CN205037917U - Wearable device of many sensings - Google Patents
Wearable device of many sensings Download PDFInfo
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- CN205037917U CN205037917U CN201520605641.XU CN201520605641U CN205037917U CN 205037917 U CN205037917 U CN 205037917U CN 201520605641 U CN201520605641 U CN 201520605641U CN 205037917 U CN205037917 U CN 205037917U
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Abstract
The utility model belongs to wearable equipment field discloses a wearable device of many sensings, including control module, air quality detection module, acceleration speed detection module, sound detection module and bluetooth module, air quality detection module generates air quality voltage according to the air quality, acceleration speed detection module generates acceleration voltage according to the acceleration, the sound detection module generates sound voltage according to the size of sound, control module acquires current environmental information according to air quality voltage, acceleration voltage and sound voltage to bluetooth module sends current environmental information to bluetooth module, so that sending current environmental information to mobile terminal, current environmental information includes air quality, acceleration and acoustic intensity. The utility model discloses a wearable device of many sensings has realized detecting sound, acceleration and the air quality many aspects of environment.
Description
Technical field
The utility model relates to Wearable device field, particularly one many sensings wearable device.
Background technology
The arriving in wearable intelligent equipment epoch means that the intellectuality of people extends, by these equipment, people can the better outside information with self of perception, can computing machine, network even other people auxiliary under more high efficiency process information, more seamless interchange can be realized.
In the outdoor field of sport and body-building, prior art with light-weighted wrist-watch, bracelet, accessories for principal mode, achieve motion or outdoor data as the indexs such as heart rate, cadence, air pressure, diving depth, height above sea level monitoring, analyze and serve.
There is following defect in prior art: does not detect the many aspects (as sound, acceleration and air quality) of environment.
Utility model content
The utility model provides a kind of many sensings wearable device, is intended to solve existing many sensings wearable device not to the technical matters that the sound of environment, acceleration and air quality many aspects detect.
The utility model is achieved in that a kind of many sensings wearable device, and described many sensings wearable device comprises control module, Detection of Air Quality module, acceleration velocity measuring module, sound detection module and bluetooth module;
The output terminal of described Detection of Air Quality module is connected with the second input end of described control module, and the second input end of described Detection of Air Quality module is connected with the first output terminal of described control module; The acceleration information output port of described acceleration velocity measuring module is connected to the 8th input end with the 3rd input end of described control module, and the output terminal of described sound detection module is connected with the 9th input end of described control module;
Described Detection of Air Quality module generates air quality voltage according to air quality; Described acceleration velocity measuring module generates acceleration voltage according to acceleration; Described sound detection module generates sound voltage according to the size of sound; Described control module obtains current context information according to described air quality voltage, described acceleration voltage and described sound voltage, and described current context information is sent to described bluetooth module, to make described bluetooth module, described current context information is sent to mobile terminal; Described current context information comprises air quality, acceleration and intensity of sound.
The beneficial effect that the technical scheme that the utility model provides is brought is:
From above-mentioned the utility model, owing to comprising control module, Detection of Air Quality module, acceleration velocity measuring module, sound detection module and bluetooth module; Detection of Air Quality module generates air quality voltage according to air quality; Acceleration velocity measuring module generates acceleration voltage according to acceleration; Sound detection module generates sound voltage according to the size of sound; Control module obtains current context information according to air quality voltage, acceleration voltage and sound voltage, and current context information is sent to bluetooth module, to make bluetooth module, current context information is sent to mobile terminal; Current context information comprises air quality, acceleration and intensity of sound; Therefore, achieve the sound to environment, acceleration and air quality many aspects to detect.
Accompanying drawing explanation
In order to be illustrated more clearly in the technical scheme in the utility model embodiment, below the accompanying drawing used required in describing embodiment is briefly described, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.
A kind of function structure chart of many sensings wearable device that Fig. 1 provides for the utility model embodiment;
The another kind of function structure chart of many sensings wearable device that Fig. 2 provides for the utility model embodiment;
The exemplary circuit structural drawing of many sensings wearable device that Fig. 3 provides for the utility model embodiment.
Embodiment
For making the purpose of this utility model, technical scheme and advantage clearly, below in conjunction with accompanying drawing, the utility model embodiment is described in further detail.
