NL1007717C2 - Exchange of communication traffic in satellite communication system - Google Patents

Abstract

A ground communication network (2) is made up of clusters of telecommunication networks (4,5,6) and land mobile telecommunication networks (7,8,9), while a satellite communication network (3) comprises telecommunication satellites (12,13,14) and ground stations (15,16). For a satellite communication user (24) to connect to a network (5), a transmission path (25) is established and an address code is provided comparable with the country code for exchanging traffic within the satellite network. The address code and that of the corresponding mobile network are used to exchange traffic between mobile telecommunication networks and ground stations An independent claim is included for a telecommunication system

Description

Short designation: Exchange of telecommunication traffic in a telecommunication system comprising a satellite 1 communication network and a ground communication network.

The present invention relates to the exchange of telecommunication traffic in a telecommunication system comprising a satellite communication network, built up of a number of telecommunication satellites in different orbits around the earth, which are operatively linked via radio transmission connections to one or more ground stations, which ground stations are mutually connected via a transmission connection. as well as a ground communications network composed of a number of fixed and mobile telecommunications networks, clusters of fixed and mobile telecommunications networks coupled to ground stations of the satellite communications network and telecommunications traffic being exchanged using an addressing plan, with the satellite communications network assigned its own unique address code .

In addition to and in addition to the known fixed telecommunication networks, in which users can establish voice and data communication via a fixed, wired connection, mobile communication via radio connections has grown enormously in recent years.

Apart from differences in the transmission techniques employed, land mobile communication is characterized by a structure in which the coverage area of a mobile radio telecommunication network is divided into areas of geographically limited dimensions, also referred to as cells. Within a cell, radio traffic is possible between a so-called base station and users' radio communication equipment.

When the user moves, a cell-to-cell communication link continues. The geographic position of a user, ie the cell in which he is currently located, is regularly scanned and stored in the system. An example of such a cellular mobile radio communication system is the "Global System for Mobile communications (GSM)". Systems based on these standard are now designated GSM-900, GSM-1800 and GSM-1900. Other cellular telecommunications networks based on a cell structure are, inter alia, 1007717 2 denoted by the acronyms AMPS, D-AMPS in the United States and PDC in Japan.

In a given area, different mobile networks can be operated by different operators. In general, 5 the operation of mobile telecommunication networks is limited to national borders. In order to facilitate international mobile telecommunications traffic, agreements have been concluded between the different national operators regarding subscriber access to each other's mobile telecommunications networks. The fixed telecommunications networks and the mobile telecommunications networks are also interconnected to enable telecommunication traffic between "fixed" and "mobile" users.

In general, telecommunications traffic between countries is exchanged through so-called "International Carriers" and at a global level through so-called "Global Carriers". These are 15 telecommunication companies that provide transmission facilities for the exchange of telecommunications traffic at international and global levels.

A further communication possibility for mobile users is satellite communication networks, built up from a number of telecommunication satellites in different orbits around the earth, which are operatively connected to one or more ground stations via radio transmission links. The ground stations are distributed over the earth in such a way that global coverage is obtained.

Depending on the network, the ground stations 25 can be interconnected via a transmission connection, for example in the form of a ring network. The ground stations are in turn linked to clusters of fixed and land mobile telecommunication networks, if desired through the intervention of global and international carriers.

A user, provided with suitable satellite radio communications equipment, can be connected, via a direct radio link to a telecommunications satellite and a respective ground station, to a user in a fixed or land mobile telecommunications network and, of course, to other users of the satellite communications network.

35 satellite communications networks proposed in practice include Globalstar and Iridium, using a relatively large number of ground stations 1007717 3 and satellites orbiting in low orbit, ie "Low Earth Orbit (LEO ) ". ICO and Odyssey are satellite communications networks that use a relatively small number of satellites orbiting medium-height orbits around the Earth, also known as "Medium Earth 5 Orbit (MEO)" satellite communications networks.

In order to make use of the existing pricing structures, it has been proposed to charge telecommunication traffic to and from a satellite communication network in a manner similar to the land mobile telecommunication networks through the intervention of global and 10 international carriers.

As will be understood by experts, the costs for mobile telecommunications are higher than for telecommunications traffic via the fixed telecommunications network already in use. This is reflected in higher connection costs per unit time for mobile telecommunications traffic compared to fixed connections.

