JP3487345B2 - Character input / recognition system and method for small electronic equipment - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a small electronic device such as a mobile phone. In particular, the present invention relates to a character / recognition system and method for a small electronic device that enables recognition of handwritten input characters drawn on a numeric keypad.

[0002]

2. Description of the Related Art Conventionally, as described in Japanese Unexamined Patent Publication No. 6-28085, in electronic equipments which have been downsized and reduced in price, only ten-key input is mainly used as an input device. When inputting characters, for example, on the numeric keypad "2" (A, B, C), "3" (D, E, F),
Assigning (G, H, I) ... to “4”, first searching for a character to be input and a number corresponding thereto, and pressing the number several times until the desired character is displayed on the display device.

[0003]

However, in the above character input, it is necessary to press the number repeatedly until the desired character is displayed, which makes it impossible to intuitively input the character. There is. Therefore, in view of the above problems, the present invention provides a character input / recognition system and method for a small electronic device that enables a large number of characters to be input inexpensively, intuitively and easily with only a numeric keypad as an input device. The purpose is to

[0004]

In order to solve the above-mentioned problems, the present invention provides a small-sized input device having a numeric keypad arranged therein.
In the character input / recognition system for portable electronic devices
Judge line vector, horizontal line vector, diagonal line vector, curve
Has the judgment data to be written, and the characters are drawn by hand on the key.
When the keyboard is touched, the key layout is vertical, horizontal, diagonal, curved
Enter the character input data by pressing the key of
Based on vertical line vector, horizontal line vector, diagonal line vector, song
The input data converter that converts to lines and the vertical
Group characters by combining lines, horizontal lines, diagonal lines, and curves
Group the characters by the number of vertical lines that
Characters are grouped by the number of horizontal lines
Characters are grouped according to the number of diagonal lines formed, and characters are
Grouped and the first pressed in the stroke order of characters
Group the characters with the key and press at the end in the stroke order of the characters
Multiple tables with characters grouped by the key
A reference data storage unit for storing as reference data, and
Vector of input data of characters converted by the force data converter
For each curve,
Refer to and give a high score to the characters that belong to the closest group.
Well, give a low score to characters that belong to a distant group.
Eh, before adding the score for each character to all tables
Enter by handwriting the character with the maximum added score.
And a character guessing unit for guessing the character
Provide a character input / recognition system for small electronic devices
To do.

By this means, it is possible to input a large number of characters inexpensively, intuitively and easily by only drawing a character on the ten key with the fingers of the hand using only the ten key as an input device. Well
Also, different concepts based on the vectors and curves that make up letters
Have character information in the table of multiple reference data
Since it has been set, accurate character recognition is possible even with input devices with few keys.
Perception becomes possible. Further, in the reference data storage section,
-When the above characters are drawn by handwriting on the screen, the stroke order of the characters
The weight of each key adjacent to the key expected to be pressed
The weighting is stored, and the weight is referred to in the character estimation unit.
Weight, the weight is added each time the key is pressed, and the weight of the entered character
Is calculated, and the added value of the weight and the added value of the score
Characters drawn by handwriting with the maximum total of
I guess.

By this means, the input numeric keypad 12
By storing each key order of,
It is possible to compare with reference data. Input data
The conversion unit has a maximum of 8 adjacent keys of the input device.
The direction of each key is the basic vector, and the basic vector is
, Upward basic vector, downward basic vector, leftward
Basic vector, rightward basic vector, right diagonal upward basic
Vector, diagonal right downward basic vector, diagonal left upward base
This vector consists of the basic vector, diagonally downward left basic vector, and upward
Basic vector combination, downward basic vector combination
It has data to judge the alignment as the vertical line vector,
Diagonal right upward basic vector, upward basic vector, rightward
Combination of basic vectors, diagonally downward left basic vector
Combination of the downward basic vector and the downward basic vector
Let, left diagonal upward basic vector, upward basic vector
Combination of left-handed basic vectors, right-handed diagonally downward base
Book Vector, Downward Basic Vector, Rightward Basic Vector
From the combination of
Possess a set of upward basic vector and downward basic vector
Set of right-handed basic vector and left-handed basic vector
Combination, upward basic vector, downward basic vector,
Combination of right-pointing basic vector and left-pointing basic vector
It has data to judge from the above curve.

By this means, it is possible to draw by hand on the numeric keypad.
The character to be printed is converted into a vector, and the above basic vector is
By combining, the lines that make up the character are vector
It becomes possible to convert to vertical line, horizontal line, diagonal line
It allows you to identify curves and recognize rounded characters.