The utility model embodiment provides a kind of structure of many sensings wearable device, and as shown in Figure 1, it comprises control module 01, Detection of Air Quality module 02, acceleration velocity measuring module 03, sound detection module 04 and bluetooth module 05.
The output terminal of Detection of Air Quality module 02 is connected with the second input end of control module 01, and the second input end of Detection of Air Quality module 02 is connected with the first output terminal of control module 01; The acceleration information output port of acceleration velocity measuring module 03 is connected to the 8th input end with the 3rd input end of control module 01, and the output terminal of sound detection module 04 is connected with the 9th input end of control module 01.
Detection of Air Quality module 02 generates air quality voltage according to air quality; Acceleration velocity measuring module 03 generates acceleration voltage according to acceleration; Sound detection module 04 generates sound voltage according to the size of sound; Control module 01 obtains current context information according to air quality voltage, acceleration voltage and sound voltage, and current context information is sent to bluetooth module 05, to make bluetooth module 05, current context information is sent to mobile terminal; Current context information comprises air quality, acceleration and intensity of sound.
In concrete enforcement, as shown in Figure 2, many sensings wearable device also comprises UV detection module 06, height above sea level air pressure detection module 07, light-intensity test module 08 and Temperature and Humidity module 09.
The output terminal of UV detection module 06 is connected with the first input end of control module 01, first output terminal of height above sea level air pressure detection module 07 is connected with the 3rd input end of the first output terminal of light-intensity test module 08 and control module 01, second output terminal of height above sea level air pressure detection module 07 is connected with the four-input terminal of the second output terminal of light-intensity test module 08 and control module 01, and the output terminal of Temperature and Humidity module 09 is connected with the tenth input end of control module 01.
UV detection module 06 generates uitraviolet intensity voltage according to uitraviolet intensity; Height above sea level air pressure detection module 07 generates air pressure voltage according to air pressure; Light-intensity test module 08 generates light intensity voltage according to light intensity; Temperature and Humidity module 09 generates humiture voltage according to humiture; Control module 01 also obtains current context information according to uitraviolet intensity voltage, air pressure voltage, light intensity voltage and humiture voltage, and current context information is sent to bluetooth module 05, to make bluetooth module 05, current context information is sent to mobile terminal; Current context information also comprises uitraviolet intensity, height above sea level, light intensity and humiture.
As shown in Figure 3, control module 01 is microprocessor U1.
The first universal input output terminal PB0 of microprocessor U1 is the first input end of control module 01, the second universal input output terminal PB2 of microprocessor U1 is the second input end of control module 01, the 3rd general input/output terminal PC1 of microprocessor U1 is the first output terminal of control module 01, the 4th general input/output terminal PD3 of microprocessor U1 is the 3rd input end of control module 01, the five-way input/output terminal PD2 of microprocessor U1 is the four-input terminal of control module 01, the 6th universal input output terminal PD4 of microprocessor U1 is the 5th input end of control module 01, the 7th universal input output terminal PD7 of microprocessor U1 is the 6th input end of control module 01, the 8th universal input output terminal PB4 of microprocessor U1 is the 7th input end of control module 01, the 9th universal input output terminal PB5 of microprocessor U1 is the 8th input end of control module 01, the tenth universal input output terminal PB1 of microprocessor U1 is the 9th input end of control module 01, the 11 universal input output terminal PE3 of microprocessor U1 is the tenth input end of control module 01, the I2C bus interface of microprocessor U1 is the second output terminal of control module 01.
In concrete enforcement, the model of microprocessor U1 can be ATmega48/V.
As shown in Figure 3, UV detection module 06 comprises operational amplifier U2, UV sensor D1, the first electric capacity C1, the second electric capacity C2, the 3rd electric capacity C3, the first resistance R1, the second resistance R2, the 3rd resistance R3, the 4th resistance R4 and the 5th resistance R5.
Normal phase input end+the In of operational amplifier U2 is connected with the first end of the first resistance R1, negative-phase input-the In of operational amplifier U2 and the first end of the 3rd resistance R3, the first end of the 4th resistance R4 and the first end of the 3rd electric capacity C3 connect, the cathode power supply end V+ of operational amplifier U2 and the first end of the second electric capacity C2 are the input end of UV detection module 06, the output terminal Out of operational amplifier U2 and second end of the 4th resistance R4, second end of the 3rd electric capacity C3 and the first end of the 5th resistance R5 connect, second end of the 5th resistance R5 is the output terminal of UV detection module 06, second end of the first resistance R1 and the positive pole of UV sensor D1, the first end of the second resistance R2 and the first end of the first electric capacity C1 connect, the negative pole of UV sensor D1, second end of the second resistance R2, second end of the first electric capacity C1, the negative electricity source V-of operational amplifier U2, second end of the second electric capacity C2 and second end of the 3rd resistance R3 are connected to power supply ground altogether.
