SU586465A1 - Multiplier - Google Patents

Description

one

The invention relates to analog computing, is intended to multiply two continuous quantities, given by the type of electrical voltage, and can be used in various fields of automation and computing.

A device for multiplying 1 is known, comprising logarithmic blocks, an adder and an anti-logarithm block. However, this device has insufficient accuracy.

The closest in technical judgments to the proposed device is a multiplying device - a logarithmic device for the intertwining of two analog values specified in the form of electrical voltages, containing two logarithmic units based on operational amplifiers with logarithmic diodes in the feedback circuit, the inputs of the logarithmic units serve as inputs devices, and the outputs are connected to the first and second inputs of the adder, the output of which is connected to the anti-log block on the basis of the operational gain It has logarithm diodes in the input circuit.

This device has a relatively low accuracy, since the magnitude of the error in the output voltage of the device depends on the degree of achievement of identity.

current-voltage characteristics of the diodes of the circuit.

Only under the condition of strict ideiticity.

parameters of diode diodes and their operation in

same output current range

device voltage is generated

Xy

4, R

i.e. the scheme does not introduce additional

error in the multiplication result.

In the known device, the fulfillment of this condition is impossible due to the fact that, firstly, it is practically very difficult to ensure the stable identity of the parameters of all

The diodes of the circuit, secondly, even when such an identity is achieved, the operating current range of the diode circuits of the input logarithm amplifiers differ from the current range of the diode circuit of the antilogarithm.

The purpose of the invention is to improve the accuracy of the operation of the device.

This is achieved in that the device contains an additional inverting unit log-based on the operational

an amplifier with logarithm diodes in the feedback circuit, with logarithm diodes included in the polarities, reverse polarities of the logarithm diodes of the main logarithmic blocks, the input of the additional inverting block logarithm is connected to the source of the reference voltage, and the output is connected to the third input of the adder.

An increase in the multiplication accuracy of this solution is achieved because by introducing an input logarithmic converter of the unit one evens out the ranges of the operating currents of the input and output converters.

The scheme of the proposed device is shown in the drawing.

The device contains blocks 1 and 2 of logarithm based on auxiliary amplifiers 3 and 4 with logarithm diodes 5 and 6 in the feedback circuit, adder 7, block 8 antilogs on the basis of an operational amplifier 9 with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms with logarithm diodes 10 in the input circuit, inverting unit 11 logarithms 9 the basis of the operational amplifier 12 with logarithm diodes 13 in the feedback circuit, with the diode polarity in block 11 being inverse to the diodes in blocks 1 and 2.

The device works as follows.

The multiplied analog magnitudes X and Y are entered into blocks 1 and 2. At the same time, the input unit of block 11 is supplied with an operating unit (device, device scale) with a sign opposite to the sign of the factors X and Y.

In blocks 1, 2 and 11, the danasetic currents of the operation of the diode circuits are identical, and the averaged characteristics of the diode circuits are equal with sufficient accuracy. Taking this into account, we can assume that the output voltages of 1, 2 and 11 blocks are respectively

vy

Ui gsrt 1n -, and // ZfT In -,

/ 0 IgK

I

and - / ft In

/ 0

where t is the coefficient;

Ft - thermal potential.

The voltages U, Uz, From are summed and fed to block 8, the output of which is the voltage

f

ln--

, aHtiln + nJ ,,

cntff

The proposed technical solution makes it possible to reduce the error of operation of the logarithmic device to 0.18% of the scale in wide ranges of temperature (from -10 to -) - 60 ° C) and frequency bandwidth compared to lime.

Claims (2)

1. Tomovic R., Karplus U. High-speed analog computers. “Peace, 1964, p. 161. 2. Aleksenko A.G. Fundamentals of microcircuitry. M., 1971, p. 288.