JP3923005B2 - Electrostatic sensor and portable electronic device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrostatic sensor that realizes an acoustic detection function and a swing detection function, and a portable electronic device including the electrostatic sensor.
[0002]
[Prior art]
An electret condenser microphone, which is an electrostatic acoustic sensor, is generally used for portable electronic devices such as a mobile phone having only an acoustic detection function. The electret condenser microphone has a capacitance between the vibrating membrane and the fixed electrode when the vibrating membrane on which the electret member is formed and the fixed electrode are arranged at regular intervals and the vibrating membrane vibrates due to sound pressure. The change is detected and the vibration of the diaphragm is measured. Therefore, a membrane that vibrates sensitively to the applied sound pressure is used as the vibrating membrane.
[0003]
In addition, an electrostatic vibration sensor that detects a swing that occurs when a person swings an object using the same principle as the above-described electret condenser microphone has also been proposed (see, for example, Patent Document 1). . The vibration sensor has the same configuration as the above-described electret condenser microphone that detects sound, the movable electrode on which the electret member is formed and the fixed electrode are arranged at regular intervals, and a weight is attached to the movable electrode, Furthermore, an impact applying means for the weight is provided. When there is vibration, the vibration of the impact applying means is applied to the weight, and as a result, the vibration of the movable electrode is detected. The effect of being able to do is achieved.
[0004]
In addition, a portable electronic device having a vibration detection function uses a vibration detector having a pedometer function that detects movement of a human body, in particular, a swing that occurs when a human walks (for example, (See Patent Document 2). Although the vibration detector described in Patent Document 2 is used as a pedometer, the vibration detection mechanism detects that a component that moves in response to vibration caused by walking collides with another component. A pendulum mechanism is used.
[0005]
A portable electronic device having an acoustic detection function (voice recorder) and a vibration detection function (pedometer) has also been proposed (see, for example, Patent Document 3). In the portable electronic device described in Patent Document 3, voice is detected by a microphone, and the number of steps is detected by a pedometer mechanism that employs a pendulum mechanism.
[0006]
[Patent Document 1]
Japanese Patent Laid-Open No. 10-9944 (FIG. 1)
[0007]
[Patent Document 2]
JP 2001-257746 A (FIG. 2)
[0008]
[Patent Document 3]
JP 2000-24969 A (FIGS. 1 and 2)
[0009]
[Problems to be solved by the invention]
As described above, when a portable electronic device having an acoustic detection function and a swing detection function is configured, a component that realizes the acoustic detection function and a component that realizes the swing detection function must be mounted, It will be difficult to achieve the objectives of reducing the size, thickness and weight of the equipment. Furthermore, since the operation principle of the sound detection function and the operation principle of the rocking detection function are different from each other, a separate signal processing circuit is required for signal processing of the sound signal and the rocking signal output from each. There is also.
[0010]
The vibrating membrane (movable electrode) used in the conventional electrostatic sensor described above either vibrates in response to an acoustic frequency or vibrates in response to a frequency lower than the acoustic frequency. And cannot vibrate in response to both frequencies. As a result, the acoustic detection function and the swing detection function cannot be exhibited together using one electrostatic sensor, and the apparatus is reduced in size, thickness, and weight while having a plurality of functions. It was not possible to achieve the purpose.
[0011]
The present invention has been made in view of the above problems, and an object of the present invention is to provide an electrostatic sensor capable of detecting vibrations having different frequencies such as an acoustic signal and a swing signal, and a portable electronic device using the same. There is in point to do.
[0012]
[Means for Solving the Problems]
The characteristic configuration of the electrostatic sensor according to the present invention for solving the above-described problems includes a fixed electrode, a first vibrating electrode disposed to face one surface of the fixed electrode, and the other of the fixed electrode. A second vibrating electrode disposed opposite to the surface, on any electrode between the fixed electrode and the first vibrating electrode, and between the fixed electrode and the second vibrating electrode An electret member is formed on the electrode, and the vibration of the first vibrating electrode that responds to sound is detected by measuring a change in capacitance between the fixed electrode and the first vibrating electrode, This is in that the vibration of the second vibrating electrode that responds to the fluctuation of the frequency lower than the acoustic frequency is detected by measuring the change in capacitance between the fixed electrode and the second vibrating electrode.
