DE2620178A1 - Cable amplifier for wideband signals transmission - has equaliser whose frequency sensitivity is automatically controlled by ladder network at amplifier output - Google Patents

Abstract

The cable amplifier contains an equaliser with adjustable frequency sensitivity. The rise of the equaliser (10) frequency sensitivity within the transmission band is adjustable. A ladder network (12) is connected to the equaliser (10) output for automatic control. Its output signal controls the rise of the equaliser frequency sensitivity as a function of the signal level in a narrow section of the transmission frequency band at the equaliser output. The amplifier circuit incorporates a narrow band filter, a level detector circuit and a comparator.

Description

Cable amplifier and clutter to broadband

transmission of electrical signals.

The invention relates to a cable amplifier for broadband transmission electrical signals, an equalizer with adjustable frequency sensitivity contains. The invention also relates to an arrangement for broadband transmission electrical signals with a transmitting station, one connected to the transmitting station Transmission cables and with cable amplifiers inserted into the same.

The transmission of television signals via coaxial cable with the so-called. Cable television is an example of broadband transmission known to be required the transmission of a single television channel already covers a frequency band of several Xlegahertz. When routed through coaxial cable, there are multiple television channels transmitted so that a participant can make a program selection. The width of the total required transmission band is correspondingly large. The bandwidth is often between 30 and 300 spleen.

A coaxial cable has evenly distributed line losses that increasingly attenuate the transmission signals as the cable length increases. These losses can be compensated for by inserting cable amplifiers in series within the coaxial cable at certain intervals. Normally these cable amplifiers are arranged at regular intervals corresponding to an attenuation of 21 dB at 30 z. As a result, the spacing between successive cable repeaters depends on the type of cable used. A branch within the cable also requires reinforcement, so that cable amplifiers are normally arranged at the exit of a branch.

The difficulty lies on the one hand in the loss of a coaxial cable are frequency dependent and temperature dependent and that it is difficult for everyone Cable amplifier one installation point at exactly the same distance accordingly an attenuation of 21 dB at 300 MHz in the worst case.

The cable amplifiers are therefore arranged at a shorter and larger distance Number of times when it is absolutely necessary. A simple cable amplifier enables the maintenance of the transmission and excludes that the signals are gradual immerse yourself in the exchange. However, it does not compensate for the irregularities the frequency-dependent losses nor the changes due to temperature fluctuations.

It has already been proposed to use such a cable amplifier to equip an equalizer or equalizer, the influence of the uneven to reduce frequency-dependent losses and also the influence of temperature fluctuations. The basic element of such an arrangement is its frequency sensitivity in some ways adjustable, a control circuit that is more or less extensive and uses this setting option.

Such arrangements are not entirely satisfactory. Because the possibilities for setting the frequency sensitivity are limited, so that in practice only a very imperfect equalization is achieved, or it is not easy to automatically do this. are extraordinarily extensive, so that correspondingly complicated regulations are required which require detailed knowledge of the real part of the losses in order to achieve good equalization. In the second case, extensive interventions by technicians are necessary. If one opts for automatic equalization, which is very critical, technical difficulties arise in the construction and maintenance of the arrangement.

The necessary quality of the equalization increases with the length of the coaxial cable and the transmission path. If you take into account. that television systems have a considerable geographic area Should have expansion and the / intervals between maintenance should be as large as possible, it is clear that the above solutions do not meet these two requirements.

The object of the invention is to provide a simple cable amplifier that automatically reduces the losses to uniform and fixed values permitted.

This object is achieved according to the invention in that the increase the frequency sensitivity of the equalizer adjustable within the transmission band is and that on the output side of the equalizer a chain circuit for automatic Control is coupled, the control output signal of which increases the frequency sensitivity of the equalizer as a function of the signal level within a narrow section of the transmission band at the output of the equalizer.

According to a preferred embodiment of the invention it is provided that the chain circuit for automatic control in series comprises a narrow band filter, a level detection circuit, a comparator to which a reference value to represent a desired level is applied, and a control circuit for the adjustable increase in the frequency sensitivity of the equalizer , wherein the control circuit increases the frequency sensitivity of the Equalizer as a function of the deviation between the signal level detected within the narrow band filter and the reference value.