Further, the input data conversion unit is operated by pressing a key.
One vector of the key press track depending on the relationship with the lower time,
Identify the curve. By this means the key is released once
Depending on the relationship between the time from pressing to the next key,
It is possible to distinguish between the vector and the vector, and the number of strokes of the character can be
It becomes possible to ask.

Further, the reference storage unit stores the same characters.
On the other hand, prepare multiple features of the lines that make up the character. This hand
The stage makes it possible to minimize the error due to input.
It The input device has at least two columns and two rows of keys.
And more preferably, three rows of columns and four rows of keys.
It consists of Applicable to various input devices by this means
Become Noh.

Further, the input data converter is a ten-key
Vector input data of English letters drawn by hand on top
And preferably the input data conversion unit is
Input data of katakana characters drawn by hand on the keyboard
Convert to Koutor. By this means, users' preference
Accordingly, the input can be easily performed.

Further, according to the present invention, a numeric keypad is arranged.
Input / recognition method for small electronic device with force device
In, a set of vertical lines, horizontal lines, diagonal lines, and curves that make up characters
A method to group characters by combination and store them in a table.
And group the characters by the number of vertical lines that make up the characters.
By the process of storing in the table and the number of horizontal lines that make up the character
The process of grouping characters and storing them in a table
Tables are grouped by the number of diagonal lines that make up the
The process of storing in the table and the table by grouping characters by the number of strokes
The first step in the process of storing
Characters are grouped by the key and stored in a table
In the process and the writing order of characters
Grouping and storing in a table, and writing characters
Key that is expected to be pressed in the order of
Key that is adjacent to the
The process of storing the weighting of the
Shape judgment data to judge cuttle, diagonal vector, curve
And the process of writing characters on the keys by hand
Key layout for vertical, horizontal, diagonal, and curved key presses
Vertically input the character input data based on the above judgment data.
Convert to line vector, horizontal line vector, diagonal line vector, curve
And the input data vector of the converted character,
For each of the tables in the reference data storage section for a curve
Refer to and give a high score to the characters that belong to the closest group.
Well, give a low score to characters that belong to a distant group.
Eh, add the score for each character to all the above tables
And the step of handwriting the character on the key
See weighting the keys for each group stored in
Then, the weight is added each time the key is pressed, and the weight of the input character
The step of obtaining the added value, the added value of the weight and the score
Draw and enter the character with the maximum total added value by hand.
Small size characterized by having a process of guessing
A character input / recognition method for an electronic device is provided.

By this means, as in the above invention, input
Use only the numeric keypad as a device,
It is cheap, intuitive and easy to enter a large number of characters just by drawing them.
Power becomes possible. Also, the vectors and curves that make up the characters
Characters in a table of multiple reference data with different concepts based on
Input device with few keys because it has information
However, accurate character recognition is possible.

[0013]

[0014]

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing an outline of a small electronic device apparatus according to the present invention. The character input / recognition system for a small electronic device shown in this figure includes a small electronic device 11, a numeric keypad 12 used as an input device for the small electronic device 11, and a display for displaying characters input from the numeric keypad 12. And part 13.

The ten-key pad 12 is an input device which comprises a total of 12 keys in which the number keys from 1 to 9 and 0 are added, and * and # are added to the horizontal 3 rows and vertical 4 rows. As shown in the figure, by handwriting, that is, by directly drawing the English character (alphabet) 14 of "A" on the ten-key 12 with the fingers of the hand, the ten-key 12 is sequentially pressed, and the pressed. The input data of the numeric keypad 12 is compared with a plurality of reference data of character information prepared in advance, the result is calculated, the character is recognized, and the display unit 13 displays the English character "A".

Here, the English characters 14 are the letters A to Z of the uppercase alphabet. As a result, it becomes possible to input a large number of English characters inexpensively, intuitively and easily using only the numeric keypad 12 as the input device of the small electronic device 11. The details will be described below.

FIG. 2 is a block diagram showing a schematic configuration of a character input / recognition system for a small electronic device. As shown in the figure, a control unit 100 is provided in the small electronic device, and the control unit 100 controls the small electronic device, for example, the numeric keypad 12, the display unit 13 and the like. Further, the control unit 100 is provided with a recognition unit 101, and the recognition unit 101 inputs an English character drawn directly from the ten-key pad 12 to perform recognition.

The recognition unit 101 includes an input data conversion unit 102.
Is provided, and the input data conversion unit 102 uses the numeric keypad 12
The input data of English characters drawn directly with the fingers of the above is decomposed and converted into a vector. Further, the recognition unit 101 is provided with a reference data storage unit 103, and the reference data storage unit 1
Reference numeral 03 stores reference data for converting the input data of the input data conversion unit 102 into a vector and a plurality of reference data for grouping the English characters according to the characteristics of the lines forming the English characters.

