KR100852020B1 - Method for Inputting Letters - Google Patents

Abstract

The present invention uses a character input device capable of generating at least four signals without using a general keyboard, so that a combination signal combining at least one of the signals is not duplicated. In response to a lowercase letter, hiragana letter, katakana number, a special character, and the like, the present invention relates to a character input method for generating a corresponding character after detecting and detecting a combined signal through a character input device. The present invention uses a character input device that can signal the movement of a finger, such as a wheel mouse, touch pad, trackball, several combined buttons, etc., with at least four signals, rather than through a keypad in the form of a general keyboard. The character input device according to the present invention comprises an input device part for signaling and inputting a movement of a finger, a memory part for temporarily storing the input signal, an arithmetic processing part for calculating and characterizing the text, and a signal control part for transmitting the character to the system. .

Character input, signal

Description

Method for Inputting Letters}

The present invention relates to a character input method using a character input apparatus capable of generating at least four signals, and inputting characters in correspondence with letters, numbers, etc. without overlapping a signal combining at least one of the signals. In detail, a character input device that generates at least four signals without using a keypad of a general keyboard type such as a keyboard is used, and the generated signals are not duplicated. The present invention relates to a character input method for generating letters, numbers, and special characters in correspondence with katakana, numbers, and special characters.

Character input in a general form is made through a keypad (such as 'keyboard') of the keyboard type, such as a keyboard. The use of the keyboard outpaces other input devices in terms of speed and convenience of text input.

However, there are some disadvantages to the character input method using the keyboard.

First, input by two hands is essential to increase the input speed. You can type with one hand, but it is inconvenient not only in speed but also in functionality. In particular, existing keyboards are inconvenient for people with disabilities that can use only one hand or those who work in an environment where only one hand must be used.

Second, in recent years, the GUI is used in the web-based program environment such as the Internet, and the mouse is used as the injection power device rather than the keyboard.

Even if you use the mouse to enter text for the search window or to enter information, it is inevitable to remove the mouse and move it to the keyboard. Alternately moving mouse and keyboard to input a few letters rather than a lot of letters is more troublesome than I thought.

Third, the keyboard currently used is excellent in its convenience, but takes up a lot of space.

The monitor and the body have made a lot of developments and changes in shape and size, resulting in a lot of workspace. However, the shape and size of the keyboard has changed little since the invention. In particular, recently, mobile terminals have developed to be comparable to those of conventional PCs by adding various functions. However, in order to fully utilize these functions, the input method of the portable terminal can be effectively input in a narrow space rather than the conventional keyboard input method. Different levels of input are required.

The present invention is to solve the problems of the prior art, it is an object of the present invention to increase the inconvenience and spatial convenience of cross-use between the mouse and the keyboard in the current user environment. The present invention is achieved through a completely new text input method, not the current text input method, and the new text input method uses a text input device such as a wheel mouse, a touch pad, a trackball, or a combination of buttons commonly used at present. The purpose is to implement.

Hereinafter will be described focusing on the technical configuration of the present invention.

The present invention uses a character input device capable of generating at least four signals, the signal generating step of generating a combined signal combining at least one of the signals through the character input device; The combination signal corresponds to syllabic letter, phonemic letter, number, or special character without overlapping, and when the combination signal is detected, the combination signal is processed and the syllable, phoneme, number, or special character corresponding thereto is detected. It provides a character input method through the character generation step of generating a.

Preferably, the character input device used in the present invention generates a signal through at least four buttons or input elements, and the character input device generates a long signal or a short signal according to a moving length in a predetermined direction, and the predetermined direction. The force field signal or the reverse stage signal may be generated according to the moving length in the reverse direction.

According to the present invention, it is possible to designate one signal among the signals as a consonant vowel conversion signal when inputting Korean characters, and in this case, the character generation step is a combination combining at least one of the remaining signals except for the consonant vowel conversion signal. A consonant generation step of generating a Hangul consonant by mapping a signal to the Hangul consonant; A consonant vowel conversion step of converting an input state from consonant to vowel or from vowel to consonant using the consonant vowel conversion signal; And a vowel generation step of generating a Hangul vowel corresponding to the Hangul vowel by combining a combination signal combining at least one of the remaining signals except for the consonant vowel conversion signal.

In addition, the present invention may cause the consonant vowel conversion signal to be generated through the consonant vowel conversion function key additionally provided to the character input device when inputting Korean characters. In this case, the character generation step may include a consonant generation step of generating a Hangul consonant corresponding to a Hangul consonant by combining a combination signal of at least one of the signals; A consonant vowel conversion step of converting an input state from a consonant to a vowel or a vowel to a consonant by further including a consonant vowel conversion function key in the character input device; And a vowel generation step of generating a Hangul vowel corresponding to the Hangul vowel with the combined signal combining at least one of the signals.

It is also possible to input a number through the present invention, the number 0, 1, 2, 3, 4, 5, 6, 7 so that the number does not overlap the number signal combining at least one of the signals in the character generation step Produced by corresponding to 8 or 9 Aribian numbers.

In addition, it is possible to input the alphabet through the present invention. In the character generation step, the alphabet is generated by corresponding to the alphabet so that the alpha bet signal obtained by sequentially combining at least one signal among the signals does not overlap.

In the present invention, the movement of the character input device in the predetermined direction and the movement in the reverse direction of the predetermined direction is performed through at least one of forward and backward movement, left and right movement, rotational movement, and Shanghaidong. The movement in the predetermined direction and the movement in the reverse direction of the predetermined direction may be implemented through at least one of a wheel mouse, a touch pad, and a trackball.

