阅读说明：本技术 可调整感应电容值的微机电感测装置 (Micro-electromechanical sensing device capable of adjusting induction capacitance value ) 是由 许郁文 黄肇达 郭秦辅 叶哲恺 于 2019-03-29 设计创作，主要内容包括：本发明公开一种可调整感应电容值的微机电感测装置,其包含特殊应用集成电路芯片以及感测元件。特殊应用集成电路芯片包含上表面、读取电路以及多个电性开关。感测元件用以侦测物理量并且包含固定电极以及可动电极。固定电极包含多个电极单元。可动电极可相对固定电极移动。该些电性开关分别电性耦接至各该些电极单元,用以控制该些电极单元的工作状态,进而可改变可调整感应电容值的微机电感测装置的感应电容值。(The invention discloses a micro-electro-mechanical sensing device capable of adjusting an induction capacitance value, which comprises an application specific integrated circuit chip and a sensing element. The ASIC chip includes an upper surface, a read circuit, and a plurality of electrical switches. The sensing element is used for detecting physical quantity and comprises a fixed electrode and a movable electrode. The fixed electrode includes a plurality of electrode units. The movable electrode is movable relative to the fixed electrode. The electrical switches are electrically coupled to the electrode units respectively for controlling the working states of the electrode units, so as to change the sensing capacitance value of the micro-electromechanical sensing device capable of adjusting the sensing capacitance value.)

1. A micro-electromechanical sensing device capable of adjusting an induced capacitance value, comprising:

an asic chip, comprising:

an upper surface;

a read circuit; and

a plurality of electrical switches; and

a sensing element for detecting a physical quantity, the sensing element comprising:

a fixed electrode including a plurality of electrode units; and

a movable electrode movable relative to the fixed electrode;

the plurality of electrical switches are electrically coupled to the plurality of electrode units respectively, and are used for controlling a working state of the plurality of electrode units, so that an induction capacitance value of the sensing element can be changed.

2. The mems sensing apparatus of claim 1, wherein the operating state includes an on state and an off state, the operating state of each of the plurality of electrode units is defined as the on state when the asic chip supplies charge to each of the plurality of electrode units via each of the plurality of electrical switches, and the operating state of each of the plurality of electrode units is defined as the off state when the asic chip does not supply charge to each of the plurality of electrode units via each of the plurality of electrical switches.

3. The mems sensing apparatus of claim 2, wherein a portion of the plurality of electrode units forms an electrode assembly, and a portion of the plurality of electrical switches enables the plurality of electrode units in the electrode assembly to have the same operating state.

4. The mems sensing apparatus of claim 2, wherein the plurality of electrical switches are capacitive sensing switches.

5. The mems sensing apparatus of claim 2, wherein the plurality of electrical switches are resettable fuse switches.

6. The mems sensing apparatus of claim 1, wherein the plurality of electrode units are disposed on the top surface of the asic chip.

7. The mems sensing apparatus of claim 1, further comprising a substrate, wherein the plurality of electrode units and the asic chip are disposed on the substrate.

8. The mems sensing apparatus of claim 6, wherein the movable electrode comprises a fixed portion and a movable portion, the fixed portion is disposed on the top surface of the asic chip, and the movable portion corresponds to the plurality of electrode units.

9. The micro-electromechanical sensing device with adjustable induced capacitance according to claim 8, wherein one end of the movable portion of the movable electrode is connected to the fixed portion, and the other end of the movable portion is suspended.

10. The mems sensing apparatus of claim 8, wherein the fixed portion of the movable electrode surrounds the plurality of electrode units.

11. The mems sensing apparatus of claim 8, wherein the plurality of electrode units of the fixed electrode include a central electrode unit and at least one ring electrode unit, and the at least one ring electrode unit surrounds the central electrode unit.

12. The mems sensing apparatus of claim 8, wherein the movable electrode is movable relative to the fixed electrode along a direction perpendicular to a normal of the top surface.

13. The mems sensing apparatus of claim 12, wherein the plurality of electrode units of the fixed electrode include at least a first electrode unit and at least a second electrode unit, the movable electrode includes a fixed portion, a flexure portion and a movable portion, the movable portion is connected to the fixed portion via the flexure portion, and the at least a first electrode unit and the at least a second electrode unit are respectively disposed on opposite sides of the movable portion.

14. A micro-electromechanical sensing device capable of adjusting an induced capacitance value, comprising:

a substrate;

the special application integrated circuit chip is arranged on the substrate and comprises a reading circuit, a plurality of first electrical switches and a plurality of second electrical switches;

the first sensing element is arranged on the substrate, is used for detecting a first physical quantity and comprises:

a first fixed electrode including a plurality of first electrode units; and

the first movable electrode can move relative to the first fixed electrode, and each of the first electrical switches is electrically coupled to each of the first electrode units respectively and used for controlling the working state of each of the first electrode units so as to change the induction capacitance value of the first sensing element; and

the second sensing element is disposed on the substrate, and is used for detecting a second physical quantity, including:

a second fixed electrode including a plurality of second electrode units; and

the second movable electrode can move relative to the second fixed electrode, and each of the second electrical switches is electrically coupled to each of the second electrode units respectively, so as to control the working state of each of the second electrode units and further change the induction capacitance value of the second sensing element.

