DE2050753C3 - Method and device for preventing system synchronization errors in the event of failure of a reference station - Google Patents

Description

The present invention relates to a method and a system for determining the failure a reference station in a satellite communications system and for selecting a secondary station, so that this takes over the work of the failing reference statinn.

With the advent of commercial satellite news broadcasts it was a natural desire for satellites to use the same type of techniques and facilities that they have been using for decades have served so well for terrestrial connections. However, as satellite technology advanced. is it It has become increasingly clear that conventional frequency division multiplexing (FDMA) is a Has a number of disadvantages; The main problem areas are the generation of Ir modulation disturbances in the satellite transponder, the need for precise power control between the stations of the Network and in the general rigidity of FDMA frequency allocation plans. A study of alternative solutions soon focused attention on the possibilities offered by time division multiplex systems (TDMA) are given in which stations with the help of non-overlapping bundle (burst) transmissions with each other circulate. Because only one at a time

Carrier signal received by the satellite transponder will become intermodulation interference and Service control difficulties eliminated

A major requirement for TDMA systems is the synchronization of the bursts so that they do not overlap even if the earth stations are so arranged that there is a difference in the propagation delay time between different earth stations and a single satellite 15 milliseconds If a station is just being powered up, it will have bundle detection difficulties; H. it must insert its transmission bundle in a suitable manner into the time frame so that it does not coincide with superimposed on the bundles of the other working stations. However, the initial detection is not Subject of the present invention.

During normal operation after detection, the relative delay times change between each of the earth stations and the satellite because of the Satellite does not maintain a perfectly constant attitude. In addition, the propagation delay time differences differ between the different earth stations. Hence it is necessary to have an ongoing Maintain checking of the bundle layers in each station and make corrections if necessary.

A known burst synchronizer works by comparing the time at which a Reference bundle, or a bundle from a reference station is received, with the time at which the bundle the local station is received. If the time difference does not equal a certain correct time offset is, a correction is made in the bundle of the local station. Obviously, results from non-existence a correction process a failure of the reference station in the continuous sending of their Data bundle a loss of synchronization of the entire system.

In DE-AS 12 56 741 is a time division multiplex messaging system described, which has a plurality of stations and a frame format that in a non-overlapping sequence a bundle of each working station contains data sent out, the bundle being one of the stations in the sequence as Reference bundle is determined which of all other stations to maintain synchronization is used in the system. A synchronized bundle is sent out from a specific reference station and transmitted via a satellite to all other earth stations. Such a synchronized bundle is used in Connection with a search pulse used, which is transmitted from each earth station via the satellite and is sent back to the sending station to maintain synchronization.

DE-AS 12 55 743 also describes a time division multiplex transmission system with a large number of multiplex stations whose incoming and outgoing channels are synchronized with one another, the signals of an incoming channel being used as a reference channel! are used for synchronization. The reference signals are derived from the signals of the one channel. The incoming signals ^oi nes other channel are input into a UnterspeL..ii. They are read from the sub-memory under the control of the reference signals in such a way that they are synchronous with the signals of the one channel. The entry of a b5 signal into the sub-memory is prevented if the signals of the other channel precede the reference signals. An additional signal is input into the sub-memory when the signals of the other signal lag behind the reference signals. Furthermore, a circuit is provided which samples the incoming signals of the other channel. A comparison circuit compares the sampled signals with the reference signals. The comparison circuit controls the switching on of a delay in the other channel. This control takes place in such a way that a signal arriving on the other channel is only input into the sub-memory in a desired phase relationship to the reference signal.

The last two known devices also have the disadvantage that if the failure Reference station in the continuous sending of their data bundle a loss of synchronization of the whole Sy-tems is the consequence

The invention is therefore based on the object of a method for preventing a system synchronization error as a result of the failure of a reference identifier in a time division multiplex messaging system to create according to the preamble of claim 1, with the help of which in a simple manner Errors or the lack of a reference station can be determined, with the synchronization of the system and the balance of the system should be maintained. This task is solved by the im Characteristic of claim 1 contained method steps. Advantageously takes over after Establishing the failure of the reference station and after the specified period of time has elapsed -; ine the Local stations automatically function as the reference station.

