DE4304906A1 - Networked computer system and method for operating a networked computer system - Google Patents

Description

The present invention relates to a networked computer system, in which packet data records between via a communication system at least one main computer and any number exchanged by user stations, the communica tion system comprises at least one central station.

The invention further relates to a method for operating a networked computer system, one via a central station having communication system with a number of users station-connected mainframe, wherein the process comprises the steps:

• - Create one between the host and one of the Package data record to be exchanged for user stations,
• - Transporting the packet data record via the communication system,
• - Receiving the packet data record at the central station or at one of the user stations, and
• - Processing the packet data record.

Networked computer systems of this type and the corresponding ones Methods for operating these networked computer systems are Known from practice and usually affect wired Computer networks.

In the known wired computer networks, several can Users via so-called front-end processors on one Main computer work and the programs available there in Use interactive mode.

In addition, wired data networks are known, such as. B. the IEC bus system, the ETHERNET system or similar local ones Data networks. As with the wired computer networks also has each participant's own number on the wired data networks, on the basis of which it is recognized who is working with the central computer want. The data is not transported here in real time, but combined into so-called data packets, which according to a specific mode between the user station and the Main computer to be replaced. Here, for example Handshake procedures or procedures in which the Data packets are preceded by a destination address.  

The known wired networks have u. a. the disadvantage that the system is not very flexible due to the cables required is. In addition, repeaters are required, whose Failure causes the respective network to break down. The same applies if two participants accidentally have the same Hang number on this network. Another disadvantage is that the structure of the network must be known exactly before a other users can connect to the network. At all it is necessary to first have some kind of network infrastructure is spread out before even operating the networked Computer system can be started.

All of this leads to the well-known networked computer systems are very expensive and require a lot of effort Material and time can be built.

In addition, it is well known to radio data exchange, being on both sides of the radio link from each other independent programs are running. These programs use the Radio link for data input or data output, so to speak. The Data sets are exchanged via radio, but none Terminal dialog is possible. The user can e.g. B. the on the Do not change programs running on their own, rather, it needs to be accurate about the programs running on the host "know". Changes in the program structure must be made on both Sides of the radio link.

Another disadvantage here is that it is an all-round radio system acts that does not know an automatic addressing of participants. Everyone Participant must decide whether the data is intended for him. As an example, the police are mentioned here, those in the mobile Driving license control over those in the control vehicle Query PCs data from the main computer of the driving license office  can. However, real dialog operation is not possible here.

On the other hand, it is also known about existing cellular Networks like the C-network telephone have a dialog between two PCs respectively. But here is just a point-to-point connection possible to operate a control center with many users not provided.

This is also a static static network, that a network control center needs to maintain the dialogue between to monitor users. Every user has a fixed one Number where the control center monitors from where the respective participant reports. The failure of one of the many required relay stations must be recognized by the control center which then takes measures to rectify the fault.

Furthermore, when leaving a reception area, another must Frequency can be switched, for which fixed relay stations for coverage of an area is required. As before mentioned above for the hard-wired computer networks is also here the structure of the network is given so that it is at the desired flexibility is lacking.

But it is often desirable, for example, in an undeveloped one Area to operate such a computer network, with grant should be that a large number of users, their more precise Location is not known on the one hand and on the other hand about who can change time significantly, a real dialogue operation with can lead the main computer. In addition to the requirements of Police, fire brigade and army are also under insurance here take, health insurance companies or, for example, the BfA, which more and more pass their customers with mobile use to look after vehicles. Here it would be especially in the new  Federal states desirable if such a mobile vehicle from any point of view with the appropriate one Central computer could connect.

The computer networks described so far enable all of this however not, because they are either missing because of the wiring flexibility or real dialogue.

There are also other radio networks available for exchange of packet data can be used. Only the AX-25 should be mentioned here, which is used in the USA for non-commercial data transmission becomes. But this radio network also requires that the structure the network is known. The user must know who over whom and where what frequency can be reached. This radio network is not standing network, but it is still not fault-tolerant, because on the one hand, a direct radio connection is required. Dialogue operation is also not possible with this radio network.

In addition, it would be possible to have a dialog mode Establishing satellite radio is disproportionate expensive. For one thing, a geostationary satellite and on the other hand, each user must have their own satellite antenna carry with them. Here it should also be borne in mind that such Satellite systems are not readily turned on in less time can be addressed, particularly due to the imponderables of space travel.

Finally, it should be mentioned that it is known for data reduction in the transmission of packet data cluster controller to use which z. B. a transmitted screen page cache and only the data during the session be changed, transmitted as differential data. These clusters controllers are especially for editing screen masks thought.

Proceeding from this, it is an object of the present invention the networked computer system of the type mentioned at the beginning and the corresponding procedure for operating this network Computer system in such a way that it is fast and is inexpensive to set up and operate. The system is supposed to also sensitive to the change of location User and the failure of one or more stations.

Regarding the networked computer system mentioned at the beginning solved this problem in that the central station via a the packet radio network carrying the packet data records with the Users in radio communication.

