DE3802736A1 - Image generating device (picture generating device) - Google Patents

Abstract

A copier can be operated in two modes of operation, that is to say "chromatic" and "monochromatic". When copying in the mode "monochromatic" the colour signals received from the original are converted into structured monochromatic signals so that all colours can be unambiguously represented even though printed in only one colour, for example blue as horizontal lines, green as oblique lines, yellow as intersecting lines, red as vertical lines, etc. <IMAGE>

Description

The invention relates to an image forming device that generates color images.

Color copiers are already known, but they are not yet generally accepted due to its high price to have.

If colored pie charts or other colored drawings, Diagrams etc. of templates with a black and white copier are copied, the copies appear with originals that have approximately the same brightness values, practically as monochrome. Colored parts of the template can be therefore difficult to recognize on the copy.

It is an object of the invention to provide an image forming device to create the color differences recognizable even then reproduces when the colored originals are copied in one color will.  

The features of the claim serve to solve this problem 1.

The image generation device according to the invention thus has Means for reading a colored template and owns first converting means to convert the color information from the Reading media in a number of different patterns implement, each of a specific color of the Color image matches the template. There are also means for optical displays of monochromatic structured images provided that correspond to the different patterns that come from the converting agent.

The invention is explained in more detail below with reference to figures explained; show it

Figure 1A is a color pie chart on a template.

FIG. 1B shows a structured pie chart copy of the template from FIG. 1A using the image generation device according to the invention; FIG.

Fig. 2 is a partially broken perspective view of the image forming apparatus;

Fig. 3 is a perspective view of the image forming apparatus;

Fig. 4 is a schematic side view of the document scanner of the device;

Figure 5 is a perspective view of the scanner as it moves along a template;

Fig. 6 is a schematic longitudinal sectional view of the copying machine;

Fig. 7 is a perspective view of a transfer operation;

Fig. 8A is a top view of a thermal ink transfer ribbon used in the transfer process of Fig. 7;

Fig. 8B is a top view of a black thermal ink transfer ribbon used in the transfer process of Fig. 7;

Fig. 9 is a plan view of the control panel of the copying machine;

Fig. 10 is a schematic block diagram of the control system of the copying machine;

Figure 11 is a detailed block diagram of a color signal converter of the control system of Figure 10;

Fig. 12 is a detailed block diagram of a digitizing circuit of the control system of FIG. 10 and

Fig. 13 is a flowchart of part of the operation of the image forming apparatus of the invention.

The invention is explained in more detail using an example, on a copier with thermal ink transfer relates.  

By selecting a first or a second operating mode, the device can copy either in color or in single color with color structuring. In the first mode of operation, colored originals are copied in full color, using a thermal ink transfer belt with four colored ink sections. In the second operating mode, a colored template, for example a colored pie chart according to FIG. 1A, is reproduced as a monochrome structured image, for which purpose a thermal transfer belt is used which has only one color area. The monochrome structured image has a number of structured images, each of which is assigned to a specific color. For example, black is used as the copy color of the copy of Fig. 1B. This makes it possible to differentiate between the different shades of color even when using only one color.

For this one-color structured color copying can for example, monochrome structured color displays can be used, as for example in the registration regulations are defined for U.S. patent applications.

Figs. 2 and 3 show a copying apparatus having a housing 1, on its front a surface 1 a is provided that contains the control panel. A scanning device 8 is arranged in the left part of the housing 1 as shown in FIG. 2 in order to scan an original document placed on a document table 7 . An image generating device 9 is provided in the right part of the housing 1 . A lid 10 is attached to the table 7 and can be opened and connected in the usual way.

The scanning device 8 is arranged according to FIGS. 4 and 5. The original table 7 is attached to the housing 1 . A scanner 11 is arranged under the table 7 and is moved back and forth in the direction of arrow a along the underside of the table 7 in order to scan an original document O placed on the table 7 . The scanner 11 thus reads an image present on an original O. It has a lamp 12 for illuminating the original O , a photoelectric converter 13 for receiving the light reflected from the original O , an optical system 14 for guiding the light reflected from the original O to the converter 13 and a carriage 15 for carrying the lamp 2 .

