EP3838709A1 - Method for transferring telegrams from a central unit to a vehicle and central unit - Google Patents

Abstract

The invention relates to a method for transferring telegrams from a route control center (RBC1 ... RBC2) of a train control system to a control device (SG1 ... SG2) of a vehicle (FZ1 ... FZ2). The control unit (SG1 ... SG2) has a buffer memory (PS1 ... PS2) with storage spaces for a certain number of received telegrams. The line control center (RBC1 ... RBC2) has a mirror buffer memory (SPS1 ... SPS2). For the vehicle (FZ1 ... FZ2) memory spaces (SP1 ... SP3) are reserved in a certain number, preferably 3 memory spaces for ETCS, in the mirror memory buffer (SPS1 ... SPS2). In the line control center (RBC1 ... RBC2) either a telegram to be transferred is written to a free memory location (SP1 ... SP6) if the specified number of telegrams that have already been transferred has not yet been reached, whereby the telegram to be transferred to the control unit (SG1 ... SG2) of the vehicle (FZ1 ... FZ2) is transferred, or, if the certain number of already transferred telegrams is reached, the transferred telegrams and in particular, the telegram to be transferred is also prioritized. The telegram with the lowest priority is rejected. All telegrams stored in the memory locations of the mirror buffer memory (SPS1 ... SPS2) are transferred to the control unit (SG1 ... SG2) of the vehicle (FZ1 ... FZ2). A route control center (RBC1 ... RBC2), a computer program product and a provision device for this are also included.

Description

The invention relates to a method for transferring telegrams from a route control center of a train control system to a control unit of a vehicle, the control unit having a buffer memory with storage locations for a specific number of received telegrams. The invention also relates to a route control center of a train control system which is set up to transfer telegrams to a control unit of a vehicle. Finally, the invention relates to a computer program product and a provision device for this computer program product, the computer program product being equipped with program commands for carrying out this method.

The transfer of telegrams is used in automatic train control systems to transfer information from a route control center to the trains running in the relevant route section. The relevant route section is the one that is controlled by the relevant route control center.

In ETCS systems (European Train Control System), the route control center is also called RBC (Radio Block Center). The telegrams are transmitted to an on-board unit (OBU), which serves as a control unit in the vehicle. It is also known from the ETCS standard that different route sections can be operated with different expansion stages of the ETCS system. These are characterized by different levels. There are level 0 to level 3 as well as the level NTC (national standards).

Does the train switch between route sections with different levels (level transition in the ETCS standard), or does the train switch between route sections that are controlled by different route control centers (RBC-RBC transition in the ETCS standard), currently valid telegrams must be transferred. For this purpose, the vehicle (train) has a buffer memory, also called a transition buffer in the ETCS standard. The buffer memory is used to take current telegrams with them into the next section of the route, so to speak. For this purpose, the telegrams are stored in the buffer memory and are therefore still available in the next section of the route.

For the ETCS standard, the use of the transition buffer is defined in subset-026-4 under 4.8.5 ff. It is then provided that in the event that three telegrams are already stored in the transition buffer, each new telegram should be saved and the oldest telegram should be deleted.

However, this can also mean that important telegrams are deleted because these are the older ones and telegrams that are not so relevant are saved. This is to be explained using the following case as an example.

First a movement authority is sent. Further general telegrams (e.g. general messages) are then sent. The third of these telegrams then deletes the movement authority. This results in an emergency brake in the event that the vehicle changes to ETCS level 2, for example, because a movement authority is required at this level and is not present in the present example.

The invention consists in specifying a method for transferring telegrams from a line control center to a vehicle, with which it is possible to give priority to more important telegrams over unimportant telegrams when the operating conditions change, for example a level transition or an RBC-RBC transition (also RBC-RBC handover) according to the ETCS standard. In addition, it is the object of the invention to provide a line control center which, when the operating conditions change, as stated above, ensures the transfer of more important telegrams with priority. Finally, the object of the invention is to provide a computer program product as well specify a provision device for this computer program product with which the aforementioned method can be carried out.