In a further embodiment, the invention provides that the equalizer includes a correction attenuator which is a T-resistance attenuator circuit, a series resonant circuit connected in parallel to the legs of the T-circuit and a 6-parallel resonance circuit connected in series to the center bar of the circuit comprises, wherein the tuning frequencies of the resonance circuits within a frequency range above or in the range of the maximum frequency of the transmission band through the Control signal are adjustable that the control circuit on the two resonance circuits acts to adjust the tuning frequency depending on the deviation between the signal level detected within the narrowband filter and the reference value control, and that the narrow band filter on a section in the upper frequency range is tuned within the transmission band, the simultaneous shift the tuning frequency of the two resonance circuits a change in the increase in frequency sensitivity causes the correction attenuator within the transmission band.

Furthermore, the invention proposes that each resonance circuit at least contains a capacitance-varying diode and that the control circuit for these capacitance-varying diodes a variable polarization voltage supplies, which the diode capacitance and thus the tuning frequency of the two resonance circuits changed.

According to a preferred embodiment of the invention it is provided that the equalize another frequency-independent Attenuator contains, whose attenuation can be controlled, but is frequency-independent and that before Correction-attenuation-Glies is arranged, and that the cable amplifier a zeiters @ et @ eschaltung for automatic control includes the input of the output side of the equalizer is removed and whose @ us @ ah @@ the frequency-independent attenuator depending on the signal level at the output of the equalizer controls, this Signal level within another narrow frequency segment of the amount band is removed.

It is also provided that the other narrow frequency segment is m the lower end of the transfer belt.

@chlichen view the invention that the frequency-independent attenuator Contains PIN diodes, which can be switched by the time chain to the automatic Control determine direct current to be flowed through.

The invention suggests that the same one be in series with the equalizer connected broadband amplifier contains and that the two chain circuits are coupled to the output of the broadband amplifier.

The invention also relates to an arrangement for broadband transmission electrical signal with a transmitter, one connected to the transmitter Transmission cables and with cable amplifiers inserted into the same, which are marked thereby is that? at least one cable amplifier as the cable amplifier described above Type is provided and daf '. the transmitting station within the narrow frequency segment of the transmission band emits a pilot frequency at a constant level.

For such an arrangement, the invention provides that the transmission control le another filot frequency with a constant level within the second transmits narrow frequency segment within the transmission band.

Embodiments of the invention are hereinafter referred to to the accompanying drawings, in which: Fig. 1 shows a cable amplifier according to the invention in a block diagram, Fig. 2 is a circuit diagram of the equalizer with frequency-dependent correction in the circuit according to Fig. 1, Fig. 3 A and 3 B Frequency characteristics of cable losses and frequency sensitivity in the context of Invention, FIG. 4 is a block diagram of a modified embodiment of the invention, 5 5 a more detailed> circuit diagram of the arrangement according to FIG. 4 and FIG. 6 shows a schematic representation of a transmission arrangement with cable amplifiers according to the invention.

The entire cable amplifier 1 according to Fig. 1 is from one block enclosed by dashed lines. The cable amplifier usually has a Attenuator 10 with controlled increase in frequency correction, a high-frequency broadband amplifier 11 and a chain circuit 12 for automatic control. The attenuator 10 is connected on the input side to an input terminal 2 of the cable amplifier 1, namely to the inner conductor 21 of the input terminal, which is connected to the inner conductor of a Coaxial cable is connected. The outer conductor 22 of the input terminal is to the earth connection of the cable amplifier. The signal output of the attenuator is with the Input of a high frequency broadband amplifier 11 connected.

The high frequency broadband amplifier 11 is known in the art built up and can feed two output terminals 3 and 4; the output terminal 3 is e.g. for the coaxial cable of the main line is provided, the output terminal 4 can be connected to a Coaxial cable that branches off to a subscriber can be connected.

The input of a chain circuit 12 for automatic control g is coupled to an output of the high-frequency broadband amplifier 11. The derailleur 12 has an output which acts on the attenuator 10 in order to increase the increase to control the frequency sensitivity according to the desired correction function.

