DE4401465A1 - Communication module - Google Patents

Abstract

To connect two or more computer systems for data exchange, a communication module (2) has a first and second coupling level (KE1, KE2) for coupling to a first databus (8) connected to the first computer system and a second databus (10) connected to the second computer system. Each coupling level (KE1, KE2) comprises a plurality of coupling units (S1n, E1n; S2n, E2n) for data transmission. Between the two coupling levels (KE1, KE2) there is a management level (VE) having a unit (20) for transferring the data from the first to the second databus (8, 10). There is also a data level (DE) between the coupling levels (KE1, KE2) comprising a parameterisable description file (38) for the data to be transferred.

Description

The invention relates to a communication module for the exchange of data between different computer systems men.

In order to adapt different computer systems to each other the so-called ISO communication protocol or Layer model developed as a quasi standard. The Ab stands cut ISO for International Standardization Organization; see e.g. B. Computer encyclopedia, lexicon and technical dictionary for data processing and telecommunications, H.H. Schulze, Rowohlt, 1998, pages 1557 to 1560. This in seven other levels or protocol layers structured ISO communication protocol is a model for developers development of interfaces for the complicated process of com communication of various computer systems via under various networks.

The lowest first layer or physical layer sets the Way of transferring individual bits from which data, texts, images, language and messages are built up. The second layer or security level sets out the procedures to ensure an error-free transfer to the individual systems of collision avoidance systems. The third layer or network level ensures the rich structure of the individual sections of the route between the transmitter and receiver. The fourth layer or transport level lays the functions and the way the systems behave within the network during data transport should, firmly. The bottom four layers represent the trans port protocol and are largely in the system today according to the ISO communication protocol.  

The fifth layer or connection level sets the one details of the connection to be used Communication between the systems firmly. In the sixth Layer or presentation level are the ver agreements on the meaning of exchanged data. Are in the top, seventh layer or application level Agreements on the permissible applications between the communicating systems fixed. These three top layers ten are also referred to as the application protocol, in which the agreements on the possible and permissible Opera tions that the sender initiates in the system of the recipient, to be hit.

As far as the technical level, d. H. the transport protocol, be is reached, fixation of individual agreements is na very unproblematic. In terms of application, i. H. regarding the application protocol, is a determination due to the organizational and to be taken into account individual ratios in the different computer systems stemen extremely difficult.

For data exchange between different computers The standard is therefore usually a network connection computer or "gateway" used, the data from the form from which they come from a computer system that translates into the form that is required in the other computer system. This relates however only on the implementation of different data forms mate with a specified transport protocol within the four lowest layers of the ISO communication protocol. Should in addition, computer systems are coupled with each other, which are both different databases and different Data buses as well as various data formats on the data buses and different access options to the Da have tenbuses, this is the task with a gateway no longer solvable. Rather, it must be for each new application elaborate software and program adjustments carried out become.

The invention is therefore based on the object, a univer Specify communication module that specifies the connection two or more computer systems for the purpose of data output enable exchange.

According to the invention, this object is achieved by a communication cation module with a first and a second coupling level ne to connect to a ver with the first computer system bound first data bus and to one with the second computer nersystem connected second data bus, each coupling level a number of coupling modules for data transfer gung includes, with one arranged between the coupling levels neten administrative level, which is a building block for implementing the Has data from the first to the second data bus, and with a data level arranged between the coupling levels, which is a parameterizable description file for the to implement data includes.

The two coupling levels only take into account the un First four protocol layers of the ISO communication prototype kolls, with the individual coupling modules under different transport protocols from the data buses to receive or send connecting computer systems. The top three protocol layers of ISO communication protocol, d. H. the different application protocols for the communication process between the different Computer systems are in the parameterizable description data level file taken into account. Because of the modular Structure of the data conversion from the actual data transfer is decoupled is advantageously the administrative level universal. This means that with a new application le only the coupling level by additional coupling modules and the data level description file by entering new ones Parameters need to be expanded during the administrative level remains unchanged.  

The two coupling levels serve to connect the communication cation module to the data buses of the computer systems. Here a distinction is made between external data transfer in the communication module and from the communication module to the outside eat. Therefore, are advantageously in each coupling level at least one coupling block for sending and at least one a coupling module for receiving data is provided.

The administration level is used for the logical implementation of the data in the data structure of the respective receiving system. This implementation takes place above the first four layers of the ISO communication protocol and ensures communication between the computer systems in the upper layers 5 to 7 of the ISO communication protocol. In order to be able to control the data flow between the two coupling levels, a component for order control connected to the component for data conversion is therefore advantageously provided in the administration level.

Most relational databases offer the possibility direct access via so-called front and back end servers resorted to making data stored there. Therefore, the Communication module in an advantageous development in the Administrative level with the block for data conversion bound preprocessing computer with a front End server is connected. This preprocessor is expediently also with the module for the order control connected.

To be sent from a data bus of a computer system and from Communication module received data that does not immediately know Intermediate storage can be processed in the Data level connected to the block for data conversion ner ring buffer provided. There the data is so long saved until the administrative level for further processing ready. The orders for data conversion between cached. There is a with in the data level  the module for order control connected order storage cher provided.

