DE1052462B - Method and arrangement for determining the coupling between two lines - Google Patents

Description

Method and arrangement for determining the couplings between two Leads Addendum to Patent 822 107 The invention relates to a method to determine the couplings between two lines with one at the end reflection-free closed line impulses given and from the on the other line returning pulses determine the couplings. Furthermore relates the invention to arrangements for the practice of this method.

This known method according to the main patent takes place, for example to eliminate the crosstalk interference caused by the couplings between two lines Use. For this purpose a pulse voltage is applied to a line by a transmitter given and at the same time the time deflection of the electron beam from this transmitter triggered in a Braun tube. The ones coming back from the other line Pulses are fed through an amplifier to the deflection plates of the Braun tube, on which a sequence of impulses is recorded, from which far-reaching conclusions can be drawn draw on the type and size of the couplings that occur. The evaluation of a However, such a screen image is relatively difficult because of the received pulses do not directly reproduce the course of the coupling along the two lines. Above this difficulty also does not help the use of integration links send- or on the receiving side, the removal of the differentiation that occurs during the coupling which serves impulses.

The invention is based on the object of a method and a Order to exercise this procedure to indicate in which these difficulties are fixed.

According to the invention, the couplings between two lines are determined in the form of a temporally affine mapping of the coupling distribution between the lines, in that one of the lines is given a pulse in the manner of a step function and the pulse returning on the other line is fed directly to an oscillographic display device or by applying a pulse train to one of the lines that corresponds to the inequality is sufficient, and that the pulses returning on the other line are fed to the oscillographic display device immediately in the case of a transmitted square-wave pulse train and, in the case of a train of short-term transmitted pulses, after integration.

(Tec = limit of the specific transit time (transit time per unit of length) for high frequencies, t overlap length of the two lines in length units, cr, - limit value of the specific attenuation (attenuation per unit length) for high frequencies, half the period of the pulse train).

The German patent specification 953 707 is an arrangement per se known, in which a square pulse train to determine the local distribution is used by coupling points between two quadrupole lines. This well-known However, the arrangement works according to the fundamentally different from the subject matter of the invention Principle that the amplitude and time difference between the sent in a line Pulse power to that in a second adjacent line at the line ends effective interference power is related. For this purpose it is known at the Arrangement also requires a compensator along with the associated equipment. Farther it is from the magazine PCables et Transmission «Heft2, 1956, pp. 91 to 114, known, a step function for the determination of discontinuities in the wave resistance to use on the or of reflections in the course of a single line. From the same magazine issue 4, 1956, pp. 288 to 313, it is still known that Near end crosstalk on a second line using a step function to determine.

The invention is based on the following considerations. as Reflux can be called the momentum that occurs at a coupling point in an adjacent double wire of a cable and then in this to the input of the cable is transported. The time difference between the one in the disruptive management at time t = O and the one in the neighboring line The pulse returning at the same end is equal to twice the transit time in the cable up to the coupling point. In other words, it will be measured when measuring this return Impulse determines the non-stationary near-end crosstalk, with the help of which one spatially time-separated couplings, because depending on the distance of the Coupling the runtimes are different. For the following considerations it is assumed that the two coupling lines are at least approximately the same have specific running times, which is generally the case.

If this is not the case, replace z, with (z ,, + T2OD) / 2, where r 1 is the limit of the specific transit time for high frequencies in the disruptive Line means and 12- = this limit value in the disturbed line.

If one looks at two parallel double lines with the wave resistances Z 1 and Z2, which overlap over the line length I, then there is a capacitive and a magnetic coupling between these double lines. The specific coupling or the coupling coating at any point in the overlap area in relation to the near end of the double line with the characteristic impedance Z is K, ', which is to be given in capacitive units for the sake of simplicity in the following considerations. The coupling k »'is composed of the capacitive k' and the magnetic coupling coating 'as follows.

This relationship arises from the line theory.

