SU1275479A1 - Scale converter - Google Patents

Abstract

This invention relates to the field of analog computing. The purpose of the invention is to expand the scope by obtaining a conversion factor greater than 1 and reducing the output impedance. The scale converter contains a differential operating force, a coupler, two different polarity current sources, two parametric voltage regulators, a voltage divider, and an additional operational amplifier. The dynamic range of the input voltages of the converter does not depend on the maximum value of the allowable common-mode input. The differential operational amplifier signal is determined by the supply voltage of the current regulators if this gain of the converter is greater than 1. The output resistance of the converter is equal to the ratio of the output resistance (L of the open differential operational amplifier to the product of its gain and feedback ratio) and may be Pleasantly small. 1 Ill.

Description

The invention relates to analog computing.

The purpose of the invention is the expansion of the scope by obtaining a conversion coefficient greater than unity and reduce output impedance.

The drawing shows a functional diagram of a scale Converter.

The converter contains a differential operational amplifier 1, two bipolar current sources 2 and 3, two parametric voltage stabilizers 4 and 5, a voltage divider 6, consisting of two resistors, information input 7 of the converter, output .8 of the converter and an additional operational amplifier 9.

The scale converter works as follows.

Parametric voltage stabilizers 4 and 5, which can be used silicon zener diodes, provide a constant voltage supply of the differential operational amplifier 1 over the entire operating range of input voltage changes. The current required to power the differential operational amplifier 1 and parametric stabilizers 4 and 5 is set by the sources 2 and 3 currents, which are powered by voltages + E and'-E, The gain of the converter, with a sufficiently large gain of the amplifier .1 ra the ratio of the sum of the resistance values of the first and second resistors of the divider 6 to the resistance value of the second resistor, the voltage at the non-inverting input of the additional operational amplifier 9, which is equal to the error of the statism of the amplifier 1 to the input voltage of the converter, is repeated by the additional operational amplifier 9 and from its output through parametric stabilizers 4 and 5 goes to the power bus of the differential operational amplifier, while its supply voltage, remaining constant in magnitude, changes are relative to the common Bus in phase with a change in the input signal. Therefore, the dynamic range of the input voltage of the converter does not depend on the maximum value of the admissible common-mode input signal of the differential operational amplifier, but is determined by the supply voltages of the sources 2 and) of the current, while the gain of the converter is more than unity.

The output resistance of the converter, equal to the ratio of the output resistance of an open differential operational amplifier 1 to the product of its gain and feedback coefficient (the ratio of the resistance of the second resistor of the voltage divider 6 to the sum of the resistances of the first and second resistors), can be arbitrarily small.

Since the input of the converter with respect to the supply voltage of the differential operational amplifier 1 is under a constant potential difference, the influence of the in-phase component of the input signal on the conversion error is eliminated, while the error from the finiteness of the value of the common-mode voltage suppression coefficient is completely excluded.

Claims (1)

This invention relates to analog computing. The purpose of the invention is to expand the field of application by obtaining a conversion factor greater than one and reducing the output impedance. The drawing shows the functionality of the scale converter circuit. The converter contains a differential operational amplifier two voltage sources 2 and 3, two parametric voltage regulators 4 and 5, a voltage divider 6 consisting of two resistors, information input 7 of the converter, output .8 of the converter, and an additional operational amplifier 9. Scale The converter operation is as follows. Parametric stabilizers 4 and 5 voltages, in which silicon zener diodes can be used, ensure the supply voltage of the differential op amp I over the entire working range of the input voltages. The current required for power supply differential operational amplifier 1 and parametric stabilizers 4 and 5, is set by sources 2 and 3 currents, which are fed by the voltage + E and-E, the gain of the converter, with a sufficiently large gain of the amplifier .1 is equal to the sum of the resistance values of the first and second resistors of the divider 6 to the value of the resistance of the second resistor. The voltage on the non-inverting input of the additional operational amplifier 9, equal to the static error of the amplifier 1 to the input voltage of the converter, is repeated by the Additional operational amplifier 9 and from its output through the parametric stabilizers 4 and 5 goes to the power supply bus of the differential operational amplifier, etc. The power supply, remaining constant in magnitude, varies with respect to the common 1 pin in phase with the change in the input signal. Therefore, the dynamic range of the input voltages of the converter does not depend on the maximum value of the allowable common-mode input signal of the differential operational amplifier, but is determined by the supply voltages of the sources 2 and the current, and the gain of the converter is greater than one. The output impedance of the converter, equal to the ratio of the output impedance of the open differential opamp 1 to the product of its gain and feedback coefficient (the ratio of the resistance of the second resistor of the voltage divider 6 to the sum of the resistances of the first and second resistors), can be arbitrarily small. Since the input of the converter with respect to the supply voltages of the differential operational amplifier 1 is subject to a constant potential difference, the influence of the common-mode component of the input signal on the conversion error is excluded, and the error of the extremity of the suppression factor of the common-mode voltage is completely eliminated. Claims of the invention A scale converter containing a differential operational amplifier, connected by a non-inverted input to the information input of the converter, and the output connected via a voltage divider on series-connected resistors to a zero potential bus, are connected positively and negatively to the power supply buses of the converter using different polarity current sources with the corresponding power lines differential operational amplifier and the inputs of the first and second parametric stabilizers voltage selectors (so that, in order to expand the scope of application by obtaining a conversion factor greater than one and decreasing the output impedance, an additional, additional operational amplifier connected by a non-inverting input to the inverting input of the differential operational amplifier and to the middle the output of the voltage divider, the outputs of the first and second parametric voltage regulators are connected to the output and inverting input of the additional operation of the UN amplifier The output of the differential operational amplification is the output of the transducer.