SE438397B - SIMULATION DEVICE - Google Patents

Description

q ..... »..- 4-, ._ pvaovvzu-A corresponding to each of the four separations and separations and the plates are used together with the corresponding dyes for sequential printing of component color images on paper for obtaining of a composite color image with all component colors.

The color correction calculator 14 is provided with a plurality of control means for changing the characteristics of the color separations produced by the scanner 12. Figure 6 shows the control panel of a prior art color correction calculator. It should be noted that the control panel contains 89 different control means, including switches and potentiometers. The control means are arranged in an order corresponding to the four color separations produced by the scanner and the different control means are, where appropriate, provided with a prefix Y, M, C and B in front of the respective numbers. Numbers that are not related to a particular separation are denoted by S for switches and R for potentiometers. The only meter has the prefix D.

With the large number of controls on a typical color scanner, the quality of the separations produced is highly dependent on the skill of the operator.

Based on its own evaluation of the color original, it is necessary for the operator to make such adjustments to the control panel that he believes will result in separations, which result in an acceptable color print in the actual printing process. After a first set of separations has been prepared, it is necessary to produce printing cylinders or printing plates and add dye to paper to determine if the operator's assessment has been correct. If the resulting pressure does not satisfy the operator or the editor, the operator must make further adjustments to the control panel and repeat the process of producing new separations and printing plates. Alternatively, the color separations or printing plates can be modified by etching or other processes.

In order to facilitate the production of color prints, color print preview devices have been developed which simulate the function of the color scanner including the color correction calculator. Such a pre-viewing device 23 is illustrated in Figure 2, in which the color original 10 is scanned by means of a video signal generating device 24, which may be constituted by a TV camera or similar device. The video signal generator 24 generates video signals representative of the element colors in the image 10 and feeds them to a color correction calculator 26 which is equal to or identical to the color correction calculator 14 used in the scanner of Figure 1. The output of the color correction calculator 26 consists of the video signals l8 used in the actual printing process. These are supplied to a printing simulator calculator 28, which modifies the video signals according to the characteristics of the particular printing process to be used. The output signals from the printing simulator 28 are fed to a color image display unit 30, which reproduces a color image representative of the resulting color print which would be obtained using a printing process with the color correction calculator control means set according to the calculator 26 control means settings.

An operator using the viewing device 23 can adjust the color correction control means taking into account the display unit 30 and achieve a setting of the control means, which when applied in the actual color correction calculator 14 in the color scanner 12 will result in an acceptable set of color separations, giving desired qualities. of the color print 22. As stated above, both the color correction calculator 14 and its simulator 26 may be of the order of 90 controls. It is both tedious and time consuming for an operator to manually adjust each of the control means in the color correction calculator 14 in the color scanner 12 in accordance with the setting of the corresponding control means of the viewing device 23. vsovvzu-ag An object of the present invention is to provide a practical, precise and inexpensive device for transferring the controller settings from a process simulating device to a process machine.

A further object of the invention is to provide such a device in which the process simulating device can be used independently of the process machine and the settings of the control means can be transmitted, as this suits the operator of the process machine.

According to the invention, there is provided an apparatus for use with a process machine having a plurality of adjustable process control means which actuate process signals to vary at least one characteristic of the signals and thereby vary the process. The device comprises a process simulating device, which operates in dependence on applied simulation signals and has adjustable simulation control means corresponding to the process control means. The simulation device comprises the indicating means for providing a representation of the actual process results in accordance with the settings of the simulation control means. There are also reading means for providing a sequence of signals representing the controller settings, each representative of the electrical output of one of the simulation controllers, when predetermined simulation signals are applied to the simulator. Finally, there are means for influencing the setting of the control means of the processing machine, which are sequentially responsive to each of the control means setting signals and the electrical output signal from each of the process control means, when the predetermined simulation signals are supplied to the processing machine. Said means affecting the setting of the control means changes the setting of the process means means.

The reading means preferably comprises means for storing the signals representing control means settings.

In this case, said control means influencing means are provided with means which are influenced by the stored signals. The process control means of the process machine can be mechanically actuated, in which case said control means actuating means comprise motors mechanically connected to each of the process control means. The reading means may comprise means for providing a sequence of simulation signals to the simulating device, a selected signal during a time when each of the control means is read to provide a control means setting signal. The controller setting signals are preferably converted from analog to digital form and stored on a storage medium, such as a magnetic tape or perforated strip. The invention is advantageously applied in connection with a color scanning process, in which a pre-viewing apparatus used in the graphic technology comprises the simulation device.