Referring to Fig. 2, the basic electrical diagram of the Attenuator 10 according to FIG. 1 explained. The attenuator 10 has an input E and an exit S.

It is accomplished by one T drag attenuator, the two Resonance circuits are switched on. The T drag attenuator includes three resistors X 101, R 102, R 103.

The resistors R1U1 and R 102 are between the live ones connections of the signal conductor from input E and output S connected in series. As a result, they form the imid legs of the T-drag attenuator. The third resistor R103 is at the connection point of the resistors R101 and R102 switched on and connected to earth potential.

The resistor R103 thus forms the central web of the T-resistance attenuator.

A first resonant circuit comprises an inductance connected in series L104 and a variable capacitance C105, which is preferably through a capacitance-varying diode what is shown below is realized. This series resonance circle is between the input E and the output X of the attenuator 10 parallel to the Resistors R 101 and R102 switched on.

A second resonance circuit comprises one connected in parallel Inductance @ 106 and a variable capacitance 0107, which is also preferably through a capacitance-varying diode is realized. This parallel resonance circuit is in series between the earth connection and the land of resistor R103 inserted. It became frequency sensitivity of the correction attenuator 10 determines when setting the variable capacitances C105 and C107 is such that the tuning frequencies of the two resonance circuits in the are essentially the same. This frequency sensitivity is represented by curves IA and 1B of FIG. 3B for a frequency range from 0 to 300 MHz. the Frequency sensitivity is given as gain, the smaller the inertia the curve shows, the greater the attenuation. Used in Figures 3A and 3B one on the abscissa a linear frequency division and on the ordi nate a logarithmic one Division for damping; the attenuation curve of a cable is also a straight line, as well as that of the equalizer.

When the tuning frequency of the two resonance circuits is close to 300 Mz is set, the curve IA in FIG. 3B applies to the frequency sensitivity. At the resonance frequency, the correction attenuator 10 essentially has an effect no attenuation. Because the series resonance circuit L104, C105 has a minimal resistance, which represents a short circuit for the series resistors R101 and H102. The parallel resonance circuit L106, C107, on the other hand, is a blocking circuit and has a maximum resistance. He blocks the flow of the high-frequency current to earth, which otherwise causes damping. As a result, this circuit simply provides a minimum resistance at the resonance frequency in parallel with resistors R101 and R102 and does not produce any attenuation; Furthermore is the input resistance of the branch circuit for the output of the correction attenuator 10 repealed. There is the high-frequency broadband amplifier 11, which this Conditions met.

In Fig. 3b, the curve IA shows a maximum at a level of the usual Ü d at a resonance frequency close to 300 MHz.

The resonance circuits are ineffective for a direct current of frequency zero; the damping is determined by the resistors R101, R102 and R103, if necessary by the resistance of the inductor R106, if these are not neglected the attenuation at zero frequency is approximately -19.5 dB.

The frequency sensitivity is thus represented by a straight line of the curve IA shown between the frequencies 0 and 300 MHz.

The slope of this straight line depends on the values of the resistors H101, R102, b103 and possibly on the resistance of the inductance @ 106. Above curve IA drops again at the resonance frequency.

The curve 11 <gives the frequency sensitivity of the same correction attenuator 10 on if the two resonance circuits for a frequency well above 300 MHz, e.g. 400 MH can be matched. This tuning frequency is with grooves above the Transfer tape laid. Under these circumstances the maximum of the sensitivity curve lies IB, which corresponds to an attenuation of Ü d, outside the character field; in the Frequency of 300 MHz results in a noticeable attenuation of -5.5 dB. in the In contrast, nothing has changed at frequency zero. as well as the Curves IA and IR in ig. 3B show, dalX has been shown by voting the two Resonance circles of the attenuator 10 according to FIG. 2 and by changing the common Tuning frequency the rise in the sensitivity curve of the correction attenuator within the specified transmission band, which here ranges from 30 to 300 MHz, can be changed.