In communication between mobile users in the same network or mutually directly linked mobile telecommunication networks and in calls from mobile users to the fixed telecommunication network, these higher call costs can be settled directly with the mobile users. The mobile telecommunication networks are provided with suitable pricing options for this purpose. At a national level, the higher call costs when using the mobile telecommunications network can also be recovered from a regular user who requests a call with a mobile user. This is because calls from the fixed network to a mobile user take place via one or more designated access centers.

However, at international and global level, calls from a fixed user to a mobile user and between mobile users of non-coupled mobile telecommunications networks are charged on the basis of connections between two users in different countries of the fixed telecommunications network. This can be explained by the fact that international and global connections with mobile users of the same transmission routes, via international and global carriers, are used as for the exchange of telecommunications traffic between users connected to fixed telecommunications networks. The costs for the use of the mobile part of the connection in the mobile telecommunication network of the called mobile user are then borne by the operator of the relevant mobile telecommunication network. Depending on the rate structure, with current rates this can quickly lead to losses in the order of USD 0.50 per 5 minutes.

Another problem arises when a mobile subscriber cannot be reached in his home network but temporarily uses a mobile telecommunication network elsewhere, for example in another country.

Namely, when establishing a connection from a fixed to a mobile user, a connection is first made to the home network of the mobile user and, depending on the current position of the mobile user, the call is forwarded to the mobile telecommunication network where the user is currently located. In the unlikely event that the mobile subscriber concerned does not answer the transferred call 15, the guest mobile network can switch back to the mobile home network. This, for example, in order to be able to use a message or messaging service and the like, to leave a spoken or written message for the relevant mobile user. It will be clear that this forward and reverse switching, also referred to as "thromboning", is highly undesirable because of the unnecessary use of expensive transmission facilities in the relevant telecommunication networks.

The object of the invention is to provide a solution to the above-described drawbacks and shortcomings in exchanging telecommunication traffic between fixed and mobile telecommunication networks at both international and global level.

In a first aspect, the invention provides a method for exchanging telecommunication traffic in a telecommunication system mentioned in the preamble, characterized in that a mobile network address added to the address code of the relevant satellite communication network is added to the mobile telecommunication networks which are coupled to a ground station. such that telecommunications traffic with a mobile telecommunications network is exchanged via a combination of the address code of the satellite communication network and the network address code of the relevant mobile telecommunications network via the interconnected ground stations.

1007717 5

The invention advantageously makes use of the fact that when the ground stations of a satellite communication network are mutually coupled, for example in the form of a ring line, an alternative transmission route can thereby be made available for the exchange of telecommunication traffic between fixed and land mobile telecommunication networks. This in addition to and in addition to the transmission capacity made available by international and / or global carriers, in this case the regular route.

By adding network address codes for the mobile telecommunications networks to the unique address code of a satellite communications network, according to the invention, these can be directly selected via the transmission route along the ground stations of the satellite communications network, allowing direct international and global exchange of telecommunications traffic. becomes possible with national mobile telecommunications networks.

Contrary to the existing regular route for the international and global exchange of telecommunications traffic between fixed and mobile networks, whereby the existing routing tables in the international switching centers do not allow any distinction between fixed and mobile telecommunication networks, in this embodiment of the method according to the invention a mobile telecommunications network is addressed in a unique way. That is, by routing the relevant telecommunications traffic through the ground stations of the satellite communications network.

Since, according to the addressing or numbering plan of the invention, mobile telecommunication networks are directly addressable, it is now possible to settle the costs of the mobile transmission part with the calling fixed user on international and global connections from fixed users to mobile users. Also referred to as "Mobile Terminating Charges (MTC)".

It will be clear to those skilled in the art that the addressing plan according to the invention makes possible a very flexible operation. Operators of ground stations and / or mobile networks thus have very flexible transmission capacity for the exchange of international telecommunications traffic between fixed and 1007717 6 mobile users, without the disadvantages of irreplaceable mobile transmission costs.

In a further embodiment of the method according to the invention, wherein the clusters of fixed and mobile communication networks 5 are operatively connected via the so-called transmission gateways to the ground stations of the satellite communication network, which transmission gateways are mutually coupled via a transmission connection, it is provided that telecommunication traffic between clusters of fixed and mobile telecommunication networks are partly exchanged via interconnected ground stations and partly via interconnected transmission gateways.