[0013]
With the above characteristic configuration, when sound is applied to the electrostatic sensor, the first vibrating electrode vibrates in response to sound, but the second vibrating electrode does not respond to sound. It is possible to selectively detect sound by measuring a change in capacitance with one vibrating electrode. Further, when the electrostatic sensor is swung at a frequency lower than the acoustic frequency, the second vibrating electrode vibrates in response to the rocking, but the first vibrating electrode has a rocking frequency. Therefore, the oscillation can be selectively detected by measuring the change in capacitance between the fixed electrode and the second vibrating electrode. Here, it is possible to selectively detect sound and fluctuation with different frequency ranges by using the same detection mechanism called electrostatic type sensor, realizing multiple functions of acoustic detection function and fluctuation detection function. The number of parts for doing so can be minimized.
[0014]
Another characteristic configuration of the electrostatic sensor according to the present invention for solving the above-described problems includes a first vibrating electrode that vibrates in response to sound, and in response to rocking at a frequency lower than the frequency of the sound. A second vibrating electrode that vibrates, an electret member is formed on any electrode between the first vibrating electrode and the second vibrating electrode, and the vibration of the first vibrating electrode due to the sound is fixed A change in electrostatic capacitance between the second vibrating electrode as the electrode and the first vibrating electrode is measured and detected, and the vibration of the second vibrating electrode due to the swing is detected as the first as the fixed electrode. This is in that the change in electrostatic capacitance between the vibrating electrode and the second vibrating electrode is measured and detected.
[0015]
Due to the above characteristic configuration, when sound is applied to the electrostatic sensor, the first vibrating electrode vibrates in response to sound, but the second vibrating electrode does not respond to sound and is in a substantially fixed state. Therefore, it is possible to selectively detect sound by measuring a change in capacitance between the second vibrating electrode as the fixed electrode and the first vibrating electrode. Further, when the electrostatic sensor is swung at a frequency lower than the acoustic frequency, the second vibrating electrode vibrates in response to the rocking, but the first vibrating electrode has a rocking frequency. Therefore, the oscillation can be selectively detected by measuring the change in capacitance between the first vibrating electrode and the second vibrating electrode as fixed electrodes. . Here, it is possible to selectively detect sound and fluctuation with different frequency ranges by using the same detection mechanism called electrostatic type sensor, realizing multiple functions of acoustic detection function and fluctuation detection function. The number of parts for doing so can be minimized.
[0016]
The characteristic configuration of the electrostatic sensor according to the present invention for solving the above problem is that a weight for adjusting the natural frequency is attached to the second vibrating electrode.
[0017]
With the above characteristic configuration, it is possible to freely adjust the natural frequency of the second vibrating electrode in accordance with the oscillation frequency to be detected by the electrostatic sensor.
[0018]
The characteristic configuration of the portable electronic device according to the present invention for solving the above-described problems includes the electrostatic sensor according to any one of claims 1 to 3, and an acoustic detection function and a swing detection function. It is in having.
[0019]
With the above feature configuration, it is possible to reduce the size of a portable electronic device that uses a plurality of functions for realizing a plurality of functions, that is, an acoustic detection function and a swing detection function.・ The objectives of thinning and lightening can be achieved.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an electrostatic sensor according to the present invention will be described with reference to FIGS. Any of the electrostatic sensors has a function of detecting sound (several tens of Hz or more) and a function of detecting a swing (several Hz or less) such as a vertical movement during walking of a human being lower than the sound frequency. It is configured.
[0021]
<First Embodiment>
The electrostatic sensor 1 illustrated in FIG. 1A includes a fixed electrode 6, an acoustic vibrating membrane (first vibrating electrode) 9 disposed to face one surface of the fixed electrode 6, and the fixed electrode 6. And a vibrating membrane for oscillation (second vibrating electrode) 12 disposed to face the other surface of the first electrode. In addition, by forming the electret member on the surface of the acoustic vibration film 9 that faces the fixed electrode 6, the acoustic vibration film 9 acts as an electrode. Similarly, the electret member is formed on the surface of the oscillating vibration film 12 that faces the fixed electrode 6, so that the oscillating vibration film 12 functions as an electrode.
