DE1549860C3 - Process for producing a corrected text and apparatus for carrying out this process - Google Patents

Description

¹

The present invention relates to a method for producing corrected text on the basis of handwritten proofreading text using an with a symbol recognition device connected to an electronic data processing machine and to a Apparatus for carrying out this process.

In all those cases in which errors or mistakes occur on the printed material, the same must be said can usually be copied again with the typewriter in corrected form. It is coming however, very often, with the exception of a single line, an entire page of data is perfect could be used; if there is no electronic storage of the printed material, for example has been made on a magnetic tape, it is then necessary that the entire data page must be rewritten or reprinted so that the insertion or deletion with regard to that can be inserted into the new text.

It is therefore an object of the present invention to provide a novel and improved method of manufacture a corrected text according to which a corrected by hand, for example after a proof Text with the help of a symbol recognition device in a data processing system - for example a printing machine - can be read in without the need for manual production beforehand a fair copy of the corrected text would be necessary.

According to the invention, this is achieved in that the symbol recognition device is controlled in this way is that it first scans lines provided with symbols, both digital signals accordingly the scanned writing symbols as well as their location coordinates in the electronic computer are fed, while then the space between the lines in view is scanned for the presence of correction symbols, likewise both digital signals fed to the computer in accordance with the scanned correction symbols and their location coordinates whereupon a coordinate comparison of the font and correction symbols is carried out and finally the written symbols stored in digital form corresponding to the one carried out Location coordinate comparison can be corrected.

The device for carrying out the method according to the invention is characterized in that the same has a scanning unit controlled by a command control unit, which via a die Shift register storing signals from a full scan, one of the characteristic features of A mask circuit which detects symbols and a symbol detection circuit which combines the characteristic features is connected to a digital code generator which converts the output signals of the symbol recognition circuit into digital signals, both the command control unit and the digital code generator via a buffer stage with the Main control unit of the electronic computer are connected. An advantageous development of a Such a device for producing a corrected text is expediently in that the mask circuit and the symbol recognition circuit are designed so that with the same handwritten correction symbols are also recognizable in addition to printed symbols, which from a vertical line and from the same above, below and / or ^ in the middle laterally after there are outstanding lines on the right and / or left.

The invention is to be explained and explained in more detail below, with reference to the drawings Is referred to; it shows

F i g. 1 is a schematic block diagram of the device according to the invention;

F i g. Figure 2 is a plan view of a sheet of one provided with correction symbols according to the invention Text passage;

F i g. 3 a set of possible correction symbols;

F i g. Figure 4 is a pictorial representation of the character recognition circuits for recognizing the various Correction symbols and

F i g. 5 and 6 are schematic block diagrams of the data flow within the device according to the invention during and after the scanning of a document.

In the following, the various figures of the drawings will now be discussed in more detail in which like reference numerals correspond to like parts.

A schematic block diagram of the device according to the invention for producing a corrected The text is shown in FIG. The apparatus includes a document handling unit 72, a Sampling unit 74, an instruction control unit 76, a shift register 78, a feature recognition circuit 80, a symbol recognition circuit 82, a digital code generator 84, a main control unit 86 and a buffer stage 88.

The document handling unit 72 consists essentially of a rotatable cylindrical roller and a document feeding unit that feeds the inputted documents to the platen. the The rotatable roller lies next to the scanning unit 74, which has a light point scanner. The scanning unit 74 consists essentially of a cathode ray tube, which is controlled by the command control unit 76 is controlled. The scanning unit 74 further includes a photoelectron multiplier tube and one Pulse generator circuit. The cathode ray tube generates a light beam grid which is directed onto the in the rotatable roller in the document handling unit 72 lying document is directed.

The size of the light grid or the position of a light point on it is determined by the size of the input signals on the lines 100 and 102 connecting the scanning unit 74 and the command control unit 76, which lines consist of a plurality of individual line cores.