The advantages achieved with the invention are in particular in that by dividing the communication mo duls in levels and an assignment of the data exchange between functions required for the computer systems different levels as well as the modular structure of each a coupling under the coupling levels and the data level different systems with the same data protocols (Bridge function) as well as with different data proto kollen (gateway function) is possible.

The type of identifiers is understood here under data protocol the one with the data packets or files Identification and assignment are transferred. This data protocols with the identifiers of the different Chen computer systems to be transferred data in the pa Parameterizable description file of the data level for the un different bus systems.

An embodiment of the invention is based on the drawing tion explained in more detail. It shows one coupled to two data buses peltes communication module with its components and compo nenten.

The figure shows the subdivided communication module 2 , which is coupled via interfaces 4 , 6 to a first data bus 8 of a first computer system (not shown) and to a second data bus 10 of a second computer system (not shown). For coupling to the first data bus 8 and to the second data bus 10 , the communication module 2 has a first coupling level KE1 or a second coupling level KE2, between which there is a management level VE and a data level DE below it hierarchically.

The coupling level KE1 comprises a number of coupling stones S₁₁. . . S _1n and E₁₁. . . E _1n for the data transfer from the data bus 8 into the communication module 2 or from this into the data bus 8 . This is indicated by the action arrows 12 and 14 . Two coupling modules S _1n and E _1n for sending and receiving such a data protocol are provided for all different data protocols.

The coupling level KE2, which is constructed in at least approximately the same way as the coupling level KE1, also includes a number of coupling modules S₂₁. . . S _2n and E₂₁. . . E _2n for the data transfer from the data bus 10 into the communication module 2 or from this to the data bus 10 . This is also indicated by arrows 16 and 18 . Also in the second coupling level KE2, a number of coupling modules S _2n , E _2n corresponding to the number of different data protocols are provided, with a coupling module S _2n for transmitting and a coupling module E _2n for receiving a specific protocol type being provided for each data protocol.

The coupling levels KE1 and KE2 have a modular structure. In a new application, ie if a new data protocol is to be transmitted between the data buses 8 and 10 and is to be implemented in the communication module 2 , then only the coupling levels KE1 and KE2 have to be replaced by corresponding coupling modules S _1n , E _1n or S _2n E _{2n can be} expanded.

The management level VE comprises a module 20 for data implementation, which is connected to the coupling modules S _1n , E _{1n of} the first coupling level KE1 and to the coupling modules S _2n , E _{2n of} the second coupling level KE2 via data lines 22 and 24 , respectively. The management level VE also includes a module 26 for order control and a preprocessing computer 28 which is connected to a front-end server 30 for access to a relational database (not shown) of one of the computer systems. As represented by the arrows 32 and 34 , the module 20 for data conversion is connected to the module 26 for order control and to the preprocessing computer 28 . The block 26 for order control is - as indicated by the effect arrow 36 - also connected to the preprocessing computer 28 .

The data level DE comprises a parameterizable description file 38 , which - as indicated by the effect arrow 40 - is connected to the module 20 provided in the administration level VE for data conversion. The parameters required for data conversion are stored in this description file 38 . These are entered in the description file 38 in the form of parameters which are characteristic of the different data protocols. The data level DE, which is independent of the management level VE, as well as the two coupling levels KE1 and KE2, can be expanded at any time by entering further parameters relevant for new applications. In contrast, the universal administration level VE remains unchanged for all applications.

The data level DE also includes a ring memory 42 connected to module 20 for data conversion and an order memory 44 connected to module 26 for job control. This is indicated by arrows 46 and 48 respectively.

If data is now to be exchanged between the computer systems, data are read into one of the coupling _modules E _1n , for example via the data bus 8 , with which a corresponding data protocol is transmitted. The received data arrive via the first coupling level KE1 in the module 20 of the management level VE. There, the data are converted to the data protocol and the data format of the data bus 10 coupled to the second coupling level KE2 of the communication module 2 . The implementation is controlled in accordance with the parameterizable description file 38 and the module 26 for order control. With large amounts of data, orders that have not yet been processed can be stored in the order memory 44 .

From the block 20 for data conversion, the data arrive at a corresponding coupling block S _{2n of} the second coupling level KE2 and are sent from there to the coupled data bus 10 . If data are to be sent in the reverse direction, the data flow takes place via one of the coupling modules E _2n , the module 20 for data conversion and a corresponding coupling module S _{1n of} the first coupling level KE1 and are sent from there to the data bus 8 .

Depending on how the data are available on the data buses 8 , 10 and how they are to be processed in the respective computer system, it may be necessary that the data must be temporarily stored in the ring memory 42 . If, for example, a computer system only needs data on request, while the other computer system constantly delivers all data to data bus 8 or 10 , these data must be temporarily stored until a request is made by one computer system.