Further, the recognition unit 101 includes a character estimation unit 10
4 is provided, and the character inferring unit 104 draws the English directly drawn on the ten-key pad 12 from the reference data stored in the reference data storage unit 103 based on the vector conversion result of the input data conversion unit 102. Guess the character. Recognition unit 10
1 displays the English characters estimated by the character estimation unit 104 on the display unit 13.

The control unit 100 is provided with a Japanese conversion unit 105, which converts the English characters AZ obtained from the character estimation unit 104 of the recognition unit 101 into Japanese by Roman character conversion. Then, it is displayed on the display unit 13. It should be noted that the English characters may be displayed as they are as an English sentence without going through the Japanese conversion unit 105. FIG. 3 is a diagram for explaining the operation of the input data conversion unit 102. As shown in the figure, in the input data conversion unit 102, the numeric keypad 12
Adjacent 4 with a key (here "5") as a base point
A total of eight types, four types of straight line vectors for pressing the keys in the directions (2, 4, 8, 6) and four types of diagonal vectors for pressing the keys in the direction (1, 7, 9, 3). As the (basic) vector, one vector of the key pressing locus is obtained from a plurality of combinations of these short vectors and the time relationship.

In the following description, the key numbers 1 to 9 of the ten-key pad 12 are the same numbers, the * key number is 10, the 0 key number is 11, and the # key number is 12.
Is replaced with and processing is performed. The direction of the short vector is determined by the difference Δ between the adjacent key number and the base key number as follows.

FIG. 4 is a diagram for explaining the short vector converted by the input data converter 102. As shown in this figure,
When the difference Δ = -3 between the adjacent key number and the base key number,
The short vector created by the adjacent key and the base point key is a straight line vector and is upward (upward and downward).

When Δ = 3, the short vector is a straight line vector and faces downward (downward short). If Δ = -1,
The short vector is a straight line vector and is directed leftward (short left).
In the case of Δ = 1, the short vector is a straight line vector and faces right (short right). In the case of Δ = −2, the short vector is a diagonal vector pointing diagonally right upward (diagonal right upward short).

When Δ = 2, the short vector is a diagonal vector and is directed diagonally downward left (diagonal left short). Δ = -4
In the case of, the short vector is a diagonal vector and is diagonally upward to the left (obliquely upward to the left). In the case of Δ = 4, the short vector is a diagonal vector pointing diagonally downward right (diagonal right downward).

FIG. 5 is a diagram for explaining a plurality of combined vectors relating to short vectors. As shown in this figure,
The upward straight line (upper) is obtained by combining the upward short vectors 2 to 4 (upper short). Straight line (down)
Is obtained by a combination of 2 to 4 downward short vectors (lower short).

The right-facing straight line (right) is obtained by combining a few right-facing short vectors (right short). A straight line pointing left (left) is obtained by a combination of a few short vectors pointing left (left short). The diagonal line pointing diagonally upward to the right (obliquely upward to the right) is obtained by a combination of 2 to 6 diagonally upward short vector (obliquely upward short), upward short vector (upward short), and rightward vector (short right).

The diagonal line pointing diagonally downward to the left (lower diagonal to the left) is 2 to
It is obtained by the combination of 6 left diagonal downward short vectors (left diagonal downward short), downward short vectors (lower short), and leftward vectors (left short). Diagonal line diagonally upward to the left (upward diagonally to the left)
Is a diagonally upward left short vector of 2 to 6 (obliquely upward left short),
It is obtained by combining an upward short vector (upper short) and a leftward vector (left short).

The diagonal line pointing diagonally downward to the right (obliquely downward to the right) is 2 to
It is obtained by the combination of 6 right diagonal downward short vectors (left diagonal downward short), downward short vectors (lower short), and rightward vectors (left short). The curve vector is obtained by combining the upward short vector (upper short) and the downward short vector (lower short).

Further, the curve is obtained by combining a right short vector (right short) and a left short vector (left short). Furthermore, the curve is an upward short vector (upper short),
It is obtained by combining a downward short vector (lower short), a right short vector (right short), and a left short vector (left short).

FIG. 6 is a diagram for explaining the relationship between the combination of short vectors and time. As shown in the figure, it is possible to determine that the vector is a diagonal vector or a straight vector from the relationship between the point where the key is pressed and the time. In addition, the relationship between the time a key is once released and the time the next key is pressed makes it possible to distinguish between vectors.
It is possible to find the number of strokes of a character.