Refinements of the method according to the invention and a device for performing the method according to the invention Process can be found in the subclaims.

According to the present invention, in normal operation, the reference station sends an identifier for the fact that it is the reference station and all other stations control the identification of the Reference station. If for any reason the reference station fails or has some other error, will the absence of the reference identifier is detected by all other stations in the system. If the The station with the second position takes over the reference identifier during a specified period of time in the time frame relative to the reference station, i.e. the bundle B, assumes the function of Reference station by sending out a reference station identifier during its own bundle.

If the station whose bundle was at point B takes over the reference function, then synchronizes each of the remaining earth stations has its own bundle transfer time with respect to the new one Reference bundle. Although it is not necessary to reallocate satellite channels to the same Time is carried out as the stations synchronize their bundles with regard to the new reference bundle it is preferable that channel reassignment is carried out at the same time because then the previously channels assigned to the previous reference station for distribution among the other earth stations Can be available. In addition, the invention in the detailed description is described in Working in connection with a reallocation system described which the functions of synchronization combined into a new reference bundle and the reallocation of the satellite channels.

-lit

Although the device for performing the reference station takeover according to the invention with the The trunk synchronizer and the reallocator cooperate, because the Bundle synchronization and reallocation facilities are known, here only so much about the bundle synchronization and reallocation facilities as described for a complete understanding of the present invention is required.

F i g. Figure 1 shows the frame, burst and preamble formats for a TDMA satellite messaging system;

F i g. 2 is a block diagram of a preferred embodiment of the present invention;

Fig. 3 is a block diagram of a CARD word detector, in the in F i g. 2 can be used, and

F i g. FIG. 4 is a block diagram of a position detector used in the embodiment shown in FIG. 2 device shown can be used.

To aid in explaining the present invention, it will be assumed that the entire system includes only three stations located in France, the United States (U.S.) and Great Britain (UK) and which are indicated in a corresponding manner; France is initially the The reference station and the order of the bundles in the time frame is France bundle A, U.S. bundle B and UK bundle C. It is further assumed that the FIG. 2 facility shown in the U.S. station (local station) but it is clear that the same facility is in all stations.

It is now referred to in FIG. 1 is referred to the frame format shown. There you can see that during the frame period of 125 microseconds each station sends out a single burst of data and that the beams do not overlap in the satellite. As mentioned above, bundle A is from from France, bundle B from the U.S. and Bundle C from UK. The bundle of every station includes a preamble followed by voice channel information. The one through the voice channel information occupied area is actually divided into voice channel sections, each channel being a single one Conversation Represents In a typical TDMA format, each voice channel is eight bits long and one eight-bit word represents a single digitally coded speech information. If the entire system with one clock rate at 50 kilobits per second, corresponding to 20 nanoseconds per bit, each channel section would be 160 Take nanoseconds of the entire bundle. It is therefore clear that in each bundle there are a number of Channels is included

The preamble of a bundle is the part that contains all signals and data necessary for synchronization and the operation of the network are required. The preamble is usually the first part of a too transmitted bundle and can also be defined as that part of a bundle that does not contain the voice information The first part of a preamble is the protective tent GT, which is an intentional between the bundles inserted period is without transmission in order to prevent their accidental overlapping. Such Overlapping could be due to tolerance changes in the system, uncertainty in the synchronization process or simply occur through transients in connection with carrier switch-ons. By doing The protection time is determined by the bundle synchronization method and that of the individual stations used clock pulses determined. A protection time of 100 nanonseconds, corresponding to 5 bits, is considered sufficient. The carrier recovery part of the preamble is a time during which the carrier is transmitted unmodulated, what the receiver when it locks onto the Carrier frequency and phase supported. The clock recovery part occupies 10 bit times and contains the carrier modulated by the clock pulses to allow the receiver to properly clock synchronize. The next 20-bit word in the preamble is the code combination for the station address (SAC) that the Sending station identifies. Therefore, all bundles from the U.S. contain a SAC word that the U.S.

characterizing.

