KR20160035517A - Smart Sign Language Glove - Google Patents

Abstract

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Description

{Smart Sign Language Glove}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a glove capable of inputting and outputting the shape and movement of both hands to a smartphone using a wireless local area network.

Typically, deaf-mutes communicate with doctors through sign language. However, ordinary people and blind people who do not know sign language can not recognize the contents at all.

Therefore, in order to solve the above-mentioned problems, it is necessary to develop a system for converting sign language into text and voice.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a three-axis acceleration sensor, an optical sensor, an inertial sensor, a pressure sensor, an angle sensor, a distance sensor, a horizontal sensor, And it is aimed to provide a system that can input the shape, movement and speed of both hands to a smart phone by using a wireless LAN.

In addition, the shape, movement and speed of the input hands are converted into text and voice by a database embedded in an application in a smart phone to provide a system that can be transmitted to the general public and the visually impaired.

1, a glove includes a wireless transmitter 100, a power source 101, a hand sensor 102, a finger sensor 103, a fingertip sensor 104, a palm sensor 105, , And a motion recognition camera (106).

2, the flow of the application in the smartphone includes a receiving unit 201, a hand and motion analyzing unit 202, an application database 203, a text and audio output 204, a foreign language translation database 205, And a foreign language text and voice output 206 to the application user.

3, the necklace operation recognition camera 301 and the necklace operation recognition sensor 302 are formed on the necklace.

Further, the power source unit 101 is characterized by being able to apply sound knowledge, a rechargeable type, and a solar type.

In addition, the wireless transmission unit 100 can use all the local wireless communication networks already installed in the smartphone itself such as Bluetooth, NFC, etc. for wireless communication with the smartphone.

Also, the hand light sensor unit 102 is a sensor for sensing the overall angle and motion of the hand, and is characterized in that a three-axis acceleration sensor, an optical sensor, an inertial sensor, an angle sensor, a distance sensor and a horizontal sensor can be formed.

Further, the finger sensor unit 103 is a sensor for sensing the shape of a hand, and may be a triaxial acceleration sensor, an angle sensor, a pressure sensor, or the like.

Further, the fingertip sensor unit 104 is a sensor for sensing the shape of a hand, and may be a triaxial acceleration sensor, a distance sensor, a pressure sensor, or the like.

In addition, the palm sensor unit 105 is a sensor for sensing the shape of the floor of the hand, and may be a triaxial acceleration sensor, a distance sensor, a pressure sensor, or the like.

In addition, a motion recognition camera 106 may be formed on the palm surface to enhance the accuracy of motion recognition.

In addition, a necklace motion recognition camera 301 and a necklace motion recognition sensor 302 may be formed to improve the accuracy of motion recognition on the necklace.

In addition, the material of the glove is characterized in that the smartphone liquid crystal can be touched even in the state of wearing gloves by using the conductive fiber.

In addition, the application is capable of directly outputting text and voice on its own smartphone by inputting text or inputting text, and can transmit text and voice to the other party.

Also, the output text size can be maximized so as to be filled in the smartphone liquid crystal and output.

Also, the receiving unit 201 matches all the near-field radios built in the smartphone itself such as Bluetooth, NFC, etc. to the application database 203 by matching the hand shape and motion analysis unit 202 with the information stored in the application itself .

In addition, the application database 203 converts input hand shapes and movements into text and sends them to text and audio output.

In addition, the text and voice output 204 outputs text on an output screen of the smartphone itself and can output voice through the speaker of the smartphone itself.

Also, when conversion into a foreign language is required, the text can be converted into a foreign language by sending text to the foreign language translation database 205.

Also, the foreign language translation database 205 is capable of sending the translated foreign language text to the foreign language text and voice output 206.

In addition, the foreign language text and voice output 206 outputs text on the output screen of the smartphone itself and can output voice through the speaker of the smartphone itself.

In addition, the sign language application recognizes the voice and outputs text to the smartphone of its own, and the text can be transmitted to the other party (deaf).

Accordingly, the smart hydration glove and the hydration application according to the present invention include a wireless transmitter 100, a power source 101, a backlight sensor 102, a finger sensor 103, a fingertip sensor A touch sensor 104, a palm sensor unit 105, and an operation recognition camera 106, so that the shape and movement of the hand can be transmitted to the smartphone.

In addition, the wireless transmission unit 100 can use all the local wireless communication networks already installed in the smartphone itself such as Bluetooth, NFC, etc. for wireless communication with the smartphone, so that the device of the present smartphone itself can be utilized.

Also, the hand light sensor unit 102 has a three-axis acceleration sensor, an optical sensor, an inertial sensor, an angle sensor, a distance sensor, and a horizontal sensor.

