DE3511749C2 - - Google Patents

Description

The invention relates to a device in the preamble of claim 1 Art.

Such a device is known from DE-AS 15 49 686. This device is used to control over Letters received remotely. In case of Failure to recognize a garbled letter this is displayed on a display device and can replaced with a correct letter using a keyboard will.

However, this has the disadvantage that after replacement of the letter the original picture pattern, namely the garbled letter, no longer exists, so no longer compared to the replaced letter can be used to check whether the correction is also in  the right direction was going. It is also known Device in its possible uses on the described Letter replacement function limited. For Editing functions, such as font modifications, or to edit other images or symbols the known device is not suitable.

Furthermore, JP-GM 58-52 587 is an image recording device known in which an image pattern, for example a letter, both as an analog signal from an image recording device fed to a display device and the image pattern after digitization as Digital signal from a memory of the display device is supplied, the display device the two Images overlaid and alternatively displayed so that digitized image can be adapted to the analog image.

This known device also has significant disadvantages, since only in the superimposed or alternative representation Corrections towards identity are possible and the representation of the analog and digital image pattern must be done on the same scale to make a comparison to be able to pull. So there are additional facilities with the image recording device necessary to the recording scale adapt, for which adjustment work is required. Furthermore, a correction can only be made here as long as the original of the image pattern to be edited lies in the receiving device.

The object of the present invention is therefore to to create a device of the type mentioned at the outset, with the easy and quick any image pattern in any Modified in a way that keeps up with the original Image samples for the purpose of checking the change can be compared.  

This object is achieved with the features of Identification part of claim 1 solved.

The device according to the invention allows simultaneous Representation of the original image pattern and the modified one Image pattern. So with any image pattern, for example not for the operator legible image patterns, such as Chinese Characters, a change possible, e.g. B. in the sense digitizing rasterization, inclination, resizing or the like, with constant visual comparison between the original and the changed Image patterns can be checked whether the change still clearly shows the original picture pattern. Faulty changes that lead to an unrecognizable image pattern lead, as they are known in the aforementioned Construction are excluded. It can be worked very quickly and efficiently will.

Further advantageous embodiments of the invention result itself from the subclaims.

In the drawings, the invention is for example and shown schematically. It shows  

Fig. 1 shows the device arrangement of an embodiment of the device according to the invention,

Fig. 2 shows the block diagram of the device according to Fig. 1,

Fig. 3 shows the flowchart of an exemplary method of operation for the apparatus according to Fig. 1,

Fig. 4 shows the example of an image display during the image processing,

Fig. 5 shows the example of image display in the case of parallel display,

Fig. 6 shows the example of image display in the event of superimposed display,

Fig. 7 shows the example of image display in the case, at different magnifications simultaneous display,

FIGS. 8 and 9 examples of displays in the simultaneous processing of multiple pixels, and

Fig. 10a-c image display examples for assembled figures.

In Fig. 1, an embodiment of the device according to the invention is shown in perspective view of the required equipment complex. Fig. 2 shows the associated block diagram.

A camera device picks up a drawing box 2 on a base plate 1 . An image recording device 6 is arranged with the suspension shown schematically adjustable in height above the base plate 1 . An image pattern 3 to be entered and processed is drawn on the cardboard 2 . The image pattern 3 can be a letter, a figure, a photograph or the like or, as in the example shown, a Chinese character (KANJI).

A lens 5 images the image pattern 3 onto an image converter (not shown) in the image recording device 6 . The lens 5 is preferably designed as a zoom lens with an aperture, so that it can take into account the imaging scale of the image pattern 3 or differences in brightness in the image pattern or in the background. In one embodiment, a television camera is used as the image recording device 6 . However, other suitable devices can also be used, such as, for example, the combination of a line sensor with a drawing board feed drive or a point sensor with a raster scanning device or the like. Luminaires 4 are provided in the usual way for lighting.