[0022]
In the electrostatic sensor 1, the acoustic vibration film 9 is mounted on the sound hole 4 side in the cylindrical housing 2 having the sound hole 4 via the acoustic vibration film ring 8, and the fixed electrode 6 is formed on the substrate. 3 is mounted in a state of being sandwiched between a fixed electrode holder 5 provided on 3 and an acoustic system spacer 10, and the oscillating diaphragm 12 is oscillated by a oscillating diaphragm ring 11 supported by the oscillating diaphragm holder 16. It is mounted in a state of being sandwiched between the oscillating system spacer 13. Further, a weight 14 for adjusting the natural frequency of the oscillating vibrating membrane 12 is mounted on the surface opposite to the surface facing the fixed electrode 6. The fixed electrode 6 and the substrate 3 are connected via a gate ring 7, and the oscillating vibrating membrane 12 and the substrate 3 are connected via an oscillating vibrating membrane ring 11 and a ground ring 15. The capacitance change between the acoustic vibrating membrane 9 and the fixed electrode 6 and the capacitance change between the oscillation vibrating membrane 12 and the fixed electrode 6 detected by the fixed electrode 6 are provided on the substrate 3. Is transmitted to the FET 17 and output. FIG. 1B shows a schematic circuit diagram of the acoustic vibration film 9, the fixed electrode 6, the swinging vibration film 12, and the FET 17 of the electrostatic sensor 1 illustrated in FIG. 1A.
[0023]
In this electrostatic sensor 1, a capacitor portion is constituted by the acoustic vibrating membrane 9 on which the electret member is formed and the fixed electrode 6, and in response to an acoustic signal that enters the housing 2 from the sound hole 4, The vibrating membrane 9 vibrates, and operates so as to output a change in electrostatic capacitance in the capacitor unit accompanying the vibration as a voltage signal from the output terminal illustrated in FIG. Similarly, in the electrostatic sensor 1, the capacitor portion is configured by the oscillation film 12 for swinging on which the electret member is formed and the fixed electrode 6, and occurs when the electrostatic sensor 1 is shaken. The oscillation membrane 12 for oscillation vibrates in response to the oscillation of a frequency lower than the acoustic frequency of FIG. 1, and the output illustrated in FIG. Operates to output from the terminal.
[0024]
When the electrostatic sensor 1 is incorporated in an electronic device, the two functions of detecting the sound around the electronic device and detecting the swing of the electronic device are combined into one function, the electrostatic sensor 1. There is an advantage that the signal processing circuit can be made common because the detected acoustic signal and the swing signal are the same kind of signals output from the same electrostatic sensor 1, which can be achieved by the parts. As a result, even if a plurality of functions are provided, it is possible to satisfy the demand for electronic devices that are reduced in size, thickness, and weight.
[0025]
Second Embodiment
An electrostatic sensor 30 illustrated in FIG. 2A includes an acoustic vibrating membrane (first vibrating electrode) 9 and an oscillating vibrating membrane (second vibrating electrode) 12. Since the electret members are respectively formed on the surfaces of the vibration film 12 facing each other, the acoustic vibration film 9 and the rocking vibration film 12 function as electrodes.
[0026]
In the electrostatic sensor 30, the acoustic diaphragm 9 is mounted on the sound hole 4 side in the cylindrical housing 2 having the sound hole 4 while being sandwiched between the acoustic diaphragm ring 8 and the spacer 18. The oscillating diaphragm 12 is mounted in a state of being sandwiched between the oscillating diaphragm ring 11 supported by the oscillating diaphragm holder 16 and the spacer 18. Further, a weight 14 for adjusting the natural frequency of the oscillating diaphragm 12 is mounted on a surface different from that facing the acoustic diaphragm 9. Further, the vibration film 12 for oscillation and the substrate 3 are connected via the vibration film ring 11 for vibration and the gate ring 7, and the vibration film 9 for vibration and the vibration film 12 for vibration detected by the vibration film 12 for vibration are detected. Is transmitted to the FET 17 provided on the substrate 3 and output. FIG. 2B shows a schematic circuit diagram of the acoustic vibration film 9, the vibration film 12 and the FET 17 of the electrostatic sensor 30 illustrated in FIG.
