DE956695C - Circuit arrangement for level control in accordance with a control signal in a telecommunications system for transmitting signals via a coaxial cable - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

ISSUED JANUARY 24, 1957

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ² GROUP 36i4 INTERNAT. CLASS H04m

N9223 Villa / 2ia ²

Lodovicus Franciscus Dert and Rainer Ananda Schraivogel, Hüversum (Netherlands)

have been named as inventors

.N. V. Philips' Gloeilampenfabrieken, Eindhoven (Netherlands)

Circuit arrangement for level control

corresponding to a control signal in a telecommunications system for the transmission of signals via a coaxial cable

Patented in the Gelderland of the Federal Republic of Germany on July 21, 1954 Patent application published on July 26, 19S6 Patent granted pending on January 3, 1957

The priority of the application in the Netherlands of July 24, 1953 has been claimed

The invention relates to a circuit arrangement for level control according to a Control signal in a signal transmission system connected to a coaxial cable, e.g. B. one Carrier frequency telephone apparatus, a television transmission system or the like.

In practice, such devices that are used for the transmission of a wide frequency band, z. B. of a few MHz, are set up,

a need for a level control device to compensate for level changes in the transmission signals, which are essentially due to damping changes in the coaxial cable, e.g. B. due to of weather influences, temperature changes or the like., arise. The changes in attenuation are strongly frequency-dependent Character; it was z. B. measured that with a cable length of 18 km and a temperature change

tion of 23 ⁰ C at 60 kHz or 4000 kHz attenuation changes of 0.56 or 3.9 db occur.

To influence the frequency response of an amplifier, it is known to use an equalization network consisting of an adjustable T-circuit consists. Furthermore, it is known in carrier frequency telephone systems, the 'attenuation changes the transmission line by means of a level regulator connected to a level regulating motor compensate, the level control motor is controlled by a pilot tone.

The invention relates to a particularly advantageous level control device in one with a Coaxial cable connected signal transmission system.

The circuit arrangement according to the invention has the feature that the level control device is provided with a cable replica impedance which has a number parallel to the coaxial Includes cable switched damping branches, each consisting of a series resistor and a variable Series capacitors with different time constants exist, while 'the Rotors of these series capacitors are arranged on a common shaft with a drive mechanism controlled in accordance with the control signal is coupled so that when driving of the common wave the size of the series capacitors is changed in the same direction. By applying the measure according to the invention, over the entire transmission area and a surprisingly good compensation of the changes in attenuation of the over the entire control area Coaxial cable achieved, while the structure of the level control device is particularly simple. Here the adjustable series capacitors can be made from a multiple capacitor of conventional design exist.

The invention and its advantages are illustrated using two exemplary embodiments shown in the drawing explained in more detail.

Fig. Ι shows an amplifier station for the carrier frequency telephone traffic over a coaxial Cable equipped with a level control device according to the invention.

Fig. 2 shows a repeater station for television broadcasting via a coaxial cable with a level control device which is a modification of the in Fig. Ι represents the control device shown. In Fig. 3 are frequency attenuation characteristics to explain the in FIGS. 1 and. 2 shown Reproduced level control device according to the invention.

The repeater station shown in Fig. 1 forms part of a carrier frequency remote speaker system, which via a coaxial cable 1, 1 'z. B.

Transmits 960 speech channels in the frequency band from 60 kHz to 5 MHz.

The received carrier frequency telephony signals from the coaxial cable 1 become fed via an equalizer 2 to the input transformer 3 of a line amplifier 4, whose Output circuit is connected to the coaxial output cable 1 '. To compensate for level changes, which are brought about by changes in attenuation in the transmission path is in the repeater station between the equalizer 2 and the input transformer 3 of the line amplifier 4 a level control device 5 is arranged, which of a together with the speech signals via the coaxial Cable 1 sent control signal with a frequency of z. B. 4 MHz is controlled. The sent Control signal of 4 MHz is after amplification in the line amplifier 4 to the Line amplifier output connected to the control receiver 6 supplied from the cascade circuit a circuit 7 tuned to the S expensive frequency, a control amplifier 8 and a rectifier circuit 9 consists. The output circuit of this rectifier circuit is thereby a DC control voltage used for level control is taken.

