JPS62269262A - Kana (japanese syllabary) kanji (chinese character) converting and inputting device - Google Patents

Abstract

PURPOSE:To minimize the movement of an operator's visual point by displaying phonetic symbols at the time of inputting a natural sentence in the same display position as display position of phonetic symbols after conversion. CONSTITUTION:Codes constituting a character string displayed in a display section 16 are stored in a text buffer 15. The starting position of inputting is made to the first position (a position where a character [a] is displayed) on the display section 16, and phonetic symbol string [WATASHI WA EKI E IKU] (I go to the station) are inputted successively from an inputting section 2. Under such a condition, natural sentence input start key is inputted first from the inputting section 2.

Description

[Detailed description of the invention] (b) Industrial application fields The present invention relates to a human-powered kana-kanji conversion device.

(b) Prior Art Currently, Japanese 7-word processors that can convert input phonetic characters into ideographic characters and create sentences containing kana and kanji are becoming popular.

Conventionally, this type of conversion method involves inputting phonetic characters (for example, kana characters) in units of words and then inputting a delimiter key to instruct conversion (Japanese Patent Publication No. 14688/1988), or converting phonetic characters in units of phrases. There is a method (Japanese Code Processor 5WP-3300 manufactured by Sanyo Electric Co., Ltd.) in which a delimiter key is input to instruct the conversion after inputting .

However, in the conventional method, it is necessary to input a delimiter key to instruct conversion for each word or phrase, which is an unnatural input method from the operator's perspective.

Therefore, in place of the conventional conversion method, each time a phonetic character is input, it is automatically determined whether or not the phonetic character string input so far constitutes a clause, and based on this determination, A method (hereinafter referred to as the natural literary power method) has been proposed in which a part of the phonetic character string determined to be a phrase is converted into an ideographic character.

(c) Problems to be Solved by the Invention In devices in which the above-mentioned method has been adopted, normally, as shown in FIG. Text display section (32)
The unconverted phonetic string is divided into kite line parts (3
1), display the converted phonetic string in the text display area (32).
It is configured to be displayed on the screen. Therefore, the operator confirms the phonetic characters input from the input section in the guideline section (31) at the bottom of the display screen (30), and also confirms the conversion result in the text display section (32) at the top of the display screen (30). Therefore, there has been a problem that the movement of the viewpoint becomes large, increasing the fatigue level of the operator and resulting in a decrease in the speed of human power.

(d) Means for solving the problem The present invention has been made in view of the problem, and its structural features include an input means for inputting phonetic characters, and a phonetic character input from the input means. A manual buffer in which codes corresponding to characters are stored in the order in which they are input, a clause judgment rosinc which judges the clause structure of the code string in the human cover/fa each time a code is input to the input buffer, and a clause judgment rono /
A conversion target buffer in which the code string constituting the first clause among the code strings is stored when it is determined that there is a clause, and a second buffer in which code strings other than the code strings forming the first clause are stored. Ha7hua, a kana-kanji logic that converts and outputs the code string in the conversion target buffer into a code string representing an ideographic character string, a first output banophor in which the code string converted and output from the kana-kanji logic is stored, and a display section. , a text buffer that stores a code corresponding to a character string displayed on the display section, a save register that stores input start position information into the text buffer, a save buffer that can store a predetermined number of code strings; The code string in the save buffer is written into the text buffer starting from the position in the text buffer corresponding to the position information in the save register, and then the code string is stored in the first output buffer 7. When the code string in the first output buffer is written from the position in the text buffer that corresponds to the position information in the save register, the next position after the last position of such writing is written to the save register. At the same time, the predetermined number of codes in the text buffer starting from the Lth position are stored in the save buffer, and then the code string in the second output buffer is written from the next position in the text buffer, and the code string in the second output buffer is written from the next position in the text buffer. If the code is not stored in the 1st output cover 7.F, the above C
= Writing to read the predetermined number of codes from a position in the text buffer corresponding to the position information in the brain star, store them in the save buffer, and then write the code string in the second output buffer from the above position in the text buffer. This is due to the fact that it is equipped with long stems.