[0027]
In this electrostatic sensor 30, a capacitor portion is constituted by the vibrating diaphragm 9 having the electret member as well as the acoustic vibrating film 9 having the electret member. When sound enters the housing 2 from the sound hole 4, the acoustic vibrating membrane 9 vibrates in response to the acoustic signal, but the weight 14 vibrates in response to vibration having a frequency lower than the acoustic frequency. The adjusted vibrating membrane 12 functions as a fixed electrode without vibrating. As a result, the operation is performed so that the change in the electrostatic capacitance in the capacitor unit due to the vibration of only the acoustic vibration film 9 is output as a voltage signal from the output terminal illustrated in FIG. When the electrostatic sensor 30 is shaken at a frequency lower than the above-described acoustic frequency, the vibrating membrane 12 vibrates in response to the oscillation, but the acoustic vibrating membrane 9 does not vibrate. It acts as a fixed electrode. As a result, it operates so that the change in the electrostatic capacity in the capacitor portion described above due to the vibration of only the vibrating membrane 12 for oscillation is output as a voltage signal from the output terminal illustrated in FIG.
[0028]
When this electrostatic sensor 30 is incorporated in an electronic device, two functions, a function of detecting sound around the electronic device and a function of detecting swinging with respect to the electronic device, are combined into one function, the electrostatic sensor 30. There is an advantage that the signal processing circuit can be shared because the detected acoustic signal and the swing signal are the same kind of signals output from the same electrostatic sensor 30. As a result, even if a plurality of functions are provided, it is possible to satisfy the demand for electronic devices that are reduced in size, thickness, and weight.
[0029]
<Third Embodiment>
The electrostatic sensor 40 illustrated in FIG. 3 is similar to the electrostatic sensor 1 illustrated in FIG. 1, and includes a fixed electrode 6 and an acoustic vibration film (facing to one surface of the fixed electrode 6) ( A first vibrating electrode) 9, and an oscillating vibrating membrane (second vibrating electrode) 12 disposed to face the other surface of the fixed electrode 6. Further, a weight 14 for adjusting the natural frequency of the oscillating vibrating membrane 12 is mounted on the surface opposite to the surface facing the fixed electrode 6. In addition, by forming the electret member on the surface of the acoustic vibration film 9 that faces the fixed electrode 6, the acoustic vibration film 9 acts as an electrode. Similarly, the electret member is formed on the surface of the oscillating vibration film 12 that faces the fixed electrode 6, so that the oscillating vibration film 12 acts as an electrode.
[0030]
In this electrostatic sensor 40, the acoustic diaphragm 9 is sandwiched between the acoustic diaphragm ring 8 and the acoustic system spacer 10 on the sound hole 4 side in the cylindrical housing 2 having the sound hole 4. The oscillating diaphragm 12 is mounted while being sandwiched between the oscillating diaphragm ring 11 and the oscillating system spacer 13. The substrate 3 is sandwiched between holders 19 and fixed between the acoustic vibration film 9 and the oscillation film 12 within the housing 2. Further, a fixed electrode 6 sandwiched between the acoustic system spacer 10 and the oscillation system spacer 13 is provided on a part of the substrate 3 facing the acoustic oscillation film 9 and the oscillation film 12 for oscillation. The capacitance change between the acoustic vibrating membrane 9 and the fixed electrode 6 and the capacitance change between the oscillation vibrating membrane 12 and the fixed electrode 6 detected by the fixed electrode 6 are provided on the substrate 3. Is transmitted to the FET 17 and output. Further, an external output terminal 21 is provided on the substrate 3 so as to penetrate the sealing plate 20 that seals the housing 2.