When drawing the above curve, the numeric keypad 12
Since there are only 12 of them, due to the relation between this and time, it starts in a certain direction, and immediately the direction of the opposite phase appears. As a result, it can be expected that the user is inputting a semicircle or a circle. FIG. 7 is a diagram illustrating reference data stored in the reference data storage unit 103 of FIG. 2 and an example of reference data for converting input data into a vector.

As shown in the figure, the reference data storage unit 10
In 3 are 16 kinds having 8 kinds of orientations and 2 kinds of sizes used for dividing the characters prepared in advance into groups in order to compare with the handwritten characters input to the ten-key pad 12. Indicates the vector of. In the reference data storage unit 103, “1”, “2” for rightward and leftward vectors, “3”, “4” for rightward and leftward short vectors, “5” for rightward diagonal downward vector, and rightward diagonal downward vector. "6", diagonally right upward, left diagonal downward short vector "7", "8", diagonal left upward, diagonal right downward vector "9", "10", diagonal left upward, diagonal right downward short vector "11", "12", upward,
"13" and "14" for downward short vectors, "15" and "16" for upward and downward vectors, and "1" for curves.
7 ”is assigned.

Fig. 8 is a diagram for explaining an example of inputting an English character "A" from the numeric keypad 12 of Fig. 1. As shown in this figure, as an example, the finger of the hand touches the numeric keypad 12 of the small electronic device. The hatch portion 22 indicated by the arrow 23.
If the English letter "A" is drawn as shown, the numeric keypad 12 is "* → 7 → 4 → 2, 2 → 6 → 9 → #, 7 → 8 →
9 ”is pressed in this order. Here, “,” indicates a short rest time until the next numeric keypad 12 is pressed.

Information generated by this pressing is the control unit 100.
Is output to the input data conversion unit 102 of the recognition unit 101. FIG. 9 is a flowchart illustrating the operation of the input data conversion unit 102 for the English character input of FIG. In steps S11 and S12, the input data conversion unit 102 sequentially inputs the information of pressing the * key and the 7 key.

In step S13, the input data conversion unit 102 obtains the difference Δ = −3 between the number of the 7 key and the * key number (10) from the information of pressing the * key and the 7 key, and refers to the reference data storage unit 103. Then, the short vector formed by pressing the * key and 7 key is determined to be the upward short vector (13). Next, in step S14, information for pressing the 4 key is input.

In step S15, the difference Δ = -3 between the number of the 4th key and the number of the 7th key is obtained, and the reference data storage unit 1
With reference to 03, the short vector formed by pressing the 7 key and the 4 key is determined to be the upward short vector (13). In step S16, 2 key press information is input. In step S17, the difference Δ = −2 between the number of the 2 key and the number of the 4 key is obtained, and the reference data storage unit 103 is referred to
The short vector formed by pressing the 4 key and the 2 key is determined to be the right diagonally upward short vector (7).

In step S18, the input data conversion unit 102 confirms that the ten-key 12 has been released from the key on the basis of the short rest time until the next ten-key 12 is pressed. In step S19, the vector formed by pressing the * key to the 2 key is a combination of two upward short vectors (13) and one diagonal right upward short vector (7). Converter 10
2 judges this vector to be the diagonally right upward vector (5).

In steps S20 and S21,
Information on the 2 key press and the 6 key press is sequentially input. In step S22, the input data conversion unit 102 obtains the difference Δ = −4 between the number of the 6 key and the number of the 2 key from the information of pressing the 2 key and the 6 key, refers to the reference data storage unit 103, and returns the 2 key, The short vector formed by pressing the 6 key is determined to be the diagonally downward right vector (12).

In step S23, next, the 9 key press information is input. In step S24, the difference Δ = 3 between the number of the 9 key and the number of the 6 key is calculated, and the short vector formed by pressing the 6 key and the 9 key is referred to the downward short vector (14) by referring to the reference data storage unit 103. ).
In step S25, the # key press information is input.

In step S26, the difference Δ = 3 between the # key number (12) and the 9 key number is calculated, and the short vector formed by pressing the 9 key and # key is referred to by referring to the reference data storage unit 103. Is determined as a downward short vector (14). In step S27, the input data conversion unit 102
Confirms the release of the finger key from the ten key 12 based on the pressing time until the next ten key 12 is pressed.

In step S28, the vectors formed by pressing the keys 2 to # are one diagonal right downward short vector (12) and two downward short vectors (1).
4), the input data conversion unit 102 determines that this vector is the diagonally downward right vector (10). In steps S29 and S30, information regarding the 7-key press and the 8-key press is sequentially input.