In Fig. 1, lines indicated by thick dashes generally mean that they are a multi-core cable having a plurality of input and output lines. The horizontal position of the grid of the cathode ray tubes and the horizontal size of the grid is determined by the size of the input signals on the lines 100 . The size and position of the vertical position of the grid on the cathode ray tube of the scanning unit 74, on the other hand, is determined by signals on the lines 102 .

The position of the grid with respect to the horizontal and vertical direction is signaled back to the command control unit 76 via the cable strands 100 and 102 and from there via the buffer stage 88 to the main control unit 86, so that the position or the coordinates of a symbol both horizontally and in the vertical direction together with the recognized symbol itself.

Within the scanning unit 74, the cathode ray tube forms the end element of the light point scanning, according to which a light beam against the document lying within the document handling unit 72 is directed, an alignment of the through a between the cathode ray tube and the document lying lens system takes place. The light beam runs within a grid, which is slightly larger than the largest character to be scanned. In the present embodiment, there is the grid of 30 vertical scan lines.

Inside the scanning unit 74 is the photomultiplier tube with a pulse shaper

ίο connected, which in predetermined time intervals samples the output of the photomultiplier tube. So while the cathode ray tube a beam of light along a vertical line onto the surface of the document emits, the photomultiplier tube generates a signal which is in accordance with the is the amount of light of the light beam reflected on the surface of the document. The pulse shaper scans the output of the photoelectron multiplier at certain time intervals, whereby the Scanning the cathode ray along the surface of the document corresponding to the white or black state of the surface pulses of different sizes are generated.

The pulse shaper samples the output of the photomultiplier tube 40 times on each line. For each light grid that the cathode ray tube throws onto the surface of the document, the pulse shaper 1200 therefore generates discrete output signals. The pulse shaper also contains suitable gate circuits so that the output signal indicates a black sampling point as long as a certain threshold value of reflected light is not exceeded. The output signal of the pulse shaper is passed from the sampling unit 74 to the shift register 78 via a line 104. The shift register 78 is capable of storing 1200 bits. The output signal generated by the scanning unit 74 can therefore be stored for the complete scanning of a character. The shift register 78 consists of 1200 flip-flop circuits which are connected to one another in series. The flip-flop circuits are arranged in 30 vertical columns and 40 horizontal rows in accordance with the location of the scanning points on the scanning grid. Accordingly, 30 columns of 40 flip-flop circuits are provided. Each of these 40 flip-flops corresponds to a set of sample points along a vertical column on the grid.

The pulse shaping unit measures the output of the photoelectron multiplier in accordance with signals from a pulse generator, which also supplies adjustment pulses via line 106 to the shift register 78. The wire harness 106 is connected to the input of each of the flip-flop circuits. While a sequence of input pulses according to the output of the photoelectron multiplier is fed to the shift register 78 via the line 104 , the control pulses on the line 106 switch the pulse sequence through the same step by step.

The individual flip-flop circuits are each provided with two transistors. Whenever a control pulse occurs on line 106 , the relevant flip-flop circuit within shift register 78 is influenced in such a way that the second transistor is switched off. If the first transistor of a certain stage of the shift register 78 is switched off, then

it brought into the conductive state on the basis of a pulse on the control line 106; however, if it is already conductive, its switching state remains unchanged. The output signal from the previous stage is then received by each subsequent flip-flop stage, as soon as a pulse arrives on the line from the previous stage, the first transistor of the following stage is switched off by the input pulse. It should be understood that appropriate pulse delay elements are provided between the output of the previous stage and the input of the next following stage so that the flip-flop circuits switched by the control pulses have sufficient time to stabilize before they receive an input signal from the previous stage be able.

When the first transistors of the flip-flop circuits are switched off, this is an indication that a black spot is being scanned on the document has been. In all cases, however, in which the first transistors are conductive, this means on the other hand, that a white area has been scanned on the document!

The shift register 78 is connected to the feature recognition circuit 80 via a wiring harness 145.

