FI104607B - Wireless system implemented over a wired network - Google Patents

Description

V

104607

FIELD OF THE INVENTION The present invention relates to wireless communication systems, and in particular to wireless communication systems implemented over a fixed network.

The invention relates in particular to the implementation of a cellular radio system capable of wireless communication over an existing fixed network, but it can also be utilized in the implementation of an entirely new network. For example, a fixed network may be an Integrated Service 10 Digital Network (ISDN) or a Public Switch Telephone Network (PSTN). Wireless data transfer can utilize cellular radio systems already in use, such as GSM (Global System for Mobile Communications) or those under development, such as UMTS (Universal Mobile Telecommunication System) and PCS (Personal Communication System). Wireless data transmission can also utilize other wireless digital systems that are not actual cellular radio systems but provide free mobility within a limited area, such as DECT (Digital European Cordless Telephone).

Cellular radio systems implemented over a fixed network utilize 20 fixed local area exchanges LE (Local Exchange) instead of MSC (Mobile Switching Center), which conventionally leaves the base station subsystem under the local exchange in the network hierarchy. Thus, the network hierarchy, from the lowest level, is the Base Transceiver Station BTS (Base Transceiver Station), the Base Station Controller (BSC), the local exchange LE, and the upper centers of the fixed network. 25 Local exchanges are often small and do not include features that support a cellular network. In this case, the top network-level cellular radio system component is the base station controller and, in particular, the network elements essential for mobility management, control and signaling, the MSC and the Visitor Location Register (VLR) are missing. This causes problems, for example, in managing the network matching functions IWF (InterWorking Functions) and handovers. In addition, the traditional network hierarchy described above requires interconnections with fixed network connections. Another problem with the traditional solution is the underutilization of the base station controllers because the local exchanges are 35 small. In the future, the local exchange LE may be expected to have some general features supporting mobile communication. The problem 104607 2 arises when the network consists of different levels of local exchanges LE, which, however, should be able to provide a similar service to the mobile stations.

One way to implement a cellular radio network over a fixed network is disclosed in "Switching and Signaling Generic Requirements for Network 5 Access Services to Personal Communication Services (PCS) Providers", GR-2801-CORE, Issue 1, December 1993, Bellcore, Bell Communications Research, Chapter 2, pages 1 to 26. In this solution, the radio interface is connected to a local network in a fixed network connected to an Advanced Intelligent Network (AIN) with a Service Control Point 10 SCP. The problem with the solution is that most of the fixed exchanges in the existing network are not connected to an intelligent network, so mobile services vary from one exchange to another. In addition, a network element incompatible with the wireless access standard, in particular, is responsible for managing mobility. The problem with the solution is that it also requires new interfaces that are still being standardized.

Finnish Patent Application 950,776 discloses a solution in which a group of two or more base station systems has one master base station controller that controls the other group of base stations and takes care of radio-specific functions related to radio path management. The solution requires that the 20 local exchanges LE either connect to the service control point SCP of the intelligent network AIN, or contain intelligent functions themselves. The solution also requires new signaling connections. Problems with this solution include the underutilization of standard base station controllers under small exchanges, cross-connections with a fixed network, and the inability of legacy local exchanges that do not have an intelligent network interface to build the network. A further problem with the solution is that it requires new signaling connections, which also requires more signaling. The problem with this solution, too, is that it needs a new interface that is still subject to standardization.

It is an object of the invention to combine fixed and wireless communication networks 30 into a single communication network which provides all cellular network services, making the best use of the fixed network, making the service level independent of the local network of the fixed network.

This object is achieved by the wireless communication system implemented by the wired network 35 according to the invention, comprising subscriber devices, base stations for connecting subscriber devices over a radio network, 104607 3 radio service unit base stations and a local

The invention further relates to a communication network in which the system according to the invention can be applied. A wireless communication network according to the invention, such as a cellular radio network or a base station system consisting of subscriber devices, base stations, radio service units controlling them, is characterized in that the signaling and traffic below the local center.