(E) Operation In this configuration, the codes in the text buffer in which codes corresponding to unconverted phonetic characters are written are held in the save buffer.

(F) Embodiment FIG. 1 shows an embodiment of the present invention, and 1) is a main control section composed of, for example, a microcomputer, and the main control section controls the various sections described below.

(2) is an input section consisting of, for example, a keyboard, and the input section includes a plurality of character keys for inputting phonetic characters such as kana, alphabets, numbers, etc., and a plurality of symbol keys for inputting period marks, etc. , there is a start key and an end key for instructing the start and end of the natural literary ability, respectively.

(3) is a key determination section, and this determination section is the input section 2.
> determines the type of key input, and outputs the result to the main control section (1). Further, if the key inputted from the input section (2) is a character or symbol key, the determination section (3) outputs a code corresponding to the key and also outputs a +13 UPI.

(4) is an input buffer, and the codes output from the key determination section (3) are stored in the manual buffer in the order in which they are output. In this embodiment, for convenience of explanation, the maximum number of codes stored in the buffer (4) is set to 40.

(5) is an input counter, and this counter is connected to the main control unit (
1) is also reset based on No. R1 from NoriSt.
Further, the content is increased by 11'' due to the +1 signal UPI from the key determination section (3).

Therefore, the contents of the input counter (5) are the number of characters and symbols stored in the manual buffer (4>).

(6) is a clause judgment logic, which inputs the character symbol code stored in the human buffer (4) according to the clause judgment statement BH from the main control unit (1), , and determine the number of clauses forming the code string. To determine such phrases, for example, the code string is divided into ψ words using a method similar to that disclosed in Japanese Patent Publication No. 53-29504, and the parts of speech of the nt words are identified. This can be done based on the part of speech structure of the code string.

In addition, when it is determined in this way that the code string in the manual buffer (4) is composed of two clauses, the Rontsuku (6) sends "11" to the main control unit (1) as a clause presence/absence signal BU. If not, output '0'.

Furthermore, when it is determined that the code string is composed of two clauses, the logic (6) executes the code string conversion target buffer (7) that constitutes the first clause of the code string.
), and the code string that constitutes the last clause is stored in the second output buffer (11), and each of the above buffers (
7) Store the numbers of codes stored in (11) in the buffer counter (8) and the second counter (12), respectively. If it is determined that the code string in the input buffer (4) does not consist of two clauses, the logic (6) stores all such code strings in the second output buffer (11) and calculates the number of codes. (same as the contents of the input counter (5)) is stored in the second counter (12>).

Furthermore, when the conversion end signal HS is input from the main control unit (1), the logic (6) stores the code string in the input buffer (4) in the all-unit conversion target buffer (7>) and stores the code string in the input buffer (4). (same as the content of the number input counter (5)) is stored in the bar/fa counter <8>.

(13) is a kana-kanji logic, which reads the code string for one phrase stored in the conversion target buffer (7) based on the conversion instruction signal HD from the main control unit (1), and A phonetic character string represented by a code string is converted into a kana-kanji-mixed character string that includes ideographic characters such as kanji. Then, the code string representing the converted character string is stored in the first output buffer (9), and the number of codes is stored in the first counter (10).
The detailed explanation will be omitted since it is well known from Publication No.-29504 and the like. Further, the first counter (10) is connected to the main control unit (
The contents of the reset temperature signal R2 from 1) are ' o
, i, = cleared.

(14) is a change circuit, which changes the second counter (12) based on the change signal HK from the main control unit (1).
and writes the contents of the second output buffer (11) to the input counter (5) and input buffer (4).

(15) is a text buffer, and the buffer 7 stores a code representing a series of character strings (sentences) inputted from the human resources department (2).

(16) is a display section made of, for example, a CRT, which reads out the code stored in the text buffer (15) and visually displays characters, symbols, etc. corresponding to the code.

(17) is a write logic, which, as will be explained in detail later, is connected to the first and second output buffers (9) <11).
Write the contents of to the text buffer (15>).

(18) is a write pointer, and the write position information to the text banner 7 (15) is stored in this pointer. Further, the contents are increased by 1 by the +1 signal UP2 from the write logic (17).Furthermore, the contents of the save register, which will be described later, are read and held by the cent signal SS from the write logic (17). .

