KR100953586B1 - Word processor based method for electronically proofreading a document and a computer-readable recording medium containing programs for the same method - Google Patents

Abstract

A method of electronicizing a word processor based document correction function is provided. The calibration code is constructed in such a way that the predetermined unit parts are assembled by appropriate combination. The size of the calibration code can be adjusted by the user as needed. After preparing the unit parts necessary to compose various various calibration codes in advance, the unit parts necessary for its construction are determined for each calibration code, and the ID and attribute information of the unit parts constituting each calibration code are defined. The generated calibration codes are provided in the form of a toolbar-type user interface (UI). When the user selects a desired calibration code from the calibration code UI and specifies a location in the original document, the calibration code is inserted into the designated location and displayed on the screen, and the calibration information related to the calibration code is stored in the storage means. If desired, the user can make additional modifications to the marked calibration code. When the user instructs the creation of a document reflecting the calibration work performed by the user, a calibration document is automatically generated according to the calibration code and the calibration content displayed on the original document.

Calibration, Unit Parts, Calibration Code, Virtual Area, Assembly, Resize, Directional, Vertical Split, Word Processor

Description

Word processor based method for electronically proofreading a document and a computer-readable recording medium containing programs for the same method}

This is a method of electronically correcting a manuscript, in particular, a word processor-based manuscript correction, which allows a document processor to perform document correction, but automatically generates a document in which a correction code is displayed on the document and reflects the contents of the correction. A method of electronicizing a function.

In the preparation of a document, corrections can always happen. For example, when making books, newspapers, magazines, etc., the first written manuscript is generally edited at least once by the editors. In the case of Hangeul, in particular, various editing codes are used for editing. If the content of the editing done by the editor is displayed in the original document as it is, it can be seen at a glance what is corrected. It is necessary to keep a record of what corrections have been made, and this requirement may be met by allowing the originals to be marked with the correction code and the corrections. In addition, if the calibration code and the calibration contents are not displayed as 'displayed' in the original document, and the calibration document can be automatically changed according to the displayed calibration codes and the calibration contents, the efficiency of the calibration work will be further increased. Can be.

However, despite these demands in the field of manuscript correction, no solution has been proposed to fully satisfy these demands. Korea has its own manuscript correction function. However, Hangul word processor program or MS word processor program does not provide the document correction function. Hangul word processor program is only to provide a memo function. MS Word provides a change tracking function, but it is limited to limited forms such as adding or deleting contents, and may not be able to display various correction codes that appear on a paper manuscript.

Korean Patent Publication No. 2001-0087577 entitled "Method for Implementing Manuscript Forms on a Computer" implements a manuscript form on a computer and inputs an input / output of a character, inputs a correction code, and corrects the input data again. This paper proposes a technology that enables the creation of manuscripts on the web by applying ActiveX control technology. However, this technique is required to display the form of the manuscript on the screen and to display characters and correction codes in accordance with the manuscript writing rules, which limits the application to various documents in the form of not using the manuscript form. In addition, the correction code should be able to flexibly change the size of the display position or the correction code according to the surrounding situation (size of the surrounding letters, etc.) of the position to be displayed, and there is no solution for this, which is not practical. Furthermore, it does not provide a solution for automatically generating the corrected document according to the displayed correction code and the correction.

The document correction function is intuitive. It is advisable to look straight at the calibration code on the document to be calibrated to see what kind of calibration it is. In view of this point, the present invention can display the desired calibration code and calibration contents on the original document in the form of a calibration code displayed on a paper document in a document creation apparatus such as a computer, and if necessary, the displayed calibration code. It is an object of the present invention to provide a method of electronically correcting a word processor-based document correction function, which can modify the size and correction content of a document again.

In addition, another object of the present invention is to provide a word processor-based electronic document correction function capable of automatically generating a corrected document according to the correction code displayed on the original document and the correction contents.

Furthermore, another object of the present invention is to provide a computer readable storage medium storing a program implementing the word processor-based manuscript correction function.

According to claim 1 of the present invention for achieving the above object, in a method for enabling a correction operation for the original document using a word program in the document correction device, the user can select on the correction window screen of the document correction device Providing a plurality of calibration codes; If the user selects a specific proofing code and designates a position in the original document, the display is processed according to the user's instruction in the selected position. A user calibration task processing step of processing such that it is also displayed in association with the corresponding calibration code; And if the user instructs generation of a calibration document reflecting the calibration work, correspondingly generating a new calibration document reflecting the calibration code and the correction contents displayed on the original document. An electronic method is provided.

According to claim 2 of the present invention, in the method of claim 1, the calibration code is configured as an assembly of at least one or more unit parts, in order to provide size variability, so that the user can optionally use the calibration code indicated in the original document. Provided is a word processor based electronic document correction method characterized in that the size can be adjusted.

In order to achieve the above object, according to claim 3 of the present invention, in the method for enabling the correction operation on the original document using a word processor in the document correction device, the user selects on the correction window screen of the document correction device Providing a plurality of calibration codes that may be present; If the user selects a specific proofing code and designates a position within the original document, the display is processed according to the user's instruction at the location selected by the user so that the proofing code is displayed on the original document. If there is, there is a user calibration operation processing step for processing to be displayed in association with the corresponding calibration code, the calibration code is configured as an assembly of at least one or more unit parts, so that the user can Provided is a word processor based electronic document correction method characterized in that the size can be adjusted.

According to claim 4 of the present invention, in the method of claim 3, if the user instructs the creation of a calibration document reflecting the calibration work, in response to the step of generating a new calibration document reflecting the calibration code and the correction content displayed on the original document Provided is a word processor based document correction function electronics method further comprising.

According to claim 5 of the present invention, the method according to any one of claims 1 to 4, wherein the plurality of calibration codes, calibration code configuration information in which the type and attribute information of the unit parts required for its assembly are defined for each calibration code. Preparing a; Using the prepared calibration code configuration information, describe the generation information to compose the calibration code according to the defined nomenclature rules of the unit parts, and merge the unit parts into one to make the same as the calibration code according to this information. Creating a shape; And the calibration code making step of determining the calibration code attribute information, which is the information required when each unit part of the calibration code is displayed on the actual screen, and storing it in the data storage means. It is characterized by losing.

According to the sixth aspect of the present invention, in any one of the methods of any one of claims 1 to 4, the unit parts necessary for constituting each calibration code are i) the section of the calibration code perpendicular to the direction in which the character to be calibrated is displayed. Vertical division method that cuts it as a standard for generating unit parts constituting the calibration code, and ii) cuts the section of the calibration code in the same direction as the direction in which the text to be displayed is displayed and makes it the standard for generating unit parts constituting the calibration code. It is characterized by being obtained by applying any one of the horizontal division method.

According to claim 7, the method according to any one of claims 1 to 4, wherein the calibration code is one or more selected from among basic symbols (figure) such as left diagonal, right diagonal, circle, arc, vertical line, horizontal line Information about one or more unit parts represented by symbols (graphics); A base box for grouping the unit parts necessary to make the calibration code; And a identification table for storing ID and attribute information of the calibration code.

According to claim 8 of the present invention, the attribute information of the calibration code according to claim 7, wherein when the calibration code is inserted in the current position of the cursor in the calibration target line of the original document or the user-specified range, The target to be calibrated according to the center point (center position) information of the calibration code, which is the position information corresponding to the center, the size information, which is information on the size of the unit parts constituting the calibration code, and the calibration code displayed on the original document to be calibrated. Editing reflection range information, which is information on the position range of the characters, and whether the correction code can be adjusted for each direction, and size variable information, which is information on the adjustable range, is characterized by including.

According to claim 9 of the present invention, in the method of any one of claims 1 to 4, when the user instructs to open by designating the original document file to be calibrated to start the calibration operation, the designated original document is correspondingly opened. And automatically changing to the non-modifiable mode.

