JP3341214B2 - Detection device for semiconductor acceleration sensor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a detecting device for a capacitance type semiconductor acceleration sensor.

[0002]

2. Description of the Related Art A conventional capacitance type semiconductor acceleration sensor is, for example, as shown in FIG. In the illustrated example, a so-called differential type is formed, in which a weight portion 3 is integrally formed at a center of a silicon plate 1 as a semiconductor substrate with a beam portion 2 interposed therebetween. The glass plate 4 is arranged at the bottom. At this time, a predetermined gap is formed between the upper and lower surfaces of the weight portion 3 and the opposing surface of the glass plate 4 to allow the weight portion 3 to swing. The upper and lower surfaces of the weight portion 3 are first and second movable electrodes 5 and 6, and the first and second fixed portions are formed at predetermined positions on the inner surface of the glass plate 4 facing the movable electrodes 5 and 6 by aluminum vapor deposition or the like. The electrodes 7 and 8 are formed.

Incidentally, the first movable electrode 5 and the first
A capacitance C1 is generated between the second movable electrode 6 and the second fixed electrode 8, and a capacitance C2 is generated between the second movable electrode 6 and the second fixed electrode 8. When acceleration is applied to this sensor, the beam 2 bends, and the distance between the opposing electrodes 5, 7, 6, and 8 changes, and the change in the distance also changes the above-mentioned capacitances C1, C2. . At this time, the acceleration is determined by detecting the difference ΔC (ΔC = C1−C2) between the capacities in the amphoteric.

With such a configuration (differential type),
Since the temperature characteristics and the parasitic capacitances of the first and second capacitances C1 and C2 are subtracted from each other and canceled, the characteristics are improved. Further, the linearity of the output (the difference ΔC in capacitance) with respect to the change in acceleration is improved for the following reason. That is, the upper electrode area (the area where the first movable electrode and the fixed electrode overlap, usually equal to each other or equal to the size of the first movable electrode 5 in order to enlarge the fixed electrode side) is S1. , The lower electrode area (equal to the size of the second movable electrode 6 for the same reason) is S2, and the distance between the opposing electrodes is d1,
d2. In this state, acceleration is applied and the weight 3
The capacitances C1 and C2 when displaced by (the downward movement is defined as positive for convenience) are as follows: C1 = εS1 / (d1 + x) (1) C2 = εS2 / (d2-x) (2) The capacitance difference ΔC is expressed as follows: ΔC = εS1 / (d1 + x) −εS2 / (d2-x) (3) In view of the characteristics, it is preferable to form the shape vertically symmetrically. Therefore, when S1 = S2 and d1 = d2, the change in the capacitance with respect to the acceleration and the change in the difference are shown in FIG.
It is shown in FIG. Note that the displacement x is proportional to the magnitude of the acceleration. As is clear from the figure, near the acceleration 0G, ΔC has better linearity than that of C1 and C2 alone.

[0005]

However, the above-mentioned conventional differential type acceleration sensor has the following problems. That is, the beam portion 2 and the weight portion 3 are formed by performing anisotropic etching on a flat silicon substrate and removing a predetermined portion of the substrate. It is controlled by the etching time,
Since the thickness of the silicon wafer to be processed is different, the thickness of the manufactured beam portion 2 also varies. Then, the rigidity (elastic coefficient) and the like of the beam portion 2 also vary, and the sensitivity of the sensor varies.

In addition, when detecting acceleration in the vertical direction (the same direction as the direction of gravitational acceleration), in a steady state,
Since the gravitational acceleration (1 G) is constantly applied to the weight portion 3, the weight portion 3 is actually displaced below the state shown in FIG. 10, that is, displaced by a predetermined distance x. Therefore, the lower distance d2 is shorter than the upper distance d1, and the capacitance changes around the point Q in the characteristic diagram shown in FIG. As a result, the linearity decreases.

Further, all of the conventional acceleration sensors detect a change in capacitance as a change in frequency. For example, such an acceleration sensor controls the operation of an active suspension of an automobile, an airbag system, or the like. In the case where it is used for a detecting unit for detecting the acceleration, a sufficient response cannot be obtained by the acceleration detection using such a frequency.

The present invention has been made in view of the above background, and an object of the present invention is to provide a detection device for a semiconductor acceleration sensor having good linearity with respect to a change in acceleration.

