JPS5816023Y2 - Linear function generator - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a linear function generator using diodes.

Conventionally, in the input/output linear characteristics of this type of linear function generator, the accuracy of the bending point is largely influenced by the characteristics near the rising point of the diode, and the forward voltage of the diode changes greatly depending on the ambient temperature. The disadvantage is that the point changes depending on the temperature.

An object of the present invention is to provide a polygonal function generator that eliminates the above-mentioned drawbacks.

Hereinafter, the present invention will be explained in detail using the drawings.

1a to 1d are diagrams showing four basic circuits of an electrical circuit illustrating an embodiment according to the present invention.

Further, FIGS. 2a to 2d schematically show the input/output characteristics corresponding to those in FIGS. 1a to d, respectively.

In FIG. 1a, 1 is a buffer amplifier section, which includes an operational amplifier A (hereinafter referred to as OP amplifier A), negative feedback resistors R1, R2, R3, and an input terminal (2).

and an output end hole Out.

Input terminal■. is connected to the (G) input terminal of OP amplifier A, and one end of negative feedback resistor R1 is connected to the output terminal O of OP amplifier A.
ut, the other end is connected to one end of negative feedback resistor R2, the other end of negative feedback resistor R2 is connected to one end of negative feedback resistor R3, and the other end of negative feedback resistor R3 is connected to a common point. There is.

Further, the connection point between the negative feedback resistors R2 and R3 is connected to the ←) input terminal of the OP amplifier A.

21 is a broken line circuit, and bias resistor R4□. R51, R6
1, diode D1, compensation diode Da.

It consists of Db, voltage source V, and constant current source (2).

One end of bias resistor R4□ is connected to the anode of compensation diode Da, the other end of bias resistor R4□ is connected to one end of bias resistor R5□, and the other end of R51 is connected to the anode of compensation diode Db. There is.

The connection point between bias resistors R4□ and R51 is bias resistor R
Connected to one end of R6□, and the other end of R6□ is connected to diode D.
1 anode.

The cathodes of the diodes D8°Db and Dl are respectively connected to the output terminal Out, the common point, and the connection point between the negative feedback resistors R1 and R2.

In addition, the anode of the compensation diode Da has a constant current source ■1
is connected to the constant current source (1), and a voltage source V is connected to the constant current source (1).

In this way, the buffer amplifier section 1 and the polygon circuit 21 constitute a polygonal function generator.

The input signal of this broken line function generator is V+n, and the output signal is V
.

Let it be ut. In addition, the connection point of negative feedback resistors R1 and R2 is a,
The connection point between bias resistors R41 and R51 is bl, and the potentials appearing at connection points a and b1 are ea and e5, respectively.
□.

In the basic circuit of Figure 1a, when the input signal is zero,
The output signal is zero.

As the input signal Vln increases, the potential eF1. The potential ebl increases as indicated by the dotted line in FIG. 2a.

When the potential eb□ becomes higher than the potential ea, and the potential difference reaches such a level that the diode D1 becomes conductive, the diode D
1 becomes conductive, the impedance between the output terminal Out of the OP amplifier A and the common point changes, and the slope of the input/output characteristics changes.

This situation is shown in solid lines in FIG. 2a.

When the input-output relationship is calculated using the formula, (I) When 1 is non-conducting, (1]) When Dl is conductive tree, however, Therefore, when Dl is conductive, it becomes ■ more than when it is not conductive.

The slope of ut decreases.

Here, ■6□, y, yb are diodes Dz, D-
, shows the forward voltage drop of Db.

This basic circuit a is a circuit in which the slope of the human output characteristic decreases from a certain corner voltage.

In Figure 1, 1 is a buffer amplifier section;
22 is a broken line circuit section, bias resistors R42, R52, R6□, diode D
2. Compensation diode D,,D,, constant voltage source-v8. It consists of a constant current source 11 and a voltage source V.

One end of bias resistor R4□ is connected to the anode of compensation diode Da, the other end of bias resistor R4□ is connected to one end of resistor bias R5□, the other end of R52 is connected to the anode of compensation diode DC, and R52 and R52 are connected to the anode of diode D2 via bias resistor R62.

The cathodes of the compensation diodes D, , Do, and the diode D2 are connected to the output terminal Out and the constant voltage source -■5. It is connected to connection point a.

Further, a constant current source (1) is connected to the anode of the compensation diode Da, similar to the circuit shown in FIG. 1A, and a voltage source (2) is supplied to the constant current source (2).

The input/output relationship of this circuit is as follows: (iii) When Dz is non-conductive, it is the same as formula (1).

(iv) When Dz is conductive, however, the slope of the input/output characteristic when D2 is conductive is smaller than when D2 is non-conductive.

Here, ■6□. Va and Vo are diodes D2. This is the voltage drop in the forward direction of the compensation diode D8°DC.

The constant voltage source 5 serves as a bias voltage source and applies a deep bias in the negative voltage direction.Thereby, the circuit shown in FIG.

