JPH04263511A - Frequency/voltage conversion circuit - Google Patents

Abstract

PURPOSE:To improve a frequency/voltage converting characteristic by improving accuracy for the constant current of a saw-tooth-wave generation circuit. CONSTITUTION:A hold voltage (signal line 207) after frequency/voltage conversion is further inputted to an integration amplifier (A2), and the above-mentioned hold voltage is compared with a reference voltage Vref at the integration amplifier (A2). A closed loop is formed by the integration amplifier (A2) and a filter (F1), voltage/current conversion is executed to the output voltage, and it is supplied as the constant current of the saw-tooth-wave generation circuit.

Description

[Detailed description of the invention]

0001

[Industrial Application Field] The present invention relates to a frequency/voltage conversion circuit,
In particular, the present invention relates to a frequency/voltage conversion circuit that can improve frequency/voltage conversion characteristics by improving the constant current accuracy of the sawtooth wave generation circuit.

0002

2. Description of the Related Art FIG. 3 is a circuit diagram showing a specific configuration of a conventional frequency/voltage conversion circuit. In FIG. 3, the conventional frequency/voltage conversion circuit is composed of a sampling pulse/discharge pulse generation circuit (10) and a sawtooth wave generation circuit (20). Terminal (100), square wave input terminal (101), NPN transistor (Q1), capacitor (C1), resistors (R1) to (R5), comparators (N1) to (N4), and AND gate (G1)
, (G2), signal lines (201) to (205), etc., and the sawtooth wave generation circuit (20) includes a reference voltage power supply terminal (102), an NPN transistor (Q2),
Capacitors (C2), (C3), resistor (R6), operational amplifier (A1), current mirror (Q3), (Q4
), signal lines (206), (207), etc.

Next, the operation of the conventional frequency/voltage conversion circuit configured as described above will be explained using FIG. 4. FIG. 4 is a waveform diagram showing signal waveforms at various parts of the conventional frequency/voltage conversion circuit shown in FIG.

First, assuming that a predetermined voltage Vcc is applied to the sampling pulse/discharge pulse generation circuit (10) from the power supply voltage terminal (100), the signal line (2
04) to (201) are gradually lowered by resistors (R5) to (R1). In this state, the input terminal (1
When the rectangular wave shown in FIG. 4(a) is input from 01), the signal line (20
The voltage 5) becomes a trapezoidal wave as shown in FIG. 4(b). Therefore, the signal line (205) and the signal lines (201) to (2)
Comparators (N1) to (N
4) is when the voltage of the signal line (205) is higher than the voltage V1 of the signal line (201) and lower than the voltage V2 of the signal line (202), and when the voltage of the signal line (203) is higher than the voltage V3 of the signal line ( 204), the outputs of all the comparators are turned ON, so the outputs of the AND gates (G1) and (G2) that input the output signals are as follows.
It turns ON only in the above case. This is shown by the signal waveform in FIG. 4(b).

As described above, the sampling pulse/discharge pulse generation circuit (10) is composed of comparators (N1) to (N4).
The sampling pulse (output signal of AND gate (G1)) and discharge pulse (output signal of AND gate (G2)) were output to the sawtooth wave generation circuit (20).

Further, the sawtooth wave generation circuit (20) is applied with a reference voltage from the reference voltage power supply terminal (102), and the discharge signal which is the output of the AND gate (G2) of the sampling pulse/discharge pulse generation circuit (10) is applied to the sawtooth wave generation circuit (20). Pulse is NPN
It is input to the transistor (Q2). Therefore, the voltage on the signal line (206) becomes a sawtooth wave as shown in signal waveform (1) in FIG. 4(c). The operational amplifier (A1) inputting this sawtooth wave outputs the voltage of the signal line (206) to the signal line (207) only when the sampling pulse of the AND gate (G1) is turned ON.