With this embodiment of the method according to the invention it is possible to have the exchanged telecommunication traffic in the ground communication network run partly via the regular route 15 (international carrier / global carrier) and partly via the alternative route between the coupled ground stations. This provides a very flexible routing of telecommunication traffic, also in those cases where ground communications networks are not directly connected to a ground station of the satellite communications network. For example, in the current concept of Odyssey, seven interconnected ground stations are provided, so that clusters of fixed and land mobile telecommunication networks will be connected to the ground station in another country via an international carrier, for example.

The addressing plan according to the invention further offers an effective possibility to solve the problem of thromboning. Yet a further embodiment of the invention provides for this purpose the exchange of telecommunication traffic with a user who uses a mobile telecommunications network guest by establishing a communication connection using the relevant network address code of the mobile telecommunications network which the user uses.

Advantageously, use is made of the fact that the current position of a mobile user is continuously scanned and stored. By making this information available in the domain of the satellite communication network, a connection from a fixed to a mobile user can be established directly 1 0 0 7 7 1 7 7 via the relevant network address code of the mobile telecommunication network where the user is located. Without first switching to the home network and then transferring to the guest network. It will be clear that the scarce mobile transmission facilities are used efficiently in this way.

In yet a further embodiment of the method according to the invention, in which the telecommunication satellites are arranged for exchanging telecommunication traffic via radio transmission connections with users provided with mobile satellite radio communication equipment, mobile telecommunication traffic is exchanged between mobile telecommunication networks and the satellite communication network by establishing of a communication link using the network address code assigned to a respective mobile telecommunications network.

In other words, in a satellite communication network in which users can establish direct radio links with a communication satellite, such as, for example, in the Odessey concept, the addressing plan according to the invention is advantageously used for the direct exchange of telecommunication traffic between mobile satellite communication users and land mobile users. Tariffs can be charged in accordance with the costs of the transmission facilities and other desired compensation.

In a second aspect, the invention also provides a telecommunication system, comprising a satellite communication network, composed of a number of telecommunication satellites in different orbits around the earth, which are operatively coupled via radio transmission links to one or more ground stations, which ground stations are mutually connected via a transmission link, as well as a ground communications network composed of a number of fixed and mobile telecommunication networks, wherein 30 clusters of fixed and mobile telecommunication networks operatively coupled to ground stations of the satellite communications network and wherein the ground stations are provided with routing means for exchanging telecommunication traffic according to an addressing plan comprising a unique address code for selecting of the satellite communications network, characterized in that the routing means are provided with selection means for exchanging telecommunications traffic with 1007717 8 a mobile telecommunications network, using a unique network address code added to the address code of the satellite communication network for selecting a respective mobile telecommunications network.

By suitable selection, mobile telecommunications traffic according to the method of the invention can be routed via the satellite communication network, in association with an appropriate pricing. For charging purposes, the existing charging devices of a respective network can be used, by suitable control in accordance with the addressing plan according to the invention.

In the case of a telecommunication system in which the clusters of fixed and mobile telecommunication networks are operatively connected to the ground stations via so-called transmission gateways, which transmission gateways are mutually coupled via a transmission connection, the transmission gateways 15 are provided with routing means for the purpose of the invention. exchange telecommunications traffic between clusters of mobile and fixed communications networks partly through interconnected transmission gateways and partly via interconnected ground stations.

Routing, routing means and selection means for routing telecommunication traffic are known per se to those skilled in the art and require no further explanation.

For optimized routing of telecommunication traffic to mobile users in guest networks, in accordance with yet a further embodiment of the invention, existing signaling systems in both the satellite communications network and the ground communications network are advantageously used. These signaling systems are preferably based on the same standard, for example fully compatible with the CCITT signaling system and designed for determining the current mobile telecommunications network with which telecommunications traffic must be exchanged with a relevant user, using the network address code of the relevant mobile telecommunications network. .

In the most advanced embodiment of the telecommunication system according to the invention, direct mobile radio communication is also provided between satellite communication users and land mobile users, wherein the satellite communication network and the 1007717 9 mobile telecommunication networks are preferably based on the same standard, for example the aforementioned GSM standard. In the concept according to the invention, the ground stations then function as "super mobile gateway switches", with the advantages of an optimal settlement of 5 call costs for calls with mobile users, optimal routing and without major modifications of the existing infrastructure in international switching centers, international carriers and global carriers.