According to claim 10 of the present invention, the method of any one of claims 1 to 4, wherein the calibration operation processing step, if the user designates the position to be displayed while selecting the desired calibration code in the calibration window, the object position detection algorithm Therefore, as a step of finding a position on the original document in the calibration window to be displayed, the object position detection algorithm is a block selected by the user (correction) when the calibration code selected by the user is a code displayed on a block basis. Grasping the start point and the end point of the correction code so that the left and right reflection points of the calibration code are positioned at the start point and the end point, respectively. In the case of the calibration code displayed based on a cursor, the current position of the cursor is identified and the calibration code is located at the cursor position. Characterized in that it is a method for positioning the center point of the; After finding the position where the calibration code is to be displayed, each calibration part for the center point of the calibration code selected by the user based on the attribute information of each unit part constituting the calibration code and the cursor state or block state in the document to be calibrated. Displaying by adjusting the size of the; If the calibration code requires the user to input the calibration contents, the focus is placed on the input box of the calibration code so that the user can input the calibration contents. Displaying in a predetermined area of the code; And storing the attribution information and the calibration contents of the displayed calibration code.

According to claim 11 of the present invention, in any one of claims 1 to 4, correction, such as selection, movement, deletion, character input, resizing of the correction code instructed by the user with respect to the correction code displayed on the original document It is characterized in that it further comprises the step of processing the code change operation.

According to the twelfth aspect of the present invention, in the method of claim 11, the step of processing the correction code change operation regards an area in which the correction code exists as a virtual area in a new window that does not actually exist, and when the user clicks with a mouse, When the clicked point is located in the virtual area, the user considers the user to select the calibration code in the virtual area, and the message and the event generated in the calibration area are processed to change the calibration code. Characterized in that the modifications to the calibration code displayed on the original document.

According to claim 13 of the present invention, in the method of claim 11, wherein the step of processing the correction code change step, the step of monitoring whether or not the messages and events generated in the word processor program to be monitored; Extracting the message and the event and calculating the location of the message and the event and the location information on the screen on which the event occurs in the original document; Determining whether a mapping point in the original document of the event occurrence position is located in a virtual region of a calibration code; And if the mapping point is located in the virtual region of the calibration code, checking the recognition information of the calibration code existing in the virtual region, and if the recognition information exists, performing the change of the calibration code or the calibration content according to the generated message. It characterized by having a.

According to claim 14 of the present invention, in the method of claim 12, if the message generated in the state that the virtual region is not generated is a mouse click, the virtual region for the corresponding calibration code is generated (activated), and the virtual region is generated. If the mouse click event occurs in the activated (activated) state, the created virtual region is released (deactivated) .If the generated message is a mouse drag, the size of the virtual region (rearization size) is adjusted or the code is moved. If it is a keyboard input, an input through the keyboard is performed in the activated virtual area.

According to claim 15 of the present invention, the method of any one of claims 1 to 4, wherein the step of generating a calibration document, the step of reading the original document marked with the calibration code to copy the calibration document; Finding identification tag information defined by a user (program) existing in the calibration document; Identifying a reference part of the correction code corresponding to the identification tag when finding the identification tag, and finding a position on the document for the edit reflection range of the identified reference part, that is, a start point and an end point of the editing reflection range; Performing correction processing such as insertion, deletion, and modification on the found edit reflection range according to the function of the correction code; And a calibration code reflecting the calibration information, wherein the calibration code is deleted from the calibration document.

According to claim 16 of the present invention, in the method of claim 15, wherein the step of generating a calibration document further comprises the step of displaying a portion changed in the calibration document due to the reflection of the calibration contents to be distinguished from the uncalibrated portion. It features.

According to claim 17 of the present invention, in the method of any one of claims 1 to 4, in the case where a plurality of people performed the correction work on the original document, the original document so that each proofreader can be distinguished Characterized in that it is displayed in a different color.

According to claim 18 of the present invention, there is provided a computer readable recording medium having recorded thereon a program implemented to perform the word processor based document correction function electronicizing method according to any one of claims 1 to 4.

According to claim 19 of the present invention, a plurality of calibration code icons and icons or function buttons for instructing deletion of the calibration code and generation of reflection result of the calibration code are displayed on the screen for the user to select, A calibration code toolbar 42 for transmitting information corresponding to an ID or a function button to the calibration code display processing module 60; It manages the creation and release of virtual area to handle the area that contains correction protection as a new window, and allows the user to select the correction code, adjust the size of the correction code, or move the correction code. Providing a virtual area module 44; It provides the function of processing the calibration code to be displayed on the screen where the user wants, resizing the calibration code as much as the user resized, and moving and repositioning the calibration code at the position moved by the user. A calibration code display processing module 60; A location information processing module (65) providing a function of obtaining information on which a calibration code is located on the original document to be calibrated and a function of obtaining information on the screen of the calibration code; A program injection module 55 for providing a function of switching to a desired function through an event and a message generated from a word processor program and a function of switching to a desired function through an event and a message received from an operating system program; And a calibrator program including a virtual region mapping module 50 that provides a function of causing a message and an event to occur in the virtual region with respect to a calibration code existing in the virtual region. A computer readable recording medium is provided.

According to claim 20 of the present invention, in the recording medium of claim 19, the virtual area module 44 transmits the calibration code area (size) information to the calibration code display processing module 60 and the position information processing module 65. It provides the position information on the screen, and provides the program injection module 55 with the mouse (move / click) / keyboard messages and events and the position information on the screen.

According to claim 21 of the present invention, in the recording medium of claim 19, the calibration code display processing module 60 provides displayable calibration code ID information to the toolbar module 42, and provides the location information processing module 65 to the position information processing module 65. It is characterized in that the information on the calibration code display area is provided.

According to claim 22 of the present invention, in the recording medium of claim 19, the position information processing module provides the position information on the document to the virtual area module, and provides the position information on the document and the position information on the screen to the calibration code display processing module. It is characterized by providing.

According to claim 23 of the present invention, in the recording medium of claim 19, the program injection module delivers the mouse (move / click) / keyboard messages and events, location information on the screen, etc. to the virtual area mapping module 50 The virtual region mapping module provides information about the region of the calibration code to the virtual region module 44.

The present invention enables to display the correction code and the correction content on the electronic document in the same way as the paper document, so that the contents of the correction work performed can be intuitively recognized.

Since each calibration code is composed of an assembly of several unit parts, the size of the calibration code displayed on the screen can be freely adjusted according to the needs of the user. The variability of the calibration code increases the practical utility of the present invention.

In addition, the correction code is not merely displayed on the original document, but the correction operation of the original document is performed according to the displayed correction code. That is, the calibration code (correction document) reflecting the calibration code and the correction contents reflected in the calibration of the original document is automatically generated according to the user's instructions, thereby improving the efficiency of the calibration work.

First, an overview of the method of electronicizing a document correction function according to the present invention is outlined. The present invention creates a calibration code in such a way that the desired unit codes are assembled by appropriate combination of predetermined unit parts. This is to adjust the size of the calibration code as needed. For this purpose, the unit parts necessary to construct various various calibration codes are prepared in advance. In addition, for each calibration code, the unit parts necessary for its configuration are predetermined, and the ID and attribute information of the unit parts constituting each calibration code are defined. The calibration codes thus created are provided in the form of a user interface (UI) such as a tool bar or a pop-up menu. This is for the user to easily display the calibration code on the original document. The user can select the desired calibration code using the user interface. In addition, modifications are also made to existing document content, such as correction or addition of text. When the user selects a desired calibration code from the calibration code UI and designates a position in the original document, the calibration code is inserted into the designated location and displayed on the screen, and the calibration information related to the calibration code is stored in the storage means. If desired, the user can make additional modifications to the marked calibration code. When the user instructs the creation of a document reflecting the calibration work performed by the user, a calibration document is automatically generated according to the calibration code and the calibration content displayed on the original document.