As described above, if the period of the rectangular wave input from the rectangular wave input terminal (101) becomes shorter (that is, if the frequency of the rectangular wave becomes higher), the capacitor (C2) is charged in the signal line (206). Under the condition that the current is constant, the peak voltage of the sawtooth wave (V5)
decreases, so the voltage of the signal line (207) also decreases, and conversely, if the period of the rectangular wave becomes longer (that is, if the frequency of the rectangular wave becomes lower), the peak voltage of the sawtooth wave (V5
) increases, so the voltage of the signal line (207) increases.

In this manner, the frequency (f) of the rectangular wave input from the rectangular wave input terminal (101) is converted into the voltage (V) taken out from the output signal line (207) by the conventional frequency/voltage conversion circuit. I understand that.

[0009]

[Problem to be solved by the invention] Since the conventional frequency/voltage conversion circuit is configured as described above, the capacitor (C
2) A constant current (I1), that is, a capacitor (
C2) depended on constant voltage fluctuations. Therefore, when the constant voltage of the capacitor (C2) fluctuates, there is a problem that the output voltage (V) does not accurately reflect the frequency fluctuation.

The present invention has been made to solve the above-mentioned problems, and by improving the accuracy of the constant current of the sawtooth wave generating circuit, it is possible to improve the frequency/voltage conversion characteristics. The purpose is to obtain a voltage conversion circuit.

[0011]

[Means for Solving the Problems] In order to achieve the above object, a frequency/voltage conversion circuit according to the present invention provides a frequency/voltage conversion circuit.
The hold voltage after voltage conversion is further input to an integrating amplifier, which compares the hold voltage with a reference voltage, and forms a closed loop with the integrating amplifier and filter to convert the output voltage of the integrating amplifier into a voltage.・The current is converted and supplied as a constant current to the sawtooth wave generation circuit.

0012

Therefore, according to the frequency/voltage conversion circuit of the present invention, the frequency/voltage conversion characteristics can be improved by improving the accuracy of the constant current of the sawtooth wave generation circuit.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram showing the configuration of a frequency/voltage conversion circuit according to the present invention. In FIG. 1, the frequency/voltage conversion circuit of the present invention includes a sampling pulse/discharge pulse generation circuit (1
0) and a sawtooth wave generation circuit (30),
The sampling pulse/discharge pulse generation circuit (10) is
Power supply voltage terminal (100) and square wave input terminal (101)
, NPN transistor (Q1), and capacitor (C1
), resistors (R1) to (R5), and comparator (N1
) ~ (N4), and gates (G1), (G2),
It is composed of signal lines (201) to (205), etc., and this configuration is similar to a conventional frequency/voltage conversion circuit.

Further, the sawtooth wave generation circuit (30) of the frequency/voltage conversion circuit of the present invention has a power supply voltage terminal (103) to which a predetermined voltage Vcc is input, and an NPN transistor (Q
2), (Q7) and capacitors (C2), (C3),
Resistors (R7) and (R8), an operational amplifier (A1), an integral amplifier (A2) that compares the output voltage of the operational amplifier (A1), which is a hold voltage, and a reference voltage Vref, and the output of the integral amplifier (A2) as a voltage. - Operational amplifier (A3) for current conversion, filter (F1), current mirrors (Q5), (Q6), and signal lines (206), (207)
It is composed of etc. Next, the operation of the conventional frequency/voltage conversion circuit configured as described above will be explained, focusing in particular on the operation of the sawtooth wave generation circuit (30), which is different from the conventional one. Sampling pulse/discharge pulse generation circuit (
10) and the operational amplifier (A1), the output voltage (V) is output to the signal line (207), but in the sawtooth wave generation circuit (30) of the present invention, the signal line (
207) is further input to the integrating amplifier (A2), where the voltage of the signal line (207) and the reference voltage Vref are compared, and the voltage of the signal line (207) is further input to the filter (F1).
is transmitted to the non-inverting input of the operational amplifier (A3). The operational amplifier (A3) converts the output voltage of the integrating amplifier (A2) into voltage and current using the NPN transistor (Q7) and the resistor (R8), and also uses the current mirror (Q5), (
Q6) to the capacitor (C2).

