JPH0812668B2 - Handwriting proofreading method - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a document processing apparatus that edits a document using handwritten proofreading symbols, and particularly to various proofreading without being aware of the input procedure or the input end instruction. The present invention relates to a document editing method suitable for inputting symbols and interactively performing editing processing.

[Background of the Invention]

Conventionally, as an editing system using a handwritten proof symbol for a document, for example, Information Processing Vol.15 No.6, p419-427 (197
As described in 4), there is known a system in which a one-stroke calibration symbol is entered in an editing target position to interactively perform online editing work. However, the calibration symbol is limited to one stroke, and
Since it is not possible to specify the edit target area, it is difficult to use, such as editing one character at a time.

Also, as described in IPSJ 28th National Convention Proceedings 4N-11, there is a system that uses a combination of a closed curve and one curve as a calibration symbol to edit offline. It was not possible to edit interactively because it was not a calibration symbol used in and was offline.

[Object of the Invention]

An object of the present invention is to provide a degree of freedom in a combination relationship and to speed up processing when defining a calibration symbol in a combination of a plurality of strokes in a document processing system such as a document processing workstation and a word processor. It is to provide a handwriting proofreading method that can be achieved.

[Outline of Invention]

According to the present invention, various calibration symbols defined by a combination of a plurality of strokes are held in advance in relation to a combination of a plurality of strokes that are respectively configured for each calibration symbol, and strokes input from a coordinate input device are recognized in stroke units. Then
This recognized stroke determines which calibration symbol in the previously held combinational relationship corresponds to, and repeatedly executes the recognition and determination processing until a state where there is no stroke input for a predetermined time is detected, It is characterized in that a calibration symbol satisfying the combination relation is recognized, and a calibration process corresponding to the recognized calibration symbol is executed.

Example of Invention

An embodiment of the present invention will be described below with reference to FIGS.

(1) Outline of Embodiment This embodiment is a document creation apparatus for inputting and editing and outputting characters or figures by handwriting. FIG. 1 is a block diagram of this embodiment. The coordinate information a of characters, figures, and calibration symbols handwritten by the coordinate input device 1 such as a tablet is sent to the character / graphic / element symbol recognition unit 2 and is recognized online. The character / graphic / element symbol recognition unit 2 recognizes constituent elements of an input character, a graphic, and a calibration symbol based on coordinate information, and various methods are known. For example, there is a method described in JP-A-58-123117 for character recognition and a method described in Technical Report IPA64-3 for the Television Society of Japan for figure recognition.

At the time of character / figure input, the recognition result b is sent to the character / figure data generation unit 3 to generate display data c for actually displaying the character / figure, which is the character / figure data storage unit 6 It is described in. The character / graphic data h stored in the character / graphic data storage unit 6 is displayed by the display device 7 each time.

On the other hand, when editing, the character / graphic / element symbol recognition unit 2
Recognizes the calibration symbol for each component based on the input coordinate information a and sends the recognition result d to the calibration symbol recognition unit 4. The proofreading element is recognized by the proofreading symbol recognition unit 4, which uses a character / graphic recognition technology, and recognizes a combination of a plurality of constituent elements as one proofreading symbol when a predetermined constituent condition is satisfied, and an edit command e corresponding to the recognition result. Is output to the character / graphic editing processing unit 5. Details of the processing of the calibration symbol recognition unit 4 will be described later.

The character / figure edit processing unit 5 fetches the character / figure data f stored in the character / figure data storage unit 6 and actually performs a process corresponding to the input edit command e,
The edited character / graphic data g is output to the character / graphic data storage unit 6. The edited character / graphic data h is displayed on the display device 7 each time.

A document is interactively created by the input and editing work described above.

(2) Calibration Symbol Recognition Processing of calibration symbol recognition in the calibration symbol recognition unit 4 will be described with reference to FIGS. 2 and 3.

