JPH05315846A - Temperature compensation device - Google Patents

Abstract

PURPOSE:To attain complete temperature compensation by devising an optimum temperature compensation signal in matching with each characteristic to be fed to each of plural temperature compensation devices whose output versus temperature characteristic differs and the adjustment of an offset voltage or the like of the temperature compensation device and the setting of the temperature compensation signal to be easily and surely implemented. CONSTITUTION:A voltage corresponding to an ambient temperature is produced at a point B by a thermister 12 and a resistor 13. The voltage appears at a point C via an operational amplifier for a buffer. Moreover, the voltage at the point C is inverted by an operational amplifier 17 and the result appears at a point D, A desired voltage (temperature compensation signal) between the voltage at the point C and the voltage at the point D is selected properly by a slider of a potentiometer 19 or 20 and fed respectively to a temperature compensation device 11 or 111 as a temperature compensation signal. A potentiometer 15 is used to adjust an output voltage level of the operational amplifier 17.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a temperature compensating device for supplying a signal for compensating for a change in output value to a device whose output value changes with a change in ambient temperature. is there.

[0002]

2. Description of the Related Art Conventionally, a high-sensitivity amplifier using a general-purpose OP amplifier has a problem that its offset voltage changes with a change in ambient temperature. In order to solve this problem, an OP amplifier having a good temperature characteristic may be used. However, since such an OP amplifier is very expensive, a high-sensitivity amplifier using a general-purpose OP amplifier is generally used. A temperature compensating circuit is provided, and a temperature compensating signal output from the circuit is used to compensate for a change in offset voltage due to a temperature change.

FIG. 3 is a diagram showing the configuration of a high-sensitivity amplifier provided with such a temperature compensation circuit.

In FIG. 3, resistors 2, 7, 6 and OP
The amplifier 3 constitutes a high sensitivity amplifier 11, and the resistor 5 and the potentiometer 4 constitute a circuit for adjusting the offset voltage thereof. Further, 1 is an input signal source of the high-sensitivity amplifier 11.

The temperature compensating circuit is generally composed of an element whose internal resistance changes in response to a temperature change and a resistor. In this example, the thermistor 8 and the resistor 9 are provided.
And a variable resistor 10.

In the conventional temperature compensating circuit configured as described above, the thermistor 8 causes a voltage change corresponding to the temperature change at the point A, and the voltage at the point A is applied to the variable resistor 10.
By converting the current into a current and flowing it into the feedback circuit of the high-sensitivity amplifier 11 which is a temperature compensated circuit, the temperature drift of the offset voltage is compensated.

[0007]

However, with respect to the temperature drift of the offset voltage of the OP amplifier, even if the offset voltage of the OP amplifier has the same product name, the amount of change and the direction of change differ depending on the temperature change. Therefore, for example, when the direction of change with respect to temperature is reversed, it is necessary to exchange the positions of the thermistor 8 and the resistor 9.

As described above, when the conventional temperature compensating device is used, a separate device is required for each temperature compensated device.

Further, when adjusting the high-sensitivity amplifier 11, ideally, the potentiometer 4 is used to adjust the offset amount that does not depend on the ambient temperature of the OP amplifier 3, and the temperature drift amount that changes depending on the ambient temperature is adjusted by the variable resistor. It may be adjusted by 10. However, in the device configured as shown in FIG. 3, the output of the temperature compensating circuit whose output changes according to the temperature change and the output of the circuit for offset adjustment are input to the high-sensitivity amplifier 11.

Therefore, when the potentiometer 4 and the variable resistor 10 are adjusted while measuring the output of the high-sensitivity amplifier 11, which part of the error that appears in the measured value is the part that does not depend on the temperature and which part does not depend on the temperature. It was not clear whether or not was a temperature-dependent part. Therefore, in the device thus configured, while changing the ambient temperature,
A complicated adjustment work of alternately performing adjustment of the potentiometer 4 and adjustment of the variable resistor 10 is required.

An object of the present invention is to supply an optimum temperature compensation signal to each of a plurality of temperature compensated devices having different output-temperature characteristics, and further to provide an offset of the temperature compensated device. An object of the present invention is to provide a temperature compensating device capable of easily and surely adjusting the voltage and the like and setting the temperature compensation signal.