With regard to the method mentioned at the beginning, this task becomes solved in that the packet data sets by radio over a Packet radio network are transported.

The object underlying the invention is achieved in this way completely solved. Since the communication network is a packet radio network, all are with the cable networks associated disadvantages eliminated. Users can be mobile their exact location does not have to be known. Such a thing The system and such a method are also very light and inexpensive to put into operation as they have no other Need infrastructure. Because of the transmitted packet records, that only ever took a very short amount of time to do to be transported, so to speak a random time-sharing process through which the individual User stations can work on the main computer.

In the networked computer system, it is preferred if that Packet radio network intermediate stations between the central station and the user stations includes which packet records received and forwarded.  

The advantage here is that the user stations are not in direct radio connection to the central station have to. This further increases the flexibility of the network, which are particularly opposed to the use of wired Computer systems in the creation costs and creation time noticeable.

It is also preferred if at least some user stations Intermediate stations are.

The advantage here is that the cost of the new computer lower the network even further. There are no additional ones Intermediate stations required, but each user station also serves as an intermediate station. In this way can function in the event of failure of an intermediate station. B. taken from another user station nearby become. This increases the speed of troubleshooting.

It is also preferred if at least some user stations are portable.

The advantage here is that it is a dynamic network deals with the respective requirements can be adjusted in terms of locations.

Furthermore, it is preferred if the user stations each have one Cluster controllers include one screen to be edited page saves and after editing from the changed Data creates a differential data packet that is over the packet radio network is transported.

In this way, the amount of those in the packet radio network increases transporting data significantly reduced what the overall  Number of user stations increased per unit of time with the Main computer can communicate. So it can be bigger Build networks.

It is further preferred if the central station has at least one Cluster controller includes.

This has the further advantage that that of the Central Data sent from the station can be what the System capacity increased even further.

It is further preferred if each user station has an emula tion device which includes a for the host provided data terminal simulated so that a user of the user station with and / or on the main computer data can process.

The advantage here is that with inexpensive terminal stations Data terminals for high-quality main in the user stations computer can be simulated, so that a real dialogue operation over the virtual connection.

This also leads to an inexpensive system.

It is further preferred if each packet data record has a destination address includes, via which its destination is set in the packet radio network is.

This measure has the advantage that data can be transported faster takes place when the destination address is given to the data record, so that the target station selectively to the intended for it Can address packet records.  

It is further preferred if the destination address identifiers of the Includes intermediate stations that the packet record from the sending location must go through to the destination.

The advantage here is that the packet data record, so to speak exact path is given through the packet radio network. Based The destination address can then be determined as the packet record to be passed on between the intermediate stations. Also this leads to a faster transport of the packet data record and thus increases the system capacity, which is reversed in the cost and speed of construction.

It is further preferred if the destination address is also a Sending location identifier and a destination identifier.

The advantage here is that the Address for the data to be returned can be determined. There is no need for extensive buffers for addresses or the like in order to.

It is further preferred if the destination address is derived from the sequential order of the transmitter identification, the Identifiers of the intermediate stations and the destination identifier together sets so that the destination address for transport from the central station to the user station in reverse order Destination address for the transport from the user station to the Central station reproduces.

It is also advantageous here that, as it were, by an inv tation of the destination address, which is only read from backwards must be, the new destination address results. This too is to see from the point of view of an inexpensive system  since no complicated algorithms are required to get out the destination address to be sent to the destination address received to generate.

It is further preferred if the central station, the intermediate stations and the user stations are constructed in such a way that the network configures itself.

This measure has the particular advantage that none Information about a so-called basic structure of the radio data network must be provided. The central station and the individual participants in the radio data network generate, so to speak automatically and dynamically a hierarchy on the logical Networking level. This also not only leads to an inexpensive, but especially to one quickly even in rough places on networked computer system to be built.

It is particularly preferred if the central station has a Device for network configuration includes that when commissioning sends a configuration address of the packet radio network, which is the identifier of the central station and a configuration identification includes, and if at least some intermediate stations and some user stations have their own identifier in the Install the received configuration address and the changed one If necessary, send the configuration address again, the intermediate stations and the user stations from the received and if necessary previously changed con figurationsadresse your own target address for addressing the Derive central station.

The advantage here is that only by stringing them together the various identifiers of the intermediate stations and users stations and the forwarding of such configuration addresses The dynamic self-configuration of the radio data network takes place.  

This is not only particularly quick, but also requires very little hardware outlay on the part of the individual Stations.

It is further preferred if at least some intermediate stations and some user stations a device for the network configuration include that when switched on for the first time switch or if the previous connection to The central station send out a search address which contains the identifier the user station itself, the identifier of the central station as well includes a configuration identifier and if the intermediate stations and user stations have their own identifier in the received one Install search address and, if necessary, the changed search address again send out, the central station from the received and if necessary, previously changed search address the new destination derives the address for the user station and returns it to it sends.

