FI57373C - ANORDING FOR OVERSTOCKING WITHOUT CONSTRUCTION INFORMATION FOR SPRING FOR SPECIFIC FORDON SPECIFICALLY FORWARDING - Google Patents

Description

R35r ^ 1 [b] (11) Publication No. 57377

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and the National Board of Registration (44) NihtMkiip ™ f.

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(32) (33) (31) Requested «tuolkuui — Bejirt prlorltut 03 * 07.72

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) P 2232530.0-21 (71) Siemens Aktiengesellschaft, Berlin / Munchen, DE; Wittelsbacherplatz 2, 8OOO Miinchen 2, Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (72) Gerhard Lutge, Braunschweig, Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (lk) Berggren Oy Ab (5 ^ +) , especially for railway vehicles - Anord-Ning för alstring och överföring av informationstelegram account spär-bundna fbrdon, speciellt account järnvägsfordon

The invention relates to an apparatus for generating and transmitting information telegrams for rail vehicles, in particular railway vehicles having track-mounted conductor loops which are electromagnetically coupled to vehicle-mounted antennas and connected in a predetermined cycle time and sequence to a central line device for each conductor. a block of information which, in a transmission interval comprising an n-fold downtime, transmits it to the relevant loop.

Special signal transmission methods and equipment are used for the control and protection of rail-bound vehicles, such as rail traffic. In order to carry out such tasks, trains shall be provided with information telegrams at regular intervals, in particular containing information to ensure adequate distance verification between trains.

Among the many methods of transferring information to trains, e.g. also by radio, this invention starts from the known system 57373, which is described in more detail in DE-A-1,530,335. · In this system, rail-mounted vehicles, in particular railway vehicles, are equipped with transmitting and receiving devices for electrical signals exchanged between vehicles and on-board fixed equipment, between the lin and the center. For this purpose, vehicles are fitted with antennas which are electromagnetically connected to short conductor loops mounted along the rail. Separate cable loops can in each case be connected to the line center via special cables. However, it is also possible to fit along the line remote-controlled switches that connect the separate cable loops, programmatically controlled, to a special cable leading to the line center. With this type of device, it is possible to accurately detect the position of the vehicle from the line center, because by cyclically switching all the wire loops only they give the signal above which the transmitting vehicle is just located, and more precisely the shorter the wire loops along the track. The position messages obtained can be given for this purpose in the memory reserved for the line center and by means of a calculator, using other data to process into control commands, which in turn are transmitted by means of a short-loop system to the vehicles to verify the distance.

However, ensuring and controlling the safety of vehicles is only sufficient if, taking into account the driving speed per unit time, there is a sufficiently frequent exchange of information, but at least one information transfer from the line center to the vehicle. For monitoring, the vehicle devices in such systems are constructed in such a way that, in the event of an unacceptably long time in the transmission of information, emergency braking can be triggered automatically.

Particularly in railway yard areas with many branch rails, several cable loops are required for adequate control of vehicle traffic, which allow data transmission in at least one direction from the center to the vehicles via a single bus center. Information transfer to the other direction can, for example, take place by radio. In such facilities, the cycle time, i.e. the time taken for each busy loop reserved in the yard area to be reconnected to the line center and to transfer the information block to the train in the line area in question, may become unacceptable 3 57373 unless special measures are taken. Another disadvantage of this known system for securing and controlling railway vehicles can be seen in the fact that the ability of the counter with all its accessories necessary to provide separate line loops with information blocks to develop information blocks is not sufficiently utilized.

Irrespective of whether the different conductor loops in the larger area are connected to the line center via separate conductors or channels or whether at least partially multiplexed transmission channels are available together with controlled switches, it is an object of the invention to provide an apparatus for generating and transmitting information telegrams to rails. thus, the necessary counters become better utilized, and in addition, given the large number of wire loops, the predetermined cycle time of each wire loop does not exceed a predetermined value. In addition, it is desirable that the device be easily adaptable to the widest possible range of track patterns with their associated conductor loops.