The SAC word is followed by four bits of channel assignment and control data (CARD). The whole CARD word is 32 bits long, but is divided into eight frames of four bits per frame. The recipient then removes the four bits in the CARD word section of eight consecutive bursts for the same station and reconstructs the entire CARD word from it. The CARD word contains the information required for the Allocation of channel connections between stations is required. The information part of the CARD word is 21 bits long with an error-detecting code combination of 10 bits that goes to the end of the 21st Data bit is attached. An extra space is added to form a 32 bil word so that the

JO CARD word can be evenly distributed over the eight frames. Typically, a BCH (31, 21) error detection code will ensure the detection of a word with four or fewer faulty bits.
The 21 bits of information in the CARD word comprise a four-bit designation section and a nine-bit channel number section. If z. B. to transfer a call from station A to station C, the channel number 5 is selected, then the bundle from station A contains an identifier of station C.

ίο in the destination section of the CARD word and the number 5 in the channel number portion of the CARD word. This informs station C that those in the fifth Channel section of the bundle of station A containing information is directed to them.

As described in the prior art, the determination section and the channel number section of the CARD word is also used to initiate the reallocation process and some reallocation information to be transmitted to all stations on the network. One in the four-bit determination section The code combination 0000 occurring in the CARD word informs all stations that a reassignment The code combination 1111 in the four-bit determination section indicates that the Number in the nine-bit channel number section represents the highest numbered channel, e.g. Zt through the transmitter is in use. All this information is used to generate the bundle during the To put reallocation back in the right place.

The last section of the preamble is occupied by an eight-bit word called an access mode circuit, which is normally used as a conference call connection.
According to the invention, two one-bit sections of the CARD word are used to identify the reference station and to identify the failure of a reference station
For example, the presence of a "one bit" shows

in the 20th bit position of the CARD word that the sending station is the reference station, whereas one "Zero" in the 20th bit position of the CARD word indicates that the sending station is not the reference station. A The "one" bit in the 21st bit position of the CARD word indicates that the sending station lost the reference station has, while a "zero" bit in the 21st bit position of the CARD word indicates that the sending station has the Has not lost the reference station

An example of logic that can be used to determine the data contained in a CARD word is in Fig. 3 shown. Each local station, e.g. B. the US station, contains logic that is able to use the CARD word of all stations used in the system including the local station itself. Be it assumed that the in F i g. 3 is located in the U.S. station, and also that it has the Logic to determine the French word CARD is. It should also be noted that every eighth The bundle sent out by a specific station contains the SAC word in complementary form. If that Complement of the SAC word arrives, this indicates the beginning of a new 32-bit CARD word.

When the recipient detects the SAC word representing France, a timer 32 begins, the To initiate control of an AND circuit 34. The timer operates to the AND gate 34 for a duration of 80 nanoseconds following the SAC word (corresponding to the time for the Four-bit CARD word). As a result, the data of the four-bit CARD word becomes from the received Data taken out and into a C ^ RD word shift register 36 entered. After eight full bundles, the CARD word in register 36 is complete reconstructed, with the determination code combination in the determination section 38, a reference station identifier in section 39 and an indicator for the failure of the reference station in the section 40. In addition, data contained in the CARD word are not shown because it is necessary for the understanding of the present invention is not important.