[0031]
The schematic circuit diagram of the acoustic vibrating membrane 9, the fixed electrode 6, the oscillating vibrating membrane 12 and the FET 17 of the electrostatic sensor 40 is the same as that illustrated in FIG. In this case, the operation in the case where the oscillation is given and the case where the oscillation is given are also the same as those explained in the first embodiment, and therefore the explanation is omitted here. However, there is an advantage that the mounting position of the substrate 3 and the FET 17 can be changed to be thinner than the electrostatic sensor 1 described in the first embodiment.
[0032]
When this electrostatic sensor 40 is incorporated in an electronic device, the two functions of detecting the sound around the electronic device and detecting the swing of the electronic device are combined into a single electrostatic sensor 40. There is an advantage that the signal processing circuit can be made common because the detected acoustic signal and the swing signal are the same kind of signals output from the same electrostatic sensor 1, which can be achieved by the parts. As a result, even if a plurality of functions are provided, it is possible to satisfy the demand for electronic devices that are reduced in size, thickness, and weight.
[0033]
<Fourth embodiment>
With reference to FIG. 4 and FIG. 5, a portable electronic device equipped with the electrostatic sensor according to the present invention will be described by exemplifying a mobile phone with a step count measuring function.
FIG. 4 illustrates a functional block diagram of a portable electronic device (mobile phone with a step count function) 50, which has an acoustic detection function and a function for detecting a swing that occurs when a user walks. This is realized using two electrostatic sensors 1 (30, 40).
[0034]
When the portable electronic device 50 is used as a mobile phone, the electrostatic sensor 1 (30, 40) outputs an acoustic signal, and the acoustic signal is amplified by the amplifying unit 51 and converted into AD (analog-digital). After being converted into a digital signal by the unit 52, it is transmitted to the information processing unit 53. The information processing unit 53 analyzes the frequency of the signal transmitted from the AD conversion unit 52, determines that the signal is an acoustic signal, and transmits the acoustic signal to the outside through the acoustic signal transmission / reception unit 59 and the antenna. On the other hand, when the antenna receives an acoustic signal from the outside, the acoustic signal is transmitted to the information processing unit 53 via the acoustic signal transmission / reception unit 59. The acoustic signal is converted into an analog signal by a DA (digital-analog) converter 55, amplified by an amplifying unit 56, and then output from a speaker 57.
[0035]
When the portable electronic device 50 is not used as a mobile phone, that is, when the user is moving while wearing the portable electronic device 50, the electrostatic sensor 1 (30, 40) swings. The oscillation signal is amplified by the amplification unit 51, converted into a digital signal by the AD conversion unit 52, and then transmitted to the information processing unit 53. The information processing unit 53 analyzes the frequency of the signal transmitted from the AD conversion unit 52, determines that the signal is a swing signal, and stores the swing signal in the storage unit 54 such as a semiconductor memory device. In addition, the total number of steps up to that time of the day can be displayed on the display unit 58 such as a liquid crystal display device.
[0036]
Illustrated in FIG. 5 is an example of a display screen in a liquid crystal display device (display unit 58) of a mobile phone with a step count function, which is an example of the portable electronic device 50. In this case, the total number of steps up to 9:00 am on September 14 is displayed as 4753 steps. In addition, the information processing unit 53 can calculate not only the total number of steps for the current day stored in the storage unit 54 but also the total number of steps for the previous day, the total number of steps for the current month, and the like, and cause the display unit 58 to display them. Specifically, the information processing unit 53 displays headings such as “steps of the previous day” and “steps of this month” as illustrated in FIG. 5 on the display unit 58, and the headline is displayed by the user operating the key input unit 60. Is input, the past step count information stored in the storage unit 54 is calculated and the corresponding information is displayed.
[0037]
<Another embodiment>
<1>
In the first embodiment and the third embodiment, the case where the electret member is formed on the acoustic vibrating membrane 9 and the vibrating membrane 12 has been described, but a back electret type in which the electret member is formed on the fixed electrode 6 is also possible. is there. In that case, the acoustic vibration film 9 and the oscillating vibration film 12 need to be made of a conductive material capable of forming the fixed electrode 6 and the capacitor portion.