It will be clear to those skilled in the art that one or more routing stations can also be included in the transmission connection to which the ground stations are interconnected. By providing these routing stations with routing means and selection means for exchanging telecommunication traffic with a connected mobile telecommunication network using its network address code, the same advantages as described above with respect to ground stations can be obtained.

The invention is described in more detail below with reference to the enclosed drawings.

Fig. 1 shows in block diagram form a telecommunication system comprising an interconnected satellite communication network and ground communication network.

Fig. 2 shows in block diagram form the current pricing via international connections from a user in the fixed telecommunication network to a user in the mobile telecommunication network.

Fig. 3 shows, in the form of a sequence diagram, the exchange of telecommunications traffic using the addressing plan of the invention.

Fig. 4 illustrates in block diagram form the effect of thromboning between existing fixed and mobile telecommunication networks.

Fig. 5 shows, in the form of a sequence diagram, the routing of telecommunications traffic based on the addressing plan according to the invention, without thromboning.

The invention is illustrated below without detailed technical descriptions of the fixed and mobile telecommunication networks or satellite communication networks, which is not considered necessary for an understanding of the invention.

«0 0 7 7 1 7 10

More detailed information about the mentioned systems can be found in handbooks and textbooks on fixed, mobile and satellite communication.

Fig. 1 shows in block diagram form a part of a telecommunication system 1, comprising a ground communication network 2 and a satellite communication network 3.

The ground communications network 2 is composed of a number of clusters of fixed telecommunications networks 4, 5, 6, denoted by the acronym PSTN ("Public Switched Telephone Network") and land mobile 10 telecommunications networks 7, 8, 9 denoted by the acronym PLMN ("Public Land Mobile Network ").

The PSTN 4, 5, 6 may be existing fixed, national telephone and data communications networks operated by different operators. Fixed telecommunications networks are also referred to as 15 with the acronym ISDN ("Integrated Services Digital Network").

The land mobile networks 7, 8, 9 may also be operated by different operators and be limited to a particular country or part of a country. For example, the PLMN 7, 8, 9 can operate according to the cellular "Global System for Mobile 20 communications (GSM)", i.e. GSM-900, GSM-1800 and GSM-1900.

The PSTN 4, 5 and the PLMN 7 are associated to a cluster 10, while the PSTN 6 and the PLMN 8, 9 form a cluster 11.

The satellite communication network 3 comprises a number of telecommunication satellites 12, 13, 14 and a number of ground stations 15, 25 16. The telecommunication satellites 12, 13, 14 orbit the Earth in different orbits. The number of telecommunication satellites 12, 13, 14 and the number of ground stations 15, 16 are chosen such that complete coverage of the entire earth is preferably obtained. Satellite communications networks with telecommunications satellites in a relatively low Earth orbit, the so-called "Low Earth Orbit (LEO)", require more satellites and ground stations for full coverage than telecommunications satellites in a so-called "Middle Earth Orbit". The telecommunication satellites 12, 13, 14 are operatively connected to one or more of the ground stations 15, 16 via radio transmission links 17.

The cluster 10 of fixed and mobile telecommunications networks is operatively connected to the ground station 15 via a so-called "gateway" or "International Switching Center 1007717 11 (ISC)" 18 via a transmission link 20. Likewise, the cluster 11 is operatively connected to the ground station 16 via a gateway 19 and a transmission link 21.

The gateways 18, 19 are interconnected via international and global transmission connections 22, while for the telecommunication system according to the invention the ground stations 15, 16 are interconnected via a transmission connection 23, for example in the form of a ring network.

The transmission links 22 and 23 are suitable for exchanging telecommunications traffic and may include both wired and wireless transmission paths, including optical fibers.

The transmission links 22 can again be divided into transmission links made available by so-called "International Carriers" and / or "Global Carriers".

In practice, telecommunications traffic between clusters 10 and 11 is exchanged through gateways 18, 19 and the transmission link 22. A user in the PSTN 5 of cluster 10, for example, who wishes to communicate with a mobile user in the PLMN 8 of cluster 11, will be connected to the PLMN 8 via the gateways 18 and 19 and the transmission link 20 22. In the PLMN 8, a radio connection is then established with the respective mobile user (not shown).

When a satellite communication user 24 desires a communication link with a user in, for example, the PSTN 25, a communication link will be established comprising a radio transmission path 25 between the satellite communication user 24 and the telecommunication satellite 14, the radio transmission connection 17 between the telecommunications satellite 14 and the ground station 16, the transmission link 21 between the ground station 16 and the gateway 19 and then via 30 the transmission link 22 and the gateway 18 to the PSTN 5 of cluster 10.

