DE1762640C3 - Procedure and arrangement for impulse fault location with carrier frequency two-wire systems - Google Patents

Description

is.

8. Arrangement according to one of claims 2 to 7, characterized in that the modulator (14) eir Field effect transistor is.

9. Arrangement according to one of claims 2 to 7, characterized in that the modulator (14) eir Bridge modulator is.

10. Arrangement according to one of claims 2 to 7, characterized in that the operating point of the active element of the generator (15) from the demodulator (13) is controlled so that the oscillation amplitude of the generator corresponds to the shape of the bell pulse.

11. Arrangement according to one of claims 5 to 10 characterized in that the auxiliary amplifier (12) is an integrated circuit! Amplifier is.

The invention relates to a method and an arrangement for pulse fault location in TF two-wire systems by means of a location pulse sent by the sending office in Senderichtimg, which is in the intermediate repeater offices implemented in the superimposition of the opposite direction and the sending Office is fed again.

HF location methods for TF two-wire systems are known. However, these require either one different structure of the amplifier (i.e. each amplifier is a very specific location assigned within a route) or a lot of effort in the case of similarly structured amplifiers. When Example of this is the oscillator location method, as it is z. B. in the German Auslegeschrift 11 85 245 is described. Each intermediate amplifier is an oscillator with a precisely defined oscillation frequency and assigned to a certain transmission level, the signal of which is received and evaluated in the terminal will. The same number of different oscillators is required as the largest permissible number of Amplifiers between two feeding amplifier points. The different structure is because of the with it associated high manufacturing, testing and storage costs disadvantageous.

Fault location methods with similarly structured amplifiers also require a great deal of effort. The pulse-locating method described in German Patent 8 87 062 is an example of this a submarine cable system. There the from a terminal in a suitable frequency position emitted location impulses on the curved characteristics of the active elements in the underwater amplifiers converted into the frequency position of the opposite direction. The newly created impulses are transmitted via the amplifier path is returned to the terminal and evaluated there with complex measuring devices.

The reason is that, on the one hand, those falling in a suitable frequency range due to non-linearity The resulting frequency components are only very small, so that for this reason alone they are mil sensitive measuring devices must be determined at the entrance. In addition, interfering frequencies in the same frequency position due to the low amplitude of the returned pulses Error displays lead, so that a clear

Location is no longer possible. In addition, the non-linearity causes adjacent harmonics generated, which are separated from the actual size to be evaluated by complex filter devices have to.

A similar arrangement, in which, however, the implementation is not represented by a curved characteristic in the active elements of the underwater amplifiers, but through its own non-linear devices, is in The Post Office Electrical Engineers Journal, Vol. 54, Part. 4, January 1962, im Article "Location of Repeater Faults on Submarine Telephone Cables" by F.Scowen, pp. 252 and 253, described.

However, this known arrangement has the disadvantage that the transmission has to be interrupted when fault location is performed, because fault location is set in motion by DC polarity reversal in that the non-linear devices MR 1, MR 2 are switched on with the aid of relays. The use of relays is a further disadvantage of this arrangement, because it introduces considerable uncertainties into the transmission system, which can consist in the fact that the relays respond and thereby disrupt the transmission due to overvoltages, such as those caused by a lightning strike. These disadvantages are eliminated by an arrangement according to the present invention.

From the German Auslegeschrift 1161321 is also a pulse fault location method for a four-wire split-layer messaging system known. From column 4, last line to column 5, line 8 of this disclosure, it can be seen that for Locating impulses are to be used that have a flank that deviates significantly from a vertical, where best pulses without sharp corners and with as sloping and rounded flanks as possible best suited.

In addition, bell impulses are known per se, such as from the "Handbook of Applied Impulse Technology" by Dr. H. Rösch lau, in particular p. 281, can be found.

The object of the present invention is to provide an RF pulse fault location method and a corresponding one To create an arrangement in which the pouring devices used for the four-wire TF transmission system can be used.

To solve this problem the procedure is such that the locating pulse above BEZW. below the Usable frequency band, but still within the transmission band is transmitted that the locating pulse is a high-frequency bell pulse sent by the sending office, which is in the respective Repeater offices are screened out and demodulated, and that the demodulated bell pulses with brought a suitable carrier frequency in the frequency position of the opposite direction and the sending office is fed back.