For a more detailed understanding of the invention and other additional objects, reference is made to the following description of the invention, which is made with reference to the accompanying drawings. The features of the invention appear from the claims.

Fig. 1 schematically illustrates a color printing process using a color scanner. In Fig. 2 is a block diagram of a pre-viewing system used in graphic technology.

Pig. 3 is a schematic block diagram illustrating an apparatus for reading and storing controller settings in a simulation system.

Pig. 4 is a schematic block diagram illustrating a device for adjusting the settings of control means in accordance with stored signals.

Pig. 5 illustrates an actuating mechanism for a control member according to the invention.

Fig. 5A is a detail view of the connection of the control means to the device according to Fig. 5.

Fig. 6 is a view of the control panel of a color scanner, which can be used in the process according to Fig. 1. 7807734-4 few - Fig. 3 is a schematic block diagram illustrating the main components of the invention, when this is used in connection with the graphic pre-viewing device 23 according to Fig. 2. The input lines of the color correction calculator 26 transmit video signals representative of the color components yellow, magenta and cyan in the original image '10 as it is scanned by the video signal generating device 24. These video signals are coupled to an array of potentiometers 38a, 38b, 38c, etc., which form control means. in the color correction calculator. The potentiometers 38 are interconnected in a matrix which provides adjustment of the amplitude of each of the video signals and provides the mixing of the video signals to produce signals suitable for the production of color separations. The potentiometers 38 are designed in such a way that they are substantially identical to the corresponding control means in the color correction calculator 14 in the color scanner together with which the graphic pre-viewing device is to be used. Each of the outputs of the contact arms of the potentiometers 38 is in addition to the internal connections in the calculator 26 also connected to a multi-position switch 40 via one of a plurality of buffer amplifiers 39. The switch 40 is controlled by a progress device 42 in accordance with control signals from a control unit 46. The output signal from the switch 40 is coupled to an analog-to-digital converter 44, which generates a digital signal representative of the amplitude of the voltage at the contact arm of the potentiometer connected to the converter 44 via the switch 40. To obtain a meaningful reading of the settings of the potentiometers 38 there is a signal generating device, which consists of a multipole multi-position switch 50 and a voltage generating circuit 48. When the settings of the control means 38 are to be read, the input switches 34 of the video signal inputs are connected to the switch 50. The voltage generating circuit 48 and the switch 50 is used to supply one predetermined set of voltages to the video input terminals switch 34 of the color correction calculator 26. The voltages applied are selected depending on the controller 38 being read. The switch 50 is actuated by a stepper motor 52 under the action of the control unit 46. The units 40-54 form the storage device 32 for potentiometer settings in Figure 3.

In accordance with the invention, signals are applied to the terminals of the color calculator 26 which cause a suitable voltage to be applied across the potentiometer to be read, which is independent of the settings of the remaining potentiometers which have not been read. For example, if all the video signal inputs are grounded to provide an input video signal voltage 0, some of the potentiometers 38 will have a suitable applied voltage, which is not dependent on the settings of the other potentiometers.

These special potentiometers can then be read by the switch 40 and the analog / digital converter 44. The contact arm voltage of the potentiometer is converted into a digital signal, which is fed to a punch strip 54 and stored on a punch strip 56. Each of the potentiometers is read in a predetermined sequence. When all the potentiometers to be read when all the input voltages are 0 have been read, the stepper motor 52 acts on the switch 50 to change the input voltages supplied to the input switch 34.

When the switch 50 is actuated, a second set of voltages is applied to the input switch 34, which provides a suitable voltage on other potentiometers 38, which have not yet been read. The voltage across each of the other sets of potentiometers shall only depend on the applied voltage and the settings of the potentiometers previously read. This condition is necessary because the signals stored for the settings of the control means on the hole strip will be used in the same order for setting the control means of a color scanner. The control unit 46 outputs control signals to the voltage generator 48, the stepping motors 42 and 52 and the strip punch 54. This provides a sequence of operations in which a given set of signals is applied to the input switch 34 of the color calculator, selected copies of the potentiometers are read with respect to the voltage at their contact arms and the readings are converted to digital form and stored on the strip 56 by means of the strip punch 54.