Telecommunication traffic between different satellite communication users 24 which are connected to different telecommunication satellites will be handled via the own transmission connection 23 of the satellite communication network 3.

1007717 12

For addressing telecommunication traffic to be exchanged with the satellite communication network 3, the satellite communication network is provided with an address code, comparable to the country code for exchanging telecommunication traffic with a PSTN in a country concerned. The address code for satellite communications networks has been assigned by the ITU ("International Telecommunications Union"). By dialing the address code assigned to the satellite communication network after the international access code (now generally 00), a connection to the satellite communication network 3 is established.

Fig. 2 schematically illustrates the settlement of the costs for the international and / or global transmission facilities, i.e. the use of gateways or ISC, such as gateways 18, 19 and prior art transmission link 22.

15 Suppose that a subscriber to the PSTN 4 in country A wants to communicate with a subscriber to the PSTN 6 in country B. In the usual manner, contact will be made with the gateway 18 via the international access code, in which case included routing tables from the user-specified country code, a connection is made to the gateway 19 to which the PSTN 6 is connected. In the PSTN 6, the desired subscriber will then be contacted in the usual manner via the area code and the subscriber number.

The cost of using the gateways 18, 19 and 25 of the transmission link 22 will be charged to the calling subscriber in the PSTN 4 as international call charges.

Similarly, if the subscriber in the PSTN 4 wishes to connect to a subscriber in the PLMN 8, which in this example is part of the same cluster as the PSTN 6, an international connection via the gateways 18, 19 and the transmission link 22 will be to be made. In the PLMN 8, a radio path is then established with the desired mobile user. Although the costs for establishing connections in the PLMN 8 are higher than in the PSTN 6, it is not possible to recover these costs from the calling subscriber in the PSTN 4. This subscriber pays the same international rate as for a connection with a regular user in 1007717 13 the PSTN 6. It will be clear that the operator of the PLMN 8 suffers a certain loss because the costs for providing the radio connection in the PLMN 8 are not reimbursed.

This problem arises in the same way when a mobile user from the PLMN 7 of country A wishes via the gateways 18, 19 and the transmission connection 22 to connect to a mobile user in the PLMN 8 of country B.

While it is theoretically possible to recover the costs of using the PLMN 8 from the called mobile user, 10 it is considered undesirable by land mobile operators, as this may weaken their competitive position. Furthermore, mobile users will switch off their mobile phone to avoid being burdened by incoming international calls. It will be clear that this is at odds with the idea of continuous accessibility in mobile telecommunications and can even lead to loss of income for the land mobile operators. This is because in the relevant mobile telecommunication network itself no more connections can be made with a switched off mobile phone, nor from the fixed telecommunication network that is part of the same cluster or the same country, as the relevant mobile telecommunication network.

Given the rapid growth in the number of land mobile telecommunication networks, direct addressing of land mobile telecommunication networks is practically impossible. Unambiguously addressing these 25 networks would lead to an explosion of the routing tables in gateways 18, 19, not to mention the scarce availability of free codes.

The invention provides a solution to this problem, via an addressing or numbering plan, using the alternative route via the satellite communication network 3. The land mobile telecommunication networks PLMN are assigned a network address code which is subordinately added to the address code of the satellite communication network. .

Suppose the satellite communication network 3 is characterized by address code "881x", where x is a number from 0-9 indicating a 1007717 14 determined satellite communication network and that according to the invention the network codes "012" and "013 are assigned to the PLMN 8, 9, respectively. "have been granted.

In order to establish a connection internationally and globally with, for example, a subscriber in the PLMN 8, where 5 is assumed that the satellite communication network 3 has the address code "8812", the address will then have to be given: "8812 012 xxxxxx", where "xxxxxx" is the number under which the relevant mobile user is registered in the PLMN 8 (subscriber number). Fig. 3 shows in a sequence diagram the connection path established in this way.

Suppose a user from the PSTN 4 wishes to connect to a user in the PLMN 8. Via the address code "8812" it is signaled that a connection to the satellite communication network 3 must be established via the gateway 18 of an international carrier, 15 possibly by intervention of a global carrier 28, also referred to as a "Global Long Distance Carrier (GLDC)". By providing the router means 26 of the ground station or "Earth Station (ES)" 15 with suitable selection means, for selecting network address codes, the relevant call path is transferred via the gateway 19, possibly with the intervention of 20 a GLDC 29, to the PLMN 8 accomplished. For this purpose, the gateway 19 only needs to have the routing information for the connected PLMN. A connection to the relevant PLMN 8 is then established on the basis of this limited number of network address codes.

