DE3215975C1 - Multi-channel directional ratio system - combines available channels on transmitting side in digital form in time-multiplexing framework - Google Patents

Abstract

In the directional radio system, the available channels on the transmitting side are combined in digital form in a time-multiplexing framework and the total signal so obtd. is transmitted in coded form to the receiving side. In addition, on the receiving side, the total signal is again decoded and the time-multiplexing framework divided up into the separate channels. Synchronising units are provided with the local timers of constant frequency for the synchronisation of the coding equipment and multiplexers, controlling these in accordance with code signs and framework recognition words sent from the transmitter. These units monitor the agreement between the beats from the transmitting and the receiving side and in case of disagreement carry out a fresh synchronisation process. There is a slip circuit for detecting any slip between the two lots of beats. ADVANTAGE - Improvement in suppression of intelligent interference.

Description

The invention relates to a radio relay system the available channels in digital form put together into a time-division multiplex frame and so obtained sum signal in encrypted form for Receiving side is transmitted, at the receiving end also the sum signal is decrypted and the Time-division multiplex frames divided between the individual channels and in addition to local clocks very high Constant frequency for the synchronization of the key devices and the multiplexer synchronizers are provided who are the key devices and the multiplexers in Dependence of from the sending side to the receiving side with transmitted key sync characters and frame passwords control their timing, Correspondence between the sending and receiving sides Monitor the clock and if found disturbed synchronization a re-synchronization of the Bring the reception side.

With the increasing relocation of those to be transferred Message signals in use of frequency division multiplexing multi-channel systems into those with a digital time division multiplex technology arise for one targeted disruption of such systems completely new opportunities.  While in directional radio systems working with frequency division multiplex the duration of a connection break is identical to the transmission time of a jammer people working with digital time division multiplex technology Directional radio systems result in numerous interference options, where the resulting disconnect the duration of exposure to the jammer is very considerable, can exceed a hundred thousand times. Every time if an intelligent jammer, for example, the one in one Time division multiplexed signal channel transmitted synchronization information  disturbs only for a short time, solves this each time a re-synchronization of the system, whereby at the same time because of the cycle synchronization Both directions of transmission are affected. On this way, a jammer can be extremely small Duty cycle the total blocking of a radio link to reach. Such a jammer achieved due to its small duty cycle high degree of camouflage, is therefore difficult to track down and close to destroy.

The invention is based, for such an object digital radio relay system to provide a solution which is high with relatively little technical effort Interference resistance against intelligent interferers guaranteed.

This task is on condition of use of local clock oscillators with very high frequency constancy according to the invention by the in the characterizing part of the claim 1 specified measures solved.

The invention is based on the finding that Use of local clock oscillators with very high frequency constancy there is a possibility of an interference signal from a useful signal by monitoring the slip between the signal of the local clock oscillator and to reliably recognize the incoming signal, so that depending such a detection the triggering of a resynchronization can be prevented. Also give local clock oscillators of very high frequency constancy Possibility, even with hierarchical multi-channel systems in the sum signal to be transmitted to the to omit otherwise required stuffing information and in this way a targeted disturbance to the interferer to complicate.

In this context, it is advantageous to receive  a phase comparator with an output-side phase actuator for gradual tightening of the receiving end Clock on the clock of the incoming signal to provide. The phase actuator is then over the slip circuit away according to the synchronizer also lockable.

In a further development of the invention can be transmitted Sum channel of a hierarchically structured digital Multi-channel radio system the clear information in the form a frame password for the multiplexer higher Order due to the fact that the synchronization this higher order multiplexer through a multiplexer lower order in connection with this Lower order multiplexer associated frame password is carried out. In the same way you can also the time monitoring of the synchronization of the key devices used. Configurations this training are in claims 3 and 4 specified.

Using the exemplary embodiments shown in the drawing the invention is intended to be described in more detail below are explained. In the drawing shows

Fig. 1 shows the block diagram of a radio relay system with two end points, with an additional circuit to increase the interference resistance according to the invention

Fig. 2 shows the block diagram of a further interference-resistant terminal with multiplex hierarchy

Fig. 3 of a variant of the block diagram of the terminal of a radio relay system of FIG. 2.

