DE2818980C2 - Adjustable attenuation equalizer - Google Patents

Description

The invention relates to an electric quadrupole

ίο trained adjustable damping eojzerrer, at the one at reference potential directly from an input terminal to an output terminal is switched through, consisting of capacitors, ohmic resistors and an amplifier, its amplifier input via a series connection of a first capacitor and a second Capacitor is connected to the input of the arrangement, the input of the arrangement via a first resistor is connected to a circuit node. from which, on the one hand, a second resistance to the input of the amplifier and on the other hand a third capacitor to that with the output of the Arrangement connected output of the amplifier leads.

For setting up carrier-frequency communication links As is known, equalizer circuits are also required. Circuits that are suitable To rectify distortions that occur on the transmission path. A special kind of that

so equalizers for equalizing frequency-dependent residual attenuation are attenuation equalizers that have one have a resonance-like course of the damping curve, and these equalizers are also known as so-called Called hump equalizer. With attenuation equalizers

r, this type can be given a predeterminable frequency ^ either a resonance-like increase or a resonance-like decrease in the damping curve achieve, and the attenuation increase or attenuation reduction that can be achieved is also called the attenuation stroke designated.

Such equalizers are often constructed as echo equalizers, which, however, generally require an undesirably high circuit complexity. To avoid this, RLC resonance equalizers are also known from DE-PS 18 05 461, for example. However, passive RLC equalization circuits always bring with them a basic attenuation. Through the article "Active Tone Control in Tantalum Thin Film Technology" by W. Bosselmann (Siemens Bauiei'e-Report, 4/1975. Pages 104 to 107), a coilless RC-active implementation of a damping noise generator has become known, but it is not all-pass is.

An arrangement of the type specified in the introduction is also based on the circuit 17 of one in Figure 8 of the Aufsat / es "Active /? C filters with four passive components" by N. Fliege (NTZ. 1960. Issue 12. Pages 689 to 693) specified circuit catalog. However, the realization is by means of the soundings specified there an adjustable attenuation equalizer with a contact-free adjustable hump frequency and height not possible.

The object of the present invention is, while avoiding the above-mentioned disadvantages, a coil-

loose realization of a Däfnpfüngsentzerrers the type mentioned by one reliable adjustability of both the damping hub * bes as well as the frequency / position of the maximum attenuation

mums or minimums by means of non-contact switching elements is guaranteed. In particular, potentiometers located in the signal transmission path should be avoided will.

Based on an adjustable damping equalizer designed as an electrical four-pole initially specified type, this object is achieved according to the invention in that the second capacitor and the third capacitor to an adjustable double capacitor with a common adjustment axis are combined, and that between the third capacitor and the output of the arrangement a differential capacitor is inserted whose rotor with the third capacitor, its first stator with the continuous line and its second stator is connected to the output of the amplifier

Advantageous refinements are given in the subclaims.

The invention is explained in more detail below using exemplary embodiments.

It shows in the drawing

Fig. I a basic circuit of an adjustable damping equalizer with ideal, voltage-controlled Voltage source,

2a shows a representation of the pole zero lines in FIG complex frequency plane for a circuit according to FIG. 1.

F i g. 2b shows the attenuation curve as a function of the frequency for a circuit according to FIG. 1,

Fig. 3 an extension of the basic circuit according to jo Fig. 1 for amplifiers with finite internal and Output resistance,

4 shows an arrangement for realizing several Attenuation hump with an amplifier.

F i g. 1 shows an attenuation equalizer which is designed in the manner of an electrical quadrupole. The input terminals are marked with 2 and 2 ', the output terminals with 3 and 3'. The input and output voltage are indicated by the arrows U \ and Ui . The input terminal 2 'and the output terminal 3' are connected to a continuous line 1, and accordingly the line 1 can be connected to reference potential, for example ground potential.