When the word in the shift register 38 is fully reconstructed, then the subsequent bundle is of the same station the complement of the SAC word. The latter flag controls a destination decoding circuit 42 and the AND circuits 44 and 45, each of which comprises some information the CARD word shift register 36 reads. When the determining section 38 sets the code combination 0000 contains, then the determination decoding circuit 42 delivers an output signal at the time of activation to the new supply exit line. If the Determination section 38 the code combination 1111 then the destination decoding circuit 42 provides an output on the output line to mark the last channel number. The two the latter output lines confirm the reallocation logic mentioned above. If France the Is the reference station, then the section 39 contains a "One" bit and it therefore occurs at readout time Output from AND gate 45 indicating receipt of a burst from the reference station. In normal operation, the section for the failed reference station contains a "zero" bit and that Output from AND circuit 44 therefore does not indicate a failure of the reference station. The way how the R and L sections of the CARD word are filled will be described later. Be on it pointed out that the readout could be carried out even if the system does not operate so that the complementary SAC word is sent out in every eighth frame. The SAC word identifier could be fed to a counter that provides an output signal for every eighth counting pulse, this latter output initiating the readout.

Reference is now made to that shown in FIG Facility referenced. Each of the CARD detectors 50, 52 and 54 performs the functions described in connection with FIG. 3 logical operations described. So the UK-CARD detector 50 has an R output and one L output. The other data determined by the CARD detectors are summarized as shown and fed to reallocation logic 56.

Before describing the main object of the invention which detects the failure of a reference station and transferring the reference station function to another station, a general description of the Given the overall system environment with which the invention is associated receives the information transmitted back from the satellite and forwards this digitally encoded information to a system 72 which extracts the voice channel information, decodes it and communicates with the correct subscriber line connects. The system 72 also encodes the input speech information from the subscriber line and forwards the encoded speech information to the transmitter 76. A timing device 74 controls the transmission so that the coded speech data and the preamble information within of the station bundle on the right slope. The timing controller 74 responds to the output of a bundle synchronizer 70 to begin its timer function before the respective bundle. the The bundle preamble is assembled in a preamble data logic 78 and is under control of the transmitter 76

The preamble data logic 78 may comprise a CARD word generator 80 which contains the above-mentioned channel allocation and control data
While the trunk synchronizer 70 on its own is not the subject of the present invention and therefore will not be fully described in detail, it is closely related to the logic for the control of the reference station failure and therefore certain aspects of the trunk synchronizer 70 are summarized herein in the trunk synchronizers the 50 Kolobit clock pulses are fed to a counter / divider which divides the clock pulse by the value N and delivers an output pulse for every N clock pulses. The output pulse triggers the bundle of the local station. In the case of a 125 microsecond frame, N would be 6.250. This number corresponds to the number of clock pulses per frame. If the trunk synchronizer determines that the local station trunk is too close to the reference station trunk then it activates an N + i gate in the trunk synchronizer which forces the counter / divider to divide by N + 1. This has the effect of delaying the burst by 1 bit per frame as long as the N + 1 gate is activated. If the burst synchronizer determines that the burst is too far from the reference burst and should be advanced in time, then the burst synchronizer turns on Activated N- 1 gate, causing the counter / divider to divide by N-1

The consequence of a division by / V-1 is a forward shift of the bundle by 1 bit per frame, see above long the N-1 gate is activated. When the trunk synchronizer determines that the location trunk is correct in time, then the N-gate is activated, with the result that the counter / divider divides by N. Of the The trunk synchronizer determines whether the location trunk is in the right position or not, or whether it is too early or not is too late by finding the time difference between the arrival of the reference station SAC code combination and compares the local station SAC code combination with a size contained in the transit time counter of the Bundle synchronizer is stored. The one stored in the run time counter of the bundle synchronizer Size represents the correct distance between the reference station and the location station bundle.

The reallocation logic 56 effects a change the position of the local station bundle by introducing a new variable into the transit time counter of the bundle synchronizer.

In accordance with the present invention, each station monitors the presence of a "one" bit in the R section of a CARD word. If no reference station symbol is received for a full second, indicating that the reference station is down or malfunctioning for any reason, the following happens: Each station immediately forces its corresponding trunk group to divide by N , thereby preventing its trunk from being shifted for a time, which is sufficient for a new reference station to take over the task. The station whose bundle was in the second position within the frame inserts a "one" bit in the R section of its CARD word and thereby assumes the function of the reference station. The latter station also triggers a channel reallocation by entering the code combination 0000 in the four-bit determination section of its CARD word.