This sequence is followed using different input voltage combinations for selected copies of the potentiometers 38 until all potentiometers have been read. The strip 56 then contains a complete set of potentiometer settings in the color calculator 26 and can be removed from the potentiometer settings storage device 32 for use in a color scanner at a later time.

Figure 4 is a schematic block diagram illustrating an apparatus utilizing the strip 56 for adjusting the control means of a color scanner. As mentioned earlier, the color calculator 14 of a color scanning curve includes a plurality of potentiometers 60a, 60b, 60c, etc., each corresponding to one of the potentiometers 38 of the graphical pre-calculator. The color calculator 14 also has a set of video input terminals with switches 58, each corresponding to one of the component colors yellow, magenta and cyan. A voltage source 62, which is programmed by a controller 76, provides a set of input signals to the input switches 58, which correspond to the signals applied to the switches 34 of the color calculator 26. A multi-position switch 64 is connected to the output of the contact arm at each one of the potentiometer controllers 60 of the color calculator 14 via an isolation amplifier. The switch 64 sequentially connects each of the potentiometer outputs to an differential amplifier 74.

A perforated strip reader 70 is fed with the strip 56, which is produced by the strip punch 54 in Figure 3, and outputs a digital output signal corresponding to the setting signals for control means stored on the strip 56, one for each of the potentiometers in the color calculator. The control position signals are converted from digital to analog form in a digital / analog converter 72 and supplied to the differential amplifier 74. The output of the differential amplifier 74 is connected to a 78077344 »9 of a number of motors 78 connected to the potentiometers 60 via the multi-position switch 68. The motors 78 are mechanically coupled to the control element of the potentiometers 60 and used to sequentially drive the potentiometers to a position in which their output signal is equal to the output signal from the digital / analog converter 72.

The device according to Figure 4 operates to adjust the position of the control elements of the color calculator 14 in a color scanner by the following sequence. The controller 76 provides a signal to the voltage source 62, which causes the source to output a selected set of predetermined simulation voltages to the input switches 58 of the color calculator 14. The controller 76 activates the stepper motor 66 to move the multi-stage switches 64 and 68 to the positions corresponding to the contact arm positions respectively, the motor of the first of the control means potentiometers 60 according to the same sequence used in the device of Figure 3. In addition, the control unit 76 causes the reading unit 70 to read the first stored digital control means of the hole strip 56 corresponding to the desired position of the first potentiometer 60. The digital controller setting signal is converted to analog form by the digital / analog converter 72 and applied to the differential amplifier 74 together with the actual contact arm voltage of the first potentiometer 60.

If the voltages at the input of the differential amplifier 74 are different, a control signal is obtained which is applied to the motor which is mechanically coupled to the closed potentiometer, and which rotates the potentiometer axis until the signals are equal. When the two signals are equal, the output signal from the differential amplifier 74 drops to 0. This state is sensed by the control unit 76, which is then activated to cause the voltage source 62, the reading unit 70 and the stepper motor 66 to be shifted to the next sequential position.

The detailed structure and function of the invention will be understood by reference to its application in connection with a special equipment, such as the color scanner whose control panel is illustrated in Figure 6. To achieve motor operation of the control means on the scanner's control panel, a device of the type shown in Figure 5 are used. The device according to Figure 5 comprises a chassis 80, in which drive motors 78 are arranged, which correspond to the control means of the scanner.

The scanner steering wheels have been removed from their respective shafts on the scanner, leaving projecting shaft pins 82 projecting from the control panel. The chassis 80 comprises a plurality of shafts 84, each corresponding to one of the guide shaft 82. Gears 86 are mounted on the shafts 84 and cooperate with corresponding gears 88 mounted on the drive motors 78, which are connected to the circuit shown in Figure 4. To facilitate installation, the axles 84 are mounted at the chassis 80, so that they can be displaced between two axial positions in the direction indicated by the arrow S. The steering knobs 90, which have been removed from the corresponding shafts 82 of the scanner control panel, can be mounted on the ends of the shafts 84, which project from the chassis 80.