The two identically constructed end points of the directional radio system according to FIG. 1 are designated VS 1 and VS 2 . The transceiver of a terminal consists of the multiplexer MUX for 30 voice channels NF, the key device CR, the transceiver S / E and the switch W connecting the transmitter and the receiver to the antenna A. The transmission side becomes the official clock AT 1 the line s fed. At the receiving end, the official clock AT 1 is supplied to the protective circuit SS. The protective circuit SS has the synchronizing device SYN, the phase comparator Ph, the slip circuit SCH and the phase actuator ϕ. The reception-side office clock AT 1 is fed to the multiplexer MUX, the key device CR and the transceiver S / E via the phase actuator ϕ and the line e. The phase comparator Ph compares the official clock AT 1 on line e with the clock of the incoming signal and derives a digital control signal for the phase actuator Phasen therefrom. The control value output by the control output of the phase comparator Ph is stored in each case on the control input side of the phase actuator. The synchronization device SYN is connected on the input and output sides to the multiplexer MUX and the key device CR. On the input side, it receives the frame password from the multiplexer in the synchronized state of the transmission system. Otherwise, the synchronization device triggers a resynchronization of the terminal, whereby a key synchronization sequence (cryptosynchronization preamble) is first requested from the opposite side, to which the key device is then synchronized. The multiplexer is then switched on until the synchronization device SYN recognizes the frame password.

The official clock AT 1 or AT 2 has a frequency constancy in the order of magnitude Δf ≈10 ^-1 , so that the overall system can be regarded as isochronous. In the channel group of 30 channels NF a 64 kbit assumed in FIG. 1, a time-division multiplex sum signal of 2048 kbit results for the transmission. If the frequency of the official clock is constant in the order of magnitude specified, it will take 6 days until an entire 8-bit PCM word is omitted once with corresponding beats or is doubled once. With fast data transmission, the event is lost in the permissible error rate. In the case of non-dedicated connections, control measures within a terminal can also prevent this error.

In the exemplary embodiment according to FIG. 1, this is done by the already mentioned phase-like tightening of the office clock via the phase actuator ϕ. In this way, it is possible to always recognize a disturbance by the fact that his clock has a certain slip to the local public clock, which is done by means of the slip circuit SCH of the protective circuit SS. If the slip circuit SCH detects such a slip, it emits a blocking signal on the one hand to the synchronization device SYN and on the other hand to the phase adjusting element ϕ. This blocking signal is retained until the fault has ended and a system-specific time interval has elapsed, which takes into account the time it takes for the regenerators provided on the relay points and the end points to use their PLL circuits to regain the path clock that has been pushed away by the fault to adjust. The fault simulating a synchronization failure and causing a shift in the route clock is avoided in this way and ensures that the system continues to run in synchronism after the end of the fault. In other words, the restriction of the interference to the duration of the interference is also achieved in this way with a digital radio relay system.

As already pointed out, an intelligent one uses Interferer in a digital radio relay system From the fact that even with encryption of the transmitted Message with regard to between the Synchronization to be maintained at the end points of a route, synchronization information in the sum signal channel is to be transmitted in unencrypted form and straight the interference of this unencrypted information Possibility, with a very small duty cycle of the To disturb such a radio link permanently.

Understandably, a digital radio relay system can be better protected against such an attack the less clear information occurs in the sum signal to be transmitted. In a first-order time division multiplex system, as shown in the block diagram of FIG. 1, no clear information is transmitted, since the frame password for the multiplexer is encrypted together with the actual useful signal in the key device. It is different if the directional radio system is to transmit 120 such channels instead of 30 voice channels NF or data channels in a total time multiplex signal channel.

In this case, the terminal according to FIG. 2 requires a second multiplexer of a higher order, which is designated here with MUX 2 . At the transmitting and receiving end, such a terminal has four multiplexers MUX 11 , 12, 13 and 14 for 30 channels each, which are then encrypted together with a frame password in a key device CR 1 , CR 2 , CR 3 and CR 4 assigned to a multiplexer will. The encrypted time-division multiplex frames obtained in this way are combined in the second-order multiplexer MUX 2 to form a sum-time multiplex frame and are normally supplied to the transceiver S / E together with a sum frame password.

Each of the first order multiplexers and the associated key device is a synchronization device SYN 1 . . . SYN 4 assigned. The total time multiplex frame requires no stuffing information due to the high frequency constancy of the official clock AT and, as shown in FIG. 2, can also dispense with the transmission of a total frame password for the second-order multiplexer MUX 2 according to the invention, so that here too in the total time multiplex frame There is no clear information on the transmission link.