15. The micro-electromechanical device for adjusting sensing capacitance according to claim 14, wherein the first movable electrode includes a first fixed portion and a first movable portion, the first fixed portion is disposed on the substrate and surrounds the plurality of first electrode units, and the first movable portion is suspended above the plurality of first electrode units.

16. The mems sensing device with adjustable sensing capacitance of claim 15, wherein the second movable electrode comprises a plurality of second fixed portions disposed on the substrate and a second movable portion disposed between the plurality of second fixed portions, the second movable portion comprises a movable mass and a plurality of elastic members, each of the plurality of elastic members is connected to the movable mass and each of the plurality of second fixed portions, and the movable mass is suspended above the plurality of second electrode units.

17. The mems sensing apparatus of claim 16, wherein the first physical quantity is air pressure and the second physical quantity is acceleration.

18. The micro-electromechanical sensing device of adjustable induced capacitance value of claim 14,

when the ASIC chip supplies charges to the first electrode units through the first electrical switches, the working state of the first electrode units is defined as ON state, and when the ASIC chip does not supply charges to the first electrode units through the first electrical switches, the working state of the first electrode units is defined as OFF state,

when the ASIC chip supplies charges to the second electrode units via the second electrical switches, the working state of the second electrode units is defined as ON state, and when the ASIC chip does not supply charges to the second electrode units via the second electrical switches, the working state of the second electrode units is defined as OFF state

The sum of the areas of the plurality of first electrode units in the on state is not equal to the sum of the areas of the plurality of second electrode units in the on state.

19. The mems sensing apparatus of claim 18, wherein a sum of areas of the first electrode units in an on state is greater than a sum of areas of the second electrode units in an on state.

20. The mems sensing apparatus of claim 19, wherein an area of each of the plurality of first electrode units is equal to an area of each of the plurality of second electrode units, and a number of the plurality of first electrode units in an on state is greater than a number of the plurality of second electrode units in an on state.

Technical Field

The present invention relates to a micro-electromechanical sensing device, and more particularly, to a micro-electromechanical sensing device with adjustable sensing capacitance.

Background

A micro-electromechanical sensor is a device that converts a change in a measured physical quantity into a change in capacitance. The micro-electro-mechanical sensor is a variable capacitor, and has the characteristics of simple structure, small volume, high sensitivity, high resolution, capability of realizing non-contact measurement and the like, so the micro-electro-mechanical sensor is widely applied to detecting the change of mechanical physical quantities such as displacement, acceleration, vibration, pressure, differential pressure, liquid height and the like.

Conventional capacitive micro-electromechanical sensors include upper and lower electrodes, one of which is a fixed electrode and the other of which is a movable electrode. When the movable electrode is subjected to an external force, the movable electrode is deformed to some extent and approaches the fixed electrode. The capacitance of the capacitive micro-electromechanical sensor is affected by the distance between the fixed electrode and the movable electrode. The capacitance value is changed by a certain variable quantity of the distance between the two electrodes, and the potential difference between the electrodes is changed. The user can estimate the degree of change of the physical quantity by reading the potential difference before and after the deformation of the electrode by the circuit.

Due to the increasing demand for micro-sensing, the capacitive mems sensor needs to have high sensitivity so as to be able to detect small physical quantity changes. In general, the micro-electromechanical sensor has a small distance between the fixed electrode and the movable electrode, which can generate a significant potential difference change, thereby increasing the sensitivity of the micro-electromechanical sensor. However, if a capacitive mems sensor suitable for micro-sensing is used to detect a large physical quantity change, the integrated circuit in the capacitive mems sensor may be burned out due to an excessive potential difference change. Therefore, the conventional capacitive micro-electromechanical sensor suitable for micro-detection cannot be used for detecting large physical quantity changes.

Disclosure of Invention

In view of the above problems, the present invention discloses a micro-electromechanical sensing device capable of adjusting an induced capacitance value, which is capable of properly adjusting the induced capacitance value, and is helpful to solve the problem that the existing micro-electromechanical sensor cannot detect both a small physical quantity change and a large physical quantity change.

The invention discloses a micro-electromechanical sensing device capable of adjusting an induction capacitance value, which comprises a special application integrated circuit chip and a sensing element. The ASIC chip includes an upper surface, a read circuit, and a plurality of electrical switches. The sensing element is used for detecting a physical quantity and comprises a fixed electrode and a movable electrode. The fixed electrode includes a plurality of electrode units. The movable electrode is movable relative to the fixed electrode. The electrical switches are electrically coupled to the electrode units respectively for controlling a working state of the electrode units, so as to adjust an induced capacitance of the mems sensor.