The converter 13 converts the light reflected from the original O into electrical signals. The image of the original O is divided into primary color signals, ie cyan, green and yellow (or red, green and blue) color signals. The converter 13 is usually a CCD line image sensor.

Referring to FIG. 5, the carriage 15 by a guide rail 16 and a guide shaft and brought hither in the direction of the arrow a back 17th A drive roller 19 is driven by a reversible scanning motor 18 (e.g. a stepping motor) and sits at one end of the guide rod 17 , while a deflection roller 20 is arranged near the other end of the guide rod 17 . A timing belt 21 runs around the pulleys 19 and 20 . At one point, the belt 21 is connected to the carriage 15 via a fastening element 22 . Thus, when the scanning motor 18 rotates forward or backward, the carriage 15 is moved in a straight line.

The image generation unit 9 is arranged according to FIG. 6. A printing cylinder 30 is located substantially in the middle of the image forming device 9 . A thermal head 31 is arranged to the left of the printing cylinder 30 . The thermal head 31 sits on a radiator 33 and is integrally formed on the rear wall surface of a holder 32 . An ink cartridge 35 , which contains a thermal ink transfer belt 34 as an image-forming agent, is detachably loaded via the holder 32 . The ink ribbon 34 lies between the head 31 and the printing cylinder 30 .

Referring to FIG. 6, a tape cassette 36, and 37 to 35 two parallel coils. The ribbon 34 is housed in a housing 38 so that both ends of the ribbon 34 are wound around the spools 36 and 37 and the part in between is exposed between the printing cylinder 30 and the thermal head 31 . The coils 36 and 37 can be coupled to a drive shaft of a motor, not shown, via a drive mechanism, not shown, when a cassette 35 is inserted into the copying machine 9 , after which it can be rotated as required. According to FIG. 2, an ink ribbon cassette can be replaced 35 through an opening 39 in the right side wall of the housing 1. A door 40 closes the opening 39 .

A paper feed roller 41 is arranged on the right below the printing cylinder 30 to feed sheets P present in the paper cassette 42 one by one. The sheet P picked up by the roller 41 is supplied to register rollers 43 which are disposed right above the supply roller. The front end of the sheet P is aligned by the alignment rollers 43 . It is then passed from these rollers to the pressure cylinder 30 and pressed on by pressure rollers 44 and 45 . In this way, the sheet P can be fed accurately. The paper cassette 42 is detachably mounted in the front of the housing 1 . With 46 6, a feeding by hand is in Fig. Designated with which an operator can carry out a single sheet.

The thermal head 31 presses the sheet P onto the impression cylinder 30 through the thermal ink transfer belt 34, and is designed to heat and melt the ink 47 on the ink ribbon 34 to transfer melted ink to the sheet P as shown in FIG . In the ink ribbon 34 , yellow, magenta, cyan and black areas 47 Y , 47 M , 47 C and 47 B are arranged one behind the other according to FIG. 8A. Each of these areas has a length that is substantially the same as the width of the sheet P. The head 31 transfers each color to the sheet P and this is returned to the starting position so that the colors overlap exactly 1: 1. The ribbon 34 needs to have 47 B no black section. If you print yellow, magenta and cyan on top of each other, you get black.

In a first operating state, which is referred to as full-color copying, the color areas 47 Y , 47 M , 47 C and 47 B of the color image 34 are used to form a full-color image.

