Patent Publication Number: US-5157518-A

Title: Image data control system for image reading equipment

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present Invention relates to an image reading equipment for digital copying machines, facsimile machines, or the like and more particularly to a data control system which, being used for an image reading equipment, develops the signals representing the image on the original sheet in terms of density signals, converting the analog signals obtained by reading, by means of its sensor, the amount of the light reflected from the original sheet into digital signals, and thereafter transforming the said digital signals into density signals. 
     2. Description of the Prior Art 
     Image reading equipments, such as digital copying machines and facsimile machines, read the original sheet by means of a CCD line sensor and converts the analog signals into digital signals, with which such equipments perform the storing in memory, processing, and editing of the said signals and perform such processes as the registration of the image signals on the copying paper. The CCD line sensor which is used for this process of reading the original sheet, is designed to read the amount of the light reflected from the original sheet on which light is shed from the light source, and, in order to use the light so read as the recording signal, it is necessary to convert the said light into signals representing the density of the toner. Moreover, the CCD line sensor is designed also to be capable of simultaneously reading a plural number of picture elements and scanning them to transforming them into serial signals, in which form the said CCD line sensor takes the image signals into the system, and, furthermore, when the CCD line sensor is employed for a color image reading equipment, it is provided with filters for R (red), G (green), and B (blue), as set in an arrangement in the stated order, for the purpose of obtaining the color decomposing signals. Therefore, the signals read out of the CCD line sensor in such a case will be serial signals in the sequence, RGBRGB . . . . . . . 
     In this regard, it would not serve the purpose of practical use, in view of the wafer size, the yield, the cost, and so forth, that uniform sensitivity should be formed, without any fall-off, as one chip on a single board in the CCD line sensor. For this reason, it is a system in common practice to set up a plural number of chips arranged in the main scanning direction, so that the individual sensors together read the image of one line as divided among them and to apply the signal processing of the divided signal in each of the individual channels. 
     For example, there is a system in which five chips with the processing capacity of 2928 picture elements arranged in a zigzag pattern in a CCD line sensor which is capable of reading an original sheet of the standard A3 size. In a color image reading device like this, the signals RGBRGB as read out of the CCD line sensor are separated into R, G, and B, respectively, and a process is performed further to synthesize the R, G, and B in the individual channels to develop serial signals on the R, G, and B, respectively. 
     However, the characteristics of the photoelectric conversion by the CCD line sensor are such that there occurs a difference in the level of signals between the individual channels and the individual picture elements as illustrated in FIG. 39 (a), where the reading signal level for the white reference board is represented as &#34;the white color&#34; while the signal level at the dark time output with no input of light is represented as &#34;the black color&#34;. Hence, it is conveivable to match the average level of the individual channels. However, such an adjustment would cause the occurrence of differences in the grades of density due to the differences in the level in the marginal parts of the individual channels. Moreover, it is also conceivable to match the level in the marginal parts of the individual channels, but an adjustment like this, which would eliminate the differences in the grade of density in the marginal parts of the channels, would nevertheless liable to the appearance of streaks or uneven coloring in the supplementary scanning direction on copies in consequence of the inconsistency caused to appear in the individual picture elements or in the region in the principal scanning direction in consequence of the fluctuations in the density level because there would be differences in the output even in the reading of an original sheet in the same density. 
     Furthermore, as lower values than those of the output from the normal picture elements are output while an original sheet with higher density is being read, the level of the density signal will be lower in relative terms, with the result that black streaks will be visually recognized in the output image, and, conversely, when higher values are output while an original sheet with higher density is being read, white streaks will be visually recognized in the output image. 
     Thus, the CCD line sensor presents such problems in the original sheet reading signal as the deviations between the chips, the deviations among the picture elements in a chip, and the differences in terms of their characteristics. In addition, the distribution of the amount of light from the light source, the fluctuations in the amount of light, the deterioration accompanying the passage of time, and so forth also present problems. 
     SUMMARY OF THE INVENTION 
     This Invention overcomes the problems mentioned above, and the purpose of this Invention consists in the effective performance of the correction of the differences between the chips and the differences among the picture elements in a chip in the conversion characteristics of the CCD line sensor. 
     Another purpose of this invention is to ensure the stable performance of the correction at all times even if changes may occur in the conversion characteristics and the the distribution of the amount of light from the light source. 
     Still another purpose of this invention is to reduce the mutual interference between the gain control and the offset control. 
     Still another purpose of this invention is to develop ease and facility in the performance of the adjustment of the image data and the correcting process. 
     Still another purpose of this invention is to output images in favorable conditions through correction of fluctuations in the signal level in the dark time output from the CCD line sensor. 
     Still another purpose of this invention is to prevent the occurrence of differences in density in the sensor boundary even in case a plural number of sensors are arranged side by side. 
     In order to attain the purposes mentioned hereinabove, this Invention propose a system which is characterized by its design to perform the offset control 8 and dark time output correction 9 by the picture element as the unit after it has performed gain control 7, as shown in FIG. 1 (b), in an image reading system which performs gain control and offset control applied, by means of the image data control means 2, to the analog signals read of the amount of the light which is reflected from the original sheet, using the line sensor as shown in FIG. 1 (a), performs the conversion of the said analog signals into digital signals by means of the A/D conversion means 3, and subsequently performs of dark time output correction through the image data control means 4, thereby converting the said digital signals into density signals, thereby obtaining the original sheet reading signals. This system is therefore capable of eliminating the inconsistency in density through its stabilization of characteristics especially in the high density region, although there may remain some fluctuation after the gain control in the low density region, which represents the region for the white color signal, because this system thus performs the offset control 8 after the gain control 7. 
     Moreover, this system stores the set adjusted values in the memory device and, by loading the adjusted values by way of the line memory 5, performs the process for the collection of data by means of the data processing means 6 with the said adjusted values, and thereafter performs the processing of the adjusted values for their conversion to the target values through the correction of the said adjusted values on the basis of the comparison performed between the values of the collected data and the target values. Therefore, this system is capable of obtaining a collected value close to the target value in the very beginning, so that it can reduce the duration of time necessary for the converging process. 
     Furthermore, this system is characterized by being connected with a dark time output correcting circuit, which has a line memory device and performs the dark time output correction for each picture element, and with a conversion table for the said dark time output correcting circuit, and with a shading correcting circuit, which has a line memory device and performs the correction of the white level in the output from the conversion table, and being capable of performing its collection of data from any of the line memory devices mentioned hereinabove. This system has the dark time output correcting circuit connected to it in this manner and utilizes the line memory device of the said circuit, and therefore this system is capable of performing the collection of data and the dark time data correction by the picture element as the unit in a simple and convenient way. 
     In the gain control process, moreover, this system corrects the gain on the basis of the ratio between the maximum value and the minimum value, performs the process for the conversion to the target value by finding the adjusted value occurring in the gain control circuit in correspondence to the said gain by a process of approximation based on the characteristics found between the gain and the adjusted gain value, and additionally this system is so designed as to find the adjusted value corresponding to the gain by an approximating equation or with reference to a look-up table. Therefore, this system can achieve the convergence with a fewer number of times of the processing operations. 
     As it is evident from the description given hereinabove, this Invention makes it possible to maintain the reproducibility of images in a stable state since it is capable of performing adequate control, adjustment, and correction, even in case there are any deterioration of the amount of light from the light source with the passage of time, any fluctuation in the input and output of the image data, the variations in the dark time output inherent in the CCD line sensor, and so forth, because the system sets the gain control value, the offset control value, and the ΔV dark time output correction value always at the prescribed target values at the power-ON time. In addition, this system can prevent the deterioration of chromatic gradation in the images since it performs the gain control prior to the offset control. The system can also accomplish an improvement on the processing speed for convergence because it performs the process for convergence to the prescribed target value with a value approximating the characteristics of the gain and offset values in the controlling circuit and the set values fed from the VCPU when it performs the gain control and the offset control. Moreover, also for the platen mode and the F/P mode, the system is capable of performing the control and the adjustment in a manner adequately dealing with the particular mode. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1(a) and 1(b) are schematic diagrams illustrating one embodiment of the image data control system according to this invention for use in the image reading system. 
     FIG. 2 is a chart illustrating one example of the overall construction of the color copying machine to which this invention is applied. 
     FIG. 3 is a chart illustrating the hardware architecture. 
     FIG. 4 is a chart illustrating the software architecture. 
     FIGS. 5(a) through 5(e) are charts illustrating the copy layers. 
     FIG. 6 is a chart illustrating the division of states. 
     FIG. 7 is a chart illustrating the sequence from the power on state to the stand-by state. 
     FIG. 8 is a chart illustrating the sequence in the progress state. 
     FIG. 9 is a chart for explaining the concept of diagnostics. 
     FIG. 10 is a chart illustrating the relationship between the system and the other remote units. 
     FIG. 11 is a chart illustrating the construction of the modules in the system. 
     FIGS. 12(a) through 12(c) are charts illustrating the making of the job mode. 
     FIG. 13 is a chart for illustrating the data flow between the system and each of the individual remote units as well as the data flows among the modules within the system. 
     FIG. 14 is a chart illustrating an outline of the construction of the modules in the IPS. 
     FIGS. 15(a) through 15(q) are charts for explaining the individual modules forming the IPS. 
     FIGS. 16(a) through 16(d) are charts illustrating an example of the hardware construction of the IPS. 
     FIG. 17 is a chart for illustrating an outline of the construction of the IOT. 
     FIGS. 18(a) and 18(b) are charts illustrating an example of the construction of the the image transfer system. 
     FIGS. 19(a) through 19(c) are charts illustrating an example of the installation of the UI with a display unit used for it. 
     FIGS. 20(a) and 20(b) are charts for illustrating examples of the angle-setting and height for the installation of the UI. 
     FIG. 21 is a chart for illustrating the configuration of the modules of the UI. 
     FIG. 22 is a chart for illustrating the configuration of the hardware for the UI. 
     FIG. 23 is a chart showing the construction of the UI CB. 
     FIG. 24 is a chart showing the construction of the EP IB. 
     FIGS. 25(a) through 25(c) are charts for explaining an example of the construction of the display screen. 
     FIG. 26 is a diagonal view for the F/P. 
     FIG. 27 is a diagonal view of the M/U. 
     FIG. 28 is a diagram for explaining the density characteristics of negative film and the principle of correction. 
     FIG. 29 is a chart schematically illustrating the construction of the F/P and showing the relationship among the F/P and the M/U and the IIT. 
     FIG. 30 is a chart for illustrating the operating procedure and the timing. 
     FIGS. 31(a) and 31(b) presents a sectional view of the imaging unit and a sectional view of the fluorescent lamp. 
     FIG. 32(a) is a chart illustrating an example of the arrangement of the CCD line sensors. 
     FIG. 32(b) is a chart showing an example of the arrangement of the color filters. 
     FIG. 33 is a chart illustrating the relationship between the reduction or enlargement ratios and the amounts of deviation in reading. 
     FIG. 34 is a diagonal view chart showing the driving mechanism for the imaging unit. 
     FIG. 35(a) is a chart showing the driving circuit for the stepping motor. 
     FIG. 35(b) a chart showing the sequence for the excitation of the magnet. 
     FIGS. 36(a) and 36(b) are charts for explaining the scanning cycles performed by the imaging unit. 
     FIGS. 37(a) through 37(c) are charts for explaining the causes for the deviations of colors in color copying. 
     FIG. 38 is a chart illustrating one example of the construction of the video signal processing circuit. 
     FIGS. 39(a) and 39(b) are charts showing the image data level and an example of data control. 
     FIGS. 40(a) and 40(b) are charts illustrating the conversion table. 
     FIGS. 41(a) and 41(b) are charts for explaining the correction applied to a deviation of picture elements. 
     FIGS. 42(a) through 42(e) are charts showing the waveform of the output. 
     FIGS. 43(a) through 43(c) are charts for explaining the control modes of the IIT, respectively. 
     FIG. 44 is a chart for illustrating the circuit diagrams of the AGC and the AOC. 
     FIG. 45 is a chart illustrating the circuitry of the ITG. 
     FIGS. 46(a) and 46(b) are charts for illustrating the construction of the shading correction section and the shading correcting circuit. 
     FIG. 47 is a chart illustrating an example of the arrangement of the connecting pins on the LSI. 
     FIG. 48 is a chart for explaining the overall flow of the image data control process. 
     FIGS. 49(a) through 49(k) are charts for explaining the flow of the individual processing routines. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     In the following part, this Invention is described in detail with reference to its preferred embodiments. 
     Table of Contents 
     As regards this embodiment, this Invention is described with reference to its preferred embodiment in a color copying machine, as a type of recording equipment provided with a reading system for the original sheets, but its embodiments are not limited to this, since this invention can, of course, be applied also to printers, facsimile machines, and other image recording equipments. 
     Before any description is made of the embodiment, a table of contents is presented below. Moreover, in the description presented hereinbelow, the items in (I) and (II) are those items for describing the outline of the overall construction of the copying machines to which this Invention is applied, and, within the said overall construction, the items under (III) present a description of the embodiment of this Invention. 
     (I) Outline of Equipment 
     (I-1) Construction of equipment 
     (I-2) Functions and characteristic features of the systems 
     (I-3) Construction of electrical control systems 
     (II) Specific Construction of Various Parts 
     (II-1) Systems 
     (II-2) Image processing system (IPS) 
     (II-3) Image output terminal (IOT) 
     (II-4) User interface (U/I) 
     (II-5) Film image reading device 
     (III) Image Input Terminal (IIT) 
     (III-1) Imaging unit 
     (III-2) Driving mechanism for imaging unit 
     (III-3) Control system for stepping motor 
     (III-4) Video signal processing circuit 
     (III-5) Control system for IIT 
     (III-6) Constructions of individual circuits 
     (III-7) Image data control process 
     (I) Outline of Equipment 
     (I-1) Construction of equipment 
     FIG. 2 shows one example of the overall construction of a color copying machine to which this Invention is applied. 
     The color copying machine to which this Invention is applied is formed with the base machine 30, i.e. the basic constituent unit, which is composed of a platen glass plate 31, which carries the original sheet thereon, an image input terminal (IIT) 32, an electrical control system container 33, the image output terminal (IOT) 34, and a paper tray 35, and a user interface (U/I) 36 and also, as optional items, of an editing pad 61, an automatic document feeder (ADF) 62, a sorter 63, and a film projector (F/P) 64. 
     Electrical hardware is necessary for performing the control of the IIT, IOT, U/I, etc. mentioned above, and these hardware items are the IIT and those installed separately on a plural number of boards for each of the processing units, such as the IIT, IPS, which performs the image-forming process for the output signals from the IIT, U/I, F/P, and so forth, and these are accommodated further in the electrical control system container 33, together with the SYS board performing the control of these, and the MCB board (the Machine Control Board) for controlling the IOT, the ADF, the sorter, and so forth. 
     The IIT 32 is composed of an imaging unit 37, the wire 38 for driving the said unit, the driving pulley 39, and so forth, and the IIT 32 reads a color original sheet for each of the primary colors B (Blue), G (Green), and R (Red) by means of a CCD line sensor and a color filter provided inside the imaging unit 37, converts the data so obtained into digital image signals, and then outputs the signals to the IPS. 
     In the IPS, the B, G, and R signals mentioned above are transformed into the primary colors of the toner, i.e. Y (Yellow), C (Cyan), M (Magenta), and K (Black), and then, with various data processing being applied to the data so obtained for the purpose of enhancing the reproduction fidelity in terms of coloration, chromatic gradation, precision and fineness, and so forth, the IPS converts the toner signals of the process color in harmonious gradation into binary toner signals and outputs them to the IOT 34. 
     The IOT 34, which is provided with a scanner 40 and a photo-sensitive material belt 41, converts the image signals from the above-mentioned IPS into optical signals in the laser output part 40a and forms a latent image corresponding to the image on the original sheet on the photosensitive material belt 41 by way of the polygon mirror 40b, the F/θ lens 40c, and the reflexive mirror 40d. The photosensitive material belt 41, which is driven by the driving pulley 41a, has a cleaner 41b, a charging unit 41c, the individual developing devices for Y, M, C, and K, and a transfer device 41e arranged around it. And, opposite to this transfer device 41e is provided a transfer unit 42, which takes into it the sheet that comes transported to it from the paper tray 35 via the paper transport channel 35a and transfers the colors in the order of Y, M, C, and K, the transfer unit 42 being rotated four turns, for example, for full-color copying in four full colors. The sheet of paper on which the image is so transferred is then transported from the transfer unit 42 via the vacuum transport device 43 to the fixing device 45, where it is fixed, and is thereafter discharged from it. Moreover, the paper transport channel 35a is so designed as to accept the paper fed alternatively from the SSI (Single Sheet Inserter) 35b. 
     The U/I 36 is designed for use by the user for making the selections of the desired functions and for giving instructions regarding the conditions for the execution of the selected functions, and this system is provided with a color display unit 51 and a hardware control panel 52 installed by the side of the said display unit, and it is further combined with an infrared ray touch board 53, so that instructions can be given directly with the &#34;soft buttons&#34; on the screen. Next, a description is made of the optional items for the base machine 30. One of them is the editing pad 61, which is an input device based on a system of coordinates and, when it is to be placed on the platen glass plate 31, permits the editing of various types of images by means of an input pen or a memory card. Moreover, the base machine 30 is so designed as to accept the installation of the existing ADF 62 and the existing sorter 63. 
     Furthermore, one of the features characteristic of this embodiment is the capability of the system to produce a color copy directly from color film, with a mirror unit (M/U) 65 mounted on the platen glass plate 31 and with the film image being projected onto the said unit from the F/P 64, and the projected image being read as image signals by means of the imaging unit 37 of the IIT 32. The original sheet materials for this process are negative film, positive film, and slides, and this unit is provided with an automatic focusing device and an automatic changing device for the rectifying filter. 
     (I-2) Functions and characteristic features of the systems 
     (A) Functions 
     This Invention has a major characteristic feature in its offer of a full automatic system covering the entire copying process from the inlet of copying work to the exit thereof while providing fully variegated and multifarious functions dealing adequately with the users&#39; needs and at the same time producing a system which everybody can operate with ease owing to such features as the selection of the functions, the selection of the executing conditions, and the display of other items on the menu, which are put on display on the CRT screen, etc. in the user interface mentioned above. 
     A principal function of the system embodying this Invention is to be found in making it possible to select the various kinds of functions by touching operations on the soft buttons on the primary screen, with operations performed on the hardware control panel for making the switching of start, stop, all clear, ten-key, interrupt, information, and language, i.e. the factors which cannot be delimited in the operational flow. Also, the system permits full-color and black-and-white copying work with such simple operations that a copying machine embodying this invention can be used with the operating impression of the conventional copying machine, owing to the features permitting the selection of various types of editing functions, such as marker editing, business editing, and creative editing, by a touch on the pathway tab corresponding to the pathway representing the region for the selection of functions. 
     This equipment offers the functions of full-color copying in four colors as its major characteristic feature, and additionally it permits the selection of three-color copying and black-and-white copying. 
     For the feeding of paper, this system permits automatic paper selection as well as the selection of a specified paper size. 
     For reduction or enlargement, this equipment accepts the setting of magnification by one per cent in the range from 50% to 400%, and also the equipment is provided with the function of differential magnification, which sets the vertical magnification and the horizontal magnification independently of each other, and the function for the automatic selection of magnification. 
     The copying density is determined by automatic density adjustment with respect to black-and-white original sheets. 
     For color original sheets, the system performs automatic color balance adjustment, and, for color balance, the system permits the operator to specify the color a reduction of which is to be desired in its reproduction on the copy. 
     For the job program, the system permits the reading and writing of a job with a memory card, which can store eight jobs in the maximum. The memory capacity is 32 kilo bytes, and it is possible to perform the programming of the jobs other than those in the film projector mode. 
     Apart from these, the system is provided with such additional functions as copy output, copy sharpness, copy contrast, copy position, film projector, page programming, and margin. 
     With the copy output function, the selection of &#34;Uncollated&#34; made while a sorter is attached as an optional item to the equipment sets the maximum adjustment function into operation, with the result that the set number of sheets is adjusted to fit within the maximum value of the sheets of paper that can be contained in the bin. 
     For the sharpness control function, by which the edges of the copied images are emphasized, provides such optional functions as manual sharpness control in seven steps as well as photograph sharpness control functions composed of photographs (Photo), characters (Character), mesh dot print (Print), mixture of photograph and characters (Photo/Character). And these functions can be set voluntarily by default and by the tool pathway. 
     The contrast of copies can be voluntarily adjusted in seven steps by the operator, and the default can be set voluntarily by the tool pathway. 
     The copy position function is the function for selecting the position where a copied image is to be placed on the paper, and, as an optional function, the system features the automatic centering function, which positions the center of the copied image in the center of the paper, and the default is automatic centering. 
     The film projector function makes it possible to get copies from various types of film, and this function permits the selection of 35 mm negative or positive projection, 35 mm negative positioned on the platen, 6 cm×6 cm slide positioned on the platen, and 4 in×4 in slide positioned on the platen. The film projector function makes automatic selection of the A4-size paper unless any other paper size is specifically selected. Moreover, a color balance function is provided in the film projector pop-up, and, with this color balance function set in the &#34;Reddish&#34; position, the coloration of the image reproduced on the copy will be rectified to assume an increased reddish tone and, when the function is set in &#34;Bluish,&#34; the color reproduced on the copy will be rectified with an increased bluish tone. Moreover, this function offers unique automatic density control and manual density control. 
     For page-programming, this system provides the covering function, which puts a back cover or a front cover to copies, the inserting function, which puts a sheet of white paper or colored paper between one copy and another, the color mode function, which makes it possible to set the color mode page by page for the original sheets, and the paper selecting function, which makes it possible to select a proper paper tray page by page for the original sheets and which can be set together with the color mode function. 
     The margin function makes it possible to set the margin by 1 mm within the range from 0 mm to 30 mm and this function is specifiable only for one side of one original sheet. 
     The marker editing function is a function for performing editing and processing work in the area surrounded with markers. 
     This function is applicable to documents, and consequently the original sheets are treated as black-and-white original sheets, the images within the specified area being restored to the palette colors on the CRT and the areas other than the specified one being rendered in black on the copy. In the black and red mode, moreover, the image is changed into red while the areas other than the specified area is rendered in black and red on the copy. This function are accompanied with the trimming, masking, color mesh, black-to-color functions. Furthermore, the specification of the area is done either by drawing a closed loop on the original sheet or by specifying the area by means of the editing pad. The same procedure applies also to the specification of the area for processing in each of the editing functions mentioned hereinbelow. Additionally, the area so specified is displayed in an analogous figure in the bit map area on the CRT. 
     The trimming function works for copying only the images within the marked area in black-and-white rendition and to erase the images positioned outside the marked area. 
     The masking function works for erasing the images within the marked area and to copy in black and white only the images positioned outside the marked area. 
     The color mesh function places a specified color mesh dot pattern in the marked area and reproduces the image in black and white on the copy, with the color of the said color mesh being selected out of the eight standard colors (the specified colors as determined in advance) or out of the eight registered colors (the colors registered by the user; a maximum of eight colors can be registered at the same time out of 16,700,000  available colors), and a mesh pattern can be selected out of four patterns. 
     The black-to-color function permits the reproduction of the image within the marked area on the copy in any specified color selected out of the eight standard colors or out of the eight registered colors. 
     The business editing function aims at quickly producing high-quality original documents mainly for business documents, and the original sheet is treated as a full-color original sheet, for which it is necessary to specify the area or the point with respect to all the functions and for which a plural number of functions can be set for each original sheet. And, in the black and mono-color mode, the areas other than the specified one are reproduced in the form of a mono-color copy while the image in black in the specified area is converted into the palette color on the CRT. In the black-and-red mode, moreover, the areas other than the specified one are rendered in a black-and-red copy while the image in the specified area is converted into a red color. And, in addition to the trimming, masking, color mesh, and black-to-color functions available for marker editing, the functions of logotype, line, paint 1, collection, and function clear are provided. 
     The logotype function is the function which makes it possible to insert a logogram or logograms, such as a symbol mark, at a point or points specified therefor, and this function makes it possible to place two types of logorams, one in a vertical position and the other in a lateral position. However, only one such logogram can be set up for each original sheet, and the logogram patterns are prepared for the individual customers and supplied in a ROM. 
     The line function offers the function of drawing a vertical line or a horizontal line in relationship to the axis X by marking two points for such a line, and the color of such a line can be selected for each such line out of the eight standard colors and the eight registered colors, the number of specifiable lines being unlimited and the number of the usable colors is seven colors in the maximum at any given time. 
     The paint 1 function performs the function of painting the overall area within a closed loop in any color selected for each such loop out of the eight standard colors or the eight registered colors, one point within a closed loop being specified therefor. The mesh function permits the selection of any mesh out of the four patterns for each area, the number of the specifiable loops being unlimited and the number of the usable color mesh patters being seven patterns in the maximum. 
     The correcting function possesses the area/point change mode, by which the function set for each area can be ascertained and modified, the area/point correction mode, by which the area size and the position of the point can be changed by 1 mm, and the area/point canceling mode, by which the specified area can be ascertained, modified, changed, or erased. 
     The creative editing function contains the functions of image composition, copy-on-copy, color composition, partial image shifting, multiple-page enlargement, paint 1, color mesh, color conversion, negative/positive reversal, repeat, paint 2, density control, color balance, copy contrast, copy sharpness, color mode, trimming, masking, mirror image, margin, line, shift, logotype, split scanning, correction, function clear, and add function. In this function, the original sheets are treated as color original sheets, and the system permits the setting of a plural number of functions for each original sheet, the setting of functions in combination for each area, and the areas to be specified are a rectangular area with two points specified therefor and a point with one point specified therefor. 
     The image composition function consists in the function for copying the base original in color in four cycles, and then, holding the paper on the transfer device, continuing to copy again the trimmed original sheet in four cycles, and thereafter outputting the copy. 
     The copy-on-copy function consists in the function for copying the first original in four cycles, and then, holding the paper on the transfer device, continuing again to copy the second original sheet in four cycles, and thereafter outputting the copy. 
     The color composition function consists in the function for copying the first original sheet in magenta, and, holding the paper on the transfer device, continuing to copy again the second original sheet in cyan, and then, holding the paper on the transfer device, continuing further to copy the third original sheet in yellow, and thereafter outputting the copy. In the case of the four-color composition, the copying process is performed again further to add black onto the copy, and then the copy is output from the system. 
     The partial image shift function consists in performing the copying process in color in four cycles and then, holding the paper on the transfer device, continuing to copying again in four cycles, and thereafter outputting the copy. 
     In the full-color mode as a part of the color mode, the copying process is performed in four cycles. In the three-color mode, the copying process is performed in three cycles unless the editing mode is turned on. In the black mode, the copying process is performed in one cycle except for the case where the editing mode is turned on. In the plus-one-color mode, the copying process is performed in one to three cycles. 
     In the tool pathway function, the system provides the auditron, machine set-up, default selection, color registration, film-type registration, color collection, presetting, film projector scanning area correction, audio-tone, timer setting, billing meter, diagnostic mode, the maximum adjustment, and memory card formatting functions. For the setting and changing operations by this pathway function, it is required to input the appropriate cipher code. Otherwise, the system does not accept any attempt at putting this function into action. Therefore, it is the key operator and the customer engineer that can perform any setting operation or changing operation by the tool pathway. However, it is only the customer engineer that can enter into the diagnostic mode. 
     The color registration function is to be used for the registration of colors on the register color buttons on the color palette, and such registration is read by the CCD line sensor into the system from the color original sheet. 
     The color collection function is employed for making fine adjustments of the colors registered on the register color buttons. 
     The film-type registration function is used for the registration of the registered film type which is to be used in the film projector mode, and, in case such a film type has not yet been registered, the system will be in the state in which it is not possible to select any register button on the screen in the film projector mode. 
     The presetting function performs the presetting of the reduction/enlargement values, the copy density in seven steps, the copy sharpness in seven steps, and the copying contrast in seven steps. 
     The film projector scanning area correction function is used for making adjustments of the scanning area at the time the operation is performed in the film projector mode. 
     The audio-tone function is put into action for making adjustments of the volume of the sounds used in the selecting operation. 
     The timer-setting function is used for performing the setting of the time which can be released to the key operator. 
     In addition to these functions, the system also provides such functions for dealing with abnormal conditions in the system as the crash recovery function, which initiates a restart in case the sub-system falls into the state of a crash, the function for initiating the fault mode in case the sub-system cannot be restored to its normal state even though the crash recovery operation is performed two times, and the function of making an emergency stop in the event of the occurrence of a jam. 
     Furthermore, it is possible also to use in combination the basic copying functions and the additional functions, the basic functions/the additional functions and the marker editing functions, the business editing functions, the creative editing functions. 
     The system embodying this Invention and possessing the functions mentioned hereinabove, as a whole, has the characteristic features mentioned in the following: 
     (B) Characteristic features 
     (a) Achievement of high-quality full-color copying 
     For this equipment, efforts have been made to achieve high-quality full-color copying capable of performing vivid and clear reproductions of color documents through improvements made of the reproduction of image quality in black, the reproducing capabilities for pale colors and shades, the quality of generation copies, the quality of OHP images, the reproducing capabilities for fine lines, the reproducing capabilities for film copies, and the maintenance durability of the copies. 
     (b) Achievement of low costs 
     Efforts have been made to achieve reductions of the prime costs of the picture components and materials such as the photosensitive material, the developing device, and the toner and the costs of the expendable goods, as well as reductions of the service costs including the costs for the UMR, the component parts, and so forth, and efforts have been made further to make the copying machine compatible with black-and-white copying operations with the additional advantage of the black-and-white copying speed of 30 sheets of A4-size paper, which corresponds to approximately three times as much as that of the comparable existing model, so that a reduction of the overall running cost and the unit cost for copies may be achieved thereby. 
     (c) Improvement on productivity 
     It has been aimed to realize a high degree of productivity in this copying machine by installing the ADF and the sorter (optional items), in order to make it possible to process a multiple number of original sheets, by incorporating the magnification range from 50 percent to 400 percent available for selection, by providing for the maximum original sheet size of A3, with the paper trays ranging from B5 to B4 being accommodated at the upper stage, the paper trays ranging from B5 to B4 also being accommodated at the middle stage, the paper trays ranging from B5 A3 being accommodated at the lower stage, and the SSI device accepting the paper sizes ranging from B5 to A3, by ensuring the full-color copying speeds of 4.8 CPM for A4 paper, 4.8 CPM for B4, and 2.4 CPM for A3, and the black-and-white copying speeds of 19.2 CPM for A4, 19.2 CPM for B4, and 9.6 CPM for A3, with the warm-up time within eight minutes and the FCOT of 28 seconds or less for the four-color full-color copying process and 7 seconds or less for the black-and-white copying process and with the continuous copying speeds of 7.5 sheets for A4 in full-color copying and 30 sheets for A4 in black-and-white copying. 
     (d) Improvements on operating ease and facility 
     This copying machine features enhanced operating facility with operations integrated in one place as much as possible, with the hardware buttons on the hardware control panel and the soft buttons on the soft panel on the CRT screen available for use side by side, so that the selection of the functions can be made directly in a manner easy for the beginners to understand and yet not troublesome to the highly skilled operators, and, at the same time, this machine has been designed to be capable of communicating the necessary information to the operator accurately through its effective utilization of colors. This copying machine has been so designed that its high-fidelity copying process is put into action only by operations at the hardware control panel and the primary screen (i.e. the opening menu screen) while the processes which cannot be regulated by the operational flow, such as start, stop, all clear, and insertion, are performed by the operations at the soft panel on the primary screen, but such operations as the selection of paper, size reduction and enlargement, copy density, picture-quality adjustment, color mode, and color balance adjustment are put into action by operations on the soft panel on the primary screen, making it possible for the users of the conventional monochromatic copying machines to use this machine well enough in a manner natural to them. Furthermore, this machine is designed to allow the users to open the proper pathway and to select the various types of its functions, such as the editing functions, merely by touching operations at the pathway tabs in the pathway region on the soft panel. Furthermore, this machine permits the automatic execution of the predetermined operations, with the copying modes, the conditions for their execution, and so forth being stored in advance in the memory card. 
     (e) Repletion of functions 
     With touching operations on the pathway tab for the pathway region on the soft panel, it is possible to open the pathway and to select the various types of editing functions. In the marker editing function, for example, it is possible to perform the editing and processing of documents in black and white, using the tool called the marker, and, in the business editing function, high-quality original documents can be produced quickly mainly for use as business documents. Moreover, in the creative editing function, various types of editing functions with many choices are made available in such a manner that this copying machine will be able to satisfy the needs of various specialists, such as designers, copying service agents, and key operators. In addition, the area specified by the editing functions is put on display in the form of a bit map area, so that the specified area can be ascertained thereby. Thus, such abundant editing functions and color creation capabilities of this system make it possible to achieve very considerable enhancements of the power of expression in writings. 
     (f) Achievement of power-saving features 
     This Invention has achieved the materialization of a highly efficient four-color full-color copying machine with the power consumption of 1.5 kVA. For this purpose, a decision has been made on a control system in such a way as to realize the power consumption of 1.5 kVA in each of the operating modes, and the distribution of electric power to the individual functions has been decided so as to set the target values. Furthermore, an energy system table has been compiled in order to ascertain the channels for energy transmission, and the system is so designed for its control and verification by the energy systems. 