As in Fig. 2, the output signal data from the receiver 58 is fed to the CARD detectors 50, 52 and 54 and the SAC detector 51. The SAC detector 51 provides an output on the UK, France or US output line in response to the detection of the appropriate SAC word. The UK, France and US output signals from the SAC detector 51 pass the corresponding CARD words into the CARD detectors 50, 52 and 54. As long as the reference burst is received, an R output signal from appears at least once per frame one of the CARD detectors. In the example described here and assuming that France is the reference station, there is 125 microseconds before. the CARD detector 52 an R output signal. The R output signal lines are routed via an OR circuit 62 to a position detector 60, a monostable integration multivibrator 66, the reallocation logic 56 and the bundle synchronizer 70. The position detector is a simple logic circuit that determines whether bundle B is the US bundle or not

The only function of the location logic 60 is to provide a signal when the location station is at point B in the bundle. An example of a logic which is suitable for determining whether the local station (US) is transmitting the bundle or not is shown in FIG. 4 and will now be described.

The output pulses from the SAC detector 51 are fed to the input of a counter 118 via an OR circuit 100 and a delay device 104. The reference pulse from the OR circuit 62 (FIG. 2) is applied to the reset input of the counter 118. The delay device 104 causes a very small delay between input and output, sufficient to ensure that the signal which represents the SAC recognition of the reference beam follows the reference pulse in time. In this way the meter registers the

ίο Counter reading "One" in response to the determination of the Reference SAC word, "two" in response to the determination of the bundle B-SAC word, "three" as Response to the detection of the bundle C-SAC word etc.

The signal for the detection of the US-SAC word is passed to two AND circuits 112 and 110 via a delay device 106. The delay device 106 provides a delay slightly longer than the delay device 104 to ensure that the counter has settled before the signal for the detection of the US SAC word is fed to the AND circuits. A "two" decoding circuit 116 supplies an output signal to the AND circuit 112 when the counter 118 registers a count "two", and supplies an output signal via an inverter 114 to the AND circuit 110 when the counter does not have a count "two " registered. The output signal of the AND circuit 112 sets a flip-flop circuit 108 and the output signal of the AND circuit 110 resets the flip-flop circuit. In the set state, the output signal of the bistable multivibrator 108 indicates that the bundle of the local station is in position B of the frame.

If, as in an assumed example, the US station is in position B, then the counter registers the count "two" at the time when the output signal of the delay device 106 is applied to the AND circuits 112 and 110 . As a result, the bistable multivibrator 108 is set and remains in the set state until the point in time when the bundle from the US station assumes another position. A 125 microsecond monostable multivibrator 102, the output of which is connected to AND circuits 112 and 110 , ensures that the state of bistable multivibrator 108 is not changed if the reference pulse fails.

In the assumed example, the US bundle is in position B. The monostable integration multivibrator 66 (FIG. 2) has a tilting time of one second. Thus, as long as a full second does not elapse between successive reference characteristics, the output of the monostable integration multivibrator remains high and the output signal of an inverting element 68 connected to it remains low. However, if the reference identifier is not received for a full second, the output signal from the monostable integration multivibrator 66 is low and causes an indication of the failure of the reference station to appear at the output of the inverter 68 CARD word determined by timing controller 74, a "one" bit passed through AND circuit 82 and inserted into the L portion of the CARD word -Section that the reference station has failed. As a result, all show

CARD words sent out by the U.S. station indicate the failure of the reference station until the point in time when a new reference station takes over the function. The low outputs from the CA RD word detectors 50, 52 and 54 are fed to a failure detector 64 which has a reference change output delivers when at least the CARD words of two stations indicate a failure of the reference station. It it should be noted that if the CARD word is only one station there is a failure of the reference station indicates the failure is likely to be a fault in the monitoring station rather than a fault in the reference station is.

