DE1269205B - Radio link with at least three radio frequency operating channels and one backup channel - Google Patents

Description

Radio link with at least three radio frequency operating channels and a replacement channel The invention relates to a radio link with at least three radio frequency operating channels and one spare channel that goes in through Switching points connected switching sections is divided, in which on the operating channels a pilot (monitoring oscillation) is also transmitted and in the case of the switching points the receiver an intermediate or pulse frequency control voltage to derive a Switching criterion is taken to replace an operating channel in the event of a fault to switch the replacement channel within the disrupted switching section, and in the furthermore as a switching criterion apart from the failure of the control voltage there are still some exceeding a predetermined value, from one above that occupied by signals Partial frequency range lying pilot voltage obtained noise voltage is used.

Such a radio relay system is through the literature reference »Bell System Technical Journal, May 1955, pp 473-510. With this system will be both the noise voltage in a sub-frequency range not covered by signals as well as the carrier frequency of the baseband in the above sense monitored by both be rectified and fed to a multivibrator, which is present in the presence of one of the two faults or both switches and switching operations at the same time initiates such. B. switching to a substitute channel. The occurrence of increased Route noise, as it is e.g. B. is often found in scatter connections, and a total failure of the carrier frequency, e.g. B. in the event of a transmission failure, will be rated the same in this system, which is particularly disadvantageous because in this system, during each switchover, all those following the point of failure are blocked Replacement channels occurs. In the event of a channel failure in this system, the following Steps taken: At all switching points following the disturbed section of the route the channel identifier is transmitted backwards on the additional signal line. then the substitute channel becomes parallel to the disturbed channel at all switching points mentioned Operating channel switched and an otherwise also transmitted pilot (8.5 MHz) from the substitute channel removed. Finally, at the switching point, the disturbed section of the route immediately follows, through the channel carrier appearing on the replacement channel, the connection established between the replacement channel and the operating channel. Then one after the other all subsequent switching points undo the first two processes mentioned can be made, which of course results in a considerable loss of time. The invention The object is to improve such a system so that in particular the above-mentioned disadvantages can be avoided.

In the case of a radio relay system, this task is mentioned in the introduction Type solved according to the invention in that the first-mentioned switching criterion opposite priority is given to the latter, so that if there is a disturbance at the same time a first channel due to failure of the control voltage and a second channel due to increased noise voltage, the substitute channel is switched to the place of the first channel is, in such a way that if the control voltage of a channel fails to all of the disrupted switching section following switching sections an unmodulated intermediate or pulse-frequency voltage, generated in a substitute generator assigned to each channel, is applied and, as is known per se, a characterizing the disturbed channel Signal (identification signal) via an additional connection between the switching points the switching point preceding the faulty switching section is transmitted, the there initiates the connection of a pilot tone to the substitute channel, which in turn on the switching point following the faulty switching section, the connection between the substitute channel and the operating channel of the following section under Shutdown of the substitute generator applied to it, and that it is impermissible if it occurs high noise in a channel on all of the following the disturbed switching section Switching points a blocking of the switching is initiated, as well as the identification signal is sent backwards, only in the one preceding the disturbed switching section Switching point switches the pilot frequency to the backup channel that in the switching point following the faulty switching section a comparison of the Causes noise voltages in the replacement channel and in the disturbed operating channel.

Compared to the system mentioned in the introduction, the invention A distinction is made between noise loss and channel loss, and also in the event of signal loss by applying a replacement generator to the service channel of the disturbed route section prevents a blockage of the replacement channels of further sections after the fault location, while in the event of unacceptably high noise a blocking for the same purpose the switchover is initiated. Finally, with the invention in each case by the pilot tone switched to the replacement channel of the disturbed route section initiates the final switchover to the substitute channel. This saves compared to the system mentioned above, the use of a further signal channel in the reverse direction between the switching points.

Further advantageous refinements of the subject matter of the invention result through the following measures.

In the directional radio link according to the invention, the operating channels an adjustable, graduated priority assigned in such a way that at the same time existing failure of the control voltage and possibly also at the same time Existing increased noise voltage in several operating channels of the substitute channel is switched to the place of the respective preferred channel.