FIG. 2 shows a recognition target handwritten calibration symbol of this embodiment.
Delete character string from 1 stroke k, erase without area designation from 2 strokes l, m, erase with area designation from 3 strokes l, m, n, move without area designation from 2 strokes o, p, with area designation The movement is from three strokes o, p, q, the enlargement / reduction is from four strokes r, s, t, u, and the character string correction is three strokes v, w, x and the corrected character string y _n (n = 1,2, ...).

As described above, each proof symbol is a combination of one or more strokes (components) and a correction character string. These constituent elements are classified into four types according to their meanings, that is, a command symbol component indicating the contents of processing, an area designating portion indicating the processing target area, a lead line indicating the relationship between the source and the destination, and a correction character string. Taking movement as an example, stroke o is a command symbol, stroke p is a lead line, and stroke q is an area designation. However, some calibration symbols do not require all four components.

FIG. 3 shows a flow of the calibration symbol recognition process. In this embodiment, each stroke input recognizes the stroke as a component of the calibration symbol and the combination thereof is recognized as one calibration symbol. At this time, it is determined whether or not the calibration symbol is satisfied by using a component element flag described later. When the calibration symbol is established, the editing process is actually performed.

First, the input stroke for initializing the component flag (process 41) is recognized as a component for each stroke (process 43), and the component flag is updated according to the recognition result (process 44). Details of this processing will be described later. processing
43 and processing 44 are repeated until there is no fixed time.

When there is no input for a certain period of time, it is determined that the calibration symbol has been input (process 42), and the determination of what calibration symbol the entire already-input component constitutes (process 45) is performed by the component flag. Details of the determination will be described later. When the corresponding calibration symbol does not exist, it returns to the first process. If it exists, the editing process corresponding to the calibration symbol is actually performed (process 46), and if the editing work is continued, the process returns to the first process.

(3) Recognition of components The calibration symbols shown in FIG. 2 are classified into four types of command symbols, lead lines, area designations, and correction character strings as described above. FIG. 4 shows which constituent elements are candidates. However,
In FIG. 4, deletion and movement are treated as different calibration symbols with and without area designation.

Here, in order to improve the recognition rate, the same input stroke is optimally regarded as a constituent element for each calibration symbol. For example, a stroke corresponding to a command symbol for deleting a character string is processed as a leader line candidate in the case of movement. The error indicates that it cannot be considered as any component of the calibration symbol.

In this embodiment, as described above, each stroke input is recognized as a constituent element, and the constituent element flag of each calibration symbol is updated according to the recognition result. As shown in FIG. 5, as component flags, four types of command symbols, lead lines, area designations, correction character strings, and errors are assigned to each calibration symbol. The numbers shown in FIG. 5 are initial values and are made to match the number of constituent elements of each calibration symbol. In addition, all error flags are set to "0".

The procedure for updating the component flag is shown in FIG. First, it is known from FIG. 4 which component of the first calibration symbol (character string deletion) the recognition result of the input stroke corresponds to (process 442). Next, the corresponding component flag is decremented (-1) (process 443). Hereinafter, the same processing is performed for all calibration symbols.

(4) Recognition of Calibration Symbol As described above, in the present embodiment, the determination of the end of calibration symbol input is made based on the no-input time after stroke input, and then the calibration symbol is recognized. It will be described with reference to the drawings. If all the constituent elements of the input calibration symbol have been input without excess or deficiency at the end of input, the fact that the corresponding constituent element flags are all 0 is used, and this is the condition for the calibration element to be satisfied.

First, it is determined whether or not all the component element flags corresponding to the first calibration symbol are 0 (process 452), and if not, the same determination is performed for the next calibration symbol. If all are 0, it is judged whether the input calibration symbol is reasonable (process 456). This is to confirm the recognition result. For example, in the case of erasing, it is rational if the two input line segments intersect, and irrational if they are apart. If it is unreasonable as a calibration symbol, move to the next determination of establishment of the calibration symbol. If it is reasonable, this proofreading code shall be satisfied (process 457). When all the calibration symbols are not satisfied, the corresponding calibration symbol does not exist (process 458). When it is satisfied, the corresponding editing process is actually performed as described above.