The output terminal 2 of the attenuation equalizer is 4 ^r i connected in series via a series circuit of a first capacitor 7 of capacitance CV and a second capacitor 8 of capacitance β Ct "to the input of an amplifier. The second capacitor 8 is designed as a tunable capacitance, and it is in Fig. I directly the capacitance value β C \ "shown in function of the rotation angle of the Abstimmachse, wherein the value β = 1 to correspond to a rotation angle at which a maximum capacitance value C" results, whereas for β = 0, the capacity adopts a minimum.

The input terminal 2 is also connected via a first resistor G to a circuit node 4, from which a second resistor G ₂ leads to the connection point 13 of the series circuit of the capacitors 7 and 8, which is connected to the input of the amplifier. A third capacitor 9 also leads from the switching node 4 to the rotor 5 of a differential capacitor 6, described in more detail below, whose first stator 11 is connected to the continuous line 1 and whose second stator J2 is connected to the output of the amplifier connected to the output terminal 3

The third capacitor 9, like the second capacitor 8, is designed as an adjustable capacitance, and it is shown in FIG. 1, in turn, its capacitance value β C ₂ " i, i is given as a function of the angle of rotation of the tuning axis, whereby the value β = 1 should also correspond to a rotation angle at which a maximum capacitance value G" results, while for / 3 = 0 the capacitance is on Minimum assumes. Leg. Embodiment according to FIG. 1, the two adjustable capacitors 8 and 9 are combined to form an adjustable double capacitor with a common adjustment axis 10, so that there is always a matching angle of rotation and thus a common β for both capacitors. The differential capacitor 6 contains two tunable capacitances, the capacitance values of which are indicated _{in FIG. 1 as α C 2} 'and (1-a ) Ci as a function of the angle of rotation of the rotor axis. Here, et = 1 is intended to mean an angle of rotation at which the rotor 5 is completely opposite the first stator 12, while for cc = 0 the rotor 5 is completely opposite the second stator 11.

The network according to FIG. 1 is based on an active filter stage of the second degree, as in the principle according to, for example, the essay "A Practical Method of Designing RC Active Filters" by R. P. S a I i e π and E. L. Key from "IRE Transactions Circuit Theory ", Vol. CT-2. March 1955, pages 74 to 85, has become known. By the types specified there Circuits, however, is one provided by the present invention and will be detailed below explained contact-free setting of hump frequency and height not possible.

The circuit according to Fig. I has the following damping function:

Dip) = f

F + P

In the above equation, ρ means the complex frequency, K a constant factor for setting the basic gain or Gn: nddamping, üj /> the frequencies of poles or zeros of the damping, Qx the blocking point quality and Q ₂ the quality of the natural frequency.

Provided

he C ₂ "

C, '+ / iC, "
~ cT + ~ ii C ₂ "

where Q is the value of a capacitor replacing the capacitors 7 and 8 and O _{1 is} the value of a capacitor replacing the capacitors 9 and 6, results for the hump ^ middle frequency and for the quality of the

Locking plate or the natural frequency the following Relationships:

Q, = | / Φ " I / C

C ₁ G ₁

= const.

(G, + G ₂ ) | / - ^ - + G ₂ (I -

-2

30th

35

• to

In the above equations, the reference symbols assigned to the ohmic resistors should be used at the same time mean their conductance values.

According to the above equations, the height of the hump can be adjusted by varying A, that is to say by changing the angle of rotation of the differential condenser 6, without this resulting in a shift in the frequency position of the hump. In the complex frequency plane, as shown in FIG. 2a shifted the zeros on a circle by varying β , while the poles remain unchanged.

By varying j3, that is to say by changing the angle of rotation of the double capacitor combining the capacitors 8 and 9, the hump frequency can be set without this resulting in a change in the relative bandwidth. In the illustration according to FIG. 2a, a variation of β is expressed by a shift of the zeros (or poles) in the radial direction.

The F i g. FIG. 2B shows the attenuation curve of the circuit according to FIG. ₁ J. 1 as a function of the frequency for variation of the values of and ß. For example, with a medium setting of the

Differential capacitor given α = results

constant attenuation (or gain); with a variation of α, with a predeterminable fruency a> _r, either a resonance-like increase or a resonance-like decrease in the attenuation curve can be achieved. A variation of β results in one shown in FIG. Shift of the resonance-like increase or decrease to higher or lower frequencies, shown in dashed lines in 2b.