[0038]
<2>
In the second embodiment, the case where the electret member is formed on the acoustic vibrating membrane 9 and the oscillating vibrating membrane 12 has been described, but the electret member may be formed on any one of the vibrating membranes. In that case, the vibration film on which the electret member is not formed needs to be made of a conductive material that can form the opposing electret member and the capacitor portion.
[0039]
<3>
In the first embodiment and the third embodiment, the case where one fixed electrode 6 is provided between the acoustic vibrating membrane 9 and the oscillating vibrating membrane 12 has been described, but it faces the two vibrating membranes described above. A modification is also possible in which a fixed electrode is provided, and an acoustic signal and a swing signal are detected from two fixed electrodes, an acoustic fixed electrode and a swing fixed electrode.
[0040]
<4>
In the fourth embodiment, a mobile phone with a step count function is illustrated as an example of an electronic device having an acoustic detection function and a swing detection function. However, the electrostatic sensor according to the present invention is applied to various other electronic devices. Can be installed. For example, when the electrostatic sensor according to the present invention is mounted on a video camera, recording can be performed using an acoustic detection function, and camera shake of a video camera operator can be monitored using a swing detection function. .
[Brief description of the drawings]
FIG. 1A is a cross-sectional view of an electret condenser microphone, and FIG. 1B is a schematic circuit diagram thereof.
2A is a cross-sectional view of another electret condenser microphone, and FIG. 2B is a schematic circuit diagram thereof.
FIG. 3 is a cross-sectional view of an electret condenser microphone.
FIG. 4 is a functional block diagram of a mobile phone.
FIG. 5 is an example of a display screen of a mobile phone.
[Explanation of symbols]
1 Electret condenser microphone (electrostatic sensor)
2 Housing 3 Substrate 4 Sound hole 5 Fixed electrode holder 6 Fixed electrode 7 Gate ring 8 Acoustic vibrating membrane ring 9 Acoustic vibrating membrane (first vibrating electrode)
DESCRIPTION OF SYMBOLS 10 Spacer for acoustic system 11 Oscillating diaphragm ring 12 Oscillating diaphragm (second vibrating electrode)
13 Oscillator spacer 14 Weight 15 Ground ring 16 Oscillating membrane holder 17 FET
18 Spacer 19 Holder 20 Sealing plate 21 Terminal 30 Electret condenser microphone (electrostatic sensor)
40 Electret condenser microphone (electrostatic sensor)
DESCRIPTION OF SYMBOLS 50 Cellular phone 51 Amplification part 52 AD conversion part 53 Information processing part 54 Storage part 55 DA conversion part 56 Amplification part 57 Speaker 58 Display part 59 Acoustic signal transmission / reception part 60 Key input part

Claims (4)

A fixed electrode; a first vibrating electrode disposed to face one surface of the fixed electrode; and a second vibrating electrode disposed to face the other surface of the fixed electrode; An electret member is formed on any electrode between the first vibrating electrode and on any electrode between the fixed electrode and the second vibrating electrode,
Detecting vibration of the first vibrating electrode in response to sound by measuring a change in capacitance between the fixed electrode and the first vibrating electrode;
An electrostatic type that detects vibration of the second vibrating electrode that responds to fluctuations of a frequency lower than the acoustic frequency by measuring a change in capacitance between the fixed electrode and the second vibrating electrode. Sensor. A first vibration electrode that vibrates in response to sound; and a second vibration electrode that vibrates in response to fluctuations of a frequency lower than the frequency of the sound, the first vibration electrode and the second vibration electrode, An electret member is formed on any of the electrodes between
Detecting the vibration of the first vibrating electrode due to the sound by measuring a change in capacitance between the second vibrating electrode as the fixed electrode and the first vibrating electrode;
An electrostatic sensor that detects the vibration of the second vibrating electrode due to the swing by measuring a change in capacitance between the first vibrating electrode and the second vibrating electrode as a fixed electrode. The electrostatic sensor according to claim 1, wherein a weight for adjusting a natural frequency is attached to the second vibration electrode. A portable electronic device comprising the electrostatic sensor according to any one of claims 1 to 3 and having an acoustic detection function and a swing detection function.

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