The shafts 84 are connected to the shafts 82 preferably by a coupling of the type illustrated in the exploded view of Figure 5A. Coupling elements 92 and 96, which are provided with projecting portions are fixedly mounted on the shafts 82 and 84, respectively. A central coupling element 94 is provided, which is provided with transverse grooves corresponding to the projecting portions of the parts 92 and 96, so that then the shafts with corresponding coupling elements are brought into contact with the coupling element 94, the projecting portions of the parts 92 and 96 engage with respective grooves in the coupling element 94. A sleeve 98 surrounds the entire coupling mechanism to prevent the coupling element 94 from sliding out of engagement with any of the coupling elements 94. parts 92 and 96 before intervention is achieved. This type of coupling is suitable for performing the blind connection between the shafts 84 and 82, when the chassis 80 is placed in position over the control panel of the scanner. Each of the shafts 84 is first displaced to its axial position at a distance from the shaft 82. The corresponding connecting part 96, which is connected to the shaft 84, is removed from the coupling part 94. This allows mounting of the chassis 80 on the control panel of the scanner without obstruction. of the shaft connections. Each of the shafts 84 can then be rotated individually, while being forced towards its lower position in the direction of the arrow S, whereby when the projecting part of the part 96 engages the groove in the central part 94 the shaft 84 can be displaced to its lower position , in which case the two axes are interconnected from a rotational point of view. Guide knobs 90 are mounted on the projecting shafts 86 and allow manual actuation of the scanner control means in the same manner as before the installation of the control unit.

The sequence for reading the settings of the control means of a graphic dry viewing device and the sequence for setting the control means of a data finder are exemplified by the following table, which indicates a sequence comprising 69 steps, each corresponding to a selection of the 89 control means on a scanner's control panel according to figure 6. Not all control means are set automatically, since some of the control means comprise multi-position switches, which are easy to set while other control means can be easily set by manual actuation. It has been found suitable to use three chassis 80 of the type illustrated in Figure 5 for adjusting the control means of the color scanner illustrated in Figure 6. A first drive chassis is used to control 32 potentiometers left on the control panel.

A second drive chassis is used for controlling the potentiometers designated Y-50 to R-69 and a third chassis is used for presetting the potentiometers Y-70 to B-89. The switch and potentiometers are grouped in the center of the control panel and set manually by the operator. Many of these are adjusted only when changing the type of original image or changing the type of printing process used. As stated above, in order to facilitate the identification of the control means at the control panel shown in Figure 6, the letter prefixes Y, II, C and B for the ferries yellow, nnagenta, cyan and black have been given, which are indicated by the color. on the steering wheel on the color scanner. The control means which comprise potentiometers which do not refer to any color are denoted by the prefix R and switches have the prefix S. The only meter in the control panel has the prefix D.

TABLE Sequence Voltages Control element no. Y M C Nr. 1 0 0 0 R 69 2 0 0 0 Y- 53 3 0 0 0 M 54 4 0 0 0 * C 55 5 O 0 0 R 65 6 0 0 0 R 67 'I 0 0 0 R 68 8 0 0 0 B 31 9 0 0 OR 73 10 0 0 0 R 87 ll 0 O 0 B 63 12 10 0 0 Y 50 1.3 10 0 0 Y 1 14 10 O '0 M 9 15 10 0 0 C 17 16 10 0 0 B 25 17 10 0 0 Y 56 18 l0_ 0 0 R 62 19 10 0 0 B 32 20 10 0 0 R 79 21 0 10 0 M 51 22 0 10 0 Y 2 23 0 10 0 M 10 24 0 10 0 C 18 25 0 10 OB 26_ 26 0 10 0 M 57 27 O 10 OY 59 28 0 10 0 C 61 29 0 10 0 Y 3 30 0 10 0 M ll 31 0 10 0 C 19 32 0 10 0 B 27 33 0 0 f 10 C 52 34 0 O 10 Y 6 35 0 0 10 M 14 36 0 0 10 _C 22 37 0 0 10 B 30 38 0 0 '10 C 50 39 O' 10 M 60 7807731441 13 Sequence Voltages Control element no. Y M C Nr. 40 0 6 10 Y 4 41 0 6 10 M 12 42 0 6 10 C_20 43 0 6 10 B 28 44 0 0,07 10 Y 5 45 0 0,07 10 M 13 46 0 0,07 10 C 21 47 '0 0.07 10 B 29 48 0 0.08 "0.32 Y 7 49- 0 0.08 0.32 M 15 50 0 0.08 0.32 C 23 51 0 0.07 0.31 Y 8 52 O 0.07 0.31 M 16 53 O 0.07 0.31 C 24 54 10 10 10 Y 81 55 10 10 10 M 82 56 10 10 10 C 83 57 10 10 10 B 84 58 10 10 10 B 89 59 10 10 10 'R 86 00 10 10 10 R 88 61 10 10 10 R 64 62 OO 0 Y 75 63 0 0 0 Y 70 64 O 0 0 M 76 65 0 0 0 M 71 66 0 0 0 C 77 67 0 0 0 C 72 68 0 0 0 B 78 69 10 10 10 R 66 The table above shows a sequence for reading the control elements in a graphical pre-viewing device and setting the control means of a typical color scanner, eg of the type Hell Chromograph DC 300. I according to the sequence, after the graphical pre-consideration disorder has been adjusted so that the indicator shows an acceptable color print, the system for automatically reading the settings of the control means of the graphic pre-consideration device and storing these settings on a strip of paper or other storage medium. The sequence given above is not unique but has been selected for simplicity and to provide a small number of different sets of input voltages and so that the control means of the color filter are set in an order so that the voltage applied slightly special control means are not dependent on the setting of a control means which has not yet been set.