The level control device 5 is equipped according to the invention with a cable simulation impedance, which consists of three parallel-connected attenuation branches 11, 12, 13 each with a series resistor 14, 15, 16 and a variable series capacitor 17, 18, 19; the rotors of these series capacitors are, as shown schematically in the figure, arranged on a common shaft which is connected to a drive mechanism 20 controlled in accordance with the control signal.

The attenuation branches 11, 12, 13 have different time constants, and the attenuation branches with their successive time constants essentially contribute to the tendency of the damping characteristic in subsequent frequency sub-bands; at the maximum capacity of the regulating capacitors 17, 18, 19, these time constants are z. B. 3 x io ~ ⁸ or 26 ■ io ~ ⁸ and 245 · ro- ⁸ seconds. It can be seen here that the overall damping characteristics of the three. Attenuation branches over the entire frequency band to be transmitted from 60 kHz to 4 MHz corresponds exactly to the frequency-dependent curve of a change in attenuation in the transmission path.

In the circuit arrangement shown, these are a smaller time constant than branch 13 having branches 11, 12 connected to the coaxial line 1 via a coupling transformer 2i; the series capacitor 19 of the attenuation branch 13 with the largest time constant is located between the ends of the secondary winding of a coupling transformer 22, its primary winding is connected to the coaxial line 1 via the series resistor 16. The transformative one Connect the capacitors 17, 18, 19 to the coaxial cable 1 has the consequence that with suitable transformation ratios of the transformers 21 and 22 capacitors of small capacitance can be used, which has the important advantage has that the level control device in a small Space can be accommodated; z. B. is in practice the level control device as a structural unit in

placed in a rectangular container of 4.5-10-8 cm ³ . In addition, this measure allows the use of capacitors of essentially the same size.

The transformer 21 for connecting the branches 11 and 12, which are only used in the high frequency sub-bands are effective, is designed as an autotransformer to reduce the leakage inductance to the lowest possible level to belittle. It is precisely the leakage inductance that causes the higher signal frequencies have an undesirable effect on the damping characteristics. The transformer 22 to connect the attenuation branch 13 with the largest time constant has windings that are capacitively shielded from one another in order to prevent interference the attenuation characteristic at the lower signal frequencies due to undesired transformer capacities reduce to a minimum. When setting the common rotor shaft of the regulating capacitors are the ratios of the time constants of the damping branches 11, 12, 13 is maintained unchanged, and essentially only the curve of the attenuation as a function changed the frequency. The undesirable influence of undesirable impedances on the through the Damping branch 13 has certain damping characteristics, which are particularly evident in the case of low values of the regulating capacitor 19 makes noticeable is in the circuit arrangement shown largely reduced that parallel to the primary winding of the transformer 22 a correction. impedance in the form of a damped series circuit 23 with a tuning frequency of 400 kHz, for example is switched.

Fig. 3 shows some damping characteristics to explain the level control device described.

In this figure, the curves a, b and c represent damping characteristics of the level control device, in which the damping is plotted against the logarithm of the frequency at different positions of the common rotor shaft of the variable capacitors 17, 18, 19. The curves α and c represent the damping characteristics for the maximum and minimum capacitance of the capacitors 17, 18 and 19; curve b shows the. Attenuation curve at an intermediate value.

In the figure, the dotted curve d shows a measured change in attenuation of the coaxial cable 1, which corresponds to the attenuation characteristic α of the level control device. It can be seen that curve d, the course of which is proportional to a close approximation of the square root of the frequency, corresponds exactly to the attenuation curve α of the level control device; z. B. the mutual deviations of these two damping characteristics α and b over the entire frequency band to be transmitted are smaller than ο, ι db.