The correction attenuator thus points within the transmission frequency band with increasing frequency a decreasing attenuation up to a minimum value of 0 dS at the adjustable common resonance frequency. The control that by the derailleur for automatic control is implemented, so acts in the Meaning a shift in the common resonance frequency and thereby changes the Increase in frequency sensitivity or the decrease in attenuation caused by the attenuator shows within the transmission frequency band. The cessation of the increase in Sensitivity curve, which is realized in this way, must in principle with regard to the signal level within a frequency segment at the upper end of the Transmission band is detected. For this purpose one sends a first pilot frequency, a high pilot frequency from the transmission point from where the signals are transmitted. The high pilot frequency is essentially monochromatic and is at the top of the transmission band from 30 to 300 MHz The sail of the pilot frequency is essentially constant.

The Kettenscbaltung for automatic control thus affects the Increase in the sensitivity curve of the correction attenuator 10 until the level equal to the high pilot frequency at the output of the attenuator with a reference level is.

Fig. 3A shows two extreme cases of cable loss as a function of the frequency. The curve A corresponds to a maximum cable length and a temperature of + 50 ° C. Curve B corresponds to a minimum cable length and a temperature from -20 ° C. The maximum and minimum cable length depend of course on the Quality of the cable. Investigations and tests have shown that the automatic joint change in the tuning frequency of the two resonance circuits essentially results in good equalization in both extreme cases and for all intermediate conditions. For the borderline case of curve B in FIG. 3A causes the derailleur to be automatic Control a regulation of the correction attenuator according to the curve iß in Fig. 3B. For the other borderline case of curve A in l'ig. 3A, the control of the correction attenuator takes place after of curve IA in Fig. 3B.

It can be seen that at the high pilot frequency, the deviation between the curves A and B in Fig. 3A of the deviation between the curves IA and IB of Fig. 3B corresponds. However, this is not correct for the lower frequencies.

The common automatic change of the tuning frequencies of the two When used alone, resonance circles lead to an equalization, the lower one Frequency range is insufficient after passing through some cable amplifiers. Because starting from the two curves of the ig. 3 the change for the frequency disappears Zero, although the change in resistance of the cable for direct current does not disappear.

A correction is thus carried out in the lower region of the transmission band can be added, according to the invention, a controlled frequency-independent attenuator 13 according to the block diagram of FIG. This attenuator 13 is between the input terminal 2 and the correction damping element 10 of the cable amplifier 5 inserted. A second derailleur 14 for automatic control is also like the first chain circuit 12 to the output of the high-frequency broadband amplifier 11 coupled. In this respect, the assemblies of FIG. 4 are the same as those of Fig. 1.

Another low pilot frequency is called the monochromatic frequency transmitted with a substantially constant level in the lower region of the transmission band. The second chain connection for automatic control acts on the frequency-independent Attenuator until the level of the low pilot frequency at the output of the Equal to another reference level.

3B uses the curves IIA and IIB to indicate two attenuation levels of the frequency-independent attenuator 13, which is connected electrically in series with the correction attenuator 10. The damping effects in question are thus But one is lost According to Fiz. 3B, tii c attenuations are measured using a logarithmic measuring stick. As is well known, the logarithmic measure of the product of two attenuations is equal to the sum of the logarithmic individual measures of the two attenuations. As a result, curve IIIA is the resultant of the effect of the correction attenuator (curve IA) and the effect of the frequency-independent attenuator (curve 11A), which is set so that curve IIIa intersects curve IIA at the low pilot frequency.

This point of intersection corresponds to the control by the second Kettenschalutng for automatic control in order to thereby reduce the losses according to curve h in FIG. 3A to compensate. One can see the good agreement between the loss curve A in Fig. 3A and the resulting correction curve IIIA in Fig.

3B between 0 and 300 MHz.

The effect of the correction attenuator is superimposed according to curve IB the curve results from the effect of the frequency-independent attenuator unci IIB, which intersects curve IIA at the low pilot frequency. Within a frequency range between 0 and 300 MHz, the correction curve IIIB essentially agrees with the loss curve B after Fir. 3d jiberein.

Finally, curves IVA and IVE in FIG. 3B indicate the limits of the Correction options for the entire equalization circuit; as shown later these limits determine the allowable tolerance for the length of the cable between neighboring cable amplifiers.

