WO2024041940A1 - Transmission of data blocks using an intermediate storage process - Google Patents

Abstract

The invention relates to a method (100) for transmitting files (D) between a stationary communication participant (12) and a mobile communication participant (14). In the process, the file (D) is divided (102) into multiple data blocks (B) which are distributed (104) to different storage devices (18) arranged in a decentralized manner according to at least one parameter relating to the mobile communication participant (14). In order to transmit the file (D), the plurality of data blocks (B) belonging to the file (D) are transmitted (106) between the mobile communication participant (14) and specified storage devices (18). Alternatively or in addition thereto, the data blocks (B) are transmitted (108) between the stationary communication participant (12) and specified storage devices (18).

Description

Description

Transmission of data blocks using buffer storage

The invention relates to a method for transmitting a file between a mobile communication subscriber and a stationary communication subscriber, as well as a communication system for carrying out the method. Furthermore, the invention relates to a computer program and a computer-readable medium.

When transmitting data between a mobile communication subscriber and a stationary communication subscriber, from a technical point of view, the amount of data to be transmitted is essentially limited by the available data transmission speed. In addition, in order to avoid overloading a mobile radio network, a maximum possible amount of data to be transmitted is specified. If this amount of data is exceeded, large costs usually arise. The aforementioned restrictions become particularly relevant in the case of communication between a land-based system and a vehicle fleet consisting of a large number of vehicles. This often involves transferring the same file from the land-based system to the individual vehicles. Furthermore, various types of data must be continuously transmitted from the individual vehicles to the land-based system. However, depending on the location or distance traveled by the individual vehicles, data transmission speeds can sometimes vary greatly. On the one hand, this leads to inefficient consumption of the maximum amount of data available. On the other hand, there is the problem that the number of vehicles and the amount of data to be transmitted is constantly increasing. In order to still enable reliable data transmission, resources for the purpose of data transmission have so far been adapted according to the existing requirements. However, the heavy load on mobile networks in this way poses the risk of interruptions the communication connection or severe delays in the transfer of files.

The object of the invention is to enable improved transmission of files between a mobile and a stationary communication subscriber.

This task is solved by a method according to the features of independent claim 1. In addition, this task is solved by a communication system with the features of the secondary system requirement.

A further object of the invention is to provide a computer program and a computer-readable medium.

This task is solved by a computer program according to the features of independent claim 14 and by a computer-readable medium according to the features of independent claim 15.

Further advantageous developments are the subject of dependent subclaims.

The method according to the invention for transmitting a file between a mobile communication subscriber and a stationary communication subscriber provides for the file to be transmitted to be divided into several data blocks. These multiple data blocks are distributed to various decentralized storage devices in accordance with at least one parameter relating to the mobile communication subscriber. For the purpose of transmitting the file, the several data blocks belonging to this file are transmitted between the mobile communication subscriber and predetermined storage devices. Alternatively or additionally, for the purpose of the transferring file, the several data blocks belonging to this file are transferred between the stationary communication subscriber and predetermined storage devices. In the present context, the storage device mentioned is a data storage in the sense of information technology. In particular, the data memory is set up so that digital data can be written to it or digital data can be read from it. For example, the storage device is a solid-state memory or a flash memory. In a preferred embodiment variant, the storage device mentioned is part of a data processing device. This data processing device is preferably set up to store, read, write, transmit and/or manage data. The data processing device can be, for example, a computer, a microcontroller or a comparable programmable hardware component with the storage device mentioned.

The parameter mentioned can, for example, relate to stopping points along a predetermined route, a property such as membership in a vehicle fleet, or an operating status of the mobile communication subscriber.

In this way, technical requirements for a communication network can be kept low. The transmission of data blocks between the stationary communication subscriber and the storage devices can be realized using a low data transmission speed. In addition, a transmission between the mobile communication subscriber and a storage device and between the storage device and the stationary communication subscriber can be decoupled from one another in time. Furthermore, an appropriate choice of the parameter makes it possible to further improve the efficiency of the file transfer. In addition, an easily customizable process can be provided.