The invention is based on the idea of utilizing a fixed network with existing elements as efficiently as possible in building a wireless communication network using existing interfaces, maximizing the capacity of standard elements of a wireless communication network, and providing a standard quality service independent of fixed network features. The major advantages of the invention are thus the independence and availability of service 20 from the characteristics of a fixed network local exchange, thanks to the radio service unit, the efficient and natural use of fixed network connections without cross-linking and the use of standardized interface interfaces. In addition, in a preferred embodiment of the invention without base station controllers, the advantages are reduced number of network elements used and consequently reduced signaling need and signaling costs compared to existing solutions and better utilization of the capacity of the network elements used. Further, in a preferred embodiment of the invention, it is possible to optimize call routing by routing calls between local exchanges under one radio service unit as local calls and reducing the need for signaling in a handover between base stations controlled by the radio service unit.

Thanks to the invention, various network adapter functions IWF and other special functions such as speech transcoding TRAU (Transcoder 35 Rate Adapter Unit) can also be located in the radio service unit.

104607 4

Advantageous embodiments of the system of the invention and the communication network are disclosed in the appended dependent claims 2-12 and 14-19.

1 is a block diagram illustrating a fixed network wireless communication network according to the invention and a first preferred embodiment thereof, FIG. a block diagram illustrating call routing optimization in a first preferred embodiment, Figs. 4 and 5 are block diagrams illustrating the division of functions of the mobile services switching center MSC and the visitor location register VLR into functional units and their allocation to different network elements.

The basic principles of the invention can be applied to the connection of any wireless access network to a local exchange of a fixed network.

In a preferred embodiment of the invention, the access network is a GSM based radio system such as PCS1900 and a fixed network 20 ISDN network. For details of the GSM system, reference is made to ETSI GSM Recommendations and the book "The GSM System for Mobile Communications", M.

Mouly, M. B. Pautet, Palaseau, France, 1992, ISBN: 2-9507190-0-7.

1 is a block diagram illustrating network elements of a first preferred embodiment of the invention. Unlike a conventional GSM-based network, base stations BTS are not connected to a base station controller and thereby to a mobile switching center, but base station BTS is directly connected to a fixed network local exchange LE, which is normally connected to another fixed network ISDN. Unlike conventionally, the local exchange LE is also connected to the radio service unit RSIWU, which is located hierarchically above the local exchange LE. Together * »

two local switches LE are connected to the radio service unit RSIWU to provide a clearly illustrated network structure. One radio service unit RSIWU can very well be connected to several local exchanges LE or just one local exchange LE. Similarly, one or more base stations BTS can be connected to the local exchange LE. The radio service unit RSIWU controls the base stations BTS that are connected to the radio service unit RSIWU

5 104607 to the connected local exchanges LE and are thus in the hierarchy below the local exchanges LE. The base stations BTS communicate via the standard radio interface of the PCS 1900 system to personal stations 1A, i.e., subscriber units. The local exchange LE takes care of the call control and routing so that the call from the fixed network to the ISDN subscriber unit 1A or from the fixed network to the ISDN circulates back from the local exchange LE to the same local exchange LE as shown in FIG. The call may also be routed to another local exchange under the same radio service unit. Radio Service Unit 10 The RSIWU operates in handovers in a manner similar to the Anchor-MSC of the GSM system, whereby a relatively short post-handover connection between the radio service unit and the local exchanges can be established. This post-handover connection is depicted in the figure by dashed line 3.

Figure 1 also makes it clear that cross-connections with fixed network connections 15 are not needed, but that the necessary new connections complement the fixed network by utilizing fixed network connections as efficiently as possible. Thus, the base stations BTS and the radio service unit RSIWU use only fixed network ISDN connections with their local exchanges LE for communication and signaling. They do not therefore form a physically or hierarchically separate transmission network from the fixed network 20 ISDN.

Preferably, the radio service unit RSIWU also includes equipment for data calls for the network adapter functions IWF. When a data call is established through a radio service unit RSIWU, it connects the correct type of network adapter function to the IWF data connection, as illustrated in FIG. Similarly, in a voice call, the radio service unit RSIWU may connect the transcoder equipment TRAU, which e.g. performs a conversion between PCM (Pulse Code Modulation) speech and lower rate speech coding used on the radio path. Examples of network matching and transcoding functions are described in the GSM system specifications.

3 is a block diagram illustrating a first preferred embodiment

* Q.