Contrary to the above description, the costs for setting up a radio connection in the PLMN 8 can now be settled with the user in the PSTN 4 who requests the relevant connection. This is because the network address code can be used to immediately deduce that a connection to a mobile network is being made, as well as the location and identity of the relevant land mobile telecommunications network. These costs can then be recovered directly from the user requesting the call, also referred to as "Mobile Terminating Charging (MTC)". Via the usual international settlement of call costs between operators and carriers, the costs of using the PLMN 8 can then be mutually settled.

00771715

It will be clear that the same settlement structure is possible for calls from the PLMN 7 in country A to the PLMN 8 in country B.

Via the addressing or numbering plan of the invention 5, telecommunication traffic from the satellite communication network 3 to a land mobile telecommunication network 7, 8, 9 can of course also be charged on the basis of the network address code. For the purpose of the invention, use can also now advantageously be made of the already existing cost exchange structures between carriers and operators of networks. 10 In the case of gateways that do not have a direct connection to a ground station of the satellite communication network, for example, part of the transmission link 22 ic the regular route can initially be followed to a gateway, such as gateways 18 or 19, which do direct transmission connection 20 15 and 21 respectively to a ground station 15, 16. According to the invention, the alternative route via the transmission connection 23 of the satellite communication network 3 can be used from such a gateway 18, 19.

Even when clusters of PSTN and PLMN, for example 20, are directly connected to a ground station 15, 16, according to the invention, both telecommunication traffic via the regular route ic the transmission connection 22 of the ground communication network 2 as well as the alternative route via the transmission connection 23 of the satellite communication network 3 are exchanged.

In accordance with the invention, the exchange of international and global telecommunications traffic between fixed and / or land mobile telecommunication networks suffices in principle to provide routing means in ground stations 15, 16. Diagrammatically indicated with reference number 26 as well as suitable routing 30 means 27 in the gateways 18, 19. In practice this will usually amount to the suitable programming of the already existing router means for exchanging telecommunication traffic via the transmission connection 23 or the transmission connection 22 and the telecommunication traffic via the transmission connections 20 and 21 between a ground station and a 35 gateway.

1007717 16

In other words, the invention provides for an extension of the exchange of telecommunications traffic in the horizontal direction across the transmission link 23 between the ground station 15, 16 as well as in the vertical direction through the transmission links 20, 21 between the ground stations 15, 16 and the gateways 18, 19 with international and global telecommunications traffic between clusters 10,11 of fixed 4, 5, 6 and land mobile 7, 8, 9 telecommunication networks.

Fig. 4 schematically illustrates the manner in which prior art connects to a mobile user 10 who uses a land mobile telecommunications network in, for example, another country.

Assume that the mobile user 30 has the PLMN 8 as home base, also referred to as "Home PLMN (HPLMN)" and that the user 30 guest uses the PLMN 7, also referred to in this connection as "Visited PLMN (VPLMN)" .

If the fixed user 31 now wishes to have a communication connection with the mobile user 30, the fixed user 31 will enter the country and subscriber number of the relevant mobile user 30 as the address code for this purpose. This leads to a connection being established 20 via the gateways 18, 19, the transmission connection 22 to the home base of the relevant mobile user 30, i.e. the HPLMN 8. IN the HPLMN 8, the user 30 is found to be abroad located. From the HPLM 8, an international connection is now again set up via gateways 18 and 19 and another transmission channel from the transmission link 22 to the relevant land mobile network where the mobile user 30 is currently located, in this example the VPLMN

7.

It can be clearly seen from Fig. 4 that an additional international connection 30 and additional connection means are confiscated at national level for establishing the final connection, while the user 31 pays the normal rate as if the user 30 his home network was HPLMN 8. The costs for the second international connection (the routing connection) are charged to the mobile user 30.

The situation becomes even more dramatic when, for example, the user 30 uses a telecommunications service such as "Call 1007717 17

Forwarding on Busy ", that is, a arriving call must be forwarded to a messaging or messaging service. Then, from the VPLMN 7, a third international transmission path through the gateways 18, 19 and the transmission link 22 to the HPLMN 8 must be established, 5 to issue the relevant message in the HPLMN 8. In the figure, this is indicated by dashed arrows In this case, the costs for this third international connection are also charged to the mobile user 30.