The invention also discloses a micro-electromechanical sensing device capable of adjusting the induction capacitance value, which comprises a substrate, a special application integrated circuit chip, a first sensing element for detecting the first physical quantity and a second sensing element for detecting the second physical quantity. The ASIC chip is disposed on the substrate and includes a reading circuit, a plurality of first electrical switches, and a plurality of second electrical switches. The first sensing element is disposed on the substrate and includes a first fixed electrode and a first movable electrode. The first fixed electrode includes a plurality of first electrode units. The first movable electrode is movable relative to the first fixed electrode. Each of the first electrical switches is electrically coupled to each of the first electrode units, and is used for controlling the working state of each of the first electrode units, so as to adjust the value of the capacitance between the first fixed electrode and the first movable electrode. The second sensing element is disposed on the substrate and includes a second fixed electrode and a second movable electrode. The second fixed electrode includes a plurality of second electrode units. The second movable electrode is movable relative to the second fixed electrode. Each of the second electrical switches is electrically coupled to each of the second electrode units, and is used for controlling the working state of each of the second electrode units, so as to adjust the value of the capacitance between the second fixed electrode and the second movable electrode.

According to the micro-electromechanical sensing device capable of adjusting the induced capacitance disclosed by the invention, the plurality of electrical switches are respectively and electrically coupled to the plurality of electrode units so as to control the working states of the electrode units. By independently controlling the working states of the electrode units, the value of the induction capacitance of the micro-electromechanical sensor can be adjusted, so that the change degree of the physical quantity to be detected can be accurately measured, and the failure of the special application integrated circuit chip can be prevented. When a small amount of physical quantity change is detected, a plurality of electrode units are in an on state (i.e., the electrical switch is turned on to supply charges to the electrode units). When a large physical quantity change needs to be detected, a small number of electrode units can be in an open state to reduce the induction capacitance value of the micro-electromechanical sensor, and further, the failure of a reading circuit in the special application integrated circuit chip is avoided.

The foregoing summary of the invention and the following detailed description of the embodiments are provided to illustrate and explain the spirit and principles of the invention and to provide further explanation of the invention's scope of the claims.

Drawings

Fig. 1 is a schematic perspective view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a first embodiment of the invention.

Fig. 2 is a schematic diagram illustrating an electrical connection relationship between an asic chip and an electrode unit in the mems sensing apparatus of fig. 1.

Fig. 3 is a schematic diagram of the operating state of the electrode unit of the micro electromechanical sensing apparatus capable of adjusting the sensing capacitance of fig. 1 when detecting a small physical quantity change.

Fig. 4 is a schematic diagram of the operating state of the electrode unit of the micro-electromechanical sensing device capable of adjusting the sensing capacitance value of fig. 1 when detecting a large physical quantity change.

FIG. 5 is a schematic perspective view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a second embodiment of the invention.

FIG. 6 is a top view of the MEMS sensing device with adjustable sensing capacitance of FIG. 5.

Fig. 7 is a schematic perspective cross-sectional view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a third embodiment of the invention.

Fig. 8 is a schematic cross-sectional view of a micro-electromechanical sensing device with an adjustable induced capacitance value according to a fourth embodiment of the invention.

FIG. 9 is a cross-sectional view of the MEMS sensing device with adjustable sensing capacitance of FIG. 8.

FIG. 10 is a schematic perspective view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a fifth embodiment of the invention.

FIG. 11 is a schematic diagram of an electrical connection relationship between an ASIC chip and an electrode unit in the MEMS sensing device with adjustable sensing capacitance of FIG. 10.

Description of the symbols

1. 1a, 1b, 1c, 1d micro-electromechanical sensing device capable of adjusting induction capacitance value

2d substrate

21 upper surface of the container

10. 10d ASIC chip

110 upper surface

120. 120d reading circuit

130 electric switch

130d first electrical switch

130e second electrical switch

11. 11a, 11b, 11c sensing element

11d first sensing element

11e second sensing element

20. 20a, 20c fixed electrodes

20d first fixed electrode

20e second fixed electrode

210 electrode unit

210a, 210d first electrode unit

211a first comb teeth

220a, 210e second electrode unit

221a second comb tooth

210c center electrode unit

220c ring electrode unit

21. 22, 23, 24, 25, 26, 27, 28 electrode combination

30. 30a, 30b, 30c movable electrode

30d first movable electrode

30e second movable electrode

310. 310a, 310b, 310c fixing part

310d first fixed part

310e second fixed part

320. 320a, 320b, 320c movable part

320d first movable part

320e second movable part

321a third comb tooth

321e electrode element

322e elastic member

330a flexure

Detailed Description

The detailed features and advantages of the present invention are described in detail in the following embodiments, which are sufficient for any person skilled in the art to understand the technical contents of the present invention and to implement the same, and the objects and advantages related to the present invention can be easily understood by any person skilled in the art according to the disclosure of the present specification, the claims and the accompanying drawings. The following examples further illustrate aspects of the invention in detail, but are not intended to limit the scope of the invention in any way.

According to an embodiment of the present invention, the mems sensor includes an Application Specific Integrated Circuit (ASIC), a fixed electrode and a movable electrode. Fig. 1 is a schematic perspective view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a first embodiment of the invention. In the present embodiment, the mems sensing apparatus 1 with adjustable induced capacitance includes an asic chip 10 and a sensing device 11.

Application specific integrated circuit chip 10 is designed and manufactured by the requirements of a particular user and the needs of a particular electronic system. ASIC chip 10 includes a top surface 110.