: routing optimization according to the embodiment. In it, the A-subscriber of the wireless network (calling) has called the B-subscriber B (called) of the subscriber unit 1A to the fixed subscriber unit 1B. If the local exchange LE-A to which subscriber A's subscriber unit 1A is connected via the base station BTS is located under the same radio service unit 35 RSIWU as the local exchange LE-B to which subscriber B's subscriber unit is connected, the call can be routed to both subscribers. the call control is at the A-subscriber's local exchange LE-A. The call is then routed through the radio service unit RSIWU via the B-subscriber's local exchange LE-B to the B-subscriber unit 1B. The established connection is depicted in the figure by solid line 2. Routing as a local call is also possible 5 if the A subscriber's subscriber unit is fixed and the B subscriber's subscriber unit is a wireless communication subscriber unit, or if both subscriber units are wireless. If the subscriber B is wireless, the local exchange LE-B of the subscriber B only transmits the A-bis interface between the radio service unit RSIWU (Radio System InterWorking Unit) and the base station BTS.

Figures 4 and 5 show an example of the division of mobile network functions into functional units that can be allocated to physical network elements of an ISDN-based PCS network. Functional unit names end with the letter F (function) to avoid confusion with the physical network elements in which the functional units can be placed.

15 Each functional unit is briefly described below.

The Base Station Controller Function (BSCF) corresponds to the functionality of the Base Station Controller (BSC) of a standard GSM network.

The Base Station Controller Function Additions (BSCF +) manages many of the functions of the MSC in the GSM network (in particular the switching capabilities associated with the handover 20). It divides the GSM-type network subsystem and

an A interface between the base station subsystem such that the call control CC

(Call Control) goes to LEF and other signaling to RSCF. The BSCF + acts as an anchor in handovers, performing the associated switching operations. It also converts GSM call control to ISDN call control and includes • · _! 25 other network adapters IWF and GSM network transcoding TRAU. BSCF + can also perform checks on the subscriber's service portfolio.

The Interworking Function (IWF) includes the network adapter functions that are required in data calls to adapt the transmission protocol between the subscriber equipment and the radio service unit RSIWU to the transmission protocol used between the radio service unit and another network, such as PSTN or ISDN. IWF also provides other non-speech services, such as fax services.

35 The LEF (Local Exchange Function) contains the standard ISDN

LE functions (by default National ISDN 3) call i 104607 7 control. LEF may support the call signaling related to a handover switching based on the NCA (non call associated signaling) and / or a three-party call. The invention does not propose any changes to the standard LEF because the ISDN-based PCS1900 system should be able to work with all standard ISDN local exchanges in the fixed network.

The Radio System Control Function (RSCF) provides many of the functions of the MSC. It controls the radio resources and handover between the local exchange LEs or the base station controllers BSC. The RSCF is also an interface between GSM A-interface and MAP protocols.

The Handover Decision Function (HOF) has been separated from the RSCF to allow for an even higher level of control over the handover process. Only high level control, such as overload control, is done in the HOF. The actual handover is performed by BSCF + RSCF.

15 The Visitor Location Registen Function (VLRF) is responsible for the functions of the VLR visitor location register in the GSM network. It is divided into two parts to allow e.g. Allocation of functions partly to the intelligent network service control point (SCP) and partly to the access network. In addition, the distribution enables extensions to the HLR hierarchy of the visitor location register VLR -20. The division could follow Bellcore's division into Interface Management AM (Access Manager) (VLR1F) and Bellcore Visitor Register VLR (VLR2F).

SCF (Service Control Function) is a fixed network standard SCF that provides standardized intelligent network services. In addition, it can perform location queries for HLRF (equivalent to gateway MSC) and VLRF (local location queries), and cooperate with VLRF in responding to intelligent network queries. The invention does not require the existence of an SCF because the ISDN-based PCS1900 system should be able to work with all standard ISDN 30 local exchanges on a fixed network.

'Home Location Register Function (HLRF) corresponds to the functionality of a normal home location register in a GSM network.

In addition, EIRF (Equipment Identification Register Function) and 35 possible Short Message Service functions (SMS-GIWF) are associated with network functionality.

Gateway / lnterworking Function). However, they do not need to be described here, as their supply is operator dependent.

Of the functions listed above, the BSCF, BSCF +, IWF, and LEF handle the network service for traffic channels, the others handle only signaling.

5 In this context, communication refers to the transmission of speech, data and other forms of information such as images.

Figures 4 and 5 illustrate that the functional units can be allocated quite freely in the solutions of the invention. The only limitations are that the LEF unit must always be located in the local exchange LE and the 10 BSCF + radio unit RSIWU. These functional units route connections.