The operating channels in both transmission directions are on the Sending and receiving side of each switching section assigned switching devices, through which they are connected in the undisturbed state, while the backup channel is separated between the switching sections, with the first in the event of a fault Switching device on the transmitting side connects the replacement channel to the disturbed operating channel and then the receiving-side switching device to the following switching section disconnects the leading line from the service channel and connects it to the backup channel, and on the transmission side of each switching section there is a substitute generator on each channel can be switched on, which emits an unmodulated intermediate or pulse-frequency voltage, whereby in the undisturbed state only the substitute generator assigned to the substitute channel is turned on.

All channels on the receiving side of each switching section are Display means assigned to the failure of the control voltage and increased Address noise voltage, and the replacement channel is also an indicator for assigned to the pilot.

The appropriate display means report one at each switching point Operating channel, the malfunction of a selection circuit, which occurs at the same time Disruptions in the same switching section a check of priority according to Art who disrupts and classifies the operating channel.

If the control voltage fails in an operating channel, the Selection circuit on the switching point following the fault location for this channel assigned replacement generator to the next undisturbed switching section and transmits a signal identifying this channel (identification signal), for example a special signal channel to a switching control of the preceding switching point, which switches off the substitute generator assigned to the substitute channel and switches it on Switching signal to the transmitting-side switching device assigned to the disturbed channel releases, whereupon the following via the substitute channel to the first named, the fault location Switching point running pilot via the display means assigned to him and the selection circuit on the substitute generator assigned to the disturbed channel from the next switching section turns off again and this by sending a switching signal to the assigned connects the receiving-side switching device with the replacement channel. In this case of malfunction the disturbed channel section is immediately clearly marked and the switchover not initiated at all on the replacement channel on the following undisturbed switching sections. This also applies if there are two operating channels in the same switching section fail; the disadvantaged, unbridged operating channel can be on the following Do not block switching sections of the replacement channel.

In the event of increased noise voltage in an operating channel, the selection circuits give on the switching points following the fault location, first a blocking signal is sent to a switchover control the same switching point that the relay assigned to the disturbed channel there blocks, and then a signal identifying the disturbed channel (identification signal), for example via a special signal channel to a switching control of the preceding switching point sends, and the switching control that sends an identification signal, but not a blocking signal receives, switches off the substitute generator assigned to the substitute channel and outputs a switching signal to the transmitting-side switching device assigned to the disturbed channel and the pilot running to the next switching point via the substitute channel caused by the display means assigned to it and the selection circuit in one Noise comparison circuit a comparison of the noise voltages in the disturbed operating channel and in the substitute channel, and the noise comparison circuit only then gives a trigger signal to the selection circuit when the noise voltage in the substitute channel by a predetermined Dimension is smaller than the noise voltage in the disturbed operating channel, whereupon the selection circuit a switching signal to the receiving-side switching device assigned to the disturbed channel gives away.

A polarized differential relay is used to compare the noise voltages used.

If there are malfunctions in two operating channels of the same Switching section blocks the selection circuit at the end of this switching section the identification signal assigned to the disadvantaged channel and the switching signal assigned to it for the switching device on the receiving side.

When a display means assigned to the replacement channel is addressed for the missing control voltage or for increased noise voltage all work Relay in the selection circuit in rest position.

In the case of switching devices on the sending and receiving sides, the substitute channel is in the idle state via series-connected, assigned to the individual operating channels mechanical changeover switch connected to its terminating resistor.

In the case of the switching device on the transmission side, there is between the service channel line and the mechanical switch a grid-controlled electron tube, the is locked in the idle state and in the event of a fault, the assigned mechanical switch is unlocked, so that the replacement channel to the the disturbed operating channel is switched on.

The switching device on the receiving side is in the line of the Operating channel a first grid-controlled electron tube and between the mechanical Switch and the output of the first tube a second grid-controlled electron tube, wherein in the idle state the first tube is unlocked and the second tube is locked and in the event of a fault with the assigned mechanical changeover switch that is actuated at the same time the first tube is locked and the second tube is unlocked, so that the next Switching section leading line disconnected from the service channel and to the replacement channel is switched on. A magnetically controlled switch is used as the mechanical switch Inert gas switchover contact, which is preferably connected to a Coaxial line is added.

