DE2118607A1 - Integrable earth-unbalanced gyrator - Google Patents

Description

Integrable earth-unbalanced gyrator (addendum to patent. ... ... (Aktz. P 19 33 120.5)) The invention relates to an unbalanced earth Gyrator with a 0 ° quadrupole and a 180 0 quadrupole, the are connected anti-parallel. Each four-pole transmission exists here from an input switching stage and an output switching stage and has a voltage input and a current output lying on one side at reference potential.

Gyrators are positive impedance inverters, with the help of which a switching element can be implemented in a dual switching element for this purpose. They have a special meaning in the construction of electronic semiconductor circuits, in particular filter circuits for the alternative realization of inductivities, importance gained. Since it is If this is equivalent circuits, there is an effort to take them into account the high demands placed on them with regard to low transmission losses, high temperature stability, largely independent of supply voltage fluctuations and high input and output resistance in monolithically integrated technology if possible easy and space-saving to design.

In the main patent, such a gyrator is specified in which thereby with a small number of resistors and a relatively low supply voltage it is managed that the input circuit stage of a four-pole transmission one voltage-controlled current source and its output circuit stage a current-controlled Power source is, to the output of which is connected to a DC operating voltage Operating current source is in parallel and in which the input circuit stage of the four-pole transmission comprises at least one transistor with a high-impedance input.

The invention is based on the object of an unbalanced-earth Gyrator according to the main patent with regard to its effective efficiency and its To further improve the basic quality.

This object is achieved according to the invention in that the current-controlled The current source of the two transmission four-poles has a current gain greater than 1, preferably 2 to 5.

When using a gyrator to implement an inductance - results for the ratio of the reactive power that represents the gyrator circuit Inductance to the total power dissipation of the circuit a value that is known with Switching is far below 1%. In the gyrator circuit according to the main patent this ratio, which represents the effective efficiency, lies in the use of current-controlled current sources at about 1. By the measure according to the invention this efficiency can be increased further. For example, for executed patterns with a current gain of the current-controlled current sources of two an efficiency achieved by approx. 2%. The measure according to the invention not only improves the efficiency of the overall arrangement, but also improves the Basic quality of the gyrator circuit, because here with a given input impedance of the gyrator with a good approximation of the gyration resistance by the factor of the current amplification current-controlled power source is reduced.

When the gyrator according to the invention, the gyrator losses and thus its basic quality essentially depends on the losses of the input circuit stages representing voltage-controlled current sources of the two transmission poles certainly. Provided that the voltage-controlled current sources of the two four-pole transmission from an npn transistor, the base of which is against reference potential outputs the voltage input for the voltage-controlled current source, and a conductance exist, and under the further prerequisite that on the one hand at a transmission four-pole the transistor with its collector with the input of the current-controlled current source and connected to its emitter via the conductance with an operating calibration voltage is and on the other hand at the other transmission quadrupole the transistor with his Collector with a DC operating voltage and with its emitter via the conductance is connected to the input of the current-controlled power source, can be extraordinarily advantageously a further improvement in the basic quality of the gyrator realize that the transistor of the voltage controlled current source of each of the both transmission poles is a super ß-transistor. This is then the DC operating voltage to choose less than the breakdown voltage of the super-ß-transistor.

Furthermore, it can be useful to compensate or

Overcompensation of losses to the input of the voltage controlled Power source, preferably both transmission poles to connect a negative impedance in parallel.

The same result can also be found, in an extraordinarily advantageous manner Way to achieve that the current controlled current source, preferably both Transmission four-pole, is dimensioned for a negative output-side resistance. Such a current-controlled current source, which in its basic structure differs from that in the IEEE Journal of Solid State Circuits, Vol. Sc-3, No. 4, December 1968, Page 344, left column, Fig. 6a, specified basic circuit for a current-controlled Power source goes out, has already been proposed (P 20 35 969.7).

Using an exemplary embodiment that is shown in the drawing is, the invention will be explained in more detail below. In the drawing Fig. 1 shows the circuit diagram of an unbalanced gyrator according to the invention, Fig. 2 shows an embodiment of a current-controlled current. source with negative output resistance.

The unbalanced earth gyrator according to Fig. 1 consists of the anti-parallel Interconnection of a 0 0 quadrupole and a 180 0 quadrupole. Each of the two four-pole transmission consists of an input circuit stage and an output circuit stage. The input circuit stage, a voltage controlled Current source, is each from a transistor Tr1 and Tr1 'with the one in the emitter lead arranged conductance g formed. When the transmission quadrupole of FIG. 1 is on the left the Transistor Tr1 'with its collector connected to the input of the current-controlled Power source SS 'connected. The current-controlled current source SS 'works with her Output to the operating current source Q2 ', which with its second connection with the negative DC operating voltage Ub- is connected. With the negative DC operating voltage The transistor Trl is also connected on the emitter side via the conductance g. At the On the right transmission quadrupole, the transistor Tr1 is on the emitter side via the conductance g connected to the input of the current-controlled current source SS, which in turn on the output side via the operating current source Q2 with the positive operating DC voltage Ub + is connected. The transistor Tr1 is also connected to the positive on the collector side DC operating voltage Ub + connected.

The base connections of the transistors Tr1 and Tr1 'each form the Voltage input of one of the two transmission poles, while the common connection point the outputs of the current-controlled current sources SS and SS! with the operating power sources Q2 and Q2t give their output.

