WO2015177932A1 - Bidirectional bone conduction communication device, bidirectional bone conduction communication method, and bidirectional bone conduction guide navigation system - Google Patents

Abstract

The objective of the invention is to obtain a bidirectional communication device, a bidirectional communication method and a bidirectional bone conduction guide navigation system whereby a headset can be worn on the head of a user for performing bidirectional bone conduction communications, and moreover, the data of user's pulses and the like can be measured and stored into an information server via the internet in real time, with the result that a manager can monitor the data in the information server. A bidirectional bone conduction communication device comprises: a helmet on which a bone conduction speaker, a bone conduction microphone, an optical pulse meter and a three-axis acceleration sensor are arranged; a processing circuit that performs computing of data from the bone conduction speaker, bone conduction microphone, optical pulse meter and three-axis acceleration sensor; and a bidirectional transmission/reception means that connects the processing circuit to the internet. The helmet is worn on the head of a user; the optical pulse meter detects the pulses of the user; the acceleration sensor detects the attitude of the user; and the bidirectional bone conduction communication device is connected to the internet by the bidirectional transmission/reception means in real time.

Description

Bidirectional bone conduction communication device, bidirectional bone conduction communication method, and bidirectional bone conduction guide navigation system

The present invention relates to a bidirectional bone conduction communication device and a bidirectional bone in which a bone conduction speaker, a bone conduction microphone, an optical pulse wave sensor, a three-axis acceleration sensor, and a bidirectional communication means are arranged on a helmet worn by a user. With respect to the conduction communication method and the bidirectional bone conduction guide navigation system, the user performs bidirectional bone conduction communication and also sends data of the user's body.

Various types of conventional bidirectional bone conduction communication devices are disclosed. A system with a body sensor is also disclosed. Patent Document 1 describes an interface system that generates a bone conduction sound and estimates a posture and a contact position of a body with a vibration input actuator disposed on a body, particularly an arm.

In Patent Document 2, a bone conduction speaker and a bone conduction microphone are arranged in a user's mouth to perform bone conduction communication, and body sensors such as body temperature and heart rate are also set in the user's mouth. It is described that it is arranged in the inside.

In Patent Document 3, a bone conduction speaker, a bone conduction microphone, and a communication device are arranged on the headband to perform bone conduction communication, and a pulse sensor is attached to the user's carotid artery, and the user's body data is collected. Sending is described.

JP 2013-33382 A Special table 2011-512049 gazette Republished WO2005-053800

In Patent Document 1, a body sensor is arranged on the arm and the posture of the user is measured. However, since the body sensor is arranged on the arm, there is a problem that the posture measurement error is large.
Moreover, in patent document 2, although the sensor of body temperature and heart rate is arrange | positioned in a user's mouth,
Due to the measurement in the mouth, there is a problem that the measurement error is large.
In Patent Document 3, the pulse sensor is arranged in the user's carotid artery, but due to the influence of the movement of the user's neck, there was a drawback that the measurement accuracy was poor,

An object of the present invention is that a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a helmet on which a three-axis acceleration sensor is disposed are mounted on a user's head to perform bidirectional bone conduction communication. In addition, the user's pulse data and posture data are accurately measured in real time, and the measurement data is stored in the information server via the Internet in real time. It is possible to provide a bidirectional bone conduction communication device, a bidirectional bone conduction communication method, and a bidirectional bone conduction guide navigation system that can be used for sightseeing, leisure, disaster, and the like.

The invention according to claim 1 of the present invention includes a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a helmet in which a three-axis acceleration sensor is disposed, the bone conduction speaker, the bone conduction microphone, and , An optical pulse meter, and a processing circuit for processing data from the acceleration sensor;
And a bidirectional bone conduction communication device configured with bidirectional transmission / reception means for connecting the processing circuit and the Internet, wherein the helmet is disposed on a user's head,
The optical pulse meter detects the pulse of the user, the acceleration sensor detects the posture of the user, and the data of the processing circuit is connected to the Internet in real time by the bidirectional transmission / reception means. This is a bidirectional bone conduction communication device.