An advantageous development provides that the multiple data blocks of the file are distributed to predetermined ones of the storage devices mentioned according to an attribute of this file become . The file attribute mentioned can be, for example, a type of content, a number of data records, a number of data records per data record type, a creator of the file, an origin of the file, a size of the file, a predetermined group of recipients, a priority or a predetermined file type. The type of content of a file mentioned can be, for example, advertising data, media data, process data, service data, maintenance data, communication data, timetable data, vehicle data or log data. In this way, a process for file transfer that can be adapted in a variety of ways and with little effort can be provided. By selectively distributing the files based on their properties, an ef fi cient use of available storage space can be achieved. In particular, there is no need for a blanket distribution of all files to be transferred to all storage devices.

Furthermore, an advantageous development provides that the multiple data blocks are distributed to predetermined storage devices mentioned in accordance with location information relating to the mobile communication subscriber. The location information mentioned can be a GPS signal or information determined based on sensors or IP addresses. In this way, reliable and ef fi cient data transmission can be achieved. This makes it possible to always select the nearest storage location and thus a high transmission quality for the purpose of file transfer. Furthermore, a transfer of the file from the storage devices mentioned to the mobile communication subscriber can be achieved largely independently of an external mobile radio network using local communication connections. A locally varying connection quality of the external mobile network is therefore of minor importance. Furthermore, this makes it possible to transmit the data blocks at a very high data transmission speed. In addition, roaming fees due to data transmission across national borders can be avoided.

Furthermore, an advantageous development provides that the multiple data blocks are distributed to predetermined ones of the storage devices mentioned in accordance with an event plan relating to the mobile communication subscriber. In the present context, the event plan mentioned is understood to be a plan in which tasks, operating states or other events affecting the mobile communication subscriber are described depending on a schedule. Such an event plan can be, for example, a timetable, a maintenance plan or an inspection plan. Using the event plan, a simple and reliable division of the data blocks can be planned at low cost. In particular, this makes it possible to easily use advantageous locations and longer downtimes for the purpose of transmitting data blocks. A transmission of data blocks during a movement of the mobile communication subscriber can thus advantageously be avoided.

Furthermore, an advantageous development provides that for the purpose of transferring the file from the stationary communication subscriber to the mobile communication subscriber, at least one data block of the plurality of data blocks is transmitted to various of the storage devices mentioned. In this way, a high level of operational reliability can be provided. For example, if a storage device fails or cannot be reached, the data block to be transferred can still be requested and downloaded from another storage device.

In a further advantageous development, it is provided that for the purpose of transmitting the file between the mobile communication subscriber and the stationary communication subscriber, assignment information regarding the storage locations of the data blocks is transmitted. For example The assignment information contains a list by means of which a storage location is linked to a data block stored at this storage location. In this way, an overview of the distributed data blocks can be provided in a cost-effective manner.

An advantageous embodiment variant provides that the data blocks of the file to be transmitted, downloaded by the mobile communication subscriber or the stationary communication subscriber from the various storage devices, are put together on the basis of the assignment information. A complex, usually error-prone search for data blocks that belong together in a file or a compilation of the data blocks based on identification parameters can simply be dispensed with.

A further advantageous embodiment variant provides that a complete transmission of all data blocks belonging to a file is verified on the basis of the assignment information. In this way, operational reliability can be further increased. In particular, a largely error-free file transfer can be provided in this way. Furthermore, a checksum can be easily determined using the assignment information or one can already be transmitted. In this way, a cost-effective completeness check can be implemented.

A further advantageous development provides that receipt of all data blocks belonging to a file is confirmed by transmitting an acknowledgment of receipt. This makes it possible to make efficient use of limited storage space. For example, upon confirmation of receipt, taking into account further specifications, cached data blocks can be deleted and thus an occupied storage space can be released. The method according to the invention can be carried out using the communication system according to the invention.