     (C) Examples of differentiation 
     The copying machine to which this Invention is applied can make its differentiation in respect of the use of copying machines in that this copying machine can be used for both full-color copying work and black-and-white copying work and additionally that they are so readily understandable to the beginners and yet not troublesome to the highly skilled operators in taking copies, and, at the same time, the copying machine permits not only mere copying work but the production of original documents as well, so that the machine will prove adequate for its utilization by specialists and artists. Examples of its uses are presented in the following. 
     For example, this copying machine can produce posters, calendars, cards, invitation cards, new year greeting cards with photographs, or the like, which have hitherto been produced by printing, at a cost much less expensive than the cost of production by printing so long as the number of copies required is not so large. Moreover, with the effective utilization of its editing functions, it will be possible to produce original works suiting the preferred design, for example, in calendars or the like, which means that this copying machine will enable the individual departments to produce their own original and highly variegated calendars although it has been a regular practice in the past years to have a uniform calendar printed for the whole company. 
     Furthermore, as observed in the instances of interior goods and electric appliances in the recent years, color is a determinant of sales quantities, and, by copying colored designs even at the stage of the production of interior goods and dresses, it will be possible for two or more persons to evaluate the coloration together with the design of such products. Thus, it will be possible to develop new works featuring colors in such a way as to achieve an increase in the consumption of such goods. Above all, the apparel industry or the like will be able to specify the colors with a degree of accuracy higher than what has been the case in the past by sending copies of charts or illustrations showing the finish of the products as rendered in color when orders for products are to be placed with dress-making workshops located in distant places, thereby achieving an improvement on their operating efficiency. 
     Furthermore, since this equipment offers the benefit of a combination of color copying and black-and-white copying, it will enable the user to copy one original sheet in black and white and/or in color respectively in the necessary numbers of sheets as required. Accordingly, for studying chromatology in technical schools and colleges, for example, this copying machine will provide the advantage of expressing a colored design as rendered both in black and white copy and in color copy, so that each of these can be compared with the other to find at a glimpse the clear fact that red is nearly identical to gray in terms of brightness, i.e. the value of color, and thus it will be possible to learn the influence which brightness and coloration give to the visual sensation. 
     (I-3) Construction of electrical control systems 
     This Section presents a description with respect to the hardware architecture, the software architecture, and the division of states. 
     (A) Hardware architecture and software architecture 
     In case a color CRT is used as a user interface (UI) as is the case with the present system, the amount of data will be increased because of the color displaying features as compared with the case where a monochromatic display is used, and also there will be an increase in the amount of data if it is attempted to construct a friendlier UI by incorporating therein contrivances regarding the composition of the display screen and the transition of the screens. 
     In dealing with such an increase in the amount of data, it will be possible to employ a CPU mounted with a memory device with a larger capacity, and yet such a step would result in using a larger board, which will present such problems as the difficulty in accommodating it in the main unit of the copying machine, the difficulty in taking flexible measures for dealing with the changes in the specifications, and a resulting increase in the costs. 
     Therefore, it has been designed, with respect to this copying machine, to deal adequately with such an increase in the amount of the data by setting up separate CPU&#39;s as remote units, embodying therein those techniques which can be used in common with other models or machines, such as the CRT controller. 
     The electrical system hardware is divided into the three types of systems, the UI system, the SYS system, and the MCB system, as illustrated in FIG. 3. The UI system includes the UI remote unit 70 while the SYS system contains in separate units the F/P remote unit 72, which performs the control of the F/P, the IIT remote unit 73, which performs the reading of the original sheets, and the IPS remote unit 74, which performs the various forms of the processing of the images. 
     The IIT remote unit 73 is provided with the IIT controller 73a, which performs control over the imaging unit, and the VIDEO circuit 73b, which converts the image signals read into digital signals and transmits them to the IPS remote unit 74, and this IIT remote unit 73, as well as the IPS remote unit 74, is controlled by means of the VCPU 74a. The SYS (System) remote unit 71 is provided to function as a system which performs the overall and coordinating control of the above-mentioned remote units and those individual remote units to be mentioned later. 
     Now that the SYS remote unit 71 is in need of an enormous memory capacity for the execution of such programs as the one for controlling the transition of the screens for the UI, 8086, which is mounted with a 16-bit microcomputer, and yet also a microprocessor than 8086, such as 68000, for example, can be employed. 
     Moreover, the MCB system is provided with the VCB (Video Control Board) remote unit 76, which is a Raster Output Scan (ROS) interface for receiving the video signals from the IPS remote unit 74 for use of the said signals in the formation of latent images by laser on the photosensitive material belt (Photo Receptor Belt) and for sending forth the said signals to the IOT, with the RCB remote unit 77 for the servo operation of the image transfer device (turtle), and further with the IOB remote unit 78 for operation as the I/O port for the IOT, ADF, the sorter, and the accessories, and with the accessory remote unit 79, all of these forming separate units and being coordinated and controlled by the MCB (Master Control Board) remote unit 75, which is provided for the purpose of coordinating all these remote units for their overall control. 
     Furthermore, each of the individual remote units shown in the Figure is composed of a single board. In this Figure, moreover, the bold solid line represents the LNET high-speed communication network at 187.5 kbps, and the bold broken line indicates the master/slave system serial communication network at 9,600 bps, while the slender solid line indicates the hot line, which is the transmission channel for the control signals. Also, the line marked 76.8 kbps in the Figure is the exclusive-purpose transmission line for use in the issuing of notices of the information on the images drawn on the editing pad, the information on the copying modes as input from the memory card, and the graphic information in the editing area from the UI remote unit 70 to the IPS remote unit 74. Furthermore, what is marked CCC (Communication Control Chip) in the Figure is the integrated circuit (IC) which supports the protocol for the high-speed communication line LNET. 
     As described in the foregoing part, the architecture of the hardware is divided into the three major systems, which are the UI system, the SYS system, and the MCB system, and the assignment of these processing functions are described in the following part with reference to the software architecture presented in FIG. 4. In this regard, the arrow marks in the Figure represent the relationship of the signals in the transmission and reception of the data by the LNET high-speed communication network at 187.5 kbps and the master/slave system serial communication network at 9,600 bps or in the transmission of the control signals as performed via the hot line, as shown in FIG. 3. 
     The UI remote unit 70 is composed of the LL UI (Low Level UI) module 80 and the module (not shown in the Figure) which performs the processing operations with respect to the editing pad and the memory card. The LL UI module 80 is the same as what is ordinarily known as the CRT controller, and thus it is a module for displaying the screen on the color CRT, and hence it is controlled by the SYS UI module 81 or the MCB UI module 86 what picture image screen is to be put on display from time to time. It should be evident from this that this architecture makes it possible to develop the UI remote unit for common use with other models or other equipments. The reason is that the CRT controller is to be used together with the CRT although it differs from one model to another what a screen composition should be used and how the transitions of the screens should take place. 
     The SYS remote unit 71 is composed of the three modules, the SYS UI module 81, the SYSTEM module 82, and the SYS. DIAG module 83. 
     The SYS UI module 81 is a software module which controls the transition of the screens, and the SYSTEM module 82 is a module which contains the software for making the selection of the F/F (Feature Function), by which it is recognized what coordinates on the soft panel have been selected on a given screen, i.e. what job has been selected, the job validation software, by which the job is finally checked to determine whether or not the conditions for the execution of the copying job contain any contradiction, and the software for controlling the communications with the other modules for the transmission and reception of such various types of information on the selection of the F/F, the job recovery, and the machine state. 
     The SYS. DIAG module 83 is the module which operates in the customer simulation mode, in which the machine performs its copying operation in the diagnostic state for conducting a self-diagnosis. As the customer simulation mode is put into action for the same operations as in the ordinary copying process, and the SYS. DIAG module 83 is thus the same in substance as the SYSTEM module 82, but, since it is used in the diagnostic state, which is a special state, the module is described separately from, but in partial overlapping with, the SYSTEM module 82. 
     Moreover, the IIT remote unit 73 accommodates the IIT module 84, which performs the control of the stepping motor used for the imaging unit, and the IPS remote unit 74 accommodates the IPS module 85, which performs the various processing operations concerning the IPS, and these modules are controlled by the SYSTEM module 82. 
     In the meanwhile, the MCB remote unit 75 accommodates the individual software modules, i.e. the MCB UI module 86, which is a software for controlling the transition of screens in the diagnostic mode, in the Auditron mode, and in case of any fault, such as jamming, the IOT module 90, which performs such processing operations necessary for the performance of the copying operations as the control of the photosensitive material belt, the control of the developing agent, and the control of the fuser, the ADF module 91, which performs the control of the ADF, and the SORTER module 92, which performs the control of the sorter, as well as the copier executive module 87, which performs control over these software modules, and the DIAG. executive module 88, which performs the various kinds of diagnoses, and the Auditron module 89, which performs the processing of the copying charges through its access made to the electronic counter by the cipher numbers. 
     Moreover, the RCB remote unit 77 accommodates therein the turtle servo module 93, which performs the control of the action of the image transfer device, and the said turtle servo module 93 is placed under the control of the IOT module 909 in order to take charge of the image transferring process of the zerography cycle. In this regard, the reason why the copier executive module 87 and the DIAG. executive module 83 are overlapping with each other is the same as the reason for the overlapping of the SYSTEM module 82 and the SYS. DIAG module 83. 
     The assignments of the processing operations mentioned above are now described below with reference to the copying operations. The copying operations show repetitions of quite similar motions except for the differences in the colors developed, and, as illustrated in FIG. 5 (a), the said operations can be viewed in terms of several separate layers. 
     One sheet of color copy is produced by repeating several times the minimum unit of operation called &#34;pitch&#34;. In specific terms, the pitch relates to such actions as how the developing device, the transfer device, and so forth should be operated for the performance of the copying operation for a single color, how the detection of jamming should be performed, and, if the pitch operation is performed with respect to each of the three colors, Y, M, and C, one sheet of copy in three colors is finished, and, if the said operation is performed for each of the four colors, Y, M, C, and K, one sheet of full-color copy in the four colors is finished. These are the copying layers, and, in terms of concrete operations, these layers represent the processes performed for transferring the toner for each color onto the paper, thereafter fixing the toner with the fuser, and then discharging the copy from the main unit of the copying machine. The control over the processes up to this point is performed by the copier executive module 87 in the MCB system. 
     Of course, the IIT module 84 and the IPS module 85, which are included in the SYS system, are also put into action in the process of a pitch, and, for the purpose of such operations, the exchanges of the two signals called PR-TRUE and LE@REG respectively are performed between the IOT module 90 and the IIT module 84 as shown in FIG. 3 and in FIG. 4. Specifically, the PR (PITCH RESET) signal, which sets the standard timing for the control of the IOT, is generated consecutively from the MCB for two or three divided parts of one turn of the photosensitive material belt. That is to say, since the photosensitive material belt is so designed as to be divided for the pitch, depending on the size of the copy paper used, in such a manner as two pitches for the A3-size copy paper and three pitches for the A4-size paper, for example, in order to achieve the highly efficient utilization of the photosensitive material belt and to achieve an improvement on the copying speed, the cycle of the PR signal generated for each pitch will get longer, i.e. three seconds for the copying operations in two pitches, while the cycle of the said signal becomes shorter, i.e. two seconds for the copying operations in three pitches. 
     Now, the PR signal which is thus generated by the MCB will be distributed by way of the hot line to those necessary locations in the IOT, such as the VCB remote unit, which performs the processing operations related to the VIDEO signals. 
     The VCB has a gate circuit in it, and it selectively outputs to the IPS remote unit only those pitches in which the images can be given exposure to light for their registration on the photosensitive material belt. This signal is the PR-TRUE signal. In this regard, the information by which this PR-TRUE signal is generated on the basis of the PR signal received from the MCB via the hot line is transmitted from the MCB by the LNET system. 
     In contrast to this, a vacant pitch for one pitch is produced on the photosensitive material belt in the duration of time when images cannot be given any exposure for their registration on the photosensitive material belt, and the PR-TRUE signal will not be generated for any such vacant pitch. As the pitches in which the PR-TRUE signal is not generated, it is possible to cite for example, the duration of time from the time when the machine discharges the paper upon completion of the transfer of images at the transfer device to the time when the next sheet of paper is fed into the transfer device. That is to say, when a lengthy sheet of paper, such as an A3-size sheet, for example, is discharged, the paper gives a shock, as its force edge enters the inlet into the transfer device, to cause some deterioration in the quality of the copied images. Thus, for the paper in excess of a certain length, the system is designed not to discharge the paper as it is even when the final transfer is completed, but to discharge it only after it is transported one more round at a certain speed while it is held in the gripper to be described later. Therefore, it becomes necessary to provide the photosensitive material belt with a skip for one pitch. 
     Moreover, the PR-TRUE signal is not output in the duration from the start of the copying operation with the start key turned on to the time when the cycle up to the completion of the sequence is brought to a finish, since the reading of the original sheet is not yet completed and it is consequently not possible to give exposure to the image for registration thereof on the photosensitive material belt. 
     The PR-TRUE signal output from the VCB remote unit is received by the IPS remote unit and, at the same time, it is also transmitted as it is to the IIT remote unit, being used as the trigger signal for the start of the scanning operation in the IIT. 
     By this, it is possible to perform the pitch process, keeping the IIT remote unit 73 and the IPS remote unit 74 in synchronization with the IOT. Also, at this stage, the IPS remote unit 74 and the VCB remote unit 76 perform the transmission and reception of the video signals for performing the modulation of the laser light to be used for the formation of latent images on the photosensitive material belt, and such signals received by the VCB remote unit 76 are furnished to the laser output section 40a, after they are converted from the parallel signals into serial signals, for use as the VIDEO modulation signals to be fed directly to the ROS. 
     When the operations described above have been repeated four times, one sheet of full-color copy in four colors is finished, and one copying cycle is thereupon completed. 
     Next, with reference to the FIGS. 5(b) through 5(e), exchanges of signals and the timing thereof are described for the processes leading to the output of the image signals read by the IIT to the IOT and then to the transfer of images onto the paper finally at the transfer point. 
     As shown in FIGS. 5(b) and 5(c), when the start job command is received from the SYS remote unit 71, the IOT 78b enter into the cycle start sequence, with such operating processes as the driving of the main motor and the start-up of the high-voltage power source. The IOT 78b outputs the PR (Pitch Reset) signal in order to cause a latent image corresponding to the length of the paper to be formed on the photosensitive material belt. For example, each time the photosensitive material belt turns one round, the IOT 78b outputs a PR signal for three pitches for the A4-size paper and such a signal for two pitches for the A3-size paper. When the cycle start sequence of the IOT 78b is brought to a finish, then a PR-TRUE signal is output, in synchronization with the PR signal as from that point in time, to the IIT controller 73a only in correspondence with the pitches which require imaging. 
     Moreover, the IOT 78b transmits the IOT-LS (line sink) signal, which is output for each revolution for one line of the ROS (Rastor Output Scan) to the TG (Timing Generator) in the VCPU 74a and here transmits to the IIT controller 73a the IPS-LS with an apparent advance of the phase by the amount of lag in the total pipeline in the IPS as compared to the IOT-LS. 
     Upon the reception of the PR-TRUE signal, the IIT controller 73a enables the counter and counts the IOT-LS signal and starts the revolutions of the stepping motor 213, which drives the imaging unit 37, when the signal attains the prescribed number of counts, so that the imaging unit may begin its scanning of the original sheet. Then, the said controller continues to perform the counting process and, after the elapse of T2 seconds, it generates the LE@REG in the position where the reading of the original sheet is started and transmits the same to the IOT 78b. 
     This position for starting the reading of the original sheet can be determined by driving the imaging unit for one time in advance, for example, after the power is turned on, thereby detecting the position of the register 217 (in the proximity of the register, which specifically is to be found at a point located approximately 10 mm closer towards the scanning side from the position of the register) and thereafter finding the real position of the register by arithmetic operations based on the detected position, and also it is possible to determine the ordinary stopping position (i.e. the home position) by arithmetic operations. Moreover, since the position of the register is different from one machine to another because of the individual differences or deviations among the units, it is possible to set the correct and accurate position for the start of the reading of the original sheet through correction at the time of the calculation of the real position of the register and the home position with the correcting value stored in the NVM. This corrected value can be modified for each factory, each serviceman, and such a correction can be put into practice merely by rewriting this correcting value electrically, and thus it is not necessary to make any mechanical adjustment of the said value. In this regard, the reason why the position of the register 217 is set up with a deviation by approximately 10 mm towards the scanning side from the real position of the register is that such an arrangement renders the correction always in a negative value, offering greater simplicity in the adjustment and the software. 
     Moreover, the IIT controller 73a outputs the IMAGE-AREA signal in synchronization with the LE@REG. The length of this IMAGE-AREA signal is equal to the scanning length, which is defined by the start command transmitted from the SYSTEM module 82 to the IIT module 84. In specific terms, the scanning length corresponds to the length of the original sheet when the copying work is performed through detection of the original sheet size and the said length is set by the divisor for the copy paper length and the magnification (with 100% in magnification taken as 1) in case the copying work is to be performed with a magnification being specified therefor. The IMAGE-AREA signal is channeled via the VCPU 74a, where the said signal has its name changed to the IIT-PS (Page Sink) and is transmitted to the IPS 74. The IIT-PS is a signal indicating the time for the execution of the processing of the image. 
     When the LE@REG is output, the data for one line of the licensor is read in synchronization with the IOT-LS signal, and various types of correcting processes and the A/D conversion are performed in the VIDEO circuit (FIG. 3), and the signal so processed is transmitted to the IPS 74, which transmits to the IOT 78b the video data for one line in synchronization with the IOT-LS. At this time, the RTN-BYTE-CLK, which is a reversal signal of the IOT-BYTE-CLK, is transmitted back to the IOT, in parallel with the video data, thereby effecting a delay in the data in the same way as in the clock, so that synchronization can be achieved with certainty. 
     When the LE@REG is input into the IOT 78b, the video data are transmitted to the ROS in synchronization with the IOT-LS signal in the same manner, and a latent image is formed on the photosensitive material belt. Upon reception of the LE@REG input into it, the IOT 78b starts the counting process with the IOT-CLK, taking the LE@REG as the basis, and on the other hand the servo-motor for the image transfer device is controlled in such a way that the fore edge of the paper is positioned at the image transfer position at the prescribed number of counts. In this regard, the PR-TRUE signal output by the rotation of the photosensitive material belt and the IOT-LS signal output by the rotation of the ROS are originally not in any synchronization with each other. Therefore, the LE@REG will have a lag by the T1 time in relation to the PR-TRUE signal when the LE@REG is output at the count n when the counting process is started from the subsequent IOT-LS with the input of the PR-TRUE signal, putting the imaging unit into operation at the count m. This lag corresponds to an amount for one line sink in the maximum, and, in the case of full-color copying in the four colors, such lags accumulate with the result that such lags express themselves in the form of color deviations in the output image. 
     In dealing with this, the counter 1 starts the counting process when the initial LE@REG is input, and the counter 2 and the counter 3 start the counting process when the second LE@REG and the third LE@REG are input, and, as shown in FIG. 5(c), when the respective counters attain the number of counts p, which marks the position for image transfer, they clear these, so that the counters are employed in the stated order in response to the input of the LE@REG at the fourth time and the subsequent times. And, as shown in FIG. 5 (e), the time T3 from the pulse immediately preceding the IOT-CLK is counted with the correcting clock. When the latent image formed on the photosensitive material belt approaches the image transfer position and when the IOT-CLK has counted the number of counts p, which marks the counts up to the position of image transfer, then the correcting clock thereupon starts the counting process, and the point equivalent to the counts obtained by the addition of the number of counts r, which corresponds to the time T3 mentioned above, will be the exact position for the image transfer. This is put on the control for the counter for controlling the image transfer position (timing) for the image transfer device, so that the servo-motor for the image transfer device is accurately controlled so as to achieve the exact synchronization of the fore edge of the paper in relation to the input of the LE@REG. 
     The operations mentioned so far correspond to the processes leading to the completion of the copy layers, in addition to which there is a process for setting the number of sheets to be copied for each original sheet, i.e. the setting of the number of times of the job to be performed by the copy as the unit for each original sheet, and this is the process to be performed in the Per Original layer. Further, on top of this is the job programming layer, in which the process for making a change in the parameter for the job. Specifically, this process relates to the point whether or not the ADF is to be used, whether or not the color of a part of the original sheet is to be changed, and whether or not the differential magnification function is to be used. These processes, i.e. the per original process and the job programming process, are controlled by the SYS module 82 of the SYS system. For this purpose, the SYSTEM module 82 checks and finally establishes the contents of a job as transmitted from the LL UI module 80, and, preparing the necessary data, gives a notice of the data to the IIT module 84 and the IPS module 85 by the serial communication network at 9,600 bps and also notifies the contents of the job to the MCB system via the LNET. 
     As mentioned above, those sets of functions which perform independent processes and those which perform the processes that can be planned for common use with other models or other equipments are set up and grouped together to form separate sets of functions assigned to different remote units, and then those separate sets of functions are divided among the major categories of the UI system, the SYS system, and the MCB system, and then the modules which perform control over the copying operations in accordance with the layers of the processes. This approach has made it possible to achieve such meritorious effects as establishing a clearly defined framework for the work of the designing staff, attaining uniformity in the techniques for the development of software and so forth, setting the delivery date and the cost clearly and definitely, and dealing properly with changes or the like in the specifications, if any, by making modifications of the related modules only, thereby making it possible to improve the efficiency in the development work. 
     (B) Division of states 
     In the foregoing part, the assignment of the processes to the UI system, the SYS system, and the MCB system have been described, and, in this section, the processes which are performed by the UI system, the SYS system, and the MCB system, respectively, at a given time at each of the copying operations are described with reference to the sequence in which the copying operations are performed. 
     For the copying machine, the power-ON operation and the subsequent copying operations, as well as the conditions after the completion of the copying operations, are divided respectively into several states, and the jobs performed in each of the states are determined, and, with the system designed not to move on to the next state unless it has completed all the jobs to be performed in each state, it is endeavored to warrant the expectation of the attainment of efficiency and accuracy in the controlling operations. This is called the state division, and, for this copying machine, the state division has been made as shown in FIG. 6. 
     What is characteristic of the state division for this copying machine is that, in each state, the controlling authority for performing control over the entirety of a given state and the UI mastering authority for using the UI in the particular state rests with the SYS remote unit 71 at some time but rests with the MCB remote unit 75 at other times. In other words, the division of the operating functions between the separate CPU&#39;s as mentioned above produces the effect that the LL UI module 80 in the UI remote unit 70 can be controlled not only by the SYS UI module 81 but also by the MCB UI module 86, and, since the processes are thus assigned to the separate modules, so that the per original process and the job programming process are controlled by the SYS module 82 while the pitch process and the copying process are controlled by the copier executive module 87 in the MCB system, this setup results in the corresponding difference in the point which one of the two modules, i.e. the SYSTEM module 82 and the copier executive module 87, holds the overall controlling authority for the controlling operations or holds the UI mastering authority in each state. In FIG. 6, it is shown that the copier executive module 87 in the MCB system has the UI mastering authority over the state represented by the vertical lines while the SYSTEM module 82 has the UI mastering authority over the state represented in solid black. 
     Of the state divisions shown in FIG. 6, those from the power-ON operation to the standby state are explained below with reference to FIG. 7. 
     When the power source is turned on to set the system in the power-ON state, the IPS reset signal and the IIT reset signal to be fed from the SYS remote unit 71 to the IIT remote unit 73 and the IPS remote unit 74, as shown in FIG. 3, become H (HIGH), and thereupon the IPS remote unit 74 and the IIT remote unit 73 are released from resetting and start their respective operations. Moreover, when the system detects that the voltage in the power source has attained its normal level, then the power-normal signal builds up, and the MCB remote unit 75 starts its operation, thereby establishing the controlling authority and the UI mastering authority and also conducting a test on the high-speed communication network LNET. Also, the power-normal signal is transmitted from the MCB remote unit 75 to the SYS remote 71 by way of the hot line. 
     After the passage of the prescribed length of time T0 after the MCB remote unit 75 starts its operation, the system reset signal which is fed from the MCB remote unit 75 to the SYS remote unit 71 via the hot line becomes H, with which the resetting of the SYS remote unit 71 is released and the unit starts its operation, at which time the start of the operation by the SYS remote unit 71 is delayed further by 200 μsec after the elapse of the above-mentioned time T0 by the effect of the two signals, 86 NMI and 86 reset, which are signals in the inside of the SYS remote unit 71. This duration of time, 200 μsec, is provided in order to store in the non-volatile memory the data on the state in which the system is operating at the moment when the machine is brought to a halt or runs out of control because of a transient trouble, such as a crash, a momentary failure of the power source, the running of the software out of control, or a bug in the software. 
     When the SYS remote unit 71 starts its operation, it conducts a core test for a duration of approximately 3.8 seconds, i.e. checks on the ROM and the RAM, and checks on the hardware and so forth. As any entry of undesired data or the like at this time may cause the system to run out of control, the SYS remote unit 71 sets the IPS reset signal and the IIT reset signal at L (Low) under its own supervisory control at the same time as the start of the core test, thereby resetting the IPS remote unit 74 and the IIT remote unit 73 to suspend them from their operation. When the core test is completed, the SYS remote unit 71 conducts a CCC self-test for a duration ranging from 10 to 3,100 m seconds, also setting the IPS reset signal and the IIT reset signal at H and making the IPS remote unit 74 and the IIT remote unit 73 resume their operation and perform their respective core tests. The remote unit conducts the CCC self-test by transmitting the prescribed data to the LNET and then receiving the data back to itself, and checking whether the data so received are identical to the data transmitted. Moreover, for the performance of the CCC self-test, a time is allocated to each CCC in such a way that there will not be any overlapping of the periods for the self-tests. 
     That is to say, the LNET is available by the contention system, by which the individual nodes in the SYS remote unit 71, the MCB remote unit 75, and so forth transmit signals when they desire to and, should there occur any collision of data, transmit the data again after the passage of the prescribed duration of time. Thus, if the SYS remote unit 71 conducts any CCC self-test while any other node is using the LNET, there occurs a collision of data, so that the self-test cannot be conducted. Therefore, when the SYS remote unit 71 begins any CCC self-test, the LNET test by the MCB remote unit 75 is already completed. 
     When the CCC self-test is completed, the SYS remote unit 71 waits until the IPS remote unit 74 and the IIT remote unit 73 complete their core tests, and then performs a communication test for the SYSTEM node in the duration T1. This communication test is a test on the serial communication network at 9,600 bps, and the transmission and reception of the prescribed data are performed in the prescribed sequence. When the said communication test is completed, a communication test is conducted between the SYS remote unit 71 and the MCB remote unit 75 in the duration T2. That is to say, the MCB remote unit 75 demands the SYS remote unit 71 to give it the results of the self test, and the SYS remote unit 71, responding to the said demand, issues the results of the tests which it has conducted so far as the Self-Test Results to the MCB remote unit 75. 
     Upon its reception of the self-test results, the MCB remote unit 75 issues a token pass to the SYS remote unit 71. The token pass is a &#34;tablet&#34; for transferring the UI mastering authority, and the delivery of the token pass to the SYS remote unit 71 effects the transfer of the UI mastering authority from the MCB remote unit 75 to the SYS remote unit 71. The steps up to this point constitute the power-on sequence. In the duration of the said power-on sequence, the UI remote unit 70 indicates a message, such as &#34;Please, wait a while!&#34; and conducts its own various types of tests, such as the core test and a communication test. 
     During the power-on sequence mentioned above, there may be a failure in responding to the demand for the self-test results or there may occur an abnormal condition in the self-test results, in which case the MCB remote unit 75 renders the machine dead and, putting the UI controlling authority in action, the said remote unit controls the UI remote unit 70 and puts on display a message to the effect that an abnormal condition has taken place. This is the machine dead state. 
     When the power-on state is completed, the system enters next into the initialize state in order to set up the individual remote units. In the initialize state, the SYS remote unit 71 holds the overall controlling authority and the UI mastering authority. Therefore, the SYS remote unit 71 initializes the SYS system and also issues the &#34;INITIALIZE SUBSYSTEM&#34; command to the MCB remote unit 75 to make also the MCB system initialized. The results come transmitted as the Subsystem Status Information from the MCB remote unit 75. With this, the IOT, for example, make preparations for the performance of the copying operations by heating the fuser and by placing the elevator for the tray in its prescribed position. The steps up to this point constitute the initialize state. 
     When the initialize state is completed, the individual remote units enter into their standby state, in which they are ready for operation. Even in this state, the SYS remote unit 71 still holds the UI mastering authority, and therefore the SYS remote unit 71 puts the F/F on the UI screen on the basis of the UI mastering authority, thereby entering into the state in which it is ready to accept the copy executing conditions. At this time, the MCB remote unit 75 is monitoring the IOT. Moreover, the MCB remote unit 75 issues the background pole once in every 500 m seconds to the SYS remote unit 71, in response to which the SYS remote unit 71 performs the process of returning the self-test results once in every 200 m seconds to the MCB remote unit 75. In case the self-test results are not returned or in case there is any abnormal condition in the contents of the self-test results at this stage, the MCB remote unit 75 gives the UI remote unit 70 a notice to the effect that an abnormal condition has taken place and causes the UI remote unit 70 to display a message to that effect. 
     When the Auditron is put into operation in the standy state, the system enters into the Auditron state, in which the MCB remote unit 75 performs the Auditron control operation and also controls the UI remote unit 70 to make the said unit display a message for the Auditron. When the start key is pushed, with the F/F set, in the standby state, the system enters into the progress state, which is divided further into the six states of setup, cycle up, run, skip pitch, normal cycle down, and cycle down shut down, and these states are explained below with reference to FIG. 8. 
     FIG. 8 presents the timing chart for the number of copies set at three for full-color copying in four colors in the platen mode. 
     When the SYS remote unit 71 detects that the start key has been pushed, the said remote unit 71 transmits the particulars of the job to the IIT remote unit 73 and the IPS remote unit 74 and also issues the particulars of the job, together with a command called &#34;the Start Job Command&#34; to the copier executive module 87 located in the MCB remote unit 75. This puts the machine into the setup state, and the individual remote units make preliminary preparations for their performance of the jobs assigned to them respectively. For example, the IOT module 90 performs such jobs as the driving of the main motor and a proper adjustment of the parameter for the photosensitive material belt (i.e. the photo receptor belt). When the SYS remote unit 71 ascertains that the ACK (Acknowledge), which is a response to the Start Job Command, has been sent back, the said remote unit 71 makes the IIT remote unit 73 perform the prescanning operations. There are four types of prescanning operations, namely, the prescanning operation for detecting the size of the original sheet, the prescanning operation for detecting the color in the specified position on the original sheet, the prescanning operation for detecting the closed loop in case an outline drawing is to be processed for coloring, and the prescanning operation for the reading of the marker in the marker editing process, and, depending on the selected F/F, the system performs the prescanning operations up to three times in the maximum. While the prescanning operation is being performed, the UI puts on display such a message as &#34;Please wait a moment!&#34;. When the prescanning operation is completed, the system issues the command, &#34;IIT Ready,&#34; to the copier executive module 87, and, at this point, the system enters into the &#34;cycle up&#34; state. This &#34;cycle up&#34; state is the one in which the system waits for the elapse of the building up time for the individual remote units, and the MCB remote unit 75 begins the operations of the IOT and the image transfer device, and the SYS remote unit 71 initializes the IPS remote unit 74. At this moment, the UI displays the message that the system is in the progress state, as well as the particulars of the selected job. 
     When the cycle up state is completed, the system enters into the run, commencing the copying operations, and, at this point, when the first piece of the PRO is issued from the IOT module 90 in the MCB remote unit 75, the IIT remote unit 73 performs the first scanning operation, and the IOT performs the development of the first color, and the processing of one pitch is completed thereupon. When the PRO is issued again at the next step, the system performs the development of the second color and completes the second pitch therewith. This operating process is repeated four times, and, when the processing operations for four pitches are completed, the IOT fixes the toner by means of the fuser, thereafter discharging the paper. With this, the system completes the copying operations for the first copy. With the repetition of the above-mentioned process three times, the machine produces three sheets of copies. 
     The processing of the pitch layer and the processing of the copy layer are controlled by the MCB remote unit 75, but the processing of the set number of sheets of copies, which is to be performed in the per original layer that represents a layer above those just mentioned, is performed by the SYS remote unit 71. Therefore, the system is so designed that, when the first PRO for each copy is issued, the MCB remote unit 75 issues a made count signal to the SYS remote unit 71 in order to enable the SYS remote unit 71 to recognize what page number of copy is being produced at the particular moment. Moreover, when the last PRO is issued, the MCB remote unit 75 issues the command, &#34;RDY FOR NXT JOB&#34; to the SYS remote unit 71 and demands the next job. At this point in time, the job can be continued if the Start Job command is issued, but, if the user does not set up the next job, the system will put an end to the job, when the SYS remote unit 71 issues the command, &#34;END JOB,&#34; TO the MCB remote unit 75. When the MCB remote unit 75 ascertains the completion of the job with the reception of the &#34;END JOB&#34; command, the machine enters into the normal cycle down state, in which the MCB remote unit 75 stops the operation of the IOT. 
     In the course of the cycle down state, the MCB remote unit 75 issues the &#34;DELIVERED JOB&#34; Command, when it is ascertained that all the copied sheets of paper have been discharged, to give a notice to that effect to the SYS remote unit 71, and also, when the machine comes to a stop upon the completion of the normal cycle down state, the MCB remote unit 75 gives a notice to that effect to the SYS remote unit 71 by issuing the &#34;IOT STANDBY&#34; Command. With this, the progress state is finished, and the standby state is resumed. 
     Furthermore, the example given above has not been described in relation to the skip pitch state or the cycle down shut down state, and yet, in the skip pitch state, the SYS remote unit 71 initializes the SYS system in preparation for the next job and the MCB remote unit 75 is in the standby state for the next copying operation. Moreover, since the cycle down shut down state is the state provided for the occurrence of faults, both the SYS remote unit 71 and the MCB remote unit 75 perform the processing of faults in this state. 
     In the progress state, as mentioned so far, the MCB remote unit 75 performs control over the pitch process and the copy process, and the SYS remote unit 71 controls the per original process and the job programming process. Therefore, the controlling authority for these processes is held by these remote units in accordance with the shares of the processes as assigned to them respectively. In contrast to this setup, the UI mastering authority rests with the SYS remote unit 71. The reason is that it is necessary for the UI to indicate such items as the number of sheets set for copying and the selected editing processes, which belong to the per original process or the job programming process, and, as such, are placed under the control by the SYS remote unit 71. 