Individual lines lead from all of the flip-flop circuits of the shift register 78, combined in a suitable manner to a plurality of feature masks within feature recognition circuits 80. Es As many feature masks are provided as features must be present in order for a through the Shift register 78 to recognize passed characters. Each feature mask comes with one A plurality of flip-flop circuits of the shift register 78 are connected. The output signals of this Feature masks get to the flip-flop circuits via two different sets of wires, each according to whether a character is recognized by the combinatorial absence or presence of various features shall be.

Each feature mask of the feature recognition circuit 80 consists of a plurality of resistors, the flip-flop stages of the shift register that are different on one side with the output lines 78 are connected. The mask also has a threshold gate circuit consisting of two Transistors and the associated switching elements. In most cases it contains a feature mask between 4 and 15 resistances, which can be staggered with regard to their size, so that with regard to the signal size at the base terminal of one transistor, certain more important subcomponents a correspondingly larger value can be assigned to a feature.

The feature recognition circuit 80 is connected to the symbol recognition circuit 82 via a wire harness 166; this wiring harness 166 contains the output lines from all threshold gate circuits feature recognition circuit 80. The recognition of symbols by combining the individual features triggers a signal within the symbol recognition circuit 82, which is carried over a wiring harness 194 to the digital code generator 84 , in which a transformation into a binary representation is made. The output of the digital code generator 84 is connected to the buffer stage 88 via a wiring harness 196.

The wire harness 96 consists of a plurality of wire cores which are recognized parallel to one another Route symbols to buffer level 88. The buffer stage 88 serves as a multiple coupling unit, to route signals in and out of main control unit 86 on a multiplex basis. The main control unit 86 is preferably a general purpose digital calculating machine which as required the proofreading device according to the invention is programmed.

The binary-coded letter signal is briefly fed to a memory within the main control unit 86. The command control unit 76 generates the x / y coordinates of the area on the document on which a symbol has been scanned and accordingly forwards a signal via x and y coordinate lines 198 and 200 to the buffer stage 88. This means that the location, at which the cathode ray tube has scanned the document, is determined by the x and j coordinates, and that corresponding electrical signals are passed via the lines 198 and 200 into the buffer stage 88. This buffer stage 88 transmits these coordinates to the main control unit 86 via a line 212.

Therefore, not only the symbol to be read, but also its location is stored in a short-term memory of the main control unit 86. It should be noted that the buffer stage 88 also provides instructions to the command control unit 76 over a line 204. The main control unit 86 finally sends a line 202 command signals for the entire device.

In standard systems for proofreading textual material, it has been necessary to date that Correct entire material and then copy it again on a typewriter or again to be printed out so that the corrections can be incorporated into the incorrect text. on Because of the following example, it is very easy to see that by using the invention Procedure after proofreading the text material, no additional work is required, because the text material can be input directly to the symbol recognition device without perfect copies would be needed.

In the example given below, the method of the invention is compared with that currently used Procedures compared; from this example it can be seen that within the scope of the present Invention the way the proofreading of textual material goes on in much the same way. The following is a table with some standard correction symbols within the scope of the invention Correction used is indicated:

1. Proofreading symbols

As part of of the invention Standard correction symbol according to ver
driving ver turned Cor correction icon Capital letter ξ I. Omission of X + Start of an omission

continuation

Standard correction yrabol

Space to be added = § =
End of an insertion

Letter swap tr

Lowercase ec

As part of
correction symbol used in the method according to the invention

In the following examples of lettering and printing instructions are given, which can also be used in the process according to the invention.

2. Alphabetical insertions

a -Γ 3. η - p S. -J e -Ί Line printing instructions Vogue Bold - J ¹ 20 point C 11 Pikazeile - ^ f

-L

It must be understood that the correction symbols given above are only given as examples. It will be understood that other symbols could be used for the same functions. The same thing Symbol can also be used not only for a correction instruction, but also for a letter insertion or a line print statement can be used. The way in which a symbol can be used is determined either by its position or by the closest correction symbol. So is z. B. always insert a letter after a correction symbol. It can therefore be specified that a Correction instruction symbol determined within the data processing system on the basis of the program, that the following symbol must be an insertion of a letter. It must also be understood be that correction symbols used in the context of the preliminary invention are not only used for alphabetic ones or graphic insertions, but also for number insertions and. other graphic symbols are used can be. The data processing system can also scan proofreading symbols in places outside of the text, it should be noted that in contrast to changes in the textual material expressly treat such a symbol as a line or typesetting instruction.