The communication system according to the invention has a mobile communication subscriber and a stationary communication subscriber. Furthermore, the communication system according to the invention has a data processing system with several decentrally arranged storage devices. The storage devices mentioned are in particular storage devices of the type already described previously in connection with the method according to the invention. The storage devices mentioned are further connected to the stationary communication subscriber by means of a network connection. Furthermore, data blocks of a file can be transferred from the stationary communication subscriber to the mobile communication subscriber by means of the various storage devices.

This communication system makes it possible to achieve reliable and rapid file transfer. By temporarily storing the data blocks on different storage devices, the network connection mentioned can be relieved. A load of data to be transferred can be distributed evenly over a specified period of time. In addition, data transmission can take place using the network connection mentioned using a low data transmission speed.

An advantageous development of the communication system provides that the mobile communication subscriber is designed as a vehicle. In particular, the vehicle is designed as a rail-bound vehicle. Common problems with mobile data transmission, such as connection interruptions or weak data transfer rates in mobile networks, can be overcome easily and inexpensively. Furthermore, a reliable and cost-effective transfer of files can be made possible. Furthermore, an advantageous development of the communication system provides that the storage devices are arranged along a predetermined route of the mobile communication subscriber. For example, storage devices are arranged at stops, maintenance depots and/or a marshalling yard. This makes it possible to provide and utilize high transmission quality at the intended locations of the mobile communication subscriber. In particular, data loss or inefficient use of an available data volume, for example due to connection interruptions, can be avoided. Furthermore, it is conceivable that storage devices are arranged at predetermined distances along the said path.

A further advantageous development of the communication system provides that the storage devices are each part of a data processing device arranged at the location of the respective storage device. By means of the data processing device, for example, a separate local communication network can be provided. In addition, a direct connection of the storage device to a data processing device enables rapid transmission of data blocks. Furthermore, this makes it possible to provide high reliability and high operational security when transmitting data blocks.

Furthermore, according to the invention, a computer program is provided which comprises commands which, when the computer program is executed by a data processing device, cause the communication system according to the invention to carry out the method according to the invention. The data processing device mentioned is in particular the data processing device already described above.

The invention further provides a computer-readable medium. This has instructions which, when executed by a data processing device, implement the invention Cause the communication system to carry out the method according to the invention. The data processing device mentioned is in particular the data processing device already described above. The computer-readable medium can be, for example, a CD-ROM, a DVD, a USB or flash memory or a non-physical medium such as a data stream and/or a data carrier signal.

The properties, features and advantages of the invention described above and the way in which these are achieved are explained in more detail in connection with the figures in the following description of the embodiments of the invention. Where appropriate, the same reference symbols are used in the figures for the same or corresponding elements of the invention. The exemplary embodiment and variations thereof described serve to explain the invention and do not limit the invention to the combinations of features specified therein, not even with regard to functional features. In addition, all of the features specified in the exemplary embodiment can be viewed in isolation and suitably combined with the features of any claim.

Show it :

1 shows a schematic illustration of a first variant of an example of a method for transmitting data blocks of a file from a landside to a vehicle;

2 shows a schematic illustration of a second variant of the example of the method for transmitting data blocks of a file from the vehicle to the landside;

3 shows an exemplary embodiment of a communication system, by means of which the in FIGS. 1 and 2 illustrated tered variants of the example of the method can be carried out.

1 shows a first variant of an example of a method 100 for transmitting a file D between a landside 12 and a vehicle 14 in the form of a schematic flowchart. The example of the method 100 can be carried out using the communication system 10 shown in FIG. 3. The variant of the example of the method 100 described in connection with FIG. 1 relates to the transmission of a file D starting from the landside 12 to the vehicle 14.