(19) is a save register, which reads and holds the contents of the write pointer (18) based on the heap signal S output from the write logic/ori (17).

(20) is a save buffer, which receives the read signal R1 from the main control unit (1) or the write logic <1
Based on the readout signal R2 from 7), the code for 40 characters is read from the text buffer (15) starting from the position in the text buffer (15) corresponding to the position information held in the save register (19). Read and hold. Also, write from write logic (17) (!F @
Based on W, the code held in the save buffer (20) is stored in the text buffer (15), starting from the position in the text buffer (15) that corresponds to the position information held in the save register (19). write to.

FIGS. 2 to 4 are flowcharts showing the operation of the device of this embodiment after the natural humanities start key is input from the input section (2), and the basics of the device of this embodiment are explained based on these flowcharts. Explain the behavior of the target.

The main control unit (1) receives a type signal from the key determination unit (3) to indicate that the natural literary ability start key has been input from the input unit (2).
) is detected, first, in step S1, a reset signal R1 is output to reset the contents of the input counter (5) to "0."

Next, in step S2, save register (19)
Set a predetermined value to . Incidentally, the predetermined value is a value indicating the leading position in the text buffer (15) when writing a code into the text buffer (15) in subsequent processing.

In the following step S3, the save buffer (20) is sent. In terms of body A, a save buffer (20) reads and holds a code of 40 characters from a text buffer (15) based on the store number R1 outputted from the main control section (1). Incidentally, the above-mentioned 40-character code is 40 codes starting from the position in the text buffer (15) corresponding to the position information held in the save register (19).

Next, in step S4, the first counter (10) is activated based on the reset signal R2 output from the main control section (1).
is cleared to '0'.

Thereafter, in step S5, key input from the input section (2) is awaited, and if there is key input, the process proceeds to step S6.

In step S6, the key determination unit 3) determines whether the key input in step S5 is the end key for natural literary and human skills, and if it is determined to be the end key, the process proceeds to step 56.
Proceed to step 01. If it is determined that the key is not the end key, the process proceeds to step S7.

In step S7, the key determining section 3) determines whether the key input in step 85 is a character or symbol key. If the input key is determined to be a character or symbol key, the process proceeds to step S8; otherwise, the process returns to step S5. Note that when the input key was determined to be a character or symbol key in step S7, the process was returned directly to step S5, but if a key instructing deletion, insertion, etc. was input, these processes could be repeated. It is also possible to configure the system so that the process returns to step S5 after the process is completed.

In the S8 step knob, when a character or symbol key is input from the input section (2), the code output from the key judgment section (3) is stored in the power buffer (4), and in the next <39 steps, the code is output from the key judgment section. (3) +IM issue UP1 output from
Based on this, the contents of the input counter (5) are incremented by 1.

Next, in step S10, the clause of the code string stored in the input buffer (4) is determined. Specifically, based on the phrase determination signal BH output from the main control unit (1>), the phrase determination logic (6) reads the same number of codes as the numerical value in the input counter (5) from the input buffer (4),
It is determined whether the character string made up of the read code string has a two-clause configuration. If it is determined that the phrase is composed of two clauses, the above logic (6) transfers the code string constituting the first clause of the code string in the input buffer (4) to the conversion target buffer (7). , the code strings constituting the trailing clause are stored in the second output buffer (11), respectively, and the conversion target buffer (7) and the second output buffer ( 11) stores the number of codes constituting each code string stored in 11). Then the above logic (6)
outputs "rl" to the main control unit (1) as the clause presence/absence signal BU.

Furthermore, if it is determined that the phrase is not composed of two clauses, the logic (6) stores all the code strings in the human buffer (4) in the second output buffer (11), and also stores the code string in the input counter (5). The contents of the second counter (12)
10'' is then output to the main control unit <1> as the clause presence/absence signal BU.

In the SII step, the main control unit (1) determines whether the phrase presence/absence signal BU output from the phrase determination unit (6) is "1."
If it is determined that 'BU≠1', the process jumps to step S14, and if it is determined that 'BU'1., the process advances to step 512.

