a is a schematic perspective view of a conventional condenser microphone device.
b is a schematic sectional view of the sensing member of
c is a schematic perspective view of the sensing member of
a is a schematic sectional view of an embodiment of an improved structure of the condenser microphone device according to the present invention.
b is a schematic sectional view of an embodiment of another improved structure of the condenser microphone device according to the present invention.
c is a schematic sectional view of an embodiment of yet another improved structure of the condenser microphone device according to the present invention.
d is a schematic sectional view of an embodiment of still another improved structure of the condenser microphone device according to the present invention.
The following descriptions are exemplary embodiments only, and are not intended to limit the scope, applicability or configuration of the invention in any way. Rather, the following description provides a convenient illustration for implementing exemplary embodiments of the invention. Various changes to the described embodiments may be made in the function and arrangement of the elements described without departing from the scope of the invention as set forth in the appended claims.
A conventional condenser microphone device, as shown in
The improved structures and methods disclosed by the present invention are mainly applied to the sensing member 100 of the microphone device. A microphone device incorporating the present invention is used by having the sensing member (housed in the casing member) in contact with the skin of the speaker, and the skin provides preliminarily shielding to the environmental noise. Then, the improved structures or methods of the present invention further reduce the sensitivity of the sensing member to the environmental noise so as to achieve the required level of noise shielding. The microphone device can be implemented into various applications such as wired or wireless headset of mobile phones. Please note that, the circuit board 110, electronic member 120, and the casing member are omitted from the following description as they are not the subject matter of the present invention. Please also note that the accompanied drawings are not drawn to scale.
b and 1c provide schematic sectional and perspective views to the sensing member of
Right beneath the receiving end, a first metallic plate 20, a charged film 30, an insulating washer 40, and a second metallic plate 50 are arranged in this sequential top-down order. The first metallic plate 20 provides a through hole 21 in the center which is covered entirely by the charged film 30 from below. The through hole 21 allows air to contact the charged film 30 and provides room for the vibration of the charged film 30. The electrical charge carried by the charged film 30 is provided by a polarization process during manufacturing the sensing member 100, and the electrical charge is sealed in silicone or similar material. Also to provide room for the vibration of the charged film 30, a through hole 41 is configured in the center of the washer 40. Similarly, the second metallic plate 50 has a number of through holes 51 to allow air to flow through.
A capacitor is formed by the charged film 30 and the second metallic film 50 with each of them functioning as an electrode to the capacitor. As the second metallic film 50 is induced to carry an equal amount of opposite electrical charge, a potential difference is thereby developed between the two electrodes, which are separated by the washer 40. The potential difference varies along with the change of distance between the two electrodes as the charged film 30 vibrates. An electrical signal corresponding to the vibration of the charged film 30 is therefore obtained. This is the general operation principle of a condenser microphone device.
The electrical signal is then conducted from the electrodes to an impedance transform element 60 on the circuit board 80 via the enclosure 10 and some wiring (not shown). The impedance transform element 60 is usually a field effect transistor (FET) whose main purpose is for impedance matching with the external circuitry outside the sensing member 100. The output of the impedance transform element 60 is provided on the output terminals 90 of the sensing member 100.
When a sensing member as shown in
The first method provided by the present invention is to reduce the sensitivity of the sensing member by endowing a smaller amount of electrical charge to the charged film 30 through reducing the voltage and operation time of the polarization process. The sensitivity of a conventional sensing member is around −40 dB, and the sensitivity of a sensing member produced by the present method is reduced to −50˜−60 dB so as to minimize the impact of the environmental noise to the sensing member.
Another method of the present invention is to reduce the aperture or the total area of the through holes 11 from the conventional 2 mm down to less than 1 mm. In this way, only a very small fraction of the air vibration caused by the environmental noise would penetrate into the enclosure 10 via the through holes 11.
To solve the problems of low-frequency distortion from violent skin vibration, of low-frequency echo from the cranium resonance, and of weakened high-frequency signal from the reduction of sensitivity, the foregoing methods are further augmented by a filtering and amplification means. In one way, the electrical signal of the low-frequency distortion and low-frequency echo are filtered and, in another way, the gain of the filtering and amplification means is increased along with the frequency of the electrical signal so as to achieve superior frequency response. In other words, the gain of the filtering and amplification means is smaller at low frequency band and larger at high frequency band within the audible sound frequency range. Even though the sensitivity of the sensing member is reduced through the foregoing methods, it is still relatively sensitive to the skin vibration compared to the conventional piezoelectric sensing members. Therefore, the gain of the filtering and amplification means is moderate and the problem of picking up circuit noise is thereby not significant.
Generally, this filtering and amplification means is implemented by a high-pass amplification circuit. The high-pass amplification circuit takes the output of the sensing member as its input, and produces its output to other circuits connected to the microphone device. The high-pass filter circuit is quite well known to people skilled in the related arts and its details are omitted here.
a˜2c are schematic sectional views of the embodiments of the improved structures of the sensing member according to the present invention. These improved structures all involve the cladding of a jacket or film 70 around the enclosure 10. The jacket 70 is usually made of a flexible material such as plastic, rubber, or artificial rubber, and the jacket 70 covers at least the through hole 11. The purpose of having the plastic jacket 70 is to shield the air vibration from the environmental noise and to reduce its strength in penetrating through the enclosure 10. According to experiments, the jacket 70 can provide a shielding effect between 10˜20 dB. As a result, it is not necessary to reduce the electrical charge of the charged film 30 or the aperture of the through hole 11, and a conventional, inexpensive manufacturing process of the sensing member could be readily adapted for the implementation of a skin-contact microphone device, lowering down the production cost significantly.
As shown in
The improved structure shown in
The improved structure shown in
The foregoing methods and improved structures can be implemented individually, or jointly to achieve even better noise shielding result. For example, the method of reducing the electrical charge of the charged film 30 can be applied along with the configuration of a flexible film or jacket 70 to cover the through hole 11, or along with a flexible film or jacket 70 having a tiny through hole 71, or along with a flexible film or jacket 70 having a buffer space 72 at the receiving end of the enclosure 10.
Similarly, to solve the problems of low-frequency distortion from violent skin vibration, of low-frequency echo from the cranium resonance, and of weakened high-frequency signal from the reduction of sensitivity, the foregoing structure is augmented by a filtering and amplification component that, on one hand, filters the electrical signal of the low-frequency distortion and low-frequency echo and, on the other hand, provides increasing gain along with the frequency of the electrical signal. The filtering and amplification component could be implemented by a high-pass amplification circuit. The high-pass amplification circuit takes the output of the sensing member 300 as its input, and produces its output to other circuits connected to the microphone device.
Although the present invention has been described with reference to the preferred embodiments, it will be understood that the invention is not limited to the details described thereof. Various substitutions and modifications have been suggested in the foregoing description, and others will occur to those of ordinary skill in the art. Therefore, all such substitutions and modifications are intended to be embraced within the scope of the invention as defined in the appended claims.