In step S31, the input data conversion unit 102 obtains the difference Δ = 1 between the number of the 8 key and the number of the 7 key from the information of pressing the 7 key and the 8 key, and the reference data storage unit 1
With reference to 03, the short vector formed by pressing the 7 and 8 keys is determined to be the rightward short vector (3). In step S32, next, the 9 key press information is input.

In step S33, the difference Δ = 1 between the 9-key number and the 8-key number is calculated, and the reference data storage unit 10
3, the short vector formed by pressing the 8 and 9 keys is determined to be the rightward short vector (3). In step S34, the input data conversion unit 102 confirms that the ten keys 12 are separated from the fingers.

In step S35, the vector formed by pressing the 7th to 9th keys is formed by the combination of two rightward short vectors (3), so the input data conversion unit 102 sets this vector to the right. Judge as an oblique downward vector (1). FIG. 10 is a diagram showing an example of conversion of the English character "A" into a vector by the conversion operation of the input data conversion unit 102 of FIG.

The English character "A" is designated by reference numeral 3-1 in this figure.
As shown in FIG. 4, it is composed of a diagonally right upward vector, a diagonally right downward vector, and a rightward vector. As shown by reference numeral 3-2, it is (5, 10, 1) when represented by the assigned number. Thus, the English character "A" is converted into a plurality of vectors, and in the above case, the number of strokes of the English character "A" is 3.
It is a picture.

FIG. 11 is a diagram for explaining an example of conversion of the English character "B" into a vector. For the English character "B" to the numeric keypad 12, the input data is (1 → 4 → 7 → *, 1 → 2
→ 6 → 8 → 7, 4 → 5 → 9 → 0 → *),
As shown in this figure, if this is shown as a vector, it consists of a downward vector, a curve, and a curve.
(15, 17, 17).

Further, another example of the English character "B" will be described. For the English character "B" to the numeric keypad 12, the input data is (1 → 4 → 7 → *, 1 → 2 → 3, 3 →
6, 6 → 5, 8 → 9, 9 → #, # → 0 → *), as shown in the figure, if this is shown as a vector, downward vector, rightward vector, downward short vector, leftward vector It consists of a short vector, a right short vector, a down short vector, and a left vector.
(16, 1, 14, 4, 3, 14, 2).

Further, another example of the English character "B" will be described. For the English character "B" to the numeric keypad 12, the input data is (1 → 4 → 7 → *, 1 → 2 → 3, 3 →
5, 8 → #, # → 0 → *), as shown in the figure, when this is shown as a vector, a downward vector, a rightward vector, a left oblique downward downward short vector, a right oblique downward downward short vector, a leftward downward vector. It is composed of a vector, and is represented by (16, 1, 8, 12, 2) when expressed by the assigned number.

Next, a table is formed in the reference data storage unit 103 by dividing all 24 English characters to be prepared into lines and dividing them into the following groups according to the line characteristics. FIG. 12 is reference data stored in the reference data storage unit 103 of FIG. 2, and is a diagram illustrating an example of a table of reference data that associates characters with lines.

As shown in the figure, the reference data storage unit 10
3 is composed of only vertical, horizontal and diagonal straight lines 2
The English characters of 6 are: E, F, H, I, L, T, B, especially as English characters composed only of vertical lines and horizontal lines, ...

V, W, X, ... Especially as an English character consisting only of diagonal lines + horizontal lines, A, Z, ... Especially as an English character consisting only of diagonal lines + vertical lines, K, M, N, Y, ...

In particular, diagonal lines + vertical lines + horizontal lines B ... As an English character consisting of a straight line and a curve, B, D, G, J, P, U, ... As an English character consisting of straight line + curved line + diagonal line,

.. are stored as reference data grouped as C, O, Q, S .. It should be noted that an English character composed of a straight line and a curved line, for example, "B" includes a curved line as shown in FIG.
When inputting, there are examples of conversion into several lines. For example, the reference data storage unit 103 stores the reference data as not only straight lines + curves but also vertical lines + horizontal lines and diagonal lines + vertical lines + horizontal lines. Stored in. In this way, errors due to input can be minimized.

FIG. 13 shows reference data stored in the reference data storage unit 103 shown in FIG. 2, and is a view for explaining another example of the reference data table in which characters correspond to lines. As shown in this figure, the number of vertical lines of English characters is "0", "1",
English characters are grouped into a group of "2". Figure 1
Reference numeral 4 is reference data stored in the reference data storage unit 103 of FIG. 2, and is a view for explaining another table example of reference data in which characters are associated with lines.

As shown in the figure, the English characters are grouped into groups of the number of horizontal lines of English characters "0", "1", "2", "3". FIG. 15 shows reference data stored in the reference data storage unit 103 of FIG. 2, and is a diagram for explaining another example of the reference data table in which characters are associated with lines. As shown in this figure, the number of diagonal lines of English characters is "0",
English characters are grouped into groups of "1", "2", and "4".