The invention is based on the embodiment shown in the drawings explained in more detail. The drawings show in FIG. 1 in a schematic representation part of a radio link with two switching points, F i g. 2 a simplified one Block diagram of a switching point with the devices according to the invention, F i g. 3 is a block diagram of the control receiver and noise indicator and the noise comparison circuit, F i g. 4 Details of the switching devices on the sending and receiving sides.

The exemplary embodiment is based on a radio link with four radio frequency (RF) channels, three of which are intended to serve as operating channels and the fourth as a backup channel. In Fig. 1, the three operating channels are labeled I, 1I, III and the replacement channel is labeled IV. The entire radio link between the terminals is divided into switching sections that are connected to one another by switching points. In Fig. 1, two switching points SS1 and SS2 are drawn, the switching point SS 1 connecting the switching sections SA 1 and SA 2 and the switching point SS2 connecting the switching sections SA 2 and SA 3 to one another. A switching section can extend over several radio fields.

For example, 600 calls or a television program can be carried over one RF channel Be transmitted. The 600 low frequency bands are on the terminals after the Frequency division multiplexing so that z. B. a baseband of 60 to 2540 kHz arises; in television, the baseband ranges from 0.01 to 5000 kHz. In addition, a pilot (monitoring oscillation) is added to each channel, its frequency z. B. 8.5 MHz. A carrier is frequency-modulated with the baseband, whereupon this band is shifted from the intermediate frequency to the radio frequency position. The intermediate frequency is around 70 MHz, the radio frequency around 4 GHz. On switching and Relay points are generally switched through the channels in the IF position.

In Fig. 1 shows only one transmission path of the radio link; the second transmission path for the opposite direction is structured in the same way. The four RF bands are each broadcast and received via a single antenna. At each switching point, the four received RF bands are divided into the four channels in a switch W and then reduced to the IF position in four reception converters ME. This is followed by the receiving and transmitting switching arrangements NE and NS; containing the devices according to the invention. The four bands are converted back into the radio-frequency position in four transmission converters MS , whereupon they are combined in the switch W and broadcast via the antenna. A special signal channel (from e1 to f 1) is also provided between adjacent switching points, the direction of which is opposite to that of the RF channels; it can be a wired or wireless connection for the transmission of low-frequency signals.

A simplified block diagram of the reception and transmission-side switchover arrangements NE and NS of a switching point is shown in FIG. 2. Each of the three operating channels I, 1I and III is assigned a receiving and a transmitting-side switching device UEI and USI, UEII and USII, UEIII and USIII. These switching devices are shown in simplified form as electromagnetic relays with mechanical contacts; However, given the high frequency of the powers to be switched and the short switching times, electronic switches are used in combination with mechanical, in particular coaxial switches, as shown in FIG. 4 shows.

In the undisturbed state, the operating channels on the switching points are connected through the assigned switching devices, while the replacement channel is disconnected. A substitute generator (EG 1 to EG 4) can be connected to each channel at the beginning of its switching section, which in the exemplary embodiment emits an unmodulated 70 MHz oscillation (intermediate frequency). In the undisturbed state, only the substitute generator EG4 assigned to the substitute channel is switched on.

