DE1272998B - Amplifier arrangement with parallel and series feedback from the output to the input - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H03f

German KL: 21 a2 - 18/05

Number: 1272 998

File number: P 12 72 998.5-31 (S 105029)

Registration date: July 27, 1966

Opening day: July 18, 1968

, The invention relates to an amplifier arrangement with very high parallel and series feedback from Output to the input, in which the parallel feedback via a T-element and the series feedback via a two-pole, which consists of a parallel connection of an ohmic resistor and a There is reactance.

In the case of amplifiers, a combined application of series and parallel negative feedback can be used generate the desired input and output resistances of the amplifier, which are independent of the properties which are not negative feedback amplifiers. In this way, adjustment is made on the generator and Load resistance achieved without signal power being lost in additionally connected matching resistors.

In order to implement such a negative feedback in practice, transformers are generally used used. However, the use of transformers comes up against resistance, especially when the requirement is asked to build an amplifier in integrated circuit technology, since large inductances in this special technology are very difficult to achieve.

The object of the invention is to create an amplifier arrangement in which without the use of Transmitter the setting of any real, frequency-independent input and / or output resistance is possible. . . ,

According to the invention, the amplifier arrangement is designed in such a way that with a high-impedance, real terminating resistance at the amplifier output and the real resistance value of the input-side series resistance dek T-element, the resistances in the negative feedback branches are dimensioned so that the ratio of the reactive component of the shunt-branch resistance of the T-element to The reactance of the two-terminal network is smaller by the number 1 than the ratio of the input-side series branch resistance of the T-element to the size of the ohmic resistance of the two-terminal network.

These measures ensure that the input resistance of the amplifier is real and independent of frequency and equals the size of the ohmic resistance in the two-terminal network. This will make the Allows adaptation to any real generator resistance.

In a further embodiment of the invention, the amplifier arrangement can also be designed so that with a high-impedance, real terminating resistor at the amplifier input and the real resistance value of the the output-side series resistance of the T-element is the resistances in the negative feedback branches

Amplifier arrangement with parallel
and series feedback from the output
on the entrance

Applicant:

Siemens Aktiengesellschaft, Berlin and Munich, 8000 Munich 2, Witteisbacherplatz 2

Named as inventor:

Dipl.-Ing. Hubert Gölz, 8000 Munich

are dimensioned so that the ratio of the reactive component of the shunt arm resistance of the T-link to the reactance in the two-pole is smaller by the number 1 than that

", Ratio of output-side series branch resistance

ao of the T-element and the size of the ohmic resistance in two-pole.

This means that the output resistance of the amplifier can always be made real and independent of frequency, which enables a good adaptation of the amplifier output to any real load resistance will.

In a further embodiment of the invention, the shunt arm resistance of the T-element and the two-pole

■: consist of ohmic resistors' and the output side Series branch resistance of the T-link can be a frequency-dependent resistance. Here receives one has the advantage of a real input resistance and at the same time a frequency-dependent gain,

- However, complete independence between the setting of the real frequency-dependent input resistance and the adjustability of the desired frequency-dependent gain is given. Power instead of the series branch resistance on the output side, the series branch resistance on the input side is used frequency-dependent, the output resistance becomes real with frequency-dependent gain, where also again gain setting and output resistance setting are independent of each other.

If the shunt resistance of the T-link and the reactance of the two-terminal network are formed as capacitances, one obtains a circuit which can be used particularly advantageously for integrated circuits because only capacitors and ohmic resistors have to be used in this arrangement. In addition, a measure of this type allows the gain to increase with increasing

809 570/387

Achieve frequency. If the shunt arm resistor is used, FIG. 3 shows a similar amplifier arrangement

stood the T-member and the reactance of the as in Fig. 2, with the difference that the

Two-pole as inductivities, so with an input resistance high resistance and the output

such a circuit with increasing frequency a real resistance independent of frequency and freely adjustable

Reduction in gain can be achieved. Is 5 bar;

If you switch one amplifier stage each, which is set to real F i g. 4 shows a circuit arrangement with radio frequency-independent Input resistance measured ohmic terminating resistance, which is, however, with such an amplifier stage with real gain decreases with increasing frequency; frequency-independent output resistance via a F i g. Figure 5 shows an amplifier arrangement, one Decoupler stage together, the decoupler stage io amplifier stage with adjustable input resistance expediently a strongly counter-coupled tran- and an amplifier stage with an adjustable output transistor stage should be in the emitter circuit, you get resistance via an emitter stage connected to one another Amplifier arrangement in which both the input pelt are;

as the output resistance is real, independent of frequency. FIG. 6 shows an amplifier arrangement in which

and can be set independently of each other. 15 the shunt arm resistance 3? of the T-link imaginary

On the basis of the exemplary embodiments according to FIGS. 1 and 2, the two-pole resistor 3s is complex. the

F i g. 1 to 6 the invention is explained in more detail. Reactive resistances should be the same in terms of circuitry,

Fig. 1 shows the basic circuit diagram of an amplifier, but dimensioned reciprocally with respect to one another

arrangement, in the case of high-resistance termination.