FIG. 16 shows reference data stored in the reference data storage unit 103 shown in FIG. 2, and is a view for explaining another example of the reference data table in which characters correspond to lines. As shown in this figure, the number of strokes of English characters is "1", "2", "3",
English characters are grouped into a group of "4". Figure 1
Reference numeral 7 is reference data stored in the reference data storage unit 103 of FIG. 2, and is a view for explaining another example of the table of reference data in which characters correspond to lines.

As shown in the figure, for each key of the numeric keypad 12, the English character that is pressed first in the writing order when the English character is input is grouped. Similarly, numeric keypad 12
For each key, the English character that is pressed at the end of the writing order when the English character is input is grouped. In this table, when inputting an English character, it is possible to predict a possible candidate of the key of the numeric keypad 12 that is pressed first in the writing order and a possible candidate of the key of the numeric keypad 12 that is pressed last. Therefore, by grouping these promising candidates in pairs, it becomes possible to fully utilize the limited keys of the numeric keypad 12, which are only 12 keys.

In this way, the character information is provided in the table of a plurality of reference data having different concepts so that the character recognition can be performed accurately even with only 12 key input devices in total. FIG. 18 shows the reference data storage unit 103 of FIG.
FIG. 3 is a diagram illustrating an example of reference data that is reference data stored in, and that converts input data into a line.

As shown in the figure, one English letter "A"
There are Candidate 1 and Candidate 2 for the writing order of, for example, the keys (*, 7, 8) adjacent to the key of the numeric keypad 12 that is expected to be pressed first for the writing order for Candidate 1.
Key) is one first group. The group of keys expected to be pressed secondly (keys 7 and 8) is the second group.

Then, the third, fourth, ... Group is formed.
Further, weights 10, 9, and 8 are given to the keys *, 7, and 8 in the first group in consideration of the direction in which the characters are drawn in the groups. Further, weights 10 and 9 are assigned to the 7th and 8th keys of the second group. By storing the order of the input keys of the numeric keypad 12, it becomes possible to compare with the reference data according to the writing order.

[0062] Here, it becomes possible simplified compared with the first pressed key and last depressed key and the reference data. Next, based on the vector conversion result of the input data conversion unit 102, an English character directly drawn with a finger of the hand on the numeric keypad 12 from the reference data stored in the reference data storage unit 103, for example, “A” is displayed. For an example to guess,
I will explain.

FIG. 19 is a diagram for explaining the outline of the character estimation unit 104 of the recognition unit 101 in FIG. In the conversion result of the input data conversion unit 102 shown in this figure, the English character "A"
Consists of horizontal lines and diagonal lines. As the guess result 1, the character guessing unit 104 finds that the English characters “A” and “Z” are closest to the reference data in the reference data storage unit 103 shown in FIG.
Give them the best 10 points. Give the next English letter “H” 8 points. The lowest 0 point is given to the English letter "C" that includes a curve. In this way, a group that departs from the closest group is given a lower point as it departs.

Next, in the conversion result of the input data conversion unit 102, the number of horizontal straight lines of the English character "A" is "1", the number of vertical lines is "0", and the number of diagonal lines is "2". Is. The character estimation unit 104 uses the reference data in the reference data storage unit 103 shown in FIGS.
The English letter "A" is the closest, so give it 10 points. Give the next English letter “H” 8 points.

Next, in the conversion result of the input data conversion unit 102, the number of strokes of the English character "A" is "3". The character estimation unit 104 uses the English character “A”, as the estimation result 3, from the reference data in the reference data storage unit 103 illustrated in FIG.
"H" is closest, so give them 10 points.

Next, in the conversion result of the input data conversion unit 102, the numeric keypad 12 for inputting the English character “A” first is given.
The key number of is "2". The character estimation unit 104 uses the reference data storage unit 103 illustrated in FIG. 17 as the estimation result 4.
Since the English characters "A" and "I" are the closest from the reference data of, the 10 points are given to them.

Next, the character estimation unit 104, as the estimation result 5, is the closest to the reference data in the reference data storage unit 103 shown in FIG.
Give it 10 points. In the character estimation unit 104, the estimation results 1 to 5 are added, and the English character having the maximum addition value is estimated and confirmed as the input English character.

As described above, since the vector information is converted once, an error caused when a plurality of numeric keys 12 are simultaneously pressed or when a key is pressed at an unintended portion is rounded, so that expected English characters can be accurately identified. Is possible. In the above description, the input and recognition of English characters A to Z have been described, but the input and recognition of katakana characters are also possible. This makes it possible to adapt to user preferences.