A control receiver (KE 1 to KE 4) and a sound indicator (GA 1 to GA 4) are provided for each channel on the switching points. In the exemplary embodiment, the four control receivers are connected with high resistance to the section ends of the three operating channels and the substitute channel upstream of the switching devices on the receiving end; the inputs of the sound indicators are parallel to the inputs of the assigned control receiver. The arrows drawn on the connecting lines of two devices in FIG. 2 indicate that the device from which the arrow emanates controls the other device. The failure of the control voltage is reported by the control receiver, an increased noise voltage is reported by the noise indicator to a selection circuit AU, which, if there is interference at the same time, carries out a test according to the type of interference and classification of the operating channel. The selection circuit sends a signal identifying the disturbed channel (identification signal) via the signal channel e1 to f 1 to the switchover control of the preceding switching point. A noise comparison circuit GV is connected to the selection circuit. The switching devices USI to USIII on the transmission side are controlled by the switchover control UM, and the switching devices UEI to UE III on the receiving side are controlled by the selection circuit AU. F i g. 3 shows the basic structure of the mutually identical control receivers and sound indicators. At the input of the control receiver KE1 for channel I, the frequency-modulated intermediate frequency oscillation is rectified by the rectifier G13 ; the directional current amplified in the DC amplifier V 3 is sent to the indicator relay KA. I fed. (The display relays KA 1I, KA III and KA IV are correspondingly assigned to channels 1I, III and IV.) In the exemplary embodiment, the 8.5 MHz pilot oscillation is used to assess the noise voltage. At the input of the noise indicator GA 1 for channel I there is a discriminator D, at the output of which the pilot oscillation is filtered out and amplified with the aid of a selective amplifier V 1. The pilot oscillation is rectified by the rectifier Gll, but the directional current is only evaluated by the indicator relay PA IV in connection with the noise indicator GA 4, which is assigned to the substitute channel. (The pilot running over the substitute channel in the event of a fault is used to transmit the switching status at the beginning of the switching section.) The rectifier Gl1 also acts as a demodulator for the amplitude modulation impressed on the 8.5 MHz pilot oscillation, by means of which, in the exemplary embodiment, a service call and alternating current signals in Frequency range from 0.2 to 3 kHz can be transmitted. The frequency band from 4 to 10 kHz is therefore used to assess the noise level. The noise voltage to be evaluated is filtered out by the filter F with the pass band 4 to 10 kHz, amplified in the amplifier V 2 and finally rectified with the aid of the rectifier Gig; the directional current feeds the indicator relay RA I (output gl) via an adjustable resistor W. The response threshold of the relay can be set with the aid of the resistor W. (Correspondingly, the display relays RA II, RA. HI and RA IV are assigned to channels 1I, III and IV.) The rectifier circuit has a second output g21 or g22 to g24 for the other channels, which leads to the noise comparison circuit GV.

The sequence of the individual switching processes can be seen from the following description of five different fault cases. The relays in the selection circuit AU and in the switchover control UM are not shown in the figures. Interruption of the control voltage on the switching points SS 3, SS 4 etc. is only about 2 milliseconds; this short time is not sufficient to stimulate a switchover; only the backup generators can be switched on for a very short time.

In addition, in the selection circuit AU, a relay KWI responds via a priority circuit (see case t), which triggers a signal (identification signal) identifying the disturbed operating channel I. For example, alternating currents in the audio frequency range with frequencies f 1, f 2 and f 3, which a signal generator generates in the selection circuit, are selected as the identification signal for the three operating channels. In the present case, the relay KW I causes the signal generator to send out an identification signal with the frequency f 1 via slave relays, which signal runs via the signal channel e 1 to f 1 to the switchover control UM of the preceding switching point SS1.

In the switchover control UM of the switching point SS1, the incoming identification signal with the frequency f 1 causes the relay KEIV to respond via a sequence relay, whose contact keIV separates the substitute generator EG 4 from the substitute channel IV. A switching signal is then triggered to the switching device USI on the transmission side, which connects the substitute channel with the disturbed operating channel I.

The completed switchover at the switching point SS1 on the transmission side is now confirmed to the switching point SS2. For this purpose, the pilot running over the substitute channel is used, who energizes the polarized relay PA IV in the noise indicator GA 4 of the switching point SS2; its armature paIV applies earth to the line leading via p to the selection circuit AU. This causes the KEI relay to drop out via the sequential relay in the selection circuit, which disconnects the backup generator EG 1 from channel I. The selection circuit then sends a switching signal to the receiving-side switching device UEI, which interrupts the disturbed operating channel 1 on the receiving side of the switching section SA 2 and connects the substitute channel IV with the operating channel I on the transmitting side of the following switching section SA 3. The disturbed operating channel I in the switching section SA 2 is thus bridged by the replacement channel.

If the fault in the operating channel I in the switching section SA 2 has been eliminated, the recurring control voltage on the switching point SS2 via the KA I relay causes the receiving-side switching device UEI to go to rest. At the same time, the selection circuit switches off the identification signal, whereupon the switching device USI at the switching point SS1 also goes into the rest position; in addition, the substitute generator EG 4 is switched back on to the substitute channel there.

Case 2: Failure of the control voltage in operating channel I continues, in the same switching section SA 2 the control voltage fails in the preferred operating channel 11 Case 1: Control voltage fails in operating channel I It is assumed that the message signal fails in switching section SA 2 in operating channel I. As a result, the control voltage on switching point SS2 and initially also on all subsequent switching points SS 3, SS 4, etc. fails. In the control receivers KE1 of these switching points, the polarized relay KA 1 responds, whose armature kaI puts earth to the line leading via ml to the selection circuit AU.

