DE2442207C3 - Pilot-regulated amplifier stage - Google Patents

Description

9. amplifier stage according to claim 7, characterized in that the frequency of the pilot signal is at the upper frequency limit of the operating frequency band.

The invention relates to a pilot-controlled amplifier stage according to the features of the preamble of claim 1.
Pilot-controlled amplifier stages are known e.g. B. off

> ■> from DE-OS 23 04 686 and from "Radio Mentor Electronics" Year 39, 1973, issue 7, pages 292 to 294. They should be used in particular in large communal antenna systems Compensate for changes in the cable attenuation on the transmission path. To this end

JO becomes a pilot signal with a highly constant level at the input of the transmission path in addition to the useful signals fed. The pilot signal is separated at the output of each amplifier unit to be regulated and is used there its amplitude of the cable attenuation on the transmission

S5 corresponds to the transmission path, as a control signal for a controllable Bode equalizer, which is connected to the isolating circuit to form a control circuit. That I however, with the help of such a control circuit attenuation changes only at the frequency of the Compensates pilot signal without residual errors! let the change in attenuation of the transmission path due to Temperature influences, however, is also dependent on frequency, several pilot signals are each with different Frequency fed and processed in control circuits, and there are controllable Bode equalizers is used with a damping frequency response that defines the damping frequency response of the transmission path compensated for the entire operating frequency band depending on the respective temperature.

w Controllable Bode equalizer of a general type, with the help of which depends on the amplitude of each supplied control signal within the operational freedom band a predetermined damping frequency response can be set, are z. B. from »Bell System

"Technical Journal", Volume 17, 1932, pages 229 to 244, known. The Bode equalizers, built according to known dimensioning rules, enable them to be controlled one or more of their resistances within the operating frequency band proportional to the control signal

horizontal damping strokes.

The total cable attenuation of the transmission line consists of a fixed part and a temperature-dependent portion together, but both portions are frequency-dependent and on the type (type) of the cable. To compensate for that resulting from the fixed component of the cable attenuation Attenuation frequency response is in the above-described, known pilot-controlled amplifier stages

fen a fixed attenuator as well as an additional fixed equalizer is provided that the constant portion compensated. The disadvantage is that the temperature-dependent portion of the damping frequency response is only compensated after a preamplifier stage and thus the headroom of the amplifier be reduced depending on the frequency. Furthermore, the errors of the fixed equalizer add to those of the controllable attenuator equalizing the temperature-dependent attenuation frequency response, resulting in in leads to an additional wedge of the attenuation frequency response of the transmission path.

The object of the invention is to utilize the headroom of the amplifier of a pilot-controlled To improve amplifier stage and to reduce the ripple of the transmission path containing the Versiärkerstufe.

This object is achieved according to the invention by what is stated in the characterizing part of claim 1 Features solved.

In this way, the fixed equalizer of the known piiotgeregeiten amplifier stages can be saved will. The Bode equalizer takes over the function of the fixed equalizer by increasing the frequency response its basic attenuation value corresponds to the frequency response of the avoided fixed equalizer. The ripple the attenuation frequency response of the transmission link remains small, as it is no longer due to an additional Fixed equalizer is increased. The Bode equalizer equalizes the attenuation frequency response of the line at to a point in the signal path in front of the amplifier of the amplifier stage, so that the headroom of the amplifier can be better utilized.

An embodiment has proven to be particularly advantageous in which the Bode equalizer is a T-element is formed with a bridged longitudinal branch and in the a single controllable impedance element is provided in the bridging branch or in the shunt branch. It It has been found that with such circuits not only the effort to control the Bode equalizer is reduced, but that in addition, despite the resulting simpler circuit of the Bode equalizer a largely residual error-free compensation of the attenuation frequency response of the transmission path can be achieved. This is especially true if the bridging branch and the Shunt branch to each other have reciprocal resistance circuits and if the bridging branch in the Operating frequency band show capacitive behavior and the shunt arm inductive behavior.

