SU1149385A1 - Simulator of mutual inductance - Google Patents

Abstract

IMITATOR IN DEEP INDUCTANCE, containing two gyrators, two load capacitors and the first coupling capacitor, characterized in that, in order to increase the quality factor of the simulated mutual inductance, each generator is made on a multi-stage voltage converter into a current, one of which is performed on an operational amplifier the input and output of which is connected to the corresponding load capacitor, the first communication capacitor is connected between the output of the operational amplifier of the first gyrator and the input of the operational usi Ithel second gyrator, and entered a second capacitor connection connected between the output of the operational amplifier and a second gyrator input of the first operational amplifier gyrator. 4 QD 00 00 ate

Description

The invention relates to electrical engineering and radio engineering and can be used in selective circuits containing self-induction.

Known simulator of mutual inductance, consisting of two gyrators and two capacities [IO However, this simulator of mutual inductance has a low quality factor of mutual inductance due to the shunting of both terminals of each gyrator with resistors. In addition, the adjustment of simulated coupled inductances is difficult due to the need to use gyration resistance of gyrators as an adjustment element.

Closest to the invention is a mutual inductance simulator containing two gyrators, two load capacitors, and a coupling capacitor connected between the load capacitors [2].

However, the known simulator of mutual inductance has a low quality factor of mutual inductance due to the shunting of both terminals of each gyrator with resistors.

The purpose of the invention is to increase the quality factor of simulated mutual inductance.

This goal is achieved by the fact that in the simulator of mutual inductance, containing two gyrators, two load capacitors and the first capacitor <; bind, each gyrator is made on a multistage voltage-to-current converter, one of the stages of which is made on an operational amplifier, between the input and output of which the corresponding load capacitor, the first coupling capacitor is connected between the output of the operational amplifier of the first gyrator and the input of the operational amplifier of the second gyrator, and a second capacitor is introduced ides connected between the output of the operational amplifier of the second gyrator and the input of the operational amplifier of the first gyrator.

The drawing shows a diagram of a simulator, and on the other hand.

The mutual inductance simulator contains two gyrators 1 and 2, each of which is made on a multi-stage voltage-to-current converter with operational amplifiers 3 and 4, respectively, load capacitors 5 and 6, respectively, and first and second coupling capacitors 7 and 8. The unloaded poles of the gyrators 1 and 2 are respectively the input and output of the mutual inductance simulator.

A simulator of mutual inductance works as follows.

The current flowing through the coupling capacitors 7 and 8 is proportional to the voltage at the input of the mutual inductance simulator, and the proportionality coefficient is independent of frequency. The current flowing through resistors 9 connected to the inputs of operational amplifiers 3 and 4 is proportional to the voltage at the input and, respectively, to the output of the mutual inductance simulator, and the proportionality coefficient is also independent of frequency. Due to the fact that the operational amplifier 3 and 4 is covered by local negative feedback, the input impedance of the circuit from the input side of the operational amplifier 3 or 4 is zero. Therefore, the current of the specified input is equal to the sum of the currents of the elements connected to this input. Further, the current flowing through the input and output of the mutual inductance simulator is proportional to the input current of the operational amplifier 3 or 4, and the proportionality coefficient contains joe in the denominator, since the local negative feedback of the operational amplifier 25 or 4 is created only by capacitors 5 or 6, respectively. Therefore, the current flowing through the inputs and outputs of the mutual inductance simulator is equal to the sum of the voltages on them, and at each voltage there is a coefficient containing j © in the denominator. So, for example, the expression for the gyrator current 1 has the form

It can be seen from this expression that the proposed circuit imitates not only self-induction, but also mutual induction.

4Q Due to the fact that capacitors 5–8 are connected only to the inputs and outputs of operational amplifiers 3 and 4, there is no shunt effect of circuit resistors on them. Therefore, the quality factor of the proposed device is higher than the quality factor of the known device.

Thus, the specified connection of capacitors with resistors and operational amplifiers leads to an increase in 50 quality factor of simulated mutual inductance, which distinguishes the proposed device from the known.

Claims (1)

MUTUAL INDUCTIVITY SIMULATOR containing two gyrators, two load capacitors and a first coupling capacitor, characterized in that, in order to increase the quality factor of the simulated mutual inductance, each generator is made on a multistage voltage-to-current converter, one of the stages of which is made on an operational amplifier, between the input and the output of which includes the corresponding load capacitor, the first coupling capacitor is connected between the output of the operational amplifier of the first gyrator and the input of the operational amplifier torogo gyrator, and put the second coupling capacitor connected between the output of the operational amplifier and a second gyrator input of the first operational amplifier gyrator. SO GO OO SL