WO2012084029A1

WO2012084029A1 - Method for providing a data memory architecture and for transmitting data, and system

Info

Publication number: WO2012084029A1
Application number: PCT/EP2010/070505
Authority: WO
Inventors: Rene Graf; Frank Volkmann
Original assignee: Siemens Aktiengesellschaft
Priority date: 2010-12-22
Filing date: 2010-12-22
Publication date: 2012-06-28
Also published as: EP2616919A1

Abstract

The invention relates to a method for providing a data memory architecture for transmitting data from a data provision apparatus (5) to at least a first (8) and a second appliance (9), having the following steps: a) an electronically and/or optically readable data storage medium (1) is provided; b) a data memory in the data storage medium (1) is partitioned into at least a first (2a) and a second data memory part (2b); and c) a data memory part manager (3) is stipulated, so that for the purpose of reading data from the first data memory part (2a) it is possible for the first appliance (8) but not the second appliance (9) to access the first data memory part (2a). The invention also relates to a method for transmitting data and to a system having a data provision apparatus.

Description

description

Method for providing a data storage architecture and for transmitting data and system

The invention relates to a method for providing a data storage architecture for transferring data from a data delivery device to at least a first and a second device. The invention also relates to a method for transmitting data from a data providing device to at least a first and a second device. Finally, the invention also relates to a system having a data providing device, a data storage medium and at least a first and a second device.

If an automation system is configured, suitable data corresponding to the respective parts of the configuration must be loaded on different modules or parts of the system. Typically, this happens via special SD (Secure Digital) memory cards. Here, the configuration is loaded (for example, CPU, Central Processing Unit) in the form of data on the configuration computer to an SD card (for example, the Pro ^¬ ject) an assembly. This SD card is then inserted into one of the modules in a second step and the program or configuration is loaded from the SD card into the module. The project (and thus the SD card contents) is specific to each module, which means that the two steps mentioned above must be repeated individually for each module. Normally seen ^¬ that this is in each case an SD card available for each module. If this is not the case, some SD cards must be used several times, which can lead to confusion. For automation, SD cards with very small capacities are typically used in automation engineering (up to 64 MB). Consumer SD cards (for example, MP3 players, digital cameras, etc.) today offer capacities up to 2 GB (in the case of SD card) or 32 GB (in the case of SDHC cards, SDHC = Secure Digital High Capacity).

It is known to partition the memory of data storage media into individual sub-memories. On these individual

However, a device capable of reading out the data storage medium can access the partial memory without restriction. The sub-data stores appear to the reader as if they were individual data storage media.

It is an object of the invention to simplify the data transfer carried out by means of data storage media to at least two devices. This object is achieved by a method for providing a data storage architecture comprising the features of claim 1, a method for transmitting data comprising the features of claim 9, and a system having the features of claim 10.

The method according to the invention serves to provide a data storage architecture. The data storage architecture, in turn, is designed to transfer data from a data preparation device to at least a first and a second device. The method according to the invention comprises the following steps:

a) providing an electronically and / or optically readable data storage medium. The storage medium can be designed in particular for storing computer data.

b) partitioning a data memory of the Datenpeichermedi ^¬ ums in at least a first and a second partial data memory. The data storage medium may include one or more data stores. These data memories can be identical or different. In particular, the first and second partial data memories are different from one another. The partial data stores can also be called partitions. Partitioning is in particular splitting the data storage to understand such partial data storage, which are separately addressable or addressable,

c) determining a portion of data storage management, so that for reading out data from the first data memory, the first device, however, the second device can not access the first sub-data ^¬ memory. In particular, a group of devices can be provided, wherein a specific device of this group can access the first partial data memory, while all other devices of the group can not access the first partial data memory. It can be provided that the second device can access the second partial data memory, but not the first partial data memory. However, it can also be provided that both the first and the second device can access the second partial data memory. The access to the first partial data storage is thus very specific; it can only be done by the first device, but not by the second device. This is the case at least for access in the form of readout of data. The second device can not recognize all the partial data memory of the data storage medium, namely at least not the first partial data memory. On a single data storage medium so several quasi-virtual data storage in the form of partial data storage can be realized, which can be assigned to specific devices. The data storage medium can behave towards the devices as if it were two different data storage media. The first device may in appropriate circumstances will only see the first part ^¬ data storage (in the sense of an access for reading data), while the second device at least space A does not see the first Teilda-. Data can be transferred so very specific to individual devices, without more than a einzi ^¬ ges data storage medium would have to be provided.

