FI103556B - Procedure for position management and searching in a cellular row io system - Google Patents

Description

103556

Field of the invention The present invention relates to a location management and retrieval method in a cellular radio system

The invention relates to a location management and retrieval method in a cellular radio system, the system comprising base stations transmitting their own base station identifier and neighbor information as base station information. Further, in the location retrieval method, the system comprises mobile stations that receive said base station information for monitoring base stations.

The invention further relates to a cellular radio system and a mobile station.

The cellular radio system comprises base stations transmitting their own base station identifier and neighbor cell information as base station information, and mobile stations receiving said base station information for monitoring base stations.

Background of the Invention

Mobile communication systems require mobile location information for routing incoming calls and other services on the network. The location of each mobile station is usually stored in the system registers with the accuracy of the location area. The size of the location area is adjustable by the network op-20, but it is not advisable to define it very small, because then the location update of the mobile station causes a large amount of signaling load, e.g. limited radio resources on the network. On the other hand, a wide location area reduces location update signaling, but paging a wide area mobile station causes a large amount of signaling load both on the radio path and between the radio network exchange and the base stations when each base station in that location area is directed to send a call. Thus, the problem in designing the location areas is, on the one hand, the unnecessary location update signaling caused by the small location areas and, on the other hand, the high paging signaling load caused by the large location areas when retrieving the mobile station.

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Figure 1 of the accompanying drawings shows a simplified pre- '! 'A block diagram of the structure of the GSM mobile communication system. The units shown in the figure also exist in other cellular networks, but may be differently denoted. The MS in standby or active mode is continuously connected to a base station BTS (Base 2 103556

Tranceiver Station), in the case of Figure 1, to base station BTS1. The Base Station System (BSS) consists of the Base Station Controller (BSC) and the BTSs under its control. The Mat Mobile MSC (Mobile Services Switching Center) generally has a plurality of BSCs. The MSC communicates with other MSCs and through the Gateway Mobile Services Switching Center (GMSC) to the public telephone network. The location information of the mobile station MS and other subscriber data is permanently stored in the system's Home Location Register HLR and temporarily in the visitor location register VLR in which the mobile station MS is currently located. The location register of the mobile station MS is stored in the visitor location register VLR with the accuracy of the location area LA (Location Area).

The geographic area monitored by the visitor register is divided into one or more Location Areas (LAs), within each of which the MS may move freely without informing the VLR. One or more base stations BTS may operate in each location area. The base stations BTS continuously transmit information about themselves and their environment, such as the Base Station Identity Code (BSIC), neighbor cell information and the Location Area Identifier (LAI). Based on the latter, the mat-20 mobile station MS locked to the base station BTS knows which location area LA it is in at any given time. If, upon changing the base station BTS, the mobile station MS detects that the base station location area code LAI has changed, the mobile station sends a location update request to the network. The location area of the mobile station MS is updated to the visitor location register VLR in whose area the mobile station is currently located. Home Register HLR Intermediate; : 25 indicates which VLR area the MS is in.

· · ·: The mobile station MS continuously measures the BTS signals of base stations closest to its location cell, for example, in the event of a possible handover. Based on the neighbor cell information transmitted by the base station on its broadcast channel, the mobile station identifies the neighboring cells it should observe. For example, in a GSM mobile communication system, a mobile station MS can simultaneously measure the signal level and / or quality of up to 32 other base stations in addition to the serving base station.

The location information of the mobile station stored in the registers of the mobile communication system is used, for example, for routing an incoming call. The incoming call is routed based on the location information of the mobile station MS from the home location register HLR and the visitor location register VLR to the mobile services switching center MSC in whose area the called subscriber's mobile station MS is currently located. The mobile services switching center MSC requests from its own visitor location register VLR information about the called subscriber for call setup. The VLR visitor-5 registers the required information of the mobile station MS, including e.g. the location area LA of the mobile station MS stored in the most recent location update, in the case of Figure 1, LA1. Based on the location area information, the mobile services switching center MSC sends a paging call to the mobile station MS via all base stations BTS of the location area in question, in the case of FIG. 1, via BTS1, BTS2 and BTS3. When the called mobile station MS receives the call, it transmits a response to the received call via the most appropriate base station BTS, for example via the base station BTS1 of Figure 1, after which the network allocates a traffic channel for the call and establishes a voice connection to the mobile station MS.