The sensing device 11 includes a fixed electrode 20 and a movable electrode 30. The fixed electrode 20 is disposed on the top surface 110 of the asic chip 10. The fixed electrode 20 includes a plurality of electrode units 210 arranged at intervals. The electrode unit 210 is, for example, a metal conductive pad, and is disposed on the upper surface 110 of the asic chip 10. The number of electrode units 210 shown in fig. 1 is not intended to limit the present invention.

The movable electrode 30 is movable relative to the fixed electrode 20. In detail, the movable electrode 30 includes a fixed portion 310 and a movable portion 320 connected to each other. The fixed portion 310 is disposed on the upper surface 110 of the asic chip 10, and the movable portion 320 corresponds to the electrode unit 210. One end of the movable portion 320 of the movable electrode 30 is connected to the fixed portion 310, and the other end of the movable portion 320 is suspended. When an external force is applied to the movable electrode 30 to deform the movable portion 320, the suspended end of the movable portion 320 can move close to or away from the electrode unit 210 relative to the fixed electrode 20, so that the distance between the suspended end of the movable portion 320 and the electrode unit 210 is changed, and the induced capacitance value of the mems sensing device 1 with adjustable induced capacitance value can be changed.

Please refer to fig. 2, which is a schematic diagram illustrating an electrical connection relationship between the asic chip and the electrode unit in the mems sensing apparatus of fig. 1. In the present embodiment, the asic chip 10 further includes a reading circuit 120 and a plurality of electrical switches 130. The number of the electrical switches 130 corresponds to the number of the electrode units 210.

The reading circuit 120 is electrically coupled to the electrode unit 210 of the fixed electrode 20, so as to read the potential difference between the fixed electrode 20 and the movable electrode 30, and further determine the capacitance of the capacitive sensor 1.

The electrical switches 130 are electrically coupled to the electrode units 210 of the fixed electrode 20, respectively, and the electrical switches 130 are used for controlling a working state of the corresponding electrode units 210. In one embodiment, the electrical switch 130 is a capacitive sensing switch. In another embodiment, the electrical switch 130 is a resettable fuse switch.

The operation states of the electrode unit 210 include an On state (On state) and an Off state (Off state). When the electrical switch 130 of the asic chip 10 is turned on to supply charges to the electrode unit 210, the operating state of the electrode unit 210 can be defined as an on state. In the on state, a potential difference exists between the fixed electrode 20 and the movable electrode 30. In contrast, when the electrical switch 130 does not supply the electrical charge to the electrode unit 210, the operating state of the electrode unit 210 can be defined as an off state. In the off state, there is no potential difference between the fixed electrode 20 and the movable electrode 30.

The specific manner in which the electrical switch 130 controls the operation state of the electrode unit 210 is not intended to limit the present invention. For example, the user can manually adjust whether the electrical switch 130 is turned on to supply the electrical charge to the electrode unit 210, or the asic chip 10 can determine whether the electrical switch 130 is turned on to supply the electrical charge to the electrode unit 210 in an automatic control manner according to an operation command in an external register (not shown).

The following describes a way of detecting a physical quantity change by using the micro-electromechanical sensing device 1 with adjustable sensing capacitance. Please refer to fig. 3 and 4. Fig. 3 is a schematic diagram of the operating state of the electrode unit of the micro electromechanical sensing apparatus capable of adjusting the sensing capacitance of fig. 1 when detecting a small physical quantity change. Fig. 4 is a schematic diagram of the operating state of the electrode unit of the micro-electromechanical sensing device capable of adjusting the sensing capacitance value of fig. 1 when detecting a large physical quantity change. In fig. 3 and 4, the blackened electrode unit 210 is in the off state, and the non-blackened electrode unit 210 is in the on state.

According to an embodiment of the present invention, each electrical switch 130 controls each electrode unit 210 of the fixed electrode 20. Further, the electrode units 210 of the fixed electrodes 20 are arranged on the upper surface 110 of the ASIC chip 10 to form an electrode array. The electrode units 210 further include a plurality of electrode combinations according to the working state of each electrode unit 210 in the electrode array. Fig. 3 and 4 illustrate 4 rows by 4 columns of electrode arrays, but the number of rows and columns of electrode arrays is not intended to limit the present invention.

FIG. 3 illustrates a plurality of electrode assemblies 21, 22, 23, and 24 formed by the electrode unit 210. In this embodiment, each electrode assembly 21, 22, 23, 24 includes a plurality of electrode units 210 arranged along the Y-axis direction. By the control of the asic chip 10, the plurality of electrical switches 130 can form an electrical path to supply charges to each electrode unit 210 of the electrode assemblies 21, 22, 23, so that the working state of each electrode unit 210 of the electrode assemblies 21, 22, 23 is in an on state. Meanwhile, the asic chip 10 can make each of the plurality of electrical switches 130 electrically open, and cannot supply charges to each electrode unit 210 in the electrode assembly 24, so that the working state of each electrode unit 210 in the electrode assembly 24 is in an off state.

FIG. 4 illustrates a plurality of electrode assemblies 25, 26, 27, and 28 formed by the electrode unit 210. Similarly, under the control of the asic chip 10, the plurality of electrical switches 130 can be turned on to supply charges to each electrode unit 210 of the electrode assembly 25, so that the working state of each electrode unit 210 of the electrode assembly 25 is turned on. Meanwhile, the asic chip 10 can make the plurality of electrical switches 130 non-conductive and unable to supply charges to each electrode unit 210 of the electrode assemblies 26, 27, 28, so that the working state of each electrode unit 210 of the electrode assemblies 26, 27, 28 is in an off state.