In the controller 46 of the device according to Figure 3, the sequence initiates by issuing an order to the voltage generating device 48 and the multi-pole switch 50, which causes the switch to be set to deliver an input voltage 0 to all input switches 34. Simultaneously activated the advancer 42, so that the switch 40 connects the control element R 69 of the graphic pre-viewer.with the analog / digital converter 44. An additional control signal causes the punch unit 54 to store the output voltage of the control means R 69 on a paper strip 56. When this has been done the controller 46 activates the advancer 42 to displace the switch 40 and connect the controller Y 53 to the analog-to-digital converter 44 for the second stage of the reading sequence of the controllers. After step number 11 in the sequence, the controller 46 outputs a control signal to the stepper motor 52 and the voltage source 48, which causes a 10 V input voltage to be applied to the yellow color video signal input terminal while the remaining video signal input terminals remain grounded. The control unit then activates the reading process of the control device outputs in the sequence indicated in the table. When the output signals from all the controllers in the sequence have been read, the paper strip can be removed from the strip punch and transferred to the color scanner together with the original image 10 for use by the scanner operator in making color separations.

An essential feature of the invention is that the color scanner can work independently of the graphic pre-viewing device and that the work of the two machines does not need to be coordinated in time for each particular original.

The original image and the output strip from the graphic prefabricator can be stored until the color scanner is free to produce separations from the corresponding original. To set the color scanner control means, the operator inserts the punched strip 56 into the strip reader 70 and the control unit 76 is activated to initiate the strip reading and the setting cycle of the control means. This cycle follows the same sequence as indicated in the table above and according to which the signal outputs from the control elements of the graphic pre-viewer were read. In the controller setting cycle, the controller 76 causes the voltage source 62 to supply the first set of voltages, all inputs 0 V, to the input switches 58 of the color calculator. The strip reader 70 then reads the digital signal representative of the output voltage of the controller No. R 69, which is stored on the strip 56, and supplies it to the digital / analog converter 72, which generates a reference voltage.

The stepper motor 62 actuates the switches 64 and 68 to connect the output terminal of the control means NrR 69 on the color scanner with the differential amplifier 74 and simultaneously connects the output of the differential amplifier 74 to the motor 78 connected to the control means R 69. The differential amplifier 74 emits an output signal to the switch 68 and the motor 78 connected to the control element R 69 which causes the motor 78 to rotate and change the setting of the control means R_69 until its output signal is equal to the stored output signal obtained from the strip 56 which is applied to the second terminal of differential amplifier 74.