Fig. 5 shows a preferred circuit arrangement for the cable amplifier. According to FIG. 4, FIG. 5 shows the controlled frequency-independent attenuator 13. gravel is connected to the input terminal 2 via a capacitor 15 of the Transmits AC voltages and blocks DC voltages; one denotes such a thing Capacitor as a coupling capacitor.

Another coupling capacitor 16 is the output of the controlled frequency-independent attenuator 13 to the input of the correction attenuator 10 connected. The output of the correction attenuator is through a third coupling capacitor 17 10 connected to the input of the high frequency broadband amplifier 11, which is shown in the Arrangement according to Fig. @@ ei separated from @ än @ e n @ t. One of those exits is connected to the output terminal 3, which leads to the main cable in the transmission direction leads. Another output is connected to output terminal 4, which is used for a Branch cable is intended.

Finally, the third output is for internal use and is used jointly for the two derailleurs for automatic control, as will now be described in detail.

Under these circuit conditions, the first chain circuit comprises for automatic control a narrow band filter 21 for the high pilot frequency, a level detection circuit 122 including, for example, a diode, a comparator 123 and a control circuit 124 having a DC and low frequency amplifier. Such an amplifier is in circuits with automatic control of the gain, e.g. well known in Xadio and television receivers.

parallel to this is the second derailleur for automatic renewal with a narrow band filter 141 for the low pilot frequency, a locking detection circuit 142, a comparator 143 and a control circuit 144 with an amplifier automatic control of the gain level.

The reference level for the comparators 123 and 143 determine the Desired sensitivity for the high and low pilot frequencies. Deliver with it the level detection circuits 122 and 142 track the levels of the two pilot frequencies Filtering; these two levels are compared with reference levels.

As soon as a comparator 123 or 143 detects a discrepancy,.

the amplifier of the associated control circuit 124 resp.

144 in the desired sense in order for this deviation to disappear is brought.

The circuit configuration of the correction attenuator 10 will now be described and the frequency-independent attenuator 13 explains the , interact with the amplifiers of the control circuits 124 and 144, respectively. at The shown example of the correction attenuator shows the resistances R101, R102 and R103 of fig. 2 again and also the inductances L104 and L1u6, which latter is adjustable here. Within the series resonance circle, the variable capacitor C105 through a capacitance varying diode D105 in series with realized with an adjustable capacitor C105A. Within the parallel resonance circuit is the variable capacitor C107 through a capacitance varying diode D107 as well realized an additional capacitor 01070. The adjustable inductance L106 and the adjustable capacitor C105 allow adjustment for the tuning range of the 1-parallel and series resonance circuit.

The capacitor 01070 is used to block the expensive direct current of the capacitance-varying diodes D105 and D107, which are used for changing the tuning frequency are determined.

Because the output of the amplifier of the control circuit 124 is over a common resistor R108 with a tap from a first resistor R109 to the capacitance varying diode D105 and a second resistor R110 of the capacitance varying diode D107. The capacitance varying diode D105 is controlled via that branch of the line that is through the common resistance H10S, through resistor R109, through the capacitance varying diode D105 itself, through inductance L104, through resistor R101, through resistor R103 and finally leads through inductance L106 to the earth connection. The other capacitance varying diode D107 is in a much simpler branch, the one across the common resistor H108, the resistor R110 and the capacitance varying diode D107 itself to the ground connection leads.

A second DC branch leads via a resistor R135, one Diode D134, a choke coil 137 and the emitter-collector -Route a transistor 158; the current in this branch depends on the one through the amplifier the control circuit 144 from the voltage present at the base of the transistor 138. So if this current controlled by transistor 138 increases, it will the high frequency resistance of diode D134 decreases, and the voltage at the junction point the diode D134 with the resistor K135 and the diode D136 drops; thereby becomes the current in the branch made up of diode D15b, diode D131 and resistor R130 is decreased so that the high frequency resistance of the diodes D131 and D136 increases and the degree of damping is reduced. If the change is reversed, the resistance tends of the diode D134 towards infinity, the resistance of the diode D131 falls accordingly and D136 to a minimum value of 75 corresponding to a characteristic resistance of the attenuator. This resistance is exploitable within the whole Change range of the attenuator held essentially at this value.

It could be shown that the penetration of a stationary waveform at the entrance of the arrangement of attenuator and equalizer within the whole The control range of the arrangement does not exceed a value of 1.3.