In color copying, the sheet P is repeatedly moved over several revolutions of the printing cylinder, depending on the number of colors. The sheet P is guided between the first and second guide plates 49 and 50 , which are arranged one behind the other along the underside of an output tray 48 which is inclined at an angle to the housing 1 . A selective feeding of the sheet 5 is effected by selection gates 51 and 52 which are arranged between the impression cylinder 30 and the first guide plate 49 and between the impression cylinder 30 and the second guide plate 50 . In particular, a sheet P removed from the paper cassette 42 is passed through alignment rollers 53 and through the first selection gate 51 . After the leading edge of the sheet P is wound around the impression cylinder 30 , the impression cylinder 30 is rotated in the forward direction by a stepping motor, not shown. Sheet P is fed at a constant speed. At the same time, heating elements (not shown) of the thermal head 31 , which are aligned with the axial extent of the printing cylinder 30 , are selectively heated in accordance with a printing command, and ink 41 is transferred from the ink ribbon 34 to the sheet P. The leading edge of the sheet P is guided after the circulation with the impression cylinder 30 to the first guide plate 49 , which is arranged on the underside of the output tray 48 ; for this purpose a selection gate 52 is used , the position of which is shown fully drawn out in FIG. 6. When ink 47 has been transferred to sheet P , impression cylinder 30 is rotated in the opposite direction, referred to as "backward". In the reverse direction, the sheet P is fed and moved back to the transfer home position. The rear end of the sheet P points in the direction of the second guide plate 50 , which is arranged along the underside of the first guide plate 49 , namely through a first drop gate 51 which is pivoted in a direction which is indicated by dashed lines in FIG. 6. In this way, the sheet P is repeatedly reciprocated to pick up different colors. When all the colors 47 have been transferred to the sheet P , it is passed to discharge rollers, specifically through the second selection gate 52 , which is brought into the position shown in broken lines in FIG. 6 for this purpose. The sheet P is finally discharged onto the discharge tray 48 through the discharge rollers 53 .

In order to form an image with a black thermal color transfer belt 34 B , which only has a black color area 47 B according to FIG. 8B, ie in order to produce monochrome structured color images, the transfer cycle is limited to one cycle and there is no reciprocation of the Sheet P. After a transfer cycle, the sheet P is thus discharged onto the output tray 48 .

Fig. 9 shows the operator panel 2. The field 2 has a status selection button 61 in order to select either the first operating status (full color copying) or the second operating status (single color structured color copying). A digital keypad 63 is used to enter the sheets to be copied. A delete button 64 deletes the number of copies, a push button 65 triggers the copying process, a sheet display 66 shows the number of copies and a graphic display 67 shows the operating state.

Fig. 10 shows the entire control system for the copying machine. It has a main control 81 and first and second auxiliary controls 82 and 83 . The main controller 81 is connected to the operator panel 2 , to a correction circuit 84 , to a brightness / color difference signal separator 85 , to an image quality improvement circuit 86 , to a chrominance signal converter 87 , to a digitizing circuit 88 and to first and second auxiliary controls 82 and 83 and controls this. The first auxiliary controller 82 is connected to and controls a light source controller 89 , a motor driver 90 , a photoelectric converter 13 , an analog / digital converter 91 and a resolution converter 92 . The light source controller 89 is connected to a lamp 12 to control the light emitted by it. The motor driver 90 is connected to the scanning motor 18 and drives it. The second auxiliary controller 83 is connected to and controls a thermal head temperature controller 93 , the thermal head 31 , various detection switches 94 and a driver 95 . Driver 92 is connected to and drives a driver system 96, such as a motor and solenoid.

The main controller 81 selects one of the two operating states depending on the actuation of an operating state selection button 61 on the operator panel 2 and applies an operating state signal to the digitizing circuit 88 . If the second operating state, namely the monochrome structured color copying is selected by the operating state selection button 61 , then an operating state signal of high value is applied to the digitizing circuit 88 , while a low signal is applied when the first operating state, namely full color copying, is selected digitizing circuit 88 is set.

The chromaticity signal converter 87 is explained in more detail with reference to FIG. 11. The respective signals of a brightness signal I , a first color difference signal C 1 and a second color difference signal C 2 , which are supplied by an image quality improvement circuit 86 , are fed into the chroma signal converter 87 . One of the Y, M, C and B color signals is selected and applied to digitizing circuit 88 . The selection of the Y, M, C or B color signal is controlled by the main controller 81 . This is done in such a way that the main control 81 applies selection commands a and b to the chrominance signal converter 87 . Then one of the Y, M, C or B color signals is selected depending on a combination of signals a and b according to the table below.

table

Here, color signals are automatically in a certain Sequence in color copy state selected in a specific sequence, e.g. B. in the sequence Y, M, C and B.

