SU731581A1 - Functional voltage -to-code converter - Google Patents

Description

The invention relates to computing and measuring equipment and can be used as the main unit of analog-to-digital converters as a quadrator, as well as in information processing circuits.

Known converter voltage to frequency, built on operational amplifiers [1]. This converter is very complex and cannot reproduce the quadratic dependence of the output frequency of rectangular pulses on the input voltage.

Of the known converters, the closest in technical essence to the invention is a multivibrator, the displacement of which is regulated by the input voltage [2].

This device contains a DC amplifier, the output of which is connected through resistors to the inverting and non-inverting inputs of the DC amplifier. A non-inverting input through a resistor is also connected to the zero bus. A capacitor 2 is connected to the inverting input, the second plate of which is connected to the zero bus, and a resistor, the second terminal of which is connected to the voltage source. The output of the DC amplifier is the output of the device. 3

However, this device does not allow to obtain at the output a quadratic dependence of the frequency on the input voltage.

The purpose of the proposed device is to expand the functionality of the device, to obtain a quadratic dependence of the frequency of the output pulses on the input voltage.

This goal is achieved by the fact that in the converter containing the differential DC amplifier, the inverting input of which is connected through the first resistor to the input voltage source, through the capacitor to the zero bus, and directly to the first output of the second resistor, the non-inverting input is connected through the third resistor to zero bus and to the first output of the fourth resistor directly, in addition two counter-active zener diodes and an additional resistor are introduced, the first output of which is under for prison to the DC output of the differential amplifier, and its second terminal connected to second terminals of the second and fourth resistors, and two oppositely zener included - to the neutral bus.

The drawing shows a diagram of the proposed functional voltage-frequency converter.

The converter contains a differential amplifier 1 DC, resistors 2-6, a capacitor 7 and a zener diode 8, 9.

The drawing also shows the source 10 5 input voltage and the output 11 of the Converter.

The converter operates as follows.

With an input signal equal to zero, bipolar periodic pulses are generated at the 10th output of the converter. With an input signal other than zero, the frequency of the periodic pulses changes. This frequency change is due to the 15 charge of the capacitor 7 from the input voltage source 10. Moreover, the change in the frequency of bipolar periodic pulses from the input signal U _BX is determined by the expression 20 ^k 2 (and + and)

CR. _t k U ₂

where k ₂ - Ri + Ra £ - (R4R2 - RzRs + ^ RiRs) ',

Pt = R _s + Pr, b = CR ₂ ; ^thirty

H (t7) —the absolute value of the amplitude of the pulses of the positive (negative 35th) half-periods at the output of the differential amplifier;

t / = | t7 | + | T / | is the sum of the amplitudes of the positive and negative half-cycles or ⁴⁰ Foot swing amplitudes.

+ -

If U = U, then the expression linearly dependent on the frequency is equal to zero, and the change in frequency is proportional to the square of the input voltage. To ensure this condition (equality U = U), an additional resistor 6 and counter-active zener diodes 8, 9 are introduced.

Such a solution compares favorably with the proposed functional voltage-to-frequency converter from known schemes for converting voltage to frequency, since it allows in addition to linear conversion to reproduce the quadratic dependence of frequency on voltage using just one differential amplifier.

Claims (2)

The converter contains a differential DC amplifier 1, resistors 2-6, a capacitor 7, and zener diodes 8, 9. The drawing also shows the input voltage source 10 and the output 11 of the converter. The Converter operates as follows. With an input signal equal to il, bipolar periodic pulses are produced at the output of the converter. At an input signal other than zero, the frequency of non-periodic pulses changes. This frequency change is caused by the capacitor 7 nozzar house from the input voltage source 10. Moreover, the change in frequency of two-pole periodic nmiuls from the input signal / VJ is determined by the expression (and + C) / -L + and, + R ,; k (I, R, - /, /, + 2 /,); 4 + R; Ts CR; Lf (U) is the absolute value of the amplitude of the pulses of positive (negative) half-periods at the output of the differential amplifier; L / I L + I t / l is the sum of the amplitudes of the positive or negative half-angles or the amplitude range. If and, then the term of the expression, linearly dependent on the frequency, is zero, and the frequency change is proportional to the square of the input voltage. To ensure this condition (equality UU), an additional resistor 6 and opposite-connected Zener diodes 8, 9 are introduced. This solution favorably distinguishes the proposed functional voltage-frequency converter from the known conversion circuits to frequency, since it allows to reproduce the quadratic dependence besides the linear transformation the frequency from the voltage using just one differential amplifier. The invention is a functional inverter — a frequency containing a differential DC amplifier, the inverting input of which is connected through the first resistor to the input voltage source, through a capacitor to the zero bus, to the first output of the second resistor directly, and the non-inverting input is connected through the third the zero bus resistor and the first output of the fourth resistor directly, characterized in that, in order to expand the functionality of the converter, it provides two oppositely zener included and an additional resistor whose first terminal is connected to the output of the differential DC amplifier, and its second terminal connected to the second terminals of the second and fourth resistors via two counter n included zener schine to zero. Sources of information taken into account in the examination 1. Japanese Patent No. 49-9578, cl. 98 (5) D 52, 1969. 2.Shilo VL, Linear integrated circuits. M., “Owls. radio. 1974, p. 188.