Such an attenuator with PIN diodes provides essentially one constant attenuation regardless of frequency; This attenuator can in principle controlled by a pilot frequency at any point within the transmission band or even with a pilot frequency outside the transmission band, see above as long as this is still in the amplification range of the amplifier 11. For both derailleurs A common pilot frequency can also be used for automatic control; apart from this case, the low pilot frequency may of course be different from that Filters for the high pilot frequency are not allowed to pass and vice versa.

However, it is very advantageous within the scope of the invention that the Second pilot frequency placed in the low range of the transmission frequency band will. This allows the broadband amplifier 11 to be operated under optimal conditions, and such operation is important for the special circuit requirements which are placed in a broadband amplifier.

In addition, there is an instability in the gain of the cable amplifier rule out that result from the reaction between the two derailleurs for automatic control, the response time of the amplifier must 144 of the second ladder circuit is much larger than that of amplifier 124 of first derailleur. The response time of amplifier 124 becomes ten times that selected to be large as that of amplifier 144.

The effects achieved with the cable amplifier according to the invention are exactly as follows: The changes are in the area of the low pilot frequency at the output less than 0.1 dB for a change of 10 dB on the input side; in the area of the high pilot frequency, the changes at the output are less than 0.1 dB for a change of 5 dB on the input side.

Within a change range of losses of 5.5 dB at 300 Mifz (in the case of FIG. 3A) remains the deviation of the compensated sensitivity curve from a straight curve to 0.1 within the entire transfer band between 30 and 3OOMH limited.

The invention can of course also be used for any other frequency band above 300 spleen can be used.

The circuit of the cable amplifier according to FIGS. 4 and 5 results in a maximum accuracy for the correction of a coaxial line and allows automatic compliance with certain signal levels within the Stations by temperature and, within certain limits, by the Cable length $ are independent.

Embodiment cable amplifiers are in a theoretical Distance of 21 dB used. A cable with a transmission quality of 5.5 diS at 100 m at 300 MHz. For a step of 21 d there is a cable length of or m between neighboring cable amplifiers. The losses of this cable change changes with temperature by 0.002 dB per dB and ° C. If the arrangement with aerial cables is designed, the cable temperature can change between -20 ° C and +500 C, i.e. within a range of 700 C. The total change in cable losses at 300 MHz is then: 0.002. 21. 70 = 2.94 dB.

The equalizer according to the invention can change by 5.5 db Compensate 500 MHz, so that it also lengthens a change range of the cable can compensate, according to: 5.5 - 2.94 = 2.5b d3, i.e. 73 or also + fG m related at 6X0 m.

In the case of an underground arrangement using the postal channels the temperature change can be estimated over a limited range of about 20 ° C. The change in cable losses at 21 dB. is therefore: 0.002. 21 20 = 0.84 dB at 300 MHz.

Looking at the same compensation of 5.5 dB as in the previous one Case one can be satisfied with an equalizer for every third cable section, the same variation in the length range applies to the three sections.

The cable amplifier can also be a logic circuit Include positive voltage for remote monitoring from Gives interference when one or the other or both pilot frequencies from any Reason not arriving exactly enough; at the same time the arrangement of the attenuator and equalizer can be switched to a level control.

In this way, despite a possible interference from a pilot wave, the output level of the amplifier can be held on a manually regulated sail, as before the use of the circuit for automatic control was common. The same Incidentally, the level can be corrected with manual control by means of a heat probe is built into the cable amplifier and acts on the attenuator.

Fig. B shows an arrangement for broadband electrical transmission Vibrations with cable amplifiers according to the invention.

A terminal 6 emits the electrical signals via the cable 7, which e.g. comprise several television channels. In series are cable amplifiers 8A, 8B ... inserted into the coaxial cable 7. The cable amplifiers dA and 8B are e.g. at branch points 9A and 9B arranged for branch lines. An auxiliary source bA gives to the coaxial cable 7 the two pilot frequencies F1 and P2 at a constant level. The source of aid 6A is set up directly next to the remote station 6 or is also integrated into the same.

