DE1269671B - Arrangement for fault location of faults occurring on the line or the intermediate amplifier points in carrier frequency systems - Google Patents

Description

Arrangement for locating faults on the line or the intermediate amplifier points Occurring Errors in Carrier Frequency Systems The invention relates to an arrangement for locating faults on the line or the repeater points Errors in carrier frequency systems with remotely puffed repeaters, in which the remote feed at the same time for controlling and / or setting one to be monitored Characterizing size is used.

In modern carrier frequency systems, the repeaters are unmanned and are supplied with remote power from a manned office. If an error occurs in the transmission path on, the location of the fault is identified by means of locating devices specially provided for this purpose determined.

There are numerous fault location methods known, which can be divided into two Divide groups of different characters.

a) The facilities for fault location in the remote-fed amplifiers differ from each other in characteristic ways, e.g. B. Locating Oscillators with different, fixed predetermined frequencies, different, narrow pass frequency ranges of artificially built-in crosstalk couplings, different characteristic frequencies of Crystals in the negative feedback path of the line amplifier to short-circuit the negative feedback etc.

b) The elements for fault location are in the remotely powered amplifiers all the same. This has the advantage that the amplifier can be used as desired without any special measures can be used and interchanged.

In such a method, a bandpass filter in each remotely fed connects Amplifier the two transmission directions of a four-wire system. If you send a defined impulse from the manned office, it arrives at every amplifier station in the opposite direction and back to the starting point. Because of the different measuring loops and the resulting different running times, so many impulses come back one after the other, how filters are turned on and amplifiers are operational.

A different procedure is in each remotely powered amplifier a switchable RF oscillator is provided with a frequency that is in the transmission range the amplifier is lying. via an auxiliary line and the same Zener diodes in each amplifier the oscillators can be started up one after the other. To this end a voltage is applied to the auxiliary line in the manned office and of 0 volts increased to a maximum value. When the voltage is increased, it switches accordingly the voltage on the amplifiers one oscillator after the other on and off again. From the number of signals arriving one after the other in the manned office, a possible error location can be closed.

The two location methods mentioned cannot be used in every case will and have some disadvantages.

Artificial measuring loops are formed for the impulse location may only have a small amount of attenuation overall. There must be amplifiers in the and reverse direction of the transmission path exist as it is for a four-wire system applies with amplifiers for both directions in the same place. The filters are to be used in relation to the supervising office.

Change between two manned offices that feed remotely at the same time at the end of the remote feed line, the connection points of the filter on the amplifier.

In a four-wire system with separately housed amplifiers and two cables (four-wire submarine cable system / portable TF systems for movable cables) HF pulse location is not applicable.

When using this location method in practice, you also need in TF operations service Measuring devices that have not yet been introduced, such as pulse generators, Oscillograph or pulse receiver.

In the location process with the switchable HF generations an additional pair of wires is required in the cable.

A monitoring device is also from the German patent specification 905149 known for unmanned amplifiers in which each amplifier has a transistor generator is assigned, which is automatically switched on in the event of a broken filament of the amplifier tubes and then sends out a signal frequency that is sent to the end stations for detection of the disturbed amplifier is used.

A monitoring device is also from the German Auslegeschrift 1010111 known for a carrier frequency telephone connection in which to monitor the Tubes in the amplifier stations in question are measuring oscillators, their Frequency is discontinuously adjustable by means of a relay circuit. The carrier circle this relay circuit is located in differential circuits in the anode circuits tubes associated with various amplifiers at this station. The measuring frequency of the oscillator is similar to the above-mentioned method and Arrangements fed to a frequency indicator.

With this arrangement, however, only the tubes of the respective Repeater stations monitored.

Another principle for fault location, in which constantly or during the duration of a review of the message transmission system different from one another Monitoring frequencies are generated, the monitoring frequencies at least two sub-areas of the frequency band to be transmitted and the respective Repeater stations assigned in certain ways is off the German Auslegeschrift 1052 464 known.

This arrangement is used to check the level profile of the entire Frequency band of a communication system. Such extensive monitoring however, in many cases it is not required.

