DE2914772C2 - Identification of cable cores carrying digital signals - Google Patents

Description

The invention relates to a method for identifying digital signals with a constant pulse repetition frequency and phasing conductors of a cable at an examination site, and arrangements for Implementation of the procedure. When setting up digital transmission lines and after cable repairs the assignment of the signal-carrying wires or wire pairs must be checked again. With digital According to the state of the art, this is transmission links only from the assigned terminals air-.

possible, in which there are fault location devices. Such a test is very complex and to the Existence of fault location devices tied. It is desirable to have the opportunity to take an exam at the Investigation agency is available. Such a test device has so far only existed for the cores of Low frequency cables. This tester is based on the fact that during operation by means of a 200 Hz tone the assignment of the wires is checked. There is currently no such cable for carrying digital signals Device, there are only devices that detect the presence of PCM signals on the wire pair of a cable can recognize.

The object of the invention is therefore to develop a method of the type mentioned at the beginning, this one The method should be usable during operation and should not interfere with the transmission of the digital signals. In addition, the method must offer the possibility of simple and uncomplicated devices for implementation to build up this process, which, because of their robust construction, allow them to be used at the repair points.

According to the invention the object is achieved in that during the transmission of the digital signals in the Signal path in front of the examination site, the reactance at one point of the wire under consideration is changed recognizably and at the examination site the digital signals on the occurrence of a Phase modulation with a corresponding period can be investigated. The particular advantage of the invention The method is based on the fact that it is bit-pattern independent, i.e. digital signals with arbitrary coding can be used provided they have a constant pulse repetition frequency and phase position. The during The jitter occurring during operation does not interfere in the practical case. Another essential one The advantage of the method according to the invention is that no electrical energy is fed into the line which could possibly lead to malfunctions. Further advantages are that with the process a large Range can be achieved. Since digital signals are often transmitted using twin wires a further development of the method according to the invention expedient in the identification of Paired wires the impedance of both wires against each other changed wi / d. A useful further development the inventive method results dadurcii that the change in the impedance of the wire by periodic connection of a reactance takes place. With regard to <S, ~ s occurrence of jitter disturbances With certain frequencies, a further development of the invention is expedient in which the change in the Impedance of the wire by connecting a reactance in the rhythm of a pulse train with lower Pulse follower frequency takes place. Further expedient developments of the invention are set out in the claims 5 to 12.

The invention is to be explained in more detail below with reference to the drawing.

In the drawing shows

I shows the block diagram of part of a transmission link with a transmitter and a receiver for identifying wires,

2 shows a transmission circuit for feeding in clock phase jitter ^; n a generation of a phase modulation of the digital signals PCM pair and

3 shows the assembly; play between sender and receiver in two cases.

In FIG. I is part of a common PCM transmission path with regenerators 1, 2, 3 ... n- \. π shown. These regenerators are connected to each other and to the assigned terminals via a two-wire

ϊ line, i.e. the wire pair of a cable connected. In the signal path upstream of the first regenerator 1, a transmitter SE is connected to the two wires, while after the regenerator π should be the examination point at which the receiver fan is connected to the wires.

ι »The one shown in FIG. The transmitter Sf shown in FIG. 1 contains two capacitors, one terminal of which is connected to one of the two wires of the transmission path, while the other terminals are connected to one another via a switch W controlled with the frequency / ö

υ are connected. The coupling by means of two capacitors was chosen in order to improve the symmetry properties of the wire pair not to be changed. By switching the capacitors on and off The generated phase deviation of the PCM clock is:

with

ω ν

Λ φ - (- arctan - = - - Λ 171
V π daily \ CZ J

Bit period

Characteristic impedance of the twin wire

switched-on capacity

Yt-h

Clock frequency.

(1)

By loading the wire pair with the additional capacitance Cz , the PCM signal is additionally attenuated. The additional damping results from:

Aa ₁ = -20 · '"log (1 / νΊ + (u.vCZ / 2) [dB]

The same phase shift but in the opposite direction. can also be achieved by switching on a coil with the inductance L , the inductance Laus

L =

o \ C

results.

In practical operation it has been found that additional attenuation of the transmitted PCM signal of 0.4 dB can be tolerated and is also sufficient for identification. It then results in a Phase deviation of about 30 mT with a connected capacitance C of about 250 pF.

