DE969029C - Circuit for the remote supply of amplifiers in telecommunication cable systems - Google Patents

Description

ISSUED APRIL 24, 1958

M 17191 Villa / 2ia ^z

has been named as the inventor

In the case of telecommunication cables operated at a carrier frequency, the amplifier points are known to be so The wider the transmitted frequency band, the shorter the distances. For economic For reasons, manned main booster offices are only placed at greater distances, while those in between unmanned intermediate repeater offices via the wires in the cable from the main repeater offices be fed from. In addition to supplying the intermediate amplifier with direct current the supply with low-frequency alternating current is already known. It is also known supply from both ends of a main amplifier section and use the same for this purpose To use lines on which the message transmission and especially the carrier frequency transmission takes place, e.g. B. the symmetrical lines connected in parallel for this purpose or the coaxial lines of the cables. The coaxial lines with their opposite symmetrical Let- ao In general, larger cross-sections are also suitable for remote powering in cables which contain both types of cable side by side and are referred to as "combined cables".

In Fig. Ι is an example of the cross section of an as such known combined cable illustrated in order to facilitate an understanding of the following figures which are deal more closely with the invention to facilitate. Above the coaxial line forming the cable core, from the inner conductor ι and the outer conductor 2

7 «961/5

is formed, the z. B. consists of a copper pipe A , there is a stranded layer L of z. B. star fours, of which the star quads 3 is shown with its four cores, while the remaining star quads, as usual, are only represented by circles. The cable jacket 4, which can be made of metal or plastic, is located above the stranded layer of the star quad 3. The insulation of the conductors, conductor groups and individual layers of the cable is not shown because it can be carried out in the usual way and is of no importance for the invention.

In this cable, assumed only as an example, the trunk circles of the star quad z. B. carrier frequency, the phantom circles, on the other hand, are operated at low frequencies. As usual, the coaxial line is used the transmission of a particularly wide frequency band and can also remote power the Intermediate amplifiers are used, for which purpose the inner and outer conductors can be used. However, it is It is also known to lay two cables of this type next to each other and each cable has a direction of transmission assign. In this case or in cases where a cable has several coaxial lines contains, it is advisable to use only the inner conductor for remote power supply. This kind of feeding the inner conductors alone have the advantage of less interference from the symmetrical ones running along Cables. Nevertheless, the disturbances caused by the supply current can occur in the symmetrical Lines be so large that, for example, high-quality broadcasting can be carried out on them (e.g. i.e. on their phantom circles) is not possible. The measure of known remote feed circuits that Supply circuits symmetrical or asymmetrical, e.g. B. to the middle of the line-side windings Connecting the line terminating transformer with or without switching on chokes does not create any Remedy. The invention aims, through simple 'measures caused by the remote feed Reduce disturbances significantly.

According to the invention, this purpose is achieved with a circuit for the remote powering of amplifier offices achieved in telecommunication cable systems, which is characterized in that the feed currents in the individual Amplifier sections are poled in such a way that their interfering influence on neighboring low-frequency Voice and radio lines are fully or partially compensated. This measure is preferred in systems in which the intermediate amplifier offices are remotely supplied with alternating current. However, it is also useful in systems with remote direct current feed if the direct current is wavy or has higher harmonic components, for example from those generating the direct current Originate from machines. These are frequencies that are below approximately 500 Hz.

The one carried out unsystematically as required, compensating for the disturbance of the feed streams Polarity reversal should be on the feed lines, in other words, on the interfering lines, take place. It is therefore an essentially different measure than the well-known systematic or unsystematic one Crossing of transmission disturbed by crosstalk from any sources of interference. cables. Although the crossing in addition to the capacitor compensation to the oldest measures against Heard of crosstalk interference has apparently not yet been recognized that by crossing the disturbing lines instead of disturbed lines, which have been known as such for a long time, for remote feeding in amplification offices occurring malfunctions, which up to now one wanted to remedy with other, more cumbersome means, can be effectively eliminated in a much simpler and therefore also surprising way.