Further, a long signal, a short signal, a force field signal, and an inverse end signal are generated by distinguishing the long signal and the short signal according to the movement length in the predetermined direction and the reverse direction of the constant direction, and distinguishing between the long signal and the short signal or the force field and the reverse signal. The distinction of may be distinguished by passing out of the range of the predetermined distance or passing through a specific distance point.

In addition, the character input device may further include an input state converting function key to convert to at least one input state among consonant generation, vowel generation, uppercase alphabet generation, lowercase alphabet generation, number generation, or special character generation.

On the other hand, in the character input method for inputting a character using the first to third input signal and the completion signal according to the present invention, the character arrangement to arrange the characters divided into three groups so as to correspond to each of the first to third input signal Steps; A character input step of inputting a character corresponding to an input number of characters among the characters arranged in the selected input signal by inputting the selected input signal one or more times among the first to third input signals; It is preferable to include a character input method comprising a completion signal input step of waiting for the next input state of the character to be pressed by inputting the completion signal once.

In this case, the method may further include a blank signal input step of inputting a blank by inputting the completion signal twice.

Further, in the character arranging step, three groups of characters arranged to correspond to each of the first to third input signals are allocated to the first and second character groups, respectively. It is preferable that a character corresponding to the input number of the first character group allocated to the selected input signal is input by inputting the selected input signal one or more times from the third input signal.

In the character input step, the second character allocated to the selected input signal is input by inputting the third input signal one or more times after inputting one or more input signals selected from the first to third input signals. Characters corresponding to the number of times is preferably input.

In this case, the character input method for inputting a character using the first to third input signals and the completion signal according to the present invention may further include a blank signal input step of inputting a blank by inputting the completion signal twice. have.

In addition, the character input method for inputting a character using the first to third input signals and the completion signal according to the present invention, when none of the first to third input signal is inputted once the completion signal The method may further include an input state switching step of switching the input state by the input.

The present invention will be described in more detail with respect to a character input method for inputting an inputtable character.

Characters used in the present specification may be used as a concept including numbers in some cases, and characters that can be input are typically divided into three types, Korean, English, and numbers. However, the characters that can be input by the present invention are not limited to Korean, English, and numerals, and include both special characters and special symbols as well as existing or already-defunct phonetic letters (表音文字, phonogram).

Phonetic letters are divided into two types. These include syllabic letters that represent sounds in syllable units, phonemic letters that represent letters, and phonemes in phoneme units.

A phonetic letter is a phonetic character whose phonetic units are smaller than the syllable. There are letters such as alphabets, Korean, etc. to express sounds by combining phonemes of consonants and vowels. Korean, in addition to the 24 basic alphabets, combines five sounds and 11 multiples to represent the sounds of the world with letters.

On the contrary, the syllable character is a character whose syllable unit is a syllable. The Japanese character Kana is a good example. Japanese characters have 50 syllables called '50 notes' (actually there are about 100 if you include sound and sound).

In the present invention, the characteristics of the characters are analyzed and grasped with respect to Korean characters, numbers, and English, and the symbols are semi-symbols used in the present invention.

The symbols of Korean, numbers, and English described below are merely illustrative, and even if the corresponding symbols are different, the same principles and technical configurations will be considered to be included within the scope of the present invention.

(First embodiment)

First, a first embodiment of a character input method according to the present invention will be described.

Most mice in use today have a round cylinder called a wheel in the middle of the two buttons to make browsing the Internet and documents easier. The original purpose of the wheel is to use the wheel to scroll the screen conveniently up and down the monitor.

The present invention is a wheel mouse that can use the movement of the wheel (wheel mouse), a touch pad that can move up, down, left and right, a trackball (trackball) or a button-type character that can generate at least four signals An input device is used to signal the movement of a finger and generate a character corresponding to the signal.

The character input device according to the present invention comprises an input device part for signaling and inputting a finger movement, a memory part for temporarily storing the input signal, an arithmetic processing part for calculating and characterizing the text, and a signal control part for transmitting the character to the system. It is more preferable.

On the basis of the up-down, left-right, forward-backward or rotational motion signal from the character input device, the long and short of the signal is received. It can be divided into 'long signal' and 'short signal' according to the movement length or rotation angle in a certain direction, and can be divided into 'field force signal' and 'reverse signal' according to the movement length or rotation angle in the reverse direction. have.

In the present specification, motion signals such as 'long signal', 'short signal', 'field length signal', and 'inverse short signal' are referred to as 'semitone signals' in the sense of incomplete character signals.

(단신호)와

(장신호)형태로 표시하고, 아래로 짧게 또는 길게 발생하는 신호는

(역단신호)와

(역장신호)형태로 표시할 수 있다. 화살표를 이용한 표시방법은 본 발명에서 문자입력장치의 움직임을 신호화할 수 있는 여러 기호 중 하나에 불과하며 다양한 기호 및 표시방법을 사용하는 것이 가능함은 물론이다.When generating a semitone signal using the wheel mouse, as the wheel is moved up and down, a signal generated shortly or longly upward

(Short signal) and

In the form of (long signal), short or long down signal

(Reverse signal)

It can be displayed in the form of (field force signal). The display method using the arrow is just one of several symbols that can signal the movement of the character input apparatus in the present invention, and it is of course possible to use various symbols and display methods.