GB-2 243 976 discloses a mobile communication system in which dynamically changing location areas are partially overlapped to avoid round-trip location updating at the boundary between two location areas. The publication mobile station comprises a path memory in which it stores the identities of the base stations whose cells it has passed through since the last 20 location updates. During the location update, the mobile station transmits its stored route list to the base station while clearing its route memory. The base station calculates a cumulative value from the routing lists transmitted by all mobile stations to each of its neighboring base stations and modifies its location area to include the neighboring base stations through which: 25 most mobile stations, i.e. the highest cumulative value. The number of base stations in the location area • * · is changed based on the location update and call load of the base stations. Thus, the system performs continuous //.*, location area planning. In the mobile communication system disclosed in the publication, the base station transmits, either in a continuous broadcast or in a message addressed to a particular mobile station ... 30, location area information comprising a list of base stations in the location area • · · * · ''. In one embodiment of the publication, the mobile station · · ·:: * compares the received base station ID with its · stored in its path memory! The base station IDs. If the corresponding base station ID is not found in the route list, the base station area list information received by the mobile station from the base station compares the base station IDs with the base station in whose area the mobile station 4103556 performed its most recent location update. The mobile station sends a location update request if this base station ID is not included in the location area list. Otherwise, the mobile station stores a new base station ID in its route memory. When retrieving a mobile station, the invitation is transmitted through all of the base stations in the location area that are currently in the location configuration. The problem with the solution presented in the publication is, in particular, the complex structure of base stations and mobile stations, e.g. with changing neighbor base station locks and route memories. Computing and storing dynamic location areas and transmitting a constantly changing list of location areas require special arrangements at the base station. The long access point list transmitted for location management only increases the size of the signaling messages. In order to achieve an optimal location area structure, location area planning has been arranged to be implemented on the basis of quite complex criteria. The proposed location update decision for a mobile station requires a mobile processing capacity of 15 to compare and store various long lists. In addition, changing location areas may in some cases even require additional location updating if the cell in which the mobile station is currently located is removed from the location area of the mobile station.

EP-A-454 648 discloses a mobile communication system in which a mobile station is called in an extended paging area so that a call can be routed despite incorrect location information. In addition to the normal location update of a mobile station, each mobile station has its own uncertainty; the music list stores the location areas where the mobile could possibly be located. In one embodiment, the list of uncertainties includes the current location area of the mobile station, at least one previous location area where the mobile station is registered, and the areas the mobile station has made: a call or answered a sent call. The call is sent to the mobile station in the extended call area according to a pre-stored list of uncertainties if the mobile station does not respond to the call sent in the primary central area indicated by the location information. The invitation can also be sent in only one location area at a time. The problem with this solution is the heavy signaling that • • · causes a large number of signals to be sent at the same time in all the areas of the expanded search area. An expanded search area may include multiple locations within the country if the mobile subscriber travels extensively,. . : 35 causing unnecessary paging load on the network. When a mobile station is called in one location area at a time, the waiting time for call set-up may be embarrassingly long for the calling subscriber. In addition, generating and storing uncertainty for all mobile stations in the system loads the fixed network and requires special arrangements from the network.

BRIEF DESCRIPTION OF THE INVENTION It is an object of the present invention to provide location management and paging in a cellular radio system in a simple low system loading manner while also reducing unnecessary signaling in the network.

This new type of location management is achieved by a method according to the invention, characterized by deriving a contact area of a mobile station MS from base station information, storing a contact area of a mobile station MS with each network activity, and updating the contact area information when .

A novel type of mobile paging is achieved by a method according to the invention, characterized in that method 20 stores a contact area of a mobile station MS in connection with each network activity, calls the mobile station MS via base stations in the last stored contact area, and calls the mobile station MS if the mobile station does not respond within a preset time to a call sent through the base stations of the contact area.