The coupling of a differential line section dx is then kn 'dx, so that the voltage d U2 (x) caused by this coupling in the disturbed line with the characteristic impedance Z2 increases calculated. The relative return flow in the line is calculated from this equation with the characteristic impedance Z2. From this connection it follows that the return flow at a coupling point corresponds to the differential quotient of the transmission pulse. If pulses are sent on the line with the characteristic impedance Z1, the return flow does not necessarily represent a true temporal image of the couplings unless special precautions are taken as provided in accordance with the invention. If the return flow p (t) on the coupled line with the characteristic impedance Z2 is projected onto the fluorescent screen of a cathode ray oscilloscope, it is laborious to draw quantitative conclusions on the coupling distribution from the screen image without applying the teaching according to the invention.

As further investigations on which the invention is based have shown, a temporally affine image of the coupling distribution is obtained on the fluorescent screen of the cathode ray tube if a step function is used as the transmission pulse, that is, a direct voltage suddenly has to be applied to the line at time t = 0 the wave resistance Z, lay. To prove this, we use the spectral representation of the step function, which in this case reads as follows: The reflux in this case is quite general with simultaneous substitution x = t / 2r, o the reflux p (t) in the disturbed line results By converting this, the return flow p (t) to where C 'is the capacitance per unit length of the disturbed line (with the characteristic impedance Z2).

The return flow p (t) is therefore a temporally affine image of the coupling distribution.

However, these considerations only apply if there is a one-time step function is sent. The reflux is therefore only a one-time process that z. B. captured by means of a strongly afterglowing oscilloscope tube or photographically will. Most of the time, however, one wishes to have a still image on the fluorescent screen. In this case you have to have periodic pulse trains or pulses or periodic square waves use. How to proceed here in order to create an affine image of the coupling distribution with pulses is set out below.

The pulse, which is usually directed in the same direction, is often used as the transmission function. This has the disadvantage that it contains a direct current component in its spectrum, for which the lines have completely different properties than for high frequencies. It is therefore necessary to use a pulse shape which only contains frequencies above a lower limit which is dimensioned such that the transit time in the cable is constant for all frequencies of the pulse. (The constant component can be split off, for example, by capacitive or inductive coupling elements.) This is an indispensable condition for affine mapping. The lower limit is what is known as the critical angular frequency cvO of the line, which is derived from the equation calculated (a, = limit value of the specific damping for high frequencies). Pulse trains that have these properties are, for. B. pulses which consist of individual pulses following one another with alternating polarity (see FIG.

The smallest angular frequency for alternating pulses is w, = s / Tg ,. Furthermore, there is also a lower limit for TX, which is determined by the fact that Type greater than twice the running time 2t, the manufacturing length to be measured or The length of the overlap must be 1 of the two lines, the transit time t being the same , O I is, so that the return flow of the cable completely into the Time interval Tp falls into it.

This results in the following relationship for the pulse spacing Tp: To give a numerical example, it is assumed that the manufacturing length I is 300 m. It follows that type for a z, from z. B. 5 10-6s / km must be about 3 10-6s. This value corresponds to a fundamental frequency of the transmission spectrum (= ll2Tp) of around 170 kHz. But this also fulfills the right half of the above inequality, namely Tp </ o) 0; because for a cable with the specified z, the limiting angular frequency m0 is in the order of magnitude of 45 103 1 / sec].

As can also be shown, it is essential that the frequency range in which a practically constant amplitude spectrum of the transmission function is given, is as large as possible. The drop in a power spectrum towards higher frequencies zu is determined by the so-called correlation duration To. With introduction the correlation range r of the coupling distribution is then the correlation duration of the return flow # 0 = 2 r ##.

(The distance between understood successive couplings in the direction of the line, for another There is a connection or a correlation between these couplings.) Should therefore the coupling distribution with its fine structure mapped as precisely as possible in the reflux the pulse duration T must be equal to or less than the correlation duration, so T12rz ,. YTco- (10) To give a numerical example, assume the smallest Correlation range is r 1 m.

Then the pulse duration T <6 10-9s would have to be selected. At a The rectangular pulse sequence (cf. FIG. 4) is the edge rise time to fulfill this condition sized in this way.