In FIG. 1C, 1 is a buffer amplifier section, 23 is a broken line circuit section, bias resistors R43, R53, R63, diodes D3 . Compensation diode Dd, Do, constant voltage source ■5. Disconnect from constant current source (2) and voltage source (2).

One end of bias resistor R43 is connected to the cathode of compensation diode Dd, the other end of R43 is connected to one end of resistor R53, the device of R53 is connected to the cathode of compensation diode De, and the connection point of R43 and R53 is Resistor R63
is connected to the cathode of diode D3 via.

Compensation diode D4. De and the anode of diode D3 are connected to a constant voltage source +V8. The common point and contact points are connected.

In addition, the cathode of the compensation diode D8 is a constant current source ■2
is connected to draw the current flowing into the cathode terminal of the compensation diode De.

Constant current source (2) is connected to voltage source - (2).

The input/output relationship of the basic circuit in figure e is: (V) When D3 is non-conductive, it is the same as formula (1).

(■) When D3 is conductive, however, the input/output characteristics become more sloped when D3 is conductive than when it is non-conductive.

This situation is shown by the solid line in FIG. 2C.

In equation (4), Vd3. Va, Ve are diodes D
3. The forward voltage drop of the compensation diodes Dd and De is shown.

The circuit shown in Figure C can change the bias voltage from zero to +5.

In FIG. 1d, 1 is a buffer amplifier section.

24 is a broken line circuit, bias resistors R44, R54, R6
4° diode D3. Compensating diodes Dd, Df, constant voltage source 5. -■5. Constant current source ■2 and voltage source -■
Consists of.

One end of bias resistor R44 is connected to the cathode of compensation diode Dd, and the other end of R44 is connected to bias resistor R54.
connected to one end of R54, and the other end of R54 is a compensation diode D
, and the connection point between R44 and R54 is connected to the cathode of the diode D4 via a bias resistor R64.

The anodes of the compensation diodes Dd, Df, and the diode D4 are connected to the constant voltage sources +Vs, Vs, and the connection point a, respectively.

Further, in order to draw the current flowing into the cathode terminal of the compensation diode Df, the constant current source ■2 is connected to the cathode of the compensation diode Df, and the voltage source -■ is connected to the constant current source ■2.
It is supplied as a power source.

The input/output relationship of this basic circuit is the same as equation (1) when (Vl)D4 is non-conductive.

(■) When D4 is conductive, the following equation is obtained, and the slope of the input/output characteristic increases when D4 is conductive than when D4 is non-conductive.

This situation is shown in solid lines in FIG. 2d.

In equation (5), Vd4. Vd and Vf are diode D4. The forward voltage drop of the compensation diodes D, , Df is shown.

The circuit shown in Figure C can change the bias voltage from -V5 to +Vs.

Now, in the circuit of FIG. 1 a to d, the diodes D1 to
D4 and the compensation diodes D, -Df can be selected to have the same change in forward voltage drop with respect to temperature, and as can be seen from the above equations (2) to (5), each diode The forward voltage drops of each are in the form of a difference, and the temperature coefficient of the forward voltage drop of each diode is almost constant regardless of the current flowing through the diode, so each of the above equations (2) to (5) V.

ut becomes almost independent of temperature changes.

That is, in the broken line function generator using the basic circuit shown in FIGS. 1A to 1D, the break point does not change depending on the temperature.

FIG. 3 shows another embodiment of the basic circuit of the linear function generator according to the present invention, and here a modified example of the circuit of FIG. 1a is shown.

11 is a buffer amplifier section, and input terminal ■.

is connected to the (1) input terminal of OP amplifier A.

A compensation diode Dal is connected to the output terminal of OP amplifier A.
The other end of the negative feedback resistor R11 is connected to one end of the negative feedback resistor R21, the other end of the negative feedback resistor R2□ is connected to one end of the negative feedback resistor R3□, and the other end of the negative feedback resistor R11 is connected to one end of the negative feedback resistor R3□.
The other end of 31 is connected to a common point.

The connection point between the negative feedback resistor R2□ and the negative feedback resistor R3□ is connected to the (-) input terminal of the OP amplifier A.

211 is a broken line circuit section, one end of bias resistor R4□1 is connected to the output terminal of OP amplifier A, and bias resistor R4
, 1 is connected to one end of bias resistor R5□1,
The other end of the bias resistor R5□1 is connected to the anode of the compensation diode Db, and the cathode of the compensation diode Db is connected to the common point.

One end of bias resistor R6□1 is connected to the connection point between bias resistor R4,1 and bias resistor R5□1, the other end of bias resistor R6□1 is connected to the anode of diode Dll, and the cathode of diode D1□ is connected to the buffer amplifier. It is connected to the connection point between negative feedback resistor R1□ and negative feedback resistor R2□ of section 11.

