Method and system for operating a radio communication network

Abstract

A method and a system for operating a radio communication network which is characterized in that a first radio communication network uses at least one function of a second radio communication network by connecting the first radio communication network to at least one module of the second radio communication network.

Description

The invention relates to a method and system for operating a radio communication network according to the preamble of the independent claims.

It is the objective of the present invention to provide a method and a system for operating a radio communication network with a reduced requirement of network infrastructure.

This objective is achieved by providing method and a system as described in the independent claims. Other features which are considered to be characteristic for the invention are set forth in the appended claims.

The inventive idea is in building a general purpose radio service network as an overlay network to a running GSM network by making use of GSM network features, such as authentication, mobility management and signalling channels. Thus using the GSM network as implementation platform for another separated radio network, which is using different radio channels. This radio network can be of any type, including also cellular and satellite networks.

The end device of the general purpose radio service network is co-located to a GSM radio device in the same hardware shelf, such that the GSM functionality's are available for the GSM part of the combined device and the general purpose radio service functionality's for the general purpose radio part. On the network side the GSM authentication, location information and mobility management functionality can be applied for mobility management, authentication and signalling to the general purpose radio network device, due to the fact that it is bundled to the GSM device and therefore e. g. the same location information is valid, the same user is accessing the device, etc. In a more tightly integrated version particular features of the GSM network could be used for both parts of the combined end device. This would for example allow activation of the general purpose radio service device via GSM signalling channels.

DETAILED DESCRIPTION

This invention can be used for all radio communication networks which utilities at least one function of a second digital radio communications network. One example of an implementation using a GSM network is described.

FIG. 1 shows a schematic system architecture of a General Purpose Radio Services Network as an overlay network to a GSM radio network.

The general purpose radio service network can be implemented in two different ways. First using a radio frequency band totally different from the GSM frequency and secondly using parts of the GSM frequency range. The coding scheme of the general purpose radio service can be any available, including GSM. Anyhow which coding scheme and which frequency band is used, the traffic is not transmitted via the GSM air interface.

The general purpose radio module is integrated into a GSM device which is sending and receiving the complete range of GSM signalling information. Please note that special applications may require parallel transceiving of GSM and general purpose radio service information, both signalling and payload. The use of GSM payload channels is not required at all for functionality of the general purpose radio network. This allows the general purpose radio service network devices to use only an IMSI for identification. However it may be required to have the full functionality of a GSM device enabled in the combined device, to enable special features which allow for certain services offerings, e. g. over the air activation or the general purpose radio service network application.

All general purpose radio service network module functions and the GSM network modules radio parts on the combined device are logically separated. However the GSM radio module may pipe through signalling information for the general purpose radio module. The transmission of information using signalling channels transmission capacity is the only direct exchange of information between both modules in the combined client. Both may be implemented using the same hardware resources, such as radio transceiver chips, processors, etc.

Prerequisite for using the general purpose radio service network is that the terminal is attached to the GSM network and the active state of the terminal is kept in the network to guarantee the availability of location and mobility management information required for operation of the general purpose radio service network. Thus it is also assured that a GSM signalling connection is available to send signalling information to the general purpose radio module, using GSM signalling capacity. Therefore the general purpose radio module is able to receive in-band signalling from the general purpose radio service network via it's air interface and out-band signalling via the GSM air interface. Both connections are using distinct frequency bands and/or coding schemes. The out-band signalling scenario may especially be applicable if the general purpose radio module is not attached to the general purpose radio service network and any action shall be triggered, according to the required features and behaviour of the general purpose radio service network application.

All payload generated by the general purpose radio service network is not to be transmitted via the GSM air interface and the GSM core network, rather through the general purpose radio service network interface.

Thus the traffic from the general purpose radio service network is completely invisible for the GSM network and the networks are separated. On the network side information is exchanged only via interfaces to the GSM network. These interfaces are providing genuine GSM information for use by the general purpose radio service network. No information about the general purpose radio service network is gathered or kept in the GSM network on behalf of the general purpose radio service network. Vice versa the general purpose radio service network may also provide it's information to the GSM network as required but is not actively gathering or keeping information.