The advantage here is that using the search address a new additional user station or a user station whose Connection to the central station was interrupted, its dynamic generated its own target address for addressing the central station. This also applies to mobile user stations, which are made up of the reception area of their previous intermediate stations and now "searches" for a new stopover, through which she joins the central station can reconnect.

With regard to the new method, it is preferred if the Step of transporting the packet record receiving the packet data set at an intermediate station and the further sending the received packet data record by radio.  

The advantage here is that the network because of the intermediate stations is easier to configure, the user stations must not in direct radio connection to the central station his.

It is further preferred if the step of generating a Packet data set generating a the transport route of the Packet record identifying destination address and the oversight of the packet data record with the destination address.

This has already been done in connection with the computer system discussed advantage, namely the path of the packet data set is dictated by the packet radio network what the transportation time significantly reduced. This increases the capacity of the system.

It is further preferred if the step of processing the Packet record includes the following steps:

• - intermediate storage of the packet data record,
• - Change some data from the packet data set, and
• - Generation of a packet data record to be returned, which in the essentially only contains the changed data.

The advantage here is that the data traffic in the packet radio network is significantly reduced, since only the processed data be sent. This increases the system capacity and lowers the reverse step the cost.

It is further preferred if the step of changing some Data the step of emulating a data terminal for the Host includes.  

The advantage here is that on inexpensive terminal stations high-quality data terminals for mainframes are simulated can, so that despite inexpensive user stations a real Dialogue operation via the virtual connection is possible.

It is further preferred if the step of changing some Data the step of simulating a real terminal dialog between the data terminal and the main computer.

The advantages resulting from this step accordingly those as related to the emulation of the data end have already been discussed above.

It is further preferred if the step of generating the Destination address includes the steps:

• - At least once after switching on the packet radio network or after a failure of the packet radio network Configuration signals from the central station via the Packet radio network,
• - Receiving and changing the configuration signals on one Intermediate station,
• Forwarding of the changed configuration signals,
• - Receive the possibly changed configuration signals the user stations, and
• - Derive the one for the receiving user station specific destination address towards the central station.

These steps show advantageous measures how that can be done Packet radio network dynamically configured itself. Every stopover leaves behind in the received configuration signals their own license plate, so that from one of several intermediate stations received and forwarded configuration signal the previous path of this configuration signal is traced can be. From this, the user station then directs its own Destination address.

It is further preferred if the step of generating the Destination address includes the steps:

• - At least once after switching on a new user station or after a partial failure of the packet radio network Send out search signals from the user concerned station over the packet radio network,
• - Receiving and changing the search signals at the intermediate stations,
• - forwarding the changed search signals,
• - Receive the possibly changed search signals the central station, and
• - Deriving the specific for the searching user station Destination address from the direction of the central station.

Further advantages result from the description and the attached drawing.  

It is understood that the above and below Features and measures to be described not only in Unique position but also in combination with the area of present invention count.

An embodiment of the above invention is according to described standing and shown in the accompanying drawing.

Show it:

FIG. 1 is a cross-linked computer system that uses the new communications system;

Fig. 2 shows two examples of destination addresses in the new com communication system;

FIG. 3 shows examples of address configuration for configuring the new communications system;

FIG. 4 shows examples of search addresses, such as are used in the new communications system for partial reconfiguration;

Fig. 5 is a block diagram of a user station for the new communication system; and

Fig. 6 shows the block diagram of the central station for the new communication system.

In Fig. 1, 10 is a networked computer system. This computer system 10 comprises a main computer 11 , which is connected via a communication system 12 to user stations 13 , which are indicated by circles. Some of the user stations 13 are connected to a central station 15 via intermediate stations 14 , whereby a communication network 16 is formed.

The communication network 16 is in the exemplary embodiment shown a packet radio network 17 which uses features of the packet radio network AX-25.

In the exemplary embodiment shown, the main computer 11 is connected to the central station 15 via a satellite communication system 18 . For this purpose, a geostationary satellite 21 is provided, which is reached by the main computer 11 via a parabolic antenna 22 and by the central station 15 via a parabolic antenna 23 .

However, the satellite communication system 18 is only one example, the main computer 11 can also be connected directly to the central station 15 via a direct connection 24 . The satellite communication system 18 is used in particular when the main computer 11 is located on a different continent, for example, than the actual communication system 12 .

The central station 15 is connected to a transmitting / receiving antenna 26 , via which the central station 15 is in radio communication with the individual user stations 13 and intermediate stations 14 . These radio connections are indicated by arrows 27 . It can be seen that the individual user stations and intermediate stations are provided with their own identifiers 28 , which is 13 * 2 * for the user station located at the bottom right in FIG. 1. The user station * 2 * is connected via the intermediate stations * 9 * and * 4 * to the central station 15 , which has the identifier * 1 *. It should be noted that the intermediate stations 14 are themselves user stations 13 .