The output end hole Out of this basic circuit is connected to the compensation diode D.
It is drawn out from the connection point between the cathode of a□ and the negative feedback resistor R1□.

In addition, a protective diode Dp connects the anode side to the output terminal Ou.
The cathode side is connected to the output terminal of OP amplifier A at t.

In the polygonal function generator constructed in this manner, the input/output relationship is the same as that of the circuit shown in FIG. 1a, and the same effects can be obtained.

Further, in the above embodiment, the compensation diode of the broken line circuit section is connected to the connection point of negative feedback resistors R1 and R2, and the connection point of negative feedback resistors R2 and R3 is connected to the OP amplifier A.
However, this connection point is reversed, and the connection point of negative feedback resistors R1 and R2 is connected to the (→ input terminal of OP amplifier A, and the negative feedback resistor R2
A compensation diode of the resistance circuit may be connected to the connection point of R3.

FIG. 4a is an electrical circuit diagram showing an embodiment of a polygonal function generator constructed by combining the basic circuits shown in FIGS. 1a to 1d.

In FIG. 4a, the same parts as in FIGS. 1a to d are given the same symbols.

FIG. 4 is a diagram showing a schematic diagram of the input/output characteristics of the circuit of FIG. 4a, which is a broken line function characteristic having four break points.

With this configuration, it is possible to obtain a broken line function generator that is independent of temperature and has high accuracy at break points.

Note that although the above embodiments have been shown for the case of positive input, by reversing the polarity of the diode and the polarity of the constant voltage source, etc., a polygonal function generator having the same effect can also be used in the case of negative input. can be realized.

As explained above, the device of the present invention includes an operational amplifier,
In a linear function generator comprising a negative feedback resistor connected to the negative feedback circuit of the operational amplifier and a linear circuit using a diode connected to the negative feedback resistor, a bias circuit that applies a bias voltage to the diode of the linear circuit. The linear function generator is characterized in that compensating diodes are connected to both ends of the bias resistor of the linear circuit so that the forward voltages of the diodes of the linear circuit and the forward voltages of the compensating diodes cancel each other out.

According to the device of the present invention, it is possible to provide a highly accurate polygonal function generator that is independent of temperature.

Furthermore, since the device of the present invention has a configuration in which a broken wire circuit section is provided on the feedback side of the operational amplifier, the input impedance is high and it is possible to handle minute signals.

Therefore, the output of a sensor such as a thermocouple can be directly added, which has the advantage of helping to simplify the system.

Furthermore, since the output impedance is low, it is resistant to noise, etc.

[Brief explanation of drawings]

Figures 1a-d are electrical circuit diagrams showing the four basic circuits of the linear function generator according to the present invention, Figure 2 is a diagram showing the input/output characteristics of Figures 1a-d, and Figure 3 is a diagram showing the input/output characteristics of each of Figures 1a-d. , an electric circuit diagram showing another embodiment of the basic circuit of the broken line function generator according to the present invention, FIG.
FIG. 3 is an electrical circuit diagram showing a broken line function generator with two broken lines; 2.21.22, 23, 24, 211... Broken line circuit, A... Operational amplifier, D1 to D4. D1□
...Diode, DB+Db+DC+D, 1
, D(3, Df, Dax, Dbr"・" Compensation diode, R1゜R2, R3, R11, R21, R3
□・・・・・・Negative feedback resistance, R41, R51°R6□,
R4□, R52, R6□, R43, R53, R631
R44, R54, R641R4□1. R5□1. R6□
1...Bias resistance, 1V5゜V5...
- Constant voltage source, II, I2...constant current source.

Claims (3)

[Scope of utility model registration request] (1) In a polygonal function generator formed from a polygonal circuit using an operational amplifier, a negative feedback resistor connected to a negative feedback circuit of the operational amplifier, and a diode connected to the negative feedback resistor, A compensation diode is connected to both ends of a bias resistor of a bias circuit that applies a bias voltage to the diode so that the forward voltage of the diode of the broken line circuit and the forward voltage of the compensation diode cancel each other out. Linear function generator. (2) The polygonal line circuit includes a diode whose one end is connected to the feedback circuit of the operational amplifier, a bias resistor circuit connected to the other end of the diode, and a bias resistor circuit whose one end is connected to a constant voltage source. a second compensating diode that connects the other end of the bias resistance circuit to a constant voltage source or a common point having a polarity opposite to that of the constant voltage source; and maintaining the compensating diode in a conductive state. Utility model registration claim 1 consisting of a current source for
Linear function generator described in section. (3) A broken line circuit includes a diode with one end connected to the feedback circuit of the operational amplifier, a bias resistor circuit connected to the other end of the diode, and one end of the bias resistor circuit connected to the output terminal of the operational amplifier. A broken line according to claim 1 of the utility model registration claim, which is constituted by a first compensating diode connected to the bias resistor circuit and a second compensating diode connecting the other end of the bias resistor circuit to a constant voltage source or a common point. Function generator.