In addition, the finger sensor unit 103 has a three-axis acceleration sensor, an angle sensor, a pressure sensor, and the like, thereby detecting the shape of the hand.

Also, the fingertip sensor unit 104 has a three-axis acceleration sensor, a distance sensor, a pressure sensor, and the like, so that it can detect the shape of the hand together with the finger sensor unit 103. [

Further, the palm sensor unit 105 is a sensor for sensing the shape of the floor of the hand, and has a three-axis acceleration sensor, a distance sensor, a pressure sensor, and the like.

In addition, since the motion recognizing camera 106 is formed on the palm surface, the accuracy of motion recognition can be improved.

Also, since the necklace motion recognition camera 301 and the necklace motion recognition sensor 302 are formed on the necklace, the accuracy of motion recognition can be improved.

In addition, the glove material can be used to touch the smartphone liquid crystal even with the gloves on using the conductive fiber.

In addition, the sign language application can output text and voice directly on its own smartphone by inputting text or text, and can transmit text and voice to the other party.

In addition, the output text size can be maximized so as to be filled in the smartphone liquid crystal and output.

In addition, the hand shape and motion analyzing unit 202 has an effect of being able to be matched with information that is databaseed in the application itself and sent to the application database 203. [

In addition, the application database 203 has an effect of converting input hand shapes and movements into text and sending them to text and audio output.

In addition, the text and sound output 204 outputs text on an output screen of the smartphone itself and can output voice through the speaker of the smartphone itself.

Also, when conversion into a foreign language is required, text is sent to the foreign-language translation database 205, and text can be converted into a foreign language.

Also, the foreign-language translation database 205 has an effect that the translated foreign-language text can be sent to the foreign-language text and voice output 206.

In addition, the foreign language text and voice output 206 outputs text on the output screen of the smartphone itself and can output voice through the speaker of the smartphone itself.

In addition, the sign language application can recognize the voice and output it as text on its own smartphone, and the text can be transmitted to the other party (deaf).

1 is a block diagram illustrating a wireless transmitter 100 according to the present invention, a power sensor 101, a finger sensor 103, a fingertip sensor 104, a palm sensor 105, Lt; RTI ID = 0.0 > 106 &
FIG. 2 is a block diagram illustrating the structure of a receiving unit 201, a hand and motion analyzing unit 202, an application database 203, a text and audio output 204, a foreign language translation database 205, And voice output 206,
FIG. 3 is a cross-sectional view showing a necklace-like necklace-motion recognition camera 301 and a necklace-motion recognition sensor 302 according to the present invention

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

1 is a block diagram illustrating a wireless transmitter 100 according to the present invention, a power sensor 101, a finger sensor 103, a fingertip sensor 104, a palm sensor 105, Lt; RTI ID = 0.0 > 106 &

FIG. 2 is a block diagram illustrating the structure of a receiving unit 201, a hand and motion analyzing unit 202, an application database 203, a text and audio output 204, a foreign language translation database 205, And voice output 206,

FIG. 3 is a cross-sectional view showing a necklace-like necklace-motion recognition camera 301 and a necklace-motion recognition sensor 302 according to the present invention

1, a glove includes a wireless transmitter 100, a power source 101, a hand sensor 102, a finger sensor 103, a fingertip sensor 104, a palm sensor 105, As shown in FIG.

2, the flow of the application in the smartphone includes a receiving unit 201, a hand and motion analyzing unit 202, an application database 203, a text and audio output 204, a foreign language translation database 205, A foreign language text and voice output 206, and can be recognized by the application user.

Also, the power source unit 101 can be applied with a sound knowledge, a rechargeable type, and a solar type.

In addition, the wireless transmission unit 100 may use any short-range wireless communication network already installed in the smartphone itself such as Bluetooth or NFC for wireless communication with the smartphone.

Further, the hand sensor 102 may be a sensor for sensing the overall angle and motion of the hand, and may be formed of a triaxial acceleration sensor, an optical sensor, an inertial sensor, an angle sensor, a distance sensor, and a horizontal sensor.

Also, the finger sensor unit 103 may be a sensor for sensing the shape of a hand, and may be formed with a triaxial acceleration sensor, an angle sensor, a pressure sensor, or the like.

Also, the fingertip sensor 104 may be a sensor for sensing the shape of the hand, such as a triaxial acceleration sensor, a distance sensor, a pressure sensor, or the like.

In addition, the palm sensor unit 105 may be a sensor for sensing the shape of the floor of the hand, and may be formed with a triaxial acceleration sensor, a distance sensor, a pressure sensor, or the like.

In addition, a motion recognition camera 106 may be formed on the palm surface to enhance the accuracy of motion recognition.