A camera control device 7 controls the image scanning by the image recording device 6 and the processing of signals. A data processing device 8 has a screen 9 , a control panel 10 , an external memory device 11 , an analog / digital converter 17 , a central process unit 18 , a first memory 19 , a second memory 20 and power supplies (not shown) and the like. The data processing device 8 controls the entire device, the data processing and the like. The screen 9 can display letters and other graphics as well as the operating menu, representation of input parameters, graphic representations of patterns and the like. The operating console 10 is in the example shown with a JIS (Japanese Industrial Standard) Keyboard equipped with a numeric keypad, function keys and the like and is used to enter operation commands and parameters. The external storage device 11 stores image patterns before and after the change as well as required programs. In the illustrated embodiment, floppy disks are used. However, other suitable storage media such as hard drives, magnetic tapes or the like can also be used.

A monitor 12 displays the image of the image pattern 3 recorded by the image recording device 6 , specifically as it is recorded. A frame is displayed on the monitor 12 , which reproduces the recording field for image pattern 3 . The operator positions the drawing board 2 , adjusts the camera position, the zoom lens or other recording-side adjustment options in such a way that the image pattern 3 appears within this frame. A printer 13 is provided as a dot printer for printing the image pattern 3 . A display 14 can show the image pattern 3 entered in the data processing device 8 in gray values, as a color pattern, as a binary-coded pattern, etc. The display 14 can also display commands when performing pattern correction.

A coordinate input device 15 is provided for designating individual pixels of the image pattern 3 shown on the display 14 and for entering operating commands. In the exemplary embodiment shown, a tablet digitizer is used. However, a light pen, a so-called "mouse", a ball roller device or the like. Devices known for this purpose can also be used.

A PROM writer 16 is used to write data to a PROM (programmable read-only memory) for storing changed patterns. The A / D converter 17 converts an analog video signal, which is obtained from the camera control device 7 , into a digital signal and writes it into the memory of the data processing device 8 . In the exemplary embodiment shown, a pixel (pixel) for inputting gray values consists of eight bits, and 320 pixels (sampling clock approximately 6 MHz) are provided in a horizontal scanning line. In the exemplary embodiment shown, a microcomputer is used for the central process unit 18 . The first memory 19 serves to store the image patterns before they are changed. The second memory 20 serves to store the image patterns after they have been changed.

In the following the image entry and processing with the described device described. This will start with on the processing of letter patterns as typical Application example received.

The cardboard 2 on which the image pattern 3 to be processed (in the present case a Chinese character) is drawn is first arranged on the base plate 1 of the camera, and the lights 4 are set for correct lighting. Then the image pattern 3 in the image recording device 6 is projected onto the image converter by means of the objective 5 and converted into electrical signals by the latter. The image pattern is displayed on the monitor 12 by means of the camera control device 7 . The operator adjusts the camera as required, that is, changes the diaphragm adjustment and focus adjustment on the lens 5 as well as the imaging scale and the lateral position of the drawing board 2 , so that the image pattern 3 appears on the monitor 12 in the frame mentioned.

After the adjustment has been made, an image input command is input to the central process unit 18 via the control panel 10 . The central process unit 18 takes in the data of the image pattern after conversion in the A / D converter 17 and stores it in the first memory 19 while displaying it on the display 14 . Although the image pattern data stored in the first memory 19 contains the gray value information, in the case of the desired production of a binary code pattern for a dot printer, the gray value level, gray value correction, production of a histogram, binary coding and the like are carried out by program processing. The data obtained in this way are stored in a memory area of the first memory 19 in addition to the gray value data and shown on the display 14 .

The operator looks at the pattern shown on the display 14 and inputs that the subsequent conversion or correction step will not take place if it is not required. Then it can command printing on the printer 13 and storage on the external storage unit 11 .