In the German explanatory document 1211276, which is to be evaluated as an older right an arrangement for indicating damage to repeaters is also described. In this arrangement, however, depending on whether at the respective amplifier point Voltages or currents are zero or not zero, relay contacts are closed, whereby then a determination of the fault location with the help of a resistance measurement along the line is enabled. At no point in this interpretative document is there a Indication given that, as with the subject of the invention, the natural voltage drop along a transmission path is exploited to a certain point the respective voltage assigned to the line for controlling the state of this relevant point to use characteristic electrical quantity. This arrangement is not only complicated in its structure, but also because of its use Numerous relays along the entire route are also very prone to failure. Also have to In this arrangement, additional pairs of lines are also provided for signaling will.

An arrangement that follows the essential principles of the foregoing is on page 23 of the »Technical reports on communications«, Vol. 19, 1960; described.

In order to avoid the disadvantages mentioned, according to the invention the different voltages due to the remote supply voltage drop on the line on the individual amplifiers for controlling or setting this electrical variable used.

The unmanned repeaters in a TF line are in almost inserted into the cable at a constant distance and supplied with remote power via its own line. The voltage from the amplifier increases according to the voltage drop on the line to amplifier by a constant amount, regardless of whether series or parallel remote feed is applied. The different voltage at the individual amplifiers in a remote feed loop can be used to set the characteristic frequency of the oscillator will.

The advantage is that the oscillators are remotely powered Amplifiers are constructed in the same way; included as a frequency-determining element she z. B. a voltage-dependent capacitance in a resonant circuit, which depends on the adjacent Voltage determines the characteristic frequency of the oscillator. About decoupling links becomes the locating signal is fed to the two amplifier inputs. From the number of im manned office incoming monitoring signals can point to a possible fault location getting closed.

The monitoring frequencies, which are permanently switched on, lie z. B. in the frequency range outside of the useful transmission range, and their level can be selected low (e.g. -15 dBm0) so that the system does not have additional is controlled. If the locating frequencies are spread over several remote feed sections repeat in their value, one sets locating blocking filter in each case in the manned office so that the detection areas do not influence each other.

The invention is illustrated with reference to FIGS. 1 to 3 explained in more detail.

F i g. Figure 1 shows a four-wire transmission system with the amplifier pairs 1 to 8 between two manned offices 9 and 10. The amplifiers 1 to 8 are from 9 and 10 from remote power supply, they are in series as consumers. The remote feed circuits can be galvanically separated in the middle (loop closed on one side, F i g. 1 a) or run through (submarine cable feed, Fig. 1 b); on the execution of the Location has no influence.

Since the amplifier pairs are all the same, there is between the TF transmission direction and the polarity of the remote power supply, in the example: at the amplifier input lies »plus«.

Each amplifier now receives an oscillator 11 with an electrical one Sensor 12 for the level of the remote feed voltage and its polarity between the two Cables. In practice, the voltage-dependent capacitance becomes a constant DC bias to which the externally supplied control voltage is added or subtracted. Accordingly, the capacity changes from an average to higher and lower values and thus the resonant circuit frequency, as shown in FIGS. 2 a, 2 b, 2 c shown. F i g. 2 a shows the dependence of the capacitance C of a controllable Capacitor from the applied voltage U ,. F i g. 2 b shows the relationship between capacitor voltage U, and oscillator frequency f. With Uo is called the rest bias. F i g. 2 c shows the monitoring frequency f the route according to FIG. 1.

The electrical voltage sensor is expediently in the low pass of the power supply switches so that the TF signal is not influenced.

In the F i g. 1 a and 1 b are the voltage ratios in the remote feed circuit shown for the two types of series supply mentioned. Addicted from the path length 1, the voltage US increases with a constant current 1 according to the homogeneous one Line resistance steadily decreases and decreases sharply at the amplifier point the voltage drop at the power supply terminals of the amplifiers.

Different voltages are applied to the individual sensors Oscillators thus give different frequencies f, to f 8 (cf.F i g. 2 c) away. In the middle of the line the polarity changes.