The attenuation frequency response of the Bode equalizer is expediently adjustable: it can then be switched on the attenuation frequency response of the cable type used. This adaptation is particularly easy if a parallel resonance circuit with changeable in series with the shunt branch Resonant frequency is switched. In embodiments in which the shunt arm has inductive behavior should show, the resonance frequency of this parallel resonance circuit is then above the operating frequency band,

For the, as explained above, preferred Bode equalizers with a single controllable impedance element Circuits are particularly suitable in which the series branch two each with the shunt branch the input and the output of the Bode equalizer connecting resistors whose resistance values is equal to the characteristic impedance of the line connected to the input or output and in which the bridging branch has a resistor connected parallel to the series branch and the shunt branch have a resistor connected in series for this purpose. Especially in connection with an in The parallel resonance circuit connected in series to a parallel branch allows the resistances of the series branch *. and of the shunt branch when designed as adjustable resistors, a simple adjustment of the basic damping value frequency response depending on the type of cable used.

Controllable impedance elements designed as controllable reactances are particularly suitable if, in addition to the controllable reactance component, they have a constant reactance component. A particularly simple control circuit is obtained when the bypass branch having an implement coupled in parallel to the longitudinal branch capacitance diode as a controllable impedance element and when the separating circuit for controlling the capacitance value of the capacitance diode a corresponding to the amplitude of the Pilotsigna '.:.-M has an average Gleiehspamiungspege! fluctuating? Output DC voltage control signal. The basic attenuation frequency response can then be determined by the capacitance of the capacitance diode in the operating point. The disconnection circuit emits the DC voltage control signal in such a way that it reduces the capacitance of the capacitance diode as the amplitude of the pilot signal increases.

In another embodiment it can be used as a controllable Impedance element a controllable impedance connected in series / around a shunt branch can be provided. the Controllable impedance is expediently connected to a connection to ground. As a controllable inductance is suitable e.g. B. a magnetic variometer, the coil of which can be changed by the control voltage electromagnetic constant field is angeodnet. Self-induction can then be achieved by changing the control voltage the coil can be influenced. Eb should be emphasized, however, that both capacitive and inductive controllable reactances using vo.ι transistors or field effect transistors as active Reaktanzschaltuiigen can be executed.

Of particular importance is an embodiment in which the pilot signal is in the upper half of the Has operating frequency band or higher frequency. This embodiment takes into account in In contrast to known pilot-controlled amplifier stages, that the one to compensate for the temperature-dependent Attenuation change required attenuation stroke of the Bode equalizer becomes larger with increasing frequency. Known pilot-controlled amplifier stages with a lower end of the operating frequency band Frer;: e: iz of the pilot signal have the disadvantage that small temperature-related level changes of the pilot signal a large attenuation swing at the upper end of the operating frequency band. At the high end of the operating frequency band, however, are the Level reserves and the signal-to-noise ratio least. This disadvantage of the known pilot-controlled amplifier stages is avoided if the frequency of the pilot signal is at the upper end of the operating frequency band. In this embodiment residual errors at the upper end of the operating frequency band can be completely avoided. True, kick residual errors at the lower limit, however, due to the higher headroom of amplifiers can be disregarded at low frequencies.

This embodiment of the invention thus has ilen The advantage that the dynamics of the entire cable gap is maintained in the permissible temperature range and that a constant intoxication and intermodulation absland result.

In the following the invention will be explained in more detail with reference to drawings, namely shows

Fig. I is a block diagram of a known pilot gcre equal amplification level:

F i g. 2 shows a diagram of the attenuation frequency response of the amplifiers run according to I i g. I:

I i g. J is a block diagram of an inventive Pillow rule amplifier suit;

I i g. 4 shows a diagram of the fundamental value I rcquency response the amplifier suite according to FIG. 3;

I i g. 5 shows a diagram of the temperature-dependent attenuation frequency response of the amplification stage I ig. J:

U, 4,., Lil, .1,1

Hing 21 is rectified and a corresponding S illwcrtsignal the Bode equalizer as Il .Steuersigna to ^r change the frequency sweep supplied guiding ;.

I i g. 2 shows in a diagram for two different nc temperature values (-JO ¹ C; + JO'C) the damping frequency response of the Bodc equalizer II within an operating frequency band from 40 MHz to 272 MHz. The solid curve here gives the desired attenuation frequency of the Bodc equalizer required for exact compensation of the attenuation frequency response of line 1; ti an. while the dashed-in / cichnel curves show actually achievable attenuation-I rcquency response. As from I · 'i g. As can be seen, the desired and the deliberately achieved attenuation / retardation response only coincide with the frequencies of the operating frequency band elwa. At higher frequencies of the operating frequency band, there is a Rcsl Fehler / ■ ", which by dei ι., Ί, ..,. Ι, ι ,,. Μ, ..r ..,.,.>, I""iv, . ,, "r ,,.,", Tv .. ,,. ,, ..,, ..., ".., ι ..

one in the amplifier suite according to Γ ι g. j usable Bode equalizer; and

Fig. 7 is a circuit diagram of another embodiment one in the amplifier suite according to Γ i g. 3 usable Bode equalizers.

