SU1451735A1 - Function generator - Google Patents

Abstract

The invention relates to analog computing and can find application for modeling simulation schemes with non-linear characteristics of an arbitrary type. The aim of the invention. The NC is an extension of the class of functions reproduced by the generator. The function generator contains the first 1 and second 2 differential voltage amplifiers, the first differential summing voltage amplifier 3, the summing voltage amplifier 4, the second differential summing voltage amplifier 5, the third differential voltage amplifier 6, the first 7 and the second 8 scale resistors , fifth scale resistor 9, fourth scale resistor 10, sixth scale resistor 11, third scale resistor 12, input 13, output 14, intermediate terminals 15 and 16, second 17 and first 18 non-linear scale resistors. Achieving this goal is ensured by introducing into the generator the functions of two differential-summing voltage amplifiers and two large-scale resistors, as well as a new connection between the elements. 1 il. SP 00 ate

Description

The invention relates to analog computing, namely to the class of generalized generators, devices that transform the character of Harpys ki according to a given non-linear law, and can be used to model systems with non-linear characteristics of arbitrary type.

The aim of the invention is to extend the class of functions reproduced by the generator.

The drawing shows a diagram of the generator functions.

The function generator contains the first 1 and second 2 differential voltage amplifiers, the first differential summing voltage amplifier 3, the summing voltage amplifier 4, the second differential

summing voltage amplifier 5, third differential amplifier 6, voltage first 7, second 8, fifth 9, fourth 10, sixth 11 and third 12 scale resistors, input 13, output 14, intermediate terminals 15 and 16, first 17 and second 18 non-linear scale resistors.

The function generator works as follows.

Let us denote the voltage on the terminals 13–15, the second nonlinear scale resistor 17, the clamp 16, and the first nonlinear scale resistor 18 with respect to the zero potential bus, respectively, U; | –U6.

The matrix of the nodal conductivities of the function generator relative to the nodes numbered above is

(1-k ,,) G, O

ABOUT

ABOUT

ABOUT

about

de G.,, 12 - i-ro conductivity

a resistor;

TO; ; - the amplification factor of the i-ro amplifier 6), the voltage across the non-inverting input, if, and both the inverting and non-inverting inputs when

i # j;

about

oh oh

R

oh oh

(U4)

and (Uj) are the current-voltage characteristics of the nonlinear scale resistors 18 and 17. Provided that K K2. -K1 -K „-K5G-K 5 -K for K5 ,, 1,; G 7- (, 0-0 „- G, j 1, the matrix of the function generator is reduced to the form

145

Reduction YJ relatively input

(13-0) and output (14-0) function generator clamps gives

, (yi)

iG

about

S

aif2 (y,)

and.

ABOUT

then by definition it gives the matrix of the probabilities of a generalized nonlinear irator with nonlinear gyration PROBODIMOST, (U) / U and,) /, respectively.

If we take the load impedance equal to Z c (and it can also be non-linear), then the input current of the gyrator, f i (U J.

Thus, in particular cases with aif 1 (and), (and,) agi, we get i-t - the usual linear gyrator (for linear load); at (and, 2) a, i.1, (V) - or i, / U ,, is the conductivity controlled by the voltage and ,; when, (Ui) a / j, aifi (Uj ar.i1 | -, ((degrees m and n are multiplied); when a, | f 1))

b (), aif (U i) ajU, - i, b. Salinu,

% (1 -1) - transformed diode characteristic (b, c - coefficients with dimensions, respectively, a and; - active load resistance), etc.

Claims (1)

Invention Formula Function generator, containing the first, second and third differential voltage amplifiers, between the outputs and non-inverting inputs of which are included the first, second and third large-scale resistors, the summing voltage amplifier, between the output and the first non-inverting, respectively. 1735 The input of which includes a fourth scale resistor, a first non-linear scale resistor connected between a non-inverting input, a third differential voltage amplifier and a zero potential bus, and a second non-linear scale resistor, non-inverting inputs 10 of the first and second differential voltage amplifiers are input and output respectively generator, and the second non-inverting input of the summing voltage amplifier 15 is connected to the inverting input the first differential voltage amplifier, characterized in that, in order to expand the class of reproducible functions, 2Q of the first and second differential-sum voltage amplifiers and the fifth and second large-scale resistors, which are connected between the outputs and the first non-inverting inputs, are included in it 25, respectively, of the first and second differential summing voltage amplifiers connected by the second non-inverting inputs to the non-inverting inputs of the second and the first differential amplifiers, respectively. The first non-inverting inputs of the differential-summing voltage amplifiers are connected to the inverting inputs of the first and second differential voltage amplifiers, respectively, and their inverting inputs are connected to the third non-inverting input of the third voltage amplifier and the inverting input of the third differential amplifier. a voltage amplifier connected by an inverting input to the output of the generator, the second non-linear scale resistor is connected between the first non-inverted the input of the summing voltage amplifier and the zero potential bus. 35 45