In the selection circuit of the switching point SS2, the relay KEI is energized, the contact keI of which applies the substitute generator EG1 to the input of the undisturbed switching section SA 3 of channel I. As a result, the control voltage, which in the exemplary embodiment represents an unmodulated 70 MHz oscillation, is present again at the switching points SS3, SS4, etc., and the relays KAI are in the rest position. The switching status in operating channel I: The relays KA I, KW I, PAIV and the switching devices US I, GEI have responded; the identification signal (f 1) continues; the disturbed operating channel I is bridged in the switching section SA 2 by the substitute channel IV.

If the control voltage fails in the operating channel TI, the relay KA 11 in the control receiver KE2 responds, whereby the relay KEII is energized in the selection circuit AU, which applies the backup generator EG2 to the undisturbed switching section SA 3 of channel 1I. (The relays assigned to channel 1I are not shown in the figures.) The priority circuit in the selection circuit works in connection with the relay KWII as follows: In series with the relay winding assigned to the channel in question, there are two break contacts of the relays of the same name assigned to the other channels, the can be bridged by switches. The break contacts of the disadvantaged relays (e.g. channel I) are bridged by switches in the circuit of the relay assigned to the preferred channel (e.g. channel 1I). In the present case, the KWII relay can respond. This causes the identification signal (f 2) and the KWI relay to drop out, which means that the receiving-side switching device UEI and then, by switching off the identification signal (f 1), the transmitting-side switching device USI also go to rest. The replacement channel from the disadvantaged channel I is thus switched off, so that the switchover to channel II, which has already been prepared by the identification signal (f 2), can now take place. This is followed by: Switching from USII to switching point SS 1, confirmation with the aid of the pilot running over the substitute channel to switching point SS2 and switching from UEII. The replacement channel IV is thus switched in place of the preferred channel II in the switching section SA 2.

Case 3: Increased noise voltage in operating channel I It is assumed that a disturbance occurs in switching section SA 2 in operating channel I which causes a noise voltage that exceeds the normal value. The fault is displayed on switching point SS2 and on all subsequent switching points SS3, SS4, etc. in the noise indicator GA 1 and reported to the selection circuit AU. This is done in that when a noise voltage in the noise indicator exceeds a predetermined value, the polarized relay RA I responds, the armature ra I of which applies earth to the line leading to the selection circuit via n 1.

The following should be noted for the setting of the RA relay: Since the noise power components of the individual radio fields add up, the permissible noise voltage increases from switching point to switching point in the course of the radio link. The response voltages of the indicator relay RA in the noise indicators are appropriately staggered so that the response voltage from switching point to switching point is higher by the noise voltage increase AU of the switching section in between. It is also expedient to set the response voltage of relay RA IV for the substitute channel higher by the noise voltage increase AU of the associated switching section than the mutually identical response voltages of relays RA I to RA III of the operating channels on one and the same switching point. This has the following reason: Is z. B. in operating channel I the noise voltage on the transmission side of a switching section just below the response threshold, but just above the response threshold on the reception side, the RA 1 relay responds and causes channel I and the substitute channel to be interconnected on the transmission side. A small increase in noise voltage in the substitute channel would now also trigger the RA IV relay with the same response threshold. This must be avoided, however, because excitation of the RA IV relay means a fault in the substitute channel and - as described in detail in case 5 - all switching operations are reversed.

In the selection circuits of the switching points SS2, SS3, SS4, etc., a relay RB I responds via the aforementioned raI contact. (In the present case, for the sake of simplicity, the channels have no staggered priority in the event of interference due to increased noise voltage.) The RBI relay causes a blocking signal to the switchover control UM at the same switching point, which blocks the relays assigned to channel I there.

In addition, the RB I relay triggers an identification signal with the frequency f 1 via an RW I relay, which runs via the signal channel e1 to f 1 to the switchover control UM of the preceding switching point. The identification signal therefore runs between the following switching points: from SS2 to SS1, from SS3 to SS2, from SS 4 to SS 3 , etc.

Only in the switchover control of switching point SS1 that does not have a locking signal receives, the incoming identification signal (f 1) causes the relay KEIV to respond, the separates the substitute generator EG4 from the substitute channel IV. A switching signal is thereupon triggered to the USI switching device on the transmitter side.

