JPH0894664A - Accelerometer - Google Patents

Abstract

PURPOSE: To obtain an accelerometer whose circuit constitution is simplified by a method wherein a capacitor for temperature compensation and a leak resistance are connected in parallel across a piezoelectric ceramic element and a signal processing circuit and a failure self-diagnostic circuit which outputs a signal for self-diagnosis to the ceramic element is provided. CONSTITUTION: An accelerometer is provided with a piezoelectric ceramic element 1, with a signal processing circuit 2 which processes its output signal, with a capacitor 3 for temperature compensation and a leak resistance which are connected in parallel across the element 1 and the processing circuit 2 and with a failure self-diagnostic circuit 20 which outputs a signal for self-diagnosis to the element 1. When a timing pulse signal is outputted, the pulse-shaped signal for self-diagnosis from the side of a collector C for a PNP transistor 12 constituting the diagnostic circuit is voltage- divided by voltage-dividing resistances 21, 22 whose resistance value has been set in advance, and the signal is applied to the element 1. The output signal of the element 1 is processed by the processing circuit 2 so as to be detected as a sensor output through an external terminal 9, and a failure is judged on the basis of a change in the sensor output. As a result, the circuit constitution of the accelerometer can be simplified.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an acceleration sensor incorporated in an in-vehicle airbag device or the like, and more particularly to a circuit configuration thereof.

[0002]

2. Description of the Related Art As an acceleration sensor of this type, as shown in FIG. 3, a piezoelectric ceramic element 1 for detecting acceleration applied due to a collision of an automobile and an output signal from the piezoelectric ceramic element 1. Signal processing circuit 2 for processing
And a temperature compensating capacitor 3 connected in parallel between them.
And a leak resistance 4 and a self-diagnosis circuit 5 that outputs a self-diagnosis signal to the piezoelectric ceramic element 1. One end of each of the piezoelectric ceramic element 1, the temperature compensating capacitor 3 and the leak resistor 4 is connected in series with each other, while the other end of each is connected to the reference voltage Vr. The reference voltage Vr means a ground voltage, for example, a reference voltage set based on the power supply voltage Vcc. Further, the signal processing circuit 2 here is the piezoelectric ceramic element 1
The impedance conversion circuit 6 for impedance-converting the output signal from the input signal, the filter circuit 7 for removing unnecessary components in the output signal, and the amplification circuit 8 for amplifying only the necessary components are included in the amplification circuit 8. An external output terminal 9 that outputs a sensor output is provided.

Further, at this time, a filter resistor 10 is connected in series on the side of the impedance conversion circuit 6 of the piezoelectric ceramic element 1, and the capacitance of the piezoelectric ceramic element 1 and
A bandpass filter is constituted by the temperature compensating capacitor 3 and the filter resistor 10. The temperature compensating capacitor 3 and the filter resistor 10 are used.
The piezoelectric ceramic element 1 is intended to prevent output saturation or malfunction of the impedance conversion circuit 6 due to input of a very large output signal generated when acceleration corresponding to the resonance frequency of the piezoelectric ceramic element 1 is applied. It is provided to reduce the output signal from the. Further, the leak resistance 4 is the piezoelectric ceramic element 1
This is to leak the charge accumulated in the.

On the other hand, the self-fault diagnosis circuit 5 is provided for early detection of a fault occurring in the acceleration sensor, and has a pulse shape synchronized with a timing pulse signal input to the base B side through the external input terminal 11. The PNP transistor 12 is provided as a switching element for outputting the self-diagnosis signal to the piezoelectric ceramic element 1. The emitter E side of the PNP transistor 12 is connected in series to the power source voltage Vcc of DC 5V, while the collector C side has the first and second voltage dividing resistors 1 and 2.
3, 14 are connected in series, and the first voltage dividing resistor 13 is connected to the reference voltage Vr.

Furthermore, a connection capacitor 15 is interposed between the connection point between the voltage dividing resistors 13 and 14 and one end side of the piezoelectric ceramic element 1, and the self-output capacitor output from the PNP transistor 12 is provided. The diagnostic signal is applied to the piezoelectric ceramic element 1 via the connecting capacitor 15. The connecting capacitor 15 functions to cut the direct current component in the self-diagnosis signal, and has a bad effect due to the large resistance value of the leak resistance 4 and the small resistance value of the first voltage dividing resistance 13. It is provided to prevent the occurrence. That is, in the acceleration sensor having the circuit configuration as described above, when the self-diagnosis signal output from the self-diagnosis circuit 5 is applied to the piezoelectric ceramic element 1, the signal processing circuit 2 and the external output terminal 9 are provided. The sensor output obtained through the above is detected, and the presence or absence of a failure in the piezoelectric ceramic element 1 and other parts is determined based on the detected change in the sensor output.