The output voltage (V) of the signal line (207) subjected to frequency/voltage conversion as described above is constantly compared with the reference voltage Vref in the integrating amplifier (A2) and configured via the filter (F1). The closed loop is configured such that the difference between the output voltage (V) and the reference voltage Vref is amplified by a gain multiplied by the filter (F1). If the output voltage of the closed loop is converted into a voltage/current and a constant current is supplied to the capacitor (C2), fluctuations in the constant current of the capacitor (C2) can be minimized.

In the above embodiment, current mirrors (Q5) and (Q6) made of PNP transistors were used, but as shown in FIG. 2, current mirrors (Q8) and (Q9) made of NPN transistors may also be used. good. However, in this case, the NPN transistor (Q2), (
As a transistor corresponding to Q7), P shown in FIG.
It is necessary to use NP transistors (Q10) and (Q11).

Furthermore, in the embodiment shown in FIG.
The output voltage of A2) is converted into voltage/current by an operational amplifier (A3), an NPN transistor (Q7), and a resistor (R8), but the Hfr of the NPN transistor (Q7)
If is sufficiently high, the output voltage of the integrating amplifier (A2) can be directly connected to the base of the NPN transistor (Q1) and the operational amplifier (A3) can be omitted.

Furthermore, the same thing can be applied to the second embodiment shown in FIG. 2, in which the output voltage of the integrating amplifier (A2) is directly connected to the base of the PNP transistor (Q11) and the operational amplifier (A3) is omitted. can do.

[0019]

[Effects of the Invention] As explained above, according to the present invention,
The hold voltage after frequency/voltage conversion is further input to an integrating amplifier, which compares the hold voltage with a reference voltage, and forms a closed loop with the integrating amplifier and filter to determine the output voltage of the integrating amplifier. Since it is configured to convert the voltage to current and supply it as a constant current to the sawtooth wave generation circuit, the accuracy of the constant current of the sawtooth wave generation circuit can be improved, and the frequency and voltage conversion characteristics can be improved. There is an effect.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing the configuration of an embodiment of a frequency/voltage conversion circuit of the present invention.

FIG. 2 is a circuit diagram showing the configuration of a second embodiment of the frequency/voltage conversion circuit of the present invention.

FIG. 3 is a circuit diagram showing a specific configuration of a conventional frequency/voltage conversion circuit.

FIG. 4 is a waveform diagram showing signal waveforms at various parts of the conventional frequency/voltage conversion circuit shown in FIG. 3;

[Explanation of symbols]

(10) Sampling pulse/discharge pulse generation circuit (20) Sawtooth wave generation circuit (100), (103) Power supply voltage terminal (101)
Square wave input terminal (102) Reference voltage power supply terminal (201) to (207) Signal line (Q1), (Q2), (Q7) NPN transistor (Q3), (Q4), (Q5), (Q6) PNP current Mirror (Q8), (Q9) NPN current mirror (Q10
), (Q11) PNP transistors (C1) to (C
3) Capacitor (R1) to (R8) Resistor (N1) to (N4) Comparator (G1), (G2) AND gate (G3) NAND gate (A1), (A3) Operational amplifier (A2) Integrating amplifier (F1) Filter

Claims (1)

[Claims] Claim 1: In a sawtooth wave generation circuit of a so-called frequency/voltage conversion circuit that converts a frequency into a voltage, a hold voltage after frequency/voltage conversion is further input to an integrating amplifier, and the holding voltage and a reference voltage are combined in the integrating amplifier. At the same time, the integrating amplifier and filter form a closed loop, and the output voltage of the integrating amplifier is
A frequency/voltage conversion circuit characterized in that the current is converted and supplied as a constant current to a sawtooth wave generation circuit.