The invention according to claim 2 of the present invention is characterized in that the bone conduction speaker is arranged in either the left or right temple part of the user, and the bone conduction microphone is arranged in the other temple part. The bidirectional bone conduction communication device according to claim 1.

The invention according to claim 3 of the present invention is the bi-directional bone conduction according to claim 1 or 2, wherein the optical pulse meter and the triaxial acceleration sensor are in close contact with the temple of the user's head. It is a communication device.

In the invention according to claim 4 of the present invention, the processing circuit includes a Bluetooth device, and the signals of the bone conduction speaker, the bone conduction microphone, the optical pulse meter, and the three-axis acceleration sensor are Input to the Bluetooth module through a modulation circuit in a processing circuit, and an output signal from the Bluetooth module is input to the bone conduction speaker;
The bidirectional bone conduction communication according to any one of claims 1 to 3, wherein the Bluetooth module exchanges data with the bidirectional communication means, and the bidirectional communication means is a smartphone. Device.

5. The bidirectional bone conduction communication device according to claim 1, wherein the helmet is a construction helmet or a bicycle helmet. It is.

According to a sixth aspect of the present invention, a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a three-axis acceleration sensor are arranged in a user's helmet. A microphone, an optical pulse meter, a processing circuit for processing data from the triaxial acceleration sensor, and the processing circuit and a bidirectional transmission / reception means connected to the Internet are arranged to perform bidirectional communication. In the bidirectional bone conduction communication method, the optical pulse meter detects a user's pulse, the triaxial acceleration sensor detects the user's posture, and the bidirectional transmission / reception means performs real-time transmission. The bidirectional bone conduction communication method is characterized in that the data of the processing circuit is connected to the Internet.

The invention according to claim 7 of the present invention is characterized in that the bone conduction speaker is arranged in either the left or right temple portion of the user, and the bone conduction microphone is arranged in the other temple portion. Item 7. The bidirectional bone conduction communication method according to Item 6.

The invention according to claim 8 of the present invention is characterized in that the optical pulse meter and the triaxial acceleration sensor are in close contact with the temple of the user's head. Is the method.

In the invention according to claim 9 of the present invention, the processing circuit includes a Bluetooth device, and the signals of the bone conduction speaker, the bone conduction microphone, the optical pulse meter, and the triaxial acceleration sensor are Input to the Bluetooth module through a modulation circuit in a processing circuit, and an output signal from the Bluetooth module is input to the bone conduction speaker;
The Bluetooth module performs data exchange with the bidirectional communication means,
The bidirectional bone conduction communication method according to any one of claims 6 to 8, wherein the bidirectional communication means is a smartphone. is there.

The bi-directional bone conduction according to any one of claims 6 to 9, wherein the helmet according to claim 10 of the present invention is a helmet for construction or a helmet for bicycles. It is a communication method.

According to an eleventh aspect of the present invention, there is provided a mobile unit equipped with a GPS receiver, a fixed information server, and a two-way data exchange between the mobile unit and the fixed information server. A helmet in which a communication means, a bone conduction speaker, a bone conduction microphone, and an optical pulse meter, and a triaxial acceleration sensor are arranged, the bone conduction speaker, the bone conduction microphone, and an optical pulse meter, In the bidirectional bone conduction guide navigation system, comprising: a processing circuit that processes data from an acceleration sensor; and data of the processing circuit; and bidirectional transmission / reception means connected to the Internet. Arranged on the user's head, the optical pulse meter detects the user's pulse, the acceleration sensor detects the user's posture, and the bidirectional transmission In real time by the signal means, the data of said processing circuit is a bidirectional osteoconductive guide navigation system, characterized in that connected to the Internet.