However, if it is necessary to correct the image pattern on the display 14 , a correction command is input from the control panel 10 . If this correction command has been entered, the image pattern before correction is shown on the display 14 , as shown in FIG. 4. Thereafter, the operator moves a pointer 23 to the location of the pixel to be corrected and inputs a change in the value of the pixel to thereby form the desired image pattern. The changed image pattern is stored in the second memory 20 , which is provided as a separate memory from the first memory 19 , in which the image pattern is stored before correction. Therefore, the uncorrected image pattern can be displayed on the display 14 during the correction work, or the uncorrected and the corrected image pattern can be displayed in parallel or superimposed, whereby the correction can be made with high accuracy by comparison with the original pattern. The corrected image pattern in the second memory 20 is printed out by the printer 13 or stored in the external memory unit 11 or written into the PROM by means of the PROM writer 16 .

The above procedure concerns the editing of a letter. In many cases, however, several letters have to be edited and saved together. For example, in the case of Chinese characters (KANJI) or the like, thousands of characters are to be processed together. An example of such a batch processing is explained in FIG. 3, stating the method steps in a flow chart.

First, white paper or drawing cardboard is inserted into the camera without labeling and entered and saved as a reference image (step a). Then the image to be processed (e.g. characters) is inserted and the image pattern is entered (step b). Then there is a normalization step with regard to the brightness level, the brightest pixel having the value 255 and the darkest pixel having the value 0 (step c). Then, after normalization, the image data are divided by the reference image in order to carry out a gray correction (step d). A histogram is then created and the threshold value for the binary coding is determined (step e). Then the binary coding (step f) and display (step g). If the result of the binary coding step is unsatisfactory, the binary coding is repeated after changing the threshold value (step h). If the binary coding is done satisfactorily, a conversion step is performed if necessary (steps i and j). If the conversion is not necessary, the correction is carried out directly (step k). The parallel or superimposed display then takes place together with the uncorrected image pattern (step 1). If a new correction is necessary, this is carried out (step m). If the correction is found to be satisfactory, the corrected image is printed out with the printer 13 (step n) and stored in the external storage device 11 (step o), and the next image pattern is input (step p). After all image patterns have been processed, they are written together in the PROM (step q) and the work is completed.

The correction of the displayed image pattern is described in detail below. Fig. 4 shows the image pattern before correction, as it is shown on the display 14. In the example shown, the image pattern 3 shown in FIG. 1 is reproduced, which represents the Chinese character with the meaning "letter". In the exemplary embodiment, a 16 × 16 dot matrix is used. The pattern has already been binary coded. The hatched pixels have the value "1" and the background has the value "0".

Pixel 21 has the value "1", pixel 22 has the value "0", pixel 23 is the pointer. The pixels 21 and 22 are shown with a different color, in the black and white representation then the pointer 23 also in a different way, for. B. by other gray value, flashing or the like. The pointer 23 can designate any pixel on the display 14 by means of cursor control by the coordinate input device 15 . The coordinate input device 15 is designed in such a way that it can change the value of the respective pixel by actuating a switch in the cursor control. At 24 , a piece of the letter shown is missing. At 25 an unnecessary pixel appears.

To correct the missing part 24 , the pointer is moved to this location with the coordinate input device 14 . By actuating the switch on the cursor control, the pixels in the missing part 24 are changed from "0" to "1", as a result of which the correction is made to the missing part 24 . To change the superfluous pixel 25 , the pointer 23 is brought to this pixel in a corresponding manner and its value is changed from "1" to "0".

FIG. 5 shows a screen representation corresponding to that in FIG. 4 for another correction method. If the display 14 switches between the uncorrected and the corrected image pattern during or after the correction process, it is difficult to accurately compare the two image patterns. The method shown in FIG. 5 aims to overcome this disadvantage by displaying both an uncorrected image pattern 27 and an image pattern 28 in which correction is carried out on a screen 26 . Such a parallel display enables easy comparison of the two image patterns and the correct implementation of corrections.