(5) Effects of this Embodiment According to one embodiment of the present invention described above, there are the following effects.

First, since the present embodiment has an online handwritten character / graphic recognition process and is also used when inputting a calibration symbol, it is possible to input handwritten characters and graphics online, and in parallel with the input. Editing can be done interactively using handwritten proof symbols.

Secondly, when recognizing the calibration symbol, after recognizing the calibration element unit, if the input component group satisfies a predetermined calibration condition, the whole is recognized as one calibration symbol. No need to consider.

Thirdly, if there is no input for a certain period of time, it is automatically determined that the calibration symbol input is completed and the editing process is executed, so that the user does not need to give an instruction to execute the editing.

Fourth, since one input stroke is recognized as the optimum calibration element for each calibration symbol, there is less erroneous recognition of the calibration symbol.

Fifth, since the number of components of the calibration symbol can be set freely, you can keep the calibration symbol that you use everyday.
The user can perform the same editing work as he or she does on daily paper.

(6) Other Embodiments of the Present Invention Next, other embodiments of the present invention will be described. In the above-described embodiment of the present invention, characters and figures are input online, but if a scanner is used as an input device, it is possible to edit a document that has already been written.

Further, in the embodiment, seven kinds of calibration symbols are used, but the kinds of calibration symbols may be set freely. Further, although there are four types of constituent elements, they may be freely changed depending on the calibration symbol used.

In one embodiment, when there is no input for a certain period of time, it is automatically judged that the calibration symbol input is completed and the editing process is executed, but the user may instruct the execution of editing. If one calibration symbol does not include another calibration symbol, the component flags may all be “0” and the corresponding editing process may be executed.

〔The invention's effect〕

According to the present invention, different calibration symbols can be recognized as different calibration symbols even when the strokes (components) forming the same have a common portion, so that a plurality of calibration symbols can be recognized. When defining with a combination of strokes, it is possible to give the combination relation a degree of freedom, and since recognition and determination in units of strokes are repeated until a state where there is no stroke input for a predetermined time is detected, The processing speed can be increased.

[Brief description of drawings]

FIG. 1 is a block diagram of one embodiment of the present invention, and FIGS. 2, 4, and 5 are diagrams for specifically explaining one embodiment of the present invention, FIG. 3, FIG. 6, and FIG. FIG. 7 is a flowchart for explaining the processing of one embodiment of the present invention. 1 ... Coordinate input device, 2 ... Character / figure / element symbol recognition unit,
3 ... Character / figure data generation unit, 4 ... Proofreading symbol recognition unit, 5
... character / figure edit processing unit, 6 ... character / figure data storage unit, 7 ... display device.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hiroshi Masashima 3-1-1 Sachimachi, Hitachi City, Ibaraki Hitachi Ltd. Hitachi Research Laboratory (56) References JP-A-57-155675 (JP, A) ) JP-A-59-20039 (JP, A) JP-A-59-229684 (JP, A) JP-A-61-80478 (JP, A) Information processing, 25 [8] (SHO-59-8-15) P ． 869-874

Claims (1)

[Claims] 1. A coordinated input device for inputting a handwritten calibration symbol, a storage means for storing data for displaying characters or graphics, a computer for processing the data, and a display means for displaying characters or graphics. In the handwriting proofreading method, various calibration symbols defined by a combination of a plurality of strokes are held in advance in a combination relation of a plurality of strokes constituting each calibration symbol, and strokes input from the coordinate input device are stroked. Recognize in units, determine whether the recognized stroke corresponds to which calibration symbol in the pre-stored combinational relationship, and perform the recognition and determination process for a state in which there is no stroke input for a predetermined time. Until the calibration symbol that satisfies the above combination is recognized and the calibration process corresponding to the recognized calibration symbol is performed. Handwritten calibration method characterized by rows.