The implementation state of the electrode assembly formed by the electrode unit 210 is not limited to the states shown in fig. 3 and 4. In another embodiment, all electrode units 210 in two adjacent electrode combinations are in the on state, and all electrode units 210 in the other two adjacent electrode combinations are in the off state. In yet another embodiment, all of the electrode units 210 may be in the on state.

As described above, some of the electrical switches 130 of the asic chip 10 are controlled to form electrical paths for supplying charges to some of the electrode units 210, respectively. The other part of the electrical switches 130 are respectively controlled to form an electrical open circuit, and the electrical charges cannot be supplied to the other part of the electrode units 210. By controlling the working state of the electrode unit 210 or the electrode assembly, the sensing capacitance of the mems sensing device 1 can be changed. Thus, the micro-electromechanical sensing device 1 with adjustable sensing capacitance can be applied to detect different physical quantities, and prevent the asic chip 10 from reading an excessive sensing capacitance and failing.

Hereinafter, the application of the mems sensing apparatus 1 with an adjustable sensing capacitance value to detect pressure is described in more detail, but the application is not limited to the physical quantity that can be detected by the mems sensing apparatus 1 with an adjustable sensing capacitance value. The micro-electromechanical sensing device 1 with adjustable sensing capacitance can also detect physical quantities such as displacement, acceleration, vibration, air pressure and the like.

The micro-electromechanical sensing device 1 with adjustable sensing capacitance is used to detect small pressure variations (e.g. 100-1000 Pa pressure difference). When a pressure is applied to the movable electrode 30 of the micro-electromechanical sensing device 1, the sensing capacitance of which can be adjusted, the movable portion 320 deforms, so that the distance between the movable portion 320 and the electrode unit 210 changes. Since the pressure applied to the movable electrode 30 is small, the change in the distance between the movable portion 320 and the electrode unit 210 is also small. At this time, the mems sensing apparatus 1 with adjustable sensing capacitance needs to have a larger sensitivity so that the reading circuit 120 of the asic chip 10 can successfully obtain a larger sensing capacitance. As shown in fig. 3, the three sets of electrical switches 130 respectively control the working states of the electrode units 210 in the corresponding three electrode assemblies 21, 22, and 23, so that the electrode units 210 are in the on states. Simultaneously, another set of electrical switches 130 controls the electrode units 210 in the corresponding electrode assembly 24, so that the electrode units 210 are in the off state. When measuring a small pressure change, the micro-electromechanical sensing device 1 with adjustable sensing capacitance generates a higher sensing capacitance value because most of the electrode units 210 are in the on state. In this case, the distance between the movable portion 320 and the electrode unit 210 needs only a small change to generate a significant potential difference change to some extent. In this way, the micro-electromechanical sensing device 1 with adjustable sensing capacitance in fig. 3, in which most of the electrode units 210 are in the on state, is suitable for detecting a slight pressure change.

However, the adjustable sensing capacitance of the MEMS sensing device 1 of FIG. 3 is not suitable for detecting large pressure variations (e.g., 10)⁵Pressure difference above pascal). When a large pressure is applied to the movable electrode 30, the sensing capacitance value generated by the micro-electromechanical sensing device 1 with adjustable sensing capacitance value is too large, which may cause the reading circuit 120 to fail. At this time, the sensing capacitance of the micro-electromechanical sensing device 1 with adjustable sensing capacitance needs to be adjusted by changing the operating state of the electrode unit 210.

As shown in fig. 4, a set of electrical switches 130 controls the working states of the electrode units 210 in the corresponding electrode assembly 25, so that the electrode units 210 are in the on state. Simultaneously, the other three sets of electrical switches 130 control the electrode units 210 in the corresponding electrode assemblies 26, 27, 28 to remain in the closed state. Since only a few of the electrode units 210 are on due to the supplied charges, the micro-electromechanical sensing device 1 with adjustable sensing capacitance has a lower sensing capacitance. At this time, even if the distance between the movable portion 320 and the electrode unit 210 is greatly changed, the capacitance change (the induced capacitance value) generated by the change is not too large, and the reading circuit 120 is prevented from being out of order. In this way, the mems sensor 1 in fig. 4 with most of the electrode units 210 in the closed state is suitable for detecting large pressure variations.

In summary, the plurality of electrical switches 130 respectively control the operating states of the plurality of electrode units 210, so as to adjust the magnitude of the sensing capacitance value of the micro-electromechanical sensing device 1 capable of adjusting the sensing capacitance value, and further enable a user or a control system to increase or decrease the sensing capacitance value of the micro-electromechanical sensing device 1 capable of adjusting the sensing capacitance value according to the variation degree of the physical quantity to be detected. When a small amount of physical quantity change is to be detected, the sensing capacitance value of the mems sensing device 1 with adjustable sensing capacitance value is increased by turning on the plurality of electrode units 210, so that the capacitance change between the fixed electrode 20 and the movable electrode 30 can be successfully read when the physical quantity change is small. When a large physical quantity change needs to be detected, a small number of electrode units 210 are turned on to reduce the sensing capacitance value of the mems sensing apparatus 1 capable of adjusting the sensing capacitance value, thereby avoiding the damage of the reading circuit 120 due to the large physical quantity change.