     In the event that any fault occurs in the progress state, the system moves on to the fault recovery state. The term, &#34;fault,&#34; is a general designation of such abnormal conditions in the machine as the absence of paper, jamming, and any failure or breakage of any component part, and there are two types of faults, one type consisting of those faults from which recovery can be made by the users by taking such steps as the resetting of the F/F but the other type consisting of those faults from which recovery can be attained only by the serviceman by such measures as the replacement of some component parts. As mentioned above, the displaying of faults is performed basically by the MCB UI module 86, but, since the F/F is controlled by the SYS module 82, the recovery from any of those faults which are correctable by the resetting of the F/F is to be performed by the SYS mode 82 while the recovery from all the other faults is to be executed by the Copier Executive Module 87. 
     Moreover, the detection of faults is performed separately for the SYS system and the MCB system. In other words, the faults in the IIT, the IPS, and the F/P, which are controlled by the SYS remote unit 71, should be detected by the SYS remote unit 71 while the faults in the IOT, the ADF, and the sorter, which are controlled by the MCB remote unit 75, should be detected by the MCB remote unit 75. Accordingly, it can be understood that there are the following four types of faults in this copying machine. 
     (1) Faults detected by the SYS node and corrected for recovery therefrom by the SYS node 
     For example, a fault occurs when the start key is pushed without the preparation of the F/P therefor, but the user can make recovery therefrom by setting the F/F again. 
     (2) Faults detected by the SYS node and corrected for recovery therefrom by the MCB node 
     The faults of this type include, for example, a trouble in the registering sensor, an abnormal condition in the speed of the imaging unit, an overrun of the imaging unit, an abnormal condition in the PRO signal, an abnormal condition in the CCC, an abnormal condition in the serial communication network, and an error in checks on the ROM or the RAM, and, in the case of these faults, the UI will display such a message as &#34;Please call the Serviceman!&#34; as well as the particulars of the fault. 
     (3) Faults detected by the MCB node and corrected for recovery therefrom by the SYS node 
     In case the sorter is specified on the F/F in spite of the fact that the sorter is not installed on the machine, a fault is detected by the MCB node, but a recovery from it can be made by the user by setting the F/F once again to effect a change to the mode in which the sorter is not to be used. The same applies also to the ADF. Also, a fault will occur when the toner has become short, when the tray is not set, or when the paper is not available. These faults are to be corrected essentially by the user by replenishing the toner, or by setting the tray, or by replenishing the paper, as appropriate, but, when the fault is due to the tray running out of paper, another tray may be used to make recovery from the fault, and, in case the toner in a given color has run short, it is possible to make recovery from the fault by specifying another color. That is to say, such faults can be corrected for recovery from them also by selections made on the F/F. Thus, the system is so designed as to perform the recovering operation with the SYS node. 
     (4) Faults detected by the MCB node and correctable for recovery therefrom by the MCB node 
     For example, in case the developing device has a fault in operation, or the toner distribution is in an abnormal condition, or in case the motor clutch has a failure, or in case the fuser has a trouble, the MCB node detects any of these faults, and a message like &#34;Please call the Serviceman!,&#34; as well as the location where the fault is present, is indicated on the U/I. Also, in case any jamming has occurred, the system indicates the location of the jamming, as well as the method of clearing the jamming, thus entrusting the user with the recovering job. 
     As described so far, the controlling authority and the UI mastering authority is vested either in the SYS node or in the MCB node in the fault recovery state, depending on the location where a fault has occurred and the method of making recovery from it. 
     When the fault is corrected for recovery therefrom and the IOT standby command is issued from the MCB node, then the system moves on to the job recovery state and finishes the remaining job. For example, if it is assumed here that jamming has taken place while the machine is processing the second copy, with the number of copies set at three, the SYS node and the MCB node attain the recovery of the job by performing the processes which they respectively control since it is necessary for the machine to produce the remaining two copies after the jamming is cleared. Therefore, also in the recovery of the job, the controlling authority is held by both of the SYS node and the MCB node in accordance with their respective shares of the processes. However, the UI mastering authority is held by the SYS node. The reason is that it is necessary for making the job recovery to indicate such messages for the job recovery, for example, as &#34;Please push the start key!&#34; and &#34;Set the remaining original sheet!&#34; and that this function is an item regarding the per original process or the job programming process, which the SYS node controls. 
     Moreover, in case an IOT standby command is issued in the progress state, the system moves on to the standby state, waiting ready for the next job, when it is ascertained that the system has moved to the job recovery state and has completed the job. In the standby state, it is possible to enter the diagnostic state (which is hereinafter referred to simply as the DIAG) by performing the prescribed key operation. 
     The DIAG. state is the state for performing self-diagnosis, which is applied to such jobs as the checks on the input into the component parts, the checks on the output, the setting of the various kinds of parameters, the setting of the various kinds of modes, and the initialization of the NVM (Non-Volatile Memory), and the concept of this state is illustrated in FIG. 9. As it is clearly seen in the Figure, the DIAG. state is provided with two modes, i.e. the TECH REP mode and the Customer Simulation mode. 
     The TECH REP mode is the mode which the Serviceman uses in performing diagnosis on the machine with respect to the checks on the input and those on the output, and the Customer Simulation mode is the mode for use in the diagnosis the customer mode which the user ordinarily uses in performing the copying job. 
     Now, assume that entry has been made by the prescribed operating procedure into the TECH REP mode by the route A shown in the Figure from the standby route in the customer mode. The TECH REP mode can be finished after simply having done the setting of the various kinds of checks and the setting of the parameters in this mode, and, to return to the customer mode (by the route B in the Figure), it is possible to move into the power-on state as shown in FIG. 6, by performing the prescribed key operation, and then return to the standby state by following the sequence indicated in FIG. 7. However, since this copying machine performs color copying and that it is also provided with a variety of editing functions, it is necessary to ascertain through the actual copying performance, after the setting of the various parameters is completed in the TECH REP mode, whether or not the copying machine can really reproduce the colors as required by the users and whether or not the machine can perform editing functions as specified. It is the Customer Simulation mode that performs this task, and this mode is different from the customer mode in the point that this simulation mode does not execute any billing job and that this mode displays a message to the effect that the machine is being operated in the DIAG. state. 
     This is the meaning of the Customer Simulation mode, in which the customer mode is used in the DIAG. state. In this regard, the shift from the TECH REP mode to the Customer Simulation mode (by the route C in the Figure) and the shift in the opposite direction from the Customer Simulation mode to the TECH REP mode (by the route D shown in the Figure) can be made respectively by the prescribed operating procedure. Moreover, as the TECH REP mode is performed by the DIAG. executive module 88 (FIG. 4), the MCB node holds both of the overall controlling authority and the UI mastering authority, but, with regard to the Customer Simulation mode, the SYS node has both of the overall controlling authority and the UI mastering authority because the machine performs its ordinary copying operations in this mode under the control of the SYS DIAG. module 83 (FIG. 4). 
     (II) Specific Construction of Various Parts 
     (II-1) Systems 
     FIG. 10 is a chart illustrating the relationship between this system and the other remote units. 
     As mentioned earlier, the remote unit 71 is mounted with the SYS UI module 81 and the SYSTEM module 82, and, between the SYS UI module 81 and the SYSTEM module 82, data are exchanged via the intermodular interface, and a serial communication interface is provided to connect the SYSTEM module 82 and the IIT 73 and IPS 74 while the LNET high transmission rate communication network is provided to connect the MCB 75, the ROS 76, and the RAIB 79. 
     Next, a description is given with respect to the configuration of the modules in the system. 
     FIG. 11 is a chart illustrating the configuration of the modules for the system. 
     For this copying machine, the individual modules for IIT, IPS, IOT, and so forth are conceived as though they were component parts, and the individual modules for the systems which perform control over these are conceived as though they had brains. And, with the adoption of the separate CPU system, the system takes charge of the per-original processing operation and the job-programming process, and, since the system has the control rights to the control over the initialize state, the stand-by state, the setup state, and the cycle state and also the UI mastering rights to the use of the UI in these states in correspondence to this set-up, the system has been constructed with such modules as are proper for its performance of these operations. 
     The System Main 100 takes into the internal buffer the data obtained through its reception from the SYS UI, the MCB, etc., and clears the data stored in the internal buffer, calls each of the modules in subordinate ranking to the System Main 100 and delivers the processes to it, and performs the process for the renewal of the system state. 
     The M/C initialize control module 101 performs control over the initializing sequence to continue from the time the power is turned on to the time when the system attains the stand-by state, and this module is started upon the completion of the power-on process for performing various types of tests subsequent to the power-on operation by the MCB. 
     The M/C set-up control module 103 performs control over the set-up sequence which continues from the time when the start key is pushed to the time when the MCB for performing the processing of the copy layer is started, the specific operation of this module consisting in the formation of a job mode on the basis of the FEATURE (i.e. the item of instructions to the M/C for fulfilling the user&#39;s requirements) as instructed from the SYS UI and then determining the setup sequence in accordance with the job mode so formed. 
     As shown in FIG. 12 (a), the formation of the job mode is accomplished by analyzing the mode instructed by the F/F and dividing the job into its sections. In this case, the job represents the actions of the M/C from the time when the M/C is started by the user&#39;s demand to the time when all the copies as required are discharged and the operation of the machine is brought to a halt, and thus a job is a collective body of the job modes, which represents the minimal units into which the job can be divided in relationship to the user&#39;s demand. For example, this can be explained with reference to the case of a synthesis with an image set into the base picture or text. As shown in FIG. 12 (b), the job modes consist of a cut, a transfer, and an extraction, and the job is a collective body composed of these. Moreover, in the instance of the three ADF original sheets as shown in FIG. 12 (c), the job modes are the feeding processes for the original sheet 1, the original sheet 2, and the original sheet 3, and the job is a collective body of all these. 
     And, the module performs document scanning in the case of the automatic mode, press scanning in the case of the mode for outline drawing for coloring, sample scanning in the case of the color detecting mode (the press scanning operation being performed three times in the maximum) and also distributes the copy mode necessary for the copy cycle to the ITT, the IPS, and the MCB, and then starts up the MCB at the time when the setup sequence is brought to a finish. 
     The M/C stand-by control module 102 controls the sequence in the course of the M/C stand-by and, in specific terms, it performs the reception of the start key, the control of the color registration, the entry into the DIAG. mode, and so forth. 
     The M/C copy cycle control module 104 performs the control of the copying sequence from the start of the MCB to the halt thereof, and, in specific terms, the module performs the notification of the paper feed count, the demand for the start-up of the IIT based on its identification of the completion of a job, and the demand of a falling operation of the IPS on the basis of its identification of the stopping of the MCB. Moreover, this M/C copy cycle control module performs the function of notifying the correspondent remote unit about the through command which is generated while the M/C is being stopped or in the course of its operation. 
     The fault control module 106 performs the monitoring of the falling factors from the IIT and the IPS, and, when any such factor occurs, the module demand the MCB to perform the falling operation, and, in specific terms, this module performs the falling operations in response to a fail command from the IIT and the IPS, and also performs the recovering operation, for example, under a jam command from the MCB, judging and determining the recovery to be made at the time of a halt of the M/C after the occurrence of a demand for a fall from the MCB. 
     The communication control module 107 performs the setting of the IIT ready signal to be generated from the IIT and the setting of the ENABLE/DISABLE for the communication in the image area. 
     The DIAG control module 108 performs control in the input check mode and output check mode in the course of the DIAG mode. 
     Next, a description is made of the exchanges of data among these individual modules or with another sub-system. 
     FIG. 13 is a chart illustrating the flow of data among the individual remote units and the flow of data among the modules in the system. The marks from A to N represent the flows of serial communications, the mark Z represents the hot line, and the marks from (1) to (12) represent the data exchanged among the modules. 
     Between the SYS UI remote unit and the initialize control section 101, the SYS UI unit transmits the TOKEN command, which hands the rights to the control of the CRT over to the SYSTEM NODE, while the initialize control section 101 transmits the &#34;config&#34; command to the SYS UI unit. 
     Between the SYS UI remote unit and the stand-by control section 102, the SYS UI remote unit transmits the mode change command, the start copy command, the job cancel command, the color registration request command, and the tray command to the stand-by control section 102, which in its turn transmits the M/C status command, the tray status command, the toner status command, the recovery bottle status command, the color registration ANS command, and the TOKEN command to the SYS UI remote unit. 
     Between the SYS UI remote unit and the setup control section 103, the setup control section 103 transmits the M/C status command (progress) and the APMS status command to the former, which in its turn transmits the stop request command and the interrupt command to the latter 103. 
     Between the IPS remote unit and the initialize control section 101, the former transmits the initialize end command to the latter 101, which in its turn transmits the NVM parameter command to the former. 
     Between the IIT remote unit and the initialize control section 101, the former transmits the IIT ready command to the latter 101B, which in its turn transmits the NVM parameter command and the INITIALIZE command to the former. 
     Between the IPS remote unit and the stand-by control section 102, the former transmits the initialize free hand area command, the answer command, the remove area answer command, and the color information command to the latter 102, which in its turn transmits the color detection point command, the initialize free hand area command to the former. 
     Between the IPS remote unit and the setup control section 103, the former transmits the IPS ready command and the document information command to the latter 103, which in its turn transmits the scanning information command, the basic copy mode command, the editing mode command, and the M/C stop command to the former. 
     Between the IIT remote unit and the stand-by control section 102, the former transmits the IIT ready command, which conveys a notice of the completion of the press scanning process, to the latter 102, which in its turn transmits the sample scanning start command and the initialize command to the former. 
     Between the IIT remote unit and the setup control section 103, the former transmits the IIT ready command and the initialize end command to the latter 103, which in its turn transmits the document scanning start command, the sample scanning start command, and the copy scanning start command to the latter. 
     Between the MCB remote unit and the stand-by control section 102, the latter 102 transmits the initialize sub-system command and the stand-by selection command to the former, which in its turn transmits the sub-system status command to the latter. 
     Between the MCB remote unit and the setup control section 103, the latter 103 transmits the start job command, the IIT ready command, the stop job command, and the declare system fault command to the former, which in its turn transmits the IOT stand-by command and the declare MCB fault command to the latter 103. 
     Between the MCB remote unit and the cycle control section 104, the latter 104 transmits the stop job command to the former, which in its turn transmits the MADE command, the ready-for-next-job command, the job delivered command, and the IOT stand-by command to the former. 
     Between the MCB remote unit and the fault control section 106, the latter 106 transmits the declare system fault command and the system shutdown completion command to the MCB remote unit, which in its turn transmits the declare MCB fault command and the system shutdown command to the latter 106. 
     Next, a description is made of the interfaces among the individual modules. 
     The System Main 100 transmits the signal reception remote unit numbers and the data for reception to the individual modules (101 through 107), and these individual modules perform the transmission and reception of data with their respective remote units. On the other hand, nothing is transmitted from the individual modules (101 through 107) to the System Main 100. 
     The initialize control section 101 gives a notice of the system state (stand-by), upon the completion of the initializing process, to the fault control section 106 and the stand-by control section 102, respectively. 
     The communication control section 107 gives information on the possibility or impossibility of communications to the initialize control section 101, the stand-by control section 102, the setup control section 103, the copy cycle control section 104, and the fault control section 106, respectively. The stand-by control section 102 gives a notice of the system state (progress) to the setup control section 103 when the start key is pushed. 
     The setup control section 103 gives a notice of the system state (cycle) to the copy cycle control section 104 when the setup is completed. 
     (II-2) Image Processing System (IPS) 
     (A) Module construction of IPS 
     FIG. 14 is a chart illustrating an outline of the module construction of the IPS. 
     In a color image forming equipment, an original sheet in color is read with the decomposition of the colors into the primary colors, i.e. B (blue), G (green), and R (red) by means of the CCD line sensors, and the data on the original sheet are further converted into the primary colors, Y (yellow), M (magneta), C (Cyan), and, additionally, K (black) for the toner, and a color picture image is reproduced with the exposure process, as well as development, with a laser beam equipment in the IOT (Image Output Terminal). In this case, with the image being decomposed into the toner images for Y, M, C, and K respectively, the copying process (pitch) with Y as the process color is performed once, and, in the same way, a copying cycle is performed one time each with M, C, and K taken as the process color, so that the all copying cycles so executed for a color image add up to a total of four times, and, with the overlapping effect of the images in these mesh dots, a color image is reproduced in full color. Accordingly, in respect of the process of converting the color decomposition signals (i.e. B, G, and R signals) into the toner signals (i.e. Y, M, C, and K signals), there arise such questions as how to control the balance of colors in such signals, how to reproduce those colors in manners suitable for the reading characteristics of the IIT and the output characteristics of the IOT, how to make adjustments of the density and contrast of the image, and how to control the emphasis of the edges and the moire. 
     The IPS inputs the B, G, and R color decomposition signals from the IIT into itself, performs various data-processing jobs for improving the reproducing characteristics, such as the color-reproducing features, the reproducing fidelity of colors in terms of chromatic gradation, and the reproducing capabilities of fine details, and then converts the toner signals for the developing process colors into ON/OFF signals, giving the output of the said signals to the IOT. And, as illustrated in FIG. 14, this system is composed of the END conversion (Equivalent Neutral Density) module 301, the color masking module 302, an original sheet size detecting module 303, the color conversion module 304, the UCR (Under Color Removal) and black-generating module 305, the space filter 306, the TRC (Tone Reproduction Control) module 307, the reduction and enlargement module 308, the screen generator 309, the IOT interface module 310, the area image control module 311 provided with an area-forming circuit and a switch matrix, the editing control module provided with the area command memory 312, the color palette video switch circuit 313, and the font buffer 314, and so forth. 
     Then, eight-bit data (in 256 chromatic shades) are input from the IIT with respect to each of the B, G, and R color decomposition signals into the END conversion module 301, where they are converted into the toner signals for Y, M, C, and K. Thereafter, the system selects the toner signal X for the process color, and, converting this into a binary signal and applying it as the ON/OFF data for the toner signals of the process color, the system outputs the data from the IOT interface module 310 to the IOT. Therefore, in the case of the full-color copying operations, the IPS initially performs the pre-scanning process in which it performs the detection of the information on the size of the original sheet, the detection of the editing area, and the detection of other items of information on the original sheet, and thereafter this system first performs, for example, the copying cycle in which the toner signal X for the process color is applied to Y, and then the copying process in which the toner signal X for the process color is applied to M, and, each time such a copying cycle is carried out one after another in sequence, this system performs the processing of the signals corresponding to the scanning operations conducted four times for reading the original sheet. 
     The IIT reads one pixel in the size of 16 dots/mm with respect to each of B, G, and R, using the CCD sensors, and it outputs the data in 24 bits (three colors×8 bits; 256 color shades). The CCD sensors are provided with filters for B, G, and R on their upper surface areas, and each of the sensors has a length of 300 mm with the density of 16 dots/mm, and they perform their scanning operation at the rate of 16 lines/mm at the process speed of 190.5 mm/sec. Therefore, the sensors read the original sheet at the speed of 15M pixels per second in respect of each color, thereafter outputting the resultant data. And, the IIT converts the information on the reflexive ratio to the information on density through log-conversion of the analog data on the picture elements for B, G, and R, and then it further converts the data into digital data. 
     Next, a description is made of the individual modules. 
     FIG. 15 is a chart for illustrating the individual modules of which the IPS is composed. 
     (a) END conversion module 
     The END conversion module 301 is the module for adjusting (i.e. converting) the signals obtained by optically reading the color original sheet by the IIT to obtain the gray-balanced color signals. The toner for the color image attains the equivalent amount, and thus gray serves as the standard. However, the values of the B, G, and R color decomposition signals which are input from the IIT when an original sheet in gray color is read are not made equal because the light source and the spectroscopic characteristics, etc. of the color decomposing filters are not ideal. For this reason, the END conversion process is performed by the use of a conversion table (LUT: Look Up Table) like the one shown in FIG. 15 (a) in order to balance the said signals. Accordingly, the conversion table is one which has the characteristic features adapted for yielding the output of the signals, when the system reads the original sheet in gray color, as converted into the B, G, and R color decomposition signals always in their equivalent shades in correspondence to their levels (black→white), and, as such, the table is dependent upon the characteristics of the IIT. Moreover, the conversion tables are prepared in a set of 16 tables in total, and, of these, 11 tables are those to be applied to the film projectors, including the tables for negative films, while three of them are tables to be used for ordinary copies, for photographs, and for generation copies. 
     (b) Color masking module 
     The color masking module 302 is one which converts the B, G, and R signals into the signals corresponding to the quantities of the toners for Y, M, and C by performing matrix operations thereof, and the module processes the signals after the gray balance adjustment is made of them in the END conversion process. 
     For the conversion matrices used for the color masking are employed three-by-three matrices which determine Y, M, and C, respectively, from B, G, and R purely by arithmetic operations. Yet, in order to take account not only of B, G, and R, but also of the effect of such components as BG, GR, RB, B 2 , G 2 , and R 2 , it is, of course, acceptable to employ various matrices or other matrices. As regards the conversion matrices, this system possesses those for the usual color control and those for generating the intensity signals in the monochromatic mode. 
     In this manner, this system performs gray-balance adjustment first of all in the processing of the video signals from the IIT by means of the IPS. If this process were to be performed after the color masking process, then it would be necessary to make adjustments of the gray balance with a gray original sheet which reflects considerations given to the characteristics of the color masking. Hence, the conversion tables to be used in such a case would be more complicated. 
     (c) Original sheet size detecting module 
     Not only the original sheets in the regular sizes, but also originals in voluntarily chosen shapes, with patches of paper pasted thereon or otherwise, may be copied from time to time. In such a case, it is necessary to detect the size of the original sheet in order that the copying machine may select an adequate size of paper matching the size of the original sheet. Moreover, when the copying paper is larger than the size of the original sheet, the erasure of the outer areas will produce copies with an improved appearance in finish. For this reason, the original sheet size detecting module 303 performs the detection of the original sheet size at the time of the pre-scanning operation and also the erasure of the platen color (the erasure of the frame) at the time of the scanning for reading the original sheet. Therefore, the color of the platen should be a color (for example, black) which is easily distinguishable from that of the original sheet, and, as illustrated in FIG. 15 (b), the upper limit value and the lower limit value for the recognition of the platen color are to be set in the threshold register 3031. And, in the course of pre-scanning, this system compares by means of the comparator 3032 the signals X as converted into information close to the reflexive ratio of the original sheet (Γ conversion) (for which the output from the space filter 306 described later is used) with the upper limit value and the lower limit value which are set in the threshold register 3031 and then detects the edge of the original sheet, then storing the maximum value and the minimum value of the coordinates (x, y) in the maximum/minimum sorter 3035. 
     For example, as shown in FIG. 15 (d), the maximum values and the minimum values (X 1 , X 2 , and Y 1 , Y 2 ) for the top, the bottom, the left, and the right of the original sheet are detected and stored in memory in case the original sheet is aslant or not in a rectangular shape. Moreover, in the course of the scanning operation for reading the original sheet, the system compares, by means of the comparator 3033, the Y, M, and C of the original sheet, with the upper limit value/the lower limit value set in the threshold register 3031 and then performs the frame-erasing process by erasing the signals on the outer sides of the edges, i.e. the signals on the reading of the platen, in the platen color erasing circuit 3036. 
     (d) Color conversion module 
     The color conversion module 305 is a module which makes it possible to convert the specified color in a specific area, and this module is provided with a window comparator 3052, a threshold register 3051, a color palette 3053, and so forth as illustrated in FIG. 15 (c). For performing the color conversion process, this system sets the upper limit values/ the lower limit values for the converted colors, Y, M, and C, respectively, in the threshold register 3051 and then sets in the color palette 3052 the values of the Y, M, and C for the colors into which the source colors are to be converted. And, the system controls the NAND gate 3054 in accordance with the area signals input from the area image control module, and, in case the area is not a color conversion area, the system sends out the Y, M, and C of the original sheet as they are from the selector 3055, but, if the system comes across with a color conversion area, it sends out the Y, M, and C signals set for the object conversion colors in the color palette 3053, effecting the switching of the selector 3052 with the output from the window comparator 3052 when the signals on the Y, M, and C of the original sheet comes between the upper limit value and the lower limit value of the Y, M, and C as set in the threshold register 3051. 
     As for the specified colors, the system recognizes the specified colors by working out the average values of the 25 picture elements, B, G, and R, respectively, in the neighborhood of the coordinates as specified at the time of pre-scanning, with the digitizer being employed to point the area on the original sheet. With this averaging operation, it is possible to recognize, for example, even the 150-line original sheet with a degree of accuracy within five in chromatic difference. For the reading of the data on the density of B, G, and R, the system reads out the specified coordinates, by converting them into the addresses, from the IIT shading correction RAM, and, for the said conversion into the addresses, it is necessary to make readjustments of the portions of data adjusted in registration, in the same way as in the case of the detection of the original sheet size. In the pre-scanning process, the IIT operates in the sample scanning mode. The B, G, and R density data which are read out of the shading correction RAM are corrected by the software and then averaged and thereafter processed further for their END correction, and, after the color masking process is executed thereon, the resultant data are set in the window comparator 3052. 
     As for the registered colors, eight colors in the maximum can be registered on the color palette 3053 at the same time out of a total of 16,700 thousand colors, and the standard colors made available are 14 colors, which are Y, M, C, G, B and R, the colors intermediate between these, and K and W. 
     (e) UCR and black-generating module 
     In case the Y, M, and C colors are in equivalent amounts, they will together form a gray color. Therefore, from a theoretical standpoint, it is possible to replace the Y, M, and C in equivalent amounts with black, thereby representing the same colors. However, from a practical standpoint, their replacement with black would cause some turbidity in the colors, with the result that the reproduction effect of the colors are deteriorated. Therefore, the UCR and black-generating module perform the processes for generating an adequate amount of K, in such a way that turbidity will not occur in the color, and also reducing the equivalent amounts of Y, M, and C in proportion to the amount of K so generated (the removal of the undercolors). In specific terms, the system detects the maximum values and the minimum values of Y, M, and C, and, in proportion to the differences between them, the system generates K in an amount equal to or less than the minimum value with reference to the conversion tables and performs the removal of the undercolors to certain degrees with respect to Y, M, and C in proportion to the amount of K so generated. 
     In the UCR and the generation of black, a color close to gray, for example, has a small difference between the maximum value and the minimum value, as shown in FIG. 15 (e), K is generated while the amounts of Y, M, and C equivalent to their minimum values are removed as they are. However, in case there is a considerable difference between the maximum value and the minimum value, the admixture of black and a decline in the chromatic saturation of the colors with low luminosity and high chromatic saturation are prevented by making the amounts of removed color smaller than the minimum values for Y, M, and C and also by reducing the amount of black generated. 
     In FIG. 15 (f), where examples of specific circuit constructions are presented, the system detects the maximum values and the minimum values of Y, M, and C by means of the maximum value/minimum value detecting circuit 3051 and works out the difference between them with the arithmetic operation circuit 3053, and generates K with the conversion table 3054 and the arithmetic operation circuit 3055. The conversion table 3054 makes adjustments of the value of K, and, when the difference between the minimum value and the maximum value is small, the value of the output from the conversion table 3054 turns out to be zero, and consequently the minimum value is output, as it is, as the value of K from the arithmetic operation circuit 3055, but, when the difference between the maximum value and the minimum value is large, the value of the output from the conversion table 3054 will not be zero, and, therefore, the system outputs as the K value the value obtained by subtracting the amount of the said difference from the minimum value with the arithmetic operation circuit 3055. The conversion table 3056 is a table with which the system finds the values to be subtracted from the Y, M, and C in correspondence to the K, and the system performs the removal from Y, M, and C in correspondence to K with the arithmetic operation circuit 3059 by way of the conversion table 3056. Moreover, the AND gates 3057 and 3058 are those for applying the gate process to the K-signal and the signals obtained after the removal of the undercolors of Y, M, and C, performing the said process in accordance with the individual signals in the monochromatic mode and the full-color mode, and the selectors 3052 and 3050 are those for selecting one of Y, M, C, and K on the basis of the process color signal. In practice, the colors are reproduced in the mesh dots in Y, M, and C in this manner, the ratios for the removal of Y, M, and C and the ratio for the generation of K are set up by the use of curves and tables or the like which have been developed on the empirical basis. 
     (f) Space filter module 
     In the devices applied to this copying machine, the original sheet is read by scanning the CCD with the IIT as described earlier, and, if the information so obtained is used as it is, the resulting output will be obscure information, and, additionally, since the system reproduces the original sheet in mesh dots, there occurs moire between the mesh dot cycle for the printed matter and the sampling cycle for 16 dots/mm. Moreover, moire appears also between the mesh dot cycle which the system forms for itself and the mesh dot cycle of the original sheet. The space filter module 306 is a module which is provided with the function of recovering obscure images like these and the function of removing the moire. And, for the removal of the moire, a low pass filter is employed in order to cut off the mesh dot components while a high pass filter is used for processing the emphasis of the edges. 
     In the space filter module 306, one color out of Y, M, C, M, Min and Max-Min input signals is taken out with the selector 3003, as shown in FIG. 15 (g), and then converts the data into information close to the reflexive ratio with reference to the conversion table 3004. This approach is taken because it is easier to pick up the edges through this type of information, and Y, for example is selected as one of the colors for this process. Furthermore, with the threshold register 3001, the four-bit binary value conversion circuit 3002, and the data coder 3005, the system separates the signals for each picture element from Y, M, C, Min and Max-Min into the eight hues, i.e. Y, M, C, K, B, G, R, and W (White). The decoder 3005 recognizes the hues on the basis of the information for the binary data conversion, and it outputs the data in the form of one-bit information on the point whether or not the hue so recognized is a necessary color as viewed with reference to the process color. 
     The output shown in FIG. 15 (g) is input into the circuit shown in FIG. 15 (h). Here, the information for the removal of the mesh dots is generated with the FIFO 3061 and the 5×7 digital filter 3063 and with the modulation table 3066, and the system generates the edge emphasis information from the information output as shown in FIG. 15 (g) with the FIFO 3062 and the 5×7 digital filter 3064, the modulation table 3067, and the delay circuit 3065. The modulation tables 3066 and 3067 are selected in correspondence to the copying modes, such as the photograph mode, the exclusive mode for characters, and the mode for photographs and characters in mixture. 
     With regard to the emphasis of the edges, assume for example that it is intended to reproduce green-colored characters like those given in FIG. 15 (i) (1) to appear as rendered in (2). For this purpose, Y and C are to be processed for emphasis as shown in (3) and (4) while M is not given any emphasizing treatment as shown by the solid line in (5). The switching operation for this is performed with the AND gate 3068. For the performance of this process, the emphasis in the manner shown by the dotted line under (5) will result in the occurrence of a turbid color in the edges as shown in (6) on account of the admixture of M. The delay circuit 3065 is a circuit which achieves the synchronization of the FIFO 3062 and the 5×7 digital filter 3064 for the purpose of switching the emphases like this for each process color by means of the AND gate 3068. If vivid green characters are reproduced by the ordinary process, magenta causes turbidity in the green characters in consequence of its admixture with green in them. For this reason, the system reduces the amount of M in order not to emphasize the edges of the characters while it outputs Y and C as usual when it recognizes any characters as one in green as mentioned above. 
     (g) TRC conversion module 
     The IOT makes it possible to reproduce full-color original sheets on copies through its performance of the copying cycle four times (in the case of full-color copy in four colors) by each of the process colors, Y, M, C, and K, in accordance with the ON/OFF signals transmitted from the IPS. As a matter of practice, however, it requires fine and delicate adjustments made in consideration of the characteristics of the IOT to reproduce with high fidelity the colors theoretically identified through the processing of the signals. The TRC conversion module 309 is a module which is provided in order to attain improvements on the features of reproducibility like this, and this system is provided with an address conversion table for accepting eight-bit image data as its address input as shown in FIG. 15 (j) in the RAM, the said address conversion table being designed to work in correspondence to each of the combinations in density of the colors, Y, M, and C, and this system is provided with such editing functions as density control, contrast control, negative-positive reversal, color balance control, character mode, and openwork synthesis, which are to be performed in accordance with the area signals. In the three upper bits in this RAM address are used the bit 0 through the bit 3 of the area signals. Moreover, the off-area mode permits the use of the above-mentioned functions in combination. Furthermore, this RAM possesses eight-face conversion tables composed, for example, of 2 k bytes (256 bytes×8 faces), which are stored up to the maximum of eight faces in the course of the carriage return of the IIT for each cycle for Y, M, and C and they are selected in accordance with such operating factors as the specification of the area and the copying mode. Of course, it will be unnecessary to load the tables for each cycle of the operations if the RAM is given an increased capacity. 
     (h) Reduction and enlargement processing module 
     The reduction and enlargement processing module 308 performs the reduction and enlargement processes through the reduction and enlargement processing circuit 3082 in the process in which the system sends out the data X after once storing it in the line buffer 3083, and this module generates the read/write addresses for the sampling signals and the line buffer 3083 by means of the resampling generator and address controller 3081. The line buffer 3083 is designed in the form of a Ping-Pong buffer composed of buffers for two lines, so that the said buffer will be capable of writing the next line data in one of the buffers at the same time as the data are read out of the other of the buffers. In the reduction and enlargement process, the operations in the main scanning direction are digitally performed with this reduction and enlargement processing module 308, but those in the supplementary scanning direction are performed by changing the speed of the scanning operations with the IIT. The scanning speed can be varied in the range from two times the rated speed to 1/4th of the said speed for making reductions or enlargements in the range from 50% to 400% of the original sheet size. In the digital processing, reductions are made by thinning out for complementation, while enlargements are made by adding for complementation, in the course of the reading/writing of data in the line buffer 3083. The data for the said complementation will be generated by a weighting process in proportion to the distances to the data on both sides as illustrated in FIG. 15(l). In the case of the data X i  &#39;, for instance, the said data can be determined by arithmetic operations performed with the equation given in the following, on the basis of X i  and X i+1  used to express the data on the two sides and the distances d 1  and d 2  between these sets of data and the sampling point: 
     