Lei of the definition of the maximum additional attenuation for the PCM signal is the behavior of the Amplitude control circuit in the automatic equalizer consider. If the time constant of this control loop, which is dependent on the bit pattern, is less than 1 // Ό, then the d'irch becomes the periodic connection of the

μ) Amplitude modulation generated on the capacitor Amplitude decision-maker is unregulated and there is only a periodic lack of determination, which is the mentioned small values is negligible. If, on the other hand, the limit frequency of the amplitude control

·> Ses in the regenerate r is less than / Ό, so it comes to a Reduction of the mean signal amplitude at the amplitude decider. This results in a low Signal-to-noise ratio deterioration. These

but is then smaller, ils An. in this example. so less than 0.4 dB.

When using an inductor than to and Disconnectable reactance results in contrast on the deformation of the PCM signals at high frequencies when using a capacitor now a deformation at low frequencies This deformation is. especially with certain Codes like the HDBJ code are much more critical so that for this reason, as a rule, the Use of a capacitance as a switched reactance is preferable.

The examination office is connected to the receiver's cable wires, which consists of a high impedance transmitter, a close-coupled automatic equalizer with an active circuit, a connected one phase demodulator, as w ell em down freq'i'Mi / filter a low frequency amplifier and a servo-converter, such as a headset .ji.ih-jit The I. 'be ^ ^ .ra he' - '. Td * ¹ nv? »'! Η · ¹¹ ! V.'l · ·' ¹ * l'continuous impedance.! Tisgc leads. in order not to affect the PCM transmission at the interface. The signal impedance converter ensures the adaptation to the input of the equalizer. With the help of the ^.! ■. • i '- atic F nt / errers Γ with activated fact

The actual [; k ^! ML'n, il is generated from the I ¹ CM signal, the individual pulses of which have the generated phase modulation. Durih ilen Ph.isendenioilulator / '</ a low frequency * · Vt'nai is generated, 'Bardp.iU / • is (read by a set to the send side ■ .erwendete Su-uerfrequ-Miz f ·. ·! eleitet. From downstream Nl -Verstärke- · \ ■ λ rcl finally the headphones /. actuated, in the the ■■ '/ • - ■ Uk'te phase modulation as a tone with! er frequency.''"■'' ^K , ir.

D'i '-. H faults can au? the -. .'hertragiingsstrek ·

■ · ■ additional phase modulations, the so-called I "" er. are generated I'm an evaluable signal / ¹ I

■ --airen. ; s »a sufficient signal-to-noise level . · -L'irch phase modulation generated in the headset •. ·· ■ <K to secure the result

S.

■ I ''

B which is greater than the width of the hand of the N! Filter and S is drawn as a normalized signal noise.

In the Ii g. 2 shows the transmission circuit for generating the desired phase modulation in detail. With Λ I and Λ 2 the two signal-carrying wires are referred to, to each of which a choke Dr I or I) r2 and a capacitor f I or C2 are connected. The source Q generates an oscillation with the I requen / f " , the source (p acting as a current source. The base connections of a complementary transistor pair 7 1. 7"I; 7 "3, T4 are connected to the two connections of the source Q The transistors are connected in such a way that the transmitter connection of the npn transistor of one transistor pair is connected to the input connection of the pnp transistor of the other transistor pair, while the collector connections of these two connected transistors are separated via one of the both capacitors C1 and C2 are connected to the signal wire • \ I or -1 2. In addition, the l.mitteranscMtiLi of the pnp transistor 7 2 of the first

ii A ΓMfl l

I ransistors of the second I ransistorpaares connected 7 4 out is the collector terminal of the transistor 72 via a · ¹ first throttle Dr I to the second signal-carrying wire \ 2 and the collector terminal of the NPN transistor 7 4 is first with a zw rush throttle Dr 2 ML'iialleitenden core Λ 1 connected. By from the source (abeegehenen J pulses the ih are alternately) or the capacitors with the signalfiihrenden veins erhundenen transistors Π and 7 3, or the ubei throttles with the signal-carrying conductors connected transistors 7 ~ 2 and 7 "4-conductive so Thereby wud. alternately either an additional capacitance or an additional inductance is connected to the wire carrying the signal, thereby changing their resistance periodically.The method naturally also works if only an additional capacitance or only an additional inductance is connected.