The completed switchover on the transmission side is confirmed to the switching point SS2 by the pilot running over the substitute channel, who there energizes the relay PA IV in the noise indicator GA 4. As a result, a RUI relay is energized in the selection circuit AU via a slave relay, which causes a comparison of the noise voltages in the operating channel I and in the substitute channel IV, which are already connected on the transmission side via USI.

The polarized differential relay RV in the noise comparison circuit GV is used to compare the noise voltages. One winding of the differential relay RV is permanently connected to the output g24 of the noise indicator GA 4 of the substitute channel, the opposite winding is connected to the output g21 or g22 or g23 of the noise indicator of an operating channel through the contact of the assigned RU relay. In the present case, the output of the noise indicator GA 1 is connected to the reverse winding of the RV relay via the ru I2 contact. The RV relay only responds if the noise voltage in the operating channel exceeds the noise voltage in the substitute channel by a predetermined amount. This ensures that the source of the error is clearly in the disturbed operating channel. The RV relay actuates the receiving-side switching device UEI via a slave relay. The operating channel I is thus switched off in the switching section SA 2 and replaced by the replacement channel IV.

Case 4: Increased noise voltage in operating channel I persists, in the same switching section SA 2 the control voltage in operating channel 1I drops out Switching state in operating channel I: The relays RA I, RB I, RWI, RUI, RV and the switching devices USI, UEI have responded; Identification signal (f 1) and blocking signal continue; the disturbed operating channel I is switched to the substitute channel IV in the switching section SA 2. In the following, the switching processes are only considered within the disrupted switching section SA 2 .

If the control voltage in operating channel II fails, the KEII relay is activated via the KA II relay in the AU selection circuit, which connects the backup generator EG2 to the undisturbed switching section SA 3 of channel II. In addition, the KWII relay and an H relay are energized. The prerequisite for the H relay to respond is that one channel is disturbed by failure of the control voltage and a second channel by increased noise voltage. The H relay causes the RWI relay to drop out, whereby the identification signal (f 1) for channel I is switched off and the receiving and transmitting-side switching devices UEI and USI and the relays RUI and RV that effect the comparison of the noise voltages go into rest position. The substitute channel is then switched off from channel I, so that the switchover to channel II, which is preferred in this case, can now take place, which has already been prepared by the identification signal (f 2).

Case 5: Fault in the substitute channel IV If the control voltage fails in the substitute channel IV, the KA IV relay in the control receiver KE4 of the corresponding switching section - the substitute channel is not connected to the switching points in the normal switching state - is activated. In the case of increased noise voltage in the substitute channel, the RA IV relay in the GA 4 noise indicator responds. In both cases, all the relays of the selection circuit are disconnected from their power source so that they go into the rest position shown if they are not already in this position. As a result, the switching devices US and UE on the transmitting and receiving sides also go into the rest position, or they cannot be operated in the event of faults.

Details of the receiving and transmitting side switching devices shows F i g. 4. Only the devices UEI and assigned to the operating channel I are USI because the switching devices for the other operating channels II and III are structured accordingly. It will be a combination of electronic and mechanical switches are used, with which the high Let requirements meet the reflection factor and the crosstalk attenuation between the channels. For a better overview, FIG. 4 the Operating voltage sources for the tubes and relays omitted.

In the idle state, ie when there is no interference, the replacement channel IV is on its receiving and transmitting side via the mechanical switches beI, be 1I, be HI or bs I, bs II, bs III with the terminating resistors R 1 and R 2 tied together. A magnetically controlled inert gas changeover contact is used as the mechanical changeover switch, which is preferably supplemented by means of an outer jacket to form a coaxial line. The contact springs, which are made of magnetic material, are melted into a gas-filled tube. The controlling solenoids are shown in FIG. 4 labeled BEI or BSI. The receiving-side switching device UEI contains a first grid-controlled electron tube V 4 in the line of the operating channel and a second grid-controlled electron tube V5 between the mechanical switch at I and the output of the tube V 4, the first tube being unlocked and the second tube locked in the idle state. In the case of the switching device USI on the transmission side, a grid-controlled electron tube V6, which is blocked in the idle state, is located between the continuous service channel line and the mechanical switch bsI.