The polarity reversal of the feed currents is preferably carried out in the repeater stations themselves. However, it can also be used at other points in the telecommunication cable systems that are accessible for polarity reversal take place. The polarity reversal points result from the special conditions of the invention Telecommunication cable systems to be treated, so that it cannot be said from the outset whether in every repeater station a polarity reversal of the feed currents is necessary or expedient.

According to a further embodiment of the invention, the should over the individual amplifier sections flowing feed streams are supplied in such a way that they deviate little or no from ο or i8o ° Have phase rotations. Furthermore, in addition to the selection of the amplifier points, in which the polarity reversals are made, the rms values of the feed currents required at these points be measured or adjusted so that the best possible compensation effect is achieved.

The invention will now be explained in more detail and at the same time illustrated in exemplary embodiments. For this serve Figs. 2 to 6 of the drawing, namely

Fig. 2 as an example of a practical case of remote feed in a schematic representation,

FIG. 3 as an equivalent circuit diagram associated with the left-hand part of FIG. 2,

4 as a representation of the current and voltage profile in this case without application of the invention,

5 and 6 as two corresponding exemplary embodiments using the invention.

Fig. 2 shows the basic type of supply in the form of an example. The left main amplifier office H ₁ feeds the intermediate amplifier offices Z ₁ , Z ₂ and Z ₃ , while in this example the right main amplifier office H _s only feeds the one intermediate amplifier office Z _4. The feed currents J ₁ to J _i flowing in the individual amplifier sections are of different magnitude, while the amplifier sections are all assumed to be of the same length, namely Z.

In FIG. 3, the influencing case shown on the left in FIG. 2 is shown schematically. In the interests of better clarity, a larger scale has been selected for the section length I in this and the following figures. Taking into account the lower interference frequencies, the resistances r or R and the capacitances C of the sections I of the stranding layer L of the star quads 3 (FIG. 1) and the copper tube A forming the outer conductor 2 (FIG. 1) can be divided into the first and third Section in ¹ ^ l or ³ J ₁ I long sections

individual positions are accepted in a concentrated manner. For the sake of simplicity, let us also consider the case of the supply assumed on the inner conductor ι and the outer conductor 2. The following considerations apply but also for a supply only on the inner conductors of two or more coaxial lines of telecommunication cable systems.

The currents J ₁ , J ₂ and J ₃ flowing in the individual sections I are, as already mentioned, of different sizes and cause the following currents and voltages in the sections of the individual circuits, which are formed from the star quadruple layer L and the outer conductor tube A:

wRC

= 3

16
wRC

16
wRC

wRC

h + J _s + 4J _z ),

Π =

16
wRC

16

(Jt + 5/3 + 4Λ). (—2 Y ₁ +2 Y ₃ +8 Y ₂ ),

(- 2 J ₁ +2 J ₃ - 8Y ₂ ), (i)

U ₁ =

ΊΓ

R. R.

(5/1 + / 3 + 4/2).

4 shows the voltages between the layer L and the outer conductor tube A and the currents within the layer for the example case that / 1 = /, / «= ² / s / and / ₃ = V ₃ / - the capacitances and resistances correspond approximately to actual proportions.

The noise performance in the balanced lines on the near and far end of these lines are obtained by summation of the noise generated in the individual services Teülängen Al, the distal end will be based on the near or.

The noise voltage Uf (x) caused by an average capacitance asymmetry e between a symmetrical circuit and the outer conductor within the subsection Al in the symmetrical circuit at point χ is the absolute value

coeZ

(2)

U '(x) corresponds to the various CT values in FIG. 4.