[0006]

By the way, in the acceleration sensor having the conventional circuit configuration, the power supply voltage V
Since the PNP transistor 12 is interposed between cc and the piezoelectric ceramic element 1, the power supply voltage Vcc cannot be instantaneously applied to the piezoelectric ceramic element 1 even when the power is turned on, and the acceleration sensor It is possible to stabilize the rising characteristics of. Further, noise is not mixed in from the power supply during operation, and the piezoelectric ceramic element 1 does not exhibit unstable behavior due to the mixing of noise. As a result, malfunction and failure of the acceleration sensor are effectively prevented. The advantage of being able to do is also obtained.
However, the smaller the number of parts, the higher the reliability of the acceleration sensor, and at the same time, the cost can be reduced. Therefore, further simplification of the circuit configuration has been demanded.

The present invention was devised in response to this demand, and an object thereof is to provide an acceleration sensor having a further simplified circuit configuration.

[0008]

A first acceleration sensor according to the present invention is a piezoelectric ceramic element for detecting acceleration, a signal processing circuit for processing an output signal from the piezoelectric ceramic element, a piezoelectric ceramic element and a signal processing. It is equipped with a temperature compensating capacitor and a leak resistance that are connected in parallel between the circuits, and a self-failure diagnostic circuit that outputs a self-diagnostic signal to the piezoelectric ceramic element. And a PNP transistor that outputs a self-diagnosis signal synchronized with a timing pulse signal input from the base side from the collector side, and a first voltage divider connected in series to the reference voltage side of the piezoelectric ceramic element. It was connected in series between the resistor, the piezoelectric ceramic element and the first voltage dividing resistor, and between the collector side of the PNP transistor. Characterized in that it comprises a second dividing resistor.

In the self-diagnosis circuit for the second acceleration sensor, the PNP is connected to the power supply voltage on the emitter side and outputs from the collector side a self-diagnosis signal synchronized with the timing pulse signal input from the base side.
Type transistor, third and fourth voltage dividing resistors serially connected to the reference voltage side of the piezoelectric ceramic element, and series connection between the third and fourth voltage dividing resistors and the collector side of the PNP type transistor. The second voltage dividing resistor is provided.

[0010]

In the above circuit configuration, the functions of the filter resistor and the connecting capacitor, which are required in the conventional example, are realized by the first voltage dividing resistor or the third and fourth voltage dividing resistors and the piezoelectric ceramic element itself. Therefore, it is possible to reduce the connection capacitor and the filter resistance.

[0011]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit block diagram showing a simplified overall configuration of an acceleration sensor according to this embodiment, and FIG. 2 is a circuit block diagram showing an overall configuration of an acceleration sensor according to a modification. Since the overall configuration of the acceleration sensor is basically the same as that of the conventional example, the same or corresponding parts in FIGS. 1 and 2 as those in FIG. 3 are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 1, the acceleration sensor according to this embodiment has a piezoelectric ceramic element 1 for detecting acceleration.
A signal processing circuit 2 for processing an output signal from the piezoelectric ceramic element 1, a temperature compensating capacitor 3 and a leak resistor 4 connected in parallel between the piezoelectric ceramic element 1 and the signal processing circuit 2, and the piezoelectric ceramic element 1 And a self-diagnosis circuit 20 for outputting a self-diagnosis signal. The self-diagnosis circuit 20 has a collector C for supplying a pulsed self-diagnosis signal whose emitter E side is connected to a power supply voltage Vcc of DC 5V and which is synchronized with an arbitrary timing pulse signal input from the base B side. PNP transistor 12 that outputs from the side, a first voltage dividing resistor 21 connected in series to the reference voltage Vr side of the piezoelectric ceramic element 1, the piezoelectric ceramic element 1 and the first voltage dividing resistor 21.
The second voltage dividing resistor 22 is connected in series between the collector and the collector C side of the PNP transistor 12.

That is, in this case, the first voltage dividing resistor 21 has a resistance value of several MΩ, and is connected to the reference voltage Vr side of the piezoelectric ceramic element 1 without the connection capacitor 15 as in the conventional example. The piezoelectric ceramic element 1 whose one end is connected in series with the temperature compensating capacitor 3 and the leak resistor 4 has the other end through the first voltage dividing resistor 21. With reference voltage V
connected to r. Also, with this circuit configuration,
The filter resistor 10 in the conventional example is not provided, and an output signal from the piezoelectric ceramic element 1 is reduced by the capacitance of the piezoelectric ceramic element 1, the temperature compensating capacitor 3 and the first voltage dividing resistor 21. While the low-pass filter is formed, the capacitance of the piezoelectric ceramic element 1, the temperature compensating capacitor 3 and the leak resistance 4 form a high-pass filter.