• für das Fahrzeug Speicherplätze in der bestimmten Anzahl in dem Spiegelspeicherpuffer reserviert werden,
• und in der Streckenzentrale entweder ein zu übergebendes Telegramm in einen freien Speicherplatz geschrieben wird, wenn die bestimmte Anzahl mit bereits übergebenen Telegrammen noch nicht erreicht ist, wobei das zu übergebende Telegramm an das Steuergerät des Fahrzeugs übergeben wird,
• oder, wenn die bestimmte Anzahl mit bereits übergebenen Telegrammen erreicht ist, in der Streckenzentrale in einem Bewertungsschritt die übergebenen Telegramme und insbesondere zusätzlich auch das zu übergebende Telegramm priorisiert werden, und das Telegramm mit der geringsten Priorität verworfen wird, wobei alle in den Speicherplätzen des Spiegelpufferspeichers gespeicherten Telegrame an das Steuergerät des Fahrzeugs übergeben werden.

This object is achieved according to the invention with the claim (method) specified at the outset in that the route control center has a mirror buffer memory, wherein

• A certain number of storage spaces are reserved in the mirror storage buffer for the vehicle,
• and either a telegram to be transferred is written to a free memory location in the line control center if the specified number of telegrams that have already been transferred has not yet been reached, the telegram to be transferred being transferred to the vehicle's control unit,
• or, if the specified number of telegrams that have already been transferred has been reached, the transferred telegrams and in particular also the telegram to be transferred are prioritized in the line control center in an evaluation step, and the telegram with the lowest priority is discarded, all in the memory locations of the mirror buffer stored telegrams are transferred to the vehicle's control unit.

For the telegram to be transferred, the term "discarded" means that it is not written to a storage location and for a transferred telegram that it is deleted from the storage location and the telegram to be transferred is written to the storage location. In other words, the method according to the invention ensures that more important telegrams are retained in any case, even if they are already older and in this respect have already been stored in the buffer memory for a longer period of time. More recent telegrams are therefore only written into the mirror buffer memory (to be precise, in a memory location of the mirror buffer memory) if either an empty memory space is still available or less important messages are stored in the memory spaces available at all.

According to the invention, storage space with which the mirror storage buffer can be implemented is made available in the line control center for the method. This storage space must have a sufficiently large capacity so that the line control center can also, so to speak, look after several trains at the same time in the relevant line section. This means that a mirror buffer memory is operated for all vehicles that are located in the relevant route section, which provides just as much memory space as the buffer memory in the control units of the vehicles.

The mirror buffer memory is used whenever the vehicle transitions. As already described, such a transition can consist, for example, of an RBC-RBC transition or a level transition in accordance with the ETCS standard. At this point in time it is necessary to fill the buffer memory in the control unit of the vehicle with the telegrams that are important for the transition. Since these are available in the mirror buffer memory assigned to the vehicle, this is easily possible according to the invention, so that the vehicle is advantageously transferred smoothly.

The difference between the buffer memory in the vehicle's control unit and the mirror buffer memory in the control center is that the buffer memory must be operated according to the ETCS standard if the automatic train control system is ETCS. On the other hand, the mirror buffer, which is operated in the line control center, is not provided for in the ETCS standard, so that its operation can be subject to other rules without violating the ETCS standard. Therefore, the control center can send the telegrams stored in the mirror buffer memory if necessary and cause them to be written into the buffer memory of the control unit of the vehicle and available there, taking their importance into account. A deletion of important telegrams prescribed by the ETCS standard can thus be advantageously prevented by sending them again without violating the ETCS standard.

It can be provided, for example, that the telegrams from the mirror buffer are sent to the control unit in the order of their importance, i.e. the least important first and the most important last. This advantageously ensures that not only are all high-priority telegrams available during the transition in the control unit of the vehicle, but are also deleted in the following in the order of increasing priority without any action by the control center, if, for example, the oldest according to the ETCS standard Telegram (and thus the least important in this case) is deleted first and then the younger ones. In other words, it is beneficial if the method according to the invention sends the telegrams in the order of their importance, since the age of the telegrams then corresponds to their importance, ie. H. the most recent telegram is also the most important (i.e. the one with the highest priority). It should be noted, however, that sorting the telegrams according to their importance is not absolutely necessary if the method according to the invention is used again at the next transition, in other words a further mirror buffer ensures that all important telegrams are retained again.