Furthermore, there may be a desire that a computer system speci el data, z. B. calculated values required, which are in a database of the other computer system. With a full database, it could take a long time before the data is assembled in the normal way via coupling levels KE1 or KE2 to data bus 8 or 10 and then again via data bus 8 or 10 and coupling level KE1 or KE2 and ready for dispatch would be. In order to shorten the running time in such a case, direct access is possible via the preprocessing computer 28 , which is connected via the front-end server or the interface 30 to the database of the corresponding computer system. These databases are so-called relational databases, which offer direct access via front and back-end servers.

Conceptually, the communication module 2 is constructed in such a way that a large number of coupling options can be implemented without significant program or software changes. Some possible actions within the VE administrative level are shown below:

For example, if a data exchange is to take place on the condition that the data bus 8 or 10 of the data-sending computer system and the data buses 10 or 8 of the data-receiving computer system transmit the same or different protocols, the data to be transmitted are passed on unchanged. Possibly different data protocols are taken into account by the corresponding coupling modules E _1n or S _2n in the coupling levels KE1 or KE2.

Another condition can be that both Computer system sending data as well as the data receiving Computer system are telegram-oriented. Are beyond the logical formats of the telegrams and their lengths are the same, it follows as an action that the data is sent directly. In contrast, are the logical formats and / or the lengths of the Telegrams differ, so these telegrams are in a first action first converted. Only in one Subsequent, second action, the data are sent.

However, according to another condition, the data sending is Computer system telegram-oriented, the data receiving Computer system but file-oriented and are the logical ones Formats differ, so first takes place in a first Action converting the telegram to a file. In a second action places the order to send the data. In contrast, both the data-sending computer system and the computer system receiving the data is and are file-oriented  If the logical formats are the same, they are sent immediately wear for the data. In contrast, the logical formats are below different, the files are con vertiert, and only in a second action the order granted to send the data.

Furthermore, according to another condition, both the data sending computer system as well as the data receiving computer passive system, the first action is the order created for data request. In a second action first the order to receive the data is given. On in a third action, the order for Sen created the data. Are both sending data de computer system as well as the data receiving computer system active, the first action is the data temp start, as a second action the job to save this da as a third action, waiting for a second request and only as a fourth action the order to send the data granted.

If a data request is made as another condition a database of one of the computer systems, so first in a first and second action the order to read the Da issued from the database to the database. Only in one The third action is the order to send the data poses.

These and other conditions as well as by linking Be rules and the resulting action Tables are listed in Tables 1a and 1b below. In table 1a there are nine rows continuously Conditions specified. The table columns correspond to 1 to 13 consecutively numbered rules, which are indicated by "and" - Links between individual conditions are formed. From the These rules are listed alphabetically in Table 1b continuous actions are derived, where Y and N for "condition he fills "or" condition not met. "The rows  follow in which the actions are carried out or processed, is numbered 1 to 4. The number 0 denotes the cases in which the data remains unchanged forwarded or sent without a Action has taken place.

Table 1a

Administrative level actions

Table 1b

Administrative level actions

The above-mentioned conversion of the telegrams and / or files takes place in the block 20 for data conversion. The orders are controlled in module 26 . To read data from the databases of the computer systems, one takes place via the front-end server 30 , the data first being read into the preprocessing computer 28 . There, the data are processed for further processing in module 20 for data conversion.

Due to the layered and modular structure of the communication module 2 , taking into account the different levels KE1, VE, DE, KE2, extensions are possible at any time. The communication module 2 can be used for simple subtasks, e.g. B. as a gateway or bridge, or for complicated tasks. It is particularly suitable for coupling computer systems within a power plant control room, in particular for coupling the control technology that controls the power plant system with a diagnostic system that monitors the system process.

Claims (7)

1. Communication module for data exchange between different computer systems,

• - With a first and a second coupling level (KE1, KE2) for coupling to a first data bus ( 8 ) connected to the first computer system and to a second data bus ( 10 ) connected to the second computer system, each coupling level (KE1, KE2) includes a number of coupling modules (S _1n , E _1n ; S _2n , E _2n ) for data transmission,
• - With a between the coupling levels (KE1, KE2) arranged management level (VE), which has a module ( 20 ) for converting the data from the first to the second data bus ( 8 , 10 ), and
• - With a between the coupling levels (KE1, KE2) arranged data level (DE), which includes a parameterizable description file ( 38 ) for the data to be implemented.

2. Communication module according to claim 1, characterized in that in each coupling level (KE1, KE2) at least one coupling module (S _1n ; S _2n ) for transmitting and at least one coupling module (E _1n ; E _2n ) are provided for receiving data. 3. Communication module according to claim 1 or 2, characterized in that in the management level (VE) one with the block ( 20 ) for data implementation connected block ( 26 ) for job control is seen before. 4. Communication module according to one of claims 1 to 3, characterized in that a preprocessing computer ( 28 ) connected to the module ( 20 ) for data implementation is provided in the management level (VE). 5. Communication module according to claim 3, characterized in that the pre-processing computer ( 28 ) is connected to the module ( 26 ) for order control. 6. Communication module according to one of claims 1 to 5, characterized in that a ring memory ( 42 ) connected to the module ( 20 ) for data conversion is provided in the data level (DE). 7. Communication module according to claim 3, characterized in that in the data level (DE) with the module ( 26 ) for order control connected order memory ( 44 ) is provided.