"로 표시되는 "끌어올리기" 부호와 "

"로 표시되는 "끌어내리기" 부호 등)도 본 발명의 적용대상이 됨은 물론이다. The type of proofing code may vary from language to language. In addition, even in the same language calibration code may be different in the type of calibration code according to the user's request. Representative proof codes used to correct Korean documents are listed in Tables 1 and 2 below. Table 1 exemplifies general calibration codes used at the mouse click position, and Table 2 exemplifies range selection calibration codes used by setting a range (block). The calibration codes listed in the table are merely exemplary, and the present invention is not limited to the scope of application of the calibration codes. Other calibration codes not included in the table (eg "

"Pull" code and "marked with"

Of course, the " pull down "

[Table 1] General calibration code

[Table 2] Range Selection Calibration Code

In order to implement the present invention, it is necessary to make the above correction codes in advance and to make a database of information about them. In addition, a calibrator program should be prepared to assist the user in performing the calibration of electronic documents using the calibration codes. The calibrator program displays the prepared calibration code on the screen as a UI, and supports the user to calibrate the electronic document to be calibrated by selecting and modifying the desired calibration code. It is necessary to have a function of performing a process such as generating a corrected electronic document by reflecting the result.

The present invention can be carried out in a personal computer or a dedicated document calibration apparatus (hereinafter referred to as a 'calibration apparatus'). This device is designed for inputting letters, numbers and other user's instructions such as keyboards and keypads, instructions (such as a mouse and touchpad), user UI and documents provided by the calibrator program. Data storage means (e.g., a hard disk device, e.g., flash memory) for storing output means (e.g., a monitor and its control device), a calibrator program, a word processor program, an operating system program, a document related to a calibration operation, etc. Computer readable recording media such as nonvolatile memory devices, CDs, DVDs, etc., arithmetic processing devices (e.g. CPUs) that execute the programs, receive and process user inputs and instructions, and provide the results as output means. Etc.), and an auxiliary memory device (e.g. RAM) that provides storage for the processing unit to process data. . By executing a word processor program and a calibrator program together in this calibration apparatus, the document calibration method of the present invention can be performed.

1 is a software structural diagram required for carrying out the present invention. A calibrator program 10, word processor programs 20 and 25, and an operating system program 30 are needed to carry out the method of the present invention. Although the word processor programs 20 and 25 may use their own dedicated word processor programs, there are already well-made commercial programs such as Hangul programs and Microsoft Word (MS Word) programs. The calibrator program 10 is not dependent on any particular word processor. Hereinafter, the present invention will be described with a focus on a calibrator program 10 which, in cooperation with a word processor program, plays a central role in realizing the electronicization of document correction work.

The calibrator program 10 is a program executed on the external API 25 of the word processor program 20 running on the operating system (OS) 30. The calibrator program 10 includes a user interface (UI) 40 including a toolbar 42 and a virtual view module 44, a virtual view mapping module 50, and a program injection. Module (program injection module) 55, calibration code display processing module 60, position information processing module 65 and the like.

The calibration code toolbar 42 provides a function that allows the user to display the calibration code in the electronic document to be calibrated, delete the calibration code selected by the user, or generate a calibration code reflection result for the portion where the calibration code is displayed. to be. The calibration codes prepared for performing the calibration work are provided to the user through the calibration code toolbar 42. To this end, the calibration code toolbar 42 displays a plurality of calibration code icons and icons or function buttons for instructing deletion of the calibration code and generation of the result of reflection of the calibration code for selection by the user. In addition, information corresponding to the ID or function button of the calibration code selected by the user is transmitted to the calibration code display processing module 60. The calibration code toolbar 42 may be implemented in a form that is inserted into a word processor program in the form of a toolbar or pops up when a right button of a mouse is clicked.

The virtual region module 44 is a UI that manages creation and release of a virtual region and provides a function for allowing a user to select a calibration code, adjust the size of the calibration code, or move the calibration code. Although the virtual area is not actually displayed on the screen, the virtual area is a virtual area to be regarded as a separate area with respect to the area in which the calibration code is displayed in order to separately process a message and an event for the area in which the calibration code is displayed. This virtual area can be defined as, for example, an area that assumes a new window as an area surrounding the calibration code on the screen and can be regarded as having a calibration code therein. When the user clicks with the mouse and the clicked point is located in the virtual area, it is used as a reference area for determining that the user has selected a calibration code in the virtual area. When the user clicks on a point in a virtual area, the boundary of the virtual area is indicated by, for example, a hatch so that the user knows that the calibration code in the virtual area is now selected.

The calibration code display processing module 60 processes the calibration code to be displayed at a position on the screen desired by the user, resizes the calibration code by the size adjusted by the user, and applies the calibration code to the position moved by the user. Provides the ability to move and reposition.

The position information processing module 65 provides a function of obtaining information on which a calibration code is located on the original document to be calibrated, and a function of obtaining information on which a calibration code is located on the screen.

The program injection module 55 provides a function of switching to a desired function through events and messages generated by the word processor 20, and a function of switching to a desired function through events and messages received from the operating system 30.

The virtual region mapping module 50 provides a function that, when a message and an event occurs in the virtual region, appropriate processing associated with it is performed on the calibration code associated with the virtual region. For example, it provides a function to conveniently support the task of correcting the length or position of the calibration code displayed in the virtual area, or provides a separate view where the work can be corrected and reflects the work contents in the Korean document at the completion of the work. To provide. A more detailed description thereof will be described later.

The toolbar module 42 transfers the calibration code ID information to be displayed to the calibration code display processing module 60, and the calibration code display processing module 60 provides the display of the calibration code ID information that can be displayed to the toolbar module 42. The virtual area module 44 transmits the calibration code area (size) information to the calibration code display processing module 60 and, on the contrary, receives the success status and the message from the calibration code display processing module 60. Information is also exchanged between the virtual area mapping module 50 and the location information processing module 65, the former providing the position information on the screen to the latter and the latter providing the position information on the document to the former. The calibration code display processing module 60 provides the position information processing module 65 with information on the calibration code display area and receives the document position information and the screen position information from the position information processing module 65. The virtual region mapping module 50 provides the virtual region module 44 with information about the region of the calibration code. The virtual area module 44 provides the program injection module 55 with a mouse (move / click) / keyboard message and events, location information on the screen, and the program injection module 55 provides a virtual area mapping module 50. It delivers mouse (move / click) / keyboard message and event, location information on screen.

2 is an overview of the overall process for performing an electronic document proofing operation according to the present invention. The user first executes the word processor program 20 and the calibrator program 10 for calibration. Then, open the original document to be calibrated, display the calibration code on the desired part (S12), and if necessary, select and correct the displayed calibration code (S14) to perform the calibration work, and when the calibration work is completed, the calibration code is completed. It is made through the process of generating the corrected document by executing reflect (S16).

Create proof sign ( S10 )

The calibration code is not constant in size, and preferably has size variability in each direction so that the size can be increased or decreased in any direction. To provide this size variability, a scheme is adopted in which the calibration code is constructed as an assembly of at least one unit part objects. That is, the present invention takes the form of assembling the appropriate unit parts to make the desired calibration code. In other words, various units of calibration code units are prepared as minimum units necessary to construct various types of calibration codes as shown in Tables 1 and 2, and each calibration code assembles one or more calibration unit units necessary to construct it. To use the configuration method. This method has several advantages, such as being able to flexibly adjust the size of the calibration code.

How to configure the unit parts eventually leads to the problem of constructing the smallest unit that can accommodate the variability of the calibration code. For the production of unit parts, each calibration code is divided into minimum unit parts in consideration of the smallest unit of the representable code, the direction in which the code may appear, and the attribute information of each unit part code is defined. And set the unit parts necessary for the composition for each calibration code.

3 shows the process of making a calibration code (S10) in more detail. First, the shape of the unit part to be used for the assembly of the calibration code is made (S20), and the operation of actually making the unit part using the shape of the prepared unit part is performed (S22). CALIBRATION SYMBOL The unit part is a shape that expresses a part of a calibration symbol.

 When the necessary unit parts are prepared, the calibration code configuration information is set through operations such as defining the type and attribute information of the unit parts necessary for the configuration for each calibration code (S24).