)으로 표시하게 된다. 상하 움직임 신호를 '주반음신호'라 하고, 좌우 움직임 신호를 '보조반음신호'로 구별할 수도 있다. 보다 구체적으로 설명한다.For example, for one such signal (one long down, one short up),

). The up-and-down motion signal may be referred to as a 'main semitone signal,' and the left and right motion signal may be classified as a 'secondary semitone signal.' It demonstrates more concretely.

In this specification, the semitone symbols corresponding to the semitone signals are as follows.

<Main sound signal system>

Semitone Semitone by finger movement

Short signal from top to bottom (single signal)

Short signal from bottom to top (reverse signal)

Long signal from top to bottom (long signal)

Long signal from bottom to top (force field signal)

These signals are combined to generate each character.

The motion signal up and down as described above serves as a main semitone signal for generating characters.

In addition, in the case of an input device capable of receiving left and right finger movement signals such as a touch pad or a trackball type, an auxiliary semitone signal may be used.

<Secondary semitone signal system>

Semitone Semitone by finger movement

Short signal from left to right

Short signal from right to left

Long signal from left to right

Long signal from right to left

The wheel mouse, touch pad, trackball, etc. used as the character input device in the present invention are merely exemplary, and can be used in the present invention regardless of how the input device is called if it can generate the same motion signal. It will be regarded as a character input device.

1 .Korean

Hangul is important to understand the principle of creation. Hangul is a combination of consonants and vowels. These vowels and consonants have a scientific design in terms of their motivation and meaning. The same holds true for computers that are said to be the greatest triumph of modern civilization. As you know, every signal in the computer consists of '0' and '1'.

The signal system of '0' and '1' is applied to the semitone signal mentioned above.

(1) display of consonants

Consonants are based on eight consonants as follows: (a, b, c, k, k, k, h, h, h). (ㄹ, ㅋ, ㅌ, ㅍ, ㅎ) or (ㄲ, ㄸ, ㅆ, ㅉ, ㅃ) is regarded as a series of basic consonants.

Consonant Generation from Basic Consonants

ㄱ-> ㅋ-> ㄲ ㄴ-> ㄹ ㄷ-> ㅌ-> ㄸ ㅁ-> blank ㅂ->--> ㅃ ㅅ-> ㅆ ㅇ-> ㅎ ㅈ->--> ㅉ

There are two ways to configure this consonant as a semitone signal.

1) Display method by consonant order

The semitone signal is combined in order according to the order of consonants in use. It is easy to understand because it is tailored to the order of consonants that everyone is familiar with.

<Consonant Semitone Signal System by Sequence>

Consonant Semitone Consonant Semitone A

ㅂ

N

S

C

ㅇ

M

ㅈ

2) Division by sound length

Consonants are divided into long and consonants according to the length of the sound to be pronounced. The consonant is composed of the first semitone signal of each consonant according to the length of the consonants. Depending on the pronunciation length of the consonant, the actual semitone signal is also short and short, and long and long.

Terminal sound (short): ㄱ, ㄷ, ㅅ, ㅈ

Long Jain (long sound): ㄴ, ㅁ, ㅂ, ㅇ

<Consonant Halftone System Based on Sound Length>

Terminal sound Semitone Longy Semitone A

N

C

M

S

ㅇ

ㅈ

ㅂ

또는

반음신호 입력으로 시작할 수 있고, 현 입력자음의 파생자음을 입력하고자하면

반음신호을 입력하면 된다.According to the above two methods, two semitones are combined to generate a consonant. When the consonant is determined, the next consonant can be input or extended to a derivative consonant, and the vowel can be input by the vowel input signal. have. New consonants again

or

You can start with a semitone signal input, and if you want to input a derivative of the current input consonant

Input the semitone signal.

가 들어와 ( ㄱ ) 이 표시된 후,

반음신호가 들어오면 ( ㅋ )이 입력되고, 여기서 다시

반음신호가 들어오면 ( ㄲ ) 이 입력된다. 다른 파생자음도 이와 같은 원리로 입력받게 된다.For example, semitones

After (a) appears,

When the semitone signal comes in, (ㅋ) is input, and here again

When the semitone signal comes in, (ㄲ) is input. Other derived consonants are input on the same principle.

(2) display of vowels

There are two ways to organize vowels into semitones.

1) Combination type collection

The combinatorial method is a method of creating a vowel by dividing the vowel into basic characters (ㅡ), (·), and (ㅣ). The semitones of these three characters are:

Combination Vowel Semitone System

collection Semitone collection Semitone collection Semitone ㅣ

ㆍ

ㅡ

The three semitones are combined to form a vowel.

와

을 입력받아 표시된다.For example, a vowel is a semitone

Wow

Is displayed.

This is due to the principle of vowel generation, which is easy to understand and quick to acquire.

2) complete vowel method

The completed vowel method displays one vowel with one semitone signal, and displays another vowel by repeatedly inputting the semitone signal.

<Complete Vowel Semitone System>

collection Semitone collection Semitone collection Semitone collection Semitone ㅏ

ㅓ ㅏ +

ㅑ ㅓ +

ㅕ ㅕ +

ㅗ

TT ㅗ +

ㅛ TT +

ㅠ ㅛ +

ㅣ

ㅡ ㅣ +

ㅢ ㅡ +

By displaying the most commonly used vowels as one semitone, the overall character input speed can be improved.

(3) change of consonant input and vowel input

The semitones of consonants and vowels are defined above, and since they share the same semitones, it is necessary to distinguish between the input of consonants and the input of vowels.

