DE386048C - Cable with steadily distributed self-inductance and compensation of crosstalk through additional capacitors - Google Patents

Description

Cable with steadily distributed self-inductance and compensation of crosstalk through additional capacitors When compensating for crosstalk through additional capacitors In the case of pupinized lines, the capacitive and inductive coupling is balanced made for each coil spacing. There are therefore just as many capacitor boxes available as coil boxes for one wavelength, and the spacing of the capacitor boxes between each other is the same as that between the coil boxes. The condenser boxes are accordingly also arranged according to Pupin's rule, and it will be accordingly five to six condenser boxes per wavelength used.

Applying the same rule to compensate for crosstalk at Cables with constantly distributed inductive load, e.g. B. for Krarup cables with iron wrapping, it has now been found that the crosstalk was improved only insignificantly.

Theoretical considerations, which are explained below, have now shown that in cables with continuously distributed self-inductance the distance the capacitor boxes should be chosen to be much smaller than what follows from Pupin's rule must for a reasonably noticeable improvement in crosstalk at least twelve capacitor boxes, but expediently more provided per wavelength will.

The general theory of internal induction in pupinized lines (WV sd SK 1921) provided the relationship for the capacitive induction current in a double line with the characteristic impedance q2 - and the propagation constant y2 Here, Tt means the receiver resistance, kv the capacitive coupling in the v ton coil field p - jw and y1 the propagation constant of the inducing line. From this relationship, the one that is valid for a line that is homogeneous with regard to the four line constants emerges without further ado, namely as a borderline case for the coil spacing zero; so you get Instead of the summation, the integration over the line length l takes place; k is now a function of the distance x from the start of the line. If the coupling is purely inductive, namely = m for the unit of length, this results in the same way If both types of couplings are present, one obtains accordingly From this it can first be seen to what extent the compensation of the inductive coupling can take place by an additional capacitive one; The possibility of this procedure is given by the fact that the characteristic impedances' 1 and 32 are predominantly real and constant in the important range of the speech frequency (n in the case of inductively loaded lines set and refer to this size as the electromagnetic coupling between the two lines; it changes its value in general with x, but is practically independent of the frequency. For the abbreviation one introduces an average propagation quantity by means of the relation 7, + 72 - 2 y # Then becomes For a small section of length s, which we choose as the compensation section, is therefore The relationship would supply the receiver current that exists when the line is already balanced by some means in the remaining section s to l, i.e. it describes the conditions as they exist during the compensation to be carried out. One can initially assume that s is small enough that approximately 8 J; s = I-2yS.

One can later convince oneself of the admissibility of this assumption. Then it will be If y is broken down into the attenuation measure, ß and the angle measure a, so is If you add a coupling K at the beginning of the lines, at x - o, to compensate for the originally present (K), the induction current is created It can be seen from this that only the part can be compensated. There remains a coupling of size which is not eliminated and which degrades the quality of the balance. If one assumes on average that K is independent of x, then KO = -K s + KP s2 must be made, the remaining coupling is a, = has2. So while the absolute amount of the induction current before equalization was, after the introduction of KO, there is still a disruption of size before. The ratio [In] : [I n %, which is to be denoted by n, gives a measure of the degree of improvement achieved by the compensation. According to equations ii and i2 -ist This is the relationship we are looking for for the size of the compensation section.

Example. For a Krarup cable y, let R = 30 ohms, L = o, oi H, C = 0.035 MF. The requirement is that the crosstalk be eliminated on the fifth part of the original induction.

It is according to known formulas for the frequency ul = 5000 Therefore, according to equation 13, with n = 3 s = i, 8 km.

The capacitor boxes would therefore have to be arranged at the intervals.

According to Pupin's rule, one would be under the same given circumstances get to a condenser box spacing of 8.4 km, a distance that is much too is great to bring about improvement. According to the above, this would be the case @n = i, 34.

Since large couplings in the cable also have a higher degree of Compensation, i.e. larger n, must demand, according to these considerations, the The length of the compensation sections depends largely on the quality of the manufacture of the cable away.

Claims (2)

PATENT CLAIMS: i. Cable with constantly distributed self-inductance and with compensation of the crosstalk by means of additional capacitors, characterized by such a dimensioning of the distance between the successive capacitor groups, that at least twelve of these, but preferably more, are accounted for by one wavelength. 2. Cable with continuously distributed self-inductance according to claim i, characterized in that the dimensioning of the capacitor group spacings according to the equation takes place, in which s is the distance between the capacitors, a is the angular dimension of the line and n is the ratio between the original induction and the induction present after the equalization.