The implementation of the location management and paging according to the invention is achieved by a cellular radio system of the type described in the preamble, characterized in that the system is adapted to derive a mobile station MS contact area from base station information to store a mobile station. when the mobile station does not receive the base station broadcast frequency: -. in the position information, no identifier belonging to the contact area, 35 to send a call to the mobile station via the base stations of the most recently stored contact area 6103556 and to send the mobile station a call via cellular base stations of the cell area indicated by the contact area cell information if the mobile station does not reply within the predetermined time.

The invention further relates to a mobile station adapted to receive base station identifier and neighbor cell information transmitted by a base station as base station information for monitoring base stations, and characterized in that the mobile station is adapted to derive contact area information from base station information and when not receiving any identifier belonging to the contact area in the base station information on the base station broadcast frequency.

The invention is based on the idea that location management and retrieval is arranged based on the cellular structure of the network utilizing neighbor cell information of base stations without separate location areas.

The location management according to the invention is implemented by storing a contact area identifier, for example, a contact cell base station identifier or a contact cell base station identifier and neighbor base station identifiers on both the fixed network side and the mobile station. As the mobile station moves from one cell to another within the network 20, it compares the base station identifier it receives from the cell base station and the neighboring base station identifiers with the contact area identifiers. When no contact area identifier is present between the base station identifier received by the mobile station and the neighbor base station identifiers being monitored, the mobile station registers to the cell base station, whereby the fixed network and the mobile message updates the cell area identifier, e.g. If the mobile station is otherwise connected to the network, for example, when making or receiving a call, using another telecommunications service, or sending an additional service request to the network, a new contact area identifier 30 is stored as the contact area identifier.

The search according to the invention is carried out by initially sending a call to the mobile station through the base stations of the contact area stored in location management. If the mobile station does not respond to this call, the preset '·. Within 35 time, an invitation is sent to the mobile station via the base stations indicated by the base station information of the base stations of the stored contact area 7 103556. In the latter step, the call to be transmitted can be restricted to transmitting only through neighboring base stations that are not in the contact area. If necessary, the first step of the call may be implemented in two pagings, whereby the mobile station is initially called through the stored contact cell base station and if the mobile station does not respond to the transmitted call within a predetermined time, the mobile station is sent through the base station designated by the cell contact information.

The advantage of such a location management and retrieval method is that no separate location areas need to be designed for the 10 networks.

A further advantage of the paging method according to the invention is that it reduces the signaling load of the radio network. The call of a mobile station according to the invention can be targeted to only one cell, for example, when the mobile subscriber is an almost stationary office user, in which case the call signaling is very small.

A further advantage of the location management method of the invention is that the base station broadcast frequencies do not need to transmit location area IDs or codes when there are no separate location areas in the network. The base station of the cellular radio system according to the invention does not transmit any information specifically intended for location-only management, so signaling from the base station to the mobile station can be minimized with this solution.

A further advantage of the location management procedure is that the location update load is distributed evenly over the various base stations of the radio network when the network is not •.:.: Distributed to the fading location areas of the location update.

The advantage of the cellular radio system and the mobile station according to the invention is a simple structure, since the implementation of the invention utilizes the structures and functionality intended for other functions of the network. List of figures

The invention will be explained in more detail below with reference to the accompanying drawings, in which Fig. 1 shows a simplified block diagram of a cellular radio system: ...: Fig. 2 shows a first example of a cellular structure of a radio network; 4 shows a second example of a cellular structure of a radio network, 5 shows a flowchart of a search method according to a preferred embodiment of the invention, and FIG. 6 shows a flowchart of a search method according to a secondary embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION The present invention is applicable to any cellular type mobile communication system. The invention will now be described in more detail by way of example in connection with the pan-European digital mobile communications system GSM. Figure 1 shows a simplified structure of the GSM network as described above. For a more detailed description of the GSM system, reference is made to the GSM Recommendations and the book "The GSM System for Mobile Communications", by M. Mouly & M. Pautet, Palaiseau, France, 1992, ISBN: 2-9507190-0-7.