The digitizing circuit 88 is explained in more detail with reference to FIG. 12. The signal provided by the chroma signal converter 87 is input to a color conversion unit 101 and a color classification unit 105 . The output signal of the color conversion unit 101 is input to an area classification unit 103 which classifies the areas. A structure memory 107 stores the monochrome color pattern signals corresponding to the monochrome structured color images of FIG. 1B, and the monochromatic color pattern is read out from the memory 107 based on a group signal classified according to the colors by the color classification unit 105 . A pattern output unit 109 outputs the monochromatic color patterns from the pattern or structure memory 107 . A data selection unit 111 selects the monochromatic color structure signal from the pattern output unit 109 or the binarized signal from the area classification unit 103 as a function of the operating state signal indication made via the main controller 81 . A control signal from the main controller 81 is applied to the structure memory 107 .

In the digitizing circuit 88 , when the first operating mode, i.e. full color copying is selected by pressing the operating mode selection button 61 and a low level signal is applied to the data selection unit 111 , the image signal is converted into gradations by the color conversion unit 101 and the area classification unit 103 . This image signal is digitized. The digitized image signal is applied to the thermal head temperature controller 93 and to the thermal head 31 with the aid of the data selection unit 111 , and full color copying takes place. Likewise, in the second operating state, the monochrome structured color copying, which is selected by the operating state button 61 and in which a signal of high level is applied to the data selection unit 111 , the image signal is broken down into each individual color by the color classification unit 105 and then into a number of color groups divided. The monochromatic color structure signals corresponding to these classified groups are read from the structure memory 107 and applied from the structure output unit 109 to the thermal head temperature control unit 93 and the thermal head 31 through the data selection unit 111 . In this way, a monochromatic color structure is printed and recorded for each color group as shown in FIG. 1B.

The color information reader has a photoelectric converter 13 , an A / D converter 91 , a resolution converter 92 , a correction circuit 84 , a brightness / color difference signal discriminator 85 , an image quality improvement circuit 86 and a chroma signal converter 87 . The color classification unit 105 and the structure memory 107 have a conversion device. The color structure output unit 109 , the thermal head temperature controller 93 and the thermal head 31 have an output means.

The function of the image generation device is explained in more detail with reference to the flow diagram of FIG . The copy mode identification signal is first deleted before copying begins. This signal indicates whether one-color or multi-color copying is to be carried out (step 210 ). It is then asked whether the state set by the selection button 61 of the operator panel 2 is the "color copying" or "monochrome copying" state (step 220 ). If the operating state is not "color copying" but "monochrome copying", then the copying state identification signal is set to "1" and the operating state signal of the digitizing circuit 88 supplied to the data selection unit 111 becomes "1" (step 230 ). In color copying, the identification signal is not set and the operating state signal of the digitizing circuit 88 supplied to the data selection unit 111 is "0". After that, when the push button 65 is turned "on", the copying operation starts (steps 240 and 250 ).