This also includes the fact that even after possible modifications with additionally installed or otherwise installed cable loops, no special modifications are required for the line unit.

According to the invention, the problem is solved in such a way that each block of information obtained from the line counter is divided into n sub-blocks, each divided into m bits, so that the sub-blocks pass successively to these connected parallel converters connected to n equal inputs n on the output side. Multiplexer) each connected to the input of a corresponding decoder (Demultiplexer) and that for each decoder at most k outputs are allocated for transmission channels from the wiring loops so that the cycle time for each transmission channel is less than the product of n, k and the descent time TR.

With such a device for generating and transmitting information telegrams to rail vehicles, it is more advantageous to use the counter's ability for information telegrams than in previous plants, while significantly reducing * 57373 cycle time because occur precisely to name waiting times.

In this connection, it is advantageous that the k-output of each decoder for the transmission channels is reserved locally for the conductive loops immediately behind each other. Since the information telegrams for successive conductor loops are generally detected against the direction of travel, it is necessary to use certain information for generating information, mainly from only one loop in the direction of travel in front of the conductor loop for which the information telegram is intended at the time of processing. For this purpose, a certain amount of memory is prescribed in the calculator for the information telegram, which, as a result of the above-mentioned operation, advantageously becomes small.

After the end of the calculation time for the information block, the information block provided by the calculator to the n sub-blocks must be processed in the correct order without erroneous switching between the sub-blocks of the previously or later calculated information blocks. For this purpose, the preferred device is characterized in that the supply line of the first sub-block of each information block is connected immediately and the supply line of the second sub-block to the corresponding parallel serial converter via an interconnected m-bit memory, that the third sub-block supply line is output from the first two series-connected memories. is connected to the and finally the output line of the n sub-blocks is connected to the first n-1 sequentially connected memory, the last memory of which supplies its associated parallel converter, and that the first control register is reserved for the parallel converter. the current memory contents are passed to the next memory, respectively, to the connected parallel serial drive.

The following embodiment is particularly practical in that a control register must be reserved for the parallel serial converter in any case, which takes care of the serial m-bit distribution per sub-block. In addition to this, it is also possible for a device for supplying separate sub-blocks to the parallel series converter 5 57373, which instead of the memory e.g. works with transit time elements.

In order to synchronize the operation, it is further preferred that the characteristics of the first control register operate for on-switching of all encoders and are fed to a second control register with n outputs for cyclically consecutive control symbols, to each of which a decoder with on-switching inputs is connected. The second control register may be constructed of an n-1 deceleration member. However, it is also advantageous to use ring-connected shift registers as the second control register.

In order to determine the information telegrams in the calculator, it is necessary to allow a number of information to be processed here, among which information about which lead loop in question. the information telegram must be counted. This can be done, for example, by reserving a standard memory programmed according to the realities of the local loop devices, which is queried before each information telegram is formatted. Since, in view of the versatile use of the device for generating and transmitting information telegrams independently of a predetermined lead-loop device, a large freedom of change is preferred, each decoder has a similar second decoder whose reconnection input line is thus connected to one n output of the second control register. is reconnectable before its first decoder and that the outputs of the second decoder are connected to a counter for data and material synchronization.

If it is desirable in each case to provide permanently stored data to separate blocks of information during the calculation times, which do not first have to be developed in the calculator by processing methods, it is advantageous to connect two associated decoders in the same position synchronously via the second control register.

Usually, certain line sections are operated in only one direction of travel. However, it is possible that due to bypass or arrangement movements, the lines are driven in an abnormal direction. In any case, since it is desirable that the guide loops also be provided with information telegrams in the opposite direction of traffic, it is advantageous to provide the decoders with devices which allow the direction of rotation to adapt to the respective direction of travel of the vehicle. The change of direction of rotation in this type of device also applies to the decoders connected to the counter for data and material synchronization.