The invention according to claim 12 of the present invention is the bidirectional bone conduction guide navigation system according to claim 10, wherein the moving body is any one of a bicycle, a car, a wheelchair, or a user himself / herself. .

According to the bidirectional bone conduction communication device of claims 1, 2, 3, 4, and 5 of the present invention, good bone conduction communication is possible, and the pulse data and posture data of the user are measured in real time. The measurement data is sent to the Internet in real time, and the health condition of the user can be monitored.

According to the bidirectional bone conduction communication method of claims 6, 7, 8, 9, and 10 of the present invention, good bone conduction communication is possible, and the pulse data and posture data of the user are measured in real time. The measurement data is sent to the Internet in real time, and the health condition of the user can be monitored.

According to the bidirectional bone conduction guide navigation system of claims 11 and 12 of the present invention, good bone conduction communication is possible, and the pulse data and posture data of the user are measured in real time, and the measurement data Can be sent to the Internet in real time to monitor the health status of the user.

According to the present invention, a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a helmet on which a triaxial acceleration sensor is disposed are mounted on a user's head to perform bidirectional bone conduction communication. Furthermore, the user's pulse data and posture data are measured in real time, and the measured data is stored in the information server via the Internet in real time, and the administrator monitors the data of the information server. It is possible to provide a bidirectional bone conduction communication device, a bidirectional bone conduction communication method, and a bidirectional bone conduction guide navigation system that can be used for sightseeing, leisure, disasters, and the like.

The figure of the helmet used for the bidirectional | two-way bone conduction communication apparatus of the Example of this invention. FIG. 1A is a diagram of a bicycle helmet, and FIG. 1B is a diagram of a construction site helmet. The block diagram of the processing circuit used for the bidirectional | two-way bone conduction communication apparatus of this invention. The figure of the bidirectional | two-way bone conduction communication apparatus of the Example of this invention. The figure of the bidirectional | two-way bone conduction communication apparatus of the other Example of this invention. The figure of the system of the bidirectional bone conduction communication apparatus of other examples of the present invention. The figure of the bone conduction headphones of the present invention.

1a, 1b Bone conduction microphone 2a, 2b Bone conduction speaker 3 Optical pulse sensor 4 Triaxial acceleration sensor 5 Circuit processing unit 6 Smartphone (two-way communication device)
7 Brutose module 8 Sensor group 9 Battery 10 Bicycle helmet 20 Construction helmet 30, 31, 32 User 40, 41 Bicycle 50 Bone conduction headset

A bidirectional bone conduction communication device according to an embodiment of the present invention includes a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a helmet in which a three-axis acceleration sensor is disposed, the bone conduction speaker, and bone conduction Bidirectional bone conduction communication composed of a microphone, an optical pulse meter, a processing circuit for processing data from the acceleration sensor, and a bidirectional transmission / reception means for connecting the processing circuit and the Internet The helmet is disposed on a user's head, the optical pulse meter detects the user's pulse, the acceleration sensor detects the user's posture, The bidirectional bone conduction communication apparatus is characterized in that data of the processing circuit is connected to the Internet in real time by a bidirectional transmission / reception means.

Here, the bone conduction speaker is arranged in the left or right temple part of the user, the bone conduction microphone is arranged in the other temple part, and the optical pulse meter, the triaxial acceleration sensor is used. It is characterized by being in close contact with the temple of the person's head.

Here, the processing circuit has a Bluetooth module, and the signals of the bone conduction speaker, the bone conduction microphone, the optical pulsometer, and the three-axis acceleration sensor are passed through the modulation circuit in the processing circuit. And the output signal from the bluetooth module is input to the bone conduction speaker, and the bluetooth module receives and transmits data to and from the bidirectional communication means. The communication means is a smartphone.

The helmet is a construction helmet or a bicycle helmet, but is not limited to these forms.