There are three ways to distinguish this.

First, you can enter by pressing the consonant / vowel input button once, or input while pressing and holding. In the case of the wheel mouse, the right button or the left button can be used for this role. Click the right / left mouse button to switch between consonants and vowel input, or generate a semitone signal while pressing the mouse button to input the vowel. The consonant is input by generating a semitone signal without pressing a button. In this case, the right mouse button functions as a consonant vowel function key on the character input device.

로써 자음과 모음 입력을 변환하는 것이다.Second, semitone

To convert consonant and vowel input.

반음신호를 받으면 그때부터 입력되는 반음신호는 모음으로 표시되며, 다시 반음신호

가 들어오게 되면 다시 자음을 입력받게 된다. 이때 반음신호

가 자/모음 변환신호 역할을 하기 위해서는 반음신호 입력 메모리 버퍼에 아직 결정되지 않은 반음신호가 존재하지 않아야 한다. 다시 말해 현재 메모리 버퍼에 자음의 반음신호

가 앞에 있는 상태에서

가 들어오면

와 같은 반음신호로 조합되어 이에 해당되는 자음이 표시되게 된다.While entering consonants

When the semitone signal is received, the semitone signal input from then is displayed as a vowel, and the semitone signal again.

When comes to receive the consonant again. Semitone

To function as a gamma / vowel conversion signal, there should be no semitone signal yet determined in the semitone signal input memory buffer. In other words, the semitone of consonants in the current memory buffer.

With in front of

Comes in

The consonant corresponding to the semitone signal is displayed.

반음신호를 입력받아 (ㄱ)을 표시한 후,

를 입력받으면 이때부터 입력되는 것은 모음신호로

이 입력되어지면 (가)가 입력된다, 이때 다시

반음신호가 입력되어지면 자음이 입력되고, 여기서

반음신호가 입력되어지면 (각) 이 입력되는 것이다. For example, consonant / vowel conversion

After receiving a semitone signal and displaying (a),

Is inputted from this time as a vowel signal

If is input, is inputted, again

When a semitone signal is input, consonants are input, where

When the semitone signal is input, (angle) is input.

In the character input method according to the present invention, if one signal among four semitone signals is designated as a consonant vowel conversion signal, characters are input as the remaining three semitone signals.

Third, in the input device using the auxiliary semitone signals to the left and the right, such as the touch pad and the trackball, the auxiliary semitone signals are collectively displayed. That is, up and down signals represent consonants and left and right signals are distinguished by vowels. This approach has the advantage of not requiring a special ruler / vowel conversion system.

The specific vowels and consonants corresponding to the semitone signal generated through the character input device during Korean input are merely exemplary, and the vowels and the consonants may correspond to the semitone signals in various ways. Even if the vowel or consonant corresponding to the semitone signal generated through the character input device is changed, it will fall within the technical configuration of the present invention.

2. Number

The numbers are divided into three groups: upper, middle, and lower to form a semitone signal in order.

The lower group is divided into (1,2,3), the middle group is (4,5,6), and the upper group is divided into (7,8,9).

), 중 그룹이 (

), 상 그룹이 (

) 로 시작되며, 반복적으로 많이쓰여지는 0 은 (

) 한 신호로 표시된다.The first semitones in these groups are

), Of which groups (

), Award group (

), And the repetitively used 0 is (

This is indicated by a signal.

number Semitone number Semitone number Semitone One

2

3

4

5

6

7

8

9

0

The number corresponding to the semitone signal at the time of numeric input is merely exemplary, and the Arabic numeral may correspond to the semitone signal in various ways. Even if the corresponding number is changed will be considered to fall within the technical configuration of the present invention.

3. English

The 26 letters of English are divided into nine groups that are currently standardized.

신호를 더하면서 같은 그룹의 다음 글자로 변환된다.In the case of English, vowels and consonants are mixed and cannot be divided by their characteristics. In each group,

As you add signals, they are converted to the next letter in the same group.

Alphabetic characters Semitone Alphabetic characters Semitone Alphabetic characters Semitone A

B A +

C B +

D

E D +

F E +

G

H G +

I H +

J

K J +

L K +

M

N M +

O N +

P

R P +

S R +

T

U T +

V U +

W

X W +

Y X +

.

Q . +

Z Q +

을 입력함으로써 변환한다.The alphabetic characters can be distinguished by uppercase and lowercase letters, and the conversion can be done by using the upper / lowercase conversion button or semitone

Convert by typing

Similarly, the alphabet corresponding to the semitone signal at the time of English input is merely exemplary, and the alphabet may correspond to the semitone signal in various ways and forms without overlapping the semitone signal. Even if the alphabet corresponding to the semitone signal is changed will be considered to fall within the technical configuration of the present invention.

4. Conversion of input state of Korean, English, and numbers

In the character input device according to the present invention, an input state converting function key is additionally provided to convert the input state into at least one of a Korean input state, a numeric input state, and an English input state. When converting the input state, it is possible to distinguish between the consonant input state and the vowel input state in the case of Korean input, and it is also possible to distinguish between the upper case input state and the lower case input state in the case of English input.

(2nd Example)

Next, a second embodiment of the character input method according to the present invention will be described.

According to the present embodiment, as the four types of input signals, characters used in an existing keyboard, specifically, Korean, English, numbers, as well as spaces between characters can be input.

The four signals have different input functions for each character (Korean, English, numbers).

Specific input methods for each character (Korean, English, numbers) will be described below.