The way in which the suggested correction symbols are used is related to the The following example can be shown more clearly: In Fig. 2 shows a document 40 with a text material, the correction symbols proposed within the scope of the present invention have been corrected is.

In the upper left corner of the sheet 40, the correction symbols 42, 44 and 46 are provided. The Cor

55

60 correction symbol 42 gives the line setting instruction for the use of »Vogue Bold«. The correction symbol 44 is an instruction for the use of "20 points" and the correction symbol 46 is a line setting instruction for an "11 pika line". It can therefore be seen without further ado that the correction symbols used in the context of the present invention are used in exactly the same way as the standard abbreviations, which in this case would be »VB 20 χ II«, for specifying how the text material is to be printed. The first line of text on Document 40 also shows a mistake, which is that the lowercase "p" in the word "problem" should be a capital "P". To correct this, the symbol 36 is placed below the lowercase letter "p", which indicates that an uppercase letter should be used in place of the lowercase letter.

Furthermore, an error appears in the third line of the document 40, which consists in the fact that the Letter "z" should be a letter "a". This error is corrected by using the correction symbol 48 is placed below the "z". The correction symbol 48 indicates that the letter is above should be omitted. The correction symbol 48 is then followed by the correction symbols 50 and 52. The correction symbol 50 indicates that the letter "a" should be inserted while the Correction symbol 52 expresses that no further letters in place of the omitted letter "z" should be inserted.

On the same line of Document 40, the word "raw material" should correctly read "raw materials". The correction symbol 54 is inserted on the document 40, which indicates that an omission has been made should therefore be below the letter "s" in from the word "raw material".

Finally, in the third line of document 40, a third error occurs, which consists in the fact that the words "about" and "our" must be separated from one another. On the document 40 is accordingly the correction symbol 56 inserted below the letters "r" and "u" in the word "überunsere", indicating that a space is inserted between these two letters target.

In the fourth line, the word "deisen" is misspelled because the "e" and "i" are not in the correct one Order. On the document 40, the correction symbol 58 is therefore below the The letters "ei" are used to indicate that the two letters have been swapped "E" and "i" must be made.

Further errors occur in the fifth line, which consist in putting the word "it" between the words "If" and "namely" should be inserted, and that the first letter of the word "soon" is a lowercase letter should be. The correction symbol 60 is therefore displayed on the document 40 below the space inserted between the words "if" and "namely" to go to the beginning of an introduction to deliver, followed by the correction symbols 62, 44, 58, through which it is given that the letters "E" and "s" should be inserted between the words "if" and "namely". Correction of the capital letter "B" in a lowercase "b", however, is given a correction symbol 66, which is placed below the letter "B" and

309 547/335

which indicates that a lower case letter should be placed in place of the upper case letter.

The next six lines contain no errors and have therefore not been corrected; however on the In the last line of Document 40, the words "in the third world" should read as follows: "in the Third World". The correction symbol 48 is therefore both below the letter "s" in the Word "des" as well as below the letter "c" of the word "thirdec". While the first ι ο Correction symbol 48 is followed by correction symbols 68 and 52, follow the second correction symbol 48 the correction symbols 70 and 52. These corrections indicate that the letters "s" and "C" should be replaced by the letters "r" and "n".

On the basis of the above description of the proofreading of document 40 it is very easy to see that in Proposed method of proofreading text material within the scope of the present invention compared to the location method using conventional correction symbols, in a relative manner can be carried out. Correction symbols proposed in the context of the present invention can be written very easily and used in many ways.