'Attribute information of unit part' includes field information value when composed of part information expression value and calibration code. The part information representation value includes a value about a part ID and a size. Fields necessary for the composition of calibration code include identification table ID, calibration code ID, reference part, screen display, reflection point position, size adjustment (left / right, up / down), size information (height, width), etc. There is this. The corresponding values of these fields are predefined. Here, the term 'reference part' refers to a part that is a reference of a display position when a calibration symbol is displayed on a screen, and includes a 'center point'. The term 'center point' refers to the positional information that will be displayed on the screen of the calibration symbol. The value of this 'center point' is in the text direction (from left to right). Ii) the selection criterion correction ratio, which is the ratio of the font size of the smallest characters among the characters in the selection range. The term 'reflection point' is a starting point and an ending point for the calibration, and serves as a reference point for expressing the range of change / delete / insertion according to the nature of the calibration code. The identification table is a part for identifying the user-defined figure in the electronic document and gives a specific ID value. This identification table stores each attribute field and its value used for each calibration code. 'Algorithm ID' is an identifier for distinguishing a calibration code, and is a value for distinguishing the processing work for each calibration code in the application step.

'Intersection code composition information' is the result information of the design for constructing the calibration code, and it corresponds to the design diagram defining the characteristics of the calibration code to be made. This information includes a list of parts to compose the calibration code, and defines the reference part, reflecting point and its range, size information, calibration code ID, and whether or not to display the display, depending on the nature of the calibration code. For example, the configuration information for the spacing correction code may include parts (identification tables, outlines, diagonal lines (left / right)), reflection points (intersections where the left / right diagonals meet), and size adjustments (up / down / left / right). Not all), and the center point (80% of the font size ratio).

'와 같이 되고, 정의된 값도 저장된 상태로 된다. When the calibration code configuration information is prepared, shape-making is performed for each calibration code by using the information (S26), and the display information of the calibration code is determined and stored in the data storage means for the calibration code for which the shape is completed. (S28). 'Display information of calibration code' is actual value of information related to screen processing among design information (configuration information) of calibration code such as reflecting point, center point, size control, calibration code character (cursor standard / range selection standard) Information defined by. The value defined in the calibration code generation information is set in the attribute field of the identification table part of the calibration code. For example, if the display information of the letter insertion correction code is set, the shape of the correction code is'

', And the defined value is saved.

In the step of creating the calibration code shape (S26), the generation information for configuring the calibration code is described according to the defined naming convention of the unit parts, and the unit parts are merged into one so that the same as the calibration code. Make. 'Interrogation code generation information' is a value expressing the configuration information of the correction code to make the correction code according to a predetermined description syntax, and also describes necessary attribute information. This information takes the form of information listed in text. For example, the 'paste correction code', the configuration information is BOX1_TON_BOX1_BOX2 = 0010_V1, TON. The composition information of this paste calibration code is made of parts BOX1, TON, BOX1, BOX2, and the calibration code ID is 0010, the calibration code generation version is V1, and the reference part is TON.

으로 된다.In the calibration code display information storing step (S28), information necessary for displaying each unit part on the actual screen according to the calibration code generation information, for example, calibration code attribute information and the like, is described. The data concerning the calibration code thus prepared is preferably stored in a computer in a database form. 'Attribute information of correction code' is any value expressing correction code. That is, all the values set for the parts constituting the calibration code. Fields not used in the property field of a part are set to a value of "N", which is a field to be skipped in the program. When the correction code is finally made, the shape of the letter insertion correction code is

Becomes

You need to know what kind of unit parts are needed to make a complete calibration code and how to assemble the unit parts to form a calibration code. In order to know which unit parts to prepare (S20, S22), it is useful to divide the calibration code into the minimum unit required, that is, the unit parts. Correction code division methods may include a horizontal division method and a vertical division method.

"(72)이 배치되고 하부영역(B)에는 V자의 좌우측에 수평날개가 연결된 다른 하나의 부품"

"(74)이 배치되는 형태이다. 이 가로분할법은 적은 수의 부품으로 교정부호를 구성할 수 있어 부호 구성이 단순하고 교정부호를 만들기가 쉽다는 장점이 있다. 하지만, 마디절은 수평방향 실선으로 표시된 세 곳인데, 이들 마디절 간의 수직방향 폭(A, B)의 크기 조절은 쉽게 이루어질 수 있으나 수평방향으로의 크기 조절은 용이하지 않다. 가로분할법은 이러한 약점 외에도 부품 상호간의 연결성을 부여하기가 모호하고 교정부호 반영범위를 정하는 것도 애매하며, 단위부품의 재사용이 어려운 점도 약점 이다.In the horizontal division method, the section of the calibration code is cut in the same direction as the text is displayed, and this is used as a standard for generating unit parts constituting the calibration code. 4 is a view for explaining the case of forming the letter insertion correction code 70 according to the horizontal division method. Letter insertion correction mark 70 is divided into two areas (A, B) of the upper and lower parts, one part combining the left and right diagonal lines in the upper area (A). "

"(72) is arranged in the lower region (B) the other component connected to the horizontal blades on the left and right sides of the V-shape"

"(74) is arranged. This horizontal division method has a merit that the calibration code can be composed of a small number of parts, so that the code construction is simple and the calibration code is easy to make. However, the section is a horizontal solid line. There are three places marked with, the vertical width (A, B) of these nodes can be easily adjusted, but the horizontal size is not easy. Also, it is ambiguous to define the range of corrective codes to be ambiguous, and it is also difficult to reuse the unit parts.

In the vertical division method, the section of the calibration code is cut in a direction perpendicular to the direction in which the text is displayed and used as a reference for generating unit parts constituting the calibration code. FIG. 5 is a diagram for explaining the case of forming the letter insertion correction code 70 according to the vertical division method. Letter insertion correction 70 may be divided into six unit parts (82, 83, 84, 85, 86, 87) as shown. There are seven nodes in the vertical direction, so it is easy to reflect the adjustment of the width (A, B, C, D, E, F) between each node. In addition, it is easy to provide connectivity between parts, easy to set initial position and size at the time of displaying the calibration code, clear reflection range of the calibration code, and easy reuse of parts. While the vertical division method has such advantages, it is difficult to make the calibration code because the calibration code is complicated and it is difficult to make the calibration code by assembling many unit parts.

Hereinafter, a method of dividing the calibration code into unit parts according to the vertical division method and merging will be described as an example. Those skilled in the art will be able to easily apply the horizontal division method by using the description of the vertical division method, and thus, only the necessary parts will be mentioned for the horizontal division method for the purpose of overlapping the description.

In the preparation of the unit parts (S20, S22), it is necessary to provide a variety of calibration code unit parts that can assemble all kinds of calibration codes to be made. Corrections can be expressed by combining some of the most basic symbols (figure). The various types of proofing unit components desired may be combined with one or more of the basic symbols (figures) required to represent the proofing symbols, such as left diagonal, right diagonal, circle, arc, vertical line, horizontal line, polygon, etc. You can make it. Each calibration code therefore contains information about one or more of the unit components that make up it. In addition, a basic box for grouping the various unit parts needed to make a calibration code into the same group, and a identification tag for storing the ID and attribute information of the created calibration code are needed. The types and uses of these most basic symbols are summarized in Table 3 below.

[Table 3] The most basic symbols (figure) for the assembly of calibration codes and unit parts

Type of sign function Remarks Dog Tag Symbol that stores ID and attribute information of code (unit part or calibration code) BOX1 Default box Outline frame symbol containing identification tag and code (unit part or calibration code) in one group BOX2 Left diagonal Left diagonal sign LDL Right diagonal Right diagonal sign RDL won Round shaped symbol JLC Arc Arc-shaped symbol TON vertical A vertical symbol VER horizon Horizon shaped symbol OHO

As there are various types of calibration codes, there are various types of unit parts necessary to make them. With the proper combination of the basic symbols (figure) mentioned above, it is possible to create various kinds of calibration codes by hand or to produce various kinds of unit parts necessary to make the calibration codes. Table 4 below shows the various unit components required to make the calibration codes shown in Tables 1 and 2 using the basic symbols (figure). If necessary, prepare additional unit parts.