With the addressing or numbering plan according to the invention, this problem, which is also referred to as "thromboning", can be solved efficiently. Consider fig. 5 for this.

In cellular land mobile telecommunication networks, such as based on the GSM standard, for example, each mobile network has a so-called "Visitor Location Register (VLR)", in which users are registered who make use of a relevant network and a so-called "Home Location Register (HLR). ) ", which records, among other things, access data of subscribers of the relevant mobile telecommunications network, as well as the current whereabouts of a mobile user, ie the cell and / or the country. Administrative data are registered in an "Administration Register (AR)".

In Fig. 5, for the PLMN 7 and the PLMN 8, the respective VLR, HLR and AR are shown, respectively denoted by the reference numerals 32, 33, 34 and 35, 36, 37. In the case of a satellite communication network 3 which is also based on the GSM 25 standard and allowing direct telecommunication traffic between telecommunication satellites 12, 13, 14 and mobile users 24 with suitable satellite communication equipment (see fig. 1), the satellite communication network 3 is also provided with a VLR 38, HLR 39 and AR 40, as shown schematically in Fig. 5. VLR 38 and HLR 39 and admin 30 40 may, if desired, be common to the entire satellite communication network 3. Of course, a VLR and HLR can also be assigned to each ground station 15, 16, for example.

Information from the various VLRs and 35 HLRs can be requested via a signaling system, such as the existing signaling system C7.

1007717 18

By now registering, according to the addressing or numbering plan according to the invention, the current location of a mobile user in the respective VLR or HLR on the basis of the network address code of the relevant PLMN, the current location of the mobile can be indicated via the signaling connection 5. determined by the user. A connection can then be made directly from the satellite communication system 3 to the relevant PLMN where the user is located.

This therefore means that with the addressing or numbering plan according to the invention an optimal routing of telecommunication traffic 10 is possible, without unnecessary use of international connections.

In the example of Fig. 5, when the fixed user 31 from the PSTN 4 wishes to connect to the mobile user 30 whose PLMN 8 is the HPLMN and which is located in the PLMN 7 as VPLMN, this user will initially according to the invention, addresses are addressed with the address code: "8812 12 xxxxxx".

The address code "8812" thereby leads to the satellite communication network 3. By means of the network address code "012", the signaling system 41 in the HLR 36 of the PLMN 8 can find out the current location of the mobile user 30. By advantageously registering this location according to the addressing plan according to the invention, ie with the relevant network address code, a connection can be established directly from the satellite communication network 3 to the mobile telecommunications network indicated by the relevant network address code.

Instead of directly requesting the current location of a mobile user, via the signaling system, in the HPLMN of the relevant user, the current location of mobile guest users can, if desired, also be in the VLR 38 of the satellite communication system 3 or another common VLR Being registered.

Although the foregoing has only referred to the allocation of a network code to land mobile networks, it will be clear to experts that other telecommunication networks, coupled to a respective ground station, can also be provided with a network address code for exchanging telecommunication traffic via the satellite communication network 3. . This could include nets for special users, both fixed and mobile.

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Therefore, when in the foregoing and the appended claims reference is made to the allocation of network address codes to mobile telecommunication networks, this also includes special (land) telecommunication networks in the context of the invention.

It will further be clear to those skilled in the art that suitable routing stations 42 can be included in the transmission connection 23 for performing the routing function of a ground station, to which a cluster 44 of telecommunication networks is connected via a gateway 43. Via these routing stations 42, use can again be made of all the advantages of the improved exchange of telecommunication traffic according to the invention. Both a ground station 15, 16 and these routing stations 42 included in the transmission connection 23 can be connected directly, without the intervention of a gateway, to fixed and land mobile telecommunication networks.

The invention also comprises an addressing plan in which the ground stations 15, 16 or the routing stations 42 are provided with a unique tracking address code subordinate to the address code of the satellite communication network and wherein the network address code of the mobile and / or other special telecommunication networks is subordinate to such a network. tracking address code.