Other aspects of the MEMS sensor of the present invention are disclosed below. FIG. 5 is a schematic perspective view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a second embodiment of the invention. FIG. 6 is a top view of the MEMS sensing device with adjustable sensing capacitance of FIG. 5. In the present embodiment, the micro-electromechanical sensing device 1a capable of adjusting the induced capacitance value includes an asic chip 10 and a sensing element 11 a. For further explanation of the asic chip 10, please refer to the first embodiment, which is not repeated below.

The ASIC chip 10 includes a top surface 110, a read circuit, and a plurality of electrical switches. The sensing element 11a includes a fixed electrode 20a and a movable electrode 30 a. The fixed electrode 20a includes a plurality of first electrode units 210a disposed at intervals and a plurality of second electrode units 220a disposed at intervals.

The first electrode unit 210a and the second electrode unit 220a are disposed on the top surface 110 of the asic chip 10. The reading circuit is electrically coupled to the first electrode unit 210a and the second electrode unit 220a, so as to read a potential difference between the fixed electrode 20a and the movable electrode 30 a. One part of the electrical switches is electrically coupled to the first electrode units 210a, and the other part of the electrical switches is electrically coupled to the second electrode units 220 a. The electrical switch is used to control the working state of the corresponding first electrode unit 210a or the second electrode unit 220 a. The number of the first electrode units 210a and the second electrode units 220a is not intended to limit the present invention.

The movable electrode 30a includes a fixed portion 310a, a movable portion 320a and a flexible portion 330a connected together. The fixed portion 310a is disposed on the upper surface 110 of the asic chip 10, and the movable portion 320a is connected to the fixed portion 310a via the flexible portion 330 a. The first electrode unit 210a and the second electrode unit 220a are located on opposite sides of the movable portion 320a, respectively. The movable electrode 30a is movable relative to the fixed electrode 20a along a direction perpendicular to the normal of the upper surface 110.

In the present embodiment, the arrangement of the fixed electrode 20a and the movable electrode 30a constitutes a comb-shaped electrode structure. As shown in fig. 6, each first electrode unit 210a includes a plurality of first comb-shaped teeth 211a, and each second electrode unit 220a includes a plurality of second comb-shaped teeth 221 a. The movable portion 320a of the movable electrode 30a includes a plurality of third comb teeth 321 a. When the movable portion 320a moves relative to the fixed electrode 20a, the capacitance of the micro-electromechanical sensing device 1a with adjustable sensing capacitance can be changed. The working states of the first electrode unit 210a and the second electrode unit 220a are controlled by the asic chip 10, so that the sensing capacitance of the mems sensing device 1a can be increased or decreased according to the variation of the physical quantity to be detected.

FIG. 7 is a schematic cross-sectional view of a micro-electromechanical sensing device with an adjustable sensing capacitance according to a third embodiment of the present invention. In the present embodiment, the micro-electromechanical sensing device 1b capable of adjusting the induced capacitance value comprises an asic chip 10 and a sensing element 11 b. For further explanation of the asic chip 10, please refer to the first embodiment, which is not repeated below.

The ASIC chip 10 includes a top surface 110, a read circuit, and a plurality of electrical switches. The sensing element 11b includes a fixed electrode 20 and a movable electrode 30b, and the fixed electrode 20 includes a plurality of electrode units 210 disposed at intervals.

The electrode unit 210 is disposed on the top surface 110 of the asic chip 10. The reading circuit is electrically coupled to the electrode unit 210 so as to read the potential difference between the fixed electrode 20 and the movable electrode 30 b. The electrical switches are electrically coupled to the electrode units 210, respectively, for controlling the working states of the corresponding electrode units 210.

The fixed portion 310b of the movable electrode 30b surrounds the electrode unit 210 of the fixed electrode 20. The movable portion 320b of the movable electrode 30b is suspended above the electrode unit 210. The movable electrode 30b is bonded to the asic chip 10 to form an airtight space, and the electrode unit 210 is accommodated in the airtight space. Thereby, it is helpful to prevent the electrode unit 210 from being contaminated with dust due to exposure to the air.

In the present embodiment, the micro-electromechanical sensing device 1b with adjustable induced capacitance is suitable for an altimeter. When the micro-electromechanical sensing device 1b with adjustable sensing capacitance is used for measuring height variation, most of the working states of the electrode units 210 can be turned on by using the electrical switch. Thus, when the atmospheric pressure generates a small pressure change due to the height change, the micro electro mechanical system sensing device 1b capable of adjusting the sensing capacitance value generates a large sensing capacitance, so that the asic chip 10 can accurately calculate the height change.

In the present embodiment, the micro-electromechanical sensing device 1b with adjustable sensing capacitance is also suitable for a barometer. When the micro-electromechanical sensing device 1b with adjustable sensing capacitance is applied to measure high-pressure gas, most of the electrode units 210 can be turned off by using the electrical switch. Thus, when the barometer measures the high pressure gas in the container, the mems sensing device 1b with adjustable sensing capacitance will not generate too large sensing capacitance, and the asic chip 10 will not fail.