The I ι g 3 shows the interaction between transmitter and receiver. where m of FIG. 3a is switched to receive. while in FIG. 3b is switched to send. The arrangement shown in FIG. 3 consists of a transmitter SF. a receiver £, a switch 55. which separates the transmitter SF from the signal-carrying wires A I or A 2 , a headphone or loudspeaker /. and switches 51 and 5 2. which connect the loudspeaker L to an output of the transmitter SE and the receiver E. The components described are combined in one unit. which is referred to as the identification unit. The internal circuit of the transmitter used is shown in FIG. 2 shown and explained, while in the Em, -catcher in the F ι g. 1 is used

Claims (15)

Patent claims: 1. Method of identifying digital signals with constant pulse repetition frequency and Phased conductors of a cable at an examination site, characterized in that that during the transmission of the digital signals in the signal path in front of the examination site the reactance is noticeably changed at one point of the wire under consideration and on the examination site the digital signals for the occurrence of a phase modulation with appropriate Period to be examined. 2. The method according to claim 1, characterized characterized in that when identifying twin cores, the impedance of the cores against each other is changed. 3. The method according to claims 1 or 2, characterized in that the changes the impedance of the wire is done by periodically connecting a reactance. 4. The method according to claims 1 to 3, characterized in that the change in the Impedance of the wire by adding a reactance in the rhythm of a pulse train low pulse repetition rate. 5. The method according to any one of claims 1 to 4, characterized in that the periodic Change in the cycle of a low-frequency oscillation takes place, the frequency of which with regard to the signal-to-noise ratio on the receiving end is selected and that the occurrence of phase modulation by a phase demodulator with a downstream bandpass filter and possibly via a Amplifier-connected transducer detected at the examination site on the vein under consideration will. 6. The method according to any one of the preceding claims, characterized in that of Wire to wire a capacitance is connected in parallel. 7. The method according to claim 6, characterized in that in a system PCM 30 at a phase shift of 0.03 of the bit duration from wire to wire at least one capacitor with a Total capacitance of 250 pF is switched. 8. The method according to any one of the claims 1 to 5, characterized in that an inductance is switched from wire to wire. 9. The method according to any one of claims I to 5, characterized in that an inductance is switched from wire to wire and that this inductance is changed. 10. The method according to any one of claims I to 5, characterized in that periodically A capacitance and an inductance can be switched alternately from wire to wire. 11. Arrangement for performing the method according to claims I to 10, characterized in that a switch (SS) connected to the signal-carrying wires transmitter (SE) is provided that a receiver (E) is connected to the signal-carrying wires and that a sound transducer (L) is provided, which is connected to the transmitter (SE) via a first switch (S 1) and a wide switch (.S '2) to the receiver (Ei !). 12. The arrangement according to claim 11, characterized in that the transmitter contains a first capacitor, on the one hand with the first signal-carrying wire (AX) and on the other hand with ■> the collector terminal of a first transistor (Ti) of the npn type is connected, that a second capacitor (C2) is also provided, which is connected on the one hand to the second signal-carrying wire and on the other hand to the KolIektoranschluB ι ο third transistor ( T3) of the pnp type is connected, that the emitter connections of the first and the third transistor are connected to one another, that a first choke (Dr 1) is provided, which is connected to the one connection with the second signal-carrying wire (A 2) and with the other connection to the collector connection of a second transistor (7 * 2) of the pnp type is connected, that a second choke (Dr 2) is provided, one connection with the first signal-carrying wire (A 1) and the other Ά other terminal is connected to the collector terminal of a fourth transistor (7 * 4) of the npn type, that the emitter terminals of the second and fourth transistor (Γ2, 7 * 4) are connected to one another and that the base terminals of the first and the j; second transistor (Tl, 7 * 2) with one terminal and the base terminals of the third and fourth transistor (7 * 3, Γ4) are connected to the other terminal of a current source (Q) and that the current source (Q) has an alternating current jo emits a frequency (fo) corresponding to the desired switching frequency. 13. The arrangement according to claim 12, characterized in that the switching frequency (fo) is keyed by briefly switching the power source (Q) on and off with a view to easier detection on the receiving side. 14. Arrangement according to claim 12, characterized in that the two chokes (Dr 1, Dr 2) with connected transistors (7 * 2, 7 * 4) or the 4 (i both capacitors (Cl, C2) with connected transistors (71, 73) are omitted. 15. The arrangement according to claim 11, characterized in that the receiver (E ^ on the input side one with the two signal-carrying wires (A 1, 4i A 2) connected high impedance transformer (Ü) contains that this transformer is an impedance converter (IW) and this is followed by an equalizer (E) with a clock circuit, that with the output of the equalizer (E) the input of a phase demodulation j (i tors (Pd) , the output of which is connected to the input of a low-frequency amplifier (V) via a low-frequency filter that acts as a bandpass filter for the switching frequency (fo) , to the output of which a sound transducer (^ is connected.