1 .Korean

The Korean input is divided into consonant (consonant), vowel (neutral), and basal (final), and the input mode is determined by the completion signal, that is, the consonant / vowel / support conversion signal.

Hangul has different forms for these consonants because they differ in their first consonants and their final consonants.

Hangul inputs characters by changing the input mode in order of consonant-> vowel-> consonant-> vowel by one complete signal, that is, consonant / vowel / support conversion signal.

In the case of a character with a backrest, the backrest can be input by sending two consonant / vowel / backrest conversion signals in the vowel input state.

Blanks can be entered by sending two consonant / vowel / supported conversion signals in the backing mode. Alternatively, it may be input by sending a consonant / vowel / supported conversion signal long. If a space is entered, it automatically enters the consonant (initial) input mode.

(1) consonants

Consonants (choseong) means the character input corresponding to the first sound when entering Hangul. So type after vowel (neutral) or base (final) or after space (Space).

The change of consonant (consonant) can be divided into two types. There are two methods of dividing the sound into consonants and a user's convenience. First, the explanation is divided into similar sound forms.

Of four input signals division Change due to repetition of input signal To the converted signal Consonant change First input signal A ↓ C ↓ ㅈ   → ㅋ → ㄲ   → ㅌ → ㄸ   → → → ㅉ Second input signal ㅇ ↓ N ↓ ㅂ   → ㅁ → ㅎ   → ㄹ   → → → ㅃ Third input signal (Conversion signal) S   → ㅆ. Characters converted from other input signals are converted to other characters Complete signal (consonant / vowel / support Conversion signal) 3 input signals respectively with consonants, vowels, Convert for input.

As shown in the table above, the four input signals for inputting the consonants are composed of the following character signals.

The first to third input signals are input signals for a representative character which is a standard of Korean consonants when a consonant (first consonant) or a consonant (final) is input, and may be converted into another representative character by repeating the character signal.

For example, 'b' may be input by pressing the second input signal twice, and 'ㅉ' may be input by pressing the character signal 1 three times and pressing the third input signal (converted signal).

If there is no character previously input, for example, when the third input signal is pressed, 'ㅅ' is input.

After the consonant (consonant) is input, the vowel can be input by inputting a consonant / vowel / support conversion signal.

Next, a method of dividing consonants (consonants) in consideration of user convenience (frequency of use) is shown in the following table.

Of four input signals division Change due to repetition of input signal To the converted signal Consonant change First input signal A ↓ C ↓ ㅈ   → ㅋ → ㄲ   → ㅌ → ㄸ   → → → ㅉ Second input signal ㅇ ↓ S ↓ ㅂ   → ㅁ → ㅎ   → ㅆ   → → → ㅃ Third input signal (Conversion signal) N   → d →. Characters converted from other input signals are converted to other characters Complete signal (consonant / vowel / support Conversion signal) 3 input signals respectively with consonants, vowels, Convert for input.

Inputting characters is the same as dividing them into similar phonetic forms.

(2) vowel (neutral)

The vowel (neutral) is always the character that comes after the consonant (first) is complete. Vowels have two forms of transformation, the first being complete and the second being combinatorial.

end. In the case of completion type

The vowel (neutral) completion type assigns and uses three complete vowels that are the basis for the three character input signals. By repeating the same text signal in this state, it is possible to convert from the basic vowel to another vowel.

In the case of double vowels, these short vowels can be made with two or more inputs.

A table for vowel entry is shown below.

Of four input signals division To repeat the input signal Vowel changes by First input signal   ㅏ → ㅓ → ㅑ → ㅕ Second input signal   ㅗ → ㅜ → ㅛ → ㅠ Third input signal   ㅣ → ㅡ → ㅢ Complete signal (consonant / vowel / support Conversion signal) 3 input signals respectively with consonants, vowels, Convert for input.

The first to third input signals are signals for inputting a vowel and a consonant / vowel / support conversion signal (blank signal) is a signal for inputting a vowel and switching to a state for inputting a final or initial.

If you input two consonant / vowel / backed conversion signals (blank signal), a blank is created.

For example, 'ㅑ' may input the first input signal three times, and 'ㅡ' may input the third input signal twice.

A double vowel such as 'ㅚ' can be made by inputting the second input signal once and the third input signal once.

In this method, a basic vowel (a commonly used vowel) is assigned to the front side, and the basic vowel is input in the form of a complete vowel, so that a vowel can be generated with a relatively small input signal.

I. In combination

Combination of vowels (jongjong) is a method of creating a vowel by combining three basic elements (ㅣ, ㅡ, `) of Korean vowels.

A table for vowel entry is shown below.

Of four input signals division To repeat the input signal Vowel changes by First input signal   ' l '  Vowel input signal Second input signal   'ㅡ' vowel input signal Third input signal   '`' Vowel input signal Complete signal (consonant / vowel / support Conversion signal) 3 input signals respectively with consonants, vowels, Convert for input.

The first to third input signals are signals for inputting a basic vowel, and a consonant / vowel / support conversion signal (blank signal) is a signal for inputting a vowel and switching to a state for inputting a final or initial.

If you input two consonant / vowel / backed conversion signals (blank signal), a blank is created.

For example, when the first input signal is input and the third input signal is input, 'ㅏ' is made. When the second input signal is input and the third input signal is input, 'TT' is made.

This method is very convenient input method because the vowel itself can be typed like a letter, and the user can easily learn how to input.