         (X.sub.i ×d.sub.2)+(X.sub.i+1 ×d.sub.1) 
    
     Where, 
     d 1  +d 2  =1 
     In the case of the reduction process, the system writes the data in the line buffer 3083 while processing the said data for complementation thereof and, at the same time, transmits the data processed for reduction for the preceding line, reading the said data out of the buffer. In the case of the enlargement process, the system once writes the data as they are and at the same time transmits the data for the preceding line while processing the said data for complementation for enlargement. Although the complementation and enlargement process performed at the time of writing the data would make it necessary to increase the clock in proportion to the enlargement ratio for the time when the writing process is performed, the design of the process described above permits the writing/reading of the data with the same clock. Moreover, with this construction, it is possible to process the shift image in the main scanning direction by reading the data from a point in the middle of the sequence or reading the data with a delay in timing, and it is possible to perform the repeating process by reading the data in repetition, and it is also possible to perform the mirror image processing by reading the data in the reverse direction. 
     (i) Screen generator 
     The screen generator 309 outputs the signals on the chromatic gradation of the toner for the process color after it converts the said signals into the binary value ON/OFF signals for the toner, and this generator performs the binary value conversion process and the error dispersion process through its comparison of the threshold value matrix and the value of the data expressed in chromatic gradation. The IOT inputs these binary value toner signals and reproduces the picture images in the halftones by turning on and off the laser beam in an oval shape approximately 80 μmφ in vertical diameter and 60 μmφ in horizontal diameter in such a way as to work with the signals in such a manner that they correspond to 16 dots/mm. 
     First, a description is made of the way how the chromatic gradation is expressed. A description is made first of a case in which the system forms halftone cells s 4×4, for example, as shown in FIG. 15 (n). First, the screen generator sets the threshold matrix m in correspondence with such a halftone cell s, and then the data values expressed in terms of chromatic gradation are compared with the said matrix. Then, in this comparing process, the system generates a signal for turning the laser beam ON in the part where the value of the threshold matrix m is &#34;5&#34; or less, provided, for example, that the data value is &#34;5&#34;. 
     The 4×4 halftone cells with 16 dots/mm are generally known as mesh dots at 100 spi in the range of 16 steps in chromatic gradation, but, at this level, the picture images are coarse, so that the reproduction fidelity of color images will be inferior. In this invention, therefore, this picture element (pixel) with 16 dots/mm is divided into four parts vertically (i.e. in the main scanning direction) as a method of increasing the chromatic gradation, and thus the ON/OFF frequency of the laser beam as viewed in relation to the picture element taken as the unit is set by the unit equivalent to 1/4th of what is used in the conventional counterpart, i.e. the said factor is improved to a level four times higher, as shown in FIG. 15 (o), so that a level of chromatic gradation higher by four times has been thereby achieved. Accordingly, in correspondence with this, a threshold value matrix m&#39; as shown in FIG. 15 (o) is set up. Moreover, for increasing the number of lines, it will also be effective to employ a sub-matrix method. 
     For the example cited above is used the same threshold value matrix m which has the only nucleus of growth in the proximity of the middle of each halftone cell. Yet, the sub-matrix method has a construction comprising a plural number of the unit matrices with the nuclei of growth for the matrices located in two or more positions (i.e. a plural number of positions) as shown in FIG. 15 (p). With the employment of a screen pattern designing technique like this, it is possible to change the number of lines and the chromatic gradation freely in accordance with the distinction between dark areas and light areas for example by applying 141 spi in 64 chromatic grades to the light areas while changing these factors to 200 spi in 128 chromatic grades according as the processed area grows darker. A pattern like this can be designed by judging the smoothness of the chromatic gradation and the fineness of lines, as well as such factors as the properties of grains, by visual observation. 
     In case images in halftone are reproduced by dot matrices like those mentioned above, the number of steps in the chromatic gradation and the resolution will be in a mutually contradicting relation. In other words, these two factors are in the relationship that amounts to the point that an increase in the number of steps in chromatic gradation results in the deterioration of the resolution while an increase of the resolution causes a decline in the number of steps in chromatic gradation. Moreover, when the matrix for the threshold data is made smaller, there occurs an error in determining the quantum basis for the picture images which are actually output. The error dispersion process works for improving the reproducibility of the chromatic gradation as viewed from a macroscopic standpoint by detecting the quantizing error of the ON/OFF signals as converted into binary values after they are generated by the screen generator 3092 and the chromatic gradation signals of the input, as shown in FIG. 15 (q), with the density conversion circuit 3093 and the subtraction arithmetic operation circuit 3094 and then by feeding the said data by the use of the correcting circuit 3095 and the addition arithmetic operation circuit 3091. This process performs, for example, the error dispersion process, in which the picture elements in the corresponding position and the positions on both sides of the said position in the preceding line are &#34;folded in&#34; through a digital filter. 
     The screen generator makes improvements on the reproducing characteristics of picture images in high chromatic gradation and with high precision by changing the threshold value data and the feedback coefficients for the error dispersion process for each original sheet or for each area in the original sheet, depending on the types of the picture images, such as the images in the neutral tones and the character images as described above. 
     (j) Area image control module 
     The area image control module 311 has a construction which makes it possible to set seven rectangular regions and their order of priority in the area generating circuit, and the control information for the areas is set in the switch matrices which correspond to the individual areas. The control information include the color conversion information, the color mode information, which relates to such points as whether the process calls for monochromatic processing or full-color processing, the modulation selecting information, which is related to photographs, characters, etc., the selection information for the TRC, and the selecting information for the screen generator, and these types of information are applied to the control of the color masking module 302, the color conversion module 304, the UCR module 305, and the space filter 306, and the TRC module 307. Moreover, the switch matrix is so designed that it can be set by software. 
     (k) Editing control module 
     The editing control module makes it possible to perform the outline drawing coloring process, which consists in painting the specified area not limited in shape with the specified color, reading the original sheet not in a rectangular form but in the form of a pie graph, or the like. As illustrated in FIG. 15 (m), the AGDC (Advanced Graphic Digital Controllers) 3121, the font buffer 3126, the logogram ROM 3128, and the DMAC (DMA Controller) 3129 are connected to the bus of the CPU. And, the encoded four-bit area command is transmitted from the CPU and written in the plane memory 3122 through the AGDC 3121, and the fonts are written in the font buffer 3126. The plane memory 3122 is composed of four planes, and it is possible to set the various point of the original sheet in four bits from plane 0 to plane 3, so that the original sheet can be output even if the command is 0 when the value kept in the memory is &#34;0000&#34; for example. It is the decoder 3123 that decodes this four-bit information into the commands 0 through 15, and it is the switch matrix 3124 that determines which of the command 0 through 15 should be assigned as the command for performing the processing of which one of the fill pattern, the fill logic, and the logogram. The font address controller 3125 generates the addresses in the font buffer 3126 in correspondence to the patterns, such as the mesh dot shade and the hatching shade, with the two-bit fill pattern signals. 
     The switching circuit 3127 performs the selection, etc. of the original sheet data X, the font buffer 3126, and the color palette on the basis of the contents of the fill logic signals and the original sheet data X from the switch matrix 3124. The fill logic provides the information for the filling of the background (i.e. the background area of the original sheet) alone with color mesh, the conversion of the specified area into color, masking work and trimming work, and the painting of the entire area with its demarcation by an outline. 
     In the IPS according to this invention, the system first performs the END conversion and thereafter the color masking process on the signals read from the original manuscript by means of the IIT as mentioned above, performing the processing of the original sheet sizes, the erasure of frames, and the color conversion, which can be processed more efficiently in full color, and thereafter performing the removal of the undercolors and the generation of black with the operations being narrowed down to those on the process color. However, such processes as space filtering, color conversion, TRC, and size reduction and enlargement are designed to process the data on the process color, so that such processes may work with a smaller amount of processing work than in the case of the processing of the full-color data, with the conversion tables to be used being reduced to one third and yet with their types being proportionately increased, so that the improvements have been attained on the flexibility of the controlling operations, the reproducibility of colors, reproducibility of the chromatic gradation, and the reproducibility of fine details. 
     (B) Hardware construction of image processing system (IPS) 
     FIG. 16 is a chart illustrating an example of the hardware construction of the IPS. 
     In the IPS according to this invention, the hardware components are mounted on two separate boards (i.e. IPS-A and IPS-B), with the parts performing the basic functions of a color image forming equipment, such as those for achieving the reproducibility of colors, the reproducibility of chromatic gradation, and the reproducibility of details with high precision, being mounted on the first board (IPS-A) and with those parts performing the applied functions and the specialized functions, such as editing, being mounted on the second board (IPS-B). The construction of the former is presented in FIGS. 16(a) through 16(c) while that of the latter is given in FIG. 16(d). Above all, the system will be able to deal flexibly with the applied and specialized functions as required merely with design modifications of the second board, so long as it is capable of satisfactorily performing the basic functions with the first board. It follows from this that any attempt at further enhancing the functions of this system as a color image forming equipment can be accomplished merely by making modifications of the design features of the second board. 
     To the boards for the IPS are connected CPU buses as shown in FIG. 16 (the address bus ADRSBUS, the data bus DATABUS, and the control bus CTRLBUS), and the video data B, G, and R from the IIT, the video clock IIT.VCLK as the synchronizing signal, the line synchronization signals IIT.LS (in the main scanning direction and for the horizontal synchronization), and the page synchronization signals IIT.PS (in the supplementary scanning direction and for vertical synchronization) are thereby connected to the IPS boards. 
     Now that the video data are processed with a pipe line in the END conversion section and the subsequent parts, there occurs a delay of the data by the clock unit necessary for the processing of the said data at each processing stage. Therefore, it is the line-synchronizing signal generation and failure-check circuit 328 that generates and distributes the horizontal synchronizing signals to deal properly with such delays at each of the individual processing stages and also performs failure-checks on the video clock and the line-synchronizing signals. For this purpose, the line-synchronizing signal generation and failure-check circuit 328 has the video clock IIT.VCLK and the line-synchronizing signal IIT.LS connected thereto, and, additionally, the CPU buses (the ADRSBUS, DATABUS, and CTRLBUS) and the chip-selecting signal CS are connected to the said circuit, so that the internal setting may be re-written. 
     The video data B, G, and R from the IIT are input into the ROM 321 of the END conversion section. The END conversion tables may be constructed in such a way as to permit their loading from the CPU as required, for example, with a RAM used therefor, but, since there scarcely arises any necessity of rewriting in the course of the processing of picture images while the equipment is in its operating state, two 2 k-byte ROM are employed for each of B, G, and R to provide a LUT (Look Up Table) system composed of these ROM&#39;s. And, the system possesses 16 faces of conversion tables, which can be changed over from one to another with the four-bit selecting signal, END Sel. 
     The output generated from the ROM 321 after the END conversion performed thereon is connected to the color masking section composed of three pieces of the arithmetic operation LSI 322, which has two faces of 3×1 matrix for each of the colors. To the arithmetic operation LSI 322 are connected the individual buses for the CPU, and these buses make it possible to set the Matrix coefficients with the CPU. To these buses are connected the setup signal SU, which is to be used for the changeover from the processing of picture image signals to the CPU buses for such purposes as the rewriting of such signals by the CPU, and the chip selecting signal CS, and one-bit switching signal MONO, which is to be used for switching the selection of the matrix. In addition, the power down signal PD is input, and this signal stops the internal video clock while the IIT is not performing any scanning operation, i.e. while it is not performing any processing of picture images. 
     The signals converted from B, G, and R into Y, M, and C are processed for their color conversion through the color conversion LSI 353 on the second board (IPS-B) shown in FIG. 16 (d), and the processed signals are then input into the LSI 353 for DOD. The color conversion LSI 353 is provided with four channels of color conversion circuits composed of a threshold register, which sets the colors not to be converted, and a color palette, which sets the colors to be converted, a comparator, and so forth, and the LSI 323 for DOD is provided with an edge detecting circuit, a frame erasing circuit, and so forth for the original sheets. 
     The output generated from the LSI 323 for DOD after its processing for frame-erasure is transmitted to the LSI 324 for the UCR. This LSI contains the UCR circuit, a black-generating circuit, and additionally those circuits for generating the necessary colors and outputs each of the signals expressing the process color X, which is a signal corresponding to the color of the toner in the copying cycle, the necessary Hue, and the Edge. Accordingly, the COLOR signal, which is a two-bit signal for specifying the process color, and also the color mode signals (4COLR and MONO) are input into this LSI. 
     The line memory 325 is composed of the FIFO, which accumulates the data for four lines in order to input into the 5×7 digital filter 326 each of the signals on the process color X, the necessary Hue, and the Edge output from the LSI 324 for the UCR, and the FIFO for adjusting the portion of the delay for matching. Here, with respect to the process color X and the Edge, the line memory accumulates the signals for four lines in the FIFO and transmits those for five lines to the digital filter 326, but, with respect to the necessary color Hue, the system is so designed as to provide a delay to the signal on the necessary hue in the FIFO, so that the signal may be put into its synchronization with the output from the digital filter 326, and then to transmit the signal to the LSI 327 for the MIX. 
     The digital filter 326 comprises two sets (the low pass filter LP and the high pass filter HP) of 5×7 filters composed of three LSI&#39;s for the 2×7 filter, and the digital filter 326 performs the processing operations in respect of the process color X with one of the sets of filters mentioned above and performs the processing operations in respect of the Edge with the other set of filters. The LSI 327 for the MIX performs such processes as the removal of mesh dots and the emphasis of the edges on these outputs with reference to the conversion tables and then the resultant data are mixed into the signal on the process color X. Here, EDGE and Sharp are input as the signals for the changeover of the conversion tables. 
     The TRC 342 is composed of 2 k-byte RAM provided with eight faces of conversion tables, which are structured in such a way as to accept the rewriting thereof by the use of the carriage return period before each scanning operation and are changed over by the switching signal TRC Sel. And, the processing output from this unit is transmitted by a transceiver to the LSI 345 for reduction and enlargement processes. The reduction and enlargement processing section is constructed in the form of a Ping-Pong buffer (line buffer) with two pieces of 8 k-byte RAM 344, and the LSI 343 performs the generation of the resampling pitch and the generation of the address for the line buffer. 
     The output form the reduction and enlargement processing section returns to the LSI 346 for the EDF by way of the area memory section on the second board on FIG. 16 (d). The LSI 346 for the EDF is provided with the FIFO for storing the information for the preceding line and performs the error dispersion process with the information on the preceding line. And, the signal X obtained after the performance of the error dispersion process is output to the IOT interface by way of the LSI 347 for SG, which forms the screen generator. 
     The IOT interface transmits the signals input into it from the LSI 347 for SG in one-bit ON/OFF signals in parallel to the IOT, putting the signals together into eight bits by means of the LSI 349. 
     Since the data actually flowing on the second board shown in FIG. 16 are for 16 dots/mm, the data are reduced to 1/4th and also converted into binary values by the reduction LSI 354 and then stored in the area memory. The enlargement decoding LSI 359 is provided with the filter pattern RAM 360, and this LSI reads the area information from the area memory and enlarges the data to 16 dots/mm when it generates a command therefrom, and then this LSI performs the processing operations for the generation of the logogram address, the color palette, and the fill patterns. The DRAM 356, which is composed of four faces, stores the coded four-bit area information. The AGDC 355 is a controller for its exclusive use for controlling the area command. 
     (II-3) Image Output Terminal (IOT) 
     (II-3-1) Schematic construction 
     FIG. 17 is a chart illustrating a schematic construction of the Image Output Terminal. 
     This equipment employs an organic belt of photosensitive material (Photo Receptor Belt), is provided with a developing unit 404 for Black (B), Magenta (M), Cyan (C), and Yellow (Y) for use for full-color development of images in four colors, the transfer device for transporting the paper to the image transfer section (Tow Roll Transfer Loop) 406, the vacuum transfer device (Vacuum Transfer) 407 for transporting the paper from the transfer device 404 to the fixing device 408, the paper trays 410 and 412, and the paper transfer channel 411, and the three units, i.e. the Photo Receptor Belt, the Developing Unit, and the Tow Roll Transfer Loop are constructed in such a way that they can be pulled towards the front side. 
     The information light obtained by modulation of the laser light from the laser light source 40 is radiated upon the photo- sensitive material 41 for its exposure by way of the mirror 40d, a latent image being thereby formed. The image formed on the photosensitive material is developed by the developing unit 404 and a toner image is formed thereby. The developing unit 404 is composed of the parts for the colors, K, M, C, and Y, which are arranged in the positional relations as illustrated in the FIG. This arrangement has been made by taking account, for example, of such factors as the relationship between the dark attenuation and the characteristics of the individual toners and the difference in the influence of the admixture of the toners for other colors into the black toner. However, the driving sequence for the full-color copying process is Y→C→M→K. 
     In the meanwhile, the paper supplied from the unit 410, which is composed of paper trays in two stages, and from the other two-staged tray 412 is fed into the Tow Roll Transfer Loop 406 through the paper transfer channel 411. The Tow Roll Transfer Loop 406, which is positioned in the transfer section, is composed of two rolls connected by a timing chain or a belt, as well as a gripper bar mentioned later, and this loop transports the paper, gripping it with the gripper bar, and has the toner image on the photosensitive material transferred onto the paper. In the case of the full-color copying process in the four colors, the paper is turned four times in the transfer loop section, so that the images in M, C, Y, and B, respectively, are transferred in this stated order. After such transfers, the paper is released from the gripper bar, being thereafter handed over from the Tow Roll Transfer Loop 406 to the vacuum transfer device 407 and then fixed by the fixing device 408 and discharged from the system. 
     The vacuum transfer device 407 absorbs the speed difference between the tow roll transfer loop 406 and the fixing device 408, maintaining these in synchronization with each other. In this equipment, the transfer speed (i.e. the process speed) is set at 190 mm/sec., and, now that the transfer speed is 90 mm/sec. for the full-color copying process, etc., the transfer speed is different from the fixing speed. In order to secure the fixing performance, the process speed is slowed down. On the other hand, it is not possible to allocate any additional power to the fuser because it is necessary to keep the power consumption within 1.5 kVA. 
     Therefore, in the processing of paper in such smaller sizes as B5 and A4, the speed of the vacuum transfer device 407 is reduced from 190 mm/sec. to 90 mm/sec. to make the speed of the said device equal to the fixing speed at the very moment when the paper bearing the image transferred thereto is released from the tow roll transfer loop 406 and gets on the vacuum transfer device. However, since this copying machine has been designed in an effort to offer it in a compact size by using as short a distance as possible between the tow roll transfer loop and the fixing device, this machine is not capable of accommodating the A3 paper in the space between the transfer point and the fixing device, and, if the speed of the vacuum transfer device were reduced, a deviation would occur in the color transferred onto the paper in consequence of the braking force working thereon because the rear end of the A3 paper would be still being processed for the transfer of the image. Therefore, a baffle board 409 is provided between the fixing device and the vacuum transfer device, so that the transfer channel is extended for the transport of the A3 paper by thrusting the baffle board 409 downward, so that the paper is transported via a loop so formed and that the leading edge of the paper reaches the fixing device after the image transfer process is completed, with the vacuum transfer device being operated at the same speed as the transfer speed and thus absorbing the difference in speed. Moreover, the same operating setup as that for the A3 paper is applied also to the processing of the OHP film sheets in consideration of their inferior thermal conductivity. 
     In addition, this copying machine is designed to perform its copying operations without any deterioration of productivity not only for producing full-color copies but also even for producing black-and-white copies. In the case of copies in black, it is possible to perform the fixing operation well enough even with a smaller amount of heat because a smaller amount of the toner is needed to form a toner layer for image reproduction, and therefore this copying machine is designed for its operation at the fixing speed of 190 mm/sec. as set without any reduction of the transfer speed at the vacuum transfer device. In other words, the same setup is applied also to the single-color copying operations in any color other than black because it is not necessary to reduce the fixing speed so long as the toner layer is a single layer. Then, the toner which remains on the photosensitive material is scraped off with the cleaner 405 when the transfer of the image is finished. 
     (II-3-2) Construction of tow roll transfer loop 
     The tow roll transfer loop 406 has the construction as illustrated in FIG. 18 (a). 
     The tow roll transfer loop of this copying machine is characterized by having a construction without any mechanical paper-supporting structure, so that any lack of consistency in color will not affect the reproduction of color on the copies, and also by incorporating a feature for increasing the transfer speed through speed control performed on the device. 
     The paper is discharged from the tray by the feed head 421 and transported through the buckle chamber 422, which is driven with the paper pass servo motor unit 423, and then the paper is fed into the tow roll transfer loop by way of the registering gate 425, which is controlled for its opening and closure with the registering gate solenoid 426. The system is so designed that the arrival of the paper at the registering gate 425 is detected by means of the pre-registering gate sensor 424. The driving of the tow roll transfer loop is performed by driving the roller 433 with a servo motor 432 via a timing belt, the said motor turning and driving the said belt in the counterclockwise direction. The roller 434 is not driven in particular, but two pieces of timing chain or belt are put between the rollers, and a gripper bar 430, which is ordinarily closed by the action of elasticity but opens its mouth at the inlet of the tow roll transfer loop by the action of a solenoid, is provided between the chains (in the direction crossing at the right angles with the transporting direction). This gripper bar 430 transfers the paper by gripping on it and pulling it around at the inlet of the tow roll transfer loop. In the conventional mechanism, the paper is supported with a Mylar sheet or mesh attached to a supporting structure made of aluminium or steel, and, consequently, a difference in the thermal expansion coefficient causes concavities and convexities to develop on the surface, so that there arises a lack of flatness for the transfer of images, with resultant localized differences in the image transfer efficiency and a consequential lack of consistency in the colors reproduced on the copies. In contrast, the adoption of this gripper bar has rendered it unnecessary to provide any particular supporting structure for the paper, making it possible to prevent the occurrence of a lack of color consistency. 
     Since this tow roll transfer loop is not provided with any supporting structure for the transported paper, the paper will be slung outwards by centrifugal force in the roller section, and the paper is attracted towards the roller with two rollers pulled by the action of vacuum in order that the paper may be prevented from being thrown out of its place, and the paper is transported in fluttering motion once it moves past the rollers. At the transfer point, the paper is sucked by electrostatic force towards the photosensitive material in which Detackcolortron and Transfercolortron are arranged, and there the paper is processed for the transfer of images. After the transfer of the image is finished, the gripper home sensor 436 detects the position of the paper at the exit of the tow roll transfer loop, and, at a proper timing, the solenoid goes into action to cause the gripper bar to open its mouth to release the paper and to hand it over to the vacuum tow roll transfer loop 413. 
     Therefore, the paper is transported four turns in the case of the full-color copying process and three turns in the three-color copying process for the transfer of images onto the paper in the tow roll transfer loop. 
     Now, the timing control for the servo motor 432 is described with reference to FIG. 18 (b). In the tow roll transfer loop, it is satisfactory to control the servo motor 432 to run at a constant speed while the image transfer is being performed and to control the said motor, after the completion of the image transfer, in such a way that the lead edge transferred onto the paper will be in synchronization with the point for the transfer of the subsequent latent image. On the other hand, the length of the Photo Receptor Belt 41 (i.e. the photosensitive material belt) is a length sufficient for the formation of latent images on three sheets in the A4-size and two sheets in the A3-size, and, in addition, the length of the belt 435 is set slightly longer than the length of the A3-size paper (approximately 4/3 times the size of the A3 paper). 
     Accordingly, for performing color copying on the A4-size paper, the servo motor 432 is controlled to run at a constant speed when the latent image I 1  for the first color is being transferred, and then, when the transfer is completed, the servo motor is controlled for a sharp acceleration in such a way that it will run in synchronization with the leading edge of the latent image I 2  for the second color. Moreover, in the case of the A3-size paper, the servo motor is controlled for a deceleration and a stand-by, upon the completion of the transfer of the latent image I 1 , in such a way that the leading edge transferred onto the paper will be set in synchronization with the fore end of the second latent image I 2 . 
     (II-4) User interface (U/I) 
     (A) Adoption of color display 
     FIG. 19 is a chart illustrating the state of installation and the external view of the user interface system built by the use of a display unit while FIG. 20 is a chart for describing the angle and height of installation of the user interface. 
     The user interface forms a system for supporting easy-to-understand dialogues between the operator and the machine, and, as such, the user interface ought to constitute a system which is capable of impressing the necessary information on the operator while making simple operations possible and clearly presenting the interrelations of information items. In order to accomplish these objectives, an original user interface matching the user&#39;s way of use has been developed for this copying machine, and it has been set as the aim for ensuring the operating facility and efficiency of this system to offer a system easy to understand for the beginners, but not burdensome to the skilled persons, to make it possible for the operator to perform direct operations for the selection of the particulars of the functions, to communicate information to the operator with as much accuracy and as promptly as possible through utilization of color, and to concentrate the operations to one place to the maximum extent possible. 
     Those copying machines which are provided with a rich variety of functions and yet offer a high degree of reliability will win higher evaluations as equipment, but, if such machines should present difficulty in using those functions, they would suffer an extreme decline of their value and would eventually be expensive machines. Consequently, such machines would also suffer a very considerable decline of their overall evaluations on the ground that they are difficult to use even though they are equipment models offering high-level functions. From this standpoint, the user interfaces constitute a major factor that largely determines whether or not the equipment is easy to use, and, above all, the operating facility of the user interface will be an important issue all the more in view of the tendency towards the incorporation of more and more functions in copying machines as experienced in the recent years. 
     With a view to making improvements on the important feature, the operating facility of the equipment, the user interface for this Invention is provided with a 12-inch color display unit 501 and with a hardware control panel 502, which is positioned by one side of the said display, as illustrated in FIG. 19. 
     Furthermore, a menu easy to view and easy to comprehend is offered to the users through integration of features reflecting contrivances for displays in color, and additionally an infrared ray touch-board 503 is combined with the color display unit 501, which allows the user to gain direct access to the system with operations on the &#34;soft buttons&#34; on the screen. Moreover, the particulars of the operations are distributed for efficiency to the &#34;hard buttons&#34; on the hardware control panel 502 and the &#34;soft buttons&#34; put on display on the screen of the color display unit 501, and this feature has made it possible to simplify the operations and to achieve an efficient composition of the menu screen. 
     On the back sides of the color display unit 501 and the hardware control panel 502 are mounted the monitor control/power source board 504, the video engine board 505, the CRT driver board 506, and so forth, as shown in FIGS. 19 (b) and (c), and the hardware control panel 502 is set at an angle for directing the said control panel 502 further towards the center than the face of the color display unit 501 as shown in FIG. 19 (c). 
     Moreover, the color display unit 501 and the hardware control panel 502 are installed not directly on the base machine 507 (i.e. the main unit of the copying machine) but on the supporting arm 508 set up on the base machine 507. The adoption of a color display unit 501 thus mounted on a stand, without the adoption of a console panel as in practice with the conventional copying machines, makes it possible to install the color display unit in a position above the base machine 507 in a three-dimensional arrangement as illustrated in FIG. 20 (a), and, therefore, by arranging the color display unit 501 in the right innermost position above the base machine 507 as illustrated in FIG. 20 (a), it is possible to design a copying machine without giving consideration to the console panel, which in turn makes it possible to design such an equipment in a compact size. 
     In a copying machine, the height of the platen, which in effect corresponds to the height of the equipment, is designed to measure up to the waist height, which is quite convenient for setting the original sheets, and this height places limitations on the height of the equipment. The conventional console panels are installed in the uppermost position of copying machines and they are consequently positioned almost at the height of the operator&#39;s waist and thus in the neighborhood of the hands, which permits easy access to the panel for performing operations thereon, but this means that the operating panel section, which is to be used for the selection of the functions and the setting of the executing conditions, and the display section are positioned in a place at a distance quite remote from the eyes. In this respect, the user interface for this Invention is installed in a position higher than that of the platen, i.e. at a level significantly closer to the height of the eyes, as shown in FIG. 20 (b), and this arrangement offers greater ease in looking at the display and also provides greater ease in operation since its position is not at a lower level but in the forward direction as viewed by the operator. In addition, the height set for the installation of the display unit at a level close to the height of the eyes makes it possible to utilize the space below the display unit effectively as a space for the installation of such optional kits as the control board, the memory card device, and the key counter. Therefore, this design approach renders it unnecessary to make any structural change for the installation of a memory card device, and thus it is possible to install a memory card device as an additional item without making any change in the external appearance of the equipment, and, at the same time, it is possible to set the position and height for the installation of the display unit in such a way as to ensure ease in viewing. Moreover, it goes without saying that the display unit may be installed rigidly at a prescribed angle, but may also be set in a construction adopted to permit the changes in the setting angle of the said unit. 
     (B) System configuration 
     FIG. 21 is a chart illustrating the module construction of the user interface, and FIG. 22 is a chart illustrating the hardware construction of the user interface. 
     The construction of the modules for the user interface of this copying machine is composed of the video display module 511, which controls the image screens put on display on the color display unit 501, as shown in FIG. 21, the editing pad 513, and the editing pad interface module 512, which performs the processing of the input and output for the memory card 514, and the systems UI 517 and UI 519, the sub-system 515, the touch screen 503, and the control panel 502, which perform control over these modules and pads, are connected to the video display module 511. 
     The editing pad interface module 512 accepts the input of the coordinates, X and Y, from the editing pad 513 and also the input of the jobs and the coordinates, X and Y, from the memory card 514, and it also transmits the video map display information to the video display module 511 and exchanges the UI control signals with the said video display module 511. 
     By the way, the processes for specifying the areas for processing consist of the marker specification, which delimits the area for processing with markers in red or in blue for performing the trimming process or the conversion of color, the two-point specification of the area for processing, which consists in delimiting a rectangular area by the coordinates, and a closed loop specification, which is executed by tracing the demarcation of the area for processing on the editing pad. However, in contrast to the fact that the marker specification has no data in particular and that the two-point specification of the area has a small amount of data, the closed loop specification requires a large amount of data for the area to be processed for editing. This editing process of the data is performed in the IPS unit, but the amount of the data is too large for any transmission thereof at a high speed. Therefore, the system is so constructed as to use an exclusive-use transmission line, separate from the ordinary data transmission line, for the transmission of the data on the coordinates, X and Y, to the IIT/IPS 516. 
     The video display module 511 recognizes the button ID data with reference to the input points as input for the vertical side and the horizontal side of the touch screen 503 (i.e. the positions of the coordinates on the touch screen) and inputs the button ID data for the control panel 502. Then, this module 511 transmits the button ID data to the systems UI 517 and UI 519 and receives the demand for display from the systems UI 517 and the UI 519. Moreover, the sub-system (ESS) 515 is connected, for example, to work stations and the host CPU, and thus it is the printer controller when this copying machine is used as a laser printer. In such a case, the information generated with the touch screen 503, the control panel 502, and the keyboard (not illustrated in the Figure) is transmitted as it is to the sub-system 515, and the contents on the display screen are transmitted from the sub-system 515 to the video display module 511. 
     The systems UI 517 and UI 519 transmit and receive the information on the copying modes and the states of the machine with the master controllers 518 and 520. As viewed in correspondence to FIG. 4 mentioned earlier, one of these systems UI 517 and UI 519 is the SYS UI module 81 for the SYS remote unit while the other of these is the MCB UI module 86 in the MCB remote unit illustrated in FIG. 4. 
     (C) Construction of display screen 
     The user interface for this Invention, as hardware, is composed of two control boards, which are UICB 521 and EPIB 522, as shown in FIG. 26, and, in correspondence to the construction of the modules mentioned above, also the functions are divided into two major groups. And the UICB 521 is mounted with two CPU&#39;s (for example, a CPU equivalent to 8085 by Intel Corp. and a CPU equivalent to 6845 by the same corporation) for controlling the hardware of the UI and for driving the editing pad 513 and the memory card 514, and also for processing the input from the touch screen 503 and writing the input data on the CRT unit, and the EPIB 522 is mounted with a 16-bit CPU (for example, 80C196KA by Intel Corp.), because an 8-bit CPU is not sufficient for performing the functions for drawing picture images on the bit map area, and the system is constructed in such a way that the data on the images drawn in the bit map area are transmitted by the DMA to the UICB 521. Thus, this design of the user interface construction has been adopted in an effort to divide the functions. 
     FIG. 23 is a chart illustrating the construction of the UICB. In the UICB, the CPU 534 (for example, a CPU equivalent to 8051 by Intel Corp.) is provided in addition to the CPU&#39;s mentioned above, and, with CCC 531 being connected to the data communication lines, such as the high-speed communication line LNET and the optional keyboard, the CPU 534 and the CCC 531 together control the communications, and the CPU 534 is employed also for the driving of the touch screen. The signals generated on the touch screen, as they are, i.e. in the form of the information on the positions of the coordinates on the said screen, are taken into the CPU 532 from the CPU 534 through the CCC 531, so that the signals are processed by the CPU 532 for the recognition of the button ID data. Moreover, the UCIB is connected to the control panel through the input port 551 and the output port 552, and the UCIB is also designed to be capable of performing the transmission and reception of commands and the status information at the rate of 9,600 bps, receiving the video data at 1M bps, together with the clock signal at 1M Hz, from the EPIB 522 and the sub-system (ESS) through the sub-system interface 548, the receiver 549, and the driver 550. 
     As regards memory devices, the UICB is provided with the frame ROM&#39;s 538 and 539, the RAM 536, the bit map RAM 537, and the V-RAM 542 in addition to the boot ROM 535, which accommodates the boot strap. The frame ROM&#39;s 538 and 539 are memory devices which store the data for the display screen not in any bit map but in a data structure which allows easy handling by software, and, when a demand for display comes transmitted through the LNET, image drawing data are first generated here by the CPU 532 using the RAM 536 as the work area, and the data are written in the V-RAM 542 by DMA 541. Also, the bit map data are transmitted and written to the bit map RAM 537 from the EPIB 522 by the DMA 540. The character generator 544 is for use for the graphic tiles, and the text character generator 543 are for use for character tiles. The VRAM 542 is controlled with reference to the tile codes, which are composed of 24 bits (three bytes), 13 bits being used for the information on the kinds of tiles, two bits for the information for making distinction among texts, graphics, and bit maps, one bit for the blinking information, five bits for the information on the colors of the tiles, and three bits for the information on the background or the fore-ground, respectively. The CRT controller 533 develops the display screen on the basis of the tile code information written in the VRAM 542 and transmits the video data to the CRT through the shift register 545, the multiplexer 546, and the color palette 547. The drawing of images in the bit map area can be changed over by the shift register 545. 
     FIG. 24 is a chart illustrating the construction of the EPIB. The EPIB is provided with a 16-bit CPU 555 (which is an equivalent, for example, to 80C196KA by Intel Corp.), the boot page code ROM 556, the OS page code ROM 557, the area memory 558, and the RAM 559, which is to be used as the work area. And, the EPIB performs the transmission of the bit map data to the UICB, as well as the transmission of the commands and the status information to the said UICB and the reception of the same therefrom, through the interface 561, the driver 562, and the driver/receiver 563 and also performs the transmission of the data on the coordinates, X and Y, to the IPS through the high-speed communication interface 564 and the driver 565. In this regard, the reading and writing operations in relation to the memory card 525 are performed through the interface 560. Therefore, when any editing area specifying information for a closed loop or any copy mode information is input from the editing pad 524 or the memory card 525, these pieces of information are respectively transmitted as appropriate from time to time to the UICB through the interface 561 and the driver 562 and to the IPS through the high-speed communication interface 564 and the driver 565. 
     (D) Construction of display screen 
     Also in the adoption of a display unit for a user interface, the offer of information matching the integration of multiple functions will necessarily indicate a proportionately larger amount of information, for which it is estimated in simple perception that a more extensive display area should be necessary and that it is, in some respect, made difficult to deal adequately with the needs for a display in a compact area. If a display unit in a compact size is employed, it will be difficult to present all the necessary information on one screen, not merely because of the problems associated with the density of display, but also from the viewpoint of offering a display screen easy to view and intelligible to the operator. 
     For the user interface according to this invention, a display unit in a compact size is employed and yet contrivances have been made for the display on its screen and for its control within the framework of the said unit. Particularly, through effective utilization of the merit that a color display unit, as compared with the LED&#39;s and liquid crystal indicators used in console panels, are capable of adopting a rich variety of displaying modes with the control of hues, luminance, and other displaying attributes, various contrivances have been put into the system in order to display the information in an easily understandable manner in spite of the compact size of the display unit. 
     For example, contrivances have been made to compose the display screens in a concise form by classifying the information to be displayed on the screen into major categories for their respective display on a plural number of screens and also, with a single screen taken as the unit, presenting the minimum of the necessary information on the primary screen with the details of information relegated to the pop-up type displays. And, with the screens which represent a plural number of information items thereon, contrivances have been made to develop characteristic features in the color indications and characteristic features in the emphatic indications so as to make it possible easily to recognize and to distinguish the necessary information on each screen. 
     (a) Screen layout 
     FIG. 25 is a chart illustrating an example of the composition of the screen on the display unit, and FIG. 25 (a) is a chart showing the composition of the basic copying screen while FIG. 25 (b) is a chart showing an example of the pop-up screens put on display on the basic copying screen, and then FIG. 25 (c) is a chart showing the composition of the screen for Paint 1 for the creative editing process. 
     In the user interface for this Invention, the basic copying mode screen shown in FIG. 25, which is used for setting the copying modes, is put on display as the initial menu screen. The screen for setting the copying modes forms a &#34;soft&#34; control panel, which is a screen divided into two parts, i.e. between the message area A and the pathway B, as shown in FIG. 25. 
     The message area A occupies the area equivalent to three lines in the uppermost area on the screen, the first line being used for the state message and the second line and the third line forming an area for use for guiding messages in case there is any contradiction in the selection of the functions, for use for messages concerning any abnormal state of the equipment, and for use for messages representing warning information, and the prescribed messages are put on display in this area. Moreover, the right-hand margin of the message area A is assigned to the area for indicating the number of sheets, and here the set number of sheets to be copied as input with the ten keys and the number of copies being produced are indicated. 
     The pathway B constitutes the area where selection is to be made of various kinds of functions, and it has the pathways of basic copying, editing features, marker editing, business editing, free-hand editing, creative editing, and tools, and, in correspondence to each of these individual pathways, the pathway tabs C are put on display. Additionally, each of the pathways is provided with pop-up menus for improving the operating ease and efficiency. In the pathway B, the system puts on display the &#34;soft&#34; button D, which forms a list of branched choices, with which selection is to be made of the functions by touching on the appropriate button, the icon E (picture), which changes, depending on the selected function, and represents the specific function, the indicator F, which indicates the reduction/enlargement ratio, and so forth. Those functions which are shown on the pop-up menus by operations on the &#34;soft&#34; buttons D are indicated by the pop-up mark G &#34;Δ&#34;. And, by touching on the pathway tab C, the pathway can be opened, and the functions of the particular pathway can be selected by touching on the &#34;soft&#34; button D. The selection of functions by touches on the &#34;soft&#34; button D is so designed in consideration of its operating efficiency that the operation are to be performed from the upper left part of the screen towards the lower right-hand side thereof in regular steps. 
     As mentioned above, the display system features the division between the basic copying screen and the rest of the screens in order to provide the maximum compatibility with the other models of equipment and the maximum compatibility with the hardware console panel, and the editing screen, moreover, is designed to have a hierarchical structure composed of a plural number of levels so as to offer screens and functions in a manner suitable for the operator&#39;s skill level. Furthermore, this system offers a set of screens enabling the operator to use the functions with ease in a highly variegated way with the advantage of the pop-up representation of high-level functions and complicated functions among those presented on a given single screen through the combination of the screen composition as described so far and the pop-up functions. 
     The pop-ups contain detailed information for the setting of particular functions, and the composition for the screen for each pathway is made easy to observe and simple by providing the pop-up opening function and by having the detailed function-setting information as required from time to time. The pop-up menu is opened when a soft button with a pop-up mark thereon is touched. And, the pop-up menu is closed, for instance, when a close button or a cancel button is selected, or when the &#34;all-clear&#34; button is pushed, or when the &#34;all-clear&#34; operation is put into action by the auto-clear function. It is FIG. 25 (b) that shows the appearance of the screen where a pop-up is opened by a touch on the soft button for variable magnification in the reduction/enlargement function. 
     When the pathway tab for creative editing is touched upon in the basic copying screen, the screen for the pathway for creative editing appears by a shift of the screen on display, and it is FIG. 25 (c) that illustrates the screen for Paint 1 in that particular pathway. On this screen, there are the bit map area H and the inductive message area I. The bit map area H occupies the upper left-hand part of the screen, and this area is designed to produce its indication of the bit map in black and white when the editing area is specified, for example, on the editing pad. In addition, the inductive message area I uses the lower left-hand part of the screen, and the message performs the function of inducing or guiding the user in correspondence to the editing job, and it changes in accordance with the particular job being performed. On the screen, the area excluding these areas, i.e. the bit map area H, the inductive message area I, and the message area A in the upper region of the screen, is used as the work area. 
     (b) Basic copying screen 
     The pathway for the basic copying function is provided with soft buttons (i.e. branched choices) for the selection of the individual functions for the color mode, paper selection, reduction and enlargement, copy quality, color balance, and job program, as illustrated in FIG. 25 (a), and is also provided with the individual pathway tabs for marker editing, business editing, free-hand editing, and creative editing, as well as aided features and tools. These pathways are the initial-phase pathways, which are put on display, for example, after the power-on operation or after turning on the all-clear button, or when the auto-clear button is turned on. 