The file D to be transferred is divided 102 into several data blocks B. It is conceivable that an event plan of the vehicle 14 is taken into account in the division 102. For example, the size of a data block B can be adjusted based on a predicted length of stay at a predetermined location. The data blocks B mentioned are then distributed 104 to various decentrally arranged storage devices 18 in accordance with a parameter relating to the vehicle 14.

In the aforementioned distribution 104 of the data blocks B, stopping points of the vehicle 14 along a route 22 intended for this vehicle 14 are initially used as parameters in the present case. In this way, the data blocks B to be transmitted are distributed 104 to those storage devices 18 which spatially coincide with stopping points of the vehicle 14. Alternatively or additionally, properties of the vehicle 14, such as membership in a vehicle fleet or a customer group, or an operating state, which relates, for example, to a break, ferry service or maintenance, can be used as parameters for the distribution 104 mentioned. If data blocks B of several files D to be transferred are to be distributed 104, the data blocks B are distributed according to an attribute of a respective file D distributed 104 to the storage devices 18 selected according to the aforementioned parameter. In the example described here, the attribute used is a relevance of the file D to be transferred. In this way, data blocks B of a file D, which is assigned a high relevance, are distributed to storage devices 18 along the route 22 which are arranged at the beginning of this intended route 22. In contrast, data blocks B of a file D, which is assigned a low relevance, are distributed 104 to storage devices 18, which are arranged in the middle or late course of the route 22. In addition, in the example of the method 100 described here, the data blocks B to be transmitted are distributed 104 to the storage devices 18 mentioned on the basis of a timetable relating to the vehicle 14. In this way, a holding period and thus a possible transmission time between a storage device 18 and the vehicle 14 can be taken into account. If, for example, a longer period of time for the vehicle 14 to stay at a predetermined stop 24 is envisaged, a larger number of data blocks B or a larger amount of data intended for the vehicle 14 can be stored on this storage device 18. If, on the other hand, only a short stay at a predetermined stop 24 is provided, then a number of stored data blocks B or a certain amount of data for this vehicle 14 can be kept low. Alternatively or additionally, a maintenance plan can be used for the purpose of distributing 104 the data blocks B to the storage devices 18 mentioned. Typically, a stay of the vehicle 14 in a maintenance depot 26 is of a longer duration, whereby a large number of data blocks B and/or a large amount of data can be transferred 106 from a storage device 18 arranged in the maintenance depot 26 to the vehicle 14.

For the purpose of a reliable transmission of the file D, the present example of the method 100 further provides that individual data blocks B are transferred 108 from the landside 12 to several of the different storage devices 18. In this way, it can be prevented that an opportunity to transmit 106 a data block B from a storage device 18 to the vehicle 14 is missed. If, for example, a communication connection between a storage device 18 and the vehicle 14 is terminated or aborted before a successful transmission 106 of the data block B, the vehicle 14 has the option of downloading 106 this data block B from another storage device 18.

Furthermore, assignment information Z is created by the land side 12, by means of which the distribution 104 of the data blocks B to the various storage devices 18 is documented and which is transmitted 116 to the vehicle 14. This assignment information Z contains information regarding the storage locations of the data blocks B. In this way, it is possible for the vehicle 14 to assign the 106 data blocks B, which are initially randomly read from various storage devices 18 by the vehicle 14, to a file D to be transmitted in a cost-effective manner. Using the assignment information Z, the file D to be transmitted is assembled 110 in the vehicle 14. Furthermore, as part of the example of method 100 described here, a checksum is transmitted 116 with the assignment information Z. This enables the vehicle 14 to verify 112 whether a complete transfer 106 of all data blocks B belonging to a file D has taken place from the storage devices 18 to the vehicle 14. As soon as the completeness has been verified 112, an acknowledgment of receipt is transmitted to the landside 12 by the vehicle 14 in order to confirm 114 that the file D has been received in full. By means of such an acknowledgment of receipt 114, the landside 12 is enabled to remove data blocks B from the storage devices 18. In this way, storage space can be freed up for additional data blocks B of other files D to be transferred.