A mobile user station with the identifier * 5 * is designated by 29 , which moves to the left in FIG. 1. The radio connection to the intermediate station with the identifier * 6 * is lost. In a manner yet to be described, the user station 29 'now creates a new radio connection 30 to the intermediate station with the identifier * 7 *, from where it communicates with the central station 15 via the intermediate stations * 3 * and * 4 *.

It is now assumed that the packet radio network 17 is a rapidly expanding network in which the distances between the individual user stations and intermediate stations are continuously increasing. In order to still maintain the individual radio connections 27 , a new intermediate station 32 is sent to the area served by the packet radio network 17 . This new intermediate station 32 has the identifier * 12 *.

In a manner that will also be described in more detail, the new intermediate station 32 now establishes new radio connections 33 and 34 to the intermediate stations with the identifications * 3 * and * 11 *. The user station * 5 * is now connected to the central station 15 via * 7 * and * 3 * and **. If, due to the further expansion of the packet radio network 17, it is no longer possible to establish a radio connection 27 between the central station 15 and the intermediate station with the identifier * 8 *, this intermediate station can still be connected to the central station via the intermediate station * 11 * and the intermediate station ** 15 communicate.

In the communication system described so far, it is thus ensured that the communication between the central station 15 and the individual user stations 13 is retained even when the network is expanded or the user stations are very mobile. Such a communication system could, for example, be used by the police, fire brigades, taxi companies, during rescue or supply operations in undeveloped / impassable areas. It would also be suitable for advisory vehicles from BfA, insurance companies or banks. In all these cases, a dynamically establishing and, so to speak, growing packet radio network would be advantageous if the individual user stations had to access programs on a main computer directly. For banks and insurance companies, this would be part of customer service, e.g. B. in the calculation of credit lines may be an advantage.

In the communication system 12 described so far, packet data sets are exchanged between the user stations 13 and the central station 15 . For this purpose, packet data sets are initially generated at the sending station - user station 13 or central station 15 - which are to be transported to a destination station via the packet radio network 17 . In addition, the transmitting station generates a destination address, which not only specifies the destination, but also the path of the packet data record through the packet radio network 17 . The transmitted packet data record is received by an intermediate station 14 , which first checks whether the packet data record is intended for it itself. If this is not the case, it is further checked whether the receiving intermediate station lies on the route of the packet data record between the transmitting station and the destination station. If this is the case, the receiving intermediate station 14 sends the packet data record out again, etc. until the packet data record reaches the destination station.

The structure of such a destination address 37 is shown in Fig. 2a. The destination address 37 initially comprises an address start identifier 38 and an address identifier 39 , which are symbolized in the exemplary embodiment shown for the sake of simplicity by the letters A and E.

The destination address 37 further comprises a transmitter identifier 41 , which in the example shown is the identifier * 1 * of the central station 15 . A target identifier 42 is also provided, which here is the identifier * 7 * of a user station 13 .

Between the transmitter identifier 41 and the destination identifier 42 , identifiers 43 , 44 are provided for the intermediate stations, via which the packet data record is to be transported from the central station 15 to the user station 13 with the identifier * 7 *. In the example shown, this connection runs via the intermediate stations 14 with the identifiers * 4 * and * 3 *.

The destination address 37 in FIG. 2a thus represents the path of a packet data record from the central station 15 to the user station 13 with the identifier * 7 *.

In Fig. 2b a further destination address 46 is shown, which describes the reverse route of a packet data set from the user station 13 with the identifier * 7 * to the central station 15 with the identifier * 1 *. It can be seen that the order of the identifiers has only been inverted. When the central station 15 receives such a destination address 46 , it can easily derive the destination address 37 from it, via which it can reach the transmitter again.

The way in which these destination addresses are assigned to the individual user stations 13 will now be described with reference to FIG. 3.

The packet radio network 17 is not preconfigured, but rather configures itself, so to speak, after being switched on for the first time. For this purpose, the central station 15 outputs a configuration signal 47 , shown schematically in FIG. 3a, which is a configuration address 48 .

This configuration address 48 contains the identifier * 1 * of the central station 15 as the transmitter identifier 41 . The configuration address 48 includes configuration identifiers 49 as identifiers for the intermediate stations 43 , 44 and as a destination identifier 42 , which are identified by a 0 in the exemplary embodiment shown for the sake of simplicity.

This configuration address 48 is now sent out via the packet radio network 17 and received by the user stations 13 / intermediate stations 14 within range.

The receiving stations change the configuration address 48 into a changed configuration address 51 , whereby they incorporate their own identifier behind the identifier * 1 * of the transmitting station 41 into the configuration address 48 . The configuration address 51 from FIG. 3b is thus expanded by one position compared to the configuration address 48 .

It goes without saying that each intermediate station 14 now sends out its own changed configuration address 51 , which is received by user stations 13 / intermediate stations 14 still further away from the central station 15 .

In the example shown in FIG. 3c, the intermediate station 14 with the identifier * 3 * received the configuration address 51 and converted it into a configuration address 53 .

