CN210781345U - MEMS microphone of single directive pickup - Google Patents

Abstract

The utility model relates to the field of microphones, in particular to an MEMS microphone for unidirectional pickup, which comprises a packaging substrate and an MEMS microphone, the packaging substrate is provided with a sound inlet hole and a switch lower sound hole, the MEMS microphone is fixed at the position of the sound inlet hole on the substrate, an MEMS switch electrically connected with the MEMS microphone is fixed on the switch lower sound hole, the packaging substrate is fixed with a cavity plate, the cavity plate is divided into a microphone cavity and a switch cavity by an internal clapboard of the cavity plate, the MEMS microphone is arranged in the microphone cavity, the MEMS switch is arranged in the switch cavity, an encapsulation cover plate is fixed above the cavity plate, an upper switch sound hole is arranged on the encapsulation cover plate and is arranged above the switch cavity, the MEMS microphone comprises a Sensor chip fixed above the near sound hole, and the Sensor chip is connected with an ASIC chip through a bonding wire. The device realizes the unidirectional pickup of the MEMS microphone.

Description

MEMS microphone of single directive pickup

[ technical field ] A method for producing a semiconductor device

The invention relates to the field of microphones, in particular to an MEMS microphone capable of picking up sound in a single direction.

[ background of the invention ]

MEMS is a Micro-Electro mechanical System (Micro-Electro mechanical System), which refers to a sensor device with a size of several millimeters or less, and the internal structure of the sensor device is generally in the micrometer or nanometer level, and the sensor device is an independent intelligent System. Briefly, the MEMS is a silicon-based sensor formed by miniaturizing mechanical components of a conventional sensor, fixing a device on a silicon wafer (wafer) by a three-dimensional stacking technique, for example, a three-dimensional through-silicon via (TSV) technique, and finally cutting and assembling the device in a specially-customized packaging form according to different application occasions. The MEMS has the advantages of miniaturization and high integration degree which cannot be achieved by the common sensor;

the microphone can be divided into a full direction, a double direction and a single direction according to different pickup modes of the microphone; the omnidirectional microphone has the same sensitivity to sounds in all directions, and the recognition degrees of the sounds in different directions are consistent; the double-directional microphone is sensitive to the sounds in the front and the back, and the sensitivity to the sounds in other areas is reduced; the single directional microphone is sensitive to only forward sound, and the sensitivity to sound in other areas is reduced; the unidirectional microphone and the double-directional microphone are collectively called as the directional microphone, compared with the omni-directional microphone, the directional microphone can reject a large amount of environmental noise, selectively pick up sound signals in a fixed area, can realize the directional sound pickup function through a single product, and has important value for terminal products needing regional sound pickup. However, the existing microphone cannot achieve complete unidirectional sound pickup, and noise is generated during use.

[ summary of the invention ]

The invention aims to overcome the defects of the prior art and provides a single-direction pickup MEMS microphone which can effectively avoid noise picked up when the microphone picks up sound in a single direction.

The invention can be realized by the following technical scheme:

the invention discloses an MEMS microphone for unidirectional pickup, which comprises a packaging substrate and an MEMS microphone, wherein the packaging substrate is provided with a sound inlet hole and a switch lower sound hole, the position of the sound inlet hole on the substrate is fixedly provided with the MEMS microphone, the switch lower sound hole is fixedly provided with an MEMS switch electrically connected with the MEMS microphone, the packaging substrate is fixedly provided with a cavity plate, the cavity plate is divided into a microphone cavity and a switch cavity through a partition plate inside the cavity plate, the MEMS microphone is arranged inside the microphone cavity, the MEMS switch is arranged inside the switch cavity, a packaging cover plate is fixed above the cavity plate, the packaging cover plate is provided with a switch upper sound hole, the switch upper sound hole is arranged above the switch cavity, the MEMS microphone comprises a Sensor chip fixed above a near sound hole, the Sensor chip is connected with an ASIC chip through a bonding wire, the MEMS switch comprises a base material fixed at the position of the switch lower sound hole, a conductive plate is arranged above the base material, one side of the conductive plate is connected with the base material through an electrode, an upper polar plate is fixed on the other side of the conductive plate, and a lower polar plate is arranged on the base material at a position corresponding to the upper polar plate; external sound enters the switch cavity through the switch lower sound hole and the switch upper sound hole, pressure difference is formed between the upper end surface and the lower end surface of the current conducting plate due to sound pressure, the sound is attenuated gradually in the transmission process, when the sound is transmitted from the corresponding surface of the switch upper sound hole, the distance from the switch upper sound hole to the upper end surface of the current conducting plate is smaller than the distance from the switch lower sound hole to the lower end surface of the current conducting plate, the pressure on the upper end surface of the current conducting plate is larger than the pressure on the lower end surface of the current conducting plate, the current conducting plate is bent, when the pressure difference reaches a certain threshold value, the upper polar plate is in contact with the lower polar plate, the circuit is conducted, the ASIC chip transmits a sound signal received by the Sensor chip, when the sound is transmitted from the opposite surface of the switch lower sound hole;