[0009]

In order to achieve the above object, a detection device for a semiconductor acceleration sensor according to the present invention comprises at least two sets of movable electrodes and fixed electrodes,
As a detection device of a differential type semiconductor acceleration sensor for detecting the generated acceleration from the difference between the respective capacitances generated between the two electrodes, a predetermined oscillation signal is inputted to each of the electrically connected movable electrodes. An oscillator circuit connected to each of the fixed electrodes, and means for obtaining an output according to acceleration by subtracting each PWM signal obtained by differentiating the given oscillation signal with each of the capacitances. With.

[0010] Further, as another detection device, a means connected to each of the fixed electrodes and alternately applying a predetermined voltage between each pair of electrodes ; Connected to a differential amplifier circuit having a feedback resistor, and synchronized with the operation timing of the means for applying the voltage.
And input means for simultaneously inputting the electric charge stored in each capacitance by the means for applying the voltage to the differential amplifier circuit, wherein the differential amplifier circuit May be converted into a voltage to obtain an output voltage corresponding to the acceleration. In addition, if the detection device of the present invention is used, the difference between the respective capacitances can be extracted as a DC component, and acceleration with good responsiveness is detected.

As an example of a semiconductor acceleration sensor connected to the detection device of the present invention, a movable electrode is integrally connected to a frame via a beam portion, and movable electrodes are provided on both surfaces of a weight portion displaced in accordance with acceleration. A semiconductor plate formed, comprising a fixed electrode opposed to the two movable electrodes with a predetermined gap therebetween, and a substrate such as a glass plate disposed so as to sandwich the semiconductor plate; A semiconductor acceleration sensor for detecting acceleration from a difference in capacitance generated between the movable electrode and the fixed electrode forming a pair, wherein the semiconductor plate has an n-layer and a p-layer arranged at predetermined positions. A layer may be provided, and a boundary surface between the two layers may be located on a surface of the beam portion that displaceably supports the weight portion and an extension thereof.

Since the p-layer and the n-layer are provided at predetermined positions on the semiconductor substrate on which the movable electrode is to be formed, when electrochemical etching is performed from one side (for example, the p-layer), the etched portion of the p-layer is removed until reaching the n-layer. Is done. Thus, for example, n
By forming the beam portion with the layer portions, the thickness of the beam portion is accurately controlled.

The distance between the movable electrode formed on one surface of the weight portion and the fixed electrode facing the movable electrode and the electrode area thereof, and the distance between the movable electrode formed on the other surface of the weight portion and The distance between the electrode and the fixed electrode facing the electrode is set so that both capacitances generated between the paired electrodes are substantially equal in a reference state where no acceleration of the detection target is applied. Can also.

Then, in the reference state (in the case where the gravitational acceleration is applied and the weight (movable electrode) is displaced by a predetermined amount,
If the respective capacitances are set to be substantially equal after the displacement (in a state in which other than gravitational acceleration is not applied), the linearity of the difference (sensor output) between the respective capacitances is good. Thus, a highly sensitive sensor is obtained.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a detecting device for a semiconductor acceleration sensor according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 shows an example of an acceleration sensor using the detection device of the present invention. As shown, the basic configuration,
That is, glass plates 11 are arranged on both upper and lower sides of a silicon plate 10 which is a semiconductor plate, and this silicon plate 10 is attached to a square frame 12 with a plurality of weights 1 via a plurality of beams 13.
4 is connected in a cantilevered manner. Then, the upper and lower surfaces of the weight portion 14 are first and second movable electrodes 15,
The first and second fixed electrodes 17 and 16 are formed on the surface of the glass plate 11 facing the electrodes 15 and 16 by aluminum evaporation or the like.
The point of forming 18 is the same as the conventional one.

Here, in the present invention, an n-layer (diffusion layer) 10a is formed at a predetermined intermediate position of the silicon plate 10 formed on the basis of P-type silicon, for example, by doping. And this n layer is comprised so that the upper part of the beam part 13 and the weight part 14 following it may be comprised.

In order to manufacture a sensor (silicon plate) having such a configuration, a predetermined portion of the plate-like silicon plate on which the n-layer 10a is formed is electrochemically etched from below. Then, the P-type silicon is removed until it reaches the n-layer 10a. Therefore, the thickness of the beam portion 13 is n layer 1
0a, and the thickness can be controlled easily and precisely by the diffusion depth of the n-layer 10a, so that variations in performance (sensitivity) among the manufactured sensors can be suppressed as much as possible. .