Please refer to fig. 8 and fig. 9 together. Fig. 8 is a schematic cross-sectional view of a micro-electromechanical sensing device with an adjustable induced capacitance value according to a fourth embodiment of the invention. FIG. 9 is a cross-sectional view of the MEMS sensing device with adjustable sensing capacitance of FIG. 8. In the present embodiment, the micro-electromechanical sensing device 1c capable of adjusting the induced capacitance value includes an asic chip 10 and a sensing element 11 c. For further explanation of the asic chip 10, please refer to the first embodiment, which is not repeated below.

The ASIC chip 10 includes a top surface 110, a read circuit, and a plurality of electrical switches. The sensing element 11c includes a fixed electrode 20c and a movable electrode 30 c.

The fixed electrode 20c includes a central electrode unit 210c and a plurality of ring electrode units 220c, and the ring electrode units 220c surround the central electrode unit 210 c. Specifically, the ring electrode units 220c and the central electrode unit 210c are concentrically arranged. The central electrode unit 210c and the ring electrode unit 220c are disposed on the top surface 110 of the asic chip 10. The reading circuit is electrically coupled to the central electrode unit 210c and the ring electrode unit 220c for reading the potential difference between the fixed electrode 20c and the movable electrode 30 c. One of the electrical switches is electrically coupled to the central electrode unit 210c, and the other electrical switches are electrically coupled to the ring electrode units 220c, respectively. The electrical switch is used to control the working state of the corresponding central electrode unit 210c or the ring electrode unit 220 c. The number of ring electrode units 220c is not intended to limit the present invention.

The fixed portion 310c of the movable electrode 30c surrounds the central electrode unit 210c and the ring electrode unit 220c of the fixed electrode 20c, and the movable portion 320c of the movable electrode 30c is suspended above the central electrode unit 210c and the ring electrode unit 220 c.

Please refer to fig. 10 and 11 together. FIG. 10 is a schematic perspective view of a micro-electromechanical sensing device capable of adjusting an induced capacitance value according to a fifth embodiment of the invention. FIG. 11 is a schematic diagram of an electrical connection relationship between an ASIC chip and an electrode unit in the MEMS sensing device with adjustable sensing capacitance of FIG. 10.

In the present embodiment, the micro-electromechanical sensing device 1d capable of adjusting the induced capacitance value includes a substrate 2d, an asic chip 10d, a first sensing element 11d and a second sensing element 11 e.

The substrate 2d is, for example, a silicon substrate, and has an upper surface 21. The ASIC chip 10d, the first sensing device 11d and the second sensing device 11e are all disposed on the upper surface 21 of the substrate 2 d.

The first sensing element 11d includes a first fixed electrode 20d and a first movable electrode 30 d. The first fixed electrode 20d includes a plurality of first electrode units 210d arranged at intervals. The first movable electrode 30d includes a first fixed portion 310d and a first movable portion 320 d. The first fixed portion 310d is disposed on the substrate 2d and surrounds the first electrode units 210d, and the first movable portion 320d is suspended above the first electrode units 210 d. The first movable electrode 30d is bonded to the asic chip 10d to form an airtight space, and the first electrode unit 210d is accommodated in the airtight space. When an external force is applied to the first movable electrode 30d to deform the first movable portion 320d, the first movable portion 320d can move relative to the first fixed electrode 20d, so that the distance between the first movable portion 320d and the first electrode unit 210d changes, and further the capacitance value between the first fixed electrode 20d and the first movable electrode 30d changes.

The second sensing element 11e includes a second fixed electrode 20e and a second movable electrode 30 e. The second fixed electrode 20e includes a plurality of second electrode units 210e arranged at intervals. The second movable electrode 30e includes a plurality of second fixed portions 310e and a second movable portion 320 e. The plurality of second fixed portions 310e are disposed on the substrate 2d, and the second movable portion 320e is interposed between the plurality of second fixed portions 310 e. The second movable portion 320e includes a movable mass 321e and a plurality of elastic elements 322 e. The movable mass 321e is connected to the second fixing portions 310e via elastic members 322e, and the movable mass 321e is suspended above the second electrode unit 210 e. The movable mass 321e can move relative to the second fixed electrode 20e to change the value of the capacitance between the second fixed electrode 20e and the second movable electrode 30 e.

The ASIC chip 10d includes a read circuit 120d, a plurality of first electrical switches 130d, and a plurality of second electrical switches 130 e. The number of the first electrical switches 130d corresponds to the number of the first electrode units 210d, and the number of the second electrical switches 130e corresponds to the number of the second electrode units 210 e. The reading circuit 120d is electrically coupled to the first electrode unit 210d, so as to read the potential difference between the first fixed electrode 20d and the first movable electrode 30d, and further determine the capacitance of the first sensing element 11 d. In addition, the reading circuit 120d is also electrically coupled to the second electrode unit 210e, so as to read the potential difference between the second fixed electrode 20e and the second movable electrode 30e, and further confirm the capacitance of the second sensing element 11 e.