Unless otherwise stated in the following description, the terms “create”, “calculate”, “calculate”, “determine”, “generate”, “configure”, “modify” and the like preferably relate to actions and / or Processes and / or processing steps that change and / or generate data and / or convert the data into other data. The data are in particular available as physical quantities, for example as electrical impulses or also as measured values. The necessary instructions / program commands are summarized in a computer program as software. Furthermore, the terms “receive” “send”, “read in”, “read out”, “transmit”, “write”, “hand over” and the like relate to the interaction of individual hardware components and / or software components via interfaces. The interfaces can be hardware technology, for example wired or as a radio link, and / or software technology, for example as an interaction between individual program modules or program parts of one or more computer programs can be realized.

In connection with the invention, “computer-aided” or “computer-implemented” can be understood to mean, for example, an implementation of the method in which one or more computers executes or executes at least one method step of the method. The term "computer" is to be interpreted broadly, it covers all electronic devices with data processing properties. Computers can thus be, for example, personal computers, servers, handheld computer systems, pocket PC devices, mobile radio devices and other communication devices that process data with the aid of computers, processors and other electronic devices for data processing, which can preferably also be connected to a network. In connection with the invention, a “memory unit” can be understood to mean, for example, a computer-readable memory in the form of a random access memory (RAM) or data memory (hard disk or data carrier).

• entweder das übergebene Telegramm in einen freien Speicherplatz des Pufferspeichers geschrieben wird, wenn die bestimmte Anzahl von empfangenen Telegrammen noch nicht erreicht ist, oder
• oder das älteste der bereits empfangenen Telegramme aus dem Speicherplatz des Pufferspeichers gelöscht wird, wenn die bestimmte Anzahl von empfangenen Telegrammen erreicht ist, und anstelle des gelöschten Telegramms das übergebene Telegramm in den frei gewordenen Speicherplatz geschrieben wird.

According to one embodiment of the invention it is provided that in the control device

• either the transferred telegram is written to a free memory location in the buffer memory if the specific number of received telegrams has not yet been reached, or
• or the oldest of the already received telegrams is deleted from the storage space of the buffer memory when the certain number of received telegrams has been reached, and instead of the deleted telegram the transferred telegram is written into the free memory space.

The procedure of this embodiment of the invention corresponds to the ETCS standard. According to this, provision is made for the telegram to be deleted to be selected in the control unit of the vehicle only with a view to the age of the telegrams. This means that that telegram is always deleted that was already on has been in the buffer for the longest time. However, this can be a telegram that is required at the latest when the vehicle transfers to another route section (level transition or RBC-RBC handover).

• Zuerst wird eine Movement Authority gesendet.
• Anschließend werden drei General Messages gesendet (update des Linking).
• Durch die dritte General Message wird die Movement Authority gelöscht.
• Dadurch kommt es zu einer Zwangsbremsung, wenn das Fahrzeug nach ETCS Level 2 wechselt, weil keine Movement Authority vorhanden ist.

A sequence of sending telegrams according to ETCS can, for example, take place in the following sequence.

• First a movement authority is sent.
• Then three general messages are sent (update of the linking).
• The movement authority is deleted by the third general message.
• This results in an emergency brake when the vehicle changes to ETCS Level 2 because there is no movement authority.

Such an emergency braking can be prevented, for example, if the Movement Authority is given such a high priority that it cannot be suppressed by general messages.

According to one embodiment of the invention, it is provided that ETCS is used as the train control system. According to one embodiment of the invention, it is also provided that the specific number is three. In other words, this means that the buffer memory provides three storage locations for telegrams, as provided by the ETCS standard.

According to one embodiment of the invention, it is provided that all telegrams stored in the memory locations of the mirror buffer memory are only transferred to the control unit of the vehicle if at least one of the memory locations of the mirror buffer memory has been rewritten after the evaluation step.

This advantageously ensures that when the information is transmitted during train operation, the method according to the invention only increases the data rate as much as is necessary. In other words, stands for the transmission of others Information is then available in a larger volume of data. Particularly with increasing utilization of the rail traffic, the data rates can be kept at such a level that several trains can be controlled at the same time.

According to one embodiment of the invention, it is provided that the telegrams are assigned a number of priority levels during the evaluation.