As shown in FIG. 1, both four-pole transmission poles are antiparallel interconnected. Connections 1 and 1 'then result in the input terminal pair and the terminals 2 and 2 'the output terminal pair of the gyrator or vice versa. The current-controlled current sources SS and SS 'are for current amplification by the Factor, which is> 1 here. When applying an input voltage ue at the terminals 1, lt is the direct current flowing in the collector of the transistor Tr1 ' I1 'the alternating current i' is superimposed. At the output of the current-controlled current source SS 'this stream appears to be hidden by the factor n. The operating DC power source Q2 'is dimensioned so that that the direct current flowing through them I2 ' = n. I1 'is.

The alternating current i1 ', amplified by the factor n, is generated at the with at the connections 2, 2 'connected, not shown consumer the Voltage drop, etc. The electrical conditions at the right four-pole transmission correspond to those of the left transmission quadrupole. The one in the emitter of the transistor Trl flowing direct current 11 is with applied input voltage ue or between the voltage occurring at the terminals 2, 2 'is increased by the alternating current i, among other things. This current then occurs by the factor at the output of the current-controlled current source SS n stepped up. The direct current I2 flowing through the operating current source Q2 is equal to the direct current 11 amplified by the factor n.

In the gyrator circuit of FIG. 1, the transistors Tr1 and Tr1 'designed as npn transistors. The circuit can of course be used in the same way Way to realize with pnp transistors. The embodiment shown in FIG however, has the advantage that here the transistors Tr1 and Tr1 'as super-ß-transistors can be carried out, which, as has already been pointed out in the introduction is, brings about an improvement in the basic good of the gyrator circuit.

To compensate for inevitable losses, it is still possible to at least the input of one of the two transfer poles has a negative resistance to connect in parallel. This can be done in an extremely simple manner, as shown in Fig. 1 shown un broken line, can be realized in that the base of the transistor Tr1 against the positive DC operating voltage Ub + the collector-emitter path de, s e transistor Tr2 in series with the emitter-side resistance Rn- is connected in parallel. The base of this transistor is with the collector of the transistor Trl connected. However, the collector of this transistor must be in this Trap connected to the positive DC operating voltage Ub + via a resistor be. This resistance is in the present case by the in the forward direction polarized diode D formed, whereby the same temperature behavior is achieved. the The voltage drop across the forward resistance of the diode D controls the transistor Tr2 so that it is like a negative resistor in parallel with the input of the transistor Trl works. In a similar way, such a negative resistance can be paralleled to Realize the input of the transistor Tr1 of the left quadrupole transmission.

Instead of the negative resistances, parallel to the inputs of the four-pole transmission there is also the possibility, in an advantageous manner, of the current-controlled current sources SS and SS 'to be dimensioned simultaneously for a negative resistance on the output side. In this way, losses can be compensated for in a corresponding manner. In Fig. 2 is such an integrable controllable power source, which in this case is the controllable Current source SS of Fig. 1 corresponds to shown. It consists of four transistors of the same conductivity type Tr3, Tr4, Tr5 and Tr6, of which the transistors Trh to Tr5 an embodiment specified by Wilson for a current-controlled Represent power source. Through the further transistor Tr6, which is on the collector side with the positive DC operating voltage Ub + is connected to the emitter side via the optionally adjustable resistor Rn to the common connection point of the emitter of the transistor Tr5, the collector of transistor Tr4 and the base of the transistors Tr3 and Tr4 is connected and on the base side with the collector of the transistor Tr5 is connected S can be a negative output-side resistance of this current-controlled Realize the power source The input side into the current-controlled power source The current II + i flowing in does not only appear at the output by the factor n amplifies but also has a negative alternating current component in the form of the current in, which represents the negative resistance on the output side. the The size of the negative alternating current in can be determined by the choice of the resistor Rn will.

The current gain of the current-controlled current source between input and output by a factor of n can be achieved when using monolithically integrated technology in a simple manner by suitable choice of the topological area ratios of the Transistors Tr3 to Tr5 can be realized. in a corresponding manner can also the current-controlled current source SS 'according to FIG. 1 can be constructed. Instead of npn transistors PNP transistors must be provided here.

4 claims 2 figures

Claims (4)

Claims (1.) Unbalanced earth gyrator with a 00 four-pole transmission and a 1800 quadrupole transmission connected together in anti-parallel that of each transfer quadrupole from an input circuit stage and an output circuit stage exists, and a voltage input and a one-sided at reference potential Having current output, in which furthermore the input circuit stage of a transmission quadrupole eie voltage-controlled current source and its output circuit stage a current-controlled The current source is the output of which is connected to a DC operating voltage (Ub +, Ub-) connected operating power source is in parallel and in which the input circuit stage the four-pole transmission comprises at least one transistor with a high-impedance input, according to patent 1 933 120, characterized in that the current-controlled current source (SS, SS ') of the two four-pole transmission a current gain> 1, preferably 2 to 5. 2. Unbalanced earth gyrator according to claim 1, wherein the voltage controlled Current source of the two transfer poles from an npn transistor, whose base against reference potential the voltage input for the voltage-controlled current source emits, and there is a conductance at which, on the one hand, there is also a four-pole transmission the transistor with its collector with the input of the current-controlled current source and connected to its emitter via the conductance with a DC operating voltage and on the other hand at the other four-pole transmission the transistor with his Collector it a DC operating voltage and with its emitter is connected to the input of the current-controlled current source via the conductance, characterized in that the transistor (Tr1, Tr1 ') is the voltage-controlled Current source of each of the two transmission poles is a Superß transistor and the positive DC operating voltage less than the breakdown voltage of the super-ß-transistor is chosen. 3. Unbalanced earth gyrator according to claim 1 or 2, characterized in that that the input of the voltage-controlled current source (S), preferably both transmission poles a negative impedance is connected in parallel. 4. Unbalanced earth gyrator according to claim 1 or 2, characterized in that that the current-controlled current source (SS, SS ') preferably both transmission four-pole is dimensioned for a negative output-side resistance.