Γ i g. I shows a pilot-controlled amplifier stage of known type. the one above cine I.position I next to a Nutzsignai a pilot signal is supplied. The useful signal and the pilot signal are transmitted to a Cig. I don't OrI shown fed into line 1. Line I can be a coaxial cable (iroU- (ieemeinsehaftsanlennenanliige act. The piloigcrcgclte Reinforcement security has the task. Attenuation changes toggle due to temperature influences. The useful signal and the pilot signal will A fixed equalizer 5 is supplied via a frequency-independent attenuator 3. During one fr frequency-independent attenuator only attenuator difference when using the pilot-controlled amplifier stage on lines with different To compensate for lengths and thereby prevent the overdriving of subsequent amplifier stages, has the fixed distortion unit 5 has a damping frequency response on. the attenuation frequency response of the upstream line 1 within the operating frequency band should compensate. At the output of the fixed equalizer 5 there is an im for a mean cable temperature Essential frequency-independent basic attenuation value of the useful signal and the pilot signal available. That The useful signal and the pilot signal are fed via a preamplifier 7 to a control circuit 9, which compensates for temperature-dependent fluctuations in the useful signal and the pilot signal in a linear manner. Of the Preamplifier 7 thus transmits a signal that has not yet been adjusted, so that its headroom be reduced. In addition, the fixed equalizer 5 increases the overall ripple of the frequency response the pilot-controlled amplifier stage.

The control circuit 9 has a Bode equalizer 11. which outputs the signals supplied from the preamplifier 7 to an amplifier 13. The damping stroke of the Bode equalizer 11 can with the help of a control signal generated by a separation circuit 15 on a Setpoint are maintained. For this purpose, the disconnection circuit 15 points to the pilot frequency of the pilot signal matched band filter 17 on. which separates the pilot signal at the output of the amplifier 13 from the Nutzsignai and via an amplifier 19 to a rectifier circuit 21. The pilot signal is in the rectifier-Bode-Ent / crres Il not to be compensated. Exact compensation is only for the in de lower half of the operating frequency band e.g. bc 118MIIz lying pilot frequency / ',, ensured. Dii well-known pilot-type amplifier has the disadvantage that the largest set-up error Γ at higher levels Frequencies occurs at which the modulation reserve vcn of the preamplifier 7 and of the amplifier 13 the S? ; nal-to-noise margin of the amplifier 13 is the lowest.

I i g. 3 shows the block diagram of an inventive pilot-operated amplifier module. The pilot signal and the useful signal from a line 23, for example the coaxial cable of a large-scale computer antenna system, are similar to the known pilot-operated signals according to FIG. an independent attenuator 25 fed. with the aid of which the level of the useful signal and the pilot signal can be adjusted to an optimum value for the downstream pilot-controlled amplification level. The pilot-regulated amplifier has a controllable Bode equalizer 27, which takes the zero signal and the pilot signal on the frequency-independent attenuator 25 and emits them via an amplifier 29 to a wide-sensing line 31 of the transmission path. To control the Bode equalizer 27, a disconnection circuit 33 is provided, similar to the known amplifier stage, which separates the pilot signal occurring at the output de: amplifier 29 from the useful signal and supplies the Bode equalizer 27 with a control signal corresponding to the amplitude of the pilot signal again. a band filter 35 tuned to the pilot frequency f _p , which is coupled to a rectifier circuit 39 via an amplifier 37. The separation circuit 33 regulates the level of the pilot signal and thus also the level of the useful signal to a constant value with the aid of a control signal generated in the rectifier circuit 3 <and fed to the Bode equalizer 27, the constant value being controlled by a separation circuit in a manner not shown trains guided setpoint signal is specified.