Preferably, the provided electronically and / or optically readable data storage medium is coupled to the data delivery device for data transmission. The data providing device may then in particular transmit data to the data storage medium and / or data from it read. It can therefore access writing and / or reading. In addition, it is preferably provided that the partitioning of the data memory of the data storage medium in at least ei ^¬ nen first and a second partial data storage is performed by the data providing device. The data ^preparation device then partitions the data memory of the data storage medium coupled to the data transmission. Alternatively or additionally, it may be provided that the setting of the partial data memory management in step c) is also carried out by the data providing device. The data providing apparatus may then determine that for reading out data from the first data store, only the first device, however, the second device can not access this space A Teilda ^¬. In this way a control center within the data memory architecture is through the DA tenbereitstellungsvorrichtung quasi provided which controls the data access by appropriate configuration of individual components and also provides the data can be accessed on the supplied ^¬. This form of data management is particularly effective and ensures smooth and fast workflows.

Preferably, in step c) when setting the partial data storage management in the data storage medium, an identification logic is provided which is designed to receive and evaluate device identification data provided by the first device and to grant the first device access to the first partial data memory depending on the evaluation , In particular, access authorizations can be assigned by the identification logic. The identification logic can check these access permissions and grant devices access to individual sub-data stores. The identification logic can be implemented in particular in the form of software in the data storage medium. Already can tifikationslogik for iden- known from the prior art and usually on data storage media before ^¬ handene structures (for example copyright verification) suitably modified. Alternatively or additionally, it may be provided that takes place in particular by the data providing device, for example via a network connection, a configuration of the first and second device in such a way that these devices can be accessed respectively assigned only to them partial data memory of the data storage medium when this Since ^¬ tenspeichermedium with a the device is coupled. An identification logic does not have to be implemented in the data storage medium itself, but can be realized via the network and a central query on the data supply device.

Preferably, a device serial number is provided by the first device as device identification data. It can then be provided that this device serial number is transferred from the first device to the data storage medium with the identification logic in the identification logic, the device serial number is checked and the first device specific access to the first partial data memory is granted based on the result of the review. This form of Identitätsve ^¬ rifikation is simple, yet highly effective. The device serial number allows a unique identification of the devices, so that a confusion regarding the data intended for them is excluded.

It can be provided that the first and second device can access the sub-data memories assigned to them only by reading, but not by writing. Preferably, the partial data store management is then determined in step c) in such a way that the data providing device can access and read all partial data memories. The data delivery device then plays a central role within the data storage architecture by providing administrator-like management of the data storage medium. Data management is thereby considerably simplified. Preferably, in step b) of the data memory is partitioned into a number of partial data to ^¬ memory corresponding to the number of devices. A number x to devices present, it ^¬ followed by partitioning the data storage medium in x partial data storage. Preferably, then in step c) the partial data storage management is set such that with respect to the access for reading data, each partial data memory is assigned exactly one of the devices. Alternatively or additionally, it can be provided that exactly one partial data memory is allocated to each of the devices. Particularly preferred is a one-to-one assignment. This results in a variety of assignment options that allow a very variable design of the data storage architecture. The electronically and / or optically readable data storage medium provided in step a) may be, for example, a magnetic data storage medium (for example a floppy disk, hard disk, etc.). Preferably, however, han ^¬ delt If the data storage medium is an electronic memory chip, in particular a flash memory chip. Particularly preferred are the systems SD (Secure Digital), CF (Compact Flash) and MMC (Multimedia Card). These storage media are characterized by a very high compactness with high memory content.

