SU720698A1 - Gyrator - Google Patents

Description

(54). GIRATOR

This invention relates to gyratory circuits built on booster amplifiers, which simulate ungrounded (floating) inductive elements. A gyrator of imitation non-injected inductive elements is known, containing three voltage amplifiers, the first of which is noninverting with a positive feedback resistive circuit, and the second and third with differential inputs and resistive circuits of positive and negative feedback, with In this case, the INPUT of the first voltage amplifier is connected to the first input terminal of the gyrator a, the second input terminal of the gyrator is connected to the non-inverting INPUT of the third voltage amplifier, to the outputs of the first and second amplifiers and are respectively connected among terminals of the resistor CCP and gyrator output is neinvertaruyShy second amplifier input voltage 1. However, the final values of the input impedance of the voltage amplifiers do not ALLOW to achieve the accuracy of the gyrator, i.e. they do not allow to achieve c6, the impedances (or individual elements) are calculated values. The purpose of the invention is to increase the accuracy of gyration . Lp of this In a well-known simulator for imitation of ungrounded inductive elements, containing three voltage amplifiers, the first of which is non-inverting with a resistive circuit of positive feedback, and the second and third with differential inputs and resistive circuits of positive and negative feedback, and the input of the first voltage amplifiers are connected to the gyratory head's first INPUT clamp, a second INPUT clamp of the gyrator is connected to the non-inverting INPUT of the third voltage amplifier, to the outputs of the first and second force The cooTBercTHOFiito voltage sensors are connected by the DCP terminals of the resistor, and the gyrator output is the rotating input of the second voltage amplifier, the second terminals of the resistors are connected to the non-inverter 11X1 bx6 d6m, the third voltage amplifier; the inverting input of which is connected to the output of the gyrator, between the output of the first and the non-inverting input of the second voltage amplifiers a third resistor is turned on, and the inverting input of the second amplifier 1v of the voltage is connected to the first Input terminal of the gyrator directly. The drawing shows the electrical circuit of the gyrator. The gyrator contains voltage amplifiers 1, 2, 3, and amplifier 1 is non-inverting with a resistive circuit of 4 positive feedback, amplifier 2 differential inputs and resistive circuits 5 and 6, respectively, of positive and negative feedback.

and amplifier 3 differential inputs and resistive circuits 7 and 8, respectively, positive and negative feedback, the first input terminal of the gyrator 9, the second terminal of the gyrator Yu, two resistors 11 and 12, the output terminal of the gyratory 13, the third resistor 14.

Gyrator works as follows. The input signals from terminals 9 and 1O are respectively fed to the non-inverting input of amplifier 3 and the inverting input of amplifier 2, and a single input of amplifier 1, which provide the output current at terminal 13 with a certain phase and proportionality coefficients, i.e., the output current is proportional to the difference of input voltages zheniy. The output voltage generates the required input current through terminals 9 and 10 with the proper phasing according to the equations given, using amplifiers 1-3 and through direct communication using resistors 4-8, 11, 1

14-.

(I) (2).

-v.U ,,

45)

, -J, and ai.

e j

- accordingly

o current and voltage - at the INPUT terminals 10 and 9 of the whole circuit.

positive feedback, and the second and third with differential inputs and resistive positive and negative feedback circuits, while

The input of the first voltage amplifier is connected to the first input terminal of the gyrator, the second input terminal of the gyrator is connected to the clockwise input of the third voltage amplifier, two resistors are connected to the outputs of the first and second voltage amplifiers, and the output of the gyratory is a non-inverting input of the second voltage amplifier distinguish u and c. By the fact that, in order to increase the accuracy of gyration, the second terminals of the resistors are connected to the non-inverting input of the third voltage amplifier,. which inverting input is connected

The third resistor is connected directly to the hopper, between the output of the first and the non-rotating input of the second amplifier, and the inverting input of the second voltage amplifier is connected to the primary input of the gyrator directly.

Sources of information taken into account in the examination

Claims (1)

1. US patent No. 3493901, CL. 333-80, 03.02.70 (prototype). 8 - output current and voltage at terminal 13, respectively; V - conductivity of gyration. The technical and economic efficiency of the proposed gyrator for imitating non-grounded inductive elements consists in increasing the accuracy of the gyration, i.e., the correspondence of the practically inverted impedances to the calculated values. Claims of the invention: A gyrator for imitating neu-grounded inductive elements, comprising three voltage boosters, the first of which is non-inverting with a resistive circuit.