     The color mode is provided with the branched choices of full-color copying (four path color) for copying in the four kinds of color, Y, M, C, and K, three path color for copying with toners in the three kinds of color excluding K, single-color copying, which offers the choice of one color out of 12 colors, black, and black/red, and the default choice, which is selected automatically, is designed to permit its voluntary setting. Here, as the choices for black/red has detailed items to be set, those items are developed on the pop-up menu. 
     The selection of paper offers the four choices of automatic paper selection (APS), trays 1 and 2, and cassettes 3 and 4, and the APS works when a specific magnification is set for reduction or enlargement, but does not work when the automatic magnification system (AMS) remains set. The default setting is for the APS. 
     The reduction and enlargement function permits the choices of 100% reproduction, the AMS, which is to be used for setting the magnification for copying on the basis of the paper size and the original sheet size when the paper size is selected, and the voluntarily chosen magnification, and puts the set magnification, the computed magnification, or the automatic setting on display on the indicator in the top area of the equipment. For the variable magnifications, this system permits the setting of magnification by one percent in the range from 50% to 400% and also permits the setting of the vertical magnification and the horizontal magnification independently of each other (differential magnification). Therefore, the detailed setting items for these are developed on the pop-up menu. Moreover, the default magnification setting is 100%. 
     As mentioned earlier, this reduction and enlargement process is performed by changing the scanning speed for the subsidiary scanning direction (i.e. in the X-axis direction) and through reduction or enlargement in the main scanning direction (i.e. in the Y-axis direction) by a change in the manner of reading the signals out of the line memory for the IPS. 
     The copy quality function offers the choices of the automatic processes by which the system performs density control for original sheets in black and white and performs automatic color balancing for color original sheets and the manual processes by which the system permits the operator to perform density control in seven steps with the pop-up menu, and the IPS performs control over these processes. 
     The color balancing function enables the operator to specify the color to be reduced on the copy out of Y, M, C, B, G, and R by operations with the pop-up menu, and the IPS performs control over the process. 
     The job programming function offers branched choices that work effectively only while a memory card remains inserted in the slot of the reading device thereof, and, in this mode, it is possible to select the reading of the job data from the memory card, as well as the writing of such data to the memory card, by operations on the pop-up menu. As for the memory card, this system uses, for example, a memory card with the memory capacity of 32 k-bytes, with which the system is capable of performing the programming of all the jobs except for those in the film projector mode. 
     (c) Aided feature screen 
     The pathway for the aided features is provided with soft buttons (i.e. branched choices) for the selection of the individual functions for copy output, copy sharpness, copy contrast, copy position, film projector, page programming, job programming, and binding margins and it is also provided with the pathway tabs for marker editing, business editing, free-hand editing, creative editing, and, in addition, basic copying and tools. 
     The copy output pathway offers the branched choices between the output of the copied paper to the top tray and the output of such paper in the sorting mode. The default choice is the output to the top tray, and, in case the sorter is not installed, this item is not put on display. The copy sharpness pathway provides the branched choices of the standard sharpness, the manual copy sharpness control offering the functions for control in seven steps with operations on the pop-up menu, the processing of letters (characters), the print processing, the processing of photographs classified into photographs/characters, with operations on the pop-up menu, and the IPS performs control over these processes. The default choice can be set voluntarily. 
     The copy contrast pathway offers the choices of control over copy contrast in seven steps. The copying position function provides the default choice of the automatic centering function, which positions the center of the copied image in the center of the paper. 
     The film projector pathway offers the mode for taking copies from various types of film as described under a separate item and permits access to the branched choices of 35 mm negatives or 35 mm positives by the projector and the 35 mm negatives, 6 cm×6 cm slides, or 4&#34;×5&#34; slides on the platen, with operations on the pop-up menu. 
     The page programming pathway gives access to the branched choices of the covering function, which puts cover on the copies, the inserting function, which inserts white paper or color paper between copies, the color mode, which sets the color mode for each page of the original sheets, the tray selecting function, by which the tray can be selected for each page of the original sheet. In this regard, this item will not be put on display unless the ADF is installed. 
     The binding margin pathway makes it possible to specify the binding margin by 1 mm in the range from 0 to 30 mm, and the said margin can be set only in one position for one original sheet. The amount of the binding margin is the amount of space from the top edge of the paper to the top edge of the image area, and the main scanning direction is set by shifting operations by means of the line buffer in the IPS and by a lag in the scanning timing of the IIT in the subsidiary scanning direction. 
     (d) Editing screen and tool screen 
     The editing screens are offered through the four pathways, which are marker editing, business editing, free-hand editing, and creative editing. 
     The marker editing pathway and the free-hand editing pathway provide the branched choices of the various individual functions relating to the extraction, deletion, color application (mesh/line/solid), and color change, and further have the pathway tabs for basic copying, aided feature, and tools. The business editing pathway provides the branched choices of the individual functions relating to extraction, deletion, color application (mesh/line/solid), color change, color painting, logogram insertion, and binding margin, and has the pathway tabs for basic copying, aided features, and tools in the same way as the marker editing pathway, etc. 
     The creative editing pathway offers the branched choices of the individual functions relating to extraction, deletion, color application (mesh/line/solid), color change, color painting, logogram insertion, binding margin, negative-positive reversal, image-setting and synthesis, openwork synthesis, painting, mirror image formation, repeating, enlargement and continuous copying, partial shifting, corner/center shifting, manual/automatic variable magnification, manual/automatic differential magnification, color mode, color balance control, continuous page copying, and chromatic synthesis and furthermore has the pathway tabs for basic copying, aided features, and tools as is the case with the marker editing pathway, etc. 
     The tool pathway can be opened to the key operator and the customer engineer by inputting the verifying cipher numbers, and this pathway permits access to the branched choices of the various individual functions for the auditron, the setting up of the initial values for the machine, the selection of the default choices for the individual functions, the registration of colors, the registration of the film types, the fine adjustments of the registered colors, the presetting of the various kinds of branched choices for the machine, the setting of the scanning area for the film projector, the control of the audio tone (the type of tone and the sound volume), and the setting of the timer for the paper transport system and the various kinds of other timers (those for the automatic clearing function, etc.), the setting of the billing meter and the dual languages, the diagram mode, the maximum value adjustment, and the formatting of the memory card. 
     The selection of the default choices is applied to the color mode, the selection of paper, the copying density, the copy sharpness, the copying contrast, the paper tray for the page programming process, the color for the single color process, the colors on the palette and the mesh for the application of color, the patterns of the logotypes, the amount of the binding margin, and the balance of colors. 
     (e) Other screen controls 
     The user interface performs constant monitorinng on the status of execution of the copying operations and, in the event of the occurrence of any jamming, the interface puts on display a screen matching the particular type of jamming. Moreover, for the setting of the functions, the user interface provides an information screen corresponding to the screen currently put on display, the said information screen being kept in a state ready for display as appropriate. 
     For the display on the screen, moreover, the system employs a tile indication measuring 3 mm (8 pixels) in width and 6 mm (16 pixels) in height, to the exclusion of the bit map area, and this indicating area contains 80 tiles in its width and 25 tiles in its height. The bit map area is displayed with 151 pixels on its vertical side and with 216 pixels on its lateral side. 
     In the user interface for this invention as described so far, it is designed to change over the screens on display for each of the categories of modes, such as basic copying, aided features, and editing, and to permit the specification of the branched choices and the input of the data for the executing conditions by touching operations on the soft buttons, with the menus for the selection of the functions and the setting of the executing conditions put on display in each of the modes. In addition, depending on the types and nature of branched choices on the menu, the system provides the pop-up displays for the items indicating their details by pop-up displays (overlapping displays or window displays) in an effort to achieve the repletion of the contents offered on the display. As the result of these features, the display screen can be presented in a neat and well-organized form, which makes it possible to achieve greater ease and higher efficiency in operation, even though there may be many functions available for selection and many conditions for setting. 
     (D) Hardware control panel 
     The hardware control panel is installed on the right side of the color display unit, at such an angle as positions the said panel more in the direction looking towards the center than the display screen. as illustrated in FIG. 20. This control panel is mounted with the individual buttons for the operations for the ten keys, ten-key clear, all clear, stop, interrupt, start, information, auditron, and language. 
     The ten-key buttons are to be used for the setting of the number of copies, the input of codes in the diagram mode and the input of data, and the input of verifying cipher numbers for the use of the tools, and these buttons are rendered inoperative during the generation of a job or while a job remains interrupted. 
     The all-clear button is to be used for restoring all the copying modes set in operation to the default states and for restoring the operating process to the basic copying screen except in the duration when the tool screen remains open, and, although the copying mode is restored to the default state while any interrupting job is set, the interrupting mode is not canceled. 
     The stop button is to be used for interrupting the job at a break of copies in the course of the execution of the job and it is used also for stopping the machine after the copy paper is discharged from the machine. Moreover, this button is used in the diagram mode to stop (interrupt) the operation for checking the input and the output. 
     The interrupting button is to be used to set the system into the interrupting mode in the course of the execution of the primary job, except for the duration of any job interruption, and to restore the operation to the primary job while any interrupting work is being performed. Also, if this button is pushed while the primary job is being executed, the system will assume the reserve status, breaking off the job or finishing the job to enter into the interrupting job in the break between the discharges of copied paper. 
     The start button is to be used for starting a job and for re-starting the job after its interruption, and, in the diagram mode, this button is to be used for inputting and saving the code values and the data values and also for starting the input operation, the output operation, and so forth. If this button is operated in the course of pre-heating, the machine will make its automatic start upon the completion of the pre-heating process. 
     The information button is composed of the ON-button and the OFF-button, which are in the state ready to accept operations thereof except in the process of execution of the copying job. When the ON-button is pushed, the system indicates the information screen for the screen on display at this moment, and the OFF-button is used to retract the information screen. 
     The auditron button is the one which is operated for the input of the verifying cipher numbers at the time when a job is to be started. 
     The language button is the one which is operated for the time when the language on the screen on display is to be changed to another. Therefore, the system is designed to have data in a plural number of languages for each screen put on display, so that they may be selected voluntarily. 
     Furthermore, in addition to the individual buttons mentioned above, the hardware control panel is also provided with LED (Light Emitting Diode) lamps as appropriate in order to indicate the operating conditions of the buttons. 
     (II-5) Film image reading device (F/P) 
     (A) Schematic construction of film image reading device 
     As shown in FIG. 2, the film image reading device is composed of a film projector (F/P) 64 and the mirror unit (M/U) 65. 
     (A-1) Construction of F/P 
     As shown in FIG. 26, the F/P 64 is provided with a housing 601, and this housing 601 is provided with the operation monitoring lamp 602, the manual lamp switch 603, the automatic focusing/manual focusing changeover switch (AF/MF changeover switch) 604, and the manual focusing operation switches (M/F operation switches) 605a and 605b. Moreover, the housing 601 is provided with an opening and closing section 606 which can be opened and closed voluntarily. Through the top surface area and side areas of this opening and closing section 606 are provided penetrating holes 608 and 609 respectively in a size large enough for accepting the film-holding case 607 holding the film 633 for original sheet when it is inserted into the housing 601 in the vertical direction or the lateral direction, depending on the manner how the subject recorded on the film 633 for the original sheet is photographed. On the side opposite to these holes 608 and 609, also a hole (not shown in any figure) is provided, so that the film-holding case 607 may come out through it. The opening and closing section 606 is either installed in the housing 601 with a double-acting spring hinge in such a manner as to permit its movement or is designed for its mounting in the housing 601 in such a way as to permit its free mounting and demounting. With the opening and closing section 606 constructed in such a way as to permit its free opening and closure, it is made possible easily to remove small extraneous matter which may find their way into the inside region of the housing 601 through the holes 608 and 609. 
     For this film-holding case 607, a case for the 35 mm negative film and another case for the 35 mm positive film are made available. Accordingly, the F/P 64 are designed to be suitable for these types of film. Moreover, the F/P 64 is designed also to be compatible with the 6 cm×6 cm negative film and 4 inches×5 inches negative film. In such a case, this negative film is held on the platen glass 31 to remain in close contact therewith between the M/U 65 and the platen glass 31. 
     As illustrated in FIG. 26, a projector lens holding member 611 for holding the projector lens 610 is supported on the right side area of the housing 601 in such a way as to permit its freedom of sliding movement. 
     Moreover, inside the housing 601, a light source lamp 613 composed of a reflector 612 and a halogen lamp, etc. is arranged on the same axis as the projector lens 610. In the proximity of the light source lamp 613, a cooling fan 614 for cooling this lamp 613 is installed. Furthermore, to the right of the lamp 613, an aspherical lens 615, which is used for the convergence of the rays from this lamp 613, a heat ray absorbing filter 616, which cuts off the rays in the prescribed wavelength, and a convex lens 617 are arranged respectively on the same axis as the projector lens 610. 
     To the right of the convex lens 617 is provided a correcting filter automatic exchanger provided with each of a correcting filter holding member 618, which, for example, supports a correcting filter 635 for adjusting the film density of 35 mm negative film and positive film (the correcting filter for one of these types of film is shown in the figure), a driving motor 619 for this correcting filter holding member 618, the first and the second position detecting sensor 620 and 621, which detect the rotating position of the correcting filter holding member 618, and the controlling unit, which controls the driving motor 619 (which is provided in the F/P 64 but not shown in the figure). And, this correcting filter automatic exchanger makes automatic selection of the correcting filter 635 matching the film 633 for the original sheet, out of the correcting filters 635 supported on the correcting filter holding member 618, and sets the said filter in its properly aligned use position on the same axis with the individual lenses, such as the projector lens 610. The correcting filter 635 for this correcting filter automatic exchanger can be positioned at any point, for example between the platen glass 31 and the imaging unit 37, so long as it is on the axis of rays for the projected light. 
     Furthermore, there is an automatic focusing device, which is provided with the light emitter 623 for the automatic focus sensor and the light receptor 624, both working in interlocking with the projector lens holding member 611, and also with a sliding motion driving motor 625 for turning the projector lens holding member 611 for the projector lens 610 into its sliding motion. The film 633 for the original sheet, which is supported with this film-holding case 697, is so arranged as to be be set in its position between the correcting filter holding member 618 on one hand and the light emitter 623 and the light receptor 624 on the other when the film-holding case 607 is inserted into the inside region of the housing 601 through the hole 608 or the hole 609. In the neighborhood of the setting position for the film 635 for the original sheet, a film cooling fan for 626 is provided for its operation for cooling this film 633 for the original sheet. 
     This F/P 64 is provided with a power source separate from that for the base machine 30, but the power source for the former is housed in the base machine 30. 
     (A-2) Construction of M/U 
     As illustrated in FIG. 27, the mirror unit 65 is provided with a base plate 627 and a cover 628 one end of which is installed on this base plate 627 in such a way as to permit the free rotating motion of the said cover. Between the base plate 627 and the cover 628 are rigidly fitted a pair of supporting blocks 629 and 629, and these supporting blocks 629 and 629 are so constructed that they support the cover 628 in such a way as to keep the angle formed by this cover 628 and the base plate 627 at 45° when the cover 628 is opened to the maximum. 
     On the back side of the cover 628 is provided the mirror 630. Also on the base plate 627, a large opening is formed, and a Fresnel lens 631 and a diffusion plate 632 are provided in such a manner that they cover this opening. 
     As shown in FIG. 29, this Fresnel lens 631 and the diffusion plate 632 are made of one acrylic resin plate. On the surface of this acrylic resin plate, the Fresnel lens 631 is formed while the diffusion plate 632 is formed on the back side of the said plate. The Fresnel lens 631 has the function of preventing the peripheral region of the image from getting dark since the said lens transforms the projected light reflected by the mirror 631 and tending to undergo its diffusion into parallel rays. The diffusion plate 632, moreover, performs the function of causing an infinitesimal diffusion of the parallel rays, so that the line sensor 226 will not be able to detect the shadow formed of the selfoc lens 224 inside the imaging unit 37 by the parallel rays from the Fresnel lens 631. 
     This mirror unit 65 is folded and stored in the prescribed storing position while the color copying process with F/P 64 is not performed. And, when the mirror unit 65 is to be used, it is opened and placed in its prescribed position on the platen glass 31 of the base machine 30. 
     (B) Principal functions of film image reading device 
     The film image reading device has the principal functions described in the following: 
     (B-1) Correcting filter automatic change function 
     The halogen lamp which is commonly used as the light source lamp 613 in the F/P 64 generally has the spectroscopic characteristics marked by the fact that the light emitted therefrom contains much red (R) but a small amount of blue (B). Therefore, when the film is projected with this lamp 613, the ratios of red (R), green (G), and blue (B) in the projected light are susceptible to the influence by the spectroscopic characteristics of the lamp 613. For this reason, it is necessary to make correction of the spectroscopic characteristics of the projected light when the film is projected with a halogen lamp. 
     In the meanwhile, there are many types of film used for the recording of picture images as it is seen not merely in the fact that there are such types as negative film and positive film, but also in the fact that there are several types in the negative film itself or in the positive film itself. These types of film are respectively different in their spectroscopic characteristics. For example, negative film is colored in orange, which produces a high transmissivity of R while it gives a low transmissivity of B. For this reason, it is necessary, in the projection of negative film, to make an adjustment of the spectroscopic characteristics of the projected light in such a way that the amount of light for B is augmented. 
     In the F/P 64, therefore, correcting filters are provided for correcting the spectroscopic characteristics of the projected light with a feature like this. 
     The F/P 64 is designed to be capable of automatically changing these correcting filters. The change of the correcting filters is performed by the correcting filter automatic change device, as mentioned above. That is to say, the microprocessor (the CPU) in the system (SYS) remote unit outputs a two-bit command signal for setting the correcting filter in proper correspondence to the film 633 for the original sheet in the position for use, and the control device, then, drives and controls the driving motor 619 in such a way that the two-bit signals from the first and the second position detecting sensors 620 and 621 come into agreement with the signal output from the CPU. Then, when the signals from the sensors 620 and 621 come into agreement with the signal from the CPU, the control device makes the motor 619 to stop. When the motor 619 has stopped, the correcting filter suitable for the film for the original sheet is automatically set in the position for its use. 
     Therefore, the correcting filters can be changed from one to another in a simple and accurate way. 
     (B-2) Function for detecting the inserting direction of film for original sheet 
     The original sheet film 633 can be inserted through either of the inserting holes 608 and 609 made in the opening and closing section 606. In specific terms, the system is so designed that the film 633 for the original film can be installed in its position by moving it in either of the two directions, i.e. the longitudinal direction and the horizontal direction, in correspondence to the manner how the subject is photographed. In that case, at least either one of the inserting holes 608 and 609 is provided with a film detecting switch. That is to say, at least one film detecting switch is provided thereto. And, in case a film detecting switch is provided on the side of the hole 609, but not on the side of the hole 609, the said detecting switch is turned on, generating a detection signal, when the switch has detected the film holding case 607 as inserted through the hole 608. When this detection signal is generated, the area necessary for the line sensor 226 is set in the vertical direction, i.e. in such a way as to set the direction of the subsidiary scanning in the direction longitudinal to the projected image. Moreover, when the film holding case 607 is inserted through the hole 609, the ON/OFF signals from the film detecting switch are set in such a way that the area necessary for the line sensor 206 is set with the main scanning direction set in the direction longitudinal to the projected image. 
     (B-3) Automatic focusing function (AF function) 
     For the installation of the film holding case 607 in the F/P 64, a degree of precision on the order of several tens of mm is required of the mounting position for the film 633 for the original sheet. For this reason, it is necessary to make a proper adjustment of the focus after the film 633 for the original sheet is installed. When this focus adjustment is to be performed by manual operation, it is necessary to find the proper focus by sliding the projector lens holding member 611 through observation of the projected image formed by projecting the image of the film 633 for the original sheet upon the diffusing plate 632 in the M/U 65 as set in the prescribed position on the platen glass 31. In such a case, it is very difficult to make any accurate adjustment of the focus because the image projected on the diffusing plate 632 is extremely hard to see. 
     Therefore, the F/P 64 has been designed to be capable of making an automatic adjustment of the focus. 
     This AF function is performed by the AF device mentioned above in the manner described in the following: 
     The light emitter 623 emits light when the keys on the display for the U/I 136 are operated to set the system in the F/P mode, and also the AF device is put into an operatable state when the AF/MF changeover switch of the F/P 64 is set for the selection of the AF, as shown in FIG. 26. When the film case 607 containing the original sheet film 633 is set on the F/P 64, as shown in FIG. 29, the light emitted from the light emitter 623 will be reflected by this film 633 for the original film, and the reflected light is detected, for example, by the two-element type light receptor 624 for the AF. 
     Then, each of the two elements in the light receptor 624 outputs to the CPU 634 signals in size proportionate to the amount of the reflected light which they have respectively detected. The CPU 634 finds the difference between these signals by performing arithmetic operations, and it generates an output signal, when the result of such arithmetic operations is anything other than zero, thereby driving the motor 625 in the direction in which the difference between the signals from the two elements will be reduced. Consequently, as the projector lens holding member 611 moves in sliding motion, both the light emitter 623 and the light receptor 624 also move in interlocking with the said member. And, when the difference between the output signals from the two elements is reduced to zero, the CPU 634 stops the motor 625. It is at the time when the motor 625 stops that a properly focused state has been attained. 
     The AF operation is performed in this way. Owing to this function, it is rendered unecessary to perform the adjustment of the focus by manual operation every time the film case containing the film for the original sheet is set in the F/P 64. It follows from this that this function not only saves the labor and the time, but also makes it possible to prevent the occurrence of failures due to a deviation from the proper focus. 
     (B-4) Manual focusing function (MF function) 
     With the AF/MF changeover switch 604 turned to MF, the lamp 613 is automatically turned ON for the prescribed duration of time, when it is possible to perform the adjustment of the focus by manual operation. The MF (Manual Focusing) operation is to be performed with the operating switches 605a and 605b, which are pushed while the operator observes the image of the film for the original sheet as projected on the diffusing plate 632 in the mirror unit 65. With this MF operation, it will be possible to bring a particular part of the film image into proper focus. 
     (B-5) Manual lighting function for light source lamp 
     This function makes it possible to turn on the lamp 613 unconditionally when the manual lamp switch 603 is pushed. Although this switch is not used ordinarily, it is used when back-lighting is to be applied to copying made of an image recorded on a relatively thick material, or when the image is viewed for a long duration of time in the course of the AF operation, or when it is to be checked whether or not the lamp has been burned off. 
     (B-6) Automatic magnification changing function and scanning are automatic changing function 
     The system is designed to perform the automatic setting of copying magnifications with the paper size set with the U/I 36. Moreover, the system is also designed to be capable of performing the automatic selection of the copying area suitable for the size of the film when the type of the film for the original sheet is selected with the U/I 36. 
     (B-7) Automatic shading correction function 
     In the ROM of the CPU 634 are stored the density data on the orange masks at ASA 100 for the negative films by FUJI (registered trademark), KODAK (registered trademark), and KONICA (registered trademark), which in general are used frequently for photographing, and, when any of these films is selected, the CPU 634 is capable of making automatic shading correction on the basis of the density data stored in the memory of the CPU. In such a case, it is not necessary to set the base film for the particular one of these films in the F/P 64. 
     Therefore, not only is it possible to save the labor and the time for setting the base film, but also it is possible to prevent the setting of a wrong film by mistake, and this function also makes it unnecessary to perform any administration of the base films. 
     Furthermore, this system is designed to permit the registration of the density data on the orange mask of one type of film other than these three brands of film. It is designed to store these data in the RAM in the system. Also in the case of this registered film, the shading correction function is performed automatically in the same way as for the three brands of film mentioned earlier. 
     (B-8) Automatic image quality control function 
     This function is provided for automatically performing the density controlling process and the color balancing process with such corrections as the Γ correction on the basis of the density characteristics of the film for the original sheet and the various conditions, such as the exposure condition at work at the time when the photographing work was done with the film. 
     (C) Image signal processing 
     (C-1) Necessity of correction of image signals and principle of correction 
     Generally, the density range which the film has is wider than the density range of the original sheet. Again, the density range is different also in various types of film as one finds even in the case of the same brand of film, which shows a wider range of density in the positive film than in the negative film. Furthermore, the density range in film depends upon the photographing conditions for the particular film for the original sheet, such as the amount of exposure of the film, the density of the subject photographed, and the brightness at the time of photographing. As a matter of fact, the density of the subject is distributed extensively within the density of the film. 
     Therefore, in case it is intended to copy the images recorded on the film in such a density range by means of a copying machine, which performs the copying process with reflected light, good reproducibility cannot be achieved so long as the same method of signal processing is employed. This system is therefore designed to obtain good reproducibility by adequately correcting the read image signals in such a manner as to condition the density of the principal subject to a proper level. 
     FIG. 28 illustrates the density characteristics of a certain negative film and the principle of density correction. In this Figure, the horizontal axis in the right half area represents the amount of exposure given to the subject (which corresponds to the density of the subject) while the same axis in the left half area in the Figure represents the density after the shading correction. Moreover, the vertical axis in the upper half region represents the video circuit output (which is approximately equal to the density on the negative film) while the same axis in the lower half region represents the density on the output color copy. That is to say, the first quadrant expresses the density characteristics of the particular negative film, the second quadrant expresses the relationship of the shading correction, the third quadrant expresses the relationship of the Γ correction, and the fourth quadrant expresses the relationship between the amount of exposure given to the subject and the density of the output copy, respectively. 
     The density characteristics of this negative film are indicated by the line α in the first quadrant of FIG. 28. Specifically, the density of the negative film is greater when the amount of exposure from the photographed subject is larger while the density of the negative film decreased linearly according as the amount of exposure from the photographed subject becomes smaller. When the amount of exposure from the photographed subject decreases to some extent, the linearity between the amount of exposure and the density of the negative film disappears. And now assume that the image recorded on the film is a bust of a human being, and if this amount of exposure is small, then the contrast between the face and the hair will not be maintained. Also, even when the amount of exposure is large, the copy will be in a soft tone unless the Γ correction is made because the inclination of the line α, i.e. the value of Γ, is smaller than 1. 
     In these circumstances, Γ correction is necessary. 
     Next, the principle of correction is explained with reference to FIG. 28. In the third quadrant of this Figure, the END curve β is set up for the Γ correction. The inclination of this END curve β, which is expressed by Γ&#39;, is set at Γ&#39;=1/Γ, so that the relation between the amount of exposure from the photographed subject and the density of the output copy will be a linear relation at 45 degrees in the fourth quadrant 
     For example, in the case of the area a where the amount of exposure from the photographed subject is relatively large, the density after the shading correction will be as indicated in the area a&#39;, provided that the density control value which is set in the register of the shading correction circuit is at the value expressed by the straight line (4) in the second quadrant. The inner area of this area a&#39; will not be included in the conversion range marked by the END curve β, with the result that the entire part of this area will be rendered white on the copy. Therefore, the density control value is shifted from the straight line (4) to the straight line (1) in the second quadrant, so that the density after the shading correction may thereby be put into the conversion range of the END curve β. With this correction made in this manner, the relation between the amount of exposure from the photographed subject and the density of the output copy is made to be in accordance with the straight line (1) at 45 degrees in the fourth quadrant, and, owing to this correction, the copies can be produced with proper chromatic gradations. 
     Furthermore, the area b, which has a relatively small amount of exposure from the photographed subject, does not have any linearity in the relation between the amount of exposure from the photographed subject and the density of the negative film. In this case, the density control value for the shading correction circuit is set at the value of the straight line (4) in the second quadrant. Then, in the third quadrant, the END curve β, which is expressed by the line (4), is selected. By selecting this END curve β, it is possible to make the amount of exposure from the photographed subject and the density of the output copy to be as expressed by the straight line (4) at 45 degrees as shown in the fourth quadrant. For example, assume that a person with black hair is wearing a brown hat, the correction just described will prevent the rendition of the hair and the hat in almost the same density, so that it will become possible to produce a clear contrast between the hair and the hat. 
     Thus, correction is made so that the density of the photographed subject may be adjusted to an adequate level. 
     (C-2) Image signal processing method 
     As shown in FIG. 29, the line sensor 226 reads in analog signals the projected light of the image on the film 633 for the original sheet in terms of the amount of light for R, G, and B, and these signals expressed in terms of the amount of light are amplified to the prescribed level by means of the amplifier 231. The image signals so amplified are converted into digital signals and further converted from light signals into density signals by the log converter 238. 
     The image signals expressed in terms of density are then processed for their shading correction by the shading correction circuit 239. This shading correction removes from the image signals the lack of uniformity in the amount of light through the selfoc lens 224, the lack of uniformity in the sensitivity of the individual picture elements in the line sensor 226, the lack of uniformity in the respective spectroscopic characteristics and the light amount level of the correcting filters and the lamp 613, or the components due to the influence of the chronological changes. 
     Prior to the performance of this shading correction, the correcting filter will first be set for a filter for a positive film if one of the three brands of film or the registered film is selected as the film for the original sheet, and the system reads the signals on the amount of light from the lamp 613 in the state without the film 633 for the original sheet set in position and amplifies the signals and converts them into digital signals, then converting the signals further into density signals, which the system uses as the basis for developing the data which it stores in the line memory 240 as the standard data. In specific terms, the system performs sampling operations with 32-line step scanning on the imaging unit 37 for each picture element for R, G, and B and then transmits these sampling data to the CPU 634 through the line memory 240, and then the CUP 634 performs arithmetic operations to find the mean density value of the 32-line sampling data, thereby obtaining the shading data. It is designed to eliminate errors for each picture element by finding the mean value in this manner. 
     Furthermore, with the film for the original sheet set in position, the CPU 634 finds the density adjusting value D ADj , at the time when it reads the image of the film for the original sheet, by arithmetic operations which it performs on the basis of the density data for the negative film as stored in memory in the ROM, thereafter rewriting the D ADj  value set in the register of the LSI in the shading correction circuit 239. Moreover, the CPU 634 makes adjustments of the amount of light of the lamp 613 and the gain in the amplifier 643 in proper correspondence to the selected film. 
     And, the shading correction circuit 239 makes a shift in the read density value by adding the D ADj  value to the actual data obtained by reading the film for the original sheet. In addition, the shading correction circuit 239 makes a shading correction by subtracting the shading data for each of the picture elements from the data derived by these adjustments. 
     Moreover, in the case of any film which is not kept in the memory in the ROM of the CPU 634 and is not registered in the RAM of the system, either, it is necessary to set the base film in place, to obtain the density data on the film, and to find the D ADj  value by arithmetic operations based on the obtained density data. 
     When the shading correction is completed, the IIT 32 outputs the density signals on the R, G, and B to the IPS 33. 
     Then, the CPU 634 selects the END curve on the basis of the actual data on the film for the original sheet and outputs the correction signal in order to have the Γ correction performed on the basis of the selected curve. With this correction signal, the IPS 33 performs the Γ correction, correcting the obscure contrast resulting from the deviation of the Γ of the film for the original sheet from 1 and the nonlinearity characteristics. 
     D) Timing of operating steps and signals 
     On the basis of FIG. 30, the timing of the operating steps and signals is described. In this regard, the broken line placed on a signal indicates that the signal can be used. 
     The operation of the F/P 64 is performed mainly on the U/I 36 for the base machine 30. That is to say, the base machine 30 is set in the F/P mode by operating the F/P operation key put on display on the screen of the display unit for the U/I 36. On the assumption that the film for the original sheet is one of the three brands of film mentioned above or the registered film, there appears a message reading &#34;Put the mirror unit in place, and then select the type of film&#34; on the screen of the display unit for the U/I 36, as illustrated in FIG. 30. Accordingly, the first step is to open the M/U 65 and to set it in the prescribed position on the platen glass 31. 
     Next, when the film selection key on the screen is pushed, the message, &#34;Please wait without inserting the film,&#34; is put on display on the screen. At the same time, the lamp 613 is turned on, and also the correcting filter control (FC CONT) signal becomes (0, 0), and, with this, the FC operation is performed. In other words, the correcting filter automatic changing device is put into action, and the position correcting filter is set in the position for its operation. When the correcting filter is so set, the correcting filter change completion (FC SET) signal becomes LOW. 
     With this change of the signal to LOW and also the elapse of three to five seconds after the lamp 613 is turned on working as the trigger, the collection of the shading data is started for the performance of the shading correction process. When this shading data collection is completed, and, with the completion of this process working as the trigger, the FC CONT becomes (0, 1), when the correcting filter automatic changing device goes into action and sets the film correcting filter in its operating position. Furthermore, with the shading correction working as the trigger, the message, &#34;Focusing operation is ready to start. Please put the film,&#34; is shown on the screen, when the lamp 613 is turned off. Therefore, the film case 607 containing the film 633 for the original sheet therein should be installed in the F/P 64. With this, the light from the light emitter 623 is reflected by this film, and the reflected light is detected by the light receptor 624. 
     In case the reflected light does not correspond to the finite difference of 0 in the amount of the received light between the two elements of the light receptor 624, the motor 625 for the AF device is put into action, and the focus is properly adjusted thereby. In other words, the AF operation is performed. Upon the completion of the focus-adjustment, the F/P operation completely ready (F/P RDY) signal becomes LOW. After this (F/P RDY) signal becomes LOW and after the elapse of one second after the FC SET signal becomes LOW, the message, &#34;Copying Ready,&#34; is indicated on the screen. When the start key on the U/I 36 is pushed, the message, &#34;Copying,&#34; is put on display on the screen and also the lamp 613 is turned on, and, after the passage of the building up time for the lamp 613, the collection of data for the automatic density adjustment (A/E) is started. In other words, the imaging unit 37 performs one stroke of scanning operation and reads one part or all of the projected image, in order to obtain the data for its performance of the density adjustment, the color balance adjustment, and the Γ correction, and so forth. 
     Next, the copying job is performed, with the imaging unit 37 performing the scanning operation four times if for copying in full color. In such a case, the shading correction and the density adjustment are performed automatically on the basis of the shading data and the automatic density adjustment data. When the copying job is completed, the lamp 613 is turned off and, at the same time, the message, &#34;Copying Ready,&#34; is put on display on the screen. Accordingly, a new copying job will be performed when the start key is pushed again. If it is desired to copy another image, the frame of the film is to be changed to another. When the film frame is changed to another, the F/P RDY signal becomes HIGH and also the message, &#34;Focusing Ready,&#34; is displayed on the screen. Then, when a new frame of the film is set, the AF operation is performed, and, at the same time, the F/P RDY signal becomes LOW and also the message, &#34;Copying Ready,&#34; is displayed on the screen. After that, a push on the start key puts the copying process into operation. 
     (III) Image Input Terminal (IIT) 
     Next, a detailed description is made with respect to the Image Input Terminal (IIT) to which the image data control system for the image reading system according to this invention has been applied. 
     (III-1) Imaging unit 
     (A) Schematic construction 
     FIG. 31 presents a sectional view of the imaging unit 37, and the original sheet 220 is set with its image surface kept face down on the platen glass, and the imaging unit 37 moves underneath the said platen glass in the direction shown with the arrow mark in the Figure, giving the surface of the original sheet exposure to the light with a daylight fluorescent lamp 222 and a reflecting mirror 223. Then, by causing the light reflected from the original sheet 220 to pass through the selfoc lens 224 and the cyan filter 225, the unit forms an upright image in identical dimensions on the light-receiving surface of the CCD line sensor. The selfoc lens 224 is a compound-eye lens composed of fiber lenses in four rows, and, since this lens has high brightness and high resolving power, it offers advantages in that it permits a reduction of the electric power to be consumed for the light source to a low level and also the fabrication of this unit in a compact size. Moreover, the imaging unit 37 is mounted with a circuit board 227 which carries thereon the CCD line sensor drive circuit, the CCD line sensor output buffer circuit, and so forth. Moreover, 228 indicates the lamp heater, 229 shows the flexible cable for the controlling signals, and 230 represents the flexible cable for the power source for illumination. On the lower part of the housing 37a, on which the CCD line sensor 226 is fixed rigidly, is mounted a circuit board 227, and also a heat radiating plate 250 having a protruding part 250b is installed between the circuit board 227 and the housing 37a. In addition, a punched metal piece 251 for electro-magnetic shielding is mounted in such a way as to cover the heat radiating plate 250. The driving IC chip 252 is arranged on the circuit board 227, and the CCD line sensor 226 is connected electrically to the circuit board 227 by means of the connecting pin 226a. 
     (B) Light source 
     FIG. 31(b) presents a detailed drawing for the daylight fluorescent lamp 222 mentioned above. This drawing shows a reflexive type fluorescent lamp in which a reflecting film 222b is formed on the inside area of the glass tube 222a, except for the area at the aperture angle α (at approximately 50 degrees), and a fluorescent screen 222c is formed on the inner side of the said film. This design feature reflects an attempt at a reduction of the power consumption by the effect of the highly efficient radiation of the amount of light from the fluorescent lamp 222 over the area of the original sheet. In this regard, the reason for the formation of the fluorescent screen 222c on the entire inner area and the formation of the reflecting film 222b on the inside area except the area set at the aperture angle that this structural feature contributes to a reduction of the ratio between the intensity of the bright line and the amount of fluorescent light emitted from the fluorescent material in the distribution of the spectroscopic spectrum of the radiated light since the fluorescent screen absorbs the bright line generated by the mercurial steam although the amount light from this lamp will be smaller in comparison with the type of fluorescent lamp with a fluorescent screen formed on the inner area except the area at the aperture angle (the aperture type). Furthermore, on the outer circumference surface of the fluorescent lamp 222 are provided a lamp heater 228 and a heat sink (heat radiating material) 222d, and these devices perform the control of the lamp heater 228 and the cooling fan on the basis of the detection of the temperature with the thermistor 222e. 
     (C) CCD line sensor 
     FIG. 32 shows an example of the arrangement of the CCD line sensor 226 mentioned above, and, as illustrated in FIG. 32 (a), the five pieces of the CCD line sensors marked 226a through 226e are arranged in a zigzag pattern in the principal scanning direction X. This arrangement of the CCD line sensors has been adopted in view of the fact that it is difficult, by reason of the wafer size, the yield, and the cost, to use a single CCD line sensor to attain any uniform photosensitivity, without suffering any deficiency in proper exposure for a large number of light-receiving elements, and that it is difficult to form the picture elements which will reach the two ends of the CCD line sensors in case a plural number of CCD line sensors are arranged in one line, with the result that any such arrangement would leave illegible areas on the copies. 
     The sensor section of this CCD line sensor 226 is so constructed that three mutually adjacent bits constitute one picture element at the time of reading, with the filters in the three colors, red R, green G, and blue B, being arranged in this stated order and applied repeatedly on the surface of the individual picture elements on the CCD line sensor 226, as illustrated in FIG. 32 (b). Provided that the density of the picture elements for the reading of each color is 16 dots/mm and that the number of the picture elements on each chip is 2,928, then the length of one chip will be: 2,928/(16×3)=61 mm, which will correspond to 61×5=305 mm in length for the five chips as a whole. It follows from this that this construction of picture elements offers an isometric-type CCD line sensor capable of reading the A3-size paper. Additionally, the individual picture elements for R, G, and B are arranged with an inclination by 45 degrees, so that the moire is thereby reduced. 
     In case a plural number of CCD line sensors 226a through 226e are arranged in a zigzag pattern in this manner, mutually adjacent CCD line sensors will perform the scanning operation for mutually different original sheet surfaces. In other words, when the original sheet is read with the CCD line sensors moved in the subsidiary scanning direction Y, which crosses at the right angles with the principal scanning direction X of the CCD line sensors, a deviation in time corresponding to the positional deviation between the mutually adjacent CCD line sensors will occur between the signals from the first row of the CCD line sensors 226b and 226d and the signals which occur subsequently from the second row of the CCD line sensors 226a, 226c, and 226e. 
     Therefore, in order to obtain the consecutive signals for one line from the picture image signals read in divided parts by means of a plural number of the CCD line sensors, it is at least necessary to store in memory the signals from the CCD line sensors 226b and 226d in the first row, which perform the scanning operation in advance of the sensors in the other row, and then to read the said signals in synchronization with the output of the signals from the CCD line sensors 226a, 226c, and 226e in the second row, which work subsequently to those in the first row. In this case, it would be necessary to provide a lag by an amount of time corresponding to four lines, if it is assumed that the amount of deviation is 250 μm and that the degree of resolution is 16 dots/mm. 
     (D) Reduction and enlargement operations 
     Furthermore, the reduction and enlargement with image reading equipment are generally performed by &#34;thinning out&#34; and &#34;watering&#34; and other processes in the video circuit in respect of the principal scanning direction and by increasing or decreasing the moving speed of the imaging unit 37 with regard to the subsidiary scanning direction. That is to say, the degree of resolution is changed only for the subsidiary scanning direction by changing the moving speed of the imaging unit 37 for the image reading equipment, while the reading speed (which means the number of the lines read per unit duration of time) is kept fixed. Therefore, if the resolution is 16 dots/mm at the time when the reduction/enlargement ratio is 100%, the relationship among the relevant factors will be as indicated in the following table: 
     