In the event of a fault in operating channel I, the switching device USI on the transmitting side is first actuated by the switching control UM of the switching point located in front of the fault location emitting a switching signal to the relay ASI. The mechanical changeover switch BSI responds via the contact asIl, and the tube V6 is opened via the contact asI = by removing the blocking high grid voltage (-GV). The switching section inputs of operating channel I and substitute channel IV are thus connected in parallel.

After the switching operations in the transmitting-side switching device USI have ended, the receiving-side switching device UEI is actuated at the switching point following the fault location. In this case, the selection circuit AU emits a switching signal to the relay AEI, whereupon the mechanical changeover switch BEI responds via the contact ae II. With the help of the changeover contact ae I- ', the tube V 4 is blocked by applying a high grid bias voltage and the tube V 5 is unblocked by removing the high grid bias voltage. As a result, the operating channel I is interrupted and the line leading to the following switching section is connected to the replacement channel IV.

In the simple representation of FIG. 4 are as grid controlled Electron tubes shown triodes; however, pentodes are particularly advantageous used with great steepness and small grid base.

Claims (7)

Claims: I. Radio link with at least three radio frequency operating channels and a substitute channel, which is divided into switching sections connected by switching points in which a pilot (monitoring vibration) is also transmitted on the operating channels and with the receiver on the switching points an intermediate or pulse frequency Control voltage to derive a switching criterion is taken to in the event of a fault an operating channel in its place the substitute channel within the disrupted switching section to switch, and also as a switching criterion in addition to the failure of the control voltage nor the one exceeding a predetermined value, from one above that of signals occupied partial frequency range lying pilot voltage obtained noise voltage serves, characterized in that the first-mentioned switching criterion compared to the the second mentioned is given priority, so that if there is a disturbance at the same time, one first channel through failure of the control voltage and a second channel through increased noise voltage of the substitute channel switched in place of the first channel will, in such a way that if the Control voltage of a channel an unmodulated one to all the switching sections following the faulty switching section intermediate or pulse frequency voltage generated in each channel assigned Replacement generator, is applied and, as is known per se, a disturbed channel identifying signal (identification signal), via an additional connection between the Switching points of the switching point preceding the faulty switching section transmitted is that causes the connection of a pilot tone to the replacement channel there, the in turn, the connection on the switching point following the faulty switching section between the substitute channel and the operating channel of the following section under disconnection of the substitute generator applied to it, and that it is impermissible when it occurs high noise in a channel on all of the following the disturbed switching section Switching points a blocking of the switching is initiated, as well as the identification signal is sent backwards, only in the one preceding the disturbed switching section Switching point switches the pilot frequency on to the substitute channel that is in the disturbed Switching section following switching point a comparison of the noise voltages in the substitute channel and initiated in the disturbed operating channel. 2. directional radio link according to claim 1, characterized in that if the control voltage fails at the same time an adjustable, graduated priority in several operating channels is assigned, so that the replacement channel takes the place of the preferred Channel is switched. 3. Directional radio link according to claim 1 or 2, characterized in that that at the same time there is increased noise voltage in several operating channels these are assigned an adjustable, graduated priority so that the Replacement channel is switched to the place of the respective preferred channel. 4. Directional radio link according to one of the preceding claims, characterized in that the operating channels in both transmission directions on the transmitting and receiving side of each switching section switching devices USI,. . . and UEI,. . . Associated) via which they are connected in the undisturbed state, during the standby channel is split between the switching sections, turns on in case of failure first, the transmission side switching means (USI ....) the protection channel of the faulty working channel and then the receiving-side switching means ( UEI,...) Disconnects the line leading to the following switching section from the operating channel and connects it to the substitute channel, and that a substitute generator (EG1 ....) can be connected to each channel on the transmission side of each switching section, which generates an unmodulated intermediate or pulse frequency Supplies voltage, whereby in the undisturbed state only the substitute generator (EG 4) assigned to the substitute channel is switched on. 5. Directional radio link according to claim 4, characterized in that all channels on the receiving side of each switching section are assigned display means which respond in the event of failure of the control voltage (relay KA I .... ) and in the event of increased noise voltage (relay RA I,...) and that the replacement channel is also assigned a display means for the pilot (relay PA IV). 