The reference change display has the effect that the bundle synchronizer is forced to divide by N in all stations. This is accomplished by setting a flip-flop 94 whose output disables the Λ / + 1 and / V-1 gates in the bundle synchronizer 70 and activates the divide-by-N gate 88 in the bundle synchronizer 70. Until the flip-flop is reset, the trunk synchronizer continues to divide by N , which does not change the position of the local station trunk. The reference change indication can be fed to a delay circuit 96 which delays the input signal by a period of time approximately equal to twice the round trip time to the satellite. The purpose of the delay is to allow enough time to be able to transmit a reallocation flag to all stations (during an initial round trip time) and the data required for the reallocation process for all stations (during a second round trip time).

In the station which is in position B, the reference change indication from the failure detector 64 runs through an AND circuit 98 and AND circuits 84 and 86 are supplied. The AND circuit 84 causes a "one" bit to be entered in the reference section of the CA R D word, whereas the AND circuit 86 causes the code combination 0000 to be entered into the determination section. The consequence is that the station, which was previously in the second position, now becomes the reference station and becomes the same Time to send out a reallocation code combination. As a result of the process described last all stations synchronize their bundles with the new reference bundle.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. Method for preventing a system synchronization error as a result of the failure of a Reference identifier in a time division multiplex messaging system, which has a plurality of stations and a frame format that a bundle of data sent by each working station in a non-overlapping sequence contains, the bundle of one of the stations in the sequence being determined as the reference bundle, which of all other stations are used to maintain synchronization in the system, α a d u r c h marked, a) that in a local station the received bundles (A, B, C) of all stations for determination the presence of a reference signal must be monitored, which one (A or B or C) identifies the received bundle as a reference bundle, b) that during the bundling time of the local station a "failed" or "miss" signal is sent out that if the reference signal is not established within a certain period of time marks or signals the failure of the reference station, c) that the received bundles of all stations for the determination of "failed" signals of the Reference station (A or B or C) are monitored, and d) that a change in the burst transmission time of the local station in relation to the other stations the detection of the "failure" signals is prevented for a certain period of time followed by a certain number of bundles received. 2. The method according to claim 1, characterized in that (a) monitors the received bundles to determine whether the bundle of the local station within the frame is the second digit assumes or not relative to the reference beam, and that (b) a reference signal is transmitted, which identifies this local station as the reference station after "failed" signals in a certain number of received bundles were determined and it was also determined that the bundle of the local station occupies the second position within the frame. 3. The method according to claim 2, characterized in that a certain code signal is sent out to cause all stations to reassign their bundles to the bundle of the local station synchronize, and that the code signal is sent out after "failed" signals in a a certain number of bundles received were determined and it was also determined that the Bundle of Ortsstalion occupies the second place within the frame 4. Device for performing the method according to one of claims 1 to 3, characterized (a) by a reference signal monitoring device (50,52,54) in the local station, for monitoring the bursts received by all stations to determine the presence of a reference signal, which identifies a bundle as a reference bundle, (b) by one with the monitoring device connected device (66, 68, 82) for sending out a "failed" signal during the bundle time of the local station, which indicates that the Reference station has failed if the reference signal has not been established for a certain period of time (c) by a "failed" signal monitor (64) to monitor the received bundles of all stations for the presence of "failed" signals and (d) by one with the "failed" signal monitoring device associated means (94, 96, 88) for preventing a change in the burst transmission time of the local station for a certain period of time in response to the detection of "failure" signals in a certain number of bundles received. 5. Device according to claim 4, characterized (a) by a position locking device (60) for Monitor the received bundles to see if the bundle of the local station is the second Position within the frame relative to the reference bundle occupies or not, and (b) through a device (84) connected to the position determining device for transmitting a reference signal, which identifies this local station as the reference station, as a result of the determination of "Failed" signals in a certain number of received bundles and the determination that these Ortsstalion occupies the second position within the frame. 6. Device according to claim 5, characterized by one connected to the position locking device Means (86) for sending out a particular code signal to cause all Stations synchronize their bundle with the bundle of the local station, as a result of the detection of "Failed" signals in a certain number of received bundles and the determination that these Local station occupies the second position within the frame.