(3) support

The consonants have a similar form to the consonants, but some of the consonants do not meet the consonants. These characters exclude the change of the bearing (the finality) and include a consonant that is not seen in the consonant (the first), so that the consonant can be input at once.

There are two types of change in the support (jongjong), the first is the conversion method considering the method of dividing into similar sound form and the second user convenience (frequency of use).

First, the input method of the support will be described based on the following table divided into similar sound forms.

Of four input signals division To repeat the input signal Change To the converted signal Due to change of support First input signal A ↓ C ↓ ㅈ   → ㅋ → ㄲ → ㄳ   → ㅌ → ㄵ → ㄶ   → Second input signal ㅇ ↓ N ↓ ㅂ   → ㅁ → ㅎ   → → → ㄺ → ㄻ → ㄼ        → ㄽ → ㄾ → ㅀ   → Third input signal (Conversion signal) S   → ㅆ → ㅄ Characters converted from other input signals are converted to other characters Complete signal (consonant / vowel / support Conversion signal) 3 input signals respectively with consonants, vowels, Convert for input.

As shown in the table above, the four input signals that input the finality consist of the following character signals.

The first to third input signals may be converted into other characters by repeating the input signal as input signals for the representative characters when inputting the support (final).

For example, 'c' may be input by pressing the first input signal twice, and 'ㄺ' may be input by pressing the second input signal twice and pressing the third input signal (converted signal) twice. have.

If there is no letter previously input, 'ㅅ' is input when the third input signal is pressed.

After inputting the support (final), the completion signal, that is, the consonant / vowel / support conversion signal is input, and the consonant (first) of the next character can be input.

To display a space, input two consonant / vowel / support conversion signals.

Next, a table for a method of inputting characters in consideration of user convenience (frequency of use) is shown below.

Of four input signals division To repeat the input signal Change To the converted signal Due to change of support First input signal A ↓ C ↓ ㅈ    → ㅋ → ㄲ → ㄳ    → ㅌ → ㄺ → ㄻ → ㄼ    → Second input signal ㅇ ↓ S ↓ ㅂ    → ㅁ → ㅎ    → ㅆ → ㄽ → ㄾ → ㅀ    →  Third input signal (Conversion signal) N → ㄹ → ㄵ → ㄶ → ㄺ → ㄻ → ㄼ → ㄽ → ㄾ → ㅀ Characters converted from other input signals are converted to other characters Complete signal (consonant / vowel / support Conversion signal) 3 input signals respectively with consonants, vowels, Convert for input.

Inputting characters is the same as dividing them into similar phonetic forms.

(4) Completion of Hangul

As described above, one Korean character can be input by sequentially entering the first consonant, the neutral, and the final consonant, and any character or sentence can be input.

2 numbers

You can enter numbers by entering the Arabic numerals 0 through 9. Since the Arabic numerals consist of 10 numbers, it is possible to convert inputs to other numeric signals by repeating the basic numeric signals.

Refer to the table below to see how to enter numbers.

Of four input signals division Numeric Arrangement First input signal                 1 → 2 → 3 Second input signal                 4 → 5 → 6 Third input signal                 7 → 8 → 9 → 0 Completion signal Completion of input of the number character currently being input

First, representative numerals are assigned to the first to third input signals, respectively. For example, the number 1 may be assigned to the first input signal, the number 4 may be assigned to the second input signal, and the number 7 may be assigned to the third input signal.

The completion signal is assigned as a signal indicating that the number input by the above three character signals is converted into the next number or the number input is completed.

As such, the Arabic numerals may be input as four signals, and specifically, may be implemented in three ways as follows.

(1) Number input by completion key value

By repeating the same text signal repeatedly, the number is changed and the number is finally input by the completion signal.

All three character signals are assigned the values (1,2,3) (4,5,6) (7,8,9,0) as shown in the table above, and the desired number is converted and input by repeating the same input signal. Can be.

If the number to be input is not a series of numbers currently being input, another number may be input by inputting another input signal without inputting a completion signal.

For example, we will explain how to enter the number 249.

First, when the first input signal is input twice, 2 is input. Thereafter, when the second input signal is inputted once, 4 is inputted, and when the third input signal is inputted three times, 9 is inputted, thereby completing the input of 249.

As another example, a method of inputting 8931 will be described.

First, when the third input signal is input twice and the completion signal is input, the input of 8 is completed. Then, if the third input signal is input three times, 9 is input. The reason for inputting the completion signal at this time and inputting the third input signal again is that the numbers in the same sequence are input twice in succession.

Then, when the first input signal is input three times, 3 is input and a completion signal is input. Finally, when the first input signal is input once, 1 is input.

This way, the user will be able to recognize the number you want to enter and then send a completion signal to enter it.

(2) Number input by time difference

By inputting the same signal over and over again, it changes the number and automatically enters it when you pause for a letter.

Each of the three input signals can be converted to the next number by assigning the values of (1,2,3) (4,5,6) (7,8,9,0) and repeating the same input signal continuously.

By not inputting the completion signal, when inputting multiple numbers, the input of the completion signal is reduced.

For example, the method of inputting the number 8931 will be described.

First, when the third input signal is input twice and pauses, 8 is input. After that, the third input signal is input three times, and when it is paused, 9 is input. Then, after inputting the first input signal three times and stopping for a while, 3 is input. Lastly, when the first input signal is input once and paused, 1 is input.

