the printer from the neural network either making suitable suggestions for one of them Finally, the neural network can to a certain extent replace the adjustments of the printer. In this way, for example, certain characteristics of a printing press can be compensated, which does not behave exactly according to the predetermined characteristics.

The setting up of the printing press can be greatly simplified for the printer by the use of one or more bar code readers (for example, at the end of lines 8 to 11). The code readers can read a comparatively large number of input variables without difficulty directly from the material intended for the printing into the control of the printing press. Thus, for example, a code reader (lines 10, 11) can be attached to the feeder for the paper stack in such a way that it reads the appropriate values from a label on the stack when the stack is retracted or when the stack is retracted. In this way, for example, not only the grammage and the format of the paper can be easily entered into the controller, but also additional suitable input variables, such as the stiffness of the paper. Other sizes, for example, the printer with a portable code reader a (lines 8,9) read from the label of the paint container, the read values can be transmitted directly through a radio link or optical link without mechanical connection between the code reader and the controller.

It is particularly useful if a so-called smart label is used in the reading of the input variables, which cooperates with a suitable code reader (which can also label). Such a smart label is able to be rewritten by a corresponding code reader similar to a credit card, so that changes to the material (eg, in terms of quantity) can be recorded, which then when using the material in a new print job without further available.

LIST OF REFERENCE NUMBERS

1

press

2, 3

links

4

control

8, 9

cables

10, 11

cables

14, 13

printing unit

20

controller

Claims (12)

1. Method of adjusting machine settings of a printing press (1) prior to or during the printing of a printed product, in particular a production run on a printing press, preferably a rotary offset printing press, wherein a machine operator or pressman, respectively, evaluates the print result of a printed product produced during the production run or during proofing, and wherein machine settings are readjusted if necessary,
   characterized by
   the fact that predetermined input parameters (8 to 11),
   which are determined by printing material parameters such as paper format, weight, paper thickness, stiffness, ink absorption behaviour and/or subject parameters such as contrasts, ink distribution, ink coverage and/or ink parameters such as tackiness, emulsification capacity and/or dampening fluid parameters and/or environmental parameters such as temperature, humidity,
   and machine settings (14) which characterize a print job and are given by the setting of the ink distribution and/or the dampening and/or the air setting for paper transport, are stored in a control unit (4) of the printing press (1) depending on a release signal (14) and
   that during the setting-up of the printing press (1) for a new printed product, the control unit (4) of the printing press (1) makes available those machine settings (14) which are influenced by corresponding values that were stored in the control unit (4) during the setting up or correction of preceding printed products.
2. Method according to Claim 1,
   characterized by
   the fact that the release signal depends on the number of printed products printed since the last adjustment of the machine settings (14) without renewed adjustment and/or on a trigger signal entered manually.
3. Method according to one of Claims 1 to 2,
   characterizd by
   the fact that the input parameters (8 to 11) of the printed products are measured by measuring devices that operate automatically or are received from the printing materials such as paper, ink, dampening fluid by means of suitable coding.
4. Method according to Claim 1,
   characterized by
   the fact that the machine settings made available depend on the predetermined input parameters of the new print job.
5. Method according to Claim 1,
   characterized by
   the fact that the control unit (4) of the printing press is equipped with an adaptive, neural network in which the input parameters (8 to 11) and the machine settings (14) are stored.
6. Method according to Claim 5,
   characterized by
   the fact that a weighting of the processors (nodes) operating in parallel in the neural network is influenced by the adjustment of the machine settings (14) in the case of a certain constellations of the input parameters (8 to 11).
7. Method according to Claim 6,
   characterized by
   the fact that the weighting of the processors (nodes) is additionally influenced by preceding machine settings such as dampening and/or ink distribution and/or air setting for paper transport.
8. Method according to Claim 1,
   characterized by
   the fact that as long as at least one of the input parameters (8 to 11) remains within a given tolerance, the neural network makes available unmodified machine settings.
9. Printing press for carrying out the method according to one of Claims 1 to 8, including a control unit (4) and an adaptive neural network,
   characterized by
   the fact that the input parameters (8 to 11)
   in the form of printing material parameters such as paper format, weight, paper thickness, stiffness, absorption behaviour and/or subject parameters such as contrasts, ink distribution, ink coverage and/or ink parameters such as tackiness, emulsification capacity, and/or dampening fluid parameters and/or environmental parameters such as temperature, humidity,
   and the machine settings (14)
   such as the setting of the ink distribution and/or the dampening and/or the air setting for paper transport are storable in the neural network and
   that a barcode scanner is provided which is used to scan properties of the material needed for a print job such as paper or ink and
   that the scanner is connected to the control unit (4) of the printing press (1), which receives the scanned data of the barcode reader.
10. Printing press according to Claim 9,
    characterized by
    the fact that the barcode reader is a portable device.
11. Printing press according to Claim 9,
    characterized by
    the fact that the barcode reader is arranged on a control unit (4), an operating console (20), or on a receiving unit of the printing press (1) for receiving materials required for printing.
12. Printing press according to Claim 9,
    characterized by
    the fact that a smart label is provided which cooperates with a corresponding code reader and in which the properties of the material required for a print job such as paper or ink are described and that the code reader is connected to the control unit (4) of the printing press (1), which receives the data of the smart label.

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