In addition to this processing of the configuration addresses 48 , 51 , 53, the receiving user stations 13 / intermediate stations 14 store the configuration addresses 48 , 51 , 53 and derive their own destination address 46 in the direction of the central station 15 . For this purpose, they simply remove the configuration identifiers 49 from the configuration addresses. As already explained with reference to FIG. 2, the destination address 46 to be used for the respective user station 13 / intermediate station 14 in the direction of the central station 15 results from the reverse order of the identifiers stored in the configuration addresses 48 , 51 , 53 .

In this way, each user station 13 and each intermediate station 14 is supplied with its specific destination address 46 after switching on the packet radio network 17 , via which it reaches the central station 15 . The central station 15 itself does not have to know these destination addresses 46 , since the destination addresses are sent along with the packet data sets sent to the central station 15 , so that the central station 15 can recognize from whom and by which means the packet data record is reaching it.

It is understood that the method just described is merely exemplary, it is not required that the identifiers are arranged in the serial order shown. Also the symbols for address start identifier, address identifier, sender ID, target ID etc. are only examples. As part of The identifiers of cryptographed and reduced data can also be included only indirectly in the destination addresses.

Referring to Fig. 4 will now be explained as a "lost close gangene" User station 13 finds its way back to the central station 15. The case indicated by dashed lines in FIG. 1 is used here, in which a mobile user station 29 with the identifier * 5 * has moved out of the reception area of its previous intermediate station with the identifier * 6 *.

The user station 29 'recognizes the interruption of the connection to the central station 15 by the fact that it no longer receives a response to its sent packet data records. After a pre-selected period of time, the user station 29 'therefore sends out a search signal denoted by 54 in FIG. 4a, which represents a search address 55 .

This search address 55 contains the identifier * 5 * of the searching user station 29 ′ as the transmitter identifier 41 and the identifier * 1 * of the central station 15 as the target identifier 42 . The identifiers 43 , 44 for the intermediate stations are provided with the configuration identifier 49 already discussed.

In the example outlined in FIG. 1, the intermediate station with the identifier * 7 * receives the search address 55 and reads therefrom that the station with the identifier * 5 * is looking for a new connection to the central station 15 . For this reason, the intermediate station * 7 * inserts its own destination address in the direction of the central station 15 into the search address 55 , so that the new destination address 57 is created, which is shown in FIG. 4b.

The new destination address 57 is now sent to the central station 15 , which recognizes from the configuration identifier 49 that the station with the identifier * 5 * indicates an interrupted connection.

The central station 15 derives the new destination address from the new destination address 57

* A * 1 * 4 * 3 * 7 * 5 * E *

from which they sent the last one to station * 5 * Submit packet record again.  

In this way, the user station 29 'learns its new destination address 57 and is also supplied again with the packet data record last sent. If this packet data record had been lost, the user station 29 can continue to work. However, if this packet data record had still arrived at the user station 29 , but its response in the direction of the central station 15 was lost, the user station 29 'in turn will send its last packet data record again in the direction of the central station 15 , where it will also arrive because of the now known new destination address.

The method just described is also used when a new user station wants to connect to the packet radio network 17 .

In addition, there is the case that the packet radio network 17 expands greatly, so that previous connections between the central station 15 and intermediate stations 14 are lost. This is assumed in FIG. 1 insofar as the radio connection 27 between the central station 15 and the intermediate station with the identifier * 8 * is interrupted. The same applies to the radio link between the central station 15 and the intermediate station 14 with the identifier * 4 *.

Even now, the mobile user station 29 'can no longer establish a connection to the central station 15 . It therefore outputs the search address 55, which is indicated schematically in FIG. 4a.

In this exemplary embodiment, the receiving intermediate stations do not now incorporate their own destination address in the direction of the central station 15 into the received search address 55 , since this can no longer be permitted in the meantime. But even if this connection still existed, it could be that there is now a better and / or shorter connection to the central station 15 . Therefore, a method is now used which corresponds to the configuration method which has already been discussed in connection with FIG. 3. Each user station 13 / intermediate station 14 namely inserts its own identifier into the search address 55 and sends out a changed search address 59 again, as is indicated in FIG. 4c.

This process is continued, a search address 61 being indicated in FIG. 4d, which is sent out by the intermediate station shown in broken lines in FIG. 1 with the identifier **.

When the central station 15 receives the search address 61 , it derives from it the new destination address 63 shown in FIG. 4e, via which the central station 15 now reaches the user station 29 '.

By the method just described, the packet radio network 17 dynamically reconfigured, so to speak, when individual radio connections 27 can no longer be maintained.

In this context, it should also be mentioned that it is not absolutely necessary for each user station 13 / intermediate station 14 of the packet radio network 17 to have its own individual identifier. Since the path of the packet data record through the packet radio network 17 is determined not only by the identifier of the destination station but also by the identifier of the individual intermediate stations 14 , several user stations 13 with the same identifier may be present, provided that they are only from the central station 15 via different intermediate stations 14 be reached from.