In addition, a necklace-shaped necklace-motion recognition camera 301 and a necklace-motion recognition sensor 302 may be formed to improve the accuracy of motion recognition.

In addition, the glove material can be manufactured so that the smartphone liquid crystal can be touched even when the glove is put on using the conductive fiber.

In addition, an application can output text and voice directly on its smartphone by signing or entering text, and can transmit text and voice to the other party.

In addition, the output text size can be maximized so as to fill the smartphone liquid crystal display.

Also, the receiving unit 201 can use all the local wireless communication networks built in the smartphone itself such as Bluetooth, NFC, and the like.

In addition, the hand shape and motion analysis unit 202 can match the information in the application itself to the application database 203 and send it to the application database 203.

Also, the application database 203 may convert the input hand shape and movement into text and send it to text and audio output.

In addition, the text and voice output 204 outputs text on the output screen of the smartphone itself and outputs voice through the speaker of the smartphone itself.

Also, when conversion to a foreign language is required, text can be sent to the foreign language translation database 205 to be text-converted into a foreign language.

The foreign language translation database 205 may also send the translated foreign language text to the foreign language text and voice output 206. [

Also, the foreign language text and voice output 206 outputs text on the output screen of the smartphone itself and can output voice through the speaker of the smartphone itself.

In addition, the sign language application can recognize the voice, output it as text on its own smartphone, and transmit the text to the other party (deaf).

It is to be understood that the present invention is not limited to the above-described embodiment, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims.

100: radio transmission unit 101: power supply unit
102: a hand light sensor part 103: a finger sensor part
104: fingertip sensor unit 105: palm sensor unit
106: Motion recognition camera
201: receiving unit 202: hand shape and motion analyzing unit
203: Application database 204: Text and voice output
205: Foreign language translation database 206: Foreign text and audio output
301: Necklace motion recognition camera 302: Necklace motion recognition sensor

Claims (20)

As shown in Fig. 1, the glove includes a wireless transmission unit 100, a power supply unit 101, a backlight sensor unit 102, a finger sensor unit 103, a fingertip sensor unit 104, and a palm sensor unit 105 Features a smart hydration glove As shown in Fig. 2, the flow of the application in the smart phone is composed of a receiving section 201, a hand and motion analyzing section 202, an application database 203, a text and audio output 204, a foreign language translation database 205, Text and voice output (206), and recognizes the application to the application user. The smart hydration glove The power source unit 101 is capable of applying sound knowledge, a rechargeable type, and a solar type. The smart sign language glove and the sign language application The hand light sensor unit 102 is a sensor for sensing the overall angle and movement of the hand and can be formed with a triaxial acceleration sensor, an optical sensor, an inertial sensor, an angle sensor, a distance sensor, a horizontal sensor, The finger sensor unit 103 is a sensor for sensing the shape of a hand, and may be formed with a triaxial acceleration sensor, an angle sensor, a pressure sensor, A fingertip sensor 104 is a sensor for sensing the shape of a hand, and may be formed with a triaxial acceleration sensor, a distance sensor, a pressure sensor, The palm sensor unit 105 is a sensor for detecting the shape of the palm, and may be formed with a triaxial acceleration sensor, a distance sensor, a pressure sensor, And a motion recognition camera can be formed on the palm surface in order to increase the accuracy of the operation. The motion recognition camera and the motion recognition sensor can be installed anywhere in the body such as a necklace type bracelet type as well as a glove, a smart hydration glove In addition, the material of the glove is made of conductive fiber, so that the liquid crystal of the smartphone can be touched even in the state of wearing the glove, the smart hydration glove The application is capable of outputting text and voice directly from a smartphone by inputting text or by inputting text, and is also capable of transmitting text and voice to the other party. The smart hydration glove And the output text size can be maximized so as to be filled in the smartphone liquid crystal, Also, the receiving unit 201 can use all the local wireless communication networks built in the smartphone itself such as Bluetooth, NFC, etc., And the hand shape and motion analysis unit 202 matches the information in the database itself to the application database 203 and sends the information to the application database 203. [ In addition, the application database 203 converts the input hand shape and movement into text and sends the text and audio output. In addition, the text and voice output 204 outputs text on an output screen of the smartphone itself and can output voice through a speaker of the smartphone itself. And the text can be converted into a foreign language by sending text to the foreign language translation database (205) when conversion to a foreign language is required, The foreign language translation database (205) is capable of sending the translated foreign language text to the foreign language text and voice output (206) Also, the foreign language text and voice output 206 outputs text on the output screen of the smartphone itself and can output voice through the speaker of the smartphone itself. In addition, the sign language application can recognize the voice, output it as text on its own smartphone, and send the text to the other deaf (deaf)

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