DE2738466C1 - Radio system for digital information transmission - Google Patents

Abstract

The radio system has digital information transmitted in both directions between a pair of radio stations via a radio link. This is switched between different radio frequencies within a wide frequency range, at defined time points. The call signal transmitted from the calling station to the called station contains synchronisation information, with the successive information bursts transmitted in the time raster of the frequency switching, the information content being repeated. The receiver of the reception station is switched to a call radio frequency, for reception of additional information during the next information burst, dependent on correct or incorrect reception of the information burst.

Description

The invention relates to a radio system for interference-resistant mutual digital information transfer between at least two stations where the radio link is too jump at least during the transmission of information as a predetermined frequency in a larger frequency richly changing radio frequency is operated and at the Establishment of the radio connection from the calling station on one the radio frequency intended for one call the other sta tion by means of a synchronization information Call signal is called.

Such a radio system is specified in the main patent, in which that when using a fast frequency hopping method for troop radio and / or dialing radio by the specified be limited number of radio frequencies occurring self-interference be reduced by the fact that in the time grid of the radio frequency alternating successive information bursts visually broadcast their news content repeatedly and in several, each provided with a fail-safe formation sections are divided. The repetition of the transmitted bursts of information regarding their message content is useful for several reasons. With disturbance ten bursts are to be expected if, on the one hand, during use of frequency hopping in tactical use on a  higher-level synchronization of neighboring radio circuits se must be waived, or on the other hand Schwunderschei due to frequency hopping or driving operation in the interference field cannot be neglected nen.

Military dial-up networks of this type are often used made the request that a station be occupied can submit an active busy signal, or a priority enforcement must be possible, d. H. that an occupied Recognize a station receiving a second call and acknowledge must be able to. For this it is necessary that by increasing the radio bit rate between those transmitted in time division duplex Additional information bursts for this auxiliary information Time slots are to be stored in which the second call detection and acknowledgment can be processed. At fast frequency jump systems, this method is very disadvantageous, because already relatively high Ver pleasure times have to be accepted.

The invention has for its object a radio system the main patent to further develop that the example wise for the processing of a second call detection and acknowledgment required time slots without increasing the radio bit rate are realizable.

This object is achieved in that the Receiver of a station occupied by Er for a transmission know of an error-free or error-free arriving Information bursts in the time domain of at least one other incoming information bursts same message content for the receipt of additional information, for example one Second call on one of the radio frequencies intended for call, is unlocked.

The invention is based on the finding that in the like repeated transmission of information-like messages content with a relatively high probability already  first transmission is good enough so that eavesdropping another burst of information with the same news content can be dispensed with. In the time gained by this the second call treatment carried out much faster and more safely are carried out without the radio bit rate to obtain additional Licher time slots must be increased. The interference resistance of the Systems and thus the security of the transmission is there not affected by. Only when the radio is severely disturbed There may be longer waiting times for the second person call detection can be accepted.

Using an exemplary embodiment for a send / receive station, the invention is explained in more detail below will. Mean in the drawing

Fig. 1 is a block diagram of a transceiver station of a radio system according to the invention,

Fig. 2 is a more detailed block diagram exhibiting a compressor in a transmitting-receiving station according to Fig. 1,

Fig. 3 is a more detailed block diagram of an expander exhibiting a transmitting-receiving station of FIG. 1.

The transceiver station according to FIG. 1 for a radio system according to the invention, the transmission side includes a microphone Mi, which is connected to the input of an analog-to-digital converter D / A. The coded information is fed via the output of the analog-digital converter to the compressor Ko, which is controlled by the time program control device ZP, which is a logic circuit whose logic operations are defined for the desired sequence control. The compressor, the construction of which is described in more detail in FIG. 2, forms information bursts from the continuous digital signal flow, which in turn are divided into several, here four, information sections. A digital error detection signal is added to each information section in the compressor. From the output side, the compressor is connected to the encryptor which represents a modulo-two adder M2 and which receives the key signal from the quasi-random generator QZG. From the output of the modulo-two adder M2, the information bursts are first converted into an intermediate frequency position by means of the modulator Mod and then in the transmitter-side converter Us into the radio frequency position. The converter Us is followed by the transmission amplifier V, which is connected on the output side to the antenna An via the transmission / reception switch As. The transmit-receive switch As can, as indicated in FIG. 1, be operated manually, as is customary in a transceiver station for simplex operation. Instead of manual operation, an automatic switchover is also possible. In this case, the transceiver switch would be controlled by the time program control device.

On the reception side, the antenna is on via the transmit / receive switch switch As switched on to the bandpass BP, which is practically one Represents noise limitation. On the output side of the band passes BP follows the receiving converter Ue. That in em converter side Ue to the intermediate frequency position received signal is set in the intermediate frequency amplifier ZV amplified, then demodulated in the demodulator and for decryption to the receiving end Modulo two adder M2 fed, which in turn is the decryption receives signal from the quasi-random generator QZG. The decision Information bursts are then rarely found in the Expander Ex freed from the digital error protection signal, on transmission Checked errors and the In Formation sections of the information bursts under cancellation the time compression on the transmission side to the original Di capital signal composed. That returned in this way Won digital signal is on the analog-digital wall ler D / A fed to the receiver Ho.