Figure 4 shows, in accordance with the basic principle of the invention, the division of functional units into different network elements. The local exchange LE is, by way of example, assumed to be a "stupid" exchange with only 15 call control LEFs. The local exchange LE may connect to the service control point SCP of the intelligent network AIN as shown by dashed line 4, but the connection is unnecessary in the case shown in the figure. The other functional units, i.e. BSCF, BSCF +, IWF, RSCF, HOF, VLR1F and VLR2F, are located in the radio service unit RSIWU. The radio service unit is directly connected to the 20 home location register HLR, where the HLRF unit is located. The local exchange LE transmits transparently the interface between the radio service unit RSIWU and the base station BTS, which in the GSM system has an A-bis interface. The interfaces and interfaces between the local exchange LE and the radio service unit RSIWU and the local exchange LE and the base station BTS are standard 1 *: 25 interfaces and interfaces specified for a fixed network.

As functions and features available over the network increase, they may be transferred from the radio service unit RSIWU to the rest of the network. Figure 5 illustrates a preferred embodiment in which virtually all signaling-only functions are obtained from a fixed network.

30 The local exchange LE is connected to the service control point I of the intelligent network AIN via the intelligent network interface. The SCP contains the SCF and VLR2F units. Alternatively, only the SCF unit could be located there and the VLR2F unit would be located in conjunction with the VLR1F unit. If the local exchange contains sufficient intelligent functions, the intelligent network may not be needed, but the units placed in the service control point SCP may be completely located in the local exchange LE.

9 104607 9

In the embodiment shown in Figure 5, there is a separate access manager AM (VLR1F, RSCF, and HOF). Access management AM may be implemented as an intelligent network service or as a separate element. If there is no access control, these units are placed in 5 radio service units RSIWU. Alternatively, some of the aforementioned units may be located in the radio service unit RSIWU and some in the intelligent network service control point SCP.

In the embodiment shown in Fig. 5, a base station controller BSC having a BSCF unit 10 is connected between the base station BTS and the local exchange LE. One or more base station controllers BSC may be connected to one local exchange LE, to which one or more base stations BTS may be connected, respectively. The interface and interface between the base station controller and the local exchange are standard interfaces and interfaces specified for a wired network. The local exchange LE then transparently transmits the A interface between the radio service unit RSIWU and the 15 base station controllers. The interface between the base station controller and the base station is the normal A-bis interface of the wireless network. In the absence of a base station controller BSC, the BSCF unit would be located in the radio service unit RSIWU and the local exchange LE would transparently transfer the A-bis interface.

In the embodiment of Figure 5, only the BSCF + and IWF units are located in the radio service unit 20 and the LE LEF unit in the local exchange. The home location register HLR, in which the HLRF unit is located, is communicated through both the service control point SCP and the VLR2F unit.

It is to be understood that the foregoing description and the accompanying drawings are merely intended to illustrate the present invention. Various variations and modifications of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention set forth in the appended claims.

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Claims (19)