In the bidirectional bone conduction communication method according to the embodiment of the present invention, a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a three-axis acceleration sensor are arranged in a user's helmet, and the bone conduction speaker is arranged. , A bone conduction microphone, an optical pulse meter, a processing circuit for processing data from a three-axis acceleration sensor, and the processing circuit and a bidirectional transmission / reception means connected to the Internet, A bidirectional bone conduction communication method for performing communication, wherein the optical pulse meter detects a user's pulse, the triaxial acceleration sensor detects a user's posture, and the bidirectional transmission / reception means The interactive bone conduction communication method is characterized in that the processing circuit data is connected to the Internet in real time.

Here, the bone conduction speaker is placed on the left or right temple part of the user, the bone conduction microphone is placed on the other temple part, and the optical pulse meter, 3-axis acceleration sensor is used. Adhere closely to the temple on the person's head.

An interactive bone conduction guide navigation system according to an embodiment of the present invention includes a mobile body equipped with a GPS receiver, a fixed information server, and data exchange between the mobile body and the fixed information server. A bi-directional communication means, a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a helmet in which a three-axis acceleration sensor is arranged, the bone conduction speaker, the bone conduction microphone, and the optical pulse And a processing circuit for processing data from the acceleration sensor,
In the bidirectional bone conduction guide navigation system, comprising the data of the processing circuit and the bidirectional transmission / reception means connected to the Internet, the helmet is disposed on the user's head. The optical pulse meter detects the pulse of the user, the acceleration sensor detects the posture of the user, and the data of the processing circuit is connected to the Internet in real time by the bidirectional transmission / reception means. This is a bidirectional bone conduction guide navigation system. Here, the moving body is any one of a bicycle, a car, a wheelchair, or the user himself / herself.

Examples of the bidirectional bone conduction communication device, the bidirectional bone conduction communication method, and the bidirectional bone conduction guide navigation system of the present invention will be described below.

Example 1
FIG. 1 is a diagram of a helmet of a bidirectional bone conduction communication device according to a first embodiment of the present invention.
FIG. 1A is a diagram of a bicycle helmet 10, and FIG. 1B is a diagram of a construction site helmet 20.
In FIG. 1A, the user 30 has a bicycle helmet 10 on his head.
The bicycle helmet 10 includes a bone conduction microphone 1a as an audio input unit, a bone conduction speaker 2a as an audio output unit, an optical pulse sensor (not shown), and a triaxial acceleration sensor (not shown). ), A processing circuit (not shown), and a battery 9 are arranged.
Here, the bone conduction microphone 1a is disposed in the left temple portion of the user, and the bone conduction speaker 2a is disposed in the right temple portion of the user. Note that this arrangement may be reversed depending on the use situation.

In FIG.1 (b), the user 30 is wearing the construction helmet 20 on the head,
The construction helmet 20 includes a bone conduction microphone 1b as an audio input unit, a bone conduction speaker 2b as an audio output unit, an optical thin film sensor 3, a triaxial acceleration sensor 4, and a processing circuit (not shown). And a battery (not shown).
Here, the bone conduction microphone 1b is arranged in the left temple portion of the user, and the bone conduction speaker 2b is arranged in the right temple portion of the user. Note that this arrangement may be reversed depending on the use situation.

Here, as for speech translation, speech data is sent to the smartphone as shown in the block diagram, the speech is extracted by the application, and the speech is translated into text.

Since the voice input part is changed to a bone conduction microphone, there is no synthesis of external sound,
High recognition rate. Due to its characteristics, the conversion rate from speech to text is improved, laryngeal cancer by translating into other languages on the cloud server, voice support for personal search to signage, cloud devices, etc., and sampling with past recorded speech It will be a basic technology for welfare by cooperating with ICT, such as social participation by patients' natural conversation.