A method according to the invention serves to transfer data from a data supply device to at least a first and a second device and comprises the following steps:

d) carrying out the method according to the invention for providing a data storage architecture;

e) coupling the data storage medium with the Datenbereitstel ^¬ lungsvorrichtung, transferring data from the data supply device to the data storage medium and Speeh-bred the data in the first data memory; and

f) coupling the data storage medium with the first device, accessing the first device to the first partial data memory and transferring data from the first sub-data store into the first device.

An inventive system comprises a data supply device, an electronically and / or optically readable data storage medium and at least a first and a second device. In this case, the data provision device is designed to partition a data memory of the data storage medium into at least a first and a second partial data memory and to define a partial data memory management in such a way that the first device, but not the second device, is read at first in order to read out data from the first partial data memory Can access partial data storage. The system may in particular be an automation system.

With respect to the inventive method for providing ^¬ provide a data storage architecture illustrated preferred embodiments and their advantages apply accordingly for the inventive method for transferring data, and the system according to the invention.

Further features of the invention will become apparent from the claims, the figures and the description of the figures. The features and feature combinations mentioned above in the description of the figures as well as the features and feature combinations and / or the features and feature combinations shown in the figures alone are usable not only in the respectively indicated combination but also in other combinations or in isolation, without to leave the scope of the invention.

Reference to exemplary embodiments, the invention is explained in more detail below. Show it:

FIG1 is a schematic view of an SD card with several ^¬ ren partitions; and FIG 2 is a schematic representation of the transmission of data in an automation system by means of an SD card. In the figures, identical or functionally identical elements are provided with the same reference numerals.

FIG1 shows a standard SD card 1 with a Speicherkapazi ^¬ ty of 2 GB, such as is used in the consumer sector. An idea is to simulate a plurality of virtual SD cards 2a to 2f on such a standard SD card 1. These virtual SD cards 2a to 2f may also be referred to as partial data memories or partitions. In the embodiment, each virtual SD card 2a to 2f has a memory size of 64 MB. In addition, a management logic 3 is provided which regulates the respective access to the individual virtual SD cards 2a to 2f. The SD card 1 thus has many small partitions. However, these partitions are not all visible if the card is inserted in a standard reading device.

FIG. 2 shows how, by means of a suitable data storage architecture, data can be transmitted from a data supply device in the form of a configuration computer 5 to a first and second device in the form of the modules 8 and 9. The system shown here is an automation ^¬ approximately conditioning system 4. First, a standard SD card is provided with 2 GB of storage. In a step Sl, this SD card 1 is introduced into an SD card reader 6a of the proj ectierungsrechners 5 and thus coupled with this for data ^¬ transmission. The configuration computer 5 configures the SD card 1 at first such that two Teilda ^¬ space A are applied in the form of the virtual SD card 2a and 2b on the SD card. 1 Both virtual SD cards 2a and 2b each have a storage capacity of 64 MB. Since the automation system 4 comprises only two modules 8 and 9, the configuration computer 5 on the SD card 1 also has only two virtual SD cards 2 a and 2 b. sets. This is just an example. Includes the automation ^¬ approximately technical installation 4 N different devices, the configuration computer 5 would accordingly create N virtual SD card in the SD card 1 by partitioning. The virtuel- len SD cards 2a and 2b are created by a suitable configuration tool, which is in the form of software in the configuration ^¬ computer 5 on the SD card. 1 After partitioning, the SD card 1 has as many Partiti ^¬ onen or virtual SD cards as modules in the entire automation system 4 are available.

The configuration computer 5 also creates a management logic on the SD card 1 is set to the that the construction ^¬ group 8 only may read 2a access to the virtual SD card, while the assembly 9 read exclusively to the virtual SD card 2b may access. However, for example, could also be an operator who is operating configu ^¬ approximately computer 5, specify that for example the construction ^¬ group 8 can access 2a and 2b to both the virtual SD card, while the assembly 9 only on the virtual SD card 2b can access. It is ever ^¬ but assumed in the following by a one correspondence.

In a next step, configuration data are now written by the configuration computer 5 to the virtual SD cards 2a and 2b. A first configuration data record for the configuration of the module 8 is stored on the virtual SD card 2a, while a second configuration data record for the configuration of the module 9 is stored on the virtual SD card 2b.