[0012]

In order to achieve the above object, the present invention provides a first temperature detecting means for changing an output voltage in response to a change in ambient temperature and a change in the ambient temperature. Of the second temperature detecting means whose output voltage changes by the same amount in the opposite direction to the change of the output voltage of the first temperature detecting means, and at least one of the first and second temperature detecting means. A voltage adjusting means for adjusting an output voltage value, a resistor to which the output voltage of the first temperature detecting means is supplied to one end, and an output voltage of the second temperature detecting means to the other end, and the resistor. Output voltage setting means capable of selecting a voltage at an arbitrary point of the container, and outputting the output voltage of the output voltage setting means to the temperature-compensated device as a temperature compensation signal.

[0013]

According to the present invention, when the offset voltage or the like of the temperature-compensated device is adjusted, the first voltage adjustment means is used.
Since the output voltage difference between the second temperature detecting means and the second temperature detecting means can be made zero, the offset voltage of the temperature compensated device can be adjusted in this case regardless of the temperature compensation signal. Then, when the ambient temperature changes, the first and second
The output voltage of the temperature detecting means changes from the voltage of the constant level signal in the opposite direction by the same amount. The temperature compensation signal having a change direction and a change rate adapted to the temperature characteristic of the temperature compensated device is selected by selecting the voltage at any point of the resistor to which the two output voltages are supplied at both ends by the output voltage setting means. Can be supplied to the temperature compensated device.

[0014]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a circuit diagram showing the configuration of an embodiment of the present invention, and the same reference numerals as those in FIG. 3 denote the same elements. Further, 111 is an OP amplifier 103 and a resistor 1.
This is a high-sensitivity amplifier which is a device to be compensated constituted by 02, 106 and 107, and the resistor 105 and the potentiometer 104 constitute a circuit for adjusting the offset voltage thereof. Reference numeral 101 is a signal source of the high-sensitivity amplifier 111. Further, 31 and 131 are resistors for current adjustment.

Reference numeral 12 is an element whose internal resistance changes in response to a temperature change, and in the present example, a thermistor is used as such an element. Reference numeral 13 is a resistor, 14 is an OP amplifier for buffer, 15 is a potentiometer for adjusting the output voltage level of the OP amplifier 17, and 16 and 18 are resistors.
The values of the resistors 16 and 18 are selected so that the input / output characteristics of the OP amplifier 17 are the same as the input / output characteristics of the OP amplifier 14. Reference numerals 19 and 20 are potentiometers for setting the changing direction and the changing rate of the temperature compensation signal supplied to the high-sensitivity amplifiers 11 and 111.

Next, the operation of the high-sensitivity amplifier 11 of the present embodiment configured as described above will be described.

A voltage according to the ambient temperature is generated at point B by the thermistor 12 and the resistor 13. This voltage appears at point C by the OP amplifier 14 for buffer. The voltage at the point C is inverted by the resistors 16 and 18 and the OP amplifier 17 and appears at the point D.

Here, when adjusting the offset voltage that does not depend on the temperature of the temperature compensated circuit 11, first, the potentiometer 15 is set so that the potentials at points C and D become equal. When set in this way, since the potentials at both ends of the potentiometer 19 become equal, the position E of the slider is
No matter where the point is, the voltage output from the slider to the high-sensitivity amplifier 11 becomes a constant level. Therefore, the resistor 31
Flows a current due to the potential difference between this voltage and the voltage on the input side of the temperature compensated circuit 11, but there is no effect on this current due to the position of the slider of the potentiometer 19. That is, in this state, the present embodiment operates as a constant voltage circuit that outputs a constant level voltage regardless of the position of the slider. Therefore, the user may adjust the offset voltage of the high-sensitivity amplifier 11 to which the constant voltage circuit having no temperature dependence is connected by using the potentiometer 4.

After that, when the ambient temperature of these devices rises, the voltage at the points B and C rises from the above-mentioned constant level voltage corresponding to the temperature change. On the contrary, D
The voltage at the point drops from the constant level voltage described above. The values of the resistors 16 and 18 are set so that the amounts of change between the points C and D are equal to each other only in different directions. As a result, the polarity and value of the output voltage changes depending on the position E of the slider.

For example, if the position E of the slider is at the midpoint of the potentiometer 19, the voltages at both ends change in opposite directions due to temperature changes, so the voltage at point E does not move from the constant level voltage described above. Absent.

When the slider of the potentiometer 19 is located on the C point side with respect to the midpoint of the slider, the voltage at the E point rises due to the temperature rise. That is, the voltage has a positive temperature coefficient. Then, the closer the slider of the potentiometer 19 approaches the point C, the greater its inclination.