In step S12, the code string indicating the phonetic symbol string stored in the conversion target buffer 7 (7) is converted into the code string indicating the ideographic symbol string, which is a character string containing kana and kanji. Specifically, in response to the conversion instruction signal HD output from the main control unit (1), the kana-kanji logic (13) controls the buffer counter (
8) is read from the conversion target buffer (7), and the read code string is converted into a code string representing the corresponding character string containing kana and kanji, and the code string is converted into the code string. is stored in the first output buffer (9). Also, at this time, the logic (13) stores the number of codes stored in the first output buffer (9) in the first counter (10).

The contents of the input buffer (4) and input counter (5) are changed using the control knob (513). Specifically, in response to the change signal HK output from the main control unit (1), the change circuit (14) reads the contents of the second output buffer (11) and the second counter (12), and reads the contents of the input buffer (11) and the second counter (12). 4> and write to the input counter (5). Therefore, when the process of step S13 is completed, the contents of the input buffer (4> and input counter 5) are the same as the contents of the second output buffer (11) and the second counter (12), respectively.

Upon completion of step S13, the process proceeds to step 914.

In the 514 Sden knob, in response to the write instruction signal WS1 from the main control unit 1), the write logic (17)
Write the code in the output buffer (9) (11) to the text buffer (15).

FIG. 3 is a flowchart showing such a write operation, and the above operation will be explained based on this flowchart.

First, in step 5140, the code held in save buffer γ(2o) is written to a predetermined position in text buffer y(15). Specifically, writing rontsuku (17)
In response to the write signal W output from the save buffer γ(
20) reads the position information from the save register (19>) and writes the text H/F (15) represented by such position information.
), the codes in the save buffer (20) are sequentially written into the text/'.'' sofa (15).

In the continuation step <3141, it is determined whether the first output buffer (9) is full of codes. Such a determination is made when the write logic (17) reads the contents of the first counter (10) and the contents are 10. This can be done by checking whether or not.

In such a determination, the content of the first counter (10) is 10.
If it is determined that this is the case, the process jumps to step 5145, and if not, steps 8142 to 5144 are sequentially processed.

In step 5142, the write pointer <18) reads and holds the contents of the save register <19) in response to the set signal SS output from the write register (17).

Next, in the 5143 Ste Knob, the first output buffer (9
) is read out from the beginning as many times as the contents of the first counter (10), and the code stored in the text buffer (1
5).

Specifically, the write logic (17) reads the code stored at the beginning of the first output buffer 9) and the position information in the write pointer (18), and reads the position information in the text buffer (18) corresponding to the position information. 15) Insert the above code t-
Write. After that, write Ron 7ri (17) +1 signal UP
2 is output and the contents of the write pointer (18) are incremented by "rl".

The write logic (17) then writes the first output buffer (9)
Code and write pointer (18) located at the second position of
The code is written to the position in the text buffer (15) corresponding to the position information. Thereafter, the write logic (17) outputs the +IGlt signal UP2 and increments the contents of the write pointer (18) by 11''.

Similarly, the third and subsequent codes in the vg1 output buffer (9) are stored in the text memory (15).

In step 3144, the save register (1) is read in response to the save signal S output from the write logic (17).
9) reads and holds the contents of the write pointer (18).

Upon completion of these steps, processing proceeds to step 5145.

At step 5145, the save buffer (20) is set as in step S3. Specifically, in response to the read signal R2 output from the write lock (17), the save buffer (20) reads and holds the code for 40 characters from the text memory (15). There are 40 codes starting from the position in the text buffer γ (15) corresponding to the position information held in the save register (19).

In the following step 5146, the set signal SS outputted from the write logic 17〉 similarly to the step 5142 is
In response, the write pointer (18) moves to the save register (1
9) is read and held.

Next, in step 5147, the second output buffer (11
) are stored in the second column in order from the beginning.
Reads as many times as the contents of (12) and saves them to the text buffer (
15).