         ______________________________________                                    
Enlargement/                                                              
            Speed    Resolution                                           
                               zigzag correction                          
reduction ratio (%)                                                       
            Times    Dots/mm   Number of lines                            
______________________________________                                    
 50         2         8        2                                          
100         1        16        4                                          
200         1/2      32        8                                          
400         1/4      64        16                                         
______________________________________                                    
 
    
     Therefore, according as the reduction/enlargement ratio increases, the resolution will increase, and consequently the number of lines needed to correct the difference by 250 μm in the zigzag arrangement mentioned above will also increase. FIG. 33 illustrates the relationship between the reduction/enlargement ratio and the amount of deviation, and a correction by one line is applied by a change of the reduction/enlargement ratio for every occurrence of deviation by one picture element. An amount of deviation by 31 μm occurs for the correction by every one line, but it is not observed that this process gives any influence to the image output therefrom. 
     (III-2) Driving mechanism for imaging unit 
     FIG. 34 shows a diagonal view of the driving mechanism for the imaging unit, and the imaging unit 37 installed, in a manner permitting its free movement, on two sliding shafts 202 and 203 and both ends of the said imaging unit are fixed rigidly on the wires 204 and 205. These wires 204 and 205 are wound around the driving pulleys 206 and 207 and the tension pulleys 208 and 209, with tension being applied to the tension pulleys 208 and 209 in the direction indicated by the arrow mark in the Figure. On the driving shaft 210, on which the driving pulleys 206 and 207 are installed, is installed a speed reduction pulley, which is connected to the output shaft 214 of the stepping motor 213 by way of the timing belt 212. Moreover, the limit switches 215 and 216 are the sensors for detecting the abnormal working of the imaging unit 37, and the registering sensor 217 is the sensor for setting the reference point for the starting position for the reading of the original sheet. 
     The reason for employing the stepping motor 213 for the driving of the imaging unit 37 is as mentioned below. In order to obtain one sheet of color copy in the four colors, R, G, B, and K, it is necessary for the imaging unit to repeat its scanning operation four times. In such a case, it is a major task to find a workable solution to the question how the deviation in synchronization and the deviation in positioning in the course of the four times of the scanning operation can be reduced to a minimum. To accomplish this objective, it is highly important to suppress the deviation in the stopping position of the imaging unit 37, to inhibit the fluctuations in the duration of time for the arrival of the imaging unit from the home position to the registering position, and to find reproducibility in the fluctuation in the scanning speed. However, the use of a DC motor will make it difficult to suppress the deviation in the stopping position of the imaging unit and the fluctuation in the duration of time for the arrival of the imaging unit from the home position to the registering position, and, for this reason, the stepping motor 213 is employed. 
     (III-3) Control system for stepping motor 
     (A) Driving circuit 
     FIG. 35(a) illustrates the driving circuit of the stepping motor 213. The driving circuit is designed to operate by bipolar driving with 10 switching transistors, with the motor winding connected in a hexagonal shape and with its connecting points connected to the positive terminal or the negative terminal of the power source by way of two transistors, respectively. Moreover, the value of the electric current conducted to the motor is fed back, and the motor is driven under such control as to maintain the electric current fed thereto at a constant rate. For the electro-magnetic excitation sequence, the one remaining phase is short-circuited at the same positive or negative potential while the four phases are magnetically excited, as illustrated in FIG. 35(b). 
     (B) Scanning operation 
     FIG. 36(a) shows the scanning cycle of the imaging unit 37 which is driven with the stepping motor 213. The figure shows the relationship between the frequency and the time, which is placed on the speed of the imaging unit 37, i.e. the stepping motor, when the said unit is operated to perform its forward scanning operation and the backward scanning operation at the magnification of 50 percent, i.e. the maximum moving speed. At the time of its acceleration, as illustrated in FIG. 36(b), the frequency 259 Hz, for example, is incrementally multiplied and increased to approximately 11 KHz or 12 KHz in the maximum. By giving regularity to the pulse column in this manner, it is made easy to generate the pulses. And, as shown in FIG. 36 (a), the said imaging unit is given regular stage-by-stage acceleration at 259 pps/3.9 ms, thereby forming a trapezoidal profile. Moreover, a pause is provided between the scanning operation and the returning operation and also between the returning operation and the scanning operation, so that the said unit may wait until the vibrations in the system of the IIT mechanism is reduced and also that the operation of the unit may be set in synchronization with the image output in the IOT. 
     In the meantime, when a color original sheet is to be read, the imaging unit 37 is driven for its performance of the scanning operation four times, so that the said unit may thereby reads the signals on the four colors, and it is consequently a major task to find a satisfactory solution to the question how the color deviation of the four colors can be reduced to an acceptably low level. In order to accomplish this objective, it is important to suppress the deviation in the stopping position of the imaging unit 37, to inhibit the fluctuations in the duration of time for the arrival of the imaging unit from the home position to the registering position, and to find reproducibility in the fluctuation in the scanning speed. 
     (C) Copy adjustment 
     FIG. 37 is a chart intended for explaining the causes of the color deviations arising from the occurrence of the vibrations as mentioned above, and FIG. 37(a) shows the fact that the position where the imaging unit stops after it has performed its scanning operation deviates by Δ L from the original position from which it starts. When the unit starts next, there occurs a deviation in the time which it takes until it reaches the registering position, with the result that there appears a deviation in color. Also, as shown in FIG. 37 (b), the transient vibrations (i.e. the fluctuations of the revolutions that occur before the motor attains its steady-state speed) results in a deviation by Δ t in the time which the unit takes until it reaches the registering position, so that there occurs a deviation in colors on the copy. Also, FIG. 37(c) shows a dispersion of the constant-speed scanning characteristics recorded in the period from the time when the unit passes over the registering position to the time when the said unit reaches the tail edge, and this figure indicates that the dispersion in the scanning speed as recorded at the first time of scanning is greater than the dispersion observed at the second to fourth times of scanning. With this fact being taken into account, the machine is designed to develop the yellow color Y, which is much less conspicuous in case of a color deviation, when it performs the first scanning operation. 
     (III-4) Video signal processing circuit (A) Schematic construction of video signal processing system 
     Next, with reference to FIG. 38, a description is made of the video signal processing circuit, which reads the original sheet in color in the form of the reflexive ratio signals for each of R, G, and B by means of the CCD line sensor 226 and then converts these into density signals in digital values. 
     As shown in FIG. 38, the read data adjusting and converting circuit 232 keeps the analog video signals in the sample hold state and converts the said signals into digital signals after performing the gain control and the offset control on the said signals. This circuit consists of the sample hold circuit 232a, the gain control circuit AGC (AUTOMATIC GAIN CONTROL CIRCUIT) 232b, the AOC (AUTOMATIC OFFSET CONTROL) 232c, and the A/D Conversion Circuit 232d. The white color signals (the signals as read of the white reference plate) by the CCD line sensor and the black color signals (the signals of the dark time output) usually show differences among the individual chips and also among the picture elements in a chip. Supposing that there are differences in output as shown in FIG. 39(a), for example, among Channel 1, Channel 2, Channel 3, and Channel 4, . . . . . . , this circuit is so designed to adjust the maximum value (i.e. the peak value) of the white color signals of each channel to the reference value, which is, for example, &#34;200&#34; in the 256 chromatic grades, in the Gain Control Circuit AGC 232b and to adjust the minimum value of the black color signals, for example, to &#34;10&#34; in the 256 chromatic grades in the Offset Control Circuit AOC 232c. In other words, the offset control circuit AOC (AUTOMATIC OFFSET CONTROL) 232c reduces the the minimum value to the level of the reference value if the said minimum value is any larger than the reference value for the A/D output level, as is the case with Channel 1 shown in FIG. 39(b), but raises the minimum value to the level of the reference value if the said minimum value if any smaller than the reference value of the A/D output level, as is the case with Channel 2 shown in the Figure. 
     The ITG (IIT Timing Generator) 238 is a unit which performs control over the delay amount setting circuit 233 and the separating and synthesizing circuit 232. This generator controls the amount of delay for the zigzag correction in accordance to the contents set in the register by the VCPU 74a and performs the control for the distribution of the color decomposing signals for B, G, and R through adjustment of the output timing of the CCD line sensors for the five channels. The ITG 238 is provided with a register for setting the amount of zigzag correction in correspondence to the magnification value, the register for setting the value for the delay correction in the IPS pipeline, the register for setting the value for the correction of registration in the principal scanning direction, the register for setting the effective width of the picture element, the register for setting the adjusting value for the zigzag correction, the register for setting the adjusting value for the dark time output timing, and so forth. And, at the time when the power is turned ON, &#34;4,&#34; which corresponds to the magnification ratio, 100%, is set in the register, and the zigzag correction value is set at the starting time in proportion to the selected magnification ratio. 
     The delay amount setting circuit 233 corrects the amount of deviation in the installation of the CCD line sensor in the subsidiary scanning direction as illustrated in FIG. 32 and Fig. 33. In other words, this circuit is the so-called zigzag correction circuit. The circuit consists of a line memory device of the FIFO construction, and stores in memory the signals from the CCD line sensors, 226b and 226d, which are positioned in the first row and performs the scanning of the original sheet earlier, and outputs the signals in synchronization with the output of signals from the CCD line sensors, 226a, 226c, and 226e, in the second row, which are set into their action subsequently, and this circuit thus controls the number of the lines to be delayed in accordance with the setting of the amount of delay in proportion to the reduction/enlargement ratio in the ITG 238. 
     The separating and synthesizing circuit 234 is the circuit which separates the eight-bit data line forming the sequence, BGR BGR . . . . . . , in each channel into R, G, and B, and stores them in the line memory, thereafter serially synthesizing and outputting the signals for each channel for R, G, and B, respectively. 
     The conversion table 236 is composed of two table. One is a logarithmic conversion table LUT &#34;1&#34; as shown in FIG. 40(a), which is to be used for the conversion of the reflexion signals into density signals, and, the other is a through conversion table, LUT &#34;0&#34;, and these tables are accommodated, for example, in a ROM. The logarithmic conversion table LUT &#34;1&#34; converts the R, G, B signals representing the reflection factors recorded when the original sheet is read into the R, G, and B signals corresponding to the degrees of density in terms of the amount of the recording material (for example, the amount of the toner). 
     The shading correction sections 235 and 237 are composed of the shading correction circuits 235a and 237a and the SRAMs 235b and 237b and perform the correction for a deviation of the picture elements, the shading correction, the adjustment of the image data input, and so forth. 
     The correction for a deviation of the picture elements consists in a process for working out the weighted mean of the picture elements. As mentioned earlier, the signal processing circuit takes the R, G, and B data in parallel into it, but, as shown in FIG. 39(b), a deviation in the positions of the filters for R, G, and B results in a deviation in the output for R, G, and B in one picture element, as illustrated in FIG. 41(a), and this causes a deviation when a black line K is read into the circuit. In order to overcome this deviation, the weighted mean process is applied to shift the R rightward by 1/3 of a picture element and to shift the B rightward by 2/3 of a picture element, so that the black like K may attain an agreement as illustrated in FIG. 39 (b). For instance, one of the patterns given below is to be selected in a manner appropriate for the R, G, and B signals, as shown in FIG. 41: 
     