2 shows a second variant of the example of the method 100, in which a file D is transferred from the vehicle 14 to the Land side 12 is transmitted. In contrast to the first variant of the example of method 100 described in connection with FIG. 1, the transmission of a file D takes place in the opposite direction.

As described above, the file D to be transferred is first divided 102 into several data blocks B. In contrast to the previously described variant of the method 100, the multiple data blocks B of the file D to be transferred are distributed 104 to the storage devices 18 in accordance with a location of the vehicle 14. The aforementioned distribution 104 takes place by changing the location of the vehicle 14. As soon as the vehicle 14 approaches a storage device 18, this is transferred 106 from the vehicle 14 to the storage device 18 for the purpose of transmitting at least one data block B. In addition, it is conceivable that an event plan of the vehicle 14 is taken into account in the distribution 104, so that in addition to a spatial proximity between the vehicle 14 and the storage device 18, an intended length of stay in the distribution 104 can be taken into account.

As already described in connection with FIG. 1, the distribution 104 takes place in the case of several files D to be transmitted from the vehicle 14 to the landside 12 according to a relevance of the respective file D. Alternatively or additionally, further attributes of a file, such as a file type or a type of content of the file, can be taken into account in the distribution 104. Furthermore, as already described in connection with FIG. 1, an event plan of the vehicle 14 can be taken into account when dividing 102 the data blocks B. By way of example, a timetable and a maintenance plan of the vehicle 14 can be used for the purpose of dividing the file D into data blocks B as required. Afterwards, data blocks B can be transferred 106 to this storage device 18 depending on the intended length of stay of the vehicle 14 at a storage device 18. After a data block B has been successfully transferred 106 from the vehicle 14 to a storage device 18, the vehicle 14 documents a storage location of the data block B and associates it with the storage device 18. In this way, the vehicle 14 creates assignment information Z. As soon as all data blocks B of a file D to be transferred have been transferred 106 to storage devices 18, the vehicle 14 transmits this assignment information Z to the landside 12. Based on the assignment information Z, the required data blocks B are then transferred 108 between the corresponding storage devices 18 and the land side 12. As already described in connection with FIG. 1, a checksum is transmitted 116 together with the assignment information Z for the purpose of verifying 112 a complete transmission of the file D to be transmitted. If all data blocks B belonging to a file D are available, they are put together 110 based on the assignment information Z. In the present example, whether all data blocks B are present is verified 112 using the transmitted checksum. After a successful verification 112 is present, a confirmation of receipt 114 is transmitted to the vehicle 14 by the landside 12. After receiving this confirmation of receipt 114, the vehicle 14 can delete the file D to be transmitted. This makes it possible to make efficient use of limited storage space.

3 shows a schematic representation of an exemplary embodiment of a communication system 10. This communication system 10 has the aforementioned vehicle 14 as an example. This is designed, for example, as a rail-bound passenger transport vehicle. Furthermore, FIG. 3 shows the previously mentioned land page 12, which has a stationary server. Furthermore, the communication system 10 has a data processing system 16. This data processing system 16 has the previously mentioned decentralized storage devices 18. Each storage device 18 is, for example, part of a data processing system (not shown) that is arranged at the same location. processing device. Furthermore, each of the decentralized storage devices 18 mentioned is connected to the landside 12 by means of a network connection 20 for the purpose of transmitting data blocks B of a file D. In addition, the several decentrally arranged storage devices 18 are set up to transmit 106, 108 the file D to be transmitted in the form of data blocks B between the landside 12 and the vehicle 14.

Furthermore, FIG. 3 shows, by way of example, that the storage devices 18 mentioned are arranged along an intended route 22 of the vehicle 14. The storage devices 18 are placed, for example, at stops 24 and in a maintenance depot 26. In addition, it is conceivable that further storage devices 18 are arranged distributed along the route 22 at predetermined intervals in a manner not shown.