1. 1. M16/Unconditional Emergency Stop
2. 2. M39/Acknowledgement of termination
3. 3. M45/Assignment of coordinate system
4. 4. M3/Movement Authority
5. 5. M33/MA with Shifted Location Reference
6. 6. M24/General Message
7. 7. M15/Conditional Emergency Stop
8. 8. M8/Acknowledgement of Train Data
9. 9. M32/RBC/RIU System Version
10. 10. M2/SR Authorisation
11. 11. M34/Track Ahead Free Request
12. 12. M40/Train Rejected
13. 13. M41/Train Accepted
14. 14. M9/Request to Shorten MA
15. 15. M6/Recognition of exit from TRIP mode
16. 16. M18/Revocation of Emergency Stop
17. 17. M27/SH Refused
18. 18. M28/SH Authorised
19. 19. M43/SoM position
20. 20. M38/Initiation of
21. 21. M37/Infill MA

The priority levels advantageously make it possible for the telegrams to be easily sorted with regard to their priority. It is also possible to combine several types of telegrams into one priority level if their importance for train operation is of equal importance. For example, M3 and M33 can be managed in one priority level and M27 / M28 in one priority level. For example, the following priorities can be defined for ETCS, with the number 1 indicating the highest priority in the following list and the prioritization being reduced according to the numbering.

1. 1. M16 / Unconditional Emergency Stop
2. 2. M39 / Acknowledgment of termination
3. 3. M45 / Assignment of coordinate system
4. 4. M3 / Movement Authority
5. 5. M33 / MA with Shifted Location Reference
6. 6. M24 / General Message
7. 7. M15 / Conditional Emergency Stop
8. 8. M8 / Acknowledgment of Train Data
9. 9. M32 / RBC / RIU system version
10. 10. M2 / SR authorization
11. 11. M34 / Track Ahead Free Request
12. 12. M40 / Train Rejected
13. 13. M41 / Train Accepted
14. 14. M9 / Request to Shorten MA
15. 15. M6 / Recognition of exit from TRIP mode
16. 16. M18 / Revocation of Emergency Stop
17. 17. M27 / SH Refused
18. 18. M28 / SH Authorized
19. 19. M43 / SoM position
20. 20. M38 / Initiation of
21. 21. M37 / Infill MA

According to one embodiment of the invention, it is provided that if there are several telegrams with the lowest priority level, the oldest one is discarded.

This advantageously provides an additional decision aid that intervenes if a decision to delete telegrams of the lowest priority level is required. In this case it is assumed that older telegrams are more likely to be out of date than younger telegrams, whereby this corresponds to the procedure according to the ETCS standard.

• bei einem Übergang des Fahrzeugs von einem andern Level nach Level 2 und/oder
• bei einem Übergang des Fahrzeugs von einem anderen Level nach Level 3 und/oder
• bei einem Übergang des Fahrzeugs zwischen zwei Steuerzentralen, insbesondere einem RBC-RBC Handover,

durchgeführt wird.According to one embodiment of the invention it is provided that the method is used in ETCS and

• when the vehicle changes from another level to level 2 and / or
• when the vehicle transitions from another level to level 3 and / or
• when the vehicle passes between two control centers, in particular an RBC-RBC handover,

is carried out.

These are advantageously operating conditions in which the prioritization of telegrams can be used so that a smooth transition can take place. In particular, in the event of a transition from level 0 or 1 or NTC to ETCS level 2, a movement authority is required to prevent emergency braking. In the example given above, this is specified with a prioritization of 4 and is therefore normally retained.

The stated object is alternatively achieved according to the invention with the initially specified subject matter (route control center) in that the route control center has a mirror buffer memory, the mirror buffer memory having storage locations for telegrams to be transferred or transferred.

Thus, according to the invention, the line control center is equipped with the hardware and software requirements to carry out the above-mentioned method. For this purpose, the storage spaces must be available in a certain number (preferably three) so that a mirror buffer can be operated in the line control center.

• für Züge individuell Speicherplätze in der bestimmten Anzahl in dem Spiegelspeicherpuffer zu reservieren,
• und in der Streckenzentrale entweder ein zu übergebendes Telegramm in einen freien Speicherplatz zu schreiben, wenn die bestimmte Anzahl von übergebenen Telegrammen noch nicht erreicht ist,
• oder, wenn die bestimmte Anzahl von übergebenen Telegrammen erreicht ist, in der Streckenzentrale in einem Bewertungsschritt die übergebenen Telegramme und insbesondere zusätzlich auch das zu übergebende Telegramm zu priorisieren, und das Telegramm mit der geringsten oder einer geringeren Priorität zu verwerfen.