FIG. 6 explains a further correction method in which the uncorrected and the corrected image pattern are displayed in a superimposed manner, which greatly simplifies the comparison of the two image patterns. The density, texture, color or the like can be represented differently. For example, when the two superimposed image patterns are displayed in the colors green (for the uncorrected image pattern) and red (for the corrected image pattern), the color yellow results for sample parts that do not require correction, the color red for supplemented pixels 24 and the color green for removed pixels 25 (for 24 and 25 see the explanations for Fig. 4).

For letter patterns such as Chinese Characters or the like, are depending on the purpose Dot matrix of 16 × 16, 24 × 24, 32 × 32 or the like is required. On the other hand, in word processors also inclined or rotated, for example Letters rotated by 90 ° are used.

The device according to the invention is designed in such a way that it can carry out changes to enlarge, reduce, modify, etc. letters using the data processing device 8 and store the changed letters in the memory and then carry out the correction. It is therefore not necessary to enter the image patterns in the desired size, orientation or the like. Rather, image patterns once entered can subsequently be changed accordingly by program processing in the data processing device 8 . The processing time when producing a large number of characters can be shortened as a result.

If the original picture pattern is as large as possible Number of pixels entered is simplified the subsequent change. For example, a Letter made in a 32 × 32 grid if the image pattern was originally entered in a 96 × 96 grid and then to 16 × 16, 24 × 24 or 32 × 32 in simple Way is reduced. It is clearly possible that Enter the original image pattern in a 32 × 32 grid and then through interpolating reducers to reduce to 24 × 24 grid.

In another correction method, according to FIG. 7, an uncorrected image pattern 29 , an enlarged image pattern 31 and a reduced image pattern 30 can be simultaneously displayed side by side on a screen 26, the correction being easy to carry out while observing the original image pattern 29 .

In addition, by transmitting the corrected image pattern in the first memory and by further correction this corrected image pattern in successive For example, a character in different steps Fonts such as B. Ming style, Gothic Style or the like.

When correcting letters, it is often necessary to jointly correct a group of pixels in transverse or longitudinal lines. In FIGS. 8 and 9 this is by using the image pattern shown in Fig. 4 explained.

In the example in FIG. 8, a group of pixels between the starting pixel 32 and the ending pixel 33 is to be brought from the represented value "0" to "1". If the pointer 23 is moved through all the pixels one after the other, this takes a long time.

In a method simplified according to the invention, the pointer 23 is brought to the starting pixel 32 of the pixel group to be corrected, and the correction switch on the cursor is actuated. Then the pointer 23 is brought to the end pixel 33 and the switch is actuated again. As a result, the entire pixel group between the start pixel 32 and the end pixel 33 is brought together to the value "1".

In Fig. 9, the reverse procedure is shown, in which a group of pixels between the start pixel 32 and the ending pixel to be brought to the value "0" 33rd In a corresponding manner, as in the process described with reference to FIG. 8, only the pointer 23 is brought here to the starting pixel and then to the ending pixel, and the correction switch is actuated once, whereby the entire pixel group to be corrected at once Value "0" is brought.

In the case of FIGS. 8 and 9, pixel groups on a transverse line are corrected together. The pixel groups to be corrected can, however, also lie on longitudinal lines or inclined lines.

So far only the case has been described that pixels have the values "0" or "1" when correcting so just be inverted. In case of use of pixels with more differentiated coded The device according to the invention is designed in such a way that that every pixel in the correction to one any value can be changed.

If the corrected image pattern is formed and stored in the second memory in accordance with the method described in FIG. 4, and if the corrected image pattern is then used in the data processing device 8 used for the correction, for example if a corrected image pattern is used as an external letter , it is necessary to save the corrected image pattern in the second memory even when the power supply is switched off. In such cases, therefore, the external memory unit 11 is used as the second memory, or a PROM is used via the PROM writer 16 . However, a CMOS RAM with low power consumption or the like can be used as the second, which is equipped with a battery and serves as a non-volatile memory. On the other hand, the second memory can also be designed as a magnetic core memory, magnetic bubble memory or the like. Non-volatile memory. Such a configuration is particularly useful if, in addition to letters stored in a ROM (eg Chinese characters), other letters that are not commercially available can be stored externally and can be used.