Figure 2 illustrates a simplified example of a cellular structure in which the geographical area covered by a network is divided into cells C1-8 such that, when in each cell, the mobile station MS communicates with the network via a base station BTS1-8 located in that cell. According to the present invention, the cellular structure of the network is not divided into location areas. The network base stations BTS1-8 transmit in accordance with GSM recommendations with their broadcasting frequency e.g. has its base station ID BSIC and neighbor cell information.

The transmitted neighbor cell information may also include information on cells other than those conventionally considered as neighbor cells. Thus, the concept of neighbor cell in this application does not necessarily mean geographically contiguous or adjoining cells, but all foreign cells reported by the base station with its broadcast frequency. All mobile stations 30 located in the cell area receive the broadcast transmitted by the base station and perform the signal measurement of the reported base stations in the manner specified in the GSM recommendations.

• · <In this application, the term cell identifier is used to mean: - /. hansa identifiers to identify a cell in the network and thereby define: 35 the geographical scope of the contact area concept. Although the invention will be described below mainly in connection with the processing of a base station identifier, other unique identifiers transmitted by the base station in the nature of a broadcast may be used as contact area identifiers. Thus, in this application, the base station identifier should be understood to mean any identifier identifying the cell in the network.

In the cellular radio system according to the invention, instead of the location areas, the contact area information is used as the location information of the mobile station. In the preferred embodiment of the invention, the contact area is the contact cell, or cell through which the mobile station is last connected to the network. The activities of the mobile station constituting the network connection 10 include, for example, making or receiving a call, requesting an additional service, and other telecommunications services provided by the network, as well as the contact area update described below.

In the following, the invention will be described in more detail in the light of the preferred embodiment with reference to Figure 2. The contact cell identifier, e.g., the base station identifier BSIC, is stored in both the mobile station MS and the fixed network, e.g., the mobile switching center MSC or the base station controller BSC, upon termination of the mobile station's network connection. In Figure 2, the last network activity of the mobile station MS is assumed to be in the terminated cell C1, so the base station identifier BSIC1 20 of the contact cell C1 is stored in, for example, the base station controller BSC and the mobile station MS. For base station measurements, the mobile station MS continuously receives base station information from base station BTS1 which comprises transmitting base station identifier BSIC1 and neighbor base stations BTS2, BTS3,: BTS4, BTS5, BTS6 and BTS7, BSIC2, BSIC3, BSIC4, BSIC4, BSIC4, BSIC4. The mobile station MS according to the invention also uses this base station information for location management by comparing the base station information last: T: with the identifier BSIC1 of the contact cell C1 it has stored. The result of the comparison is a common identifier BSIC1 for the data, whereby no action is required for location management. When the mobile station MS moves to cell C7 according to the pattern 20 in Figure 20, the mobile station MS receives base station information transmitted by base station BTS7 including base station identifiers BSIC7, BSIC2, BSIC1, BSIC6 and IDs of base station BTS7 not shown in FIG. The mobile station compares the received weapon: ·. 35 is still a common identifier for the data being compared, so location management still does not require action. As the route proceeds further along route 20, the mobile station MS receives base station information transmitted by the base station BTS6 of cell C6, which the mobile station MS again compares with its stored contact cell identifier BSIC1 as described above.

Further, the mobile station MS may find that the identifier BSIC1 is found in the neighboring cell identifiers of the base station BTS6, respectively, as above in the area of cell C7. Next, the mobile station MS moves on route 20 to the area of cell C8 where it receives base station information transmitted by base station BTS8, including base station identifiers BSIC8, BSIC6, BSIC5 and identifiers of base station BTS8 neighbor base stations not shown in the figure. The mobile station compares the contact cell identifier BSIC1 with the received base station information. The same base station identifiers are not found in the comparison, whereby the mobile station transmits a contact cell update message to the base station BTS8, and at the same time updates the base station identifier BSIC8 to its own contact cell identifier. Similarly, on the fixed network side, for example, the base