         d.sub.n =D.sub.n (No correction is to be made.) 
    
     
         d.sub.n =(D.sub.n-1 +2D.sub.n)/3 
    
     
         d.sub.n =(2D.sub.n-1 +D.sub.n)/3 
    
     where, 
     D n  =the input data in the n-th picture element; and 
     d n  =output data. 
     The shading correction is a process for deducting the image data written in the SRAM as the reference data from the image input data as corrected to compensate for the deviation of the picture elements, and this shading correction is performed in order to rectify the dispersion resulting from the distribution of light from the light source or due to the chronological change of the light source, the scattering caused in the optical system by stains or the like on the reflecting mirror, etc., and the dispersion in sensitivity among the individual bits in the CCD line sensors. The shading correction circuit 235a, which is connected to the front stage of the conversion table 236, performs the correction of the dark time output level (i.e. the level of the dark time output in the duration of time when the fluorescent lamp is turned off), and the shading correcting circuit 537a, which is connected to the rear stage of the conversion table 236, performs the correction for the output from the reading of the white color reference plate. Therefore, the dark time output data and the data on the reading of the white color reference data are written in the respective SRAMs as the reference data 
     (B) Summary description of the working of the video signal processing system 
     Next, an explanation is given with respect to the outline of the working of the circuit along the flow of the image signals. 
     First, the original sheet is read as divided by the CCD line sensors 226 into five channels composed of CH1 through CH5, from each of which the serial signals, RGBRGB . . . . . . , as shown in FIG. 42(a) are sent out. These serial signals are amplified in the pre-amplifying circuit 231 and are thereafter processed for the elimination of noises therefrom in the sample hold circuit SH 232a, being held by the sample hold pulse SHP. These signals thus held are converted into digital signals by the A/D conversion circuit 232d, being subjected to their gain control and offset control as they are led through the gain control circuit AGC 232b and the offset control circuit AOC 232c. Then, the serial digital signals, RGBRGB . . . . . . , are given line synchronization in the individual channels by the operation of the delay amount setting circuit 233, and are then separated into R, G, and B for each channel in the separating and synthesizing circuit 234. Thereafter, the serial digital signals formed by the synthesis of the R in the individual channels and the serial digital signals formed by the synthesis of the G in the individual channels, and the serial digital signals formed by the synthesis of the B in the individual channels are generated and sent out to enter into the shading correction circuit, which performs the processing of the image input data in a manner as appropriate for the mode of operation from time to time. 
     Furthermore, apart from the copy scanning mode described above, this system also offers the color detecting sample scanning mode, in which the system first moves the IIT carriage to the point specified for color detection and writes in the SRAM the density data derived from reading the original sheet. Then, the system takes the data on the specified picture element into the VCPU 74a. This color detecting sequence is now explained in slightly greater detail. In the color detecting sequence, the system issues the WHTREF to the ITG 785, when 50 mS has elapsed after the IIT carriage is moved to the specified point, and then performs the process of writing the data into the SRAM in synchronization with the line sink signal generated by the IPS. Subsequently, with the next line sink signal, IPS-LS, the ITG issues the WHTINT signal, and the data on the picture elements at the specified point are transferred to the RAM of the VCPU 784. The duration of time, 50 mS, mentioned above corresponds to the time elapsed before the IIT carriage stops its vibration and comes to a standstill. This color detecting process covers the five picture elements from the specified point in the principal scanning direction and the five picture elements from the specified point in the subsidiary scanning direction. Therefore, the system reads the data on the picture elements at the specified point and the five subsequent points from the picture element data for one line in the principal scanning direction as written in the SRAM and inputs the data into the RAM of the VCPU 784 and then, moving the IIT carriage four times by one pulse at each time, reads the picture element data on every five points to input them into the said RAM. The processes just described form the procedure to be followed in case one point is specified. It follows from this that the same process will be repeated with each of the specified points in case there are a plural number of specified points. 
     (C) Adjustment of reading data 
     The level of the signal read by the CCD line sensor will be higher in proportion to the reflection factor because light is irradiated on the original sheet from the light source and the signals in the reflected light are read by the said sensor. It is therefore possible to improve the accuracy in reading the original sheet by setting the level of the signals read from the white color reference plate at a value close to 2.5 V in case the input range from 0 to 2.5 V in the A/D conversion circuit is to be converted, for example, into the range from 0 to 255 in eight bits in one byte. Therefore, the level of the signals derived by reading the white color reference plate is to be adjusted through gain control to a level corresponding approximately to 2.0 V, and the signals so obtained are divided into 256 equal portions and converted into digital signals. Yet, as the amount of the light from the fluorescent lamp declines along with its usage, the signals derived from the reading of the same white color reference plate will undergo a gradual decline in their level, which entails a decline in the resolution per one bit. Since the reflection factor of the white color reference plate is approximately 80%, any further increase of this read signal level to a higher level, for example, 2.3 V, would be liable to cause the problem that there occurs a saturation with the bright white color on the original sheet. 
     The gain control AGC is a device which ensures a stable resolving capacity even in such a case as just described, and, in case the level of the signals derived from reading the white color reference plate is set, for example, at 2.0 V, this gain control AGC performs control over the gain in such a way as to keep the gain at this value at all times, setting the optimum gain in any of those chips in which a deviation is found in the sensitivity of the sensor. 
     Moreover, the level of the signals output from the CCD line sensor while the fluorescent lamp remains in the state of being turned OFF (i.e. the dark time output level, or the dark level) will assume the lowest level. This dark level is not flat but shows various types of curves even in one chip, and also present differences in the lowest level among the various chips. Therefore, it is the offset control AOC that guarantees the raising of the lowest value of this dark level to a certain level by the use of an additional lifting base. 
     In the gain control, the data read from the white color reference plate is first written, for example, in the SRAM of the white color shading circuit. Thereafter, the VCPU 74a performs sampling of the read data at the prescribed intervals from this SRAM and finds the maximum value for each chip. Then, the system sets the gain in such a way that this maximum value will be 200, for example, in the prescribed output in 256 chromatic grades. Also, in the offset control, the dark time output is similarly written in the SRAM of the white color shading correction circuit, and thereafter the VCPU 74a performs sampling of the read data from this SRAM at the prescribed intervals of picture element, thereby finding the minimum value for each chip, and sets the offset value in such a way that this minimum value will be 10, for example, in 256 chromatic grades at the prescribed output. 
     However, this alone will not attain any uniformity of the levels among the picture elements and at the ends of the chips, and the image will a rough texture or streaks in the region with high density. The ΔV dark correction is a process for correcting such a dispersion at the dark level in each picture element as the unit, and the white shading correction is a process applied to the correction of a dispersion at the white level in each picture element as the unit. 
     In the ΔV dark correction, the dark time output is written in the SRAM for the white color shading correction circuit, after which the VCPU 74a reads the data from this SRAM, repeating this process four times, and finds the average value of the sum obtained by the addition of the values of the data, thereafter writing the said average value in the SRAM of the dark shading correction circuit. Therefore, at the time of these adjustments, it will be seen that the VCPU 74a has selected and set the through conversion table shown in FIG. 40(b). 
     Furthermore, the system will be ready to shift to the copying operation when it has completed its performance of the gain control, the offset control, and the Δ V dark correction in the manners described hereinabove. In the copying operation, the system selects the logarithmic conversion table, and first, prior to its shift to the copying cycle, it performs the writing of the reference data in the SRAM of the white color shading correction circuit. This is a process whereby the data read from the white color reference plate is written in the SRAM in the state attained through the various adjustments mentioned above and upon the completion of the Δ V dark correction. Therefore, the data so written in this SRAM will be: 
     
         log (D.sub.W -D.sub.D) 
    
     where, D W  =data read from the white color reference plate; and D D  =corrected data as written in the SRAM of the dark shading correction circuit. 
     Therefore, when the white color shading correction circuit finds the difference between the data set in this SRAM and the data read of the original sheet in the actual copying cycle, the following equation is derived since the data read of the original sheet, D X  is first processed for the ΔV dark correction in the dark shading correction circuit: 
     
         log (D.sub.X -D.sub.D)-log (D.sub.W -D.sub.D) 
    
     This is tantamount to saying that, as the result of the dark shading correction circuit and the white color shading correction circuit, the density signal will be subjected to the correcting process shown in the following: 
     
         log (D.sub.X -D.sub.D)-log (D.sub.W -D.sub.D)=log (D.sub.X -D.sub.D)/(D.sub.W -D.sub.D)=log R 
    
     For the reflected signals, the correcting process will be as shown in the following: 
     
         R=(D.sub.X -D.sub.D)/(D.sub.W -D.sub.D) 
    
     Thus, the ΔV dark correction, which performs the correction on the basis of the black color signals, is made of the reflected signals prior to the logarithmic conversion, and the shading correction, which performs the correction on the basis of the white color, is made of the density data after the logarithmic conversion, realizing a reduction of the number of the corrective values and thereby achieving a significant improvement upon the correcting efficiency. Moreover, the adoption of the SRAM for storing the correcting data for one line and the performance of the correcting process through subtraction of the said data have made it possible to employ a general-purpose adder IC, with the result that the arithmetic operations can be performed in a simple way. Accordingly, it is not necessary to set up a hard logic subtractor composed of highly complicated circuits on a large scale as in the conventional system. 
     (III-5) Control system for IIT 
     The IIT remote unit performs the functions of the sequential control for the various types of copying operations, the service support functions, the self-diagnostic functions, and the fail-safe functions. The sequential controls with the IIT are divided among the ordinary scanning, the sample scanning, and the control over the initializing operation. The various types of commands and parameters for the control of the IIT come transmitted by serial communication from the SYS remote unit 71. 
     FIG. 36 (a) shows the timing chart for the ordinary scanning process. The data on the scanning length is set in the range from 0 to 432 mm (by 1 mm step), depending on the length of the paper and the magnification, and the scanning speed is set on the basis of the magnifications (from 50% to 400%), and also the prescanning length (the distance from the stopping position to the registering position) is set on the basis of the magnifications (from 50% to 400%). When the unit receives a scanning command, it turns the fluorescent lamp on by the FL-ON signal and also turns the motor driver on by the SCN-RDY signal and generates the shading correction pulse WHT-REF signal after the elapse of the prescribed duration of time, starting the scanning operation therewith. When the unit passes over the registering sensor, the image area signal, IMG-AREA, comes down to a level lower by the prescribed scanning length, and, in synchronization with this, the IIT-PS signal is output to the IPS. 
     FIG. 36 (b) is a timing chart for the sample scanning operation. The sample scanning process is applied to the detection of color at the time of the color conversion and the correction of the color balance, as well as the correction of the shading, at the time when the F/P is employed. On the basis of the data on the stopping position from the registering position, the moving speed, and the frequency of minute actions, and the step intervals, the unit moves to the target sampling position, where it repeats a temporary stop or minute actions several times and thereafter comes to a halt. 
     FIG. 36 (c) shows the timing chart for the initializing process. When the power source is turned on, the unit receives a command from the SYS remote, and it performs the verification of the registering sensor, the verification of the operations of the imaging unit by the registering sensor, and the correction of the home position of the imaging unit by means of the registering sensor. 
     (III-6) Constructions of individual circuits (Level control circuit for read data 
     The photoelectric conversion characteristics of the CCD line sensor are different from one picture element to another and from one chip to another. Therefore, the output generated even from reading an original sheet with the same density will be different. If such signals are output as they are, streaks or unevenness will appear in the image data. For this reason, it is necessary to perform such correcting or adjusting processes as the gain control, the offset control, the ΔV dark correction, and the shading correction. 
     The gain control circuit AGC 232b and the offset control circuit AOC 234 may be composed, for example, of the voltage control type variable resistor element 242 and the arithmetic operation amplifier 244 as illustrated in FIG. 44. 
     The gain control circuit AGC 232b is a circuit for amplifying the output from each sensor to the volume adequate for the input signal range for the A/D converter 232d, and a voltage control type variable resistor element 242, like an FET element, is to be used for the gain control circuit AGC 232b to control the gate electric voltage V GS , thereby making it possible to make variable the resistance value R 2  between the drain and the source in the element 242. The gain G is expressed by the following: 
     
         G=V.sub.OUT /V.sub.IN =R.sub.2 /(R.sub.1 +R.sub.2) 
    
     This gain is set in the D/A converter 241, which takes it from the VCPU 74b, and the gain is converted into an analog value the D/A converter 241, and the analog value so obtained is applied as the gate voltage V GS  for the voltage control type variable resistor element 242. Thus, when the setting of the D/A converter 241 is to be done with digital values in eight bits, it will be possible to control the gain in 256 stages. 
     In order to control the gain, the white color reference plate is first to be read for one line portion by means of the CCD line sensor prior to the reading of the original sheet, and the value so read is to be converted into a digital value through the A/D converter circuit 232d, and the resulting value is to be stored in the SRAM 237b. Subsequently, the VCPU 74b takes this datum into it and detects the picture element with the maximum value for each channel, and determines the prescribed gain on the basis of its comparison of this maximum value, for example, with 200 in 256 chromatic grades. And, this gain control system sets the gain automatically by setting the digital data adequate for the gain in the A/D converter 241. 
     The offset control circuit AOC 232c is called &#34;black level control&#34; and it a circuit which control the dark time output voltage, and, as illustrated in the Figure, it forms a nonreversal adding circuit by the use of the arithmetic operation amplifier 244. This circuit adds the offset voltage, V OFFSET , to the video signal, V CCD , which is output from the CCD line sensor 226. The output, V OUT  in this offset control circuit AOC 232c will be as shown in the following: 
     