Specifically, the write logic (17) outputs the code stored at the beginning of the second output buffer (11) and the position information in the write pointer (18), and writes the text corresponding to the above position information. Write the above code to the position in the buffer (15), then write ron/ri (17) +l:t@U
P2 is output and the contents of the write pointer (18) are incremented by 11''.

The write logic (17) then writes to the second output sofa (11).
) and write pointer (18) located at the second position of
The code is written to the position in the text buffer (15) corresponding to the position information. The write logic (17) then outputs a +1 signal UP2 to increment the contents of the write pointer (18) by 111.

Thereafter, the third and subsequent codes in the first output buffer (9) are similarly stored in the text buffer (15).

When step 5147 is completed, the process returns to step S4.

Further, returning to step S6, in step 5601, which is proceeded when the natural humanities end key is input in this step, the main control unit (1) reads the contents of the input counter (5), and the contents are 10. Determine whether or not. In such a determination, '0. If it is determined that this is the case, all the processing that started from step 81 will be completed. In addition, in the above judgment, if it is judged that it is not 0.
Proceed to step 602.

In step 5602, in response to the conversion end signal H3 output from the main control unit (1), the phrase judgment Ron/ri (6
) unconditionally stores the code string in the input buffer (4) and the numerical value in the input counter (5) into the conversion target buffer (7) and the buffer counter (8).

In step S12, the code string indicating the phonetic symbol string stored in the conversion target buffer (7) is converted into the code string indicating the ideographic symbol string, which is a character string containing kana and kanji. Specifically, in response to the conversion instruction signal HD output from the main control unit (1), the kana-kanji logic (13) converts the codes for the numerical values that can be stored in the buffer counter (8) into the conversion target buffer (7). At the same time, this code string is converted into a code string representing a corresponding character string containing kana and kanji, and the converted code string is stored in the first output vanofa (9). At this time, the logic (13) outputs the first output cover 7 to the first counter (1o).
Stores the number of codes stored in the front (9).

When step 5603 is completed, the contents of the first output buffer (9>) are written to the text buffer (15) in steps 8604 to 5606.

Specifically, in step 5604, in response to the write instruction signal WS2 output from the main control unit (1), the write logic (17) saves the code held in the save buffer (20) into the text buffer. (15) Write in the specified position inside. In such writing, the save buffer (20) reads position information from the save register (19) in response to the write signal W output from the write logic (17), and represents the position information in the same way as in step 5140. The codes in the save buffer (20) are sequentially saved in the text buffer (15) starting from the position in the text buffer (15).
) write inside.

Next, in step 5605, the cent signal S output from the write logic (17) is output in the same way as in step S142.
In response to S, the write pointer (18) is set to the save register (
19) is read and held.

In step 5606, as in step 5143, the code stored in the first output buffer (9) is read out from the beginning by the number of times equal to the contents of the first counter (10).
Write to text buffer (15).

Step 8606 is the final step, and when this step is completed, the entire process is complete.

Next, the above operation will be explained based on an example of a combination.

Now, the text buffer (15) stores the code that constitutes the character string displayed on the display section (16) as shown in Figure 5(a), and the input start position is on the display section (16). The first position is the position where the character ``ra'' is completely displayed), and from the input section <2), 1 goes to the end. It is assumed that the phonetic character strings , , and , are input sequentially.

In this state, first, when the natural literary ability start key is input from the input section 2), steps S1 to S4 are sequentially processed, and the input counter (5) and the first counter (10) are "
0. , the save register (19) is fully set with input start position information 11J, and the save buffer (20) is filled with the input start position information 1 to 'PJ4 on the display section (16).
Each code in the text buffer (15) corresponding to the character t (displayed at position 0) is stored.

From the human power department (2) in 55 steps, the phonogram “
When the key corresponding to wa is input, steps S6 and S7 are processed in sequence, and in the leading steps S8 and S9, the code corresponding to the phonetic character 1 wa is stored in the bag; 77 (4). The contents of the power counter (5>) are changed to rl.

After that, in step S10, a phrase judgment is performed for codeta II in the input buffer (4), but since only the code indicating ``1'' is currently stored in the input buffer (4), ) and the contents of the input counter (5) are the second output Hanofa <11
) and the second counter 12).