The ten-key pad 12 has been described as having a total of twelve keys in three columns vertically and four rows horizontally, but the present invention is realized by inputting and recognizing vertical, horizontal and diagonal straight lines. , 2 columns in the vertical direction and 2 rows in the horizontal direction, a total of four keys can be similarly realized. As a result, it can be applied to various input devices.

[0070]

As described above, according to the present invention,
Only the numeric keypad as an input device is used to convert the characters drawn with the fingers of the hand on the numeric keypad into a vector and recognize the characters from the converted vector, so it is cheap to draw the characters on the numeric keypad. Many characters can be input intuitively and easily.

Further, since character information is given to a plurality of reference tables having different concepts and the reference table is referred to, the character is inferred and confirmed from the converted vector. Draw on
It becomes possible to enter.

[Brief description of drawings]

FIG. 1 is a diagram showing an outline of a small electronic device apparatus according to the present invention.

FIG. 2 is a block diagram showing a schematic configuration of a character input / recognition system of a small electronic device.

FIG. 3 is a diagram illustrating the operation of the input data conversion unit 102.

FIG. 4 is a diagram illustrating a short vector converted by an input data conversion unit 102.

FIG. 5 is a diagram illustrating a plurality of combined vectors related to short vectors.

FIG. 6 is a diagram illustrating a relationship between a combination of short vectors and time.

FIG. 7 is a diagram illustrating an example of reference data that is reference data stored in the reference data storage unit 103 of FIG. 2 and that converts input data into a vector.

FIG. 8 is a diagram illustrating an example of inputting an English character “A” from the numeric keypad 12 of FIG.

9 is a flowchart illustrating an operation of the input data conversion unit 102 for an English character input of FIG.

10 is a diagram showing an example of conversion of an English character "A" into a vector by a conversion operation of the input data conversion unit 102 of FIG.

FIG. 11 is a diagram illustrating an example of conversion of an English character “B” into a vector.

FIG. 12 is a diagram illustrating an example of a reference data table that is reference data stored in the reference data storage unit 103 of FIG. 2 and that associates characters with lines.

FIG. 13 is a diagram illustrating another example of reference data that is reference data stored in the reference data storage unit 103 of FIG. 2 and that associates characters with lines.

FIG. 14 is a diagram illustrating another example of the reference data stored in the reference data storage unit 103 in FIG. 2, which is reference data in which characters are associated with lines.

FIG. 15 is a diagram illustrating another example of reference data that is reference data stored in the reference data storage unit 103 of FIG. 2 and that associates characters with lines.

FIG. 16 is a diagram illustrating another example of reference data that is reference data stored in the reference data storage unit 103 of FIG. 2 and that associates characters with lines.

FIG. 17 is a diagram illustrating another example of reference data that is reference data stored in the reference data storage unit 103 of FIG. 2 and that associates characters with lines.

FIG. 18 is a diagram illustrating an example of reference data which is reference data stored in the reference data storage unit 103 of FIG. 2 and which converts input data into lines.

19 is a character estimation unit 10 of the recognition unit 101 in FIG.
It is a figure explaining the outline | summary of FIG.

[Explanation of symbols]

11 ... Small electronic device 12 ... Numeric keypad 13 ... Display 100 ... Control unit 101 ... Recognition unit 102 ... Input data converter 103 ... Reference data storage unit 104 ... Character guessing section 105 ... Japanese conversion unit

Front page continuation (51) Int.Cl. ⁷ identification code FI H04M 1/23 (58) Fields investigated (Int.Cl. ⁷ , DB name) G06K 9/62 G06F 3/023 G06F 15/02 H04M 1 / 02 H04M 1/23

Claims (10)