In the embodiment according to FIG. 1 it was assumed that the input impedance Z _{1 of} the amplifier approaches infinity and that the output impedance is approximately zero. This is shown in the illustration according to FIG. 3 taken through a resistor connected between the input of the amplifier and the continuous line resistance 1 G ₁ and by a downstream Versiärkerausgang the resistance Go indicated, the amplifier including resistors G, and G ₀ is in Fig.3 by a dashed line a with the The block provided with the reference symbol V , which is provided to the amplifier of the arrangement according to FIG. 1 should correspond. The circuit according to FIG. 3 contains the entire circuit arrangement according to FIG. 1 and is evident from the circuit addition described below in FIG. 1.

A third resistor G3 is inserted between the connection point 13 and the input of the amplifier, and a series circuit of a fourth capacitor 14 and a fifth capacitor 15 is inserted between the connection point 13 and the continuous line 1. The fourth capacitor 14 is designed as a tunable capacitance and its capacitance value, depending on the angle of rotation of the tuning axis, is β C ₃ ", where the value β = 1 is intended to mean a rotation angle at which a maximum = / («) · capacitance value C ₃ " results. This results in the

Possibility either to combine the second 8, third 9 and fourth capacitor 14 into a triple capacitor with a common adjustment axis or to design the second capacitor 8 and the fourth capacitor 14 together as a butterfly trimming capacitor whose axis of rotation is common to that of the third capacitor 9. The fifth capacitor 15 is constructed as a fixed capacitor in the exemplary embodiment, the capacitance of which has the wen Ci .

Furthermore, the arrangement according to FIG. 3 differs from the arrangement according to FIG. 1 in that a quadruple resistor Gi is inserted between the third capacitor 9 and the rotor 5 of the differential capacitor 6. As a further addition, a fifth resistor L- / 'is connected between the first stator 11 of the differential capacitor 6 and the continuous line 1 and a sixth resistor G /' is inserted between the second stator 12 of the differential capacitor 6 and the output of the amplifier block V.

So that even with the circuit "according to FIG. and the pair of zeros in the p-plane lie on a circle, the condition must

_C_3_ _ G, _ + _ G_2 G ₃ Gj
C ₁ G | G ₂ G ₃ + G ₁ -

are respected, whereby

C, =

C ₃ '+ "/ JC ₃ "

is applicable. G ₀ , Ga "- * °° was assumed. The above requirement C ₃ ICx = const can be met exactly by using a butterfly trimmer for the capacitors 8 and 14 on the same axis with the trimmer 9. From the above condition, applies realize that in the case

G ₃ G ₁ - G ₁ G ₂

G ₃ + G;

G ₂

a small fixed capacitor can be used for C3 can, which is sufficient for mean values G. It would also be an implementation with electronically variable capacitors, for example capacitance diodes, is conceivable. If the following condition is met

G ₀ +

c ' c "

G _4. + G ₄ .
at G _L the conductance of one at the output of the

Arrangement lying Abschlüßwiderslahdes Cl means that the damping curve then does not deviate from that of the circuit according to FIG. The resistances ö / and Gt, " are required here in order not to overload the amplifier output in an inadmissible manner.

If several damping humps are to be implemented with only one single amplifier, the Circuits according to FIGS. I or 3 according to the Representation according to Fig. 4 are trained.

The core of the circuit according to P i %. 4 is given from the aürch ro of Figure 3 arising and the amplifier with series resistor C-, and output resistance C ₀ summary V block. Compared to the arrangement according to FIG. 3, the arrangement according to FIG. 4 is supplemented in that the input and the output of the amplifier block V with the input 2 and the output of the amplifier block V with the input 2 or dsrn AüE "sn ^CT 3 of the Each of these subnetworks corresponds to the corresponding circuit part of the arrangement according to FIG. 3 located between input 2 and amplifier input or between amplifier output and circuit output 3 For reasons of clarity, only two of η subnetworks connected in parallel in this way are shown in FIG.