Image patterns produced in the device according to the invention can be transferred to non-volatile memories, such as magnetic disks, PROMs or the like, to other data processing systems and can therefore be used with widespread use. For this purpose, the processed image patterns and stored in the second memory are transferred to the external memory unit 11 or the PROM recorder 16 individually or together. If another data processing device is installed nearby, the transmission can also take place via a data transmission line.

Image patterns already stored in a ROM or the like can be used as a basis for the production of new picture patterns will. You will then first of all from the ROM in the first memory or can transfer the ROM itself be used as the first memory. In particular is it is possible to easily change font to make, for example, characters from Ming style can be changed to Gothic style or Like ..

Furthermore, it is possible to obtain new image patterns by synthesizing from a large number of image patterns that have already been created. This is explained in FIGS. 10a-c using Chinese characters, for example. Thus, the Chinese character with the meaning "tree" shown in FIG. 10a can be read out twice and shown side by side according to FIG. 10b, whereby the Chinese character with the meaning "woody" is created. Furthermore, the character according to FIG. 10a can be composed three times in the arrangement according to FIG. 10c and then forms a new character with the meaning "forest".

The above description relates to examples of education of character image patterns. In the same way you can however also shaded figures, color photographs and the like. to be edited.

Claims (11)

. Image input and processing device for input and display of image patterns, such as. B. letters, figures or the like., And to change and / or correct this input data, with a device for storing the input original image pattern in a first memory, a device for changing the original image pattern from the first memory and a display device for display of the original image pattern from the first memory, characterized in that means ( 10, 18 ) for storing the changed image pattern in a second memory ( 20 ) and a display device ( 14 ) for displaying the changed image pattern are provided. 2. Apparatus according to claim 1, characterized in that the means for storing the original image pattern ( 3 ) in the first memory ( 19 ) has an image recording device ( 6 ) for scanning the original image pattern to be entered ( 3 ) and for conversion into electrical signals and an A / D converter ( 17 ) for converting the electrical signal. 3. Device according to claim 1, characterized in that the display device ( 14 ) is equipped for displaying the original and the changed image pattern on the same screen. 4. The device according to claim 3, characterized in that the display device ( 14 ) is provided for displaying both the original and the changed image pattern in parallel representation on the same screen. 5. The device according to claim 3, characterized in that the display device ( 14 ) is provided for superimposed representation of the original and the changed image pattern on the same screen. 6. The device according to claim 1, characterized in that the change and / or correction device ( 10, 15, 18 ) is equipped for enlarging, reducing, inverting or modifying the original image pattern from the first memory. 7. The device according to claim 1, characterized in that the change and / or correction device ( 10, 15, 18 ) is provided for designating individual or groups of pixels from the original image pattern and has means for changing the values of the designated pixels. 8. The device according to claim 7, characterized in that that the facility to designate groups of Pixel the start and end pixel of a Group designated and that the change facility  is designed for the pixel values such that the entire group of pixels from the beginning to be changed together to the final pixel.   9. The device according to claim 1, characterized in that the second memory ( 20 ) is designed as a non-volatile memory, for example as a magnetic memory or the like. 10. The device according to claim 1, characterized in that a transmission possibility for in the second memory ( 20 ) stored changed image patterns in the first memory ( 19 ) is provided for the purpose of renewed correction. 11. The device according to claim 1, characterized in that a transmission possibility for in the second memory ( 20 ) stored changed image pattern to non-volatile memory, such as magnetic memory, PROM or the like., Is provided.