57373

According to local realities vd. it may well be possible that not all the outputs of the decoder k are connected to the transmission channels of the conductor loops, so that a few outputs remain in case. These spare channels can be used to shorten the cycle time for other transmission channels. This is advantageously possible in that the decoders are provided with additional control devices which, for each control characteristic which causes the decoder to be switched off, trigger a predetermined multi-phase repeat connection so that the spare channels are crossed. However, it is also advantageously possible that the several outputs of the respective decoder and the associated second output are provided per se in connection with a transmission channel belonging to the line loop. Thus, a normal multiple of the time reserved for this transmission loop or for the transmission channel in general and marked as the transmission time slot of the information block is available.

An embodiment of the invention will be explained in more detail below with reference to the drawing. The figures show:

Figure 1 schematically shows a branched line part of a track-side device, with short guide loops.

Figure 2 is a block circuit diagram for generating and transmitting device information to line loops.

Figure 3 is a diagram with information blocks and their belonging to each other, respectively, to the conductor loops.

The line part of the track device schematically shown in Fig. 1 is driven in the direction of travel P from left to right. Short branch loops are installed on the branch track GS, which are connected to a fixed device, the line center, via various wires (not shown in more detail). The arrangement of short conductor loops along the line is arbitrary. For separation, each lead loop can be equipped with at least one cruise point. Sequentially arranged conductor loops SI.5, S1.4-S1.1, S4.1; S2.5j S2.A-S2.1 and the line loops S3.5, S3.4-S3.1 are regularly fed in succession with information which moves in question. to a rail vehicle above the line loop (not shown). For this purpose, receiving antennas are installed in rail vehicles, which are electromagnetically connected to the line loops. The block diagram according to Fig. 2 is an embodiment of a line exchange showing devices for generating and transmitting information for wiring loops. For the purpose of the embodiment, it is assumed that each information telegram assigned for a wire loop, which is intended to be transmitted to a train above this wire loop, consists of a block of information with 40 bits. These blocks of information are specially developed for each wire loop in the counter RR. For this purpose, the counter RR receives an indication via the collector line LI for which line of information the information block is to be obtained. In addition, there is other information, via lines L2 and L3, which, for example, can be queried from memories (not shown). Since it is irrelevant for the purpose of explaining the invention what information the blocks of information consist of and how this information is processed in detail in the calculator RR, these details will not be further affected.

For this embodiment, it was further assumed that 40 bits of each information block are transmitted over a relatively long transmission time TU (Fig. 3) to the line loop in question. The transfer interval should be, for example, four times the count time TR in Fig. 3 in the counter RR (n = 4). It follows that each information block is divided into n = 4 sub-blocks, which are simultaneously subdivided by the counter RR via the flow lines L5, L6, L7 and L8. Of these supply lines, only the supply line L5 leads directly to the parallel serial variable PS1, which thus processes only the first 10 bits of each information block, i.e. the first sub-block. The other parallel serial converters PS2, PS3 and PS4 are reserved for serial processing of the remaining three sub-blocks of each information block. Between the supply line L6 of the counter RR and the supply line L6 of the parallel series converter PS2 of the second sub-block, a memory SRI with a storage capacity of m = 10 bits is connected to each information block. Thus, when the information block is output via the counter RR, the SRI enters this memory exclusively with the second sub-block stored, so that this does not immediately end up in the parallel serial converter PS2. Between the supply line L7 of the counter RR and the parallel series converter PS3 are arranged the memories SR20 and SR21 connected in series, which in each case can only temporarily store a sub-block with 10 bits. The memory SR20 receives each third sub-block given via the line L7 and gives it to the memory SR21 by a special instruction. Before that, the second sub-block already stored here has been given to the parallel serial drive PS3. In addition, three series-connected memories SR30, SR31 and SR32 for each of the 10 bits are connected between the supply line L8 of each fourth sub-block of the information blocks and the input line of the parallel serial converter PS4. Thus, by means of this memory, the fourth sub-block of the information block given via line L8 is given to the parallel serial converter PS4 in such slow motion that the other three sub-blocks belonging to the same information block have already been processed by the parallel serial converters PS1, PS2 and PS3 when the remaining 10 bits remain. the fourth sub-block of the information block should be provided in series.