Therefore, the processing jumps from the SIO step/bu to the 314 step/b, and steves 8140 and below are processed.

First, in step 5140, the code string in the save buffer (20) is written to a predetermined position in the text buffer (15), and in step 5141, it is determined whether the content of the first counter (10) is "OJ". However, at this time, since the above content is "1θ", the process jumps to step 5145.

In steps 5145 to 5147, the save buffer (20
), the code string in the second output buffer (11) is written into the text buffer (15) corresponding to the input start position, but currently the second output buffer (11) is filled with one character. Since only the code corresponding to is stored, the text buffer (15) displays the character 1 in the first position of the display section (16), which is the input start position, as shown in Figure 5 <b>. The code corresponding to the character 1wa is written inside.

Next, the letters ``Tarushi% is yo'', ``ki''.

The characters lltff are input from the input section 2), but even if the above characters are input, the input string does not constitute two clauses, so S5 is input for each character input above.
, S6, S7, S8, S9, S10, S 11°514
0.5141.5145.5146.5147, S4 steps are processed sequentially, and as shown in FIG.

A predetermined code is written into the text buffer (15) so that each character such as "shi" 1 wa" and "e" 1 ki" is displayed.

After that, in step S5, the character "to" is input,
When S6 to S9 stems are processed, the input buffer (4) is full of the character strings consisting of two phrases, 1 wa, haeki heyo, and the corresponding code, and the input counter (5)
The content of is 7.

Therefore, in the following step S10, the code string corresponding to the character string ``Watashi wa'', which is the first phrase of the above character string, is added to the conversion target buffer (7), and the code string ``Ekihe'', which is the last phrase of the above character string, is stored in the conversion target buffer (7).
The code string corresponding to the character string is stored in the second output buffer (
11) and a buffer counter (8).
and the second counter (12) has numbers 14" and 13" respectively.
are set respectively.

Furthermore, at this time, Monarchy Renbu (1
), “11” is output as the clause presence/absence BU.
Processing is from step 510 to step 31 through step 311.
Proceeding to step 2, S12.313 staves are processed in sequence.

Therefore, the code string representing the character string 0 watashi wa yo stored in the conversion target buffer (7) is the kana kanji ronnoku (
13〉, the corresponding character string 1 containing kana and kanji is converted into a code string consisting of 2 codes representing
The numerical value 12'' is stored in . Also, input buffer (4)
and a second output buffer (11) for the input counter (5), respectively.
) and the contents of the second count (12) are changed circuit (14)
Therefore, the input buffer (4)
and the input counter (5>) respectively store a code string representing "Character string 1" and a numerical value "13".

In the following step S14, since the content of the first kakunta (10>) is not 10., steps 5140 to 5147 are sequentially processed.

Therefore, in the text buffer (15), as shown in Fig. 5(d)
The code string is stored so that the character string "I am bait" is displayed in the first to fifth positions of the display section (16) as shown in FIG. In addition, the value 13J is stored in the save register <19), and the value shown in Fig. 5 (a) is stored in the save buffer (20).
) The code strings corresponding to the character strings displayed from the third position to the 42nd position of the display section (16>) are stored.

This post-processing returns to step S4 and the first counter (lO
) is reset to 10.

Next, when the character 1 is inputted from the input section (2),
Processing is S5, S6, S7, S8, S9, S10, S11
．． 5140.5141.5145.5146.5147
, the text buffer (15) is displayed on the display section (16) as shown in FIG. 5(e).
A code string corresponding to the character string 1, ``I am angry'' will be stored inside. Also at this time, the first counter (10)
The content of is ``10'', and the content of save revsta (19) is ``
3" and save buffer < 20) as shown in Figure 5 (
Code strings corresponding to the character strings displayed at the third to forty-second positions of the display section (16) shown in a) are stored.

After that, when the character 1 is entered manually from the input section 2),
The process proceeds from step S5 to step S13, 5140 to 5147, and step S4, and the character string ``I'm going to the station'' is displayed in the first to sixth positions of the display section (16) as shown in FIG. 5(r). A code string corresponding to the above character string is written into the text buffer 15). Also, at this time, the contents of the first counter (10) and the save register (19) are 1''0'' and 15'', respectively. Further, the save buffer (20) stores code strings corresponding to the character strings displayed at the 5th to 44th positions of the display section (16) shown in 5fJ(a). Then, a code string and a numerical value 12 corresponding to the character string "Iku" are stored in the power buffer (4) and the input cursor (5), respectively.