Likewise, the total current * 'flowing in the symmetrical circuit to be examined generates a noise voltage Uf * (x) of magnitude in the symmetrical circuit at the point χ within the subsection Al with the mean longitudinal asymmetry Ar

Ar

(3)

i (x) corresponds to the current i of FIG. 4. m is the number of similar circuits in the position. In the case of the phantom circles of the cable cross-section Fig. 1, for example, m = 8, in the case of the trunk circles m = 16. The noise power at the near end now results from (2) and (3)

(Uf (X) * + U

f *

(4)

η is the number of sections of the length L Z is the wave resistance, β is the wave attenuation of the circuit to be examined of length Al.
The noise voltage at the near end is

w + tW)

p _f is the weighting factor of the frequency f. At 105, measurement of the external voltage, p _f = ^ ₈₀₀ . If several frequencies are involved in the creation of the noise, then is

CT (O) =

(6)

The corresponding formulas for the far-end noise are

Ν («) = ^ Σ (CT, * (xf + Uf * (xf) ■ e ~

Pwo

U ₁ (») =

The frequency spectrum of the impressed interference current or the impressed Uf * (xf) -e are therefore of importance for the magnitude of the noise voltage

(7)

(8th)

(9)

Interference voltage, the distribution curves of the latter in the length diagram of the line and the symmetry relationships the disturbed line.

Experience has shown that the third, fifth and seventh harmonics are still present in a supply current of 50 Hz decisive ", while the higher harmonics are less important. In the case of External voltage conditions, for example in the case of broadcast lines, this fact is more important Significance, as it represents a noticeable tightening of the values of the specifications. on the other hand It is precisely here that there is the possibility of very effective countermeasures. The smaller phase rotations Low-frequency currents enable a compensation effect, which is particularly effective is when the influence of reactive current components is eliminated at the repeater points.

FIG. 5 shows this for the case that, in the example of FIG. 4, the polarity of currents / ₂ and J _{3 is} reversed. Since the hatched areas in FIGS. 4 and 5 (as well as FIG. 6) are of decisive importance for the occurrence of the disturbances, one can clearly see the advantage of the opposing connection of the currents J ₂ and / ₃ . In FIG. 6, an even more favorable effect can evidently be achieved by switching currents J ₁ and J _{3 in line} and by switching currents / _{2 in the opposite direction.} The numerical calculation, assuming normal conditions, results. Note that the unweighted noise voltage for the fundamental wave of 50 Hz in the case of FIG. 6 is only about a third of that according to FIG.

As feeding the individual. Amplifier sections takes place in such a way that at the end of each of them the voltage is stepped up again, the desired compensation effect can be achieved, for example, by simply unipoles of the secondary windings of these transformers. It goes without saying that. this decreases with increasing frequency of the interference currents; however, for the reasons mentioned, the disruptive effect decreases for them, quite apart from the fact that a further reduction in the disruptive effect can be achieved by compensatory measures with regard to the asymmetries of the disturbed circuit.

The choice or dimensioning or adjustment of the effective values required at the polarity reversal points the feed currents should be made so that the compensating effect of the feed currents is optimal. That can be z. B. can be achieved with the help of the transformer without any particular difficulty.

Claims (3)

PATENT CLAIMS: 1. Circuit for the remote supply of amplification offices in telecommunication cable systems, characterized in that the feed currents in the individual amplifier sections are polarized in this way are that their disruptive influence on neighboring low-frequency voice and radio lines fully or partially compensated. 2. Circuit according to claim 1, characterized in that that the feed currents flowing through the individual amplifier sections are supplied in this way that they have no or only slightly different phase rotations from 0 or 180 ° own. 3. Circuit according to claim 1, characterized in that that the amplification points and the effective values of the required at these points Feed currents are chosen in such a way that the most optimal possible compensation effect is achieved will. Considered publications:
German Patent No. 606619;
U.S. Patent No. 2,526,942;
A. Engelhardt: "Fernkabel-Telephonie", 3rd edition, 1932, pp. 176, 181 and 203. 1 sheet of drawings