The general purpose radio service network is using the mobility management information of the GSM network for it's own mobility management. The information used can be any combination GSM location and mobility information data elements, such as cell-ID, LAC, VLR-ID, etc. This information can be polled by the general purpose radio service network via suited MAP, CAP, ISUP, OAP or INAP requests, such as Any-Time-Interrogation, Location-Area-Update, etc or any proprietary command accessing the GSM network information databases. This includes also the base station subsystem application part (BSSAP) and its protocols BSSMAP and direct transfer application part (DTAP). The Databases to be addressed are e.g. MSC/VLR, BSC, and HLR, but can also be any implementation specific database, which may also include non-standardised data elements.

The information can also be actively send by the GSM network. Enabling the GSM network nodes to send appropriate location and mobility management information to the general purpose radio service network requires implementation of appropriate trigger mechanisms. This could be for example a function in the BSC triggering the sending of MSISDN, IMSI or any proprietary ID together with previous and current cell ID as an information message via the CCS7 or any other network interface to the general purpose radio service network whenever a general purpose radio service device roams across cell boundaries. The same mechanism could be implemented using MSC/VKLR ID's. In more sophisticated applications these functions could comprise as well filter lists to filter out information related to subsets of clients with particular attributes.

Please note that the use of GSM network location and mobility information by the general purpose radio service network does not require co-located radio base station sites. However an existing base station subsystem infrastructure would ease installation of general purpose radio services radio equipment enormously from an deployment, installation and roll-out point of view.

The general purpose radio service network nodes and application servers may be implemented by making use of hardware resources in the GSM network, such as base transceiver stations, base station controllers, mobile switching centers, etc. This means that these or other GSM modules are hosting the general purpose radio service network logic's together with their genuine GSM functionality's on the same hardware. This can also include the re-use of existing GSM air interface capacity if the according combination of coding schemes and frequency ranges are used.

As the functions are separated, there is no need for co-located general purpose radio service network radio transceiver stations and GSM base transceiver stations. Nevertheless for reasons of network management, mobility management and ease of operation, it may be beneficial to design the cells of the general purpose radio service network in accordance with the GSM RAN. This could include common radio cell boundaries or even logical structures of higher levels, such as BSC or MSC/VLR areas, especially if the general purpose radio service network is of cellular type. For non-cellular general purpose radio service networks any installation method appropriate to the geographical coverage of the related GSM network may be used.

List of Abbrevations

• GSM Global Standard for Mobile Communication
• IMSI International Mobile Station Identity
• Cell-ID Cell Identity
• LAC Local Area Code
• VLR-ID Visitor Location Register Identity
• MAP Mobile Application Part
• CAP CAMEL Application Part
• CAMEL Customer Application Mobile Enhanced Logics
• ISUP ISDN user part
• ISDN Integrated Services Digital Network
• OAP Operation and Administration Application Part
• INAP Intelligent Network Application Part
• MSC Mobile Switching Center
• VLR Visitor Location Register
• MSC/VLR Mobile Switching Center/Visitor Location Register
• MSC/VKLR Mobile Switching Center/Visitor Location Register
• BSC Base Station Controller
• HLR Home Location Register
• MSISDN Mobile Station Integrated Services Digital Network
• ID Identity
• CCS7 Common Channel Signalling System Number 7
• RAN Radio Access Network
• AUC Authentication Center
• EIR Equipment Identity Register
• OMS Operation and Maintenance Center
• BTS Base Transceiver Station
• BSS Base Station Subsystem (BTS+BSC)

Claims

1-20. (canceled)

21. A method for operating a radio communication network comprising a first radio communication network which comprises a general purpose radio service network, and a second radio communication network which comprises a GSM radio network, the method comprising: operating the first radio communication network as an overlay network to the second radio communication network by using network features of the second radio communication network; generating payload by the first radio communication network through a first radio communication network interface, wherein the networks are separated and the traffic from the first radio communication network is completely invisible for the second radio communication network, and wherein the traffic from the first radio communication network is separate from the traffic from the second radio communication network; selectively exchanging information via standardized interfaces between both networks via MAP, CAP, ISUP, OAP, and INAP requests; and accessing the network information databases of the second radio communication network selectively through Any-Time-interrogation, Location-Area-Update, and any proprietary command.