The through the resistances Cw, R - \, 2 η

Individual currents flowing are added up at the series resistor Gi -ies amplifier and amplified together jo. In order to keep the mutual influence low, it is advantageous to adhere to the conditions Gw <G, and Ga "r <G" + Gl .

summary
Adjustable attenuation equalizer

The invention relates to an active adjustable bämpfungsentzeffefschaHuhg, in which one from each other independent setting of the damping stroke and the frequency range of the damping maximum or * -minimuiiis by means of correspondence-free switching elements, in particular while avoiding potentiometers in the signal transmission path, in flush-free technology should be realized. According to the invention for this purpose the input terminal (2) is in the manner of an electrical one Quadrupole constructed attenuation equalizer via a series connection of a first capacitor (7) and a tunable second capacitor (8) connected to the input of an amplifier. The input terminal (2) is still through a first resistor

which leads from a second resistor (Gi) to the connection point (13) connected to the input of the amplifier. A tunable third capacitor (9) also leads from the circuit node (4) to the rotor (5) of a differential capacitor (6), the first stator (11) of which with the continuous line (1) and the second stator (12) of which with the Output terminal (3) connected to the output of the amplifier. The two adjustable capacitors (8) and (9) are combined to form an adjustable double capacitor with a common adjustment axis (10), so that there is always a matching angle of rotation for both capacitors. The circuit is suitable for signal equalization in carrier-frequency communication systems (Fig. 1).

For this purpose 3 sheets of drawings

Claims (6)

Patent claims: 1. As an electrical four-pole adjustable Attenuation equalizer in which a line at reference potential is directly connected to an input terminal is switched through to an output terminal, consisting of capacitors, ohmic resistors and an amplifier, the amplifier input of which is connected in series from a first capacitor and a second capacitor to the input of the arrangement is connected, the input of the arrangement being connected to a circuit node via a first resistor, from which one on the one hand second resistor to the input of the amplifier and on the other hand a third capacitor to the one with the output of the amplifier connected to the output of the arrangement, characterized in that that the second capacitor (8) and the third capacitor (9) to an adjustable Double capacitor with a common adjustment axis (10) are combined, and that a differential capacitor between the third capacitor (9) and the output (3) of the arrangement (6) is inserted, its rotor (5) with the third capacitor (9), its first stator (11) with the continuous Leitur.g (1) and its second stator (12) with the output (3) of the amplifier connected is. 2. Attenuation equalizer according to claim!, Characterized in that the capacitance ratio Ci '/ Ci " u ^ s first capacitor (7) to the second capacitor (8) corresponds to the capacitance ratio CiICi' d ° s differential capacitor (6) EU to the third capacitor ^). 3. Attenuation equalizer according to one of claims 1 or 2, characterized in that when using an amplifier with finite input and output impedance on the one hand between the connection point (13) and the input of the amplifier, a third resistor (G] \ and on the other hand Ewischen the connection point ( 13) and the continuous line (1) a further series circuit of a fourth capacitor (14) and a fifth capacitor (15) is inserted, that the fourth capacitor (14) as one with the second capacitor (8) and the third capacitor ( 9) jointly variable capacitance is formed. That a fourth resistor (Gt) is inserted between the third capacitor (9) and the rotor (5) of the differential capacitor (6). That furthermore between the first S'ator (11) of the differential capacitor ( 6) and the continuous line (1) a fifth resistor (GS ") is connected and that between the second stator (12) of the differential capacitor (6) and the output of the verse stronger a »real resistance (Gi,") is inserted. 4. Attenuation equalizer according to claim 3, characterized in that the second capacitor (8), the third capacitor (9) and the fourth capacitor { 14) have a common adjustment axis. 5. Därripfüngsentzerrer-.nach claim 3 ₍ characterized in that the second capacitor (8) and the fourth capacitor (14) are combined to form a Schmetten IingS'Trimmkondensätor uhd have a common adjustment axis with the third capacitor (9). 6. damping equalizer according to one of the preceding claims, characterized in that several attenuation equalizers are combined with one amplifier.