3. English

The alphabetic characters are assigned to the first to third input signals after the basic representative characters are set, and are then converted into the desired representative characters by repeatedly inputting the input signals. After that, the characters are converted and input in alphabetical order based on the representative character by the converted signal.

There are uppercase / lowercase letters in alphabetical letters. Basic input is based on lowercase letters, and uppercase letters can be input by uppercase / lowercase conversion signal. Capital letters are basically written at the very beginning of the sentence, so the capital letters are inputted when a capital / rumor conversion signal is received after the beginning of a sentence or a space. In other cases, lowercase letters are entered automatically.

The space is input as two consecutive uppercase / lowercase input signals during character input. Alternatively, it can also be input by inputting the uppercase / lowercase input signal long.

The alphabet can be divided into four types depending on the type of the basic representative character. For example, how to divide by alphabetical order, how to follow the method on the dial of the cell phone, how to divide by frequency of use of the alphabet, based on the vowels of the alphabet letters.

First, referring to the table below will be described how to enter the alphabet in alphabetical order.

Of four input signals division English Arrangement Change due to converted signal First input signal A ↓ D ↓ G ↓ J   → B → C   → E → F   → H → I   → K → L Second input signal P ↓ S ↓ V ↓ Y   → Q → R   → T → U   → W → X   → Z →. Third input signal (Conversion signal)  M   → N → O Convert the character converted by the input signal to another character Completed signal (case change signal) Complete the three letter signs and change the uppercase / lowercase Transform to receive input.

As described in the above table, the first to third input signals are signals for inputting most English characters. By repeating each input signal, it is converted into another alphabet and inputted.

For example, A may input the first input signal once, and S may input the second input signal twice.

The third input signal (conversion signal) is a signal for inputting one character (here M), and a signal for converting the character when there is an input signal previously input. If no input signal has been previously entered, enter the unique letter assigned to this signal, eg M.

For example, E may input the first input signal twice and then input the third input signal (converted signal) once. X inputs the second input signal three times and then inputs the third input signal (conversion signal) twice.

The completion signal (upper / lowercase change signal) is a signal for changing the uppercase and lowercase letters of English or inputting a space.

If there is no input signal before, inputting completion signal (case change signal) changes the character input form at the current input time from lower case to upper case.

When this completion signal (case change signal) is input twice in succession, a space is input.

If there is a character input in the current state, it is recognized as an input completion signal for the character and a state in which a new character can be input.

For example, in the case of inputting Kim, once the completion signal (case change signal) is inputted, the capital letters can be input. In this state, when the first input signal is input four times and the third input signal (conversion signal) is input once, K is input.

Then, when the completion signal (case change signal) is inputted, the lowercase letters can be entered. In this state, when the first input signal is input three times and the third input signal (conversion signal) is input twice, i is input.

Then, when the completion signal (case change signal) is inputted, the next character can be entered. In this state, when the third input signal (conversion signal) is input once, m is input. In this way, English can be input.

Next, a method of entering characters in the manner found in the dial face is shown in the table below.

Of four input signals division English Arrangement Change due to converted signal First input signal A ↓ D ↓ G ↓ J  → B → C  → E → F  → H → I  → K → L Second input signal P ↓ T ↓ W ↓ .  → R → S  → U → V  → X → Y  → Q → Z Third input signal (Conversion signal) M  → N → O Convert the character converted by the input signal to another character Completed signal (case change signal) Complete the three letter signs and change the uppercase / lowercase Transform to receive input.

Next, a method of inputting characters by frequency of use of the alphabet is shown in the table below.

Of four input signals division English Arrangement Change due to converted signal First input signal A ↓ E ↓ I   → B → C → D   → F → G → H   → J → K → J Second input signal O ↓ R ↓ T ↓ W   → P → Q   → S →.   → U → V   → X → Y → Z Third input signal (Conversion signal) L   → M → N Convert the character converted by the input signal to another character Completed signal (case change signal) Complete the three letter signs and change the uppercase / lowercase Transform to receive input.

Finally, a table below shows how to enter characters based on vowels among alphabetic characters.

Of four input signals division English Arrangement Change due to converted signal First input signal A ↓ E ↓ I   → B → C → D   → F → G → H   → J → K → J Second input signal O ↓ R ↓ U ↓ W   → P → Q   → S → T   → V →.   → X → Y → Z Third input signal (Conversion signal) L   → M → N Convert the character converted by the input signal to another character Completed signal (case change signal) Complete the three letter signs and change the uppercase / lowercase Transform to receive input.

In the present embodiment, by inputting a character using only at least one input signal, the user can easily input the character by increasing the intuitiveness of the character input and easily convert to another character.

In the above, the configuration of the present invention was described in detail with reference to Examples. However, the scope of the present invention is not limited to the above embodiments but may be embodied in various forms of embodiments within the appended claims. Without departing from the gist of the invention as claimed in the claims, any person of ordinary skill in the art is considered to be within the scope of the claims described in the present invention to the extent possible to vary.

As described above, the character input method according to the present invention can generate a character by mapping only a few finger movements through a simple character input apparatus and corresponding to Korean, numeral, English, and the like. Therefore, the existing keyboard occupies a lot of space, and the inconvenience of having to secure a large work space, as well as being adopted as a new character input method of the increasingly smaller portable terminal can be made easier to input characters. In addition, it provides a more convenient text input method for users who can use only one hand.