According to one embodiment of the invention it is provided that it is set up to

• to reserve the specific number of memory spaces for trains individually in the mirror memory buffer,
• and either to write a telegram to be transferred to a free memory location in the line control center if the specific number of transferred telegrams has not yet been reached,
• or, when the specific number of transmitted telegrams has been reached, prioritize the transmitted telegrams and in particular also the telegram to be transmitted in an evaluation step in the line control center, and discard the telegram with the lowest or lower priority.

It is advantageous if the line control center can hold the individually allocated memory spaces for several trains at the same time. For this purpose, the mirror buffer storage powder has sufficient storage space so that several sets of storage spaces can be kept free in the specific number. Each set of memory locations is then assigned to a vehicle during operation.

Furthermore, a computer program product with program instructions for carrying out the mentioned method according to the invention and / or its exemplary embodiments is claimed, the method according to the invention and / or its exemplary embodiments being able to be carried out by means of the computer program product.

In addition, a provision device for storing and / or providing the computer program product is claimed. The provision device is, for example, a data carrier that stores and / or provides the computer program product. Alternatively and / or additionally, the provision device is, for example, a network service, a computer system, a server system, in particular a distributed computer system, a cloud-based computer system and / or virtual computer system, which the computer program product preferably stores and / or provides in the form of a data stream.

The provision takes place, for example, as a download in the form of a program data block and / or command data block, preferably as a file, in particular as a download file, or as a data stream, in particular as a download data stream, of the complete computer program product. This provision can, for example, also take place as a partial download, which consists of several parts and is downloaded in particular via a peer-to-peer network or made available as a data stream. Such a computer program product is read into a system, for example, using the supply device in the form of the data carrier and executes the program commands so that the method according to the invention is executed on a computer or the creation device is configured in such a way that it generates the workpiece according to the invention.

Further details of the invention are described below with reference to the drawing. The same or corresponding drawing elements are each provided with the same reference numerals and are only explained several times insofar as there are differences between the individual figures.

The exemplary embodiments explained below are preferred embodiments of the invention. In the exemplary embodiments, the described components of the embodiments each represent individual features of the invention which are to be considered independently of one another and which make up the invention in each case also independently of one another and are therefore to be regarded as part of the invention individually or in a combination other than the one shown. Furthermore, the described embodiments can also be supplemented by further features of the invention that have already been described.

FIG 1

ein Ausführungsbeispiel der erfindungsgemäßen Streckenzentrale während der Ausführung eines Ausführungsbeispiels des erfindungsgemäßen Verfahrens, schematisch,

FIG 2

ein Ausführungsbeispiel des erfindungsgemäßen Verfahrens, welches durch die Steuerzentrale gemäß FIG 1 durchgeführt werden kann, als Ablaufdiagramm.

Show it:

FIG 1

an embodiment of the line control center according to the invention during the execution of an embodiment of the method according to the invention, schematically,

FIG 2

an embodiment of the method according to the invention, which by the control center according to FIG 1 can be done as a flow chart.

In FIG 1 two route control centers RBC1, RBC2 are shown, which carry out an exemplary embodiment of the method according to the invention. The route centers RBC1, RBC2 control a route ST on which vehicles FZ1, FZ2 travel in the form of two traffic trains. In doing so, these different route sections STA1, STA2, STA3 pass. The first route section STA1 is controlled by the route control center RBC1, while the second route section STA2 is controlled by the second route control center RBC2. The route control centers RBC1, RBC2 implement the ETCS standard for train communication at level 3 L3 (ETCS stands for European Train Control System). On the third line section STA3, ETCS is only available at level 0 L0.

In the route control centers RBC1, RBC2 computers CP1, CP2 are provided, which take over the tasks of automatic train control. In the vehicles FZ1, FZ2 control devices SG1, SG2 are available, which are equipped to carry out an automatic train control operation according to the ETCS standard. For the purpose of automatic train control, the first line control center RBC1 and the second communicate Route control center RBC2, the first vehicle FZ1, the second vehicle FZ2 and possibly other vehicles (not shown) with one another via the interfaces S1 ... S4, as will be explained in more detail below.

The control units SG1, SG2 in the vehicles FZ1, FZ2 each have a buffer memory PS1, PS2, in each of which three memory locations SP1, SP2, SP3 for telegrams T1 ... T4 transferred within the automatic train control system (see Fig FIG 2 ) are provided.