The operation of the copying machine is explained in more detail with reference to FIG. 10. Light from the lamp 12 is reflected from an original and focused on a photoelectric converter 13 . The photoelectric converter 13 divides the reflected light into the colors cyan (C), green (G) and yellow (Y) in the form of analog signals. These analog color signals are introduced into the A / D converter, which converts them into digital color signals. The digitized color signals are applied to the resolution converter 92 , which performs a resolution conversion in order to adapt the resolution of the photoelectric converter 13 to the thermal head 31 . A conversion result from the resolution converter 92 is applied to the correction circuit 84 . The correction circuit 84 effects correction processing of the color signals C, G and Y which are received by the resolution converter 92 in order to compensate for the fluctuations of the photoelectric converter 13 . A correction result is applied to the brightness / color difference signal separator 85 . The isolator 85 carries out various processing of the signals C, G and Y which come from the correction circuit 84 to generate a brightness signal I and first and second color difference signals C 1 and C 2 . The brightness and color difference signals are applied to the image quality improvement circuit 86 . This analyzes the brightness signal and the first and second color difference signals in order to carry out image enhancement such as edge enhancement and character recognition. An output from the circuit 86 is supplied to the chrominance signal converter 87 . This effects a color conversion on the basis of the brightness and the first and second color difference signals after the image quality improvement and generates the color signals yellow (Y), magenta (ie a kind of red M), cyan (C) and black (B). The selected color signal is applied to digitizing circuit 88 .

When the operation control signal "0" is applied from the main controller 81 to the digitizing circuit 88 , which corresponds to "color copying", then the digitizing circuit 88 digitizes the signals from the brightness signal converter 87 and effects the signal transmission to the thermal head temperature control circuit 93 . This sends correspondingly digitized signals to the thermal head 31 , which accordingly carries out the printing process. In this case, it prints in color.

If, on the other hand, the operating state signal "1" is applied to the digitizing circuit 88, the latter classifies the image signals and reads in the monochromatic color structure signals according to the groups that are color classified in the structure memory 107 . These monochromatic color structure signals are then applied to the thermal head temperature controller 93 via the structure output unit 109 and the data selection unit 111 . This then supplies monochromatic color structure signals to the thermal head 31 , which then prints in a single-color structure.

The conversion of color into single-color structured signals is carried out according to FIGS. 1A and 1B, for example in the following way: blue becomes horizontal lines, green as oblique lines of a first inclination, white as white without lines, yellow as horizontal and vertical crossing lines, red as vertical lines, brown as oblique lines of a second slope, opposite to the slope of the lines for green, orange as a grid pattern from the two oblique lines and black as black without lines. This means that colored images can be clearly reproduced even with single-color reproduction.

Claims (7)

1.

• 1. Copier with
• 2. a reading means for reading a colorful original and for outputting color information from the template, at least one color being a main color;
• 3. first converting means for converting the color information from the reading means into a number of different patterns, each of which corresponds to a different color of the original; and
• 4. a display means for the optical display of monochrome structured images corresponding to the different structures obtained from the conversion means.

2. The apparatus of claim 1, wherein the reading means comprises:

• 2.1 means for illuminating the original in order to obtain light reflecting it;
• 2.2 means for receiving the reflected light from the original artwork and converting the light into electrical signals; and
• 2.3 Means for dividing the electrical signals into three primary analog color signals.

3. The apparatus of claim 2, wherein the reading means further comprises:

• 2.4 a second conversion means for converting the three primary analog color signals into digital signals;
• 2.5 means for correcting the fluctuations of the digital signals from the second conversion signal for the formation of corrected signals;
• 2.6 means for separating the corrected signals from the correction means into a brightness signal and a first and second color difference signal; and
• 2.7 a third conversion means for selectively converting the brightness signal and the first and second color difference signals into one of the three primary color print signals.

4. The apparatus of claim 1, wherein the first converting means comprises:

• 3.1 means for classifying the color information into a number of groups; and
• 3.2 Means for storing various predetermined structural data corresponding to each group classified by the classification device.

5. The apparatus of claim 1, wherein the display means comprises:

• 4.1 means for feeding an image forming sheet for taking structured images;
• 4.2 means for extracting structure signals in accordance with the stored structure data; and
• 4.3 Means for printing monochrome structured images on the sheet depending on the structure signals.

6. The device according to claim 5, wherein the pressure medium comprises:

• 4.3.1 a thermal head for generating heat as a function of the structure signals; and
• 4.3.2 a monochromatic thermal ink transfer ribbon which is activated by the thermal head for transferring monochrome printed images onto the sheet.

7. Device according to one of claims 1 to 6, with:

• 5. a device for selecting between the states "color copying" and "monochrome copying".