Also added by mashup with popular social apps such as Skype and line
Value creation is possible. For example, by pairing with a smartphone via bluetooth, you can communicate by calling without blocking your ears while cycling, and you can visualize your health status with vital data, etc. A health-oriented complementary tool for the next generation can be realized.
Also, by using it as a construction helmet, it is possible to detect life-critical events at an early stage, such as managing the physical condition of workers and detecting falls due to accidents.

Here, the bone conduction speaker is disposed on the left or right temple portion of the user, and the bone conduction microphone is disposed on the other temple portion. Further, the optical pulse meter and the triaxial acceleration sensor are in close contact with the temple of the user's head. Adhering to the temple has the effect of improving measurement accuracy.

(Example 2)
FIG. 3 is a block diagram of the processing circuit of this embodiment. As shown in FIG. 3, the Bluetooth module 7 in the data processing circuit 5 and the external smartphone 6 exchange data bi-directionally. A signal from a condenser microphone or a bone conduction vibrator (microphone side) and a pulsation sensor are input to the input side of the Bluetooth unit 7 in the data processing circuit. Further, a triaxial acceleration sensor may be added. The processing circuit 5 sends voice data to the smartphone 6, extracts voice by the application, and performs text translation of the voice.

Further, a bone conduction vibrator (speaker side) is connected to the output side of the blue-tose module 7.

Example 3
FIG. 3 is a diagram of a bidirectional bone conduction communication device according to an embodiment of the present invention. A user 31 uses the bicycle 40 as a moving means and wears the helmet 10. Similarly, the user 32 uses the bicycle 44 as a moving means and wears the helmet 10. Here, via the smartphone 6, bone conduction audio data, optical pulse meter data, and triaxial acceleration sensor data are connected via the Internet, and conversation or health data can be shared.

Example 4
In the example of FIG. 3, if a GPS receiver is additionally provided in the helmet, various information regarding the position where the user currently exists flows to the bone conduction speaker via the Internet. Effective for leisure, crime prevention or disaster response.

(Example 5)
FIG. 4 is a diagram of a bidirectional bone conduction communication device according to another embodiment of the present invention. FIG. 5 is a system diagram of a bidirectional bone conduction communication device according to another embodiment of the present invention. In this embodiment, bone conduction headphones are used in place of the previous helmet. FIG. 6 is a diagram of the bone conduction headphones of the present invention.
In the bone conduction headphones shown in FIG. 6, voice reception from the navigation terminal and voice transmission / reception (call) from the smartphone are performed using the built-in Bluetooth.
Since the voice by bone conduction is used in the call, even in a noisy environment, only the person's own voice can be clearly transmitted.
People with hearing impairments can hear the same sound as healthy people.
Moreover, the pulsation acquisition sensor is provided and pulsation data is transmitted to a smart phone. You can know the approximate health status of the user.

According to the bidirectional bone conduction communication device, the bidirectional bone conduction communication method, and the bidirectional bone conduction guide navigation system of the present invention, a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a three-axis acceleration sensor are arranged. The helmet is attached to the user's head and can perform two-way bone conduction communication. Further, the user's pulse data and posture data are measured in real time, and the measurement data is real time. Bi-directional bone conduction communication device and bi-directional bone conduction, which are stored in an information server via the Internet, allow an administrator to monitor the data of the information server, and can be used for sightseeing, leisure, disaster, etc. A communication method can be provided, contributing to industrial development and disaster countermeasures. In addition, by using a helmet as a construction helmet, it is possible to detect life-threatening events at an early stage, such as managing the physical condition of workers and detecting falls due to accidental accidents.