In the route control centers RBC1, RBC2 computers CP1, CP2 are used, with the help of which the automatic train control system is operated. The computers CP1, CP2 also provide storage space, this being used in each case as the first mirror buffer memory SPS1 in the computer CP1 and as the second mirror buffer memory SPS2 in the computer CP2. Storage locations SP1 ... SP6 are also provided in the mirror buffer memories SPS1, SPS2, into which telegrams T1 ... T4 (cf. FIG 2 ) can be written. Examples are in FIG 1 in each of the mirror buffer memories SPS1, SPS2 six memory locations SP1 ... SP6 are shown, which, for example, according to the ETCS standard, would range for two vehicles FZ1, FZ2 in the respective route section STA1 ... STA3. Of course, the computers CP1, CP2 also offer sufficient storage capacity for additional storage locations (not shown), so that more than two vehicles can also be checked in the relevant route section. Alternatively, the computers can also have several mirror buffers, one mirror buffer for each train.

For the first vehicle FZ1, which is traveling in the direction of RI1 on the route ST, in FIG 1 an RBC-RBC handover is shown. Train control is transferred from the route control center RBC1 in the route section STA1 to the route control center RBC2 in the route section STA2. During the illustrated journey of the first vehicle FZ1 on the first route section STA1, the first vehicle FZ1 communicates with the first route control center RBC1 via the third interface S3. Among other things, telegrams that are important for train operation are sent from the first line control center RBC1 to the first vehicle FZ1 and are stored in the memory locations SP1 ... SP3 of the first buffer memory PS1. The same telegrams are also stored in the memory locations SP1 ... SP3 of the first mirror buffer memory SPS1 in the computer CP1.

How to FIG 2 will be explained in more detail, however, different rules apply to the storage of the telegrams in the first mirror buffer memory SPS1 than in the first buffer memory PS1. While according to the ETCS standard in the first buffer memory PS1 the oldest telegram is overwritten by the current telegram to be saved as soon as all storage locations SP1 ... SP3 are occupied, the storage locations SP1 ... SP3 become the telegram with the smallest Priority deleted when a new telegram is to be saved in the first mirror buffer memory SPS1. In the event of a change (transition or handover) time, it must be ensured that the telegrams that are important for the onward journey are stored with high priority in the first buffer memory PS1. This can be ensured in two ways.

According to the invention, all three telegrams stored in the memory locations SP1 ... SP3 of the first mirror buffer memory SPS1 are sent via the third interface S3 to the first vehicle FZ1 when a new telegram has been written to the first mirror buffer memory SPS1. This deletes all three older telegrams from the storage locations SP1 ... SP3 in the first buffer memory PS1 of the first vehicle FZ1, which ensures that the high-priority telegrams stored in the first mirror buffer memory SPS1 are also stored in the first buffer memory PS1.

Another example according to FIG 1 is the transition of the second vehicle FZ2, which is traveling in one direction RI2, this changing from the route section STA3 with ETCS level 0 to the second route section STA2 with ETCS level 3. It is therefore a level transition. Even with this, the smooth operation of the second vehicle FZ2 is only guaranteed if important, ie high-priority telegrams are available in the second route section STA2. These are therefore transferred in the manner described for the first vehicle FZ1 via the fourth interface S4 from the second mirror buffer memory SPS2 in the second route control center RBC2 to the second buffer memory PS2 of the second vehicle FZ2. Here, too, it is ensured that this always happens when telegrams are overwritten in one of the memory locations SP1 ... SP3 of the second mirror buffer memory SPS2.

The telegrams required for this are thus available in the second vehicle FZ2 when driving through the second route section STA2, which is operated at ETCS level 3. It should be noted that the second line control center RBC2 also remains responsible in the second line section STA2. Although this is in FIG 1 As explained above, however, a situation would also be conceivable in which an RBC-RBC handover and a level transition coincide, ie a change from one route section to another takes place, with different route control centers being responsible for both route sections and the Route sections also differ in level with regard to their operating mode.

In FIG 2 the process sequence is shown as an example for the first line control center RBC1. It should be noted, however, that the method in the second line control center RBC2 works analogously.

After the start of the procedure, which is initiated shortly before a level transition or an RBC-RBC handover, a distinction must be made between the alternatives A1 and A2 in step 1 of the procedure. The alternative A1 is present, the method has just started, in which case the first buffer memory PS1 is still empty.