The protection circuit SS 'differs from the protection circuit SS according to FIG. 1 only in that only the synchronization device SYN 4 acts on the relaying of the second-order multiplexer MUX 2 . For this purpose, the associated first-order multiplexer MUX 14 is different from the frame passwords of the other first-order multiplexers MUX 11 . . . MUX 13 clearly distinguishing frame password assigned. For example, this frame password can be the inversion of the frame password used for the other first order multiplexers. When synchronization is carried out, in a first synchronization step for the key device CR 4, the synchronization is carried out in the usual way and then by means of the synchronization device SYN 4 the multiplexer second order MUX 2 is switched on until the multiplexer first order MUX 14 recognizes its synchronization device assigned frame password signals. Finally, the other key devices and the multiplexers connected to them then synchronize themselves automatically via the synchronization devices assigned to them. The signal output of the slip circuit SCH is in each case with a lock input of the synchronization device SYN 1 . . . SYN 4 and connected to the lock input of the phase control element ϕ.

Fig. 3 shows a variant of the terminal VS of Fig. 2, in which instead of the key devices provided on the part of the first order multiplexer a higher-level key device CR 'is provided, which carries out the encryption in the second multiplexer level. The multiplexers of the first order have MUX 11 for their synchronization. . . MUX 13 an integrated synchronization device, not shown, which is not influenced by the output signal of the slip circuit SCH. This simplification is possible since the multiplexers can each be synchronized very quickly and therefore there is practically no interference beyond the time of the action of an interferer if they initiate a synchronization process each time.

The maintenance of the synchronization can be carried out by the constant reception of the frame password assigned to the multiplexer MUX 14 by the synchronization device SYN 14 , so that the transmission of a cryptosynchronization preamble for the key device CR 'according to FIG. 3 or for the key devices CR 1 . . . CR 4 according to FIG. 2 can be carried out at substantially larger time intervals than would otherwise be the case.

Claims (4)

1.Radio radio system, in which the available channels are combined in digital form to form a time-division multiplex frame and the sum signal thus obtained is transmitted in encrypted form to the reception side, in which the sum signal is also decrypted on the reception side and the time-division multiplex frame is divided between the individual channels and in which In addition to local clocks of very high frequency consistency, the synchronism of the key devices and the multiplexer synchronization devices are provided, which control the key devices and the multiplexers in terms of their timing in accordance with the key synchronization signals and frame passwords transmitted from the transmission side to the reception side, the correspondence between the transmission and Monitor the clock at the receiving end and, if a faulty synchronization is found, bring about a re-synchronization of the receiving end, characterized in that a slip at the receiving end f circuit (SCH) for detecting a slip between the receiving clock (AT, AT 1 , AT 2 ) and the clock of the incoming signal is provided and that the slip circuit for the time of the presence of a slip and a subsequent system-related waiting time the synchronization device ( SYN, SYN 1 . . . SYN 4) prevents it resynchronization, the key device (CR;... CR ', CR 1 CR perform 4) optionally also to the multiplexer. 2. Directional radio system according to claim 1, characterized in that a phase comparator (Ph) on the receiving side with an output-side phase actuator (schritt) is provided for the gradual retracing of the receiving-side clock (AT, AT 1 , AT 2 ) to the clock of the incoming signal and that Phase actuator can be locked across the slip circuit (SCH) according to the synchronization device (SYN, SYN 1 ... SYN 4 ). 3. Directional radio system according to claim 1 or 2, in which according to a hierarchical order time-division multiplex frames of a given order are combined using encryption for their transmission to a sum-time multiplex frame of the next higher order, characterized in that one of the time-division multiplex frames is dispensed with without a sum-time multiplex frame associated with the sum-time multiplex frame A frame password that is clearly different from the other time-division multiplex frames is assigned, that furthermore the multiplexer (MUX 14 ) to which this time-division multiplex frame is assigned via the synchronization device (SYN 14 ) after the synchronization of the key devices (CR 11 ... CR 14 ) the multiplexer (MUX 2 ) continues to advance until it recognizes its frame password at the point indicating its synchronization and that the multiplexers assigned to the other time-division multiplex frames (MUX 11 ... MUX 13 ) subsequently connect their own sy Carry out synchronization. 4. microwave system according to one of the preceding claims, characterized in that the temporal monitoring of the synchronization of the key devices (CR, CR ', CR 1 ... CR 4 ) largely by recognizing the frame password in the multiplexer (MUX) or in one of several existing multiplexers (MUX 14 ) takes place, so that the transmission of a cryptosynchronization preamble is only required at larger time intervals.