The thus configured SD card 1 is removed in a step S2 from the SD card reader 6a of the configuration computer 5 and it can now be a data transfer to the modules 8 and 9.

First, data is transferred to the module 8. For this purpose, the SD card 1 in the SD card reader 6b of the module. 8 pushed and coupled in this way with this module for data ^¬ transmission. Each virtual SD card 2a or 2b of the SD card 1 is now individually addressable, provided that the respective module relative to the SD card 1 can identify accordingly. The device serial number of the module 8 is suitably adjusted for this purpose via the management logic 3, so that the module 8 is granted only read access to the data of the virtual SD card 2a. For this purpose, the SD card 1 or the administration logic 3 query the device serial number of the module 8. The assembly 8 is now exactly the Parti ^¬ tion of the SD card 1 presented, which corresponds to the corresponding Gerä ^¬ teseriennummer, namely the virtual SD card 2a. By contrast, the virtual SD card 2b is not perceived by the module 8 or access to the data stored therein is not possible.

After the module 8 has been configured in this way, the SD card 1 is removed from the SD card reader 6b and inserted into the SD card reader 6c of the module 9. There now takes place the same process as in the assembly 8.

Once again, when the SD card 1 is inserted, the module 9 informs it of its serial number and thus shows itself to the SD card 1. The management ^logic 3 then grants finally read access to the data stored in the virtual SD card 2b.

For such a configuration carried out according to the prior art instead of an SD card 1 two SD cards 1 are required, which must first be described sequentially in the configuration computer 5 with suitable data. Subsequently, an operator must be eight, the SD-described not to be confused with each other cards 1 and to insert the respective suitable SD card 1 in the SD card reader 6b and 6c the construction ^¬ groups. 8 and 9 Alternatively, it could also be provided according to the prior art to use only a single SD card 1. This would then be described in a first step by the configuration computer 5 with data inserted into the SD card reader 6b of the module 8 and the assembly 8 be projected in this way. Thereafter, however, the SD card 1 would have to be removed from the SD card reader 6b and inserted again into the SD card reader 6a of the configuration computer 5 in order to be deleted there and to be written with new data intended for the assembly 9. Only then is the so-described SD card 1 in the SD card reader 6c of the assembly could be introduced 9 to this to configu ^¬ ren. So you can see that can be saved with the help of the proposed procedural ^¬ proceedings according to the invention significantly effort as part of the project planning process.

The invention thus has considerable advantages. The configurations for multiple modules can be loaded onto the SD card 1 from the configuration computer 5 in one step. This saves a considerable amount of time, since, on the one hand, the pure transfer works faster because the card changes are eliminated; on the other hand, the user does not have to constantly change SD cards, so he does not have to permanently attend the charging process. During commissioning, there is a one ^¬ Zige SD card 1, where all configurations are available, which minimizes errors during use. Each assembly can only see exactly its own partition. If an incorrect SD card is inserted that contains no configuration information for the required ^¬ celled module, the module provides no or only an empty partition.

Apart from the transfer of the configuration or the PLC program, this virtualization of the SD card 1 is also ideal for use in the firmware update of many modules. A configuration tool (for example, Step 7) of the configuration computer 5 loads for all in the automation ^¬ approximately technical installation existing modules (for example, CPU, Central Processing Unit; IM, interface modules; CP, com- munication Processor; etc.) the current firmware version of down the Internet via an Internet connection 7 from the manufacturer and distributes them to the virtual SD cards 2a to 2f. Subsequently, an employee with a single SD card 1 can bring all modules in the complete automati ^¬ tion technical system 4 to the latest firmware version, without that it can lead to incorrect operation, as each module sees only exactly their assigned version. Of the

Effort to establish this mechanism is minimal since it is mainly only in the configuration software or in the assembly only during the initialization of the SD card instead ^¬. If the correct partition is selected, the SD card 1 behaves like any other automation SD card.