If any telegram T1 is to be transferred according to alternative A1, the decision is made in step 2 whether all storage locations SP1 ... SP3 (cf. FIG 1 ) are occupied in the first mirror buffer memory SPS1. If this isn't the If so, in a step 3 the telegram T1 is transferred to the first mirror buffer memory SPS1 and also to the first buffer memory PS1 of the first vehicle FZ1 (cf. FIG 1 ) transfer. To the left of step 3 it is shown which memory constellations can thus result in the memory locations SP1... SP3 both in the first buffer memory PS1 and in the first mirror buffer memory SPS1. Accordingly, one, two or three of the storage locations SP1 ... SP3 are occupied. This applies in the same way to the next two telegrams T2 and T3. For a fourth telegram T4 and other telephones (T5, T6, etc., not shown), alternative A2 of the method, which is described in more detail below, is run through.

If from the fourth telegram T4 in step 2 the result is that all memory locations of the first mirror buffer memory SPS1 are already occupied, then in step 4 the telegrams already stored and the telegram currently to be transmitted are prioritized. These are telegrams T1 ... T4. After the prioritization step, it can thus be decided which three telegrams of telegrams T1 ... T4 have the highest priority (in the following it is assumed as an example that the telegram currently to be transmitted is T1 - but the quality of the process does not change if a another telegram is currently to be transmitted).

In a step 5 it is queried whether the telegram T1 currently to be transmitted has been deleted. If this is the case, no further action is necessary. If this is not the case, however, step 6 is carried out, the three relevant telegrams T1 ... T4 being written to the memory locations SP1 ... SP3 of the first mirror buffer memory SPS1 and the buffer memory PS1. The most relevant (ie the highest prioritized) telegrams for a further journey are thus stored in the buffer memory PS1 of the first vehicle FZ1 and the same telegrams are stored in the first mirror buffer memory SPS1 in order to be able to carry out a prioritization again in a subsequent step 4.

Step 5 is not absolutely necessary. Even if the current telegram T1 to be transmitted has been deleted, telegrams T2, T3 and T4 can be transmitted without a query, since these are the most relevant telegrams, which, however, are also stored in the first mirror buffer memory SPS1 and first buffer memory before this storage step PS1 templates.

In a step 7 it is checked whether the RBC-RBC transition or a level transition to level 2 or to level 3 has been completed (DONE?). If this is not the case, the procedure is repeated for the next transmitted telegram, with the line control center RBC1 generating the next required telegram T1. As long as memory locations SP1 ... SP3 are still free, the next process cycle is processed according to alternative A1. If all storage locations SP1 ... SP3 are already occupied, this is indicated in step 1 by the alternative A2. In this case, only the telegram T4 is added as an example, whereby the query according to step 2 leads to step 4, since all memory locations SP1 ... SP3 are already occupied. This naturally also applies analogously to all further telegrams T5, T6 ..., even if this is not shown in FIG.

List of reference symbols

ST

route

STA1 ... STA3

Route section

FZ1 ... FZ2

vehicle

RI1 ... RI2

direction

SG1 ... SG2

Control unit

T1 ... T4

telegram

RBC1 ... RBC2

Route control center (Radio Block Center)

CP1 ... CP2

computer

PS1 ... PS2

Buffer storage

SPS1 ... SPS2

Mirror buffer

SP1 ... SP6

Storage space

S1 ... S4

interface

L3

Level 3 (ETCS)

L2

Level 2 (ETCS)

1 ... 7

step

Claims (14)