These symbols not only give instructions for text changes and omissions, but also can also be used for letter insertions, new line instructions, and insertions and instructions more general Kind be used.

In the following, reference should also be made to FIG. 4, which schematically shows a combination of feature recognition masks for recognizing and identifying correction symbols proposed within the scope of the present invention. The vertical line of the correction symbol consists of 15 sectors MI to M-15. Each of these sectors is 5 fields long and 1 field wide and has an elongated shape in the vertical direction; the sectors are essentially on the center line of the grid. The upper left bar of the correction symbol consists of the sectors TI, T-2 and Γ-3, while the upper right horizontal bar consists of the sectors T-4, T-5 and Γ-6. The left middle horizontal bar consists of sectors CI, C-2 and C-3, while the right central horizontal bar corresponds to sectors C-4, C-5 and C-6. The lower left horizontal bar consists of sectors LI, L-2 and L-3, while the lower right horizontal bar is determined with the help of sectors L-4, LS and L-6. Each of the sectors TI to L-6 making up the horizontal bars is elongated in the horizontal direction and has a length of 5 fields at the width of one field.

Each of the sectors MI to M-5 represents a feature recognition mask with 5 input resistors. These resistors are connected to the output lines of the various stages of the shift register 78 in accordance with the position of the fields as shown in FIG. 4 connected. Each of the sectors TI to Γ-6, CI to C-6 and LI to L-6, which make up the horizontal lines of the correction symbol, corresponds to a pair of feature recognition masks each having 5 resistors. The resistors of the first set of these feature detection masks are connected to the corresponding stages of the shift register 78 via a strand of output lines, while the resistors of the second set are connected to the corresponding stages of the shift register 78 via a second strand of output lines. There are therefore feature recognition masks, both for determining the presence and absence of each sector within the horizontal bars of the correction symbol.

A horizontally extending sector TZ is provided above the horizontal sectors Γ-1 and T4 and the upper fields of the vertical sectors MI M-2 and M-3. This sector is 13 fields long and 1 field wide and therefore has exactly the same width as the upper line of the correction symbol. Furthermore, the sector is provided at a distance of one field above the correction symbol. Below the horizontal sectors L-3 and L-6 and the lowermost fields of the vertical sectors M-13, M-14 and M-15 a horizontally extending sector DZ is provided, which is also 13 fields long with a width of one field . The sectors TZ and DZ are each connected to a feature recognition mask which has 13 resistors. Each of these resistors is connected to the output line of the corresponding stages of the shift register 78.

A sector LZ is provided between the two upper horizontal lines and the vertical line, which is 3 fields long and 2 fields wide. Another sector RZ is provided between the two lower horizontal lines and the vertical line 22. This is also 3 fields long with a width of 2 fields. The sectors LZ and RZ are connected to the corresponding feature recognition masks, which have 6 resistors; the resistors are connected to corresponding stages of the shift register 78 via the lines. The sectors TZ, BZ, LZ and RZ guarantee that the signals produced when the correction symbol is scanned appear in the correct order when passing through the shift register 78 so that the symbol identification can be carried out correctly.

As already mentioned above, the feature recognition masks can have different resistances in terms of value exhibit. However, it is provided that within the individual feature recognition masks the Resistors are designed essentially the same. Those related to the individual sectors Threshold gates are appropriately biased so that they are the same overall Address 5 fields by receiving at least 3 signals from shift register 78. If so due to the scanning by the cathode ray tube of a total of 5 fields within one sector responds to black, the threshold gate circuit switches within the feature recognition mask indicating that the sector is present. Normal variations in line width when used a pencil or a pen therefore in no way have the consequence that the gate scales of the corresponding sectors do not address.