stand with a combined current voltage 20 If one sets the current ratio negative feedback, a real frequency-independent input resistance can be generated; Μι = - -><x>,

F i g. 2 shows an amplifier arrangement in which at Z _{1 a} high-impedance termination through combined current-voltage negative feedback at the output, a real 25 which can be set with a very strong negative feedback constant frequency-independent resistance; which is significant, one obtains for the input impedance gain increases with increasing frequency; Wb stood the following formula:

_{Wjs =} 3 * IZaF _x + S ₂ F ₁ + S ₁ ] (Q ₂ Fa + S ₁ )

[F ₂ (Z. F ₁ + S ₂ F ₁ + Si) - Za] + Z _a (S ₂ F ₁ + Si)

A corresponding relationship is obtained for the output resistance Wa

_{Wa =} 3 * [S ₉ F ₂ + Si F ₂ + SJ (Si F ₂ + S ₂ )

3 * [F ₁ (R _g F ₂ + Si F ₂ + S ₂ ) - Rg] + Rg (Si F ₂ +

The voltage gain v «becomes arbitrary in such a way. For Si = ^ i and 82 one obtains the Case 40 matching condition

3 «-

_- U ₁

«L S * ZaF ₁ + (S ₂ F ₁ + Sl) Xs Rs

Is Hierb _egg for 45 _{ffierbei ahead} g _ese TZT that Z _a> S ₂ + ^ - ·

^ ₁ - ι - | _ 5i The input resistance We is then obtained

.... 3 » We ^ Rs.

and for

ρ _ - · ι Sa- 5ο Conversely, if one sets 32 - -Ra ^{un (} i Si

² ~~ "·" ο any, you get the comparison conditions for

the output resistance FF ^ set.

S ₁ and S2 are the series resistances of the im ^g = j ^ L _ 1.

Parallel feedback path lying T-link, and 55 X ₃ R _s

Sp is the cross resistance, and 3 "represents the two-terminal series feedback. Should μι With The generator resistance must the gain of the amplifier arrangement without

Be referred to as negative feedback. R _g ^. Q ₁ _ | _ A.

If one sets a pure reactance 60 F _{2 for the impedance 3p}

dance Xp, be a parallel circuit for the impedance Ss.

from a resistance R ₈ and a reactance X _s , so the output resistance is then

you get

; ν Wa r * Rs-

ρ - JA- _V ,

j>, - Y " Since in one case the series branch resistance 3

gg S ₂

_f and in the other FaU the series branch resistance des

R ₈ 4- j X ₈ T-link Si the input or output resistance

These impedances can be used for this purpose, but not co-determined, but influencing the gain to change the gain frequency response.

Claims (8)

Patent claims: 1. Amplifier arrangement with very high parallel and series feedback from the output to the input, in which the parallel feedback takes place via a T-element and the series feedback via a two-pole, which consists of a parallel connection of an ohmic resistor and a reactance, characterized in that With a high-resistance, real terminating resistor (Ζ «) at the amplifier output and the real resistance value of the input-side series resistance (3i) of the T-element, the resistances in the negative feedback branches are dimensioned in such a way that the ratio of the reactive component of the shunt-branch resistance (3p) of the T-element to the reactance (X ₈ ) of the two-pole is smaller by the number 1 than the ratio of the input-side series branch resistance (Q ₁ ) of the T-element to the size of the ohmic resistance (R ₈ ) of the two-pole. 2. Amplifier arrangement with a very high parallel and series feedback from the output to the input, in which the parallel feedback takes place via a T-element and the series feedback via a two-pole, which consists of a parallel connection of an ohmic resistor and a reactance, characterized in that In the case of a high-resistance, real terminating resistor (R _g ) at the amplifier input and the real resistance value of the series resistance (Q ₂ ) on the output side of the T-element, the resistances in the negative feedback branches are dimensioned in such a way that the ratio of the reactive component of the shunt-branch resistance (2p) of the T-element to Reactance (X ₈ ) of the two-terminal network is smaller by the number 1 than the ratio of the output-side series resistance (Q ₂ ) of the T-element to the size of the ohmic resistance (R ₈ ) of the two-terminal network. 3. Amplifier arrangement according to claim 1, characterized in that the shunt arm resistance of the T-element and the two-terminal network consist of ohmic resistors and the output side Series branch resistance of the T-link is a frequency-dependent resistance. 4. Amplifier arrangement according to claim 2, characterized in that the shunt arm resistance of the T-element and the two-terminal network consist of ohmic resistors and the input side Series branch resistance of the T-link is a frequency-dependent resistance. 5. Amplifier arrangement according to claim 1 or 2, characterized in that the shunt arm resistance of the T-member and the reactance of the two-terminal network are capacitances. 6. Amplifier arrangement according to claim 1 or 2, characterized in that the shunt arm resistance of the T-member and the reactance of the dipole are inductances. 7. Amplifier arrangement according to claim 1, characterized in that it has a decoupling stage is connected to an amplifier arrangement according to claim 2. 8. Amplifier arrangement according to claim 7, characterized in that the decoupling stage is a strongly negative feedback transistor stage is in common emitter circuit. 1 sheet of drawings 809 570/387 7.68 © Bundesdruckerei Berlin