Next, when the symbols も and yo are input from the input section (2),
Processing is from S5 to S11. S140. S14
1. Proceed sequentially through steps 5145 to 5147 and S4.

Therefore, I go to the station at the 1st to 7th positions on the display section (16). The loader l is stored in the text buffer (15) so that the character string ``'' is displayed. Also, the cover/
The character string r is entered in the input counter (5) and input counter (4), respectively. ” and the numerical value r3J are stored.

After that, when the natural literary ability end key is input from the input unit (2), the process is performed in sequence after processing S5 and S6 steno knobs in 5601
The process advances to step/step, and since the content of the input counter (5> is "3"), steps S602 to S5606 are sequentially processed.

Therefore, at step 8603, the code string in Dairyoku buffer (4) is converted to the character string 1, which corresponds to the character string "Iku.," mixed with kanji, and the text buffer < 15
), the character string 1 is written in the first to seventh positions of the display section <16). ' will be displayed.

Incidentally, when the natural literary ability start key and end key are pressed consecutively in the input section (2), steps S1 to S6.5601 are sequentially processed and the process ends.

(g) Effects of the invention According to the present invention, the phonograms used when performing natural literary skills are displayed at the same position as the ideograms after conversion, so movement of the operator's viewpoint is minimized. can be used to improve operator operation.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIGS. 2 to 4 are FmJ-charts showing the operation of the A2 embodiment.
FIG. 5 is a schematic diagram showing the display state on the display unit, and FIG. 6 is a schematic diagram for explaining a conventional example. (2) Input means, (4) Power buffer, (6)
Clause judgment Ron /ri, (7) Conversion target buffer, <9
>(11...1st, 2nd output/<Sofa, (13)...
・Kana-kanji Rontsuku, (15) ・Text buffer, (16) Display section, (17>...Writing loss,
(19)・Save register, (20)・Save buffer. Applicant Sanyo'rIL Machine Co., Ltd. Agent Patent attorney Atsugu Nishino (1 other person) Figure 3 Figure 6

Claims (1)

[Claims] (1) Every time a phonetic character is input, the clause structure of the phonetic character string input so far is determined, and a part of the phonetic character string is converted into an ideographic character string based on the result of such determination. A device for inputting the phonetic characters, comprising an input means for inputting the phonetic characters, an input buffer in which codes corresponding to the phonetic characters inputted from the input means are stored in the input order, and codes input into the input buffer. A phrase determination logic that determines the phrase structure of the code string in the input buffer every time a phrase is found, and when the phrase determination logic determines that a phrase exists, a code string that constitutes the first phrase of the code string is stored. a conversion target buffer, a second buffer in which a code string other than the code string constituting the first clause is stored, a kana-kanji logic for converting and outputting the code string in the conversion target buffer into a code string representing an ideographic character string; A first output buffer in which the code string converted and output from the kana-kanji logic is stored, a display section,
A text buffer in which a code corresponding to a character string displayed on the display section is stored, a save register in which input start position information into the text buffer is stored, a save buffer capable of storing a predetermined number of code strings; When the code string in the save buffer is written into the text buffer starting from the position in the text buffer corresponding to the position information in the save register, and then the code string is stored in the first output buffer, After writing the code string in the first output buffer from the position in the text buffer that corresponds to the position information in the save register, the next position after the last position of such writing is stored in the save register, and the next position is stored in the save register. The predetermined number of codes in the text buffer starting at the position are stored in the save buffer, and then the code string in the second output buffer is written from the next position in the text buffer, and the code is stored in the first output buffer. If not stored, the predetermined number of codes are read from the position in the text buffer corresponding to the position information in the save register and stored in the save buffer, and then the second code is read from the position in the text buffer.
A kana-kanji conversion input device comprising a write logic for writing a code string in an output buffer.