In this embodiment, since the electrochemical etching is performed from the lower side, the area S1 of the first movable electrode 15 is larger than the area S2 of the second movable electrode 16,
Accordingly, the areas of the corresponding fixed electrodes are also made different (substantially equal to the area of the paired movable electrodes). However, as shown in FIG. . Furthermore, instead of providing an n-diffusion layer at a predetermined portion of P-type silicon as described above, a plate-like (consisting of substantially the same planar shape) P-type silicon and N-type silicon are stacked and arranged in layers. (In such a case, N-type and P-type silicon are located all around the frame 12 as well).

Further, in this embodiment, since the areas of the upper and lower electrodes are different as described above, if the distances d1 and d2 between each pair of electrodes are equal, the linearity of the output with respect to the change in acceleration is reduced. Further, as shown in FIG. 2, when the beam portion 13 and the weight portion 14 are arranged to be in a horizontal state in order to detect the acceleration in the vertical direction, gravitational acceleration is constantly applied to the weight portion 14, and the acceleration to be detected is determined. As shown in the drawing, the weight moves downward even if there is no, and even if d1 = d2 is set in the state shown in FIG. 1, d1> d2 in an actual use situation.

In such a case, in order to improve the linearity, the relationship between the areas S1 and S2 and the distances d1 and d2 is set as follows. That is, a predetermined acceleration is applied from the reference state where the acceleration (excluding the gravitational acceleration that is constantly applied) is not applied (the distance between the paired electrodes is d1 and d2, respectively), and the weight portion is applied. As described above, the output ΔC when 14 is displaced downward by x is ΔC = εS1 / (d1 + x) −εS2 / (d2-x) (3)

Therefore, the condition under which the linearity of the ΔC with respect to the acceleration at this time is the best is that the ΔC in the reference state, that is, when x = 0, becomes the transition point P shown in FIG. More specifically, the second derivative of the above equation (3) becomes zero. Therefore, the second derivative Δ
C ″ is ΔC ″ = k (S1 / (d1 + x) ³ −S2 / (d2-x) ³ ) (4) where k is an arbitrary constant.

The condition for satisfying ΔC ″ = 0 when x = 0 is as follows: d 2 = d 1 (S 2 / S 1) ^1/3 (5) .

Therefore, each value is set so that the above conditional expression (5) is satisfied. That is, since the areas S1 and S2 are determined first in the manufacturing process, the area is substituted into the equation (5) to determine the ratio between d1 and d2. Then, for example, the semiconductor plate 1 shown in FIG.
By removing a predetermined amount of the upper side 10b of the zero by etching or the like, a sensor structure with the best linearity can be obtained. Note that the adjustment for obtaining the optimum structure is not limited to the above, and various methods such as removal of an arbitrary portion can be adopted. In addition, the above-mentioned electrode areas S1 and S2 are actually effective areas, that is, areas where the paired electrodes overlap (when the area of the fixed electrode is small, the area of the fixed electrode).

Further, the linearity is best when the above conditional expression (5) is satisfied, but it is not necessary to exactly satisfy this condition. The setting may be made to have a certain range.

As shown in FIG. 2, the amount of deflection due to the gravitational acceleration is calculated from the weight of the weight portion 14 and the elastic coefficient of the beam portion 13 to determine how much displacement from the horizontal position is obtained. When doing so, consider the amount of displacement,
It is necessary to make adjustments such as adding to d1 and d2 obtained by the above conditional expressions.

FIG. 3 shows a first embodiment of the detecting device according to the present invention. As shown in the drawing, the capacitance C generated between two pairs of electrodes of the acceleration sensor in the above-described embodiment.
1 and C2 and the two resistors R1 and R2 form a bridge circuit. The connection side of the two capacitances C1 and C2 is configured by connecting the wirings connected to the first and second movable electrodes 15 and 16 formed on the silicon plate 10, for example. The oscillation circuit 20 is connected to the electrodes 15 and 16
Is applied.

As a connection structure of the two electrodes 15 and 16, for example, as shown in FIG. 4, the second movable electrode 16 is formed by applying aluminum vapor deposition 19 on the lower surface side of the weight portion 14. The end 19a of the aluminum deposition is connected to the n-layer 10
By connecting to a, the movable electrodes 15 and 16 have the same potential, and wiring can be easily drawn out.

Further, the other ends of the capacitances C1 and C2 (the wirings of the fixed electrodes 17 and 18 in this example) are connected to a differential amplifier circuit 23 via Schmitt circuits 21a and 21b and rectifier circuits 22a and 22b. .