[Table 4] Unit parts for calibration code assembly

In Table 4, 'Y' and 'N' are screen output parts and parts that are not on screen, and 'Y / N' means parts that may or may not be displayed on screen in some cases. . For example, LDL should not be boxed, so 'Y / N' of BOX2 or EDC is 'N'. When 'Y / N' becomes 'Y', it is meaningful when the calibration code is actually made, for example, when the EDT or post-it function is used. The information stored in the box 1 corresponding to the identification table includes ID information and attribute information of the corresponding unit part. BOX2 corresponding to the basic box includes the sign and the identification tag of the unit part when used as a box indicating the unit part, and when used as a box indicating the calibration code, the identification box of the calibration code and the calibration code Contains unit parts. BOX1 and BOX2 must be included in all unit parts or calibration codes. The EDC and EDT contain two BOX2s, one of which is a box that is not displayed on the screen and the other is a box that is displayed on the screen, which contains the actual calibration. The line break symbol RLD is illustrated in the form of a unit part in the table below, but alternatively, it may be in the form of a calibration symbol assembled with a 90 ° rotated LCO, an RCO, and arrows made of separate parts. As such, unit parts or calibration codes may be flexibly defined and used according to the needs of use.

The calibration code generating method (S24, S26, S28) will be described. 6 conceptually illustrates a method of assembling unit parts to generate a calibration code. According to the vertical division method, a calibration code is constructed by vertically arranging necessary unit parts. In FIG. 6, (a) merges related unit parts without overlapping, while (b) merges related unit parts by overlapping them. The code thus obtained may be a complete calibration code or another unit part. In addition, (C) shows that the calibration code can be made by merging with other unit parts by using the symbol 2 obtained in (B) as a unit part. In this way, the unit parts can be merged to generate new unit parts or calibration codes, and the unit parts or calibration codes thus created can be merged with other unit parts or calibration codes to generate another unit parts or calibration codes.

When generating the calibration code, set the information about the type of unit parts constituting the calibration code (for example, ID information of the component parts) for each calibration code. Also, attribute information on the calibration code is set. Attribute information of the calibration code includes center point (center position) information of the calibration code, part size information, edit reflection range information, and size variability information. The center point information is the position information corresponding to the center of the display of the calibration code when the calibration code is inserted in the current position of the cursor in the calibration target line of the original document or the range specified by the user. The ratio information between the height from the basic position (the bottom reference line of the calibration target line) to the center point of the calibration code with respect to the font size of the character of the target line. Here, the size of the correction target line is preferably set to the font size of the largest letter among the left and right letters of the center point. The part size information is information about the size of the unit parts constituting the calibration code, and the size (height / width) of each part to the center point of the calibration code (or to the maximum height of the line to be calibrated) when the calibration code is inserted. It can be expressed as ratio information of. The information on the edited reflection range is information on the position range of characters to be corrected according to the correction code displayed in the original document to be corrected, and can be determined by designating two reflecting points, a start point and an end point of the position range. The action of the part specifying the scope of editorial reflection, ie the 'reference part', will be described in detail in the description of the correction information. The variability information (direction information) is information about whether the calibration code can be adjusted in each direction and the adjustable range, and whether the user can adjust the size of the calibration code and, if possible, to what extent in which direction Information that can be indicated by the presence or absence. When inserting the calibration code, it is preferable to set the center position (X, Y coordinate value) of the calibration code variably according to the size of the line to be calibrated (that is, the character or sentence to be calibrated).

Configuration information and default values of the calibration codes generated according to the calibration code generation method described above are illustrated in Tables 5 and 6, respectively. The generated calibration codes are stored in a database. In the table below, the 'size of the part' is expressed as the position value of the center point, which is to reduce unnecessary calculation since the center point itself is a font ratio with respect to the reference character. The value expressed in the height of the part is a ratio value expressed based on the height value of the center point. For example, if the center point height value is 100 and the height value of the part is 20%, the height of the part is 100x0.2 = 20. The height value 20 of this part is the height at the center point. The same is true for the width of the part. That is, the value displayed on the width of the part is a ratio value expressed with respect to the center point, and is a value expressed with reference to the height value of the center point. For example, if the height of the center point is 200 and the part width is 20%, the width of the part is 200x0.2 = 40. The width of the calibration code is the sum of the widths of the components, ie the sum of the ratios. Here, in the case of the general calibration code based on the position of the cursor, the center point of the calibration code is the ratio of the height of the left character to the Y coordinate of the center point based on the character immediately to the left of the cursor, and the X coordinate of the center point is the cursor. It is a circumference point of the width between the character where is located and the left character. In the case of a range selection calibration code, the center point of the calibration code is determined by the Y-coordinate of the center point of the calibration code based on the smallest sized character in the selected block. Both end points of the selection block become reflection points.

[Table 5] General calibration code (sign used at the position where mouse is clicked)

[Table 6] Range selection calibration code (Calibration code used by selecting a range (block))

To display the calibration code on the screen ( S12 )

The procedure of displaying the calibration code on the screen (S12) first allows the calibration code assembly to be displayed first in basic form, and then allows the user to adjust the size of the calibration code assembly. When the correction code is first displayed in the basic form, each unit part has its own attribute information. Therefore, the position information and the size of each unit part are determined by looking at the attribute information. In addition, when displaying the calibration code, it is displayed in accordance with the block selected by the user according to the type of the calibration code or in accordance with the current cursor position. When the whole unit part is assembled, the characteristics according to the properties of each unit part may appear. Hereinafter, a process of displaying the calibration code on the screen will be described in more detail.

When a user performs a calibration operation on a document to be calibrated, a series of processes are performed to display the result of the calibration operation on the screen. The detailed flow of the operation of displaying the calibration code on the screen is shown in FIG. The calibration operation is performed while the word processor programs 20 and 25 and the calibrator program 10 are executed together in the calibration apparatus. As a preliminary step in full-fledged calibration, it is advisable to change the original document to non-modifiable mode. That is, when the user instructs to open the original document file which is the target of the calibration work to start the calibration work, the designated original document is automatically changed into the non-modifiable mode accordingly. This is because, despite the corrections, the original document needs to be preserved as it is. When the user specifies the original document to be corrected in the word processor program, the calibrator program 10 automatically changes the original document to the non-modifiable mode (S30).

In order to enable the user to efficiently perform the calibration operation on the original document that has been changed to the non-modifiable mode, a user interface in the form of a toolbar menu or a pop-up menu marked with a calibration code is provided on the calibration window screen. 8 illustrates a toolbar menu 90 for serving as a user interface. When the user clicks (selects) the desired calibration code in the user interface (S32), the selected calibration code is automatically displayed at the desired position on the screen on which the original document is displayed (S34). In order to display the calibration code and the corrections (i.e., modifications to replace the original contents) on the screen, i) the function to find the calibration code and the position on the screen of the original document where the corrections will be displayed, and ii) It is necessary to calculate and display the size and position of each calibrated component, to display the input calibration text at a predetermined position, and iii) to store attribute information and calibration text information of the displayed calibration code.

It is effective to utilize the function provided by the word processor to find out exactly where the calibration code and the calibration contents will be displayed. The present invention uses an object position detection algorithm (Object Position Detecting Algorithm) specially designed for the display of the calibration code. The word processor provides a 'block selection' function as one of the editing functions. In the case of a calibration code displayed on a block basis, the user selects a word to be corrected using this function. The object position detection algorithm detects the start and end positions of the block (word) selected by the user, and displays the corrected codes so that the left and right reflecting points of the corresponding corrected codes are positioned with respect to the start and end points. In the case of the calibration code displayed on the basis of the cursor, the calibration code is displayed so that the current position of the cursor is determined and the center point of the calibration code is located there. The positioning of the center point of the calibration code and the size of each part are calculated according to the criteria mentioned above.