1. Wireless data transmission system implemented by means of a fixed network, which system comprises subscriber devices (1A), base stations (BTS) for connecting the subscriber devices (1A) to the network via the radio path, a radio service unit (RSIWU) for controlling the base stations (BTS) ) and a fixed network (ISDN) with local exchange (LE) for call control, characterized by the radio service unit (RSIWU) located hierarchically above the local center (LE) and the base station (BTS) below the local exchange (LE). 2. A system according to claim 1, characterized in that the call control is arranged in the local exchange (LE), which is arranged to transmit data traffic from the subscriber device (1A) via the base station (BTS) via the radio service unit (RSIWU) to the fixed network (ISDN) and data traffic from the fixed network (ISDN) via the radio service unit (RSIWU) via the base station (BTS) to the subscriber device (1A). 3. A system according to claim 1 or 2, characterized in that the radio service unit (RSIWU) comprises the division of the interface between the wireless data transmission network subsystem and the base station subsystem in call control and other signaling, the anchor functions of the switching network and the transmission control network transmission functions. (ISDN) to the wireless network and vice versa. System according to claim 1, 2 or 3, characterized in that network adaptation functions (IWF), speech transcoding functions and / or other special functions requiring wireless tai or data transmission are provided in the radio service unit (RSIWU). System according to any of the preceding claims, characterized in that the interface (A-bis) between the base stations (BTS) and the radio service unit (RSIWU) is transparently connected via a local exchange (LE) by means of the fixed network connections. System according to any of the preceding claims, characterized in that the radio service unit (RSIWU) comprises means for dynamic connection and exclusion of base stations (BTS) to and from the control of the radio service unit (RSIWU). 7. A system according to any of the preceding claims, characterized in that the system comprises an intelligent network (AIN) with a connection (SCP) to the local exchange (LE), and that part of the wireless data transmission system. »The functions of the ring network (SCF, VLR2F) and properties are provided in the intelligent network. 8. A system according to any of the preceding claims, characterized in that the system comprises a passage control (AM), with a connection to the radio service unit (RSIWU), and that part of the functions of the wireless data transmission network (VLR1F). , RSCF, HOF) and properties are provided in the passage control (AM). System according to any of the preceding claims, further comprising base station controllers (BSC) for control of associated base stations (BTS), characterized in that the base station controllers (BSC) are hierarchically connected under the local exchange (LE) for control by the radio service unit ( RSIWU), and that the interface (A) between the radio service unit (RSIWU) and the base station controller (BSC) is transparently connected via the local exchange (LE) by means of the fixed network connections. System according to claim 9, characterized in that part of the functions of the wireless data transmission network (BSCF) are arranged in the base station controller (BSC). System according to claim 1, characterized in that one or more local exchange (LE) is connected to the radio service unit 20 (RSIWU), the call control is arranged in the local exchange (LE), whereby a subscriber device's call is arranged to be disconnected from the local exchange (LE) via the radio service unit. (RSIWU) to the same local exchange or another local exchange connected to the same radio service unit (RSIWU). : 25 12. System according to claim 1, characterized in that the system is arranged to direct a call between subscriber devices (1A, 1B) of A and B subscribers via the radio service unit (RSIWU) from the local exchange (LE-A) of the subscriber device of the A subscriber. the local exchange (LE-B) for the B subscriber's subscriber device so that the call control is maintained in the local center. The subscriber device (LE-A) of the A subscriber's subscriber device, if both the subscriber device of the A subscriber device and the local exchange (LE-B) of the subscriber's subscriber device are connected to the same radio service unit (RSIWU) . 13. Wireless data transmission network, such as a cellular radio network or a base station system consisting of subscriber devices (1A), base stations (BTS), these controlling radio service units (RSIWU), characterized by the signaling and traffic channels between the base stations (BTS) and the radio service unit (RSIWU) are connected via the local network's local switchboards (LE) so that the radio service unit (RSIWU) arrives hierarchically over the local exchange (LE) and the base station (BTS) below the local exchange (LE). Data transmission network according to claim 13, characterized in that base stations (BTS) which form a wireless connection to subscriber devices connect to local exchanges (LE) by means of connections and interfaces specified in the fixed network (ISDN). 15. A data transmission network according to claim 13 or 14, characterized in that the local exchange (LE) transmits the interface (A-bis) between the base station (BTS) and the radio service unit (RSIWU) transparently and handles the call control. 16. The data transmission network of claim 13, 14 or 15, characterized by the radio service unit (RSIWU) comprising at least one of the following functions: division of the interface between the wireless data transmission network subsystem and the base station subsystem into call control and other signaling; the anchor function of the clutch; Transmitting the call control from the fixed network (ISDN) to the wireless network and vice versa; and the features of the wireless data transmission network (BSCF, RFCF, HOF, VLR1F, VLR2F) and features that the local exchange (LE) and base station (BTS) lack. «F: 25 17. The data transmission network according to claim 13, characterized in that the base stations (BTS) and the radio service units (RSIWU) are arranged to use only for the fixed network (ISDN) with local exchanges (LE) for traffic and signaling. 18. A data transmission network according to any of claims 13-17, characterized in - Characterized in that the radio service unit (RSIWU) is arranged to connect both subscriber devices (1A, 1B) of both A and B subscribers directly to the local exchange (LE-A) of the A subscriber's subscriber device, whereby the local exchange (LE-B) for B the subscriber's subscriber device transmits only the interface (A-bis) between the radio service unit (RSIWU) and the base station (BTS), where the local centers (LE-A, LE-B) of both the subscriber devices of the A and B subscribers are connected to the same radio service unit ( RSIWU). 104607 17 19. A data transmission network according to claim 13, characterized in that network matching functions, speech transcoding functions and / or other special functions required by the wireless tai or data transmission are provided in the radio service unit (RSIWU). m •>