F i g. 3 shows the one cable of a four-wire line with the amplifiers 1 to 8 between the remote feeding offices 9 and 10. In contrast to the series feeding, the amplifiers are here parallel to the line and are fed remotely from both sides at the same time. The polarity of the remote feed voltage U does not change here along the line, as does the course of the voltage according to FIG. 3 b to the equivalent circuit diagram of the remote feed circuit according to FIG. 3a shows. The amplifiers are referred to herein as consumers Rv and the series resistances of the line as RL. With parallel remote feed from both sides, the voltage alone is not used as a controlling criterion; it is the same size at two points along the route and has the same polarity as the voltage curve of the remote feed in FIG. 3 b shows. On the other hand, the current directions differ at these points. The remote feed currents J1 and J2 each flow from the feeding office to the consumer, i.e. from the two terminals to the center. If you add an ohmic resistor Ro to each amplifier in the series circuit, practically in series with the line resistance RL, a voltage d U drops across it. B. is negative for amplifiers 1 to 4 and positive for 5 and 8, as shown in the expanded equivalent circuit diagram according to FIG. 3 c is shown. As before, with the series feed, the characteristic frequencies of the oscillators can be clearly set.

The power supply in operation of the transistor oscillators can be taken from the general remote feed in the usual way.

The described locating method can be remotely fed in every TF system Intermediate amplifiers are used, regardless of whether the amplifiers are and reverse direction can be assembled or not. All repeaters and locating oscillators are structured in the same way. As a display device in the terminal can be a usual selective receiving part of a TF measuring station can be used.

Claims (13)

Claims: 1. Arrangement for locating faults on the line or the repeater points occurring errors in carrier frequency systems with remote-fed intermediate amplifiers, in which the remote feed is also used for control and / or setting a point that characterizes the point to be monitored in each case Size is used, characterized in that because of the remote supply voltage drop on the line different voltages at the individual amplifiers for control or setting this electrical quantity are used. 2. Arrangement according to claim 1, characterized in that the remotely powered intermediate amplifiers are all the same, Contain oscillators adjustable or variable in their frequency. 3. Arrangement according to claim 1 or 2, characterized in that the output from an oscillator Frequency is determined by the level of voltage and / or its polarity. 4th Arrangement according to one of Claims 1 to 3, characterized in that the oscillator As a frequency-determining element, an oscillating circuit with a voltage and current-dependent one Includes capacity. 5. Arrangement according to one of claims 1 to 3, characterized in that that the oscillator as a frequency-determining element is a resonant circuit with a voltage and current-dependent inductance. 6. Arrangement according to one of the claims 1 to 3, characterized in that the oscillator acts as a frequency-determining element Among other things, a resistor that can be changed depending on the voltage or current (NTC thermistor) contains. 7. Arrangement according to one of claims 1 to 6, characterized in that that the voltage and current dependent element have a direct bias voltage (a bias current) for setting a rest work point. B. Arrangement with remote-fed Amplifiers, as consumers, all in parallel across the line resistances to remote supply voltage sources at the beginning or at the end of the line, according to a of claims 1 to 7, characterized in that in each remotely fed amplifier an additional resistor is in series with the line series resistor. 9. Arrangement according to one of claims 1 to 8, characterized in that the polarity of the Voltage drop across this resistor, based on the amplifier connection point, additionally controls the frequency of the oscillator. 10. Arrangement according to one of the claims 1 to 9, characterized in that the frequencies emitted by the oscillators lie in the transmission range of the amplifier, in the case of the amplifiers in the line are coupled and thus reach the monitoring office. 11. Arrangement according to one of claims 1 to 10, characterized in that in the receiving office the Identification signals are filtered out via filters and their presence or absence by means of Lamps is brought to the display. 12. Arrangement according to one of claims 1 to 11, characterized in that in the receiving office the identification signals with a heterodyne receiver are scanned and their presence or absence is indicated by lamps will. 13. The arrangement according to claim 12, characterized in that a tuning head in the superimposition receiver can only be rotated in one direction of rotation by hand or by motor, the identification signals being scanned in part of the full revolution and the indicator lamps extinguished in the remaining part and the locating process in the starting position be returned. Documents considered: German Patent No. 905149; German Auslegeschriften Nos. 1052 464, 1010 111, 1044175; Communications Fachber., 1960, pp. 20 to 24.