22. The method according to claim 21, wherein the first radio communication network uses the features for authentication, mobility management, and signaling channels of the second radio communication network.

23. The method according to claim 21, wherein the information used can be any combination of location and mobility information data elements.

24. The method according to claim 22, wherein the information used can be any combination of location and mobility information data elements.

25. The method according to claim 23, wherein the information data elements comprise, selectively, cell-ID, LAC, and VLR-ID.

26. The method according to claim 24, wherein the information data elements comprise, selectively, cell-ID, LAC, and VLR-ID.

27. The method according to claim 21, wherein both radio communication networks use different radio channels.

28. The method according to claim 22, wherein both radio communication networks use different radio channels.

29. The method according to claim 21, wherein both radio communication networks use at least one common radio channel.

30. The method according to claim 22, wherein both radio communication networks use at least one common radio channel.

31. The method according to claim 21, wherein an end device (mobile station) of the first radio communication network is located in proximity to an end device, of the second radio communication network, such that the functionalities of both radio communication networks are available in the same end device.

32. The method according to claim 22, wherein an end device (mobile station) of the first radio communication network is located in proximity to an end device of the second radio communication network, such that the functionalities of both radio communication networks are available in the same end device.

33. The method according to claim 31, wherein selected features of the second radio communication network are used for both parts of the combined end device.

34. The method according to claim 32, wherein selected features of the second radio communication network are used for both parts of the combined end device.

35. The method according to claim 21, wherein during use of the first radio communication network the end device is attached to the second radio communication network and the active state of the end device is kept in the second network to provide the availability of location and mobility management information required for operation of the first radio communication network.

36. The method according to claim 22, wherein during use of the first radio communication network the end device is attached to the second radio communication network and the active state of the end device is kept in the second network to provide the availability of location and mobility management information required for operation of the first radio communication network.

37. The method according to claim 21, wherein the second radio communication network databases to be addressed by the first radio communication network comprise MSC, VLR, BSC, HLR, and AUC.

38. The method according to claim 22, wherein the second radio communication network databases to be addressed by the first radio communication network comprise MSC, VLR, BSC, HLR, and AUC.

39. The method according to claim 21, wherein information is-actively sent from the second radio communication network to the first radio communication network by using appropriate trigger mechanisms.

40. The method according to claim 22, wherein information is actively sent from the second radio communication network to the first radio communication network by using appropriate trigger mechanisms.

41. A system for operating a radio communication network comprising a first radio communication network which comprises a general purpose radio service network, and a second radio communication network which comprises a GSM type radio network, the method comprising: connecting the first radio communication network to at least one module of the second radio communication network. implementing the general purpose radio service network nodes and application servers by using hardware modules of the GSM type radio network, which comprises base transceiver stations, base station controllers, and mobile switching centers; and hosting by these or other GSM modules the general purpose radio service network logics together with their genuine GSM functionalities on the same hardware.

42. The system according to claim 41, wherein the first radio communication network is selectively connected to authentication, mobility management, and signaling modules of the second radio communication network.

43. The system according to claim 41, wherein the first radio communication network is selectively connected to the BTS and the BSC modules of the radio subsystem of the second radio communication network.

44. The system according to claim 42, wherein the first radio communication network is selectively connected to the BTS and the BSC modules of the radio subsystem of the second radio communication network.

45. The system according to claim 42, wherein the first radio communication network is selectively connected to the MSC, the HLR, and the VLR modules of the network subsystem of the second radio communication network.

46. The system according to claim 42, wherein the first radio communication network is selectively connected to the MSC, the HLR, and the VLR modules of the network subsystem of the second radio communication network.

47. The system according to claim 41, wherein the first radio communication network is selectively connected to the AUC, the EIR, and OMC modules of the operation and maintenance subsystem of the second radio communication network.

48. The system according to claim 42, wherein the first radio communication network is selectively connected to the AUC, the EIR, and OMC modules of the operation and maintenance subsystem of the second radio communication network