The four parallel series converters PS1, PS2, PS3 and PS ii have a common first control register ST1. This receives a forward switching pulse from the synchronizer TG, which is also connected to the counter RR on the output side. The ten control lines of the first control register ST1 are simultaneously applied to four parallel-series converters PS1-PS4 and operate to transmit the control pulses of the sub-block assigned to each parallel-series converter for serial processing. After ten steps in each case, i.e. after giving a complete sub-block with 10 bits in each case to the parallel serial converter PS1-PS4, the first control register ST1 gives a characteristic which first acts to produce it, which comes second via line L4 to counter RR and which also acts as memories SRI, SR20 and SR21 to control memories SR30, SR31 and SR32.

The four parallel-serial converters PS1-PS4 include n = 4 encoders MR1, MR2, MR3 and MR * J. Each of the four encoders has n = 4 inputs, of which mainly only the first and last in each case are provided with reference marks.

The equivalent inputs of encoders MR1-MR4 are labeled 1MR1, 1MR2, 1MR3 and 1MR4 and connected to each other on the output line of the parallel serial converter PS1 which transfers the first sub-block from each information block. The equivalent is true for the equivalent second inputs of the encoders connected to the PS2 parallel serial converter. The equivalent third inputs of the four encoders MR1-MR4 are connected to the output of the third parallel serial converter PS3, through which the third sub-block of each information block is transmitted. Finally, the equivalent fourth inputs 4MR1, 4MR2, 4MR3 and 4MR4 of the four encoders MR1-MR4 are connected to the output of the parallel series converter PS4. As seen from the control, the encoders are connected to the output ST1A of the first control register ST1 and thus become reconnected in one position at a time when the first control register ST1 in the parallel series converter has caused the output of a complete sub-block, e.g. controls memories SRI, SR20, SR21, SR30, SR31 and SR32. The function of the encoders MR1 to MR4 is - as will be explained later - to re-assemble each block of information divided into four sub-blocks.

Each of the encoders MR1-MR4 is connected to its decoder DM1, DM2, DM3, respectively. DM4 input. Each decoder DM1-DM4 has a maximum of k outputs for transmission lines, especially for conductor loops. The devices for transmission in one or both directions are only very schematically shown immediately at the actual output of the decoder, but are not marked further. The outputs to which the separate line loops (Figure 1) are connected via cable are marked A1.1-A1.5 in decoder DM1 and A2.1-A2.5 »A3.1-A3.5 and A4.1 in decoder EM2-DM4. A4.5, since it was assumed that the same number is reserved for each decoder DM1-DM4, k = 5 outputs. Assuming that the number is n = 4, and if the number of bits per sub-block is denoted by m, the number k is such that the cycle time in which all the outputs of the four decoders are once connected to the counter RR for one transmission interval remains less than n. k and the product of the descent time TR.

In the exemplary embodiment, it is assumed that all four decoders DM1-DM4 have the same number of k = 5 outputs. However, it is quite possible to use decoders with a different number of outputs. Even in such an embodiment, the predetermined cycle time will not be exceeded if the above condition is carefully considered.

As already explained in more detail above, before the counter RR is placed on a given lead loop, a notification must be made as to which lead loop, i.e., to which transmission block the information block to be transmitted will belong. For this purpose, each decoder DM1-DM4 has a similar second decoder DM10, DM20, DM30, respectively. DM40. Each of these decoders has the same number of k = 5 outputs as the decoder included in the information transmission. The output wires of the decoder DM10 are assembled as an assembly wire and marked MSG1. The same is also true for the forward lines of decoders DM20, DM30 and DM40 marked MSG2, MS03 and MSG4. These four bus lines finally form a bus line LI connected to the counter RR. In the embodiment, the bus line LI thus consists of 20 different lines.