(57) [Claims] 1. A small unit having an input device in which a numeric keypad is arranged.
Vertical line vector, horizontal line vector, diagonal line vector, and curved line are recognized in the character input / recognition system for portable electronic devices.
It has decision data to refuse, and handwritten characters on the keys
When you draw the keyboard layout vertically, horizontally, diagonally,
The character input data by pressing the line key is the judgment data
Vertical line vector, horizontal line vector, diagonal line vector,
The combination of the input data converter that converts to a curve and the vertical lines, horizontal lines, diagonal lines, and curves that make up the character
Characters are grouped and the characters are grouped by the number of vertical lines that make up the character.
Group and group characters by the number of horizontal lines that make up the character.
Groups and groups characters by the number of diagonal lines that make up the character
And group the characters by the number of strokes, and the first in the stroke order of the characters.
Characters are grouped by the key pressed on the eye and written
Characters are grouped by the last key pressed in the order of
Reference data that stores multiple tables as reference data
The storage unit and the input data of the character converted by the input data conversion unit
For each vector and curve, each table in the reference data storage section
Get high on the letters that belong to the closest group with reference to the bull
Give points and score low for characters belonging to distant groups
And add the score for each character to all tables
Then, draw the character with the maximum added value of the above points by handwriting
It is specially equipped with a character guessing unit that guesses the entered characters.
Character input / recognition system for small electronic devices. 2. The handwriting on the key in the reference data storage unit
When the above characters are drawn in the
Each adjacent key is expected to be weighted.
The character guessing unit refers to the weighting and
The weight is added each time it is pressed, and the added value of the weight of the input character is added.
Then, the sum of the added value of the weight and the added value of the score is the maximum.
Guess the large characters by handwriting
The small electronic device apparatus according to claim 1, characterized in that
Character input / recognition system. 3. The input data converter is the input device.
The direction of up to 8 keys adjacent to any key of
Kuturu, and the basic vector is the upward basic vector
Le, downward basic vector, leftward basic vector, rightward
Basic vector, diagonally upward right Basic vector, diagonally downward right
Can the basic vector, left diagonally upward basic vector, lower left
A set of upward basic vectors consisting of upward basic vectors
And the combination of downward basic vectors
It has the data to judge that
Tor, upward basic vector, right basic vector pair
Matching, diagonal left downward basic vector, downward basic vector
Combination of left-handed basic vector, diagonally upward-left base
Book vector, upward basic vector, leftward basic vector
Combination, right diagonal downward basic vector, downward basic
The inclination from the combination of vector and right-pointing basic vector
It has the data to judge that it is a diagonal vector, and has an upward basic vector.
Le, downward basic vector combination, right basic vector
Tor, a combination of leftward basic vectors, and an upward basic vector
Cuttle, downward basic vector, right basic vector, left
Judge as the above curve from the combination of the orientation basic vectors
Small data according to claim 1, characterized in that it has data.
Input / recognition system for portable electronic devices. 4. The input data conversion unit, key press time
Depending on the relationship with
The small electronic device according to claim 1, characterized in that it is identified.
Character input / recognition system for equipment. 5. The reference storage unit stores the same character
Characterized by preparing multiple features of lines that make up characters
Character input / recognition of the small electronic device according to claim 1.
Knowledge system. 6. The input device comprises at least two vertical columns
The key according to claim 1, characterized in that the key consists of two horizontal rows.
Character input / recognition system for the small electronic devices listed above. 7. The input device comprises keys in three columns and four columns.
2. The miniature battery according to claim 1, characterized in that
Character input / recognition system for child devices. 8. The input data converter is placed on the numeric keypad.
Convert input data of written English characters into vector
The small electronic device according to claim 1, wherein
Device character input / recognition system. 9. The input data converter is placed on the numeric keypad.
Input data of katakana characters drawn by writing into a vector
The small electronic device according to claim 1, wherein the electronic device is converted.
Character input / recognition system for equipment. 10.Has an input device with an array of numeric keys
In the character input / recognition method for small electronic devices, With a combination of vertical lines, horizontal lines, diagonal lines, and curves that make up characters
Grouping characters and storing them in a table, A table that groups characters by the number of vertical lines that make up the character
Process of storing in Table by grouping characters by the number of horizontal lines that make up the characters
Process of storing in Group text by the number of diagonal lines that make up the text and
The process of storing in a bull, The process of grouping characters by the number of strokes and storing them in a table
When, The character is pressed with the key that was pressed first in the writing order of the character.
The process of looping and storing in a table, Use the above-mentioned key that was pressed last
And the process of storing in a table Keys that are expected to be pressed in the order in which they are written
Each key that is adjacent to
Storing the weighting for the key of the group, Vertical line vector, horizontal line vector, diagonal line vector, curve
Forming judgment data to be cut off, When a character is drawn by hand on the key, the vertical direction of the key layout
Directional, lateral, diagonal, and curved key presses
Input data based on the judgment data
The process of converting to line vector, diagonal line vector, curve, Converted character input data vector, for curves
Referring to each of the tables in the reference data storage unit,
Higher scores are given to characters that belong to the closer group,
Give a low score to the letters belonging to the group
The process of adding scores for each character to the table, Stored when the character is drawn by hand on the key
Refer to the weighting of the key of each group
The weight is added for each bottom, and the added value of the weight of the input character is calculated.
And the The sum of the added value of the weight and the added value of the score is the maximum.
And the process of guessing the input characters by handwriting
Of a small electronic device having a Character input
-Recognition method.