As shown in Figure 3, height above sea level air pressure detection module 07 comprises baroceptor U4, the 5th electric capacity C5, the 6th electric capacity C6, the 7th resistance R7 and the 8th resistance R8.
The power end VDD of baroceptor U4, the input and output power end VDDIO of baroceptor U4, the first end of the 5th electric capacity C5, the first end of the 6th electric capacity C6, the first end of the 7th resistance R7 and the first end of the 8th resistance R8 are the input end of height above sea level air pressure detection module, the I2C serial data end SDA of baroceptor U4 is the first output terminal of height above sea level air pressure detection module, the I2C serial clock terminal SCL of baroceptor U4 is the second output terminal of height above sea level air pressure detection module, the earth terminal of baroceptor U4, second end of the 5th electric capacity C5 and second end of the 6th electric capacity C6 are connected to power supply ground altogether.
As shown in Figure 3, light-intensity test module 08 comprises light intensity sensor U5, the 7th electric capacity C7, the 8th electric capacity C8 and the 9th resistance R9.
The power end VDD of light intensity sensor U5, the first end of the 7th electric capacity C7 and the first end of the 9th resistance R9 are the input end of light-intensity test module 08, the reference voltage end DVI of light intensity sensor U5 is connected with the first end of second end of the 9th resistance R9 and the 8th electric capacity C8, the I2C serial data end SDA of light intensity sensor U5 is the first output terminal of light-intensity test module 08, the I2C serial clock terminal SCL of light intensity sensor U5 is the second output terminal of light-intensity test module 08, the slave address end ADDR of light intensity sensor U5, the earth terminal GND of light intensity sensor U5, second end of the 7th electric capacity C7 and second end of the 8th electric capacity C8 are connected to power supply ground altogether.
As shown in Figure 3, Temperature and Humidity module 09 comprises Temperature Humidity Sensor U7 and the 11 resistance R11.
The power end VDD of Temperature Humidity Sensor U7 and the first end of the 11 resistance R11 are the input end of Temperature and Humidity module 09, the serial data end DATA of Temperature Humidity Sensor U7 is the output terminal of Temperature and Humidity module 09, and the earth terminal GND of Temperature Humidity Sensor U7 is connected to power supply ground.
As shown in Figure 3, Detection of Air Quality module 02 comprises dust sensor U3, the 4th electric capacity C4 and the 6th resistance R6.
The LED power source end V_LED of dust sensor U3, the first end of the 4th electric capacity C4 and the first end of the 6th resistance R6 are the first input end of Detection of Air Quality module 02, the light emitting diode earth terminal LED_GND of dust sensor U3, second end of the 4th electric capacity C4 and the earth terminal S_GND of dust sensor U3 are connected to power supply ground altogether, the power end VCC of dust sensor U3 is connected with second end of the 6th resistance R6, the output end vo of dust sensor U3 is the output terminal of Detection of Air Quality module, the light emitting diode control end LED of dust sensor U3 is the second input end of Detection of Air Quality module.
As shown in Figure 3, acceleration velocity measuring module 03 comprises motion sensor U6, the 9th electric capacity C9, the tenth electric capacity C10, the 11 electric capacity C11 and the tenth resistance R10.