When the two signals applied to the differential amplifier 74 are equal, the output of the differential amplifier approaches 0 volts, a state which is triggered by control clock 76 which activates the reader 70 to read the stored setting signal corresponding to the next control means, control means Y 53, and supplying a new reference signal in analog form to the differential amplifier 74, while the step switch 66 connects the output of the control means Y 53 and the motor corresponding to the control means Y 53 to the differential amplifier 74. This process is repeated until all the control elements of the color scanner which are motorized have in- 7807734-4 16 .still. At appropriate points in the sequence, the controller 76 supplies a control signal to the voltage source 62, which causes the source 62 to change the input voltage applied to the input switches 58. It was noted above that not all of the color scanner controllers need to be motorized. The non-motorized control means can be set manually by storing their settings, when the image is viewed on the graphical pre-viewing device, and by the color scanner operator adjusting the position of these control means, when necessary or appropriate. In many cases, the settings of the control means do not need to be changed from one image to the next.

It is obvious to those familiar with this technique that the device according to the invention can be applied to systems other than color scanners and graphic pre-viewers. In general, the system is applicable for use together with a process machine_with variable control means and with a process simulating device with corresponding control means. Similar electronic devices can simulate chemical processes, such as photographic, mechanical, or electrical processes, such as the production of tape recordings or recordings.

It is further understood that components other than those illustrated can be advantageously used in a device according to the invention. In the form illustrated by the invention, multi-position and / or multi-pole step switches are used. Those familiar with digital circuits will recognize that such switches can be easily replaced with semiconductor type multiplexing circuits which perform the switching function depending on digital control signals. Similarly, the strip punching device described above can be replaced by any similar storage device, such as a magnetic tape, disk memory or perforated card. It is also possible and in some cases practical to apply the invention without the use of a storage medium by directly connecting the output of the switch 40, which is connected to the control means in the process simulating device with one of the poles of the differential connection. the amplifier 74. The use of a storage medium, such as a strip 56, facilitates separate and independent use of the process simulating device, such as a graphic pre-viewer, and the processing machine, such as a color scanner.

The invention can also be applied to systems which use control means other than potentiometers. The control means used in a system may comprise variable capacitors or inductors or even variable gain amplifiers. In such applications, it may be necessary to use other or more complex test signals when reading and adjusting the control means.

In some cases, for example, it may be necessary to use tone signals with a single frequency or the like for setting the control elements. In these cases, the characteristic output signal from the control means may be something other than the voltage at the output of the elements. Accordingly, other types of detectors and test signal generator circuits may be suitable.

Although it has been described above what are considered to be the preferred embodiments of the invention, those skilled in the art will recognize that other and further modifications thereof may be made without departing from the spirit of the invention as defined in the appended claims.

Claims (12)