a production method of a single-direction pickup MEMS microphone comprises the following steps

a. Attaching an ASIC chip to the end face of the packaging substrate by using an adhesive, and baking and curing;

b. mounting a Sensor chip right above a position of a sound hole on a packaging substrate through an adhesive, and completely sealing the bottom of the Sensor chip through the adhesive;

c. attaching the MEMS switch right above the position of a lower sound hole of the switch on the packaging substrate through an adhesive;

d. the electrical connection among the Sensor chip, the ASIC chip, the MEMS switch and the packaging substrate is completed by using a bonding wire in a lead bonding mode;

e. bonding the package substrate and the cavity plate together by using an adhesive, wherein the adhesive layer is completely sealed;

f. the cavity plate and the package cover plate are bonded together using an adhesive, the adhesive layer being completely sealed.

Preferably, the conductive plate is uniformly provided with plate electrode sound holes.

Preferably, a switch pin is arranged at the assembly position of the MEMS switch on the packaging substrate and is electrically connected with the ASIC chip through a copper foil on the packaging substrate.

Preferably, the bonding wire is made of metal materials such as gold, aluminum, copper and the like.

Compared with the prior art, the invention has the following advantages:

external sound gets into in the switch cavity through the phonate hole under the switch and on the switch, receive sound pressure on the terminal surface and form the pressure differential about the current conducting plate, because sound can attenuate gradually in the transmission process, it comes to transmit to correspond the face from the phonate hole on the switch when sound, the distance that sound reachs the current conducting plate up end from the phonate hole on the switch is less than the distance that sound reachs terminal surface under the current conducting plate from the switch, the pressure that receives on the current conducting plate up end is greater than the pressure that terminal surface received under the current conducting plate, the current conducting plate takes place to buckle, when pressure differential reaches certain threshold value, go up polar plate and bottom plate contact, the circuit switches on, the ASIC chip receives sound signal transmission with the Sensor chip, the unidirectional pickup function of this device has been realized.

[ description of the drawings ]

The following detailed description of embodiments of the invention is provided in conjunction with the appended drawings, in which:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is a block diagram of a MEMS switch of the present invention;

FIG. 4 is a front view of a MEMS switch of the present invention;

FIG. 5 is a schematic diagram of a MEMS switch with sound over a conductive plate;

FIG. 6 is a schematic diagram of a MEMS switch with sound under the conductive plate;

FIG. 7 is a schematic of the present invention with sound over the conductive plate;

FIG. 8 is a schematic of the present invention with sound below the conductive plate;

FIG. 9 is a graphical illustration of the acoustic threshold of the present invention;

FIG. 10 is an acoustic threshold map of the present invention;

FIG. 11 is a circuit diagram of the present invention;

FIG. 12 is a diagram of a Sensor chip according to the present invention;

in the figure: 1. a package substrate; 11. a sound inlet hole; 12. switching a lower sound hole; 13. a switch pin; 2. a MEMS switch; 21. a conductive plate; 22. an electrode; 23. an upper polar plate; 24. a lower polar plate; 25. a substrate; 26. acoustic holes of the polar plate; 27. a through hole; 3. an ASIC chip; 4. a Sensor chip; 401. a back electrode; 402. silicon-based; 403. vibrating diaphragm; 5. a cavity plate; 51. a microphone cavity; 52. a switch cavity; 6. packaging the cover plate; 61. switching the upper sound hole;