The calibration filter capacitor end REGOUT of motion sensor U6 is connected with the first end of the 9th electric capacity C9, the SPI sheet choosing end of motion sensor U6
the power end of motion sensor U6, the first end of the tenth electric capacity C10 and the first end of the 11 electric capacity C11 are the input end of acceleration velocity measuring module 03, the I2C serial data end SDA of motion sensor U6 is the first output terminal of acceleration velocity measuring module 03, the I2C serial clock terminal SCL of motion sensor U6 is the second output terminal of acceleration velocity measuring module 03, the I2C main serial data end AUX_DA of motion sensor U6 is the 3rd output terminal of acceleration velocity measuring module 03, the main serial clock terminal AUX_CL of I2C of motion sensor U6 is the 4th output terminal of acceleration velocity measuring module 03, the I2C of motion sensor U6 is the 5th output terminal of acceleration velocity measuring module 03 from the first end of address end AD0/SD0 and the tenth resistance R10, the interruption digital output end INT of motion sensor U6 is the 6th output terminal of acceleration velocity measuring module 03, the external clock input end CLKIN of motion sensor U6, second end of the 9th electric capacity C9, second end of the tenth electric capacity C10, second end of the 11 electric capacity C11 and second end of the tenth resistance R10 are connected to power supply ground altogether.
First output terminal to the 6th output terminal of acceleration velocity measuring module 03 forms the acceleration information output port of acceleration velocity measuring module 03.
As shown in Figure 3, sound detection module 04 comprises Mike MIC, audio-frequency power amplifier U8, the 12 electric capacity C12, the 13 electric capacity C13, the 14 electric capacity C14, the 15 electric capacity C15, the 16 electric capacity C16, the 17 electric capacity C17, the 18 electric capacity C18, the 19 electric capacity C19, the 20 electric capacity C20, the 12 resistance R12 and the 13 resistance R13.
The output terminal OUT of audio-frequency power amplifier U8 is connected with the first end of the 12 electric capacity C12 and the first end of the 13 electric capacity C13, the first gain end Gain of audio-frequency power amplifier U8 is connected with the first end of the 14 electric capacity C14, the second gain end Gain of audio-frequency power amplifier U8 is connected with second end of the 14 electric capacity C14, the electrode input end IN+ of audio-frequency power amplifier U8 is connected with the first end of the 16 electric capacity C16, the shunt capacitance end Bypass of audio-frequency power amplifier U8 is connected with the first end of the 15 electric capacity C15, the first end of the power supply ground VCC and the 19 electric capacity C19 of audio-frequency power amplifier U8, the first end of the 20 electric capacity C20 and the first end of the 17 electric capacity C17 connect, second end of the 12 electric capacity C12 is connected with the first end of the 12 resistance R12, second end of the 12 resistance R12 is the output terminal of sound detection module 04, second end of the 13 electric capacity C13 is connected with the first end of the 13 resistance R13, second end of positive terminal the 1 and the 16 electric capacity C16 of Mike MIC, second end of the 17 electric capacity C17 and the first end of the 18 electric capacity C18 connect, the negative pole end 2 of Mike MIC, second end of the 18 electric capacity C18, second end of the 15 electric capacity C15, the negative input IN-of audio-frequency power amplifier U8, second end of the 19 electric capacity C19, second end of the 20 electric capacity C20 and second end of the 13 resistance R13 are connected to power supply ground altogether.
In concrete enforcement, Detection of Air Quality module 02 generates air quality voltage according to air quality, and is sent to the second universal input output terminal PB2 of microprocessor U1 by the output end vo of dust sensor U3; Acceleration velocity measuring module 03 generates acceleration voltage according to acceleration, and is sent to the 4th general input/output terminal PB2 of microprocessor U1 to the 9th universal input output terminal PB5 by acceleration information output port; Sound detection module 04 generates sound voltage according to the size of sound, and is sent to the tenth universal input output terminal PB1 of microprocessor U1 by the 12 resistance R12; UV detection module 06 generates uitraviolet intensity voltage according to uitraviolet intensity, and is sent to the first universal input output terminal PB0 of microprocessor U1 by the 5th resistance R5; Height above sea level air pressure detection module 07 generates air pressure voltage according to air pressure, and is sent to the 4th general input/output terminal PD3 and five-way input/output terminal PD2 of microprocessor U1 respectively by the I2C serial data end SDA of baroceptor U4 and I2C serial clock terminal SCL; Light-intensity test module 08 generates light intensity voltage according to light intensity, and is sent to the 4th general input/output terminal PD3 and five-way input/output terminal PD2 of microprocessor U1 by the I2C serial data end SDA of light intensity sensor U5 and I2C serial clock terminal SCL; Temperature and Humidity module 09 generates humiture voltage according to humiture, and is sent to the 11 universal input output terminal PE3 of microprocessor U1 by the serial data end DATA of Temperature Humidity Sensor U7; Control module 01 obtains current context information according to air quality voltage, acceleration voltage and sound voltage, and current context information is sent to bluetooth module 05, to make bluetooth module 05, current context information is sent to mobile terminal; Current context information comprises air quality, acceleration, intensity of sound, uitraviolet intensity, height above sea level, light intensity and humiture.