The Bode equalizer 27 has, similar to the Bode equalizer 11 of the known amplifier stage according to FIG. 1 at least one controllable impedance element, through which its attenuation swing in the operating frequency band is something like £ proportional to the control signal of the separation circuit 3J can be changed around a basic damping value. The Bode equalizer 27 is constructed so that its attenuation

Frequency response compensates for the attenuation frequency response of the line 23 at at least one temperature value. This means that the attenuation strokes achieved for the respective value of the control signal as a function of the frequency are in an almost => fixed ratio to one another. The basic attenuation frequency response of the Bode equalizer 27, ie the dependence of the basic attenuation value on the frequency, is selected such that it compensates for the attenuation frequency response of the line 23 at the mean cable temperature. This measure eliminates the need to use a separate fixed equalizer. whereby the ripple of the amplifier stage can be improved. The basic attenuation frequency response of the Bode equalizer is selected so that at the ti output of the Bode equalizer 27, at the mean cable temperature, a frequency-independent curve of the attenuation of the Bode equalizer 27 with an upstream line 23 results. An example of a fundamental value frequency response of the Bode equalizer 27 in FIG. 4 is shown for a coaxial cable having 1000 m length with a mean cable temperature of 20 ⁰ C.

For better utilization of the headroom of the amplifier 29, the cable-typical frequency response and the cable-typical temperature-dependent frequency response are equalized before amplification and secondly a pilot frequency f _p at the upper end of the operating frequency band is used. F i g. 5 shows a function of the frequency of the course of the temperature-dependent attenuation in dB for two temperature values (-30 ⁰ C; +30 "C). The drawn with solid lines curves show the line 23 for accurate compensation of the attenuation frequency characteristics at these temperatures required temperature-dependent attenuation curve of the Bode equalizer 27. The attenuation curves that can be achieved with an amplifier stage according to FIG. 3 are shown in dashed lines the higher frequencies of the operating frequency band is reached,

H h Hpi Frpmipn7Pti hpi Hpnpn Hip AiicctPiiPrimtrcrpcpr-

ven and the signal-to-noise ratio of the amplifier 29 are lower. Noticeable residual errors F only occur at lower frequencies in the operating frequency band, However, due to the higher headroom of the amplifier 29 at these frequencies remain unconsidered.

F i g. 6 shows a particularly simple exemplary embodiment of the Bode equalizer 27. It is included as a T element built up bridged series branch. The series branch consists of two resistors 41 connected in Ser e and 43, which are connected to the input 49 and 43 via capacitors 45 and 47 serving as a high frequency short circuit Output 51 of the Bode equalizer are connected. The resistance values of the resistors 41 and 43 are equal and correspond to the characteristic impedance of those connected to input 49 and output 51, respectively Lines selected. The bridging branch connected in parallel to resistors 41 and 43 shows in Operating frequency band, reciprocal resistance behavior to the shunt branch. This is done by alternating current achieved essentially dual circuits. The shunt branch becomes a series circuit preferably adjustable resistor connected to the junction of resistors 41 and 43 53 formed with a parallel resonance circuit 55 connected to ground. The bridging branch has essentially one, preferably adjustable, connected in parallel to resistors 41 and 43 Resistor 57, which has two capacitors 59 and 61 serving as high-frequency short circuits Capacitance diode 63 is connected in parallel. The resonance frequency of the composed of an inductor 65 and a Trimmer capacitor 67 formed parallel resonance circuit 55 is chosen so that it is above the Operating frequency band lies, so that the parallel resonance circuit 55 is inductive in the operating frequency band Behavior shows.

By choosing the working point of the capacitance diode, i.e. by choosing its own capacitance, the The basic damping frequency response of the Bode equalizer can be set in such a way that it matches the damping frequency response compensated for the line at the mean temperature. The course of the attenuation frequency response is in this case of the resonance frequency of the parallel resonance circuit 55 and, if applicable, of the setting the resistors 53 and 57 dependent. By adjusting the resonance frequency and the resistances 53 and 57, the basic attenuation frequency response can be adapted to the cable type.

A direct voltage U which changes around an average direct voltage level is fed to the capacitance diode 63 as the control voltage. The mean DC voltage level of the DC voltage U determines the capacitance of the capacitance diode 63. The DC voltage U is polarized in the reverse direction of the capacitance diode 63 and is applied to one connection of the capacitance diode 63 via a load resistor 69 and a high-frequency choke 71 or 73. Increasing DC control voltage has the effect of reducing capacitance. Two filter capacitors 75 and 77 connect the diode-remote connections of the high-frequency chokes 71 and 73 to ground. The control voltage U is obtained in a manner not shown in detail from the disconnection circuit 33 according to FIG. 3 supplied.