Next, the operation principle of the above embodiment will be described with reference to a timing chart shown in FIG.
First, a rectangular wave having a period T is output from the oscillation circuit 20 ((A) in the figure), and is differentiated by the capacitances C1 and C2 ((B) in the figure). Then, a rectangular wave is created by inputting the differentiated signal to the Schmitt circuits 21a and 21b (FIG. 3C). And the pulse width t of this rectangular wave
Is proportional to the time constants C1R1 and C2R2 (PWM
signal).

Next, the rectangular waves are converted into rectifier circuits 22a and 22a.
2b, where a DC signal corresponding to the pulse width t, that is, the capacitances C1 and C2 is obtained (FIG. 3D). These two DC signals are converted to a differential amplifier circuit 2
3, the circuit 23 outputs a DC signal proportional to ΔC. In the example shown in the figure, each waveform has the same shape because C1 = C2. However, if the acceleration is applied and the capacitance changes,
The duty ratio of each waveform changes as appropriate.

With this configuration, the difference (ΔC) between the two capacitances can be viewed as the magnitude (change) of the DC signal with the magnitude (change) of the acceleration, and the response is good. Is mounted on the airbag system, an operation signal is issued when the output of the differential amplifier circuit 23 exceeds a certain threshold (for example, the output of the circuit and the above-mentioned threshold are easily inputted by comparison). Can be configured).

FIG. 6 shows an example of a specific circuit configuration of this embodiment. In this example, the output is 2.5 V in the reference state.
It has been adjusted to be. In the present embodiment, a DC signal is output. However, for example, when a DC signal is not necessary in a subsequent device or the like, the Schmitt circuit 21 is output.
By taking out the PWM signals from a and 21b, digital processing becomes possible.

The detection device according to the present invention can be applied not only to the output detection of the acceleration sensor according to the present invention described above but also to various types of conventional differential acceleration sensors in addition to those shown in FIG. (The same applies hereinafter).

FIG. 7 shows a second embodiment of the detecting device according to the present invention. As shown in the figure, first, the first and second fixed electrodes 17 and 18 of the semiconductor acceleration sensor are
A DC voltage (Vin) is applied through the second analog switches 30a and 30b. Further, the first and second movable electrodes 1 electrically connected to each other to form a common electrode
5 and 16, via a third analog switch 31,
It is connected to the inverting input terminal of an operational amplifier 32 which is a differential amplifier.

Then, the first and second analog switches 3
The operation timings φ1 and φ2 of 0a and 30b are as shown in FIG. 8, and the operation timing of the third analog switch 31 coincides with that of the second analog switch 30b. With this configuration, a switch and a capacitor circuit are formed, and the capacitance C
It can be detected as a differential output (voltage) corresponding to the difference (ΔC) between 1 and C2.

FIG. 9 shows a third embodiment of the detection apparatus according to the present invention. The structure of the third embodiment is substantially the same as that of the above-described second embodiment. , 18
Are different from each other. Since other configurations and operations are the same as those of the above-described second embodiment, the same reference numerals are given and the description thereof is omitted.

Predetermined charges Q1 and Q2 are stored in the capacitances C1 and C2 in the acceleration sensor to which the voltages V1 and V2 are applied.
Is output as an output voltage Vout as shown in the following equation via the operational amplifier 32 (note that if V1 = V2 in the following equation (6), the output voltage becomes the output voltage in the second embodiment). Vout = α (Q1-Q2) = αε (S1 * V1 / (d1 + x) + S2 * V2 / (d2-x)) (6) where α is a constant determined by a circuit constant

The condition at which the linearity of the Vout with respect to the acceleration at this time is the best is that the Vout is located at the inflection point P shown in FIG. 11 in the reference state (x = 0) as described above. When the second derivative (Vout ″) at the time of x = 0 in the above equation (6) is solved as 0, Vout ″ = k (S1 * V1 / (d1 + x) ³ −S2 * V
From 2 / (d2-x) ³ , V2 = V1 * (S1 / S2) * (d2 / d1) (7)

Therefore, by setting the voltages V1 and V2 so as to satisfy the condition of the above equation (7), the linearity with respect to the acceleration can be made the best. That is, even if there is a difference or variation in the electrode area and the distance between the electrodes of the differential type acceleration sensor, the linearity can be improved only by applying a voltage satisfying or close to the above equation (7). A simple acceleration sensor (detection device) can be configured.