In order to obtain a wide control range, capacitors with a large ratio are used between the maximum and the minimum capacity, in particular a larger one as 10, used; namely, the control range of the level control device shown is essentially by the ratio between the maximum and minimum capacitance of the capacitors 17, 18, 19 conditional.

To explain the level control device described, some data of a equipment that has proven itself in practice. '

Transformation ratio of the transformer 21 1: 2

Stray self-induction of the transformer 21 0.13 ^ H

Resistance 14 650 Ω

Capacitor 17 400 pF

Resistance 15 150 Ω

Capacitor 18 200 pF

Transformation ratio of the transforma-

gate 22 1: 6

Resistance 16 - 290 Ω

Capacitor 19 234 pF

Ratio between the maximum and minimum capacitance of the capacitors

17, 18, 19 about 36

The level control device described here is used to compensate for level changes in a coaxial cable of 18 km length with an attenuation of 4.8 db / km at 4 MHz and 25 ⁰ C.

The level control takes place in the case of the one shown Circuit arrangement by means of the control motor 20, which is connected via parallel branches 24, 25 to the Terminals 26 of a power source, not shown, is located. In each branch 24, 25 there is one Normally open contact 27, 28 of a delayed dropping maximum or minimum relay, their excitation windings 29 and 30 are in the output circuit of the rectifier circuit 9. ioo

If the level of the control signal falls below a certain limit value, this speaks with a delay falling minimum relay 28, 30, whereby the control motor 20 is set in the state, the Adjust level control device 5 to minimum attenuation. In the opposite case, that speaks Maximum relay on, and the level control device is set to maximum attenuation. While During the control process, the level changes very gradually over the entire frequency band, which is a special one results in calm level control.

The level control can also take place in such a way that the output voltage of the rectifier circuit, after being amplified in a power amplifier, is fed to the regulating motor 20 as an operating voltage. With such a level control _x it can be achieved that the sum of the cable attenuation and the attenuation of the level control device is kept essentially constant, that is to say that the changes in attenuation of the cable 12 are practically completely compensated here.

There is also the possibility of using a so-called program control in which the Level control device 5 directly from an end station by means of a z. B. About a special one Cable · skillful control frequency is controlled.

To be a quiet settlement, especially for one

undisturbed telegraphic transmission to achieve ..

should be the control speed at the shown

Circuit arrangement low, e.g. about 0.1 db / sec., to get voted.

In the circuit arrangement shown, the level control device 5 is a two-pole network designed, in which a very precise adaptation of the cable impedance to the level control device is not easily feasible. In general, they are caused by mismatching errors Reflections do not interfere with telegraphic and telephone traffic; these can be reduced to a considerable extent by the fact that the level control device 5 connected in the manner shown in the figure via the equalizer network 2 to the coaxial cable will / In the case of a television broadcast, however, adjustment errors should largely be avoided which can be done in the manner shown in FIG.

Fig. 2 shows an amplifier station for television. transmission with z. B. a frequency band of 30Q kHz to 6 MHz via a coaxial cable, the structure of which is essentially that already on hand corresponds to the apparatus described by Fig. ι. Corresponding parts are provided with the same reference symbols.

In this design, the level control device 5 is designed as a four-pole network; here namely forms the attenuation branch 31 with the series resistor 32 and the variable Series capacitor 33, the shunt arm of a bridged T-filter, whose resistors 34, 35 existing series impedances by connecting a fixed resistor 36 and one in parallel variable self-induction 37 are bridged with an adjusting member on the common Drive shaft of the capacitors 33, 18, 19 is arranged. The damping branch 31 and the Series branches with the parallel resistor 36 and the parallel self-induction 37 form reciprocal ones Impedances.