Claims (17)

delete Using a character input device capable of generating at least four signals, A signal generating step of generating a combined signal combining at least one of the signals through a character input device; The combination signal corresponds to syllabic letter, phonemic letter, number, or special character without overlapping, and when the combination signal is detected, the combination signal is processed and the syllable, phoneme, number, or special character corresponding thereto is detected. Including the character generation step to generate, The character input apparatus includes at least four buttons or input elements, and designates one of the signals as a consonant conversion signal. The character generation step comprises: a consonant generation step of generating a consonant consonant by combining a combination signal combining at least one of the signals other than the consonant vowel conversion signal with a Hangul consonant; A consonant vowel conversion step of converting an input state from consonant to vowel or from vowel to consonant using the consonant vowel conversion signal; And a vowel generation step of generating a Hangul vowel corresponding to a Hangul vowel by combining a combination signal combining at least one of the remaining signals except for the consonant vowel conversion signal. Using a character input device capable of generating at least four signals, A signal generating step of generating a combined signal combining at least one of the signals through a character input device; The combination signal corresponds to syllabic letter, phonemic letter, number, or special character without overlapping, and when the combination signal is detected, the combination signal is processed and the syllable, phoneme, number, or special character corresponding thereto is detected. Including the character generation step to generate, The character input device includes at least four buttons or input elements, The character generation step may include a consonant generation step of generating a Hangul consonant corresponding to a Hangul consonant by combining a combination signal of at least one of the signals; A consonant vowel conversion step of converting an input state from a consonant to a vowel or a vowel to a consonant by further including a consonant vowel conversion function key in the character input device; And a vowel generation step of generating a Hangul vowel corresponding to the Hangul vowel with the combined signal combining at least one of the signals. delete delete Using a character input device capable of generating at least four signals, A signal generating step of generating a combined signal combining at least one of the signals through a character input device; The combination signal corresponds to syllabic letter, phonemic letter, number, or special character without overlapping, and when the combination signal is detected, the combination signal is processed and the syllable, phoneme, number, or special character corresponding thereto is detected. Including the character generation step to generate, The character input device generates a long signal or a short signal according to the movement length in a predetermined direction, generates a force field signal or an inverted signal according to the movement length in the reverse direction of the predetermined direction, and collects one signal among the signals. Designated as the conversion signal, The character generation step may include: a consonant generation step of generating a consonant consonant corresponding to a consonant combination of at least one of the signals other than the consonant vowel conversion signal with a Hangul consonant; A consonant vowel conversion step of converting an input state from consonant to vowel or from vowel to consonant using the consonant vowel conversion signal; And a vowel generation step of generating a Hangul vowel corresponding to a Hangul vowel by combining a combination signal combining at least one of the remaining signals except for the consonant vowel conversion signal. Using a character input device capable of generating at least four signals, A signal generating step of generating a combined signal combining at least one of the signals through a character input device; The combination signal corresponds to syllabic letter, phonemic letter, number, or special character without overlapping, and when the combination signal is detected, the combination signal is processed and the syllable, phoneme, number, or special character corresponding thereto is detected. Including the character generation step to generate, The character input device generates a long signal or a short signal according to the movement length in a predetermined direction, and generates a force field signal or an inverted signal according to the movement length in the reverse direction of the predetermined direction, The character generation step may include a consonant generation step of generating a Hangul consonant corresponding to a Hangul consonant by combining a combination signal of at least one of the signals; A consonant vowel conversion step of converting an input state from a consonant to a vowel or a vowel to a consonant by further including a consonant vowel conversion function key in the character input device; And a vowel generation step of generating a Hangul vowel corresponding to the Hangul vowel with the combined signal combining at least one of the signals. The method according to claim 6 or 7, The movement in the predetermined direction and the movement in the reverse direction of the predetermined direction is performed by at least one of forward and backward movement, left and right movement, rotation movement, Shanghai movement. The method according to claim 6 or 7, The movement in the predetermined direction and the movement in the reverse direction of the predetermined direction is a character input method, characterized in that implemented through at least one of a wheel mouse (touch mouse), touch pad (touch pad), trackball (trackball). The method according to claim 6 or 7, A long signal, a short signal, a force field signal, and an inverse end signal are distinguished and generated according to the movement length in the predetermined direction and the reverse direction in the predetermined direction, and the distinction between the long signal and the short signal or between the force field and the reverse signal Character input method characterized in that the distinguished by moving out of the range of the predetermined moving distance or passing through a specific moving distance point. delete In the character input method for inputting a character using the first to third input signal and the completion signal, A character arrangement step of dividing characters into three groups so as to correspond to each of the first to third input signals; A character input step of inputting a character corresponding to an input number of characters among the characters arranged in the selected input signal by inputting the selected input signal one or more times among the first to third input signals; And a completion signal input step of waiting for an input state of a next character to be pressured by inputting the completion signal once. The method of claim 12, And a blank signal input step of inputting a blank space by inputting the completion signal twice. The method of claim 13, In the character arranging step, three groups of characters arranged to correspond to each of the first to third input signals are allocated to the first and second character groups, respectively. In the character input step, a character corresponding to an input number of the first character group assigned to the selected input signal is input by inputting the selected input signal one or more times among the first to third input signals. Input method. The method of claim 14, The character input step may include inputting the selected input signal from the first to third input signals one or more times and then inputting the third input signal one or more times to the number of inputs among the second characters allocated to the selected input signal. Character input method characterized in that the corresponding character is input. The method of claim 15, And a blank signal input step of inputting a blank space by inputting the completion signal twice. The method of claim 16, And an input state switching step of switching the input state by inputting the completion signal once when none of the first to third input signals is input.