In sum, the utility model embodiment is by comprising control module, Detection of Air Quality module, acceleration velocity measuring module, sound detection module and bluetooth module; Detection of Air Quality module generates air quality voltage according to air quality; Acceleration velocity measuring module generates acceleration voltage according to acceleration; Sound detection module generates sound voltage according to the size of sound; Control module obtains current context information according to air quality voltage, acceleration voltage and sound voltage, and current context information is sent to bluetooth module, to make bluetooth module, current context information is sent to mobile terminal; Current context information comprises air quality, acceleration and intensity of sound; Therefore, achieve the sound to environment, acceleration and air quality many aspects to detect.
Above-mentioned the utility model embodiment sequence number, just to describing, does not represent the quality of embodiment.
One of ordinary skill in the art will appreciate that all or part of step realizing above-described embodiment can have been come by hardware, the hardware that also can carry out instruction relevant by program completes, described program can be stored in a kind of computer-readable recording medium, the above-mentioned storage medium mentioned can be ROM (read-only memory), disk or CD etc.
The foregoing is only preferred embodiment of the present utility model, not in order to limit the utility model, all within spirit of the present utility model and principle, any amendment done, equivalent replacement, improvement etc., all should be included within protection domain of the present utility model.
Claims (10)
1. the wearable device of sensing more than, is characterized in that, described many sensings wearable device comprises control module, Detection of Air Quality module, acceleration velocity measuring module, sound detection module and bluetooth module;
The output terminal of described Detection of Air Quality module is connected with the second input end of described control module, and the second input end of described Detection of Air Quality module is connected with the first output terminal of described control module; The acceleration information output port of described acceleration velocity measuring module is connected to the 8th input end with the 3rd input end of described control module, and the output terminal of described sound detection module is connected with the 9th input end of described control module;
Described Detection of Air Quality module generates air quality voltage according to air quality; Described acceleration velocity measuring module generates acceleration voltage according to acceleration; Described sound detection module generates sound voltage according to the size of sound; Described control module obtains current context information according to described air quality voltage, described acceleration voltage and described sound voltage, and described current context information is sent to described bluetooth module, to make described bluetooth module, described current context information is sent to mobile terminal; Described current context information comprises air quality, acceleration and intensity of sound.
2. many sensings wearable device as claimed in claim 1, is characterized in that, described many sensings wearable device also comprises UV detection module, height above sea level air pressure detection module, light-intensity test module and Temperature and Humidity module;
The output terminal of described UV detection module is connected with the first input end of described control module, first output terminal of described height above sea level air pressure detection module is connected with the 3rd input end of the first output terminal of described light-intensity test module and described control module, second output terminal of described height above sea level air pressure detection module is connected with the second output terminal of described light-intensity test module and the four-input terminal of described control module, and the output terminal of described Temperature and Humidity module is connected with the tenth input end of described control module;
Described UV detection module generates uitraviolet intensity voltage according to uitraviolet intensity; Described height above sea level air pressure detection module generates air pressure voltage according to air pressure; Described light-intensity test module generates light intensity voltage according to light intensity; Described Temperature and Humidity module generates humiture voltage according to humiture; Described control module also obtains described current context information according to described uitraviolet intensity voltage, described air pressure voltage, described light intensity voltage and described humiture voltage, and described current context information is sent to described bluetooth module, to make described bluetooth module, described current context information is sent to mobile terminal; Described current context information also comprises uitraviolet intensity, height above sea level, light intensity and humiture.
3. many sensings wearable device as claimed in claim 2, is characterized in that, described control module is microprocessor;
First universal input output terminal of described microprocessor is the first input end of described control module, second universal input output terminal of described microprocessor is the second input end of described control module, 3rd general input/output terminal of described microprocessor is the first output terminal of described control module, 4th general input/output terminal of described microprocessor is the 3rd input end of described control module, the five-way input/output terminal of described microprocessor is the four-input terminal of described control module, 6th universal input output terminal of described microprocessor is the 5th input end of described control module, 7th universal input output terminal of described microprocessor is the 6th input end of described control module, 8th universal input output terminal of described microprocessor is the 7th input end of described control module, 9th universal input output terminal of described microprocessor is the 8th input end of described control module, tenth universal input output terminal of described microprocessor is the 9th input end of described control module, 11 universal input output terminal of described microprocessor is the tenth input end of described control module, the I2C bus interface of described microprocessor is the second output terminal of described control module.