6. Directional radio link according to claim 5, characterized in that the responsive display means of an operating channel (relay KA I,... And RA I, ...) Report the malfunction of a selection circuit (AU) at the same time, when there are malfunctions in the same switching section carries out a check of priority according to the type of disturbance and classification of the operating channel. 7. Directional radio link according to claim 6, characterized in that in the event of failure of the control voltage in an operating channel, the selection circuit (AU) on the switching point following the fault location sets the replacement generator (EG 1,...) Assigned to this channel to the next undisturbed switching section and a Signal identifying this channel (identification signal), for example via a special signal channel, to a switching control (UM) of the preceding switching point, which switches off the substitute generator (EG4) assigned to the substitute channel and sends a switching signal to the transmitting-side switching device (USI,. ..) whereupon the pilot running over the substitute channel to the first-mentioned switching point following the fault location uses the display means assigned to him (relay PA IV) and the selection circuit (AU) to transfer the substitute generator (EG 1,...) assigned to the disturbed channel from the next switching section switches off again and this en connects to the substitute channel by sending a switching signal to the assigned receiving-side switching device (UEI ....). B. radio link according to claim 6, characterized in that with increased noise voltage in an operating channel, the selection circuits (AU) on the switching points following the fault location first emit a blocking signal to a switching control (UM) of the same switching point, which there blocks the relay assigned to the disturbed channel , and then a signal identifying the disturbed channel (identification signal), for example via a special signal channel, to a switchover control (UM) of the preceding switching point, so that the switchover control (UM) which receives an identification signal but no blocking signal, the substitute generator assigned to the substitute channel ( EC 4) off from this, and a switching signal to the write. the disturbed channel associated transmitting-side switching means (USI,..), that the current through the spare channel to the next switching point pilot on its associated display means (relay PAIV) and the selection circuit (AU ) in a noise comparison scarf device (GV) causes a comparison of the noise voltages in the disturbed operating channel and in the substitute channel and that the noise comparison circuit only sends a trigger signal to the selection circuit if the noise voltage in the substitute channel is a predetermined amount less than the noise voltage in the disturbed operating channel, whereupon the selection circuit switches on Switching signal to the receiving-side switching device (UEI,. . .) gives away. 9. Directional radio link according to claim 9, characterized in that a polarized differential relay is used to compare the noise voltage. 10. microwave link according to one of the preceding claims, characterized in that at the same time the presence of noise in two operating channels of the same switching section selecting circuit (AU) at the end of switching portion that is associated with the vulnerable channel identification signal and its associated switching signal for the receiving-side switching means (UEI,. ..) locks. 11. Directional radio link according to one of the preceding claims, characterized in that when a display means assigned to the substitute channel for the missing control voltage or for increased noise voltage (relay KA IV or RA IV) responds, all relays in the selection circuit (AU) go into the rest position. 12. Directional radio link according to claim 4, characterized in that in the case of switching devices (USI, ... and UEI, ...) on the sending and receiving side, the replacement channel in the idle state is connected to its terminating resistor via mechanical changeover switches assigned to the individual operating channels in series . 13. Directional radio link according to claim 12, characterized in that in the transmission-side switching device (USI, ...) Between the operating channel line and the mechanical switch there is a grid-controlled electron tube which is locked in the idle state and which in the event of a fault with the simultaneously actuated, associated mechanical Changeover switch is unlocked so that the replacement channel is connected to the disturbed operating channel. 14. Directional radio link according to claim 12, characterized in that in the receiving-side switching device (UEI, ... ) in the power train of the operating channel, a first grid-controlled electron tube and between the mechanical switch and the output of the first tube is a second grid-controlled electron tube, in the idle state the first tube is unlocked and the second tube is locked and, in the event of a malfunction, the first tube is locked and the second tube is unlocked with the simultaneously actuated associated mechanical switch, so that the line leading to the following switching section is switched off from the operating channel and connected to the replacement channel. 15. Directional radio link according to claim 12, characterized in that a magnetically controlled inert gas switchover contact is used as the mechanical switch, which is preferably supplemented by means of an outer jacket to form a coaxial line. Publications considered: Zeitschrift "FTZ", 1952, issue 10, p. 460; "Telefunken-Zeitung" magazine, June 1957, pp. 100 to 118; The Bell System Technical Journal, May 1955, pp. 473-510.