SU756423A1 - Device for inversely proportional conversion of dc voltage - Google Patents

Description

The invention relates to electrical dividing devices and can be used in analog computers.

A device designed to divide two voltages, containing logarithmic diodes, operational amplifiers, large-scale amplifiers N ·

This device is characterized by low accuracy. Closest to the proposed device is an inversely proportional DC voltage conversion, containing an operational amplifier, between whose input and output a logarithm diode is connected, the output of the input voltage source is connected to the input of the amplitude, the output of the differentiator is connected to the input of the operational amplifier, the output of the differentiator which is the output of the device, the output of the generator is a sinusoidal voltage through the second current-setting resistor n with the input of the operational amplifier m.

15

20

25

thirty

This device also has a low accuracy in a wide range of input voltages.

The purpose of the invention is to improve the accuracy of work.

This goal is achieved by the fact that an odd harmonic filter is inserted in it, the input of which is connected to the output of the operational amplifier, the output of the filter of odd harmonics is connected to the input of the differentiator.

The drawing shows a functional diagram of the proposed device for inversely proportional conversion of DC voltage.

The device contains a sinusoidal voltage generator 1, input source 2, voltage, first current-setting resistor 3, second current-setting resistor 4, operational amplifier'5, logarithmic diode 6, odd harmonics filter 7, differentiator 8, amplitude meter 9, output 10 of the device.

The device works as follows.

The input potential of the operational amplifier 5 is zero due to negative feedback through a logarithmic diode 6. Therefore, it is constant 756423

The current 0 ₅ flowing through the logarithm diode 6 is proportional to the input voltage supplied from the input voltage source 2, and inversely proportional to the resistance of the first setting resistor 3. Similarly, the AC current amplitude through the logarithm diode 6 is determined by the signal amplitude coming from generator ί

. sinusoidal voltage, and the resistance of the second current-setting resistor 4.

As a result, a sinusoidal current with a constant component, proportional to the input voltage, flows through a logarithmic diode 6. The amplitude of the alternating current through the logarithm diode 6 during operation of the device does not change. _

The output AC voltage 1) d of the operational amplifier 5 is equal to the alternating voltage on the logarithmic diode 6 and due to the non-linearity of its characteristics, in addition to the fundamental frequency, it also contains higher-order harmonics. The spectral composition of this voltage is determined by decomposition in a Fourier series:

h Ϊ pts) 1+ - cos2 (CA

5 ΐ η Zyl

Η

1+

(ABOUT

measure of harmonics, therefore the amplitude A _{p of} voltage II p is equal to the algebraic 'sum of the amplitudes of the individual harmonics

And _p , 2 СЧ> -, (Р - Р ^г + Р ⁵ "- Р ⁷ + ...). (4)

Given the value of P, it is easy to get that

^And p. (five)

Thus, the amplitude of the alternating voltage at the output of the differentiator 8 is precisely inversely proportional to the direct current flowing through the logarithmic diode 6, and, therefore, inversely proportional to. on the value of the constant input voltage of the entire device.

The voltage amplitude at the output of the differentiator 8 is measured by an amplitude meter 9, for example, by a peak detector, whose output constant voltage ^υ is inversely proportional to the input constant voltage.

The filter of odd harmonics 7. can be performed, for example, in the form of 25 therefore not included filters which are configured to suppress even harmonics. Practically, to achieve an accuracy of about 1%, it suffices to limit the suppression of the second

30 • and fourth harmonics.

where is c? _t is the temperature potential of the logarithm diode 6,

W - circular frequency generator of a sinusoidal signal /

ι - time.

This alternating voltage is fed to the filter of odd harmonics 7, which passes only odd harmonics of voltage (main, first, third, etc.) and delays even harmonics. At the output of the filter of odd harmonics acts AC voltage and f

p · e

CHF = 2ts, ^ Ρβίηωΐ - - 3ΐη34ιί +

K ⁵ .

+ - £ - s> p5y ^_ ·· .Ί. . ·. (2)

Next, the voltage goes to the differentiator 8, which increases the amplitude. Each harmonic is proportional to its number. After differentiation to the input of the meter amplitude 9 receives an alternating voltage and having a spectrum

u = 2c, <l> (P of sfg - P * so53iTs +

η

+ P ⁵ so5sh1 -. . ·) (3)

The amplitudes of the spectral components rather rapidly decrease with increasing

Claims (1)

Claim 35 - A device for inversely proportional DC voltage conversion, containing an operational amplifier, between the input and output of which a logarithmic diode is connected, the output of the input voltage source is connected to the input of the amplitude meter through the first current-setting resistor and is connected to the input of the amplitude meter. 45 'by the output of the device, the output of the generator of sinusoidal voltage through the second current-setting resistor is connected to the input of the operational amplifier, characterized in that 50 that, in order to improve the accuracy of work, an odd harmonic filter is introduced into it, the input of which is connected to the output of the operational amplifier, the output of the filter of odd harmonics of sub-55 keys to the input of the differentiator.