10 57373

For the control and reconnection of the decoders DM1 to DM4 and the corresponding decoders DM10 to DM40, a second control register ST2 is reserved, which is formed as a ring-connected shift register and has n = 4 steps. The on-switching inputs of decoders DM1 and DM20 are connected to the output of the fourth stage D of the second control register ST2. The first stage of the output A of the control register ST2, which in the cyclic reconnection gives an output signal after the last output D, is connected to the reconnection inputs of both decoders DM2 and DM30. The equivalent is also true for the output of the second stage B and the reconnection inputs of both decoders DM3 and DM40. To the third stage C of the second control register ST2, the reconnection inputs of both decoders DM4 and DM10 are connected. Thus, it is achieved that each of the second decoders DM10-DM40 before the corresponding decoder DM1-DM4 is further switched on.

For reconnection of the second control register ST2, the characteristics provided by the first control register ST1 operate. Other details regarding the delivery method of the device of Figure 2 for generating and transmitting information blocks will be explained in more detail using the diagram of Figure 3 below.

Figure 3 shows a diagram of information blocks over time and with respect to each other. The time unit is marked with a T. As can be seen from the diagram, under the given conditions, namely that the period of the transmission interval TU is four times as long as the descent time TR and taking into account the cycle time TZ, a maximum of 20 information blocks can be prepared for a total of 20 transmission channels, i.e. the loop. In this connection, it is assumed that a wire loop is connected to each of the outputs of the decoder DM1 to DM4, and thus all 20 blocks of information must be obtained via a counter FR. According to the diagram of Figure 3, it is further observed that the information telegrams 1.1, 1.2, 1.3-1.5 are transmitted sequentially. At least partial concurrency in the transmission is valid in each case in overlapping information blocks, such as e.g. 1.1, 2.1, 3.1 and 4.1. The information blocks are offset by the descent time TR in each case and thus by one descent time TR. Thus, the simultaneous transmission is exactly true only for directly overlapping sub-blocks, e.g. at time T1 the fourth and thus the last time sub-block of information block 1.1, the third sub-block of information block 2.1, the second sub-block of information block 3.1 and the first sub-block of information block 4.1. These four sub-blocks are included simultaneously at the time T1 in the four parallel series converters PS1-PS4.

For a better understanding of the diagram of Figure 3, a few sub-blocks in the information block are provided with slashes. The purpose of these is to indicate the amount of landing time required for the blocks of information to be transmitted in the next transmission period.

First, on the basis of the diagram according to Fig. 3, it will be briefly explained in which order the different information blocks with the counter RR (Fig. 2) are obtained and in which order the transmission takes place. During the calculation time TRI, the counter RR determines, on the basis of the data transmitted to it and available to it (indication of the first position of the decoder DM10) for the information block 1.1, for which the transmission interval available is TU1. After the calculation time TRI, the counter RR is again free and can calculate the time of the next information block 2.1 within TR2. After this, the descent time TR3 for information block 3.1 closes. After the descent time TR 4, in order to detect the information block 4.1, a descent time TR5 follows, which is also still located within the transmission interval TU1 of the information block 1.1. In relation to information block 1.2, the counter RR gives the following information blocks: 2.2; 3.2; 4.2; 1.3; 2.3; 3-3; 4.3; 1.4; 2.4; 3.4; 4.4; · 1.5; 2.5; 3.5; 4.5.

choice johtosilmukoiden shown in Figure 1 of separate reference marks on one side and the choice of the decoders DM1-DM4 ulosme-nöjen reference marks and Figure 3 a diagram of the information blocks of reference marks on one side of each cohesion is observed. So there is, for example, a lead loop

Sl.1 is connected to the output A1.1 so that this lead loop belongs to the information block 1.1. The equivalent is true for lead loop SI.2, output AI.2 and information block 1.2. The line loop S2.1 is connected to the output A2.1, through which the information block 2.1 is transferred, etc.

The working examples described in the following text assume that the counter RR has just determined the information block 1.1 and that the observation moment is just before the calculation time TR2. It is further assumed that memories SRI, SR20, SR21 and memories SR30, SR31 and SR32 are not yet occupied. The same is true for the parallel series converter PS1-PS4. The second control register ST2 has already, via the output of the last stage D, given a control symbol to both decoders DM1 and DM20, which are then 12 57373 in the position shown. When the decoder DM20 is in the position shown, this fact is indicated via the dynamic input of the counter RR of the lines MSG2 and LI. From this message, the counter RR can state that now during the descent TR2 of the information block 2.1, it must be determined to which the wire loop S2.1 belongs.