In order to apply the object position detection algorithm to, for example, a Hangul word processor, the object position detection algorithm preferably includes a position mapping function to support both the side outline and the general mode provided in the Hangul program. The document viewing methods provided by Korean word processors include page view and general view. These two viewing methods have a certain ratio relationship in the location information. That is, since the location information values differ according to the document viewing method, it is necessary to generalize the location information and map the location information according to the document viewing method. The position of the cursor or the position of the selection block in the document to be calibrated can be obtained from the word processor API. If the location information value is X in the page outline view and Y in the normal mode, the general expression of the location information according to the relative value between the page outline view and the general view is as follows.

X: Y = (the current position value): (the position value to obtain) ..... (1)

After finding the position where the correction code is to be displayed, the user adjusts the size of the correction code designated by the user according to the cursor state and the block state in the document to be corrected (S36). In case of general calibration code shown in Table 5, it shall be indicated according to 'Cursor reference code display' method. Cursor reference code display method is to position the center point of the calibration code according to the letter size on the left and right sides of the cursor at the specific point specified by the user in the electronic document to be calibrated, adjust the size of the reference part, and then place the reference part. The parts to be placed on the top, bottom, left, and right sides of the center are adjusted in size according to the ratio set based on the position of the center point. 9 illustrates a process of displaying a space correction code based on a position of a cursor. When the position of the cursor is the arrow point, the horizontal coordinate (X coordinate value) of the center point of the space is equal to the horizontal coordinate of the cursor, and the vertical coordinate (Y coordinate value) is the letter of the largest size of the line to be corrected. The height of a predetermined ratio with respect to the height of "B" is determined by the vertical coordinate value of the center point = the font size of the letter "B" x the predetermined ratio when the reference position is viewed as 0. Once the center point is located, the spacing correction code is first displayed as the base size as shown in (A), and then the size of the right and left diagonal unit parts is immediately determined as shown in (B) and (C). Change the display according to the size of the display. In practice, it will display the state of (C) through a series of calculations required.

The range selection calibration code shown in Table 6 shall be indicated by the 'block reference code display' method. 10 shows a process of displaying the letter change correction code in this manner. First, as shown in (A), the block reference code display method finds the start point and the end point of the selected block in the electronic document to be calibrated, and places the left and right reflecting points of the reference part of the corresponding calibration code at the positions thereof, respectively. Unit parts shall be marked on the left and right sides of the reference part as the basic size first. In this case, the center point of the calibration symbol is automatically located at the center of the start point and the end point, and the height is defined as the height of a predetermined ratio with respect to the height of the letter “B” of the largest size of the line to be calibrated as described above. Then, adjust the size of the remaining parts other than the reference part in order as shown in (B) to (E) based on the position of the center point.

The method of adjusting the position and size of the unit part of the calibration code will be described in more detail by taking the example of the character change correction code shown in FIG. 11 (the block reference display symbol and the reflection points are A1 and A2). The adjustment of the calibration code is done by locating the center point (C) of the calibration code and changing the size of the unit parts starting from the reflecting point of the calibration code based on the connection point between the unit parts and toward the next connection point adjacent thereto. Adjust the size. In step-by-step, first, the reflection points (A1, A2) of the calibration symbol are positioned at the start and end points of the block selected by the user (the height of the center point (C) of the reference part is determined according to the rules described above). Adjust the size of the unit part L1 between the reflecting point A1 and the connection point B1. The starting position of the unit part L1 becomes the connection point A1 and starts from this position to change the width and height of the unit part L1. Subsequently, the size of the part between the connection point B1 and the connection point C1 is also adjusted. The starting position of the unit part L2 becomes the connection point B1, and from this position, the width and height of the unit part L2 are changed. In this way, the size of the unit parts R1 and R2 is adjusted.

In the adjustment of the calibration code, the boundary point (section) between the unit parts allowed to be adjusted is the size adjustment point. For example, the unit parts A, B, and C are adjacent in the vertical direction, and the unit parts A and C are allowed to be resized, but the unit part B positioned between them is not the upper part of the unit part A and the unit part C. The resize point is only displayed at the bottom of the. Also, if there are other parts to the top based on the part with edit reflecting range, it should not be resized to the bottom of the edit reflecting range. If there is another part at the bottom based on the part with edit reflect range, it should not be resized to the top of the edit reflect range.

If the calibration code is required to input the user's calibration contents, the focus is placed on the input box so that the user can immediately input the desired contents. The calibration contents entered by the user are displayed in the calibration code area. In this way, the result of the calibration work performed by the user (calibration code and calibration content) is processed so that the original document is displayed overlapping with the original document in the calibration work window in which the original document is displayed (S38). In displaying the calibration code, in case of insufficient space, the function of displaying the calibration code in the reverse direction should be provided and utilized. 12 shows an example in which the calibration code and the calibration contents are displayed on the original document in the calibration window 95 according to the calibration code display method described above. As shown, the proof sign is available for tables as well as letters.

Types of information necessary for displaying and reflecting calibration information include basic information, location information, reflection information, and stationery information. The basic information (identification table) of the calibration code includes the designation code number and the number of configured unit parts. Position information of the calibration code is the position information to be displayed in the calibration target within the electronic document. The reflection information of the correction code includes division (change, deletion, edit information) and target information (start point, end point). The phrase information of the correction code includes a change phrase (phrase to be reflected) or an information phrase (information phrase).

Select and modify calibration code S14 )

The calibration code displayed on the screen can be selected and modified by the user. Program-Injection Technology provides this functionality. The program-injection technology uses the operation (event) information and the message information generated by the word processor 20 to check the recognition information and the location information of the calibration code to determine whether the calibration code is desired. It is a technique that allows a function to be performed. Specifically, event information and message information generated in the word processor 20 are provided to a queue of the OS 30. The program injection module 55 browses the queue of the OS 30 and determines whether or not the correction code is selected. That is, the action or message that occurred is that of the word processor 20, the predefined action information (e.g. events such as mouse clicks or keyboard presses) and the message information (e.g. reduce the size of the window, close the program, exit) Message), it is determined whether the calibration code is selected by checking the recognition information of the calibration code and the position information on the screen. When the selection of the calibration code is confirmed, the calibration code recognition information and the position information on the screen are provided to the corresponding module to perform a predefined function.

The present invention also provides a virtual area mapping technology (Virtual-) to provide a function for conveniently supporting a change operation (correction code selection, movement, deletion, character input, size adjustment, etc.) displayed on the calibration window screen. view Mapping Technology). This virtual area mapping technology considers the area where a calibration code exists as a virtual area of a new window that does not actually exist, and changes the calibration code for messages and events generated within this calibration area. Technology. It provides a separate view where corrections can be made to the correction code and provides a way to reflect the work in the word processor electronic document at the completion of the correction.

13 and 14 are functional description screens and detailed processing flowcharts of the virtual region mapping module 50, respectively. In FIGS. 13 and 14, the virtual region mapping module 50 treats the position where the calibration code 105 is as a virtual view 100. When messages and events occur in word processor 20 they are delivered to OS 30 and entered into message queue 35. The calibrator program injection module 55 monitors message and event occurrences by viewing the message queue of the OS 30 and when a monitored message is detected (for example, [MSG: MOUSE / location: X = 300, Y]. 100)), and extracts the message and the event, and transmits the message and the event and the location information (eg, (x, y) = (300, 100)) on the screen where the event occurred to the virtual region mapping module 50. To pass. The virtual area mapping module 50 calculates in cooperation with the location information processing module 65 whether the received location information on the screen is mapped to which location in the original document. Since the generated message is a mouse that is one of the desired messages, check the information (recognition table) of the calibration code existing at the mapping position (for example, the 10th paragraph and the 30th column) in the original document of the event occurrence position (300,100). If this check confirms that there is a tag, the generated event and message are related to the function to be performed on the calibration code. Therefore, the following correction function is executed according to the generated message. If the message generated when the virtual area 100 is not created is a mouse click, the virtual area 100 for the corresponding calibration code is generated (activated), and the virtual area 100 is generated (activated). If a mouse click event occurs, the generated virtual region 100 performs a function to release (disable). In addition, if the generated message is a mouse drag (virtual region 100 is already generated), the size (correction code size) of the virtual region 100 is adjusted or the code is moved. In addition, in the case of keyboard input, an input value through the keyboard is performed in the activated virtual area 100 (for example, the inputted characters are inputted in the correction code input window or the selection or deletion of the correction code). For this processing, the virtual region mapping module 50 transmits the calculated mapping position (eg, 10th paragraph, 30 columns) information and message / event information to the activated virtual region module 44. The result processed by the virtual domain module 44 is transmitted to the word processor 20 through the calibration code display module 60, the location information processing module 65, the word processor API 25 and displayed together in the original document.