The sectors TZ, LZ, RZ and BZ are control sectors which serve to prevent imprecise identification of a feature within the feature recognition mask. The feature identification mask of these sectors TZ and BZ are designed so that the 13 resistors are of equal value and that the corresponding gate circuit responds when at least 10 signals are received from the 13 stages of the shift register 78. When

that is, if the cathode ray tube scans 10 white fields out of a total of 13 fields in this sector, the feature recognition mask responds. The feature recognition masks associated with the sectors LZ and RZ, however, are designed in such a way that at least 4 of the 6 fields must respond to the scanning of the sector by the cathode ray tube due to the threshold value gate circuit on white before the feature recognition mask responds. The feature identification mask of the ι ο sectors LZ and RZ indicate in the excited state that the color of the corresponding fields on the document 40 is predominantly white.

As soon as the symbol recognition circuit 82 has recognized a correction symbol, an output signal is passed to the encryption generator 84 via the line 194. The encryption generator 84 transforms the signal arriving via the line 194 into a binary-coded signal and forwards this binary signal via the line 196 to the buffer stage 88. The command control unit 76 also sends via the lines 198 and 200 binary signals which contain the spatial coordinates of the correction symbol on the Correspond to document 40. The buffer stage 88 then transmits both the correction symbol itself and its location coordinates χ and y to the main control unit 88, in which storage is carried out. The main control unit 86 also gives command control unit 76 and the buffer stage 88 via line 204 in order to control the scanning unit 74 with regard to the coordinates of the scanning as well as the size of the scanning grid. The size of the scanning raster must be variable in those cases in which the correction symbol can be variable with regard to its size. Therefore, if the correction symbol is written too small, the screen produced by the cathode ray tube is reduced. On the other hand, the dimensions of the grid are enlarged as soon as the correction symbol is written too large.

The general workflow is illustrated schematically in the flow chart of FIG. A proofread document 40 is for scanning on the cylindrical roller within the Document handling unit 72 inserted. As soon as the document 40 is in the correct position, the document handling unit releases 72 sends a signal to scanning unit 74 over line 206 indicating that document 40 is in the correct position located.

If the document 40 is not exactly in the correct position, the feed device becomes the document handling unit 72 controlled until the document 40 is correctly inserted.

The cathode ray then begins to search for the first line of the document 40 in the scanning unit. As soon as the first line is found, the horizontal and vertical position of the cathode ray is displayed over the Command control unit 76 and the buffer zone 88 are transmitted to the main control unit 86. As soon as the Main control unit 86 has received the exact location of the first line on the document 40, gives the same the scanning unit 74 the command to scan at the given horizontal and vertical position of the Document 40 to begin. The scanning unit 74 then starts the letter scanning. Should of the scanning unit 74 do not recognize any video characters - which would mean that none in the first position Letter is present - on the basis of commands from the command control unit 76, the letter scan becomes moved further along the line. However, once a video character has been discovered it will be the x / y coordinates of the letter via the command control unit 76 and the buffer stage 88 are transmitted to the main control unit 86. At these coordinates the letter is then scanned by the cathode ray tube and the output of the photomultiplier tube passed via line 104 to shift register 78. As soon as the letter is removed from the Detection circuits 80 and 82 have been identified and recognized, electronic signals become this Letter and its x / y coordinate stored within the main control unit 86. The command control unit 76 then gives corresponding commands to the scanning unit 74, so that the latter with the letter scanning continues along the line to the end.

At the end of the line, the scanning unit 74 is commanded by the command control unit 76, below the to perform a correction symbol scan on the line just scanned. The scanning unit performs like this continue searching for the correction symbol for a long time until the video signal is interrupted. This means that a Correction symbol is present within this correction line. The x / y coordinate of the relevant correction symbol is then sent to the main control unit 86 and the scanning unit 74 begins scanning that symbol. To set the on the Correction symbol found in the relevant line, the scanning unit 74 transmits the output signals of the Photomultiplier to the shift register 78. The detection circuit 80, 82 then sends the appropriate Signals of the correction symbol to the main control unit 86, thus the same thing at the same time is saved there with its x / y coordinates. The command control unit 76 then commands the Scanning unit 74 to continue scanning the correction line to its end.