Referring to Fig. 5, the basic structure of an intermediate station 14 will now be explained in more detail.

Each intermediate station 14 , which can also be a user station 13 , initially has a transmission / reception antenna 65 which has been omitted in FIG. 1 for the sake of clarity. The transmit / receive antenna 65 is provided with a transmit / receive switch 66 which routes the incoming packet data records via a line 67 to an address evaluator 68 . This Adreßbewerter 68 decides whether the received packet data set is determined for the intermediate station 14, to be further sent from the repeater station 14 or is to be ignored. If the received packet data record is to be forwarded by the intermediate station 14 because it contains either a configuration address or a search address, or because the intermediate station 14 is to serve as an actual intermediate station here, the packet data record is led via a line 69 to a transmission amplifier 71 . This transmission amplifier 71 forwards the transmission data via a line 72 to the transmission / reception switch 66 , which leads the data to the transmission / reception antenna 65 .

It should be noted here that the packet data sets are sent out by means of short transmission pulses, which can be in the range from 20 to 50 ms. This means that the packet radio network 17 does not include any standing radio waves, but that the individual stations 13 , 14 , 15 only transmit if they actually want to send packet data records. In this way, the individual stations 13 , 14 , 15 consume little transmission energy. The packet records include e.g. B. a certain number of digitized data that are transported according to a fixed pattern. In this way, the packet radio network 17 connects the individual user stations 13 to the central station 15 and, via this, to the main computer 11, according to a random time-sharing method.

If the received packet data record is intended for the intermediate station 14 itself, the packet data record is forwarded via a line 73 to a cluster controller 74 . The cluster controller 74 temporarily stores the data from the packet data record.

Furthermore, it has a device 75 for generating difference data, the purpose of which will be explained in more detail later.

The cluster controller 74 is connected via a two-way line 76 to an emulation device 77 , which simulates a data terminal that can be connected to the main computer 11 . This is indicated in FIG. 5 by a further two-way line 78 , which leads to a data terminal indicated at 79 , which is a PC 80 in the example shown. Emulation device 77 and data terminal 79 are combined in a terminal station indicated at 81, on which the simulated data terminal 79 is generated.

In this way, the user can use the terminal station 81 to conduct a virtual dialog operation with the main computer 11 , although the terminal station 81 itself is not a data terminal for the main computer 11 . In this way it is e.g. B. possible with the help of a simple PC 81 to simulate an IBM data terminal 3270 , with which one can edit programs on a main computer 11 in real dialog mode.

This processing takes place in such a way that a screen page of the simulated data terminal 79 is transmitted from the main computer 11 to the user station 13 / intermediate station 14 via one or more packet data records, where it is buffered by the cluster controller 74 . In simulated dialog mode, data from the transmitted screen page - the z. B. can be a screen mask - changed. The changed data are recorded by the previously mentioned device 75 for generating difference data and are forwarded on a line 83 to a cyyptography device 84 . This cyptography device 84 is used to encrypt and reduce the data to be transmitted as a data packet set. Because of the transmission of differential data and the cryptographing and reduction of these differential data, only a few data are exchanged between the main computer 11 and the terminal station 81 , although an entire screen page is shown on the simulated data terminal 79 . This method allows relatively little data to be transported over a packet data record, so that the transmission times for a packet data record can be in the range from 20 to 50 ms. In this way, it is possible to connect up to 50 terminal stations 81 to the main computer 11 on the packet radio network 17 on a single frequency, and thereby to guarantee real interactive operation.

The cryptographed and reduced data are passed on via a line 85 to a device 87 for address generation. This device 87 is also connected via a line 88 to the address evaluator 68 , from which it receives the received destination address. The device 87 converts the received destination address according to the method described in connection with FIG. 2 into the new destination address with which the packet data record is routed to the central station 15 . The packet data set thus provided with a destination address is led via a line 89 to the transmission amplifier 71 , from where it reaches the transmission / reception antenna 65 via the transmission / reception switch 66 .

The intermediate station 14 shown further comprises a device 91 for the network configuration, which is connected via a further two-way line 92 to the device 87 for address generation. This network configuration device 91 monitors the time that elapses before the response to a transmitted packet data record arrives at the intermediate station 14 . If a predetermined period of time is exceeded here, the device 91 for network configuration causes a search signal 54 to be output, as was explained in connection with FIG. 4 above. The device 91 also stores the own identifier of the intermediate station 14 as well as the identifier of the central station 15 .

It should also be mentioned that the configuration addresses or search addresses received from the intermediate station 14 are also loaded into the device 87 for address generation via the connecting line 88 . In this case, the device 91 for the network configuration causes the creation of a changed configuration address or a changed search address.