The new method enables the amplifier sections to be checked during operation. the Control includes quantitatively and qualitatively all components of each individual amplifier, as the impulses run through the amplifiers in both frequency ranges.

The procedure is like the procedure for TF four-wire amplifiers, easy to use. The devices can be used by staff without special specialist knowledge to be served.

The intermediate amplifiers are interchangeable, stock

and testing costs are low. Additional cost and space requirements arise in the repeaters and end parts compared to other location methods only to a small extent.

An arrangement for performing the method according to the invention is designed such that at Intermediate amplifier offices with transverse amplifiers the output of the transverse amplifier is the high-impedance input of a location filter is parallel, the output rr.it is connected to a demodulator, which is connected to a Modulator is coupled, which at the same time with a generator with a within the transmission range the opposite direction lying carrier frequency is connected, and that the output of the modulator with connected to the input of the amplifier. The high resistance of the filter input can also through a voltage divider can be implemented.

In the case of repeater stations with separate amplifiers in the sending and receiving directions, the Arrangement can also be designed so that the high-impedance input of a transmitter amplifier at the output ues Locating filter lies in parallel, the output of which is connected to a demodulator, which is connected to a modulator is coupled, which at the same time with a generator with a within the transmission range of the opposite direction lying carrier frequency is connected, and that the output of the modulator with the input of the Amplifier is connected in the receiving direction.

Another modification provides that the output of the modulator with the output of the amplifier of the Opposite direction is connected.

With these arrangements there is no risk of feedback within the amplifier loop formed, because the location add-on does not transmit any high-frequency signals.

Between the locating filter and the demodulator can be used for the purpose of amplifying the tapped Switch on the pulse voltage of an auxiliary amplifier. As an auxiliary amplifier with regard to noise, clink, adjustment etc. there are no particularly high requirements, this can also be done in an integrated circuit as long as it has at least the same reliability as the main amplifier.

An ohmic resistor can also be connected downstream of the modulator for decoupling.

The modulator consists either of an inertia-free controllable resistor, e.g. B. a field effect transistor or a bridge modulator, as it is often used in terminals for modulating the pulse carrier frequency is used.

On the basis of the diagrams according to FIGS. 1, 5 and 6, the basic circuit diagrams according to FIGS. 2a and 2b and the embodiments according to Figures 3 and 4 is the Invention explained in more detail.

As shown in FIG. 1, TF two-wire amplifiers are constructed in such a way that they transmit signals in the frequency position f \ ... h in one direction and signals in the frequency position h ■ ■ ■ U in the other direction. There are two versions, one with a transverse amplifier, as shown in FIG. 2a, or with two longitudinal amplifiers, as shown in Fig. 2b. In both amplifier designs, there is the problem of finding the fault location in the event of a disturbed amplifier path.

Fig. 3 shows in principle a TF two-wire amplifier with cross amplifier and direction switches without power supply. The following explanations can however, it can also be applied analogously to the circuit according to FIG. 2b.

The signals in the transmission range h ... U are transmitted in the direction Fi - <■ F ₂ . You get through the transmitter 9 and the high-pass filter 2 to the input a of the queue amplifier. In this they are amplified and passed on from its output b via the high-pass filter 5 and the transformer 10 to the output F ₂ . The signals in the lower transmission range f \ ... f ₂ run through the path

Terminals F ₂ - transformer 10 - low pass 3 amplifier 1 - low pass 4 - transformer 9 -
Terminals F ₂ .

The direct current path is not shown as it is assumed to be known.

The actual amplifier 1 itself is decoupled from the input and output by resistors 6, 7, 8 Locating attachment 16 connected, which is shown in more detail in FIG is drawn.

The location pulses have the shape of the Gaussian bell curve with the bandwidth 2Af (see FIG . 5c). Let the bell curve be modulated above the upper transmission band to the carrier frequency / 5 or below to the frequency h ' (see FIGS. 1 and 5a). The pulse takes the same path in the repeater as the signals of the upper transmission range, if the pass range of the high-pass filters is dimensioned accordingly.