In the semiconductor acceleration sensor according to the above-described embodiment, the beam portion is made of a material (n) different from other weight portions, frame members, and the like.
Layer or a p-layer), the beam portion can be composed of only the n-layer (p-layer) by removing unnecessary portions by electrochemical etching or the like. That is,
The thickness of the beam portion is the thickness of the n-layer (p-layer), and can be accurately formed to a predetermined thickness. Therefore, variations in characteristics (sensitivity) are reduced. When the area of each electrode and the distance between the electrodes are set so that the respective capacitances are substantially equal in the reference state, output characteristics with good linearity with respect to changes in acceleration can be obtained.

[0041]

As described above, in the detection device according to the present invention, it is possible to output a DC signal corresponding to the difference between the capacitances, so that the detection is simple and the response is good.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a preferred embodiment of a semiconductor acceleration sensor according to the present invention.

FIG. 2 is a diagram showing an example under a use situation.

FIG. 3 is a diagram showing a first embodiment of a detection device according to the present invention.

FIG. 4 is a block diagram showing an example of connection of first and second movable electrodes.

FIG. 5 is a timing chart of the circuit shown in FIG. 3;

FIG. 6 is a circuit diagram showing a specific configuration of the circuit shown in FIG. 3;

FIG. 7 is a diagram showing a second embodiment of the detection device according to the present invention.

FIG. 8 is a diagram showing the operation timing of the analog switch.

FIG. 9 is a diagram showing a third embodiment of the detection device according to the present invention.

FIG. 10 is a sectional view showing a preferred embodiment of a conventional semiconductor acceleration sensor.

FIG. 11 is a diagram illustrating an example of the characteristics of the capacitance with respect to the acceleration and the difference therebetween.

[Explanation of symbols]

REFERENCE SIGNS LIST 10 silicon plate (semiconductor plate) 10 an n layer 11 glass plate (substrate) 12 frame 13 beam 14 weight 15 first movable electrode 16 second movable electrode 17 first fixed electrode 18 second fixed electrode 20 Oscillator circuits 21a, 21b Schmitt circuits (means for obtaining output according to acceleration) 22a, 22b Rectifier circuits (means for obtaining output according to acceleration) 23 Differential amplifier circuits (means for obtaining output according to acceleration) 30a, 30b First and second analog switches (means for applying a predetermined voltage alternately) 31 Third analog switch (means for inputting to a differential amplifier circuit) 32 Operational amplifier (differential amplifier circuit)

Continuation of the front page (72) Yoshiyuki Morita Inventor 801 Shimogyo-ku, Higashi-Irikawa, Shimogyo-ku, Shimogyo-ku, Kyoto, Japan Omron Corporation (56) References JP-A-4-157369 (JP, A) JP-A Heihei 5-172845 (JP, A) JP-A-6-265417 (JP, A) JP-A-5-333053 (JP, A) JP-A-58-10661 (JP, A) JP-A-62-32372 (JP, A A) Special table Hei 4-504003 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G01P 15/125 H01L 29/84 G01L 9/12 G01R 27/26

Claims (2)

(57) [Claims] 1. A detection device for a differential type semiconductor acceleration sensor comprising at least two sets of movable electrodes and fixed electrodes, and detecting an acceleration based on a difference between respective capacitances generated between the two electrodes. An oscillation circuit for inputting a predetermined oscillation signal to each of the movable electrodes, which are connected to each other; and an oscillation circuit connected to each of the fixed electrodes, obtained by differentiating the given oscillation signal with each of the capacitances. Means for obtaining an output corresponding to acceleration by subtracting each PWM signal. 2. A differential type semiconductor acceleration sensor detecting device comprising at least two sets of movable electrodes and fixed electrodes, and detecting an acceleration from a difference between respective capacitances generated between the two electrodes, Means for applying a predetermined voltage alternately between each pair of electrodes connected to each fixed electrode, the movable electrode electrically connected, and a feedback resistor
A means for connecting the differential amplifier circuit and applying the voltage
Operating in synchronization with the operation timing of the stage, and input means for simultaneously inputting the electric charge stored in each capacitance by the means for applying the voltage to the differential amplifier circuit, wherein the differential amplifier circuit A detecting device for a semiconductor acceleration sensor, wherein an output voltage corresponding to an acceleration is obtained by converting a difference between the respective capacitances into a voltage.