By means of the communication system 10 described by way of example in connection with FIG. 3, in particular the variants of the example of the method 100 described in connection with FIG. 1 and FIG. 2 can be carried out.

Although the invention has been illustrated and described in detail by the preferred embodiments, the invention is not limited by the disclosed examples and other variations may be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims

Patent claims

1. Method (100) for transmitting a file (D) between a stationary communication participant (12) and a mobile communication participant (14), in which

- the file (D) to be transferred is divided into several data blocks (B) (102);

- the several data blocks (B) are distributed (104) to various decentralized storage devices (18) in accordance with at least one parameter relating to the mobile communication subscriber (14);

- for the purpose of transmitting the file (D), the several data blocks (B) belonging to this file (D) are transmitted (106) between the mobile communication subscriber (14) and predetermined storage devices (18) and/or between the stationary communication subscriber (12 ) and predetermined storage devices (18) are transmitted (108).

2. Method (100) according to claim 1, in which the plurality of data blocks (B) of the file (D) are distributed (104) to predetermined ones of said storage devices (18) according to an attribute of this file (D).

3. Method (100) according to claim 1 or 2, in which the plurality of data blocks (B) are distributed (104) to predetermined ones of said storage devices (18) in accordance with location information relating to the mobile communication subscriber (14).

4. Method (100) according to one of the preceding claims, in which the plurality of data blocks (B) are distributed (104) to predetermined ones of said storage devices (18) in accordance with an event plan relating to the mobile communication subscriber (14).

5. Method (100) according to one of the preceding claims, in which for the purpose of transferring the file (D) from the stationary communication subscriber (12) to the mobile communication subscriber (14) at least one data block of the plurality of data blocks (B) is transmitted to various of the storage devices (18) mentioned (106).

6. Method (100) according to one of the preceding claims, in which, for the purpose of transmitting the file (D) between the mobile communication subscriber (14) and the stationary communication subscriber (12), assignment information (Z) relating to the storage locations of the data blocks (B) is transmitted (116).

7. Method (100) according to claim 6, in which, based on the assignment information (Z), the data blocks (B.) downloaded (106, 108) by the mobile communication participant (14) or the stationary communication participant (12) from the various storage devices (18). ) of the file to be transferred (D) are merged (110).

8. Method (100) according to claim 6 or 7, in which a complete transmission of all data blocks (B) belonging to a file (D) is verified (112) on the basis of the assignment information (Z).

9. Method (100) according to one of the preceding claims, in which receipt of all data blocks (B) belonging to a file (D) is confirmed by transmitting a confirmation of receipt (114).

10. Communication system (10) for carrying out the method (100) according to one of the preceding claims

- a stationary communication participant (12);

- a mobile communication subscriber (14);

- a data processing system (16) with several decentrally arranged storage devices (18), each of which is connected to the stationary communication by means of a network connection (20). nication participants (12) are connected and by means of which a file (D) can be transferred between the stationary communication participant (12) and the mobile communication participant (14).

11. Communication system (10) according to claim 10, characterized in that the mobile communication subscriber (14) is designed as a vehicle, in particular a rail-bound vehicle.

12. Communication system (10) according to claim 10 or 11, characterized in that the storage devices (18) are arranged along a predetermined route (22) of the mobile communication subscriber (14).

13. Communication system (10) according to one of claims 10 to 12, characterized in that the storage devices (18) are each part of a data processing device arranged at the location of the respective storage device (18).

14. Computer program which, when executed, causes the communication system (10) according to one of claims 10 to 13 to carry out the method (100) according to one of claims 1 to 9.

15. Computer-readable medium having instructions which cause the communication system (10) according to one of claims 10 to 13 to carry out the method (100) according to one of claims 1 to 9.