CS210936B1 - Involved to control immunity dipoles - Google Patents

Abstract

So far, electrical analog and non-electrical control of imitation dipoles has limited possibilities in the accuracy of setting the input or transfer imitation and thus limited use. According to the invention, the circuit for controlling the immittance dipoles consists of a digital-analog converter with a connected control variable and ground potential terminals, while a controlled immittance is connected to the circuit. This controlled immittance can be connected either between the input and output terminals of the multiplying digital-analog converter or between the input terminal of the digital-analog converter and the ground potential terminal. Both alternatives are shown in the circuit diagram. The use is expected for digital control, measurement.

Description

(54) Connected to control immittance dipoles

So far, electrical analog and non-electrical control of imitation dipoles has limited possibilities in the accuracy of setting the input or transmission imitation and thus limited use.

According to the invention, the circuit for controlling the immittance dipoles consists of a digital-to-analog converter with a control variable connected and ground potential terminals, and a controlled immittance is connected to the circuit. This controlled immittance can be connected either between the input and output terminals of the multiplying digital-to-analog converter or between the input terminal of the digital-to-analog converter and the ground potential terminal.

Both alternatives are shown in the wiring diagram. The use is expected for digital control, measurement.

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The invention relates to a circuit for controlling immittance dipoles.

Various methods of electrical analog and non-electrical control of immittance dipoles are known. Their disadvantage is the limited possibilities in the accuracy of setting the input or transfer immittance and thus also the limitations in the possibilities of use.

The above-mentioned shortcomings are eliminated by the connection for controlling the immittance dipoles according to the invention, the essence of which lies in the fact that the first and second terminals and the control terminals are connected to the multiplying digital-to-analog converter, and the controlled immittance is connected between the first and second terminals or between the first terminal and the ground potential terminal.

A significant advantage of the solution according to the invention is the digital control method, the accuracy of which in setting the value of the input or transmission immittance is theoretically unlimited.

The attached figure 1 shows the principle block diagram of the circuit for providing the product ' and in figure 2 for providing the ratio of the controlled immittance and the control digital quantity, according to the invention

The first terminal aa is connected to the input of the multiplying digital-to-analog converter 2 ³ and the second terminal b is connected to its output. The input voltage U^ is between the first terminal aa and the terminal c of the ground potential. The output voltage Ug is between the second terminal b and the terminal o of the ground potential. The input current I ₁ is conducted in the direction of the arrow, the input current i' is then the input current of the multiplying digital-to-analog converter £ and is marked with the arrow £. The input number representing the control quantity D is supplied to the control terminals 2 of the multiplying digital-to-analog converter 2'

If the controlled immittance 6 is connected between the first and second terminals a and b, the input admittance Ý _yst is determined

If the controlled immittance 6 is connected between the first terminal a and the terminal c of the ground potential, the transfer admittance Y _and ^ are determined. If the output voltage Ug holds

Ug = (1 - D) U,, where U, is the input voltage, and assuming that I'-»0, the following relation applies for the input admittance ^{: 1} τ

This relationship is the essence of the solution ab according to the invention for T _yst · Y

This relationship is the essence of the solution according to the invention for the transmission admittance.

The invention can be used in various applications such as a digitally controlled capacitor, where in conjunction with an RC oscillator a generator with digitally controlled output frequency is implemented and with further connection of digital feedback a digitally controlled phase loop is then created. Other possible applications include use in digital R, L, C measuring devices, digitally controlled filters and so on.

Claims (1)

SUBJECT OF THE INVENTION Wiring for impedance dipole control, characterized in that the first and second terminals (a, b) and the control terminals (7) are connected to the multiplying analogue converter (5) and the controlled imitation (6) is connected between the first and second terminals (a) , b) or between the first terminal (a) and the earth potential terminal (c).