         V.sub.OUT =(R.sub.2 /R.sub.1)V.sub.CCD +V.sub.OFFSET 
    
     Also this offset value, in digital value, is set in the D/A converter 243 by the VCPU 74b, in the same way as the gain value, and the value is then converted into an analog value, which is applied as the offset voltage, V OFFSET , by the arithmetic operation amplifier 244 to the video signal, V CCD . This value, again, makes it possible to adjust the offset in 256 chromatic grades, in the same way as the gain, if the setting of the D/A converter 243 is to be done with an eight-bit digital value. 
     In order to adjust the offset voltage, the dark time output from each CCD line sensor is read for one line, with the fluorescent lamp being turned off, and the output is to be stored in the SRAM 237b after it is converted into a digital value through the A/D converter circuit 232d. Next, the VCPU 74b takes the data into itself and detects the picture element with the minimum value for every channel, and determines the prescribed offset value, comparing this minimum value, for example, with 10 in 256 chromatic grades. And the system automatically sets the offset value for each by setting a digital data commensurate with the offset value in the D/A converter 243. 
     (B) ITG 
     FIG. 45 is a chart illustrating the circuit construction of the ITG (IIT Timing Generator LSI). 
     The ITG shown in FIG. 45 is the LSI for generating such various types of timing, such as the timing for the driving of the CCD line sensor, the timing for the zigzag position adjustment, the separating and synthesizing timing, the signal for the synchronization of the principal scanning and the subsidiary scanning, and the timing for taking the shading data into the system. The sensor driving signal generating circuit 708 is the circuit for generating lateral transfer duration signal CCDLS for the CCD line sensor (TCD-116DC made by Toshiba), the signal for synchronized grounding DARK, and the vertical register shift pulses V1 and V2. The signal for synchronized grounding DARK becomes active in keeping with the output of the light shielding picture element from the CCD line sensor, and the vertical shift pulses V1 and V2 generate a pattern, for example, for the fixed three delay lines for the vertical register in the inside of the CCD line sensor. The zigzag arrangement correcting timing generating circuit 709 is the circuit which generates, for example, the individual signals, read ZRE, write ZWE, reset ZRSTR and ZRSTW for the zigzag position correcting delay amount setting circuit 233 with the FIFO construction. 
     The separating and synthesizing circuit 710 generates the individual signals, write NWE A-C  and reset NRSTW for the separating and synthesizing circuit 234, and the the synthesizing timing generating circuit 712 is the circuit which generates the individual signals, NRE 1-5  and the reset NRSTR, for the separating and synthesizing circuit 234. The page sink generating circuit 702 is the circuit which receives the input of the image area AREA and generates the page sink IITPS as the synchronizing signal. The image area AREA indicates the range for reading by the subsidiary scanning, and this signal treats the output from the CCD line sensor between the active elements as the effective data. Also, the page sink IITPS indicates the effective range of the image data in the subsidiary scanning direction after the correction of the zigzag arrangement. The line sink generating circuit 713 is the circuit which generates the IITLS as a synchronizing signal, the line sink IPSLS which marks a delay in the falling edge of the line synchronizing signal IOTLS, and the total data range LSO after the synthesis. The IOTLS for the line synchronizing signal is the input signal for effecting the synchronization of the IIT and the IOT in the principal scanning direction, and, with the rising edge of this signal serving as the starting point, the operation of the ITG is started and the output signal is formed. The line sink IITLS indicates the effective range of the image data which is output from the IIT. The resetting signal generating circuit 706 in the timing generating counter generates the line synchronizing pulse NSH2 on the basis of the count value of the line synchronizing signal IOTLS. With this pulse, the counter for generating the timing in the inside of the ITG is reset. The reference timing generating circuit 703 generates the white reference WREF, which indicates the position of the white color reference plate, and the shading data writing signal NWW as a signal for indicating the timing for the collection of the shading data, and the WINT, which is the signal indicating the completion of writing. 
     The CPU interface and register 701 contains the interface with the VCPU as well as the various types of controlling registers as mentioned above for setting the operating values for the circuits mentioned above. The register PS-DLY sets the amount of the zigzag adjustment in accordance with the copying magnification and controls the number of shift lines for the IITPS, the NWW, and the NWINT, and the generating cycles of the ZRSTW and ZRSTR. The register, IPS-LS-GEN, sets the count numbers from the falling point of the IOTLS to the NSH2, with which the IITLS is advanced to a point ahead of the IOTLS, thereby correcting the delay of the IPS pipeline. The register, LEG-ADJUST, sets the count number from the NSH2 to the rising point of the IITLS and thereby corrects the error in the installation of the CCD line sensor in the principal scanning direction. The register, LS-SIZE, sets the count number from the NSH2 to the rising point of the IITLS, thereby setting the high level period for the IITLS and setting the effective width of the picture elements in the principal scanning direction. The register, DV-GEN, sets the zigzag correction adjusting value and adjusts the timing of the zigzag correction and the separation with the delay from the time when the transfer clock is sent to the CCD line sensor to the time when the picture element transferred by the said clock enters the zigzag correction circuit. The register, DARK, sets the adjusting value for the timing of the dark output. 
     Each of the registers mentioned above is capable of reading and writing, and the proper register is selected by the chip selecting signal NCS an the address signals A 0  to A 2 , and the data in the D 0  to D 7  are read or written wit the read signal NRD and the write signal NWR. Moreover, the writing of the data is performed upon the falling of the write signal NWR. 
     (C) Shading correction circuit 
     FIG. 46 is a chart illustrating the shading correction section and its circuit construction, and FIG. 46 (a) shows the details of the shading correction section, which is composed of the shading correction circuits 235a and 237a and the conversion table 236, as illustrated in FIG. 38, and FIG. 46(b) shows the internal construction of the shading correction circuits 235a and 237a. 
     In the shading correction process, the dark shading correction (the black color) and the white shading correction (for the white color) are performed, as explained above, and, for this purpose, two shading correction circuits 235a and 237a are employed, and these circuits are connected respectively to the fore and back parts of the conversion table 236. The shading correction circuits 235a and 237a are so designed as to make it possible for the VCPU 74a to read from and to write to the internal registers. Also, the system is so designed to enable the SRAMs 235a and 237b to read from and to write to the VCPU 74a by way of the shading correction circuits 235a and 237a. 
     FIG. 46 shows that the image input data are written once to the SRAM 237b and are thereafter taken into the VCPU 74a in each of the modes, which are the gain control, the offset control, and the Δ V dark correction, as described earlier. Therefore, for writing the image input data to the SRAM 237b, &#34;0&#34; is written to the SRAM 235b in advance from the VCPU 74a through the shading correction circuit 235a, and the conversion table 236 to be selected is the through table, with the image input side being selected for the shading correction circuits 235a and 237a. Then, the shading correction circuit 235a performs arithmetic operations on the input data and &#34;0&#34; of the SRAM 235b with the correcting arithmetic operation circuit. In other words, the shading correction circuit 235a and the conversion table 236 are set at &#34;through&#34;. In the shading correction circuit 237a, the image input data is written to the SRAM 237b. The image data thus written to the SRAM 237b are taken into the VCPU 74a through the shading correction circuit 237a. Then, in the VCPU 74a, the prescribed arithmetic operations as described above are performed to set the gain and the offset and to set the Δ V dark correction value. 
     Furthermore, with regard to the setting of the Δ V dark correction value, the value is written to the SRAM 235b through the shading correction circuit 235a. For this ΔV dark correction process, the four-line portion of the dark time output from the CCD line sensor is taken in its offset-controlled state into the system and the average value of the said output is written to the SRAM 235b. In this case, since the offset value is to be adjusted so as to set it at approximately 10 in 256 chromatic grades, as explained above, also the ΔV dark correction value will assume a value in the range from 10 to 20. Consequently, the dark time output for four lines will have &#34;0&#34; in the most significant bit and the immediately subsequent bit in the case of eight-bit data in 256 chromatic grades. Therefore, the average value is generated by a process for shifting the two least significant bits and the two most significant bits, as stated in the following: ##STR1## 
     Then, this value is written to the SRAM 235b as the ΔV dark correction value. Then, the six lower-order bits (D 5  to D 0  as illustrated above) are used as the ΔV dark correction data while the two most significant bits (D 7  and D 6  as illustrated above) are used as the data indicating the values below the decimal point for use as the address in the conversion table 236. The control of this process is performed by the bus control circuit, which takes the relevant data from the VCPU 74a and writes them in the form of eight-bit data to the SRAM 235b, and, in the ΔV dark correction process, the bus control circuit reads out the six lower-order bits to the shading correction circuit 235a, so that arithmetic operations for the correction may be performed therewith in the correction arithmetic operation circuit to perform the subtraction (A-B) from the image input data and also performing a logarithmic conversion with the conversion table 236 by applying the output from the said arithmetic operation circuit, as well as the two most significant bits, to the said conversion. 
     When the system enters into the copying mode after the completion of the gain control, the offset control, and the ΔV dark correction, the logarithmic conversion curve is selected on the conversion table 236, and, at this point, shading correction is performed on the image input data as read from the white color reference plate and the original sheet, and also the process for the conversion of the reflected signals into the density signals is performed. In this process, the ΔV dark correction value is subtracted in the shading correction circuit 235a from the image input data read from the white color reference plate, and, the value so obtained is converted into the density signal with the conversion table 236. And, this density signal is written as the white correction value to the SRAM 737b through the shading correction circuit 237a. 
     Subsequently, the ΔV dark correction value is subtracted in the shading correction circuit 235a from the image input data obtained by reading the original sheet, and the value so derived is converted into the density signal with the conversion table 236, and then the white correction value is subtracted from the said density signal and the resulting value is output to the IPS as the image output data. 
     In this regard, the logarithmic conversion curve presents a larger variation in the output value Y in the region where the input value X is small, as shown in FIG. 40(a). For this reason, in case the input value remains in the 256 chromatic grades in this region, even with a change in the input value by one chromatic grade, for example, from 11 to 12, the output value will change by several chromatic grades. That is to say, in the region with a high degree of density after the logarithmic conversion, it will not be possible to obtain the image data by one chromatic grade, with the result that the resolution for the chromatic gradation in the high-density region will be deteriorated remarkably. Therefore, in order that such a deterioration of the resolution for the chromatic gradation may be prevented, the data below the decimal point in the value for the ΔV dark correction as written in the SRAM 235b are used as the reading address in the conversion table 236. If the data below the decimal point are not employed as the data of the ΔV dark correction, a change by the several chromatic grades mentioned above will occur to affect the entire area in the high-density region of one line corresponding to one datum in the ΔV dark correction on the screen in the subsidiary scanning direction, producing an image hard to read by the effect of the conspicuousness of the streaks running in the subsidiary scanning direction. 
     The LSIs in the shading correction circuits 235a and 237a are composed of the correction circuit for the deviation of the picture element, the addition circuit 722 for density adjustment 722, the subtraction circuit 723 for the shading correction, the registers 729 through 731 in which various kinds of information are set by the VCPU 74a, the bi-directional bus drivers 726 and 732, the selectors 724, 725, 728, and 733, the address decoder 732, the address counter 734, and so forth, as illustrated in FIG. 47, and these component units perform their respective processes as explained above in accordance with the particulars of contents set in the registers 729 through 731. The NPD prohibits the input of the video clock VCLK and reduces the consumption of power at the time when the picture image is not being processed. Yet, even when this unit is in its active state, it is possible for the VCPU to perform the reading/writing operations addressed to the registers in the LSI and to the SRAM externally connected to the system. 
     The register 729 is set with the set-up bit NSU, the selection bits RBSEL and GSEL for the correction of the deviation of the picture elements, and the DIAG. bit DIAG. The set-up bit NSU puts the VCPU 74a into its active state when the VCPU 74a performs its reading and writing operations addressed to the SRAM externally connected to the system while the said bit turns the VCPU 74a into its inactive state when the operation is finished. The selection bits RBSEL and GSEL for the correction of the picture elements select either one of the correction equations explained above and given below: 
     
         d.sub.n =D.sub.n 
    
     
         d.sub.n =(d.sub.n-1 +2D.sub.n)/3 
    
     
         d.sub.n =(2D.sub.n-1 +D.sub.n)/3 
    
     The DIAG bit DIAG, when put into its active state, outputs the contents of the externally connected SRAM as they are for use as the image output data. Therefore, these set values work as the input into the circuit for the correction of the deviation of the picture elements 721 and the selectors 724 and 721. The register 730 sets the desity adjusting value, which adds a certain constant value to the image input data, and is used as the input into the addition circuit 722. The register 731 sets the preset address in the internal address counter 734. 
     (D) Arrangement of Pins in LSI 
     FIG. 48 is a chart illustrating an example of the arrangement of the connecting pins in the LSI. 
     The connecting pins in the LSI are arranged in the upper, lower, left-side, and right-side positions as illustrated in FIG. 48, and these pins are put together in groups in such a way that greater ease can be secured in the layout and the wiring to be done on the occasion when the LSI is actually mounted on the printed circuit board. Namely, in the example shown in the Figure, which is to be used for the shading correction, the pins related to the output of the image data are positioned on the right side, and the pins related to the interface with the SRAM are position on the upper side, the pins related to the interface with the CPU are arranged on the left side and lower side, and the pins for the input of the image data are positioned on the right side. In the shading correction circuit, there are the mode in which the image input data are written to the SRAM as mentioned above and the mode in which the image input data and the data written to the SRAM are processed by arithmetic operations and output therefrom. For these operating modes, the LSI is so constructed that the controlling information is supplied from the left side while the image data flow from the lower side to the upper side, and from the lower side and the upper side to the right side. Moreover, it is also acceptable to have the image data flow from the left side to the right side, in correspondence to FIG. 46, with the pins related to the input of the image data being arranged on the left side, the pins related to the output being arranged on the right side, the pins related to the SRAM being arranged on the lower side and the pins related to the control, such as those for the CPU interface, being arranged on the upper side. Thus, the unification of the arrangement of the pins for each LSI in groups makes it possible to increase the density of the actual installations and also to achieve a neater wire arrangement and a shorter wiring length to attain a reduction of noise troubles. 
     (III-7) Image data adjusting process 
     FIG. 48 is a chart for explaining the overall flow of the image data level adjusting process, and FIG. 49 is a chart for illustrating the flows of the individual sub-routines. 
     First, the overall flow of the image data adjusting process, which is performed in advance of the copying operation, is explained with reference to FIG. 48. 
     (1) The power is turned ON, and then the initializing process, the warming up of the fluorescent lamp (LTC; the lamp temperature control ready) are performed. Thereafter, 
     (2) The AGC adjusting process in the platen mode is performed. Subsequently, 
     (3) The AOC adjusting process is executed, and 
     (4) ΔV dark correction process is executed. Next, 
     (5) It is checked whether the system is in the platen mode or in the F/P mode, and 
     (6) If the system is in the platen mode, then the copying operation is executed with the operation of the start key, and the operation returns to the process described in (5). 
     (7) In case the system is in the F/P mode, the operation depends on the point whether or not the AGC adjusting process, the AOC adjusting process, and the ΔV dark correction process are to be done for the first time in the F/P mode in the sequence of operations from the operation for turning the power ON. 
     (8) If for the first time, 
     (9), (10) The AGC adjusting process for the F/P mode is executed. 
     (11) The shading data are collected. Then, 
     (12), (13) The AOC adjusting process, the ΔV dark correction process are performed. Next, 
     (14) It is checked whether the system is in the platen mode or in the F/P mode, and, in case it is in the platen mode, the operation returns to the process described in (5), but, if in the F/P mode, 
     (15) to (17) The A/E scanning process is performed and, with the changeover thereby made of the individual set values for the gain, the offset, and the ΔV dark correction, the copying operation is performed. Then, the operation returns to the process mentioned in (13). 
     Next, the details of the individual processes are explained. First, the AGC adjusting process and the AOC adjusting process in the platen mode are respectively explained with reference to FIG. 49(a). 
     (1) First, the fluorescent lamp is turned ON, and the sensor enable is turned ON, and the conversion table 236 is set at &#34;through&#34; and the imaging unit is set in its home position. Furthermore, the shading correction circuit 235a for the dark time output and the shading correction circuit 237a for the white color data are initialized for the VCPU access mode, and the SRAM 235b for the dark time output is thereby cleared. 
     (2) A non-volatile value is loaded into the AOC(i) for the channel i as the platen offset value, which is then set in the D/A converter for the AOC. Here, the non-volatile value is the value set at the previous time in the operation. 
     (3) The non-volatile value is loaded as the platen gain into the ga(i), and 200 is set in the target value X 0  (i) for the AGC, 200 in X(i), and 1 is set in i 0  (starting with Channel 1). That is to say, the target value for the time when the white color reference plate is to be 200 in 256 chromatic grades. 
     (4) The AGC converging flow is executed. 
     This AGC converging flow is executed by first setting the loop counter n at 0, and arithmetic operations with the following equations are performed: ##EQU1## 
     Moreover, the operations are limited in such a way that the following expression will hold: 
     
         0&lt;AGC(i)&lt;255 
    
     The value of AGC(i) obtained from the equations given above is set in the D/A register in Channel i as the adjusting value for the gain. 
     The processes mentioned above are performed up to Channel 5. 
     With the data collecting flow set at [Max], the measured value (the collected value) X(i) is to be found. 
     Next, a judgment is made of: 
     
         0.98×X.sub.0 (i)&lt;X(i)&lt;1.02×X.sub.0 (i) 
    
     In specific terms, it is to be judged whether or not the measured value X(i) comes into the range of ±1% or less (200±2) of the target value X 0  (i). If the answer is YES (passed), the operation moves on to the subsequent process. If NO, the loop counter n is incremented, and the equations given above are again applied repeatedly with a new measured value X(i). 
     The application of the equations given above usually lead to a convergence after the repetition of the process four to five times (n=4 or 5), and, if not passable even after the application of the equations ten times in the maximum, it is to be judged that the measured value should be processed as a fault, and the channel is to be stored in the memory device. 
     Here, the approximating equations for the gain characteristics shown in FIG. 49(e) are the relational equations for the ga and the AGC mentioned above. In FIG. 49(e), the horizontal axis AGC represents the input values (the adjusting values for the gain) in the D/A converter 241 illustrated in FIG. 44, and the vertical axis ga represents the gain developed in the gain control circuit 232b in correspondence to the input value. On the basis of such a relation between the input value and the gain as what has just been described, the efficiency of the converging process is improved by modifying the error in terms of a deviation from the reference value by the process described above. Accordingly, it goes without saying that the modified value AGC(i) may be derived from the LUT instead of the approximating equations given above. In such a case, the target value is actually set at 200, and the converging process is to be performed in its proximity, and consequently it is enough to form the LUT not in the entire range but in a certain range. 
     (5) The value determined by ga(i) (0.2&lt;ga&lt;1.0) is saved as a platen gain in eight bits in a non-volatile form, with which the non-volatile value of each of the channels (i=1 to 5) is renewed. 
     (6) Then, the fluorescent lamp is turned OFF, and X 0  and X(i) are set at 10. 
     (7) The The AOC converging flow is executed. 
     For the execution of the AOC converging flow, the first step is to set the loop counter n at 0, as shown in FIG. 49(f), and then the arithmetic operations are performed with the following equation: 
     
         AOC(i)=4.8×(X(i)-X.sub.0)+AOC(i) 
    
     Moreover, the operation is to be limited in such a way that the result will be in conformity with the following equation: 
     
         0&lt;AOC(i)&lt;255 
    
     The value found for the AOC(i) by the equation given above is set in the D/A register for Channel i. 
     The process described above is to be performed up to Channel 5. 
     The data collecting flow is set at [Min], and the measured value X(i) is to be found. 
     Next, a judgment is given with (X 0  -2)&lt;X(i)&lt;(X 0  +2). 
     In specific terms, it is to be judged whether or not the measured value X(i) is in the range of ±1 or less (10±1). If the result is YES (Passed), the operation is to move on to the next process, but, if the answer is NO, the loop counter n is to be incremented, and the equation given above is applied repeatedly with a new measured value, X(i). The application of the equation given above ordinarily results in a convergence by its repetition two to three times (n=2 or 3), and, in case no passable result is achieved even after the repetition of the application of this equation up to eight times, it is to be judged that the result is abnormal, and the operation is to be treated as a fault, the channel being so indicated. 
     (8) The AOC is to be saved as the platen offset in the non-volatile form of memory, and the non-volatile value for each of the individual channels (i=1 to 5) is to be renewed. 
     (9) The ΔV dark correction routine given below is executed. 
     First, as shown in FIG. 49(b), the loop counter n is set at 0, and a demand is issued for the WHT-REF. 
     Next, the picture element data d lm  on the SRAM-l for the white color is transferred to the FP memory (D lk ) in the CPU within the range determined by the following equation: 
     l=1 to 3 (1:R, 2:G, 3:B) 
     m=15 to 4894 
     k=0 to 4879 
     (In the F/P mode, however, 
     m=991+α to 3870+α 
     k=0 to 2879) 
     With D lk  =d lm  assumed for the initial n=0, and with D lk  =D lk  +d lm  assumed for any n-value subsequent to n=1, the picture element data d lm  are kept added up. In this process, when the D lk  attains any value upward of 128, it is processed as a fault, indicating the value of l and the channel number. 
     The same process is performed four times, i.e. for four lines, while incrementing the loop counter n. 
     Next, the bit shift process is made from D lk  =D 7  D 6  D 5  D 4  D 3  D 2  D 1  D 0  to D lk  =D 1  D 0  D 7  D 6  D 5  D 4  D 3  D 2  within the range determined by the following equation: 
     l=1 to 3 (1:R, 2:G, 3:B) 
     m=7 to 4886 
     k=0 to 4879 
     (In the F/P mode, however, 
     when j=1, 
     m=983+α to 3862+α 
     when j=2, 3, 
     m 1  to m 2  ; m 2  -m 1  =2880 
     k=0 to 2879) 
     Additionally, the data D lk  on the F/P memory in the CPU is transferred to the address m in the SRAM-l for the dark time output correction (when j=1) or to the address m in the SRAM-l for the F/P dark time output j. 
     (10) With the sensor enable being turned OFF and with the conversion tables being respectively set in the log, and further with the dark shading correction circuit 235a and the white shading correction circuit 237a being initialized for the image data input side, the setup of the system is made for the copying operations. 
     Then, the copying operations are performed. 
     Next, the data collection flow is explained with reference to FIG. 49(g). 
     (1) and (2) First, the WHT-REF output demand is issued, and, upon reception of the WHT-REF, it is judged whether the received reference represents &#34;Ave&#34;, &#34;Max&#34;, or &#34;Min&#34;. 
     (3) and (4) In case of &#34;Ave&#34;, an access is made to the SRAM for the white color for B (Blue), and n 1  =706, n 2  =2, and n 3  =706 are set. 
     (5) and (6) In case of &#34;Max&#34; or &#34;Min&#34;, an access is made to the SRAM for the white color for G (Green), and n 1  =976, n 2  =16, and n 3  =-968 are set. 
     (7) The picture element data in the address n 1  ×Xi+n 2  ×l+n 3  (i=1 to 5, l=1 to 61) are transferred to the CPU. 
     (8) through (11) In case of &#34;Ave&#34;, an average value is found for l=1 through 61 with respect to the picture element data in Channel i, and the average value is set as X(i), and, in the case of &#34;Max&#34;, the maximum value is found of l=1 through 61 with respect to the picture element data for Channel i, and the maximum value so identified is set as X(i), and, in the case of &#34;Min&#34;, the minimum value is found of l=1 through 61 with respect to the picture element data in Channel i, and the minimum value is set as X(i). 
     Then, with reference to FIG. 49(h), as description is made of the processing in the E/P mode. 
     (1) First, a non-volatile value is loaded in the LV&#39;, and it is set at the electric voltage for the halogen lamp, and the correcting filter for the positive film is selected. The imaging unit is moved to the center of the projection area, and the halogen lamp for the F/P is turned ON, and the sensor enable is also turned ON. In addition, the dark shading correction circuit 235a and the white shading correction circuit 237a are initialized for the CPU access mode, and the SRAM 235b on the dark time output side is cleared, and &#34;through&#34; is selected on the conversion table. 
     (2) A non-volatile value is loaded as the F/P offset 1 in the AOC(i) in Channel i, and the value is set in the D/A converter for the AOC. 
     (3) A non-volatile value is loaded as the F/P gain 1 in the ga (i), and 200 is set in the target value X 0  (i) of the AGC, 200 in X(i), and 2 in the i 0  (executed in Channels 2 through 5). 
     (4) The AGC converging flow is executed. Moreover, &#34;Max&#34; should be selected for the data collecting flow. 
     (5) ga(i) (0.2&lt;ga &lt;1.0) is taken in eight bits as the F/P gain 1 and saved in the non-volatile form of memory, therewith renewing the non-volatile value of each channel. 
     (6) Next, the AGC(i) is stored in the table in the RAM for the F/P AGC 1 as the back-up for switching of the gain. 
     (7) The halogen lamp voltage LV&#39; is set at LV&#39;=LV 0  ×0.875, and wait for five minutes. 
     (8) The data collecting flow at &#34;Ave&#34; is executed (i 0  =2). 
     (9) X 0  (i)=X(i) is established. 
     (10) A non-volatile value is loaded in the AOC (i) for Channel 1 as the F/P offset j (j=2, 3), and the value is set in the D/A converter for use for the AOC. 
     (11) A non-volatile value is loaded as the F/P gain j in the ga (i), and the following is set therein: 
     
         X.sub.0 (i)=(X.sub.0 (i)-10)×1.41+10 
    
     
         X.sub.0 (i)=X.sub.0 (i) 
    
     
         i.sub.0 =2 
    
     In other words, the value 1.41 times (in case j=2) as much as the average level of the A/D input signal generated when the electric voltage for the lamp is reduced to LV&#39;=LV 0  ×0.875 and the higher value at a level 1.41 times (in case j=2) as much as the value just cited are to be taken as the target values. 
     (12) The AGC converging flow is executed. At this jucture, &#34;Ave&#34; is selected for the data collecting flow. 
     (13) ga(i) (0.2&lt;ga&lt;1.0) is saved as the F/P gain j in the non-volatile form of memory, and the non-volatile value for each channel is renewed therewith. 
     (14) Next, the AGC(i) is stored in the table in the RAM for the F/P AGC j as the backup for the switching of the gain. 
     (15) The halogen lamp voltage LV&#39;=LV 0  is set, and wait for 0.5 minute. Moreover, the conversion table is set in the log, and the F/P AGC 1 being loaded in the AGC(i) and set in the D/A converter for the AGC, and the F/P offset 1 is loaded in the AOC(i) and set in the D/A converter for the AOC. 
     (16) The shading sub-routines mentioned below are executed. 
     First, the imaging unit is moved to a point positioned approximately in the center of the projection area, as illustrated in FIGS. 49(i) and 49(j), and the shading area in the RAM of the CPU is cleared. 
     Next, sample scanning is performed, and the result is transferred to the CPU, with the data R ij  for the address 990+α+i in the SRAM for the white for R (Red) being used as the address. Next, it is checked whether or not the R ij  -R STD  &gt;50 holds, and, in the case of &#34;YES&#34;, R STD  =R ij  +50 is established, and R ij  is added to the i-th address for R in the shading area of the RAM in the CPU. This arithmetic operation is conducted from 1 up to 2880. The same process is performed with respect to G and B, and this operation is conducted up to j=1 to 32. 
     The data at the i-th address for R in the shading area in the RAM of the VCPU are divided by 32, and, with the addition of 32 thereto, the value Ri so obtained is stored at the same address. And, in case the value does not satisfy the condition, 990+α+i&lt;1800, or the condition, 990+α+i&gt;4250, it is examined whether or not R i  -R STD  &gt;72 holds, on the basis of which it is judged if there is any fault in the shading process. The same process is performed on G and B. 
     (17) The halogen lamp is turned OFF, the conversion table is selected for the use of &#34;through&#34;, and the imaging unit is moved to its home position, and the sensor enable is turned ON. 
     (18) The F/P AGC j is loaded from the table in the RAM to the AGC(i), and the value is set in the D/A converter for the AGC. Then, the F/P offset j is loaded in the AOC(i), and it is set in the D/A converter for the AOC. 
     (19) The off, X 0 , and X(i) are set at 10. 
     (20) The AOC converging flow is executed. 
     (21) The AOC(i) is saved in the non-volatile area of the memory as the F/P offset j, with which the non-volatile value in each channel (i=1 to 5) is renewed. 
     (22) The ΔV dark correction routine given below is executed. 
     (23) The set-up of the copying operation is performed. 
     Next, an example of the processing flow by the adaptive type multiplying and dividing calculation method, which brings into convergence through alteration of the setting by the use of a coefficient in accordance with the difference from the target value, without the use of any approximating equation, is explained, as another example of embodiment of the AGC converging flow, with reference to FIG. 49(k). 
     (1) and (2) First, with X 0  =200 established, the AGC set value is loaded from the non-volatile part of the memory. 
     (3) The AGC for Channel i is set. 
     (4) The data collecting flow is executed, and X(i) is found. 
     (5) It is examined whether or not X&gt;0.98 X 0  holds. 
     (6) through (10) In the case of NO, it is further examined whether X&gt;0.9 X 0  or X&gt;0.8 X 0  holds. In case X&gt;0.9 X 0  holds, then the setting is changed to: 
     
         AGC(i)=0.97×AGC(i) 
    
     And, in case 0.9 X 0  ≧X&gt;0.8 X 0  holds, then the setting is changed to: 
     
         AGC(i)=0.9×AGC(i) 
    
     And, in case 0.8 X 0  ≧X holds, then the setting is changed to: 
     
         AGC(i)=0.7×AGC(i) 
    
     (11) through (17) In case the judging process in (5) mentioned above yields YES, it is further examined which of X&lt;1.02 X 0  or X&lt;1.1 X 0  or X&lt;1.2 X 0  holds, and in case X&lt;1.02 X 0 , it is passed. And, in case 1.02 X 0  ≦X&lt;1.1 X 0  holds, then the setting is changed to: 
     
         AGC(i)=1.03×AGC(i) 
    
     In case 1.1 X 0  ≦X&lt;1.2 X 0  holds, the setting is changed to: 
     
         AGC(i)=1.1×AGC(i) 
    
     And, in case 1.2 X 0  ≦X holds, then the setting is changed to: 
     
         AGC(i)=1.3×AGC(i) 
    
     The processes described in (5) through (17) above are executed up to five channels, excluding the channels which have already produced convergence. When all the channels are found passable, these processes are finished. 
     As described so far, the present invention is characterized by the point that it proposes the performance of the gain control first, subsequently the offset control, and then the ΔV dark correction. This is due to the fact that the gain control is a type of control over the reading range as seen on the basis of the white color level, whereas the offset control is a type of control of the black color level. That is to say, this design feature is founded on the finding that the fluctuations in the black color level is more liable to their appearance in the form of inconsistent degrees of density or streaks on the reproduced image and hence more conspicuous in terms of their influence in the case of those image recording equipments which reproduces the images by the density signals. For example, if the process in (2) and that in (3) are reversed in the operations illustrated in FIG. 48, the gain control process will be performed before the offset control process, and this will cause fluctuations in the offset control. However, these processes as performed in the sequence shown in FIG. 48 would give little influence on the image in the region just mentioned even if fluctuations occur in the level of the white color, which is taken as the basis for the control of the gain.