Method for the transfer of telegrams (T1 ... T4) from a route control center (RBC1 ... RBC2) of a train control system to a control device (SG1 ... SG2) of a vehicle (FZ1 ... FZ2), the control device (SG1. ..SG2) has a buffer memory (PS1 ... PS2) with storage locations (SP1 ... SP6) for a certain number of received telegrams (T1 ... T4),
characterized,
that the route control center (RBC1 ... RBC2) has a mirror buffer memory (SPS1 ... SPS2), whereby • Memory spaces (SP1 ... SP6) are reserved for the vehicle (FZ1 ... FZ2) in the specified number in the mirror memory buffer (SPS1 ... SPS2), • and in the line control center (RBC1 ... RBC2) either a telegram to be transferred (T1 ... T4) is written to a free memory location (SP1 ... SP3) if the specified number of telegrams that have already been transferred (T1 ... .T4) has not yet been reached, whereby the telegram to be transferred (T1 ... T4) is transferred to the control unit (SG1 ... SG2) of the vehicle (FZ1 ... FZ2), • or, if the certain number of already transferred telegrams (T1 ... T4) is reached, in the line control center (RBC1 ... RBC2) in an evaluation step the transferred telegrams (T2 ... T4) and in particular additionally also the transmitted telegram (T1) are prioritized, and the telegram (T1 ... T4) with the lowest priority is discarded, whereby all telegrams stored in the memory locations (SP1 ... SP3) of the mirror buffer memory (SPS1 ... SPS2) are sent to the Control unit (SG1 ... SG2) of the vehicle (FZ1 ... FZ2). Method according to claim 1,
characterized,
that in the control unit (SG1 ... SG2) • Either the transferred telegram (T1 ... T4) is written to a free memory location (SP1 ... SP3) of the buffer memory (PS1 ... PS2) if the certain number of received telegrams (T1 ... T3) is still available is not reached, • or the oldest of the telegrams already received (T1 ... T3) is deleted from the memory location (SP1 ... SP3) of the buffer memory (PS1 ... PS2) when the specific number of telegrams received (T1 ... T3 ) is reached, and instead of the deleted telegram (T1 ... T3) the transferred telegram (T4) is written into the free memory location (SP1 ... SP3). Method according to one of the preceding claims,
characterized,
that only then all telegrams (T1 ... T4) stored in the memory locations (SP1 ... SP3) of the mirror buffer memory (SPS1 ... SPS2) are sent to the control unit (SG1 ... SG2) of the vehicle (FZ1 ... FZ2 ) if at least one of the memory locations (SP1 ... SP6) of the mirror buffer memory (SPS1 ... SPS2) has been rewritten after the evaluation step. Method according to one of the preceding claims,
characterized,
that the telegrams (T1 ... T4) are assigned a number of priority levels when evaluating. Method according to claim 4,
characterized,
that if there are several telegrams (T1 ... T4) with the lowest priority level, the oldest of them is discarded. Method according to one of the preceding claims,
characterized,
that the definite number is three. Method according to one of the preceding claims,
characterized,
that ETCS is used as the train control system. Method according to claim 7,
characterized,
that the procedure • when the vehicle (FZ1 ... FZ2) changes from another level to level 2 (L2) and / or • when the vehicle (FZ1 ... FZ2) changes from another level to level 3 (L3) and / or • when the vehicle (FZ1 ... FZ2) passes between two control centers, in particular an RBC-RBC handover, is carried out. Method according to one of the preceding claims,
characterized,
that telegrams (T1 ... T4) with the same prioritization are grouped together when prioritizing. Route control center (RBC1 ... RBC2) of a train control system, which is set up to send telegrams (T1 ... T4) to a
To hand over the control unit (SG1 ... SG2) of a vehicle (FZ1 ... FZ2),
characterized,
that the line control center (RBC1 ... RBC2) has a mirror buffer memory (SPS1 ... SPS2),
The mirror buffer memory (SPS1 ... SPS2) has storage locations (SP1 ... SP6) for telegrams to be transferred or transferred (T1 ... T4). Route control center (RBC1 ... RBC2) according to claim 10,
characterized,
that this is set up to • to reserve individual memory spaces (SP1 ... SP6) in the specific number in the mirror memory buffer (SPS1 ... SPS2) for trains, • and in the line control center (RBC1 ... RBC2) either to write a telegram to be transferred (T1 ... T4) to a free memory location (SP1 ... SP3) if the certain number of transferred telegrams (T1 ... T3) has not yet been reached, • or, when the certain number of transmitted telegrams (T1 ... T3) is reached, the transmitted telegrams (T1 ... T3) and in particular also the one to be transmitted in the line control center (RBC1 ... RBC2) in an evaluation step Telegram (T4) closed prioritize and discard the telegram (Tl ... T4) with the lowest priority. Route control center (RBC1 ... RBC2) according to one of claims 10 or 11,
characterized,
that the line control center (RBC1 ... RBC2) is set up to carry out a method according to one of claims 1-11. Computer program product with program instructions for carrying out the method according to one of Claims 1-9. 13. Provision device for the computer program product according to claim 13, wherein the provision device stores and / or provides the computer program product.

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