During the descent time TRI (Fig. 3) was observed for the lead loop

S1.1 for the reserved information block 1.1, which after the fall time TRI, then with the characteristic of the first control register ST1 on line L4 via lines L5, L6, L7 and L8, is given as n = 4 sub-blocks, in each case m = 10 bits. The output time matches encoders MR1-MR4 and with the layout of decoders DM1-DM20. The first sub-block of the information block 1.1 arrives via the line L5 directly to the parallel serial converter PS1, while the remaining sub-blocks of the information block 1.1 (Fig. 3) are stored in the memories SRI, SR20 resp. SR30 and will initially remain in them as well. Thus, nothing has yet been assigned to the parallel series converters PS2, PS3 and PS4 and to the memories SR21, SR31 and SR32. During the on-circuit of the first control register ST1, the first ten bits of the first sub-block in the parallel series converter PS1 are output in series via the input 1MR1 of the encoder MR1 and are passed to the decoder DM1 via the input 1MR1 of the encoder MR1. Since, as the observation time, the encoders MR2, MR3 and MR4 are not set to the transmission of their first inputs 1MR2, 1MR3, respectively. 1MR4, nothing can arrive from the first sub-block of the information block 1.1 (Fig. 3) of the decoders DM2, DM3, respectively. Via DM4.

After reading the first sub-block of the information block 1.1 from the parallel series converter PS1, the first control register ST1 again gives the characteristic which passes via the line L4 to the counter RR, the memories SRI, SR20, SR21, SR30, SR31 and SR32, the encoder MR1-MR4 and the second control register ST2. Thus, this and encoders MR1-MR4 become further connected. Through the output of the first stage A, the control register ST2 gives a control signal for switching on both decoders DM2 and DM30. Thus, all encoders as well as both decoders are still connected by one. From the decoder DM30, the counter RR is instructed to obtain the information block 3.1 during the count time TR3.

X3 57373

The previous notification of the decoder DM20 to the counter RR provided that during the counting time TR2 it determined the information block 2.1 which now, immediately after seeing the characteristic of the first control register ST1, is given via the lines L5, L6, L7 and L8. From this information block 2.1, the first sub-block is again given immediately to the parallel series converter PS1, while the remaining three sub-blocks are stored in the memory SRI, SR20 resp. SR30, the contents of which, namely the second, third, respectively, fourth sub-block of the information block 1.1, through the characteristic of the first control register ST1, are read in advance and passed on. During the reading method, the second sub-block of the information block 1.1 enters the parallel serial converter PS2, while the third sub-block enters the memory SR21 and the fourth sub-block enters the memory SR31. During the next serial output via the parallel "serial converters PS1 and PS2, the decoder DM30, when set, acts on the announcement given to the first stage in the counter RR during the counting time TR3, and the information block 3 · 1 becomes calculated.

During the descending time TR3 (Fig. 3), the parallel-to-serial converter PS1 provides the input of the first sub-block of the information block 2.1 via the encoder MR2 and the decoder DM2 and this output A2.1 to its lead loop S2.1. At the same time, the second parallel serial converter PS2 processes the second sub-block of the information block 1.1, and assigns ten bits of this second sub-block to the encoder MR1 now on the second stage and to the decoder DM1 on the first stage and its output A1.1.

After the output of the sub-blocks to the parallel series converter PS1 and PS2, the first control register ST1 of the memory SRI is re-assigned, whereby the contents of the memory SRI are transferred to the parallel series converter PS2. The same is true for the SR21 memory and the PS3 parallel serial drive. The contents of the memory SR20 are then stored in the memory SR21. Further, the contents of the memory SR31 are fed to the memory SR32 and the contents of the memory SR30 to the memory SR31. In addition, another control register of ST2 is switched step further, so that the control characteristic of the step B of the outlet of the decoder will DM3 and DM40, which is therefore connected to a step forward in the direction of the arrow. The aggregation lines MSG4 and LI are then notified to the counter RR about the construction of the information block 4.1 on the conducting loop S4.1 during the descent time TR4. The encoders MR1-MR4 are further switched on by the characteristic of the first control register ST1, which then find themselves in positions three, two, one and four.