It has been found that by using the four-pole network mentioned, reflection phenomena largely avoided. The influence of an incorrect termination of the bridged T-filter by the attenuation branches 12, 13 can be reduced considerably as a result that a correction impedance 38 is arranged in series with the resistor 34 will. This consists z. B. from a resistor,

In order to reduce the remaining reflection phenomena, a second attenuation branch can be integrated bridged T-filter can be included. With a particularly favorable training of such Network, the two attenuation branches form the Ouer branches of a bridged T-filter; and the series branch consists of the series connection of two networks, each of which consists of the parallel connection a resistance and a self-induction. i

It has been found in practice that such a level control device provides excellent television transmission enables.

Claims (14)

Patent claims: 1. Circuit arrangement for level control in accordance with a control signal in a telecommunications system for the transmission of signals via a coaxial cable, characterized in that the level control device with a cable replica impedance is provided which is a number in parallel with the coaxial cable contains switched attenuation branches, each consisting of a series resistor and a variable Series capacitor with different time constants exist while the rotors of these series capacitors are arranged on a common shaft, the is coupled to a drive mechanism controlled in accordance with the control signal, so that when driving the common shaft the size of the series capacitors are in the same direction will be changed. 2. Circuit arrangement according to claim 1, characterized in that at least three Damping branches are provided with different time constants and that the attenuation branches mainly with the size according to successive time constants contribute to the inclination of the attenuation characteristic in contiguous frequency sub-bands. 3. Circuit arrangement according to claim 1 or 2, characterized in that at least the regulating capacitor of one of the damping branches is coupled via a transformer. 4. Circuit arrangement according to claim 3, characterized in that the damping branches with different time constants Damping branch with the smallest time constant via an autotransformer to the coaxial cable is connected and from the attenuation branch with the largest time constant the regulating capacitor is coupled via a transformer which is provided with a capacitive shield so that the un- desired capacities are reduced to a minimum. 5. Circuit arrangement according to claim 1, 2, 3 or 4, characterized in that parallel to the primary winding of the coupling transformer a damped one for the control capacitor of the damping branch with the largest time constant Series circuit is connected. 6. Circuit arrangement according to one of the preceding claims, characterized in that that the ratio between the maximum and minimum capacitance of the variable series capacitors has a large value, in particular greater than 10. 7. Circuit arrangement according to one of the preceding claims, characterized in that that at least one of the damping branches the Forms cross branch of a bridged T-filter. 8. Circuit arrangement according to claim 7, characterized in that the series impedances of the bridged T-filter by connecting a resistor and a variable in parallel Self-induction are bridged, the adjustment element is coupled to the common rotor shaft of the variable capacitors. 9. Circuit arrangement according to claim 7 or 8, characterized in that the shunt branch -the bridged T-filter and the parallel connection of the resistor · and the control self-induction represent reciprocal impedances. 10. Circuit arrangement according to claim 7, 8 or 9, characterized in that behind the bridged T-filter the other attenuation branches are connected and that in that of this attenuation branches facing away from the series branch of the bridged T-filter a correction impedance is connected to the aforementioned attenuation branches for impedance matching. 11. Circuit arrangement according to claim 7,8,9 or 10, in which two attenuation branches are included in a bridged T-filter, thereby characterized in that the two damping conditions form the cross-branch of the bridged T-filter and the longitudinal branch emerges the series connection of two networks, each composed of one of a resistor bridged self-induction exist. 12. Circuit arrangement according to one of the preceding Claims, characterized in that the regulating speed of the level regulating device less than 0.4 db / sec. is. 13. Circuit arrangement according to one of the preceding Claims, characterized in that the level control device has an equalizer connected to the coaxial cable. 14. Circuit arrangement according to one of the preceding Claims, characterized in that the level control device by the drive mechanism when the control signal falls below a certain limit value or when another limit value is exceeded is set to minimum or maximum damping. Considered publications:
German Patent No. 899,372;
W. Klein: "Carrier Frequency Technology", 1949, p.68. 1 sheet of drawings © 609576/3 * 1 T. (609 773 1.57)