The central station 15 , shown schematically in the block diagram in FIG. 6, is constructed in a similar manner to the intermediate station 14 . A transmission / reception switch 94 , which performs similar tasks to the transmission / reception switch 66, is included at the transmission / reception antenna 64 . In this way, a received packet data record arrives in an address evaluator 95 , which at the same time serves as a buffer and takes over a kind of multiplexer function. In other words, the address evaluator 95 ensures that the various terminal stations 81 access and are operated by the main computer 11 from the user stations 13 using the time sharing method. For this purpose, the address evaluator 95 leads with its output line 96 to a cluster controller 97 , which essentially corresponds to the cluster controller 74 of the intermediate station 14 . In interactive mode via the connecting line 24 to the main computer 11 , the data which the cluster controller 97 temporarily stores are changed. The changed data are fed as differential data via an output line 98 into a cryptography device 99 , which performs the same tasks as the cryptography device 84 from FIG. 5.

The cryptographed and reduced data are transmitted via an output line 101 to a device 102 which, like the address evaluator 95, performs a type of multiplexer / demultiplexer function.

The differential data set to be transmitted arrives via a line 103 into a device 104 for address generation, which in turn corresponds to device 87 . The device 104 for address generation is also loaded via a line 105 with the destination address via which the associated reference data set had reached the central station 15 . This destination address also reaches device 102 , where it ensures synchronization of the time sharing.

In the device 104 , the packet data record to be transmitted is supplied with the correct destination address and is then led via a line 106 to a transmission amplifier 107 , which is connected to the transmission / reception switch 94 via its output line 108 .

The central station 15 also has a device 109 for the network configuration, which is connected to the device 104 for address generation via a connecting line 110 .

Device 109 outputs the configuration signal that was discussed in connection with FIG. 3.

Finally, it should be mentioned that the so far described Communication system an automatically building network  encompasses, whose hierarchy adjusts itself, so to speak and dynamic to the changing circumstances of the network adjusts. This packet radio network can easily accommodate other users is fault tolerant to the failure of Intermediate stations and can be established in an area whose spatial extent is not predictable. It is not Network control center required because every user too acts as an intermediate station and the network con figured. If the network grows too big, a second central can station that has its own identifier and set up its own radio data network that is entirely or can partially overlap with that of the first central station.

With regard to the networked computer system described, the use of this communication system has the advantage that a real terminal dialog can be carried out on a frequency of up to 50 terminals in a random time-sharing process via a virtual connection to the main computer. Since reduced and compressed packet data sets are transmitted, the individual stations in the radio data network 17 each only have to go on the air very briefly, so that little transmission energy is required.

Claims (23)

1. Crosslinked computer system in which a communication system (12) packet data sets between at least one host computer (11) and any of a number of user stations (13, 14) to be replaced, wherein the communication system (12) comprises at least one central station (15) , characterized in that the central station ( 15 ) is connected to the users ( 13 , 14 ) via a packet radio network ( 17 ) which transports the packet data records. 2. Networked computer system according to claim 1, characterized in that the packet radio network ( 17 ) comprises intermediate stations ( 14 ) between the central station ( 15 ) and the user stations ( 13 ), the intermediate stations ( 14 ) receiving the packet data records and sending them on. 3. Networked computer system according to claim 1 or 2, characterized in that at least some of the user stations ( 13 ) are intermediate stations ( 14 ). 4. Networked computer system according to one of claims 1 to 3, characterized in that at least some user stations ( 13 , 29 ) are mobile. 5. Networked computer system according to one of claims 1 to 4, characterized in that the user stations ( 13 , 14 ) each comprise a cluster controller ( 74 ), which saves a screen page to be processed and, after processing, creates a differential data packet from the changed data, which is transported over the packet radio network ( 17 ). 6. A networked computer system according to one of claims 1 to 5, characterized in that the central station ( 15 ) comprises at least one cluster controller ( 97 ) which stores a screen page to be processed and, after processing, creates a differential data packet from the changed data, which via the Packet radio network ( 17 ) is transported. 7. Networked computer system according to one of claims 1 to 6, characterized in that each user station ( 13 , 14 ) comprises an emulation device ( 77 ) which simulates a data terminal ( 79 ) provided for the main computer ( 11 ), so that a user of the user station ( 13 , 14 ) can process data with and / or on the main computer ( 11 ). 8. Networked computer system according to one of claims 1 to 7, characterized in that each packet data set comprises a destination address ( 37 , 46 ), via which its destination ( 13 , 14 , 15 ) in the packet radio network ( 17 ) is fixed. 9. A networked computer system according to claim 8, characterized in that the destination address ( 37 , 46 ) comprises the identifiers of the intermediate stations ( 14 ) which the packet data record from the sending location ( 13 , 14 , 15 ) to the destination ( 13 , 14 , 15 ) must go through. 10. A networked computer system according to claim 9, characterized in that the destination address ( 37 , 46 ) additionally comprises a sending location identifier ( 41 ) and a destination identifier ( 42 ). 11. Networked computer system according to claim 10, characterized in that the target address ( 37 , 46 ) is composed of the sequential sequence of the transmitter identifier ( 41 ), the identifiers ( 43 , 44 ) of the intermediate stations ( 14 ) and the target identifier ( 42 ) so that the destination address ( 37 ) for the transport from the central station ( 15 ) to the user station ( 13 ) in reverse order represents the destination address ( 46 ) for the transport from the user station ( 13 ) to the central station ( 15 ). 12. Networked computer system according to one of claims 1 to 11, characterized in that the central station ( 15 ), the intermediate stations ( 14 ) and the user stations ( 13 ) are constructed in such a way that the packet radio network ( 17 ) configures itself. 13. Networked computer system according to claim 12, characterized in that the central station ( 15 ) comprises a device ( 109 ) for the network configuration, which emits a configuration address ( 48 ) when the packet radio network ( 17 ) is started, which identifies the identifier of the central station ( 15 ) and a configuration identifier ( 49 ), and that at least some intermediate stations ( 14 ) and some user stations ( 13 ) incorporate their own identifier into the received configuration address ( 48 ) and, if necessary, send out the changed configuration address ( 51 , 53 ) again , wherein the intermediate stations ( 14 ) and the user stations ( 13 ) derive their own destination address ( 46 ) for addressing the central station ( 15 ) from the configuration address ( 51 , 53 ) received and possibly previously changed by other intermediate stations. 14. Networked computer system according to claim 12 or 13, characterized in that at least some intermediate stations ( 14 ) and some user stations ( 13 ) comprise a device ( 91 ) for the network configuration, which when switching on the relevant station ( 13 , 14 ) or If the previous connection to the central station ( 15 ) is interrupted, it sends out a search address ( 55 ) which includes the identifier of the station ( 13 , 14 ) itself, the identifier of the central station ( 15 ) and a configuration identifier ( 49 ), and that the intermediate stations ( 14 ) install their own identifier in the received search address ( 55 ) and, if necessary, send the changed search address ( 59 , 61 ) again, the central station ( 15 ) deriving from the received and possibly previously changed search address ( 61 ) the new destination address ( 37 ) for the searching user station ( 13 ) or the searching intermediate station ( 14 ) and sends them back. 15. A method for operating a networked computer system ( 10 ) comprising a via a central station ( 15 ) of the communication system ( 12 ) with a number of user stations ( 13 , 14 ) in communication with the main computer ( 11 ), the method has the steps:

• - generating a packet data record to be exchanged between the main computer ( 11 ) and one of the user stations ( 13 , 14 ),
• - Transporting the packet data set via the communication system ( 12 ),
• - Receiving the packet data set at the central station ( 15 ) or at one of the user stations ( 13 , 14 ), and
• - processing the packet data set,

characterized in that the packet data sets are transported by radio over a packet radio network ( 17 ). 16. The method according to claim 15, characterized in that the step of transporting the packet data set comprises receiving the packet data set at an intermediate station ( 14 ) and transmitting the received packet data set by radio. 17. The method according to claim 15 or 16, characterized in that the step of generating a packet data record comprises generating a destination address ( 37 , 46 ) characterizing the transport route of the packet data record and providing the packet data record with the destination address ( 37 , 46 ). 18. The method according to any one of claims 15 to 17, characterized in that the step of processing the packet data set comprises the steps:

• - intermediate storage of the packet data record,
• - Change some data from the packet data set, and
• - Generation of a packet data record to be returned, which essentially only contains the changed data.

19. The method according to claim 18, characterized in that the step of changing some data comprises the step of emulating a data terminal ( 79 ) for the main computer ( 11 ). 20. The method according to claim 19, characterized in that the step of changing some data comprises the further step of simulating a real terminal dialog between the data terminal ( 79 ) and the main computer ( 11 ). 21. The method according to any one of claims 17 to 20, characterized in that the step of generating the destination address ( 37 , 46 ) comprises the steps:

• - At least once after switching on the packet radio network ( 17 ) or after a failure of the packet radio network ( 17 ) sending configuration signals ( 47 ) from the central station via the packet radio network ( 17 ),
• - receiving and changing the configuration signals at the intermediate stations ( 14 ),
• - Forwarding the changed configuration signals ( 47 ),
• - Receiving the possibly changed configuration signals ( 47 ) at the user stations ( 13 ), and
• - Deriving the destination address ( 46 ) specific to the receiving user station ( 13 ) in the direction of the central station ( 15 ).

22. The method according to any one of claims 17 to 21, characterized in that the step of generating the destination address ( 37 , 46 ) comprises the steps:

• - At least once after switching on a new user station ( 13 , 29 ) or after a partial failure of the packet radio network, transmission of search signals ( 54 ) from the relevant user station ( 13 , 29 ) via the packet radio network ( 17 ),
• Receiving and changing the search signals ( 54 ) at the intermediate stations ( 14 ),
• - Forwarding the changed search signals ( 54 ),
• - Forwarding the changed search signals ( 54 ),
• - Receiving the possibly changed search signals ( 54 ) at the central station ( 15 ), and
• - Deriving the destination address ( 37 ) specific to the searching user station ( 13 , 29 ) from the direction of the central station ( 15 ).