SU473190A1 - Functional converter - Google Patents

Description

(54) FUNCTIONAL CONVERTER

one

The invention relates to the field of computer technology and can be used, for example, to form predetermined functional dependencies in an industrial automation system.

A functional converter with a piecewise-linear approximation is known, which contains the slope setting potentiometers connected in parallel between the input of the converter and the potential-free bus, and in parallel the transistor cells connected in parallel. The collector of the output transistor of each cell is connected to the negative terminal of the supply voltage source, and the emitter is connected to the output of the converter and through two corresponding series-connected emitter resistors to the midpoint of the limiting potentiometer connected to the outputs of the reference voltage source.

However, the accuracy of reproduction of the functions of such a converter is low due to temperature instability, and its adjustment to reproduce a given function is very laborious.

In the proposed functional converter, in order to increase accuracy and simplify tuning, each transistor cell contains two transistors, the base of the first of which is connected to the midpoint

the corresponding slope setting potentiometer, the collector is connected to the negative terminal of the power supply source, to which the collector of the second transistor and the base of the output transistor are connected via a collector resistor. The emitters of both transistors are connected via a third emitter resistor to the positive terminal of the power supply, and the base of the second transistor is connected to a common point of the first and second emitter resistors.

The converter circuit is shown in the drawing.

It contains the slope setting potentiometers, transistor cells 2i-2n, which include output transistors 3i-3 ", two emitter resistors each and 5i-5p, limiting potentiometers 6i-b,

two transistors 7i-7 "and Sj-8", the emitters of which are connected to the third emitter resistors 9i-9p. The collector of each second transistor 8i-8 "is connected to a power source via a collector

resistor Id-lOn. The power supply terminals are labeled 11 and 12, and the reference power supply terminals are 13 and 14. The function converter works

in the following way.

The steepness of the linear sections of the approximation is set with potentiometers L -1 „. The input voltage is applied to the inputs of the non-volatile transistors.

In.

Each transistor cell 2 | -2 „is assembled according to the DC voltage compensating voltage regulator circuit and serves as a DC amplifier. In this case, the voltage at the output of the cell corresponds to its input voltage with a proportionality factor determined by the division factor of the divider consisting of resistors 4i-4.1 and 5i-5p.

The effect of temperature on the stability of the gain is small, since the temperature instabilities of transistors 1 and 8 cancel each other out, and the temperature instability of the base-emitter transition of transistor 3i is weakened by deep negative feedback from the splitter (resistors 4i-5i) to the base of transistor 8i. Connecting the common point of resistors 4i and 5i to the midpoint of the limiting potentiometer at which the voltage is set to set the offset level of the corresponding linear portion of the approximated function allows you to adjust the offset level without changing the slope.

Each transistor cell in combination with li-In and 6i-Bq potentiometers ensures the formation of a linear dependence of the output voltage on the input voltage.

Since the emitters of the transistors are connected together, the maximum voltage from the entire set is separated at the output terminal 15 of the functional converter. At the same time, only one transistor is always open, and all the others are closed.

Thus, the described functional converter ensures the independence of the adjustment of each of the linear sections of the approximated function to a given slope and initial level.

Subject invention

A functional converter containing slope setting potentiometers connected between the converter input and a zero potential bus, and transistor cells, the collector of the output transistor of each of which is connected to the negative terminal of the supply voltage source, and the emitter is connected to the output of the converter and through two corresponding series-connected emitter resistors - with a midpoint of a limiting potentiometer connected to the outputs of the voltage source, characterized in that in order to increase accuracy and

simplifying the setup; each transistor cell contains two transistors, the base of the first of which is connected to the midpoint of the corresponding warmth setting slope, the collector is connected to the negative terminal of the supply voltage to which the collector of the second transistor and the base of the output transistor are connected; emitters of both transistors through the third emitter resistor

connected to the positive terminal of the supply voltage, and the base of the second transistor is connected to the common point of the first and second emitter resistors.

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