The first electrical switches 130d are electrically coupled to the first electrode units 210d, respectively, and the first electrical switches 130d are used for controlling the working states of the corresponding first electrode units 210 d. In addition, the second electrical switches 130e are electrically coupled to the second electrode units 210e, respectively, and the second electrical switches 130e are used for controlling the working states of the corresponding second electrode units 210 e.

The working states of the first electrode unit 210d and the second electrode unit 210e include an on state and an off state. When the first electrical switch 130d of the ASIC 10d is turned on to supply charges to the first electrode unit 210d, the operating state of the first electrode unit 210d can be defined as an ON state. Similarly, when the second electrical switch 130e of the ASIC chip 10d is turned on to supply charges to the second electrode unit 210e, the operating state of the second electrode unit 210e can be defined as an ON state. In the on state, a potential difference exists between the first fixed electrode 20d and the first movable electrode 30d or between the second fixed electrode 20e and the second movable electrode 30 e.

On the contrary, when the first electrical switch 130d does not supply charges to the first electrode unit 210d, the operating state of the first electrode unit 210d is defined as the off state. When the second electrical switch 130e of the ASIC 10d is not supplying charge to the second electrode unit 210e, the operating state of the second electrode unit 210e can be defined as an OFF state. In the off state, there is no potential difference between the first fixed electrode 20d and the first movable electrode 30d or between the second fixed electrode 20e and the second movable electrode 30 e.

In the present embodiment, the first sensing element 11d is used for detecting a first physical quantity, and the second sensing element 11e is used for detecting a second physical quantity different from the first physical quantity. Further, the first sensing element 11d is a barometer, and the second sensing element 11e is an accelerometer.

As shown in fig. 10, the first electrode units 210d are respectively controlled by the first electrical switches 130d, such that the working states of a portion of the first electrode units 210d are in an on state, and the working states of another portion of the first electrode units 210d are in an off state. When the air pressure around the micro-electromechanical sensor 1d increases, the first movable portion 320d deforms, so that the distance between the first movable portion 320d and the first electrode unit 210d changes. The change in the pitch between the first movable portion 320d and the first electrode unit 210d causes a change in the potential difference between the first fixed electrode 20d and the first movable electrode 30 d.

In addition, the second electrode units 210e are respectively controlled by the second electrical switches 130e, such that the working states of a portion of the second electrode units 210e are in an on state, and the working states of another portion of the second electrode units 210e are in an off state. When the acceleration of the carrier (e.g., an automobile) carrying the micro-electromechanical sensing device 1d with adjustable capacitance varies, the second movable portion 320e moves close to one of the second fixed portions 310e, so that a potential difference between the second fixed electrode 20e and the second movable electrode 30e varies.

In the present embodiment, the area a1 of each first electrode unit 210d is equal to the area a2 of each second electrode unit 210 e. When the first sensing elements 11d and the second sensing elements 11e are simultaneously detecting, the number of the first electrode units 210d in the on state is N1, the number of the second electrode units 210e in the on state is N2, and the following conditions are satisfied: n1> N2. In this way, when the first sensing element 11d detects a small air pressure change and the second sensing element 11e detects an acceleration change, the second sensing element 11e does not generate an excessive sensing capacitance, thereby helping to prevent the asic chip 10d from failing. In another embodiment, when the first sensing element 11d detects a larger change of the first physical quantity and the second sensing element 11e detects a smaller change of the second physical quantity, the area of each first electrode unit 210d is equal to the area of each second electrode unit 210e, and the number (N1) of the first electrode units 210d in the on state is smaller than the number (N2) of the second electrode units 210e in the on state.

In another embodiment, when the first sensing element 11d and the second sensing element 11e are simultaneously detecting, the sum of the areas of the plurality of first electrode units 210d in the on state is TA1, and the sum of the areas of the plurality of second electrode units 210e in the on state is TA2, and the following conditions are satisfied: TA1> TA 2. In this way, when the first sensing element 11d detects a small air pressure change and the second sensing element 11e detects an acceleration change, the second sensing element 11e does not generate an excessive sensing capacitance, thereby helping to prevent the asic chip 10d from failing.

In another embodiment, when the first sensing element 11d detects a larger change of the first physical quantity and the second sensing element 11e detects a smaller change of the second physical quantity, the sum of the areas (TA1) of the plurality of first electrode units 210d in the on state can be smaller than the sum of the areas (TA2) of the plurality of second electrode units 210e in the on state.

In summary, in the mems sensing apparatus with an adjustable sensing capacitance disclosed in the present invention, the plurality of electrical switches are electrically coupled to the plurality of electrode units respectively to control the operating states of the electrode units. By independently controlling the working states of the electrode units, the value of the induction capacitance of the micro-electromechanical sensor can be adjusted, so that the change degree of the physical quantity to be detected can be accurately measured, and the failure of the special application integrated circuit chip can be prevented. When a small amount of physical quantity change is detected, a plurality of electrode units are in an on state (i.e., the electrical switch is turned on to supply charges to the electrode units). When a large physical quantity change needs to be detected, a small number of electrode units can be in an open state to reduce the induction capacitance value of the micro-electromechanical sensor, and further, the failure of a reading circuit in the special application integrated circuit chip is avoided.