4. many sensings wearable device as claimed in claim 2, it is characterized in that, described UV detection module comprises operational amplifier, UV sensor, the first electric capacity, the second electric capacity, the 3rd electric capacity, the first resistance, the second resistance, the 3rd resistance, the 4th resistance and the 5th resistance;
The normal phase input end of described operational amplifier is connected with the first end of described first resistance, the negative-phase input of described operational amplifier and the first end of described 3rd resistance, the first end of described 4th resistance and the first end of described 3rd electric capacity connect, the cathode power supply end of described operational amplifier and the first end of described second electric capacity are the input end of described UV detection module, the output terminal of described operational amplifier and the second end of described 4th resistance, second end of described 3rd electric capacity and the first end of described 5th resistance connect, second end of described 5th resistance is the output terminal of described UV detection module, second end of described first resistance and the positive pole of described UV sensor, the first end of described second resistance and the first end of described first electric capacity connect, the negative pole of described UV sensor, second end of described second resistance, second end of described first electric capacity, the negative electricity source of described operational amplifier, second end of described second electric capacity and the second end of described 3rd resistance are connected to power supply ground altogether.
5. many sensings wearable device as claimed in claim 2, is characterized in that, described height above sea level air pressure detection module comprises baroceptor, the 5th electric capacity, the 6th electric capacity, the 7th resistance and the 8th resistance;
The power end of described baroceptor, the input and output power end of described baroceptor, the first end of described 5th electric capacity, the first end of described 6th electric capacity, the first end of described 7th resistance and the first end of described 8th resistance are the input end of described height above sea level air pressure detection module, the I2C serial data end of described baroceptor is the first output terminal of described height above sea level air pressure detection module, the I2C serial clock terminal of described baroceptor is the second output terminal of described height above sea level air pressure detection module, the earth terminal of described baroceptor, second end of described 5th electric capacity and the second end of described 6th electric capacity are connected to power supply ground altogether.
6. many sensings wearable device as claimed in claim 2, is characterized in that, described light-intensity test module comprises light intensity sensor, the 7th electric capacity, the 8th electric capacity and the 9th resistance;
The power end of described light intensity sensor, the first end of described 7th electric capacity and the first end of described 9th resistance are the input end of described light-intensity test module, the reference voltage end of described light intensity sensor is connected with the first end of the second end of described 9th resistance and described 8th electric capacity, the I2C serial data end of described light intensity sensor is the first output terminal of described light-intensity test module, the I2C serial clock terminal of described light intensity sensor is the second output terminal of described light-intensity test module, the slave address end of described light intensity sensor, the earth terminal of described light intensity sensor, second end of described 7th electric capacity and the second end of described 8th electric capacity are connected to power supply ground altogether.
7. many sensings wearable device as claimed in claim 2, is characterized in that, described Temperature and Humidity module comprises Temperature Humidity Sensor and the 11 resistance;
The power end of described Temperature Humidity Sensor and the first end of described 11 resistance are the input end of described Temperature and Humidity module, the serial data end of described Temperature Humidity Sensor is the output terminal of described Temperature and Humidity module, and the earth terminal of described Temperature Humidity Sensor is connected to power supply ground.
8. many sensings wearable device as claimed in claim 1, is characterized in that, described Detection of Air Quality module comprises dust sensor, the 4th electric capacity and the 6th resistance;
The LED power source end of described dust sensor, the first end of described 4th electric capacity and the first end of described 6th resistance are the first input end of described Detection of Air Quality module, the light emitting diode earth terminal of described dust sensor, described second end of the 4th electric capacity and the earth terminal of described dust sensor are connected to power supply ground altogether, the power end of described dust sensor is connected with the second end of described 6th resistance, the output terminal of described dust sensor is the output terminal of described Detection of Air Quality module, the light emitting diode control end of described dust sensor is the second input end of described Detection of Air Quality module.