780773444 Patent claims A simulation device for use in connection with a process machine (12) having a plurality of adjustable process control means (60), which actuate process signals to vary at least one characteristic of said process signals and thereby vary the process, comprising means (24) for providing simulation signals representative of said process signals, a plurality of adjustable simulation control means (38) for modifying said simulation signals, each corresponding to one of said process control means (60), and indicating means (30) susceptible to said modified simulation signals for providing a representation of the current process result corresponding to the settings of said simulation control means (38), characterized in that it comprises reading means (40, 44) operatively connected to said simulation control means (38) for producing a sequence controller setting signals are each representative of the electrical the output of one of said simulation controllers (38), when predetermined simulation signals are supplied to said simulation device, and machine controllers connected to respective outputs of said reading means for providing a machine readable representation (56) of said controller setting signals. Device according to claim 1, characterized in that said machine control means comprises storage means (32) for providing stored sequences of machine-readable control signals for said process machine. Device according to claim 1, characterized in that said reading means comprises means (44) for providing a digital signal representative of said electrical output signal corresponding to the setting of each of said control means (38). Device according to claim 2, characterized in that it comprises means (40) for sequentially connecting said reading means to each of said simulation control means (38). 780773114) 19 Device according to claim 2, arranged to operate as a graphic pre-viewing device (23) for use in connection with a color scanner (14) with a plurality of adjustable control means (60) for influencing color-representative video signals in order to vary the video signal characteristics and thereby vary the color separations (18) provided by the scanner, characterized in that said control means are constituted by the control means (38) of a color correction calculator (26), each corresponding to one of said control means (60) of the scanner (12); , in order to influence simulation video signals in order to vary the video signal characteristics and thereby generate simulation signals representative of color separations, that said means for supplying simulation signals is constituted by a video signal generating device (24), which on the basis of a color image (10) provides a set of color representative simulation video signals corresponding to the video signals in said scan (12) and supplying said video signals to said control means (38), that a printing simulator (28) is arranged to influence said separation signals for generating video signals representative of a color print, which would be produced in a color print, in response to said color separation simulation signals. actual printing process, that said indicating means (30) are arranged to, in response to outputs from said printing simulator (28), illustrate an image representative of a color print, and that said reading means (40, 44) are arranged to produce a sequence control means setting signals, each representative of the electrical output signal from one of said control means (38) of the pre-viewing device (23), when predetermined voltages are applied to the video signal input of said color correction calculator (26). IN Apparatus according to claim 1, wherein said machine control means is arranged to provide a real-time control of said process machine, characterized in that it comprises detection means (70, 72), which in dependence on an encoded storage medium ( 56) are arranged to supply a sequence of reference signals representative of the outputs of the desired control means (60), when a predetermined set of process signals is supplied to said processing machine, said means for supplying simulation signals being a signal generator (62) for supplying said set of predetermined process signals to said processing machine, said reading means being sampling means for producing a sequence controller means each representative of the output of one of said control means, said machine control means comprising drive means (74, 78) susceptible to said reference signals and said control means for sequentially varying each of said control means (60) til The signals of said control means are equal to said regeneration signals, and system control means (76) for controlling the function of said detection means (70), said signal generator (62), said sampling means and said drive means. Device according to claim 6, characterized in that said sampling means comprises means (64) for sequentially connecting each of said process control means (60) to said drive means. _ Device according to claim 6 or 7, characterized in that the drive means comprise a differential amplifier (74) receptive to said reference signals and said control means signals for providing a motor drive signal, and motors (78) for adjusting the settings of said process control means (60). Device according to claim 8, characterized in that said drive means further comprises a means (68) for connecting the connection of each of said motors (78) to the output of said differential amplifier (74). Device according to any one of claims 6-9, characterized in that said drive means comprises a plurality of motors (78), each mechanically connected to one of said process control means (60). IN Device according to claim 10, characterized in that said motors (78) are mounted on a chassis adapted for mounting on said processing machine and that means 7807734-4 21 are arranged for mechanically connecting said motors (78) to said process control means (60). Device according to claim 6 for setting control means (60) of a color scanner (12) in accordance with control means setting signals, which are coded on a storage medium (56), characterized in that said detecting means (70, 72) is sufficient for said coded setting signals to provide a sequence of reference signals representative of desired outputs from the scanner control means (60), when a predetermined set of simulated video signals is supplied to said scanner, said signal generator being a voltage source (62) said predetermined set of simulated video signals to said scanner, said drive means comprising a differential amplifier (74) receptive to said reference signals and outputs from the control means (60) to provide a motor drive output signal, a plurality of motors (78), each mechanically for - connected to one of said control means (60), and first switch means (68) for selectively connecting the output of said a differential amplifier (74) having each of said motors (78), said sampling means comprising second switch means (64) for selectively connecting the outputs of each of said control means (60) to an input of said differential amplifier (74), and that said system controller (76) is arranged to drive said detection means (70), said voltage source (62) and said first and second switch means (64, 68) in accordance with a predetermined sequence. 'lš. . Device unliql. claim 1 avzn-dcl .ull inqí) in vn .mouling for use in connection with a color scanner (12) with a plurality of adjustable scanner controllers (60) for influencing color-representative video signals to vary the video signal characteristics and thereby vary the color separations (18) obtained by the scanner (12), characterized in that it is arranged to serve as a graphical pre-viewing device (23), which operates in dependence on added color representative video 780773114; 22 signals and has adjustable pre-viewer control means (38) corresponding to said scanner styrog (60), that said pre-viewer device (23) comprises a display unit (30) for illustrating a simulation of a color print produced from separations which would be generated by a scanner set. according to the settings of said preamplifier control means (38), said reading means (40, 44) of said simulation device being arranged to provide a sequence of control means setting signals, each representative of the electrical output signal from one of said preamplifier control means (38). 38), when predetermined voltages are applied to the video signal input of said pre-viewing device, and that said machine control means is in the form of drive means for the scanner control means (60) for adjusting the settings of said scanner control means and sequentially responsive to each of said preamplifiers. controller setting signals and the electrical output of each n by said process control means, when said predetermined voltages are applied to the video signal input of said scanner.