Reflect the correction code S16 )

15 sequentially shows a process of reflecting the contents of the correction work performed by the user, taking the letter change correction code as an example. A reflection button (not shown) for instructing a user to generate a calibration document reflecting the calibration work is provided to the user UI, for example. When the user presses the reflect button (not shown), a calibration document reflecting all of the calibration work performed by the user with respect to the original document is generated.

 The process of creating a calibration document reflecting the calibration code indicated on the original document is made by modifying the contents of the original document according to the calibration code to reflect the calibration contents, and deleting the calibration code after the reflection is completed. The calibrator program 10 and the word processor 20 program work together to perform this process. Specifically, first, read the entire original document marked with the calibration code and copy it to the calibration document (see FIG. 15A). Then, the identification tag information defined by the user (program) existing in the original document is found (see FIG. 15B). There may be various marks or marks in the original document, in order to distinguish among them the calibration codes according to the present invention. When the identification tag is found, it is checked the edit reflecting range part of the calibration code corresponding to the identification tag, that is, the reference part (the unit part indicated by "A" corresponds to the reference part in C of FIG. 15), and the identified reference part Find the starting point and end point of the editing reflection range in the document, i.e., the editing reflection range. (The starting point (A) and the ending point (B) of the unit part across the letter "Slope" in FIG. 15D) Range). The information existing in the edited reflection range thus found is subjected to correction processing such as insertion, deletion, change, etc. according to the function of the correction code (the correction code is the character change in FIG. Change the "slope" to "three sides"), so that the user can recognize the changed information (e.g., the reflected portion "three sides" is displayed in a different color). As shown in (F) of FIG. 15, the calibration code reflecting the calibration content is deleted from the calibration document.

16 exemplifies an original document on which the calibration operation displayed on the calibration task window 95 is performed and a calibration document reflecting the results of the calibration operation performed on the calibration reflection window 97, respectively. The proofs in the proof documents are shaded. In addition, there may be a case where several people perform correction work on one original document. In this case, as illustrated in FIG. 17, when the secondary proofer corrects again on the original document corrected by the primary proofreader first, the original document may have different colors so that the portions corrected by these two proofers can be distinguished. It is preferable to make the display (for example, the calibration performed by the primary calibrator in red and the calibration performed by the secondary calibrator in blue).

The present invention can be widely used in the field requiring the document correction work. For example, when the National Assembly amends or revises legislation, when amending or revising contracts between contractors, and when creating various publications such as magazines, reference books, novels, etc. Communication can be made smoothly about the correction or correction of the manuscript between the documents, and the efficiency of the correction work can be greatly improved.

1 is a software structural diagram required for carrying out the present invention.

2 is an overview of the overall process for performing an electronic document proofing operation according to the present invention.

3 is a detailed flowchart of the calibration code making step S10 of FIG. 2.

4 is a view for explaining a method of making a letter insertion correction code 70 according to the horizontal division method.

5 is a view for explaining a method of making a letter insertion correction code 70 according to the vertical division method.

6 conceptually illustrates a method of assembling unit parts to generate a calibration code.

7 shows the detailed flow of the operation S12 of displaying the calibration code on the screen.

8 illustrates a toolbar menu 90 for serving as a user interface.

9 is a diagram for describing a method of displaying a calibration code based on a cursor position by using a space calibration code as an example.

FIG. 10 is a diagram for describing a method of displaying a correction code based on a block range by using a character change correction code as an example.

11 is a view for explaining in detail the method of adjusting the position and size of the unit part of the correction code by taking the letter change correction code as an example.

12 shows an example in which the calibration code and the calibration contents are displayed on the original document in the calibration window 95.

13 and 14 are functional description screens and detailed processing flowcharts of the virtual region mapping module 50, respectively.

15 illustrates a process of reflecting contents of a calibration operation performed by a user by taking a letter change correction code as an example.

16 exemplifies an original document on which the calibration operation displayed on the calibration task window 95 is performed and a calibration document reflecting the results of the calibration operation performed on the calibration reflection window 97, respectively.

17 shows an example in which a calibration document calibrated by two calibrators displays different colors of calibration contents for each calibrator.

Explanation of symbols on the main parts of the drawings

10: calibrator program 20: word processor program

30: operating system program 40: user interface

42: toolbar module 44: virtual view module

50: virtual mapping module module

55: program injection module

60: calibration code display module 65: location information processing module

Claims (27)