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Claims (8)

1. A method for exchanging telecommunication traffic in a telecommunication system comprising a satellite communication network, composed of a number of telecommunication satellites in different orbits around the earth, which are operatively linked via radio transmission links to one or more ground stations, which ground stations are mutually connected via a transmission link, as well as a ground communications network composed of a number of fixed and mobile telecommunications networks, where clusters of fixed and mobile telecommunications networks operating with ground stations of the satellite communications network are coupled and telecommunications traffic is exchanged using an addressing plan, whereby the satellite communications network is assigned its own unique address code, characterized in that the mobile telecommunication networks coupled to the ground station operatively coupled to the address code of the respective satellite communication network The added unique network address code is allocated such that telecommunication traffic with a mobile telecommunication network is exchanged via a combination of the address code of the satellite communication network and the network address code of the relevant mobile telecommunication network via the interconnected ground stations. 2. Method according to claim 1, wherein the clusters of fixed and mobile communication networks are connected via so-called transmission gateways to the ground stations of the satellite communication network, which transmission gateways are mutually coupled via a transmission link, characterized in that telecommunication traffic between clusters of fixed and mobile telecommunications networks are partly exchanged via interconnected ground stations and partly via interconnected transmission gateways. A method according to claim 1 or 2, characterized in that for exchanging telecommunication traffic with a user who uses a mobile telecommunication network guest, a communication connection is established using the network address code of the mobile telecommunication network which the user uses. A method according to claim 1, 2 or 3, wherein the telecommunication satellite 1 is adapted for exchanging telecommunication traffic via radio transmission connections with users provided with mobile satellite radio communication equipment, 1007717, characterized. that mobile telecommunication traffic between mobile telecommunication networks and the satellite communication network is exchanged by establishing a communication connection using the network address code assigned to a respective mobile telecommunication network. Method according to claim 1, 2, 3 or 4, characterized in that the transmission connection to which the ground stations are connected includes one or more routing stations to which mobile and / or clusters of fixed and mobile telecommunication networks are connected, whereby telecommunication traffic with a mobile telecommunication network connected to such a routing station is exchanged using its network address code via the relevant routing station. 5. Telecommunication system, comprising a satellite communication network, composed of a number of telecommunication satellites in different orbits around the earth, which are operatively linked via radio transmission connections to one or more earth stations, which earth stations are mutually connected via a transmission connection, as well as a ground communication network composed of a number of fixed and mobile telecommunications networks, where clusters of fixed and mobile telecommunications networks operatively coupled to satellite communications network ground stations and wherein the ground stations are provided with routing means for exchanging telecommunications traffic according to an addressing plan comprising a unique address code for selecting the satellite communication network, characterized in that the routing means are provided with selection means for exchanging telecommunication traffic with a mobile telecommunication network, using Singing of a unique network address code added to the address code of the satellite communication network 30 for selecting a respective mobile telecommunication network. Telecommunication system according to claim 6, wherein the clusters of fixed and mobile telecommunication networks are operatively connected via so-called transmission gateways to the ground stations, which transmission gateways are mutually coupled via a transmission connection, characterized in that the transmission gateways are provided with routing means 1007717 exchange telecommunications traffic between clusters of fixed and mobile communications networks via interconnected transmission gateways and partly via interconnected ground stations. 8. Telecommunication system according to claim 6 or 7, wherein the satellite communication network and the ground communication network are connected to a signaling system and wherein the mobile telecommunication networks are provided with means for registering the reachability of a user in a mobile telecommunication network, characterized in that it signaling system is arranged for determining, based on the means for registering the accessibility of a user of a mobile telecommunication network, the current mobile telecommunication network with which telecommunication traffic is to be exchanged with a relevant user, for the network address code of establishing the relevant mobile telecommunications network a communication link with the user. Telecommunication system according to claim 6, 7 or 8, wherein the telecommunication satellites are arranged for exchanging telecommunication traffic with radio users via mobile transmission connections, provided with mobile satellite radio communication equipment, characterized in that the selection means are arranged for establishing a communication connection. between the satellite communications network and a mobile telecommunications network using the network address code assigned to the relevant mobile telecommunications network. 10. Telecommunication system according to claim 6, 7, 8 or 9, characterized in that the transmission connection to which the ground stations are connected includes one or more routing station to which mobile and / or clusters of fixed and mobile telecommunication networks are connected, wherein the routing stations are provided with routing means and selection means for exchanging telecommunication traffic with a mobile telecommunication network connected to a relevant routing station using the network address code of the relevant mobile telecommunication network. 1 ü 0 7 7 1 7