[ detailed description ] embodiments

The embodiments of the present invention will be described in detail below with reference to the accompanying drawings:

as shown in fig. 1 to 12, the present invention discloses an MEMS microphone for picking up sound in one direction, which comprises a package substrate 1 and an MEMS microphone, wherein the package substrate 1 is provided with a sound inlet hole 11 and a switch lower sound hole 12, the MEMS microphone is fixed at the position of the sound inlet hole 11 on the substrate, the MEMS switch 2 electrically connected to the MEMS microphone is fixed on the switch lower sound hole 12, the package substrate 1 is fixed with a cavity plate 5, the cavity plate 5 is divided into a microphone cavity 51 and a switch cavity 52 by a partition plate inside the cavity plate 5, the MEMS microphone is arranged inside the microphone cavity 51, the MEMS switch 2 is arranged inside the switch cavity 52, a package cover plate 6 is fixed above the cavity plate 5, the package cover plate 6 is provided with a switch upper sound hole 61, the switch upper sound hole 61 is arranged above the switch cavity 52, the MEMS microphone comprises a Sensor chip 4 fixed above the near sound hole, the Sensor chip 4 is connected to an ASIC chip 3 by a bonding wire, the MEMS switch 2 comprises a base material 25 fixed at the position of a lower sound hole 12 of the switch, a through hole 27 is arranged on the base material 25 corresponding to the lower sound hole 12 of the switch, a conductive plate 21 is arranged above the base material 25, one side of the conductive plate 21 is connected with the base material 25 through an electrode 22, an upper polar plate 23 is fixed on the other side of the conductive plate 21, and a lower polar plate 24 is arranged on the base material 25 corresponding to the upper polar plate 23; external sound enters the switch cavity 52 through the switch lower sound hole 12 and the switch upper sound hole 61, pressure difference is formed between the upper end surface and the lower end surface of the conductive plate 21 due to sound pressure, the sound is gradually attenuated in the transmission process, when the sound is transmitted from the corresponding surface of the switch upper sound hole 61, the distance from the switch upper sound hole 61 to the upper end surface of the conductive plate 21 is smaller than the distance from the switch lower sound hole 12 to the lower end surface of the conductive plate 21, the pressure on the upper end surface of the conductive plate 21 is larger than the pressure on the lower end surface of the conductive plate 21, the conductive plate 21 bends, when the pressure difference reaches a certain threshold value, the upper polar plate 23 is in contact with the lower polar plate 24, the circuit is conducted, the ASIC chip 3 transmits a sound signal received by the Sensor chip 4, and when the sound is transmitted from the right opposite surface of the switch lower sound hole 12, the upper polar plate 23 moves away;

a production method of a single-direction pickup MEMS microphone comprises the following steps

a. An ASIC chip 3 is attached to the end face of the packaging substrate 1 by using an adhesive and is cured by baking;

b. the Sensor chip 4 is attached to the packaging substrate 1 right above the position of the sound hole 11 through an adhesive, and the bottom of the Sensor chip 4 is completely sealed through the adhesive;

c. the MEMS switch 2 is attached to the packaging substrate 1 right above the position of the lower switch sound hole 12 through an adhesive;

d. the electrical connection among the Sensor chip 4, the ASIC chip 3, the MEMS switch 2 and the packaging substrate 1 is completed by using a bonding wire in a lead bonding mode;

e. bonding the package substrate 1 and the cavity plate 5 together using an adhesive, the adhesive layer being completely sealed;

f. the cavity plate 5 and the package cover plate 6 are bonded together using an adhesive, the adhesive layer being completely sealed.

Wherein, the conductive plate 21 is uniformly provided with plate electrode sound holes 26.

The MEMS switch 2 assembly position on the packaging substrate 1 is provided with a switch pin 13, and the switch pin 13 is electrically connected with the ASIC chip 3 through a copper foil on the packaging substrate 1.

The bonding wire is made of metal materials such as gold, aluminum, copper and the like.