In the method of enabling the correction work on the original document using a word program in the document correction device, Providing a plurality of calibration codes selectable by a user on a calibration window screen of the document calibration device; If the user selects a specific proofing code and designates a position in the original document, the display is processed according to the user's instruction in the selected position. A user calibration task processing step of processing such that it is also displayed in association with the corresponding calibration code; And If the user instructs the generation of a calibration document reflecting the calibration work, correspondingly generating a new calibration document reflecting the calibration code and the correction contents displayed on the original document. Way. The method of claim 1, wherein the calibration code is configured as an assembly of at least one or more unit parts to provide size variability, so that the user can adjust the size of the calibration code displayed on the original document as necessary. A word processor based electronic document correction method. In the document correction apparatus using a word processor to enable the correction work on the original document, Providing a plurality of calibration codes selectable by a user on a calibration window screen of the document calibration device; If the user selects a specific proofing code and designates a position in the original document, the display is processed according to the user's instruction in the selected position. If there is, it is provided with a user calibration operation processing step of processing to be displayed in association with the corresponding calibration code, The proofing code is configured as an assembly of at least one or more unit parts, so that the user can adjust the size of the proofing code displayed on the original document as necessary. [4] The word according to claim 3, further comprising the step of generating a new calibration document reflecting the calibration code and the calibration contents displayed on the original document when the user instructs the generation of the calibration document reflecting the calibration work. Processor-based electronic document correction. The method according to any one of claims 1 to 4, wherein the plurality of calibration codes Preparing calibration code configuration information for which each type of calibration code defines the type and attribute information of the unit parts required for assembly thereof; Using the prepared calibration code configuration information, describe the generation information to compose the calibration code according to the defined nomenclature rules of the unit parts, and merge the unit parts into one to make the same as the calibration code according to this information. Creating a shape; And With respect to the calibration code for which the shape has been completed, the calibration code attribute information, which is necessary information when each unit part of the calibration code is displayed on the actual screen, is determined and stored in the data storage means. Method for digitizing the document correction function based on a word processor. 5. The unit parts according to any one of claims 1 to 4, wherein the unit parts necessary for constituting each calibration code are i) cutting the section of the calibration code at right angles to the direction in which the character to be corrected is displayed to form a calibration code. Either the vertical division method of generating the unit parts, or ii) the horizontal division method of cutting the section of the calibration code in the same direction as the direction in which the text to be displayed is displayed and making it the generation standard of the unit parts constituting the calibration code. A word processor based manuscript correction function electronic method, characterized in that obtained by applying. The method according to any one of claims 1 to 4, wherein the calibration code is represented by one or more symbols (figure) selected from basic symbols (figure) such as left diagonal line, right diagonal line, circle, arc, vertical line and horizontal line. Information on one or more unit parts; A base box for grouping the unit parts necessary to make the calibration code; And a identification table for storing ID and attribute information of the correction code. 8. The method of claim 7, wherein the attribute information of the calibration code is position information corresponding to the center of the display of the calibration code when the calibration code is inserted in the current position of the cursor in the calibration target line of the original document or the range designated by the user. Information on the center point (center position) of the calibration code, size information, which is information on the size of the unit parts constituting the calibration code, and position range of characters to be corrected according to the calibration code displayed on the original document to be calibrated. Editing range of the word processor-based manuscript correction function, characterized in that it includes the information on the editing range, the size of the correction code can be adjusted for each direction, and the size variable information which is information about the adjustable range. The method according to any one of claims 1 to 4, wherein when the user instructs to open the original document file to be corrected to start the proofing operation, the user automatically changes the designated original document to the non-modifiable mode accordingly. A word processor-based manuscript correction function electronic method, characterized in that it further comprises a step. The method of any one of claims 1 to 4, wherein the calibration operation processing step, When the user selects a desired calibration code in the calibration window and designates a position to be displayed, the user can find a position on the original document in the calibration window in which the calibration code will be displayed according to the object position detection algorithm. If the selected calibration code is a code displayed on a block basis, the method determines a starting point and an end point of a block (word) selected by the user so that the left and right reflection points of the calibration code are located at the start point and the end point, respectively. In the case of the calibration code displayed on the basis of the cursor, characterized in that the method for determining the current position of the cursor to position the center point of the calibration code at the cursor position; After finding the position where the calibration code is to be displayed, each calibration part for the center point of the calibration code selected by the user based on the attribute information of each unit part constituting the calibration code and the cursor state or block state in the document to be calibrated. Displaying by adjusting the size of the; If the calibration code requires the user to input the calibration contents, the focus is placed on the input box of the calibration code so that the user can input the calibration contents. Displaying in a predetermined area of the code; And And storing the attribute information of the displayed proofing code and the proofing content. The method according to any one of claims 1 to 4, further comprising a step of processing a correction code change operation such as selection, movement, deletion, character input, and size adjustment of a correction code indicated by a user with respect to the correction code displayed on the original document. A word processor based manuscript correction function electronic method according to claim 1, further comprising a. 12. The method of claim 11, wherein the correcting code changing operation process regards an area in which a correcting code exists as a virtual area of a new window that does not actually exist, and when the clicked point is located in the virtual area when the user clicks with a mouse. It is assumed that the user selects the calibration code in the virtual area, and the message and the event generated in the calibration area are processed so that the change of the calibration code is made. A word processor based electronic document correction method, characterized in that for performing a change operation. The method of claim 11, wherein the correcting code change operation processing step, Monitoring whether messages and events occurring in the word processor program correspond to a monitoring target; Extracting the message and the event and calculating the location of the message and the event and the location information on the screen on which the event occurs is mapped in the original document; Determining whether a mapping point in the original document of the event occurrence position is located in a virtual region of a calibration code; And If the mapping point is located in the virtual region of the calibration code, checking the recognition information of the calibration code existing in the virtual region, and if the recognition information exists, performing the change of the calibration code or the calibration content according to the generated message. Method for digitizing the document correction function based on a word processor, characterized in that it comprises. 13. The method of claim 12, wherein if the message generated when the virtual region is not created, a mouse click is generated (activated), and a mouse click is generated (activated) for the corresponding calibration code. If an event occurs, the created virtual area is released (disabled) .If the generated message is a mouse drag, the virtual area is resized or the sign is moved.If it is a keyboard input, the virtual area is activated. A word processor based electronic document correction method, characterized in that for performing input through a keyboard. According to any one of claims 1, 2 and 4, wherein the step of generating a calibration document, Reading the entire original document marked with the calibration code and copying the original document; Finding identification tag information defined by a user (program) existing in the calibration document; Identifying a reference part of the correction code corresponding to the identification tag when finding the identification tag, and finding a position on the document for the edit reflection range of the identified reference part, that is, a start point and an end point of the editing reflection range; Performing correction processing such as insertion, deletion, and modification on the found edit reflection range according to the function of the correction code; And The proofing code reflecting the correction content is a word processor-based original document correction function characterized in that it comprises the step of deleting from the proof document. The method of claim 15, wherein the step of generating a calibration document, And displaying the changed part in the proofing document so as to be distinguished from the uncorrected part due to the reflection of the proofing content. The method according to any one of claims 1 to 4, wherein when a plurality of persons make a correction on the original document, the original document is displayed in a different color so that each proofreader can distinguish the corrected part. A word processor based electronic document correction method. A computer-readable recording medium having recorded thereon a program implemented to perform the word processor-based document correction function electronicization method according to any one of claims 1 to 4. A number of calibration code icons and icons or function buttons for instructing deletion of calibration codes and generation of reflection results of the calibration code are displayed on the screen for the user to select, and information corresponding to the ID or function button of the calibration code selected by the user A calibration code toolbar 42 which transmits the to the calibration code display processing module 60; It manages the creation and release of virtual area to handle the area that contains correction protection as a new window, and allows the user to select the correction code, adjust the size of the correction code, or move the correction code. Providing a virtual area module 44; It provides the function of processing the calibration code to be displayed on the screen where the user wants, resizing the calibration code as much as the user resized, and moving and repositioning the calibration code at the position moved by the user. A calibration code display processing module 60; A location information processing module (65) providing a function of obtaining information on which a calibration code is located on the original document to be calibrated and a function of obtaining information on the screen of the calibration code; A program injection module 55 which provides a function of switching to a desired function through an event and a message generated from a word processor program and a function of switching to a desired function through an event and a message received from an operating system program; And When a message and an event occurs in the virtual area, a calibrator program including a virtual area mapping module 50 that provides a function of causing a process related to the calibration code existing in the virtual area to be recorded is recorded. Computer-readable record media. 20. The apparatus of claim 19, wherein the virtual area module 44 transmits the calibration code area (size) information to the calibration code display processing module 60, and provides on-screen location information to the location information processing module 65. A computer-readable recording medium having a calibrator program recorded thereon, which provides the program injection module 55 with mouse (move / click) / keyboard messages and events and location information on the screen. 20. The apparatus of claim 19, wherein the calibration code display processing module 60 provides displayable calibration code ID information to the toolbar module 42, and provides the position information processing module 65 with information on the calibration code display area. A computer-readable recording medium having a calibrator program recorded thereon. 20. The calibrator program of claim 19, wherein the position information processing module provides position information on the document to the virtual area module and provides position information on the document and position information on the screen to the calibration code display processing module. Computer readable media. 20. The method of claim 19, wherein the program injection module delivers mouse (move / click) / keyboard messages and events, location information on the screen, etc. to the virtual area mapping module 50, and the virtual area mapping module transmits the virtual area. A computer-readable recording medium having a calibrator program recorded thereon which provides the module 44 with information about the area of the calibration code. In the method of automating document correction using a computer, A calibration code is indicated for calibration of the original document, wherein the calibration code is constructed by assembling a plurality of calibration symbol unit parts, and at least some of the unit parts may vary in size as necessary. If the correction code is a method for automating the original, characterized in that it comprises the step of changing the overall size but the original shape is maintained. 25. The method of claim 24, further comprising the step of displaying a desired calibration code at a desired position according to a user's instruction, and if there is an input of the calibration content, it is also displayed in association with the corresponding calibration code. Way. 25. The manuscript according to claim 24, further comprising, when the user instructs the creation of a calibration document that reflects the calibration work, in response to the user creating a new calibration document that reflects the calibration code and the calibration content displayed on the original document. How to automate calibration. 27. The unit parts according to any one of claims 24 to 26, wherein the unit parts necessary for constituting each calibration code are i) cutting a section of the calibration code at right angles to the direction in which the character to be corrected is displayed to form a calibration code. Either the vertical division method of generating the unit parts, or ii) the horizontal division method of cutting the section of the calibration code in the same direction as the direction in which the text to be displayed is displayed and making it the generation standard of the unit parts constituting the calibration code. Automated document correction method characterized in that obtained by applying.

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