At the output terminals 6 of the internal amplifier, a small part of the output voltage is tapped off at high resistance via the voltage divider 6, 7. In the following locating filter 11 with the pass bandwidth 2Δ and the center frequency f ₅ or / 5 ', the pulse is separated from the other signals. The auxiliary amplifier 12 increases the level of the pulse so that it can be demodulated in the rectifier circuit 13 (FIG. 5c). The resulting LF signal modulates in the modulator the frequency f _b or f _b ' originating from the generator 15 (FIGS. 1 and 5 d). The modulation results in a secondary pulse which has the same shape and effective bandwidth as the first pulse, but a different carrier frequency (FIG. 5c). The secondary pulse is fed to the input a of the amplifier 1 via the high-resistance resistor 8. The attenuation caused by the coupling is compensated for in the amplifier.

If the transmission range of the low-pass filters includes the new carrier frequency fc (Z ₆ ') ± 4 / ", the new pulse reaches the end point 20 via the amplifier path, from where the primary pulse was sent (FIG. 6).

In the last amplifier (22, 25) of a locating and thus also remote feed section, the so-called Last-fed amplifier can be used as with four-wire systems a pulse blocking filter (23, 24) can be provided, which does not affect the primary pulses in the next Locating section can get.

From the terminal of this latter Ortungsab section, the primary pulses must be sent with the carrier frequency f _b or ft . Therefore, the amplifiers of this route are to be equipped in such a way that they convert di (pulses into the frequency position f _s or / 5 '. The locating filters must therefore be dimensioned for f ₆ (£') and the oscillators for / 5 (fs').

For this purpose 4 sheets of drawing

Claims (7)

Patent claims: 1. A method for fault location in pulse TF two-wire systems by means of a full-sent from the transmitting office in ^r> transmission direction locating pulse is implemented in the Zwischenverslärkerämtern in the transmission position of the opposite direction and fed back to the sending office, characterized in that the locating pulse is transmitted above ι <> hallb or below the useful frequency band, but still within the transmission band, that the locating pulse is transmitted by the sending office emitted high-frequency bell pulse is. Which is screened out and demodulated in the respective intermediate amplifier offices, and that the de-modulated bell pulse with a suitable carrier frequency is brought into the frequency position of the opposite direction and fed back to the sending office. 2. Arrangement for performing the method according to claim 1, characterized in that at Intermediate amplifier offices with cross amplifiers (1) the output of the cross amplifier of the high impedance Input of a locating filter (11) is parallel, ^ 5 the output of which is connected to a demodulator (13) which is connected to a modulator (14) is coupled, which at the same time with a generator (15) with a within the transmission range of the Carrier frequency lying in the opposite direction is connected, and that the output of the modulator (14) with connected to the input of the amplifier. 3. Arrangement for performing the method according to claim 1, characterized in that at Intermediate amplifier offices with one amplifier each in the send and receive direction at the output of the Transmission amplifier the high-resistance input of a locating filter (11) is parallel, the output with a demodulator (131) is connected, which is coupled to a modulator (14) which is at the same time with a generator (15) with one lying within the transmission range of the opposite direction Carrier frequency is connected, and that the output of the modulator (14) to the input of the amplifier is connected in the receiving direction. 4. Arrangement for performing the method according to claim 1, characterized in that at Intermediate amplifier offices with one amplifier each in the send and receive direction at the output of the Transmission amplifier the high-resistance input of a locating filter (11) is parallel, the output with a demodulator (13) is connected, which is coupled to the modulator (14), which at the same time with a Generator with a carrier frequency lying within the transmission range of the opposite direction is connected, and that the output of the modulator with the input of the amplifier in the opposite direction downstream low pass is connected. 5. Arrangement according to one of claims 2 to 4, characterized in that the high-resistance <> »Input of the locating filter (11) with a voltage divider (6,7) is realized. 6. Arrangement according to one of claims 2 to 5, characterized in that between the location filter (U) and demodulator (13) an auxiliary amplifier (12) ^ is arranged. 7. Arrangement according to one of claims 2 to 6, characterized in that the modulator (14) an ohmic series resistor (8) downstream