As shown in fig. 11: the BIAS electrode 22 of the Sensor chip 4 is connected with the BIAS voltage of the ASIC chip 3, and the ASIC chip 3 provides a stable Charge source for the operation of the Sensor chip 4 through a Charge bump; vout of the ASIC chip 3 is connected with Vout of the Sensor chip 4, the Sensor chip 4 transmits an output signal to a Vout interface of the ASIC chip 3, and the ASIC chip 3 performs subsequent amplification, filtering and other processing;

the ASIC chip 3 needs external power supply for work, so the VDD end of the ASIC chip 3 needs external power supply, the power voltage is 1.6V-3.6V, the GND end of the ASIC chip 3 is grounded, the OUT end of the ASIC chip 3 is connected with the MEMS switch 2, when the upper polar plate 23 of the MEMS switch 2 is contacted with the lower polar plate 24, the circuit is conducted, and the ASIC chip 3 realizes the function of leading OUT the output signal of the Sensor chip 4.

As shown in fig. 12, the structure of the Sensor chip 4 is shown, the Sensor chip 4 is composed of a diaphragm 403, a back electrode 401 and a silicon substrate 402, the diaphragm 403 and the back electrode 401 are fixed inside a cavity of the silicon substrate 402 by a semiconductor processing technology (etching, polishing, evaporation, etc.), the operation principle of the chip is equivalent to a parallel plate capacitor, the diaphragm 403 and the back electrode 401 constitute upper and lower substrates of the capacitor, charges directionally move under the action of voltage, a stable voltage difference is formed between the upper and lower substrates, when external sound pressure acts on the diaphragm 403, the distance between the diaphragm 403 and the back electrode 401 changes, the formula C ∈ S/4 π kd shows that the capacitance of the capacitor changes accordingly when the distance changes (C: capacitance ∈: dielectric constant, S: the facing area d between the diaphragm 403 and the back electrode 401: the distance between the two plates, k: Q/C), when the distance changes, the output voltage value changes (Q: the constant charge value of the capacitor 403, Q: the constant charge value, U: U-403, U-36, U-v) shows that the chip can be transformed into a voltage after the external sound pressure of the chip 3632, and the chip can be transformed into a voltage after the sound pressure of the external sound pressure changes 1.

Wherein, the adhesive is made of silica gel material.

The above description is only a preferred embodiment of the present invention, and it should be noted that a person skilled in the art can make various changes, modifications, substitutions and alterations to the embodiments without departing from the technical principles of the present invention, and such changes, modifications, substitutions and alterations should also be regarded as the protection scope of the present invention.

Claims (3)

1. A MEMS microphone of single finger pickup which characterized in that: the MEMS microphone comprises a packaging substrate and an MEMS microphone, wherein a sound inlet hole and a switch lower sound hole are formed in the packaging substrate, the MEMS microphone is fixedly arranged at the position of the substrate upper sound hole, an MEMS switch which is electrically connected with the MEMS microphone is fixedly arranged on the switch lower sound hole, a cavity plate is fixedly arranged on the packaging substrate, the cavity plate is divided into a microphone cavity and a switch cavity through an internal partition plate of the cavity plate, the MEMS microphone is arranged inside the microphone cavity, the MEMS switch is arranged inside the switch cavity, a packaging cover plate is fixedly arranged above the cavity plate, a switch upper sound hole is formed in the packaging cover plate, the switch upper sound hole is arranged above the switch cavity, the MEMS microphone comprises a Sensor chip fixed above the near sound hole, the Sensor chip is connected with an ASIC chip through a bonding wire, the MEMS switch comprises a base material fixed at the position of the switch lower sound hole, and a conductive plate is arranged above the base material, one side of the current-conducting plate is connected with the base material through an electrode, the other side of the current-conducting plate is fixedly provided with an upper polar plate, and a lower polar plate is arranged on the base material at a position corresponding to the upper polar plate.

2. The MEMS microphone of single directional pickup of claim 1, wherein: and the conductive plate is uniformly provided with plate electrode sound holes.

3. The MEMS microphone of single directional pickup of claim 1, wherein: and a switch pin is arranged at the assembly position of the MEMS switch on the packaging substrate and is electrically connected with the ASIC chip through a copper foil on the packaging substrate.

Images