For a practically executed example of the embodiment according to FIG. 6 resulted in the following dimensions- ηιρπιησ-

Characteristic impedance of the line
Operating frequency band
Pi'ot frequency
Control voltage

Resistance 53
Resistors 41 and 43
Resistance 57
inductance 65
Trimmer Capacitor 67
Capacitors 59,61,65,77
High frequency chokes

Work resistance 69

75 Ω

40 ... 300MHz
/ p = 306MHz
£ / = 3 ... 15 V for a medium one

DC level of 7V

100 Ω adjustable
75 Ω

500 Ω adjustable
3OnH

1.4 ... 5.5 pF
1nF

2 μΗ on ferrite core
470 Ω

The result was a temperature-dependent damping frequency response of the type shown in FIG Waviness S <1.5 (for a temperature difference of ± 15 ° C).

Fig./ shows another embodiment of the Bode equalizer which can be used in the amplifier stage according to FIG 27. The reference numerals of parts with the same effect are compared to the embodiment according to FIG. 6

the number 100 increases. The Bode equalizer is also in this embodiment as a T-member with a bridged series branch formed from resistors 141 and 142 educated. A resistor 157 is provided as a bridging branch. The branch consists of the Series connection of a resistor 153, a parallel resonance circuit 155 and one connected to ground, by c'ds control signal of the disconnection circuit

10

controllable inductance 179. The self-inductance of the controllable Inciukt'vität 179 is in turn connected with the resonance frequency of the parallel resonance circuit 155 is selected so that the basic damping value frequency response of the Bode equalizer, the attenuation frequency response of the line at the mean temperature compensated.

For this purpose 3 sheets of drawings

Claims (8)

Patent claims: 1. Pilot-controlled amplifier stage with one amplifier and one that is frequency and temperature dependent Changes in attenuation on a line transmitting a pilot signal, in particular a coaxial cable of a large communal antenna system, compensating pilot control circuit, the one Bode equalizer connected in series to the line with at least one controllable Impedance element and an isolating circuit coupled to the line downstream of the Bode equalizer for the pilot signal, through which the controllable element by means of a control signal corresponding to the amplitude of the Pilot signal is controllable, the Bode equalizer is constructed so that its attenuation swing in Operating frequency band roughly proportional to the control signal around a basic attenuation value changeable is ·, and that of the temperature of the Line-dependent attenuation frequency response compensated, characterized that through the Bode equalizer (27) the attenuation frequency response of the line (23) before amplification transmitted signals can be equalized by the amplifier (29) and to avoid fixed equalizers is constructed so that the frequency response of its fundamental damping value at an average temperature the attenuation frequency response of the line (23) compensated. 2. Amplifier stage according to claim 1, characterized in that the Bode equalizer (27) is designed as a T-member with bridging Lä.igszweig (41, 43; 141, 143) and a single controllable impedance element (63; 179) in the L jerbrückungszweig (57, 63) or in the cross branch (153, 155, 179) is provided (Fig. 6 and 7). 3. Amplifier stage according to claim 2, characterized in that in series with the shunt arm (53,55) a parallel resonance circuit (55) is connected, the resonance frequency of which is above the operating frequency band lies. 4. Amplifier according to claim 3, characterized in that the longitudinal branch (41, 43) has two each the shunt branch (53,55) with the input (49) or the output (51) of the Bode equalizer (27) connecting resistors (41; 43), the resistance values of which are each equal to the characteristic impedance the line (23) connected to the input (49) or the output (51), and that the Bridging branch (57, 63) a resistor (57) connected parallel to the series branch (41, 43) and the transverse branch (53, 55) one to the parallel resonance circuit (55) have resistor (53) connected in series (Fig. 6). 5. Amplifier stage according to one of claims 2 to 4, characterized in that the bridging branch (57, 63) a variable capacitance diode (63) coupled in parallel to the series branch (41, 43) as a controllable one Has impedance element and that through the disconnection circuit (33) for controlling the capacitance value of the capacitance diode (63) a corresponding to the amplitude of the pilot signal by an average DC voltage level fluctuating DC voltage control signal (t / ^ can be emitted. 6. Amplifier stage according to claim 5, characterized in that through the disconnection circuit (33) a reducing capacitance of the capacitance diode (63) with increasing amplitude of the pilot signal DC voltage control signal can be emitted. 7. Amplifier stage according to one of claims 2 to 4, characterized in that in series with the shunt arm (153, 155, 179) a controllable inductance (179) is geschähet (Fig. 7). 8. Amplifier stage according to one of the preceding claims, characterized in that the Pilot signal has a frequency in the upper half of the operating frequency band or above.