Furthermore, different serial numbers can refer to identical partitions. This is advantageous for the firmware update of the same modules and for the configuration of series machines.

When using SDHC cards with extremely high capacity is in addition to present a SD card the opportunity outward face the Inter-, since any older Ge ^¬ councils do not master the new SDHC standard. The SDHC card would only use this internally or with respect to the configuration computer in order to exploit the high capacity or to be able to describe very many partitions in one go. The possibility arises because SDHC cards to SD cards are backward compatible electrically so that the SDHC card as a SD card can presenta ^¬ animals with their maximum capacity. In summary, therefore, a virtualization of an SD card, so that different devices can only see and change the content intended for them after identification ^¬ identified. In this way, standard cards with high storage capacity can be used for uniting smaller, special cards in automation technology. For program and firmware updates, there is a considerable effort and error minimization. On the SD card, a SWOS (Software Operating System) can be provided for this purpose. Reference sign list

1 SD card

2a-2f virtual SD card

3 administration logic

4 automation system 5 project calculator

6a, 6b, 6c SD card reader

7 Internet connection

8 assembly

9 assembly

Sl, S2, S3, S4 step

Claims

claims

A method of providing a data storage architecture for transferring data from a data providing device (5) to at least a first (8) and a second device (9), comprising the steps of:

a) providing an electronically and / or optically readable data storage medium (1);

b) partitioning a data memory of the data storage medium (1) into at least a first (2a) and a second one

Partial data memory (2b); and

c) Specification of a partial data memory management (3) so that the first device (8), but not the second device (9), can access the first partial data memory (2a) in order to read out data from the first partial data memory (2a).

2. The method according to claim 1,

characterized in that

the data storage medium (1) provided in step a) is coupled (6a) to the data delivery device (5) for data transfer and step b) and / or step c) is performed by the data providing device (5).

3. The method according to claim 1 or 2,

characterized in that

) is in the data storage medium (1) an identification logic (3) provided in step c, which is designed to receive provided (from the first device 8) Geräteidentifi ^¬ cation data, evaluate, and (depending on the evaluation of the first device 8) To grant access to the first partial data memory (2a).

4. The method according to claim 3,

characterized in that

a device serial number is provided by the first device (8) as device identification data.

5. Method according to one of the preceding claims, characterized in that

in step c) the partial data storage management (3) is set so that the data provision device (5) can read and / or write access to all partial data memories (2a, 2b, 2c, 2d, 2e, 2f).

6. The method according to any one of the preceding claims, characterized in that

in step b) the data store is partitioned into a number of partial data stores (2a, 2b) corresponding to the number of appliances (8, 9).

7. The method according to any one of the preceding claims, characterized in that

in step c), the partial data storage management (3) is set so that with regard to the access to read data exactly one of the devices (8, 9) and / or each of the devices (8, 9) exactly matches each partial data memory (2a, 2b) Partial data ^memory (2a, 2b) is assigned.

8. The method according to any one of the preceding claims, characterized in that

in step a) as data storage medium, an electronic memory chip, in particular a flash memory chip (1), is provided.

9. A method of transmitting data from a data providing device (5) to at least a first (8) and a second device (9), comprising the steps of:

d) performing the method of providing a data storage architecture according to any one of claims 1 to 8;

e) coupling (6a) of the data storage medium (1) with the Datenbe ^¬ provisioning device (5), transferring data from the data supply device (5) to the Datenpeichermedium (1) and storing the data in the first partial data memory (2a); and

f) coupling (6b) of the data storage medium (1) to the first device (8), accessing the first device (8) to the first Partial data memory (2a) and transferring data from the first partial data memory (2a) into the first device (8).

10. System (4) comprising a data providing device (5), an electronically and / or optically readable data storage medium (1) and at least a first (8) and a second device (9), wherein the data providing device (5) is adapted to a Data storage of the data storage medium (1) in at least a first (2a) and a second partial data storage (2b) to partition and a Teilildem data ^¬ cherverwaltung (3) set so that for reading data from the first partial data memory (2a), the first device (8), but not the second device (9) can access the first Teilda ^¬ space A (2a).