9. many sensings wearable device as claimed in claim 1, is characterized in that, described acceleration velocity measuring module comprises motion sensor, the 9th electric capacity, the tenth electric capacity, the 11 electric capacity and the tenth resistance;
The calibration filter capacitor end of described motion sensor is connected with the first end of described 9th electric capacity, the SPI sheet choosing end of described motion sensor
the power end of described motion sensor, the first end of described tenth electric capacity and the first end of described 11 electric capacity are the input end of described acceleration velocity measuring module, the I2C serial data end of described motion sensor is the first output terminal of described acceleration velocity measuring module, the I2C serial clock terminal of described motion sensor is the second output terminal of described acceleration velocity measuring module, the I2C main serial data end of described motion sensor is the 3rd output terminal of described acceleration velocity measuring module, the main serial clock terminal of I2C of described motion sensor is the 4th output terminal of described acceleration velocity measuring module, the I2C of described motion sensor is the 5th output terminal of described acceleration velocity measuring module from the first end of address end and described tenth resistance, the interruption digital output end of described motion sensor is the 6th output terminal of described acceleration velocity measuring module, the external clock input end of described motion sensor, second end of described 9th electric capacity, second end of described tenth electric capacity, second end of described 11 electric capacity and the second end of described tenth resistance are connected to power supply ground altogether,
First output terminal to the 6th output terminal of described acceleration velocity measuring module forms the acceleration information output port of described acceleration velocity measuring module.
10. many sensings wearable device as claimed in claim 1, it is characterized in that, described sound detection module comprises Mike, audio-frequency power amplifier, the 12 electric capacity, the 13 electric capacity, the 14 electric capacity, the 15 electric capacity, the 16 electric capacity, the 17 electric capacity, the 18 electric capacity, the 19 electric capacity, the 20 electric capacity, the 12 resistance and the 13 resistance;
The output terminal of described audio-frequency power amplifier is connected with the first end of described 12 electric capacity and the first end of described 13 electric capacity, first gain end of described audio-frequency power amplifier is connected with the first end of described 14 electric capacity, second gain end of described audio-frequency power amplifier is connected with the second end of described 14 electric capacity, the electrode input end of described audio-frequency power amplifier is connected with the first end of described 16 electric capacity, the shunt capacitance end of described audio-frequency power amplifier is connected with the first end of described 15 electric capacity, the power supply ground of described audio-frequency power amplifier and the first end of described 19 electric capacity, the first end of described 20 electric capacity and the first end of described 17 electric capacity connect, second end of described 12 electric capacity is connected with the first end of described 12 resistance, second end of described 12 resistance is the output terminal of described sound detection module, second end of described 13 electric capacity is connected with the first end of described 13 resistance, the positive terminal of described Mike and the second end of described 16 electric capacity, second end of described 17 electric capacity and the first end of described 18 electric capacity connect, the negative pole end of described Mike, second end of described 18 electric capacity, second end of described 15 electric capacity, the negative input of described audio-frequency power amplifier, second end of described 19 electric capacity, second end of described 20 electric capacity and the second end of described 13 resistance are connected to power supply ground altogether.
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CN110940708A (en) * | 2019-12-16 | 2020-03-31 | 中国科学院半导体研究所 | Humidity sensor, preparation method thereof, wearable humidity sensing system and application |
CN112137607A (en) * | 2019-06-26 | 2020-12-29 | 深圳市冠旭电子股份有限公司 | Heart rate detection device and heart rate detection earphone |
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CN106767818A (en) * | 2016-12-05 | 2017-05-31 | 北京仿真中心 | Wearable electronic and its healthy travel system |
CN112137607A (en) * | 2019-06-26 | 2020-12-29 | 深圳市冠旭电子股份有限公司 | Heart rate detection device and heart rate detection earphone |
CN110940708A (en) * | 2019-12-16 | 2020-03-31 | 中国科学院半导体研究所 | Humidity sensor, preparation method thereof, wearable humidity sensing system and application |
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Address after: Longgang District of Shenzhen City, Guangdong province 518116 Ping Street Takahashi Industrial Park East Area Patentee after: SHENZHE GUANXU ELECTRONIC CO., LTD. Address before: Longgang District of Shenzhen City, Guangdong province 518116 Ping Street Takahashi Industrial Park East Area Patentee before: Shenzhen Grandsun Electronic Co., Ltd. |