To carry out the frequency hopping method, the transceiver station according to FIG. 1 has a central frequency processing unit ZFA in the form of a synthesizer to which a frequency address memory FAS is assigned. The frequency addresses are retrieved from the frequency address memory FAS by quasi-random sequences from the quasi-random generator QZG. From the output side, the central frequency processing is connected to the two inputs of the transmitter and receiver converters Us and Ue. During the tuning period of the synthesizer of the central frequency processing, the transmission amplifier is deactivated in order to avoid interference. In Fig. 1, this is indicated by the connecting line from the central frequency processing device ZFA to the transmitter amplifier V.

Furthermore, the transceiver points to the reception side a synchronization device behind the demodulator Dem and a correlation receiver Ke on the output side of the Modulo two adder M2. The synchronizer Syn wins the synchronization signal from the received signal for the quasi-random generator QZG and the time program control facility ZP. It stands with the one arranged in the Expander Ex Fault detection device in connection, through the safe is that that of the synchronizer for Maintaining the bit clock synchronization only the bits such sections of information are used by the error detection device are recognized as error-free. The transmitter-side switch to switch between the output of the module lo-two adder M2 and the input of the modulator Mod there the possibility to call the person before the start of a program Stations a syn generated by the quasi-random generator QZG broadcast chronological information, with the help of which receiving stations are quasi-random generators with the quasi-random generator of the transmitting station synchronize. The signaling receiver SE on the Em pfangsseite serves the call recognition. He will be for the second Call detection indirectly from the error detection device in the Expander Ex via the time program control device ZP in turn operates and controls via its exit in depend the time program control Facility.  

As the more detailed details of the compressor Ko according to FIG. 1 shows a block diagram according to FIG. 2, this essentially consists of a memory Sp which stores the information sections of an information burst, which in the present embodiment for four information sections forming one information burst has four double memory cells with one Has an input and an output. The inputs and outputs of the double memory cells are connected to the four connecting contacts with rotating switches S1 and S2. On the input side, the information sections corresponding to information sections are supplied to the double memory cells of the memory Sp one after the other in the rhythm of the switching function of the switch S1. On the output side of the memory these information components are temporally compressed, successively read out via the switch S2 and fed to the input of the OR gate OG and the input of the error code generator EDC, which is implemented, for example, by means of a microprocessor or a feedback shift register.

Circuits from error code generators as well as from the error detection circuits required on the receiving side are described, for example, in the book by Peterson WW "Error Correcting Codes", published by Wiley New York, 1961. The error code generator EDG derives the digital error protection signal from the information components supplied to it. The error protection signals are appended to the associated time-compressed information portions read from the memory cells of the memory Sp and, together with them, form information sections from which the information bursts are composed. The switches S1 and S2 and the error code generator are controlled by the time program control device ZP according to FIG. 1. In the embodiment of Fig. 1 is seen before that two information bursts the same Nachrich teninhalts be transmitted in succession, and in mutually opposite order. For this reason, the switch S2 changes the direction of rotation after each pass. In addition, its rotational speed is greater than twice the rotational speed of the switch S1. In contrast, the switch S1 always maintains its direction of rotation when queried.

The expander Ex, the more detailed block diagram is shown in Fig. 3, in turn consists essentially of the memory Sp with the four double memory cells and the two input and output side rotating switches S1 and S2. The memory input-side switch S2 reverses its direction of rotation in the rhythm of the received information bursts and in this way cancels the reversal of the sequence of the information sections in successive information bursts of the same message content made in succession on the transmission side. The received demodulated and decrypted information bursts are also fed to the error detection device EDC 'of the expander Ex, which checks the information section of an information burst for error-free transmission and always outputs an erase pulse to the associated one via its four outputs connected to the four double memory cells of the memory Sp Memory cell is there if the error evaluation detects a non-correctable error. The error detection device EDC 'can be realized, for example, by means of a microprocessor or a feedback shift register with an error detector. If upon receipt of the second information section having the same message content, the corresponding information section of the previous information burst is already error-free, then this second information section is ignored.

The four outputs of the error detection device EDC 'are connected to corresponding inputs of the evaluator Au, which in turn is supplied with the control clock for the rotating switch S2 from the time program controller ZP according to FIG. 1. The evaluator AU consists of a logic circuit which, depending on the reversal of the rotational movement of the switch S2, always emits a signal to the time program control device ZP when the error detection device EDC 'at the end of an information burst read into the memory Sp all four information sections as error-free or recognizes error-correctable. This signal causes the time program control device ZP to activate the receiver for a second call detection on one of the radio frequencies intended for a call for the now following period of an incoming further information burst with the same content via the central frequency processing device ZFA. If such a second call is recognized in the correlation receiver KE and this second call has priority for the establishment of a connection, a corresponding activation of the time program control device ZP via the output of the correlation receiver KE causes the station to use the previous connection in favor of establishing a connection to terminate the calling privileged station.

Claims (1)

Radio system for interference-resistant reciprocal digital information transmission between at least two stations, in which the radio connection is operated at least during the information transmission with leaps and bounds at predetermined times in a larger frequency range changing radio frequency, in addition to establishing the radio connection from the calling station one of the radio frequencies intended for a call, the other station is called by means of a call signal containing a synchronizer information and in which the information bursts successively alternating in the time grid of the radio frequency are repeatedly transmitted with regard to their message content and are divided into several information sections each provided with an error protection, according to patent 27 06 616, characterized in that the recipient of an occupied station for a transmission upon detection of an error-free or error-free incoming information bursts in the time range of at least one other message content arriving the same for the reception of additional information, for example a second call on one of the radio frequencies intended for call, is released.