Claims (12)

1. A helmet in which a bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a three-axis acceleration sensor are arranged;
   A processing circuit for processing data from the bone conduction speaker, bone conduction microphone, optical pulse meter, and acceleration sensor;
   And a bidirectional bone conduction communication device configured with the processing circuit and bidirectional transmission / reception means for connecting to the Internet,
   The helmet is arranged on the user's head,
   The optical pulse meter detects a user's pulse,
   The acceleration sensor detects a user's posture,
   A bidirectional bone conduction communication apparatus, wherein the data of the processing circuit is connected to the Internet in real time by the bidirectional transmission / reception means.
2. 2. The bidirectional bone conduction communication device according to claim 1, wherein the bone conduction speaker is disposed in a left or right temple portion of the user, and the bone conduction microphone is disposed in the other temple portion. .
3. 3. The bidirectional bone conduction communication device according to claim 1, wherein the optical pulse meter and the triaxial acceleration sensor are in close contact with a temple of a user's head.
4. The processing circuit has a Bluetooth module, and each signal of the bone conduction speaker, bone conduction microphone, optical pulse meter, and triaxial acceleration sensor is transmitted via the modulation circuit in the processing circuit. Input to the Bluetooth module and the output signal from the Bluetooth module is input to the bone conduction speaker;
   The Bluetooth module performs data exchange with the bidirectional communication means,
   The bidirectional bone conduction communication device according to any one of claims 1 to 3, wherein the bidirectional communication means is a smartphone.
5. The bidirectional bone conduction communication device according to any one of claims 1 to 4, wherein the helmet is a construction helmet or a bicycle helmet.
   
6. A bone conduction speaker, a bone conduction microphone, an optical pulse meter, and a 3-axis acceleration sensor are placed on the user's helmet,
   A processing circuit for processing data from the bone conduction speaker, bone conduction microphone, optical pulse meter, and triaxial acceleration sensor;
   And arranging the processing circuit and bidirectional transmission / reception means connected to the Internet,
   A bidirectional bone conduction communication method for performing bidirectional communication,
   The optical pulse meter detects a user's pulse,
   The three-axis acceleration sensor detects a user's posture,
   A bidirectional bone conduction communication method characterized in that the data of the processing circuit is connected to the Internet in real time by the bidirectional transmission / reception means.
7. The bidirectional bone conduction communication method according to claim 6, wherein the bone conduction speaker is disposed on a left or right temple portion of the user, and the bone conduction microphone is disposed on the other temple portion.
8. 8. The bidirectional bone conduction communication method according to claim 6, wherein the optical pulse meter and the triaxial acceleration sensor are in close contact with the temple of the user's head.
9. The processing circuit has a Bluetooth module, and each signal of the bone conduction speaker, bone conduction microphone, optical pulse meter, and triaxial acceleration sensor is transmitted via the modulation circuit in the processing circuit. Input to the Bluetooth module and the output signal from the Bluetooth module is input to the bone conduction speaker;
   The Bluetooth module performs data exchange with the bidirectional communication means,
   The bidirectional bone conduction communication method according to any one of claims 6 to 9, wherein the bidirectional communication means is a smartphone.
10. The bidirectional bone conduction communication method according to any one of claims 6 to 8, wherein the helmet is a construction helmet or a bicycle helmet.
    
11. A mobile body equipped with a GPS receiver, a fixed information server, a bidirectional communication means for transferring data between the mobile body and the fixed information server, a bone conduction speaker, a bone conduction microphone, And a helmet in which an optical pulse meter and a three-axis acceleration sensor are arranged,
    A processing circuit for processing data from the bone conduction speaker, bone conduction microphone, optical pulse meter, and acceleration sensor;
    In the bidirectional bone conduction guide navigation system, characterized in that it is constituted by data of the processing circuit and bidirectional transmission / reception means connected to the Internet,
    The helmet is arranged on the user's head,
    The optical pulse meter detects a user's pulse,
    The acceleration sensor detects a user's posture,
    The interactive bone conduction guide navigation system, wherein the data of the processing circuit is connected to the Internet in real time by the interactive transmission / reception means.
12. 12. The bidirectional bone conduction guide navigation system according to claim 11, wherein the moving body is any one of a bicycle, a car, a wheelchair, and a user himself / herself.

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