The measurement of the couplings along the two lines is as follows: The deflection of the electron beam from the Braun tube A in Fig. 2 is proportional to the voltage ga (t) at the input terminals of the device A. The circuit isc must be set up in such a way that ga ( t) becomes proportional to the coupling fluctuations of the cable. If one uses as the transmission function uo (t) of the generator G, which has an internal resistance of the value Z1 of the connected line, a sequence of pulses of alternating polarity that satisfies the above conditions and one assumes a constant (ohmic) input resistance R, of the display device A, the proportionality between «a (t) and kn / can only be achieved if a coil Lv is connected in front of the display device, the impedance of which is even greater than R i at the lowest frequency of the transmission spectrum, ie w, L, Lv> ru (11) This inductance Lv is expediently divided symmetrically, as shown in FIG. 2, so that there is a coil with the value LV / 2 in each lead to R. The voltage zr, (t) is then given by It should be noted here that the voltage function assumes the opposite sign when the time advances by half a period Tp. This can be remedied by reversing the polarity of voltage ga (t) on display device A synchronously with the pulses. Another advantageous solution, in which the polarity reversal can be dispensed with, consists in extending the electron beam to a whole period 2Tp. The function n '(2) is then drawn twice on the screen, with the opposite sign, assuming a negligibly short or darkened beam return on the oscilloscope screen.

The input resistance of the display device A can, as shown in Fig. 3, can also be chosen capacitively.

A constant series resistor Rv must be selected, which is to be measured according to the inequality 1 Rv # (13) # 1 Ca. Analogously to the case of the ohmic resistance, the voltage usa (1) results in If instead of a pulse from a sequence of pulses of alternating polarity, a square wave (cf.

Fig. 4) used as a send function, this has the advantage that the Resistance in front of the display device A can be omitted, which increases the sensitivity possibly improved. The corresponding circuit is shown in FIG.

Claims (5)

PATENT CLAIMS 1. A method for determining the couplings between two lines, in which pulses are given to a line terminated without reflection at the end and the couplings are determined from the pulses coming back on the other line, according to patent 822107, characterized in that for time-affine mapping of the Coupling distribution between the lines on which one of the lines a pulse is given in the manner of a step function and the pulse returning on the other line is fed directly to an oscillographic display device or that a pulse train is given to one of the lines that corresponds to the inequality is sufficient, and that the pulses coming back on the other line are fed to the oscilloscope display device immediately in the case of a transmitted square-wave pulse train and, in the case of a train of short-term transmitted pulses, after integration. (T ,, O = limit value of the specific transit time (transit time per unit of length) for high frequencies, I = overlap length of the two lines in length units, a, = limit value of the specific damping (damping per unit length) for high Frequencies, Tp = half the period of the pulse train.) 2. Method according to claim 1, characterized in that when a series of brief pulses is transmitted, the The duration of each of the individual impulses is the same or less than the correlation duration the statistical coupling distribution is chosen. 3. Arrangement for performing a method according to claim i, characterized characterized in that a generator is connected to one of the two lines is, whose output voltage runs according to a step function, that both lines at the far end are closed without reflection and that at the near end the unpowered Line an oscillo graphical display device is connected, which is preferably one has real input resistance. 4. Arrangement for carrying out a method according to claim 1, characterized in that a generator (G) is connected to one of the two lines, the output voltage of which is one of the inequality fulfilling rectangular pulse sequence corresponds to the fact that both lines are terminated without reflection at the far end and that an oscillographic display device (A) is connected at the near end of the unpowered line and has a preferably real input resistance (FIG. 5). 5. An arrangement for performing a method according to claim 1 or 2, characterized in that a generator (G) is connected to one of the two lines, the output voltage of which is one of the inequality A satisfying sequence of short-term pulses corresponds to the fact that both lines are terminated without reflection at the far end and that an oscillographic display device (A) is switched on at the near end of the unpowered line, which is preceded by an inductance (Lv), preferably divided into both conductors, in the case of an ohmic input impedance (Ra) whose impedance at the lowest frequency of the transmission spectrum is still sufficiently greater than the ohmic input impedance of the oscillographic display device, while with capacitive input impedance (Ca) an ohmic series resistor (Rv), preferably split into both conductors, is switched on in the supply line to the oscillographic display device, which at the lowest frequency of the transmission spectrum is still sufficiently greater than the capacitive input impedance of the oscillographic display device (FIGS. 2 and 3). Considered publications: German Patent Specifications No. 822107, 953,707; "Cables et Transmission", 1956, No. 2, pp. 91 to 114, and No. 4, Pp. 288 to 313.