It is not necessary that: all cable amplifiers in the sense of Invention are formed. A corrective effect already results with one single cable amplifier according to the invention. You can also use individual cable amplifiers the circuit diagram of FIG. 1, others according to the circuit diagram of FIG.

It is extremely important to have cable amplifiers in the transmission line to be installed according to FIGS. 4 and 5 at a mutual distance which is a maximum value does not exceed.

This maximum value depends on the type of coaxial cable as well as to a lesser extent Scope depends on the climatic values.

The invention is not restricted to the embodiment described. Above all, the invention is also applicable to transmission bands in other frequency ranges or can be used with a larger width.

L e r s e i t e

Claims (10)

Cable amplifier for broadband electrical transmission Sigale, which contains an equalizer with adjustable frequency sensitivity, thereby characterized in that the increase in the frequency sensitivity of the equalizer (10) is adjustable within the transmission band and that on the output side of the equalizer (10) is coupled to a chain circuit (12) for automatic control whose control output signal the increase in the frequency sensitivity of the equalizer depending on the signal level within a narrow section of the transmission band influenced at the output of the equalizer. 2. Cable amplifier according to claim 1, characterized in that the Chain connection for automatic control in series connection of a narrow band filter (121), a level detection circuit (122), a comparator (123) which is connected to a Reference value is applied to represent a desired level, and a Control circuit for the adjustable increase in frequency sensitivity of the equalizer wherein the control circuit comprises increasing the frequency sensitivity of the equalizer depending on the deviation between that detected within the narrowband filter Signal level and the reference value influenced. 3. Cable amplifier according to claim 2, characterized in that the The equalizer includes a correction attenuator which is a T-resistor attenuator circuit (R 101, R 102, R 103), one parallel to the legs (R 101 and R 102) of the T-circuit connected series resonance circuit (L 104, C 105) and one in series on the center bar (R 103) the T-circuit connected parallel resonance circuit (L 106, L 107), wherein the tuning frequencies of the resonance circuits are within a frequency range above or in the range of the maximum frequency of the transmission band by the control signal are adjustable that the control circuit (124) on the two resonance circuits acts to adjust the tuning frequency depending on the deviation between the signal level detected within the narrow band filter and the reference value control, and that the narrow band filter on a section in the upper frequency range is tuned within the transmission band, the simultaneous shift the tuning frequency of the two resonance circuits a change in the increase in frequency sensitivity causes the correction attenuator within the transmission band. 4. Cable amplifier according to claim 3, characterized in that d each Resonant circuit contains at least one capacitance variation diode (D 105 or D 107) and since the control circuit (124) for these capacitance-varying diodes is variable The polarization voltage supplies the diode capacitance and thus the tuning frequency of the two resonance circles changed. 5. Cable amplifier according to claim 3 or 4, characterized in that that the equalizer contains a further frequency-independent attenuator (13), whose attenuation is controllable, but is frequency-independent and that before the correction attenuator (10) is arranged, and that the cable amplifier is a further chain circuit for automatic control, the input of which is on the output side of the equalizer is removed and the output of the frequency-independent attenuator (13) in Depending on the signal level at the output of the equalizer controls, this Signal level within another narrow frequency segment of the transmission band is removed. 6. Cable amplifier according to claim 5, characterized in that the other buckle frequency segment is located at the lower end of the transmission band. 7. Cable amplifier according to claim 5 or 6, characterized in that that the frequency-independent attenuator (13) contains iIN diodes, which by a the second chain circuit for automatic control flowed through certain direct current will. 8. Cable amplifier according to one of claims 1 to 7, characterized in that The same has a broadband amplifier connected in series to the equalizer (11) and that the two chain circuits (12, 14) to the output of the broadband amplifier (11) are coupled. 9. Arrangement for broadband transmission of electrical signals with a transmitting station, a transmission cable connected to the transmitting station and with cable amplifiers inserted into the same, characterized in that at least a cable amplifier designed as a cable amplifier according to claims 1 to 8 and that the transmission point is within the narrow frequency segment of the transmission band emits a pilot frequency with a constant level. 10. An arrangement according to claim 9, characterized in that the transmitting parts (6) Another pilot frequency with constant level within the second narrow one Frequnezausteils transmits within the transmission band.