1ϋ 57373

From the information block 3 · 1, which is given by the last-mentioned characteristic of the first control register ST1 to the devices matched from the counter RR via lines L5-L8, the first sub-block again arrives at the parallel serial converter PS1 and the next three sub-blocks of information block 3.1 in memory SRI, SR20, resp. SR30.

During the calculation time TR4 of the information block 4.1, it is transferred from the parallel serial converter PS1 from the first sub-block of the information block 3 · 1 via the encoder MR3 and the decoder DM3 and this output A3.1. During this time interval, which corresponds to the sub-transmission interval, the parallel serial converter PS2 processes the second sub-block of the information block 2.1 and provides serial information about the encoder MR2 set in its second stage and the decoder DM2 and its output A2.1. Finally, the parallel serial converter PS3 processes the third sub-block MR1 of the information block 1.1, which is then output via its associated decoder DM1 and this output A1.1.

After the assignment of the three different sub-blocks from the parallel series converter PS1-PS3 »i.e. at the end of the countdown time TR4, the first control register ST1 is again given the characteristic which further switches the control register ST2 and the four encoders MR1-MR4. In addition, when the memory SRI, SR20, SR21, SR30, SR31 and SR32 are queried with said feature, the second sub-block of information block 3.1 in PS2, the third sub-block of information block 2.1 in PS3 and the fourth sub-block of information block 1.1 in PS4 are transferred. Through the counter query, the first sub-block of the information block 4.1 arrives in the parallel serial converter PS1 via the line L5, the remaining sub-blocks of which are stored in the memory SRI, SR20, resp. SR30.

By further connecting the second control register ST2, it becomes set to the last stage D and then gives a control signal from the last output of the previous stage C, by which the decoder DM10 becomes set to the second step and the decoder DM4 to the first step. When setting the second step in the decoder DM10, the counter RR is informed via the bus lines MSG1 and L1 that during the calculation time TR5 of the information block 1.2, it is necessary to determine which is determined for the lead loop SI.2.

Serial information output via the four parallel-to-serial converters PS1-PS4 now takes place via four encoders MR1-MR4, from which the following inputs are connected efficiently: 4MR1, 3MR2, 15 S7373 2MR3 and 1MR4. At the same time, the inputs of decoders DM1, DM2, DM3 and DM4 are still connected to the respective first outputs: A1.1, A2.1, A3.1, resp. A4.1.

During the descent time TR5, the first sub-block of the information block 4.1 is serially transferred via the parallel serial converter PS1 and the encoder MR4 and the decoder DM4 to the conductor loop S4.1. The second sub-block of the information block 3.1 enters the lead loop S3.1 from the parallel series converter PS2 via the encoder MR3 and the decoder DM3 and this output A3.1. At the time of the third sub-block of the information block 2.1, the parallel serial converter PS3 signals via the encoder MR2 and the decoder DM2. Through the output A2.1, said sub-block reaches the connected conductor loop S2.1. From the information block 1.1, the last sub-block is passed from the parallel series converter PS4 via the encoder MR1 and the post-connected decoder DM1 and this output A1.1 to the lead loop S1.1. At the end of the transmission time slot TU1 (Fig. 3), i.e. also at the end of the descending time TR 5, a complete information block and thus a complete information telegram is transmitted to the lead loop S11. The same is true after the second descent time TR6 for the information block 2.1 and the lead loop S2.1. In connection with information block 4.5, the calculator RR again delivers information block 1.1.

From these working examples, it is observed that the counter RR has at its disposal during the transmission interval, e.g. TU1, four consecutive descent times TR2, TR3> TR4 and TR5, whereby four different information blocks can be provided. It is also found that the device according to the invention for generating and transmitting information telegrams has the possibility to process an increased number of information blocks without having to increase the cycle time - as would actually be expected - n-4 times.