Further, when the slider of the potentiometer 19 is on the D point side from the midpoint, the voltage at the E point has a negative temperature coefficient, and the inclination increases as the slider of the potentiometer 19 approaches the D point. Become.

By utilizing this, when the offset voltage of the temperature compensated circuit is first adjusted and then a drift due to temperature occurs, the potentiometer 19 is irrespective of the direction.
The temperature compensation of the temperature compensated circuit can be easily performed by adjusting so as to cancel the drift by using.
That is, moving the position of the slider of the potentiometer 19 means that the voltage of the above-mentioned constant level (the voltage at the midpoint).
It is equivalent to continuously changing the temperature coefficient of voltage centered at from the positive region to the negative region. Therefore, it is possible to deal with whether the temperature-compensated device has a positive temperature coefficient or a negative temperature coefficient.

The operation of the high-sensitivity amplifier 111 of this embodiment is similar to the operation of the high-sensitivity amplifier 11, and therefore its explanation is omitted.

As described above, according to this embodiment, if the number of potentiometers is equal to the number of temperature-compensated devices,
An optimum temperature compensation signal can be supplied to each temperature compensated device. In other words, as is clear from FIG. 1, when an optimum temperature compensation signal is supplied to each of a plurality of high sensitivity amplifiers composed of OP amplifiers having completely different temperature coefficients, the high sensitivity amplifier It suffices to add more potentiometers.

FIG. 2 is a circuit diagram showing the configuration of another embodiment of the present invention.

In FIG. 2, the grounded NPN of the base
The type transistor 23 forms an emitter follower circuit,
The emitter potential is a potential lower than the ground potential by a base-emitter voltage drop (hereinafter referred to as V _be ). The absolute value of this V _be is known to have a temperature coefficient of about -2.5mV / ℃. Further, the PNP transistor 26 also forms an emitter follower circuit, but its base potential is set by the variable resistor 22. Then, the emitter potential of the PNP transistor 26, has become the only rose potential _V be against this base potential. Reference numerals 21, 24 and 25 are resistors, and 27 is a potentiometer.

Here, when adjusting the temperature compensated circuit, the emitter potential of the transistor 23 and the emitter potential of the transistor 26 are set to the same potential by the variable resistor 22. Transistor 23 and transistor 26 are NPN type and PN
Since it is formed of P type, the emitter potential of each emitter is 2.5 m in the opposite potential direction due to temperature change.
It changes at the rate of V / ° C. If the potentiometer 27 is connected between the emitters of both transistors and the temperature compensation signal is taken out from the slider, the same effect as that of the embodiment of FIG. 1 can be obtained.

[0030]

According to the present invention, a single device can generate a plurality of signals that individually change in response to changes in temperature, which is optimal for each temperature compensated device. In order to be able to supply the temperature compensation signal,
Optimum temperature compensation can be performed for each of a plurality of temperature compensated devices having different output temperature characteristics. Therefore, it is not necessary to independently provide a temperature compensation generator for each temperature compensated device. Further, for example, the adjustment work of the offset voltage of the OP amplifier and the setting work of the temperature compensation signal can be performed easily and surely, so that complete temperature compensation can be performed.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of an exemplary embodiment of the present invention.

FIG. 2 is a circuit diagram showing a configuration of another embodiment of the present invention.

FIG. 3 is a circuit diagram showing a configuration of a conventional device.

[Explanation of symbols]

11,111 High-sensitivity amplifier 12 Thermistor 13,16,18,21,24,25,31,131
Resistor 14,17 OP amplifier 15,19,20,27 Potentiometer 22 Variable resistor 23 NPN type transistor 26 PNP type transistor

Claims (1)

[Claims] 1. A first temperature detecting means for changing an output voltage in response to a change in ambient temperature, and an output voltage corresponding to a change in the ambient temperature for an output voltage of the first temperature detecting means. Second temperature detecting means that changes by the same amount in the opposite direction to the change, voltage adjusting means that adjusts the output voltage value of at least one of the first and second temperature detecting means, and the first temperature The output voltage of the detection means is supplied to one end,
The output voltage of the output voltage setting means includes a resistor to which the output voltage of the second temperature detecting means is supplied to the other end, and an output voltage setting means capable of selecting a voltage at an arbitrary point of the resistor. Is output to the temperature compensated device as a temperature compensation signal.