Therefore, in the acceleration sensor adopting the circuit configuration according to the present embodiment, the functions of the filter resistor 10 and the connection capacitor 15 are realized by the first voltage dividing resistor 21 and the piezoelectric ceramic element 1 itself. That is, the pulse-shaped self-diagnosis signal output from the collector C side of the PNP transistor 12 forming the self-diagnosis circuit 20 in response to the input of the timing pulse signal has a resistance value set in advance. 1 and second voltage dividing resistor 2
The voltage is divided by 1, 22 and then applied to the piezoelectric ceramic element 1. The output signal from the piezoelectric ceramic element 1 is processed by the signal processing circuit 2 and then detected as a sensor output through the external output terminal 9. Therefore, the piezoelectric ceramic element 1 or the piezoelectric ceramic element 1 is detected based on a change in the detected sensor output. The presence / absence of a failure in another component is determined. That is, the piezoelectric ceramic element 1
If a failure such as the above occurs, the voltage waveform of the sensor output changes differently from that in the normal state, so that the failure is determined.

By the way, in the present embodiment, only a single first voltage dividing resistor 21 having a resistance value of several MΩ is provided, but as shown in FIG. 2, the reference voltage Vr side of the piezoelectric ceramic element 1 is provided. The third and fourth voltage dividing resistors 21
a and 21b are connected in series, and the PNP transistor 12 and the third and fourth voltage dividing resistors 21a and 21b are connected to each other.
The second voltage dividing resistor 22 may be connected in series with the collector C side of. And in the case of such a configuration,
The pulse height of the self-diagnosis signal output from the PNP transistor 12, that is, the rise in voltage can be finely adjusted. Incidentally, these third and fourth voltage dividing resistors 21
a and 21b are provided in place of the first voltage dividing resistor 21, and the sum of the resistance values of both voltage dividing resistors 21a and 21b is equal to the first voltage dividing resistor 21 and is equal to the number MΩ. In this case, the resistance value of the third voltage dividing resistor 21a is set to several MΩ, and the resistance value of the fourth voltage dividing resistor 21b is set to several tens of KΩ.

[0017]

As described above, according to the acceleration sensor of the present invention, the functions of the filter resistor and the connection capacitor, which are required in the conventional example, are provided by the first voltage dividing resistor or the third resistor. Since the fourth voltage dividing resistor and the piezoelectric ceramic element itself fulfill the function, it is possible to reduce the connection capacitor and the filter resistor. as a result,
The effect that the circuit configuration of the acceleration sensor can be further simplified without lowering the function, and the acceleration sensor can be improved in reliability, reduced in cost, and downsized.

[Brief description of drawings]

FIG. 1 is a circuit block diagram showing a simplified overall configuration of an acceleration sensor according to an embodiment.

FIG. 2 is a circuit block diagram showing an overall configuration of an acceleration sensor according to a modification.

FIG. 3 is a circuit block diagram showing a simplified overall configuration of an acceleration sensor according to a conventional example.

[Explanation of symbols]

 1 Piezoelectric Ceramic Element 2 Signal Processing Circuit 3 Temperature Compensating Capacitor 4 Leakage Resistance 12 PNP Transistor 20 Self-Fault Diagnosis Circuit 21 First Voltage Dividing Resistor 21a Third Voltage Dividing Resistor 21b Fourth Voltage Dividing Resistor 22 Second Voltage dividing resistance E Emitter B Base C Collector Vcc Power supply voltage Vr Reference voltage

Claims (2)

[Claims] 1. A piezoelectric ceramic element (1) for detecting acceleration, a signal processing circuit (2) for processing an output signal from the piezoelectric ceramic element (1), a piezoelectric ceramic element (1) and a signal processing circuit (2). ), A temperature compensating capacitor (3) and a leak resistance (4), and a self-diagnosis circuit (20) for outputting a self-diagnosis signal to the piezoelectric ceramic element (1). The self-diagnosis circuit (20) has an emitter (E) side connected to a power supply voltage (Vcc) and a self-diagnosis signal synchronized with a timing pulse signal input from the base (B) side to a collector (C). ) Side and a PNP type transistor (12) that is connected in series with the reference voltage (Vr) side of the piezoelectric ceramic element (1).
And a piezoelectric ceramic element (1) and a first voltage dividing resistor (2
1) and the collector (C) side of the PNP transistor (12), a second voltage dividing resistor (2) connected in series.
2) An acceleration sensor comprising: 2. A piezoelectric ceramic element (1) for detecting acceleration, a signal processing circuit (2) for processing an output signal from the piezoelectric ceramic element (1), a piezoelectric ceramic element (1) and a signal processing circuit (2). ), A temperature compensating capacitor (3) and a leak resistance (4), and a self-diagnosis circuit (20) for outputting a self-diagnosis signal to the piezoelectric ceramic element (1). The self-diagnosis circuit (20) has an emitter (E) side connected to a power supply voltage (Vcc) and a self-diagnosis signal synchronized with a timing pulse signal input from the base (B) side to a collector (C). ) Side, the PNP type transistor (12), the third and fourth voltage dividing resistors (21a, 21b) connected in series to the reference voltage (Vr) side of the piezoelectric ceramic element (1), the third and The fourth voltage dividing resistor (21
An acceleration sensor comprising a second voltage dividing resistor (22) connected in series between a and 21b) and the collector (C) side of the PNP transistor (12).