As another design of the described device, it is e.g. possible to connect the inputs of decoders DM1, DM2, DM3 and DM4 via lines L9 to a counter RR. In this way, e.g. location information from the carriageway to the counter is possible, because this is informed on the basis of the notifications of the decoder DM10-DM40, which of the line loops is in each case connected to the corresponding decoder DM1, DM2, resp.

DM3 or DM4.

Claims (11)

1. Device for the development and transmission of information telegrams for immobilized vehicles, in particular railway vehicles, comprising conductor loops located along the barrier, which are electromagnetically coupled to existing antennas on the vehicle and connected to a central line device within a predetermined period of time. , which for each conduit loop within the required counting time (TR) delivers an information block which is transmitted, within a transmission interval of n times the counting time, on the respective conduit loop, characterized in that each one is delivered in a counter (RR) of the line device. information blocks (1.1) are divided into a number of n sub-blocks each of which extends m bit, so that the sub-blocks over n output lines (L5, L6, L7, L8) of counter (RR) arrive one after another at this connected parallel series converter (PS ], PS2, PS3, PS4), which at the output side are connected to n equivalent inputs of a naplex device (MR1, MR2, MR3 »MR4), each of which is connected to the associated demultiplex device (DM1, DM2, DM3, DM4), and that for each demultiplex device (DM1, DM2, DM3), DM4) at most a number of k exits (Al.l, AI.2, A1.3-A1.5) for transmission channels of wiring loops (Sl.l., SI.2, SI.3, SI.4, SI.5 ) is arranged so that the period time (TZ, figure 3) is less than the product of the quantities n, k and the counting time TR. Device according to Claim 1, characterized in that the k outputs (Al.l-AI.5) of each demultiplex device (DM1) are arranged for the transmission channels of immediately adjacent conduit loops (S1.1-rS1.5). Device according to claim 1, characterized in that the output line (L5) of the first sub-block within each information block (1.1) is instantaneous and the output line (L6) of the second sub-block during intermediate coupling of a memory (SRI) is connected to the corresponding to the parallel serial converters (PS1, PS2), that the output line (L7) of the third sub-block is supplied to the first of two interconnected memories (SR20, SR21), of which the second memory (SR 21) is connected to the present parallel serial converter (PS3) and finally the output line (L8) of the n sub-block is connected to the first of n-1 interconnected memories (SR30, SR31, SR32), of which the last memory (SR32) feeds the associated parallel-series converter (PS4), and a first control register (ST1) is provided for the parallel-series converters (PS1-PS4), which after release of m bits of the partial blocks received in the parallel-series converters, emits a k end characters to all memories (SRI, SR20, SR21, SR30, SR31, SR 32), at which character the obvious memory memory is output to the following memory or memory, respectively. to the connected paral-lell series converter. Device according to claims 1 and 3, characterized in that the characteristics of the first control register (ST1) serve for simultaneous redirection of all multiplex devices (MR1-MR4) and a second control register (ST2) is provided, which comprises cyclically successive control characteristics. n outputs to which a multiplexing device (DM1-DM4) is always connected with its forwarding input. Device according to claim 4, characterized in that the second control register (ST2) consists of a ring-switched shift register. Device according to claim 4, characterized in that the second control register (ST2) consists of n-1 delay means. Device according to claims 1 and 3, characterized in that a similar second demultiplex device (DM10-DM40) has been assigned to each demultiplex device (DM10-DM40), whose switching input is thus connected to one of the n outputs of the second control register (ST2), that the second demultiplex device (DM10-DM40) is always redirectable before the associated first demultiplex device (DM1-DM4), and that the outputs of the second demultiplex device (DM10-DM40) in and for data and material synchronization are connected to the counter (RR). Device according to any of claims 1-7, characterized in that two related demultiplex devices (DM1, DM10) are synchronously transmitted in the same position synchronously through the second control register (ST2).