The command control unit 76 then commands the scanning unit 74 to scan the next Line of document 40 to begin. This process of scanning along a line of document 40 and then below this line the search for correction instructions is continued step by step. At the end of the document 40, a final signal is generated within the main control unit 86, and the document handling unit 72 is instructed to reject the document 40 and the next Bring the document into the correct position for optical scanning.

The main control unit is a general purpose data processing system. The information regarding the letters along the lines of the document 40 and the correction symbols become temporary stored in a store. By programming the main control unit 86, the lines are mixed up the text characters and the corresponding correction lines and the correction operation executed that way.

In Fig. 6, the correction process is shown schematically in the form of a flow chart, whereby the Information flow for the execution of the line mixing within the data processing system is recognizable. When the document closure signal arrives, the x / y coordinates of the first letter become the first line from the short-term memory

fetched. The x / y coordinates of the first correction symbol are then also extracted from the short-term memory. The two sets of coordinates for the letter and the correction symbols are then compared. If the two sets of coordinates do not correspond to one another - or, to put it differently, as soon as it is certain that the x / y coordinate of the correction symbol is not near or below the x / y coordinate of the letter - then the letter points within the text does not show any errors and does not have to be changed. The x / y coordinates of the next letter are then searched for and the coordinate sets of the correction symbol are compared with this letter in the same way. If, however, a comparison has been made in which the two sets of coordinates of the letter and the correction symbol lie within defined limits - that is, if the correction symbol is more or less below the letter - then the correction symbol is fetched from the memory and the necessary correction operation, as indicated by the correction symbol. The result of the correction operation is stored in the final memory together with the previous letter of the text that has already been corrected. After the correcting operation has been completely carried out, the final operation is carried out in accordance with the correcting symbols of the typesetting instructions. On the basis of this information, the data processing system determines the number of letters per line or the division of letters and words within the line for a specified column width for the reproduction of the text material, whereupon the text material is then output, for example, by a printing machine connected to the data processing system. The present invention permits the proofreading of printed or typed documents for direct input into a symbol recognition device. The need for a new machine copy or printing of the entire sheet as a fair copy has therefore become superfluous. The method of proofreading according to the invention does not require more time than already known methods for proofreading. The correction symbols proposed in the context of the present invention are very easy to write, while at the same time easy recognition by a symbol recognition machine is guaranteed. The document to be corrected can therefore be inserted directly into the symbol recognition device, which can read both the text material and the changes made.

For this purpose 2 sheets of drawings

Claims (3)

• Patent claims: 1. Method of producing a corrected text using a handwritten one Corrections of provided text using a symbol recognition device connected to an electronic data processing machine, characterized in that the symbol recognition device is controlled in such a way that it is first provided with written symbols Scanned lines, both digital signals corresponding to the scanned writing symbols and their location coordinates are fed into the electronic computer while then the space between the lines in terms of presence of correction symbols is scanned, likewise both digital signals corresponding to the scanned correction symbols as well as their location coordinates are fed to the computer, whereupon a coordinate comparison of the font and correction symbols is carried out and finally the written symbols stored in digital form according to the location coordinate comparison carried out Getting corrected. 2. Device for performing the method according to claim 1, characterized in that that the same has a scanning unit (74) controlled by a command control unit (76), which via a shift register (78) storing the signals of a full scan, one of the characteristic Mask circuit (80) detecting features of the symbols and a characteristic Characteristic combining symbol recognition circuit (82) with one of the output signals the symbol recognition circuit connected to digital code generator converting digital signals is, wherein both the command control unit (76) and the digital code generator via a buffer stage (88) are connected to the main control unit (86) of the electronic computer. 3. Apparatus according to claim 2, characterized in that the mask circuit (80) and the symbol recognition circuit (82) is designed so that with the same next to printed Handwritten correction symbols (34-70) can also be seen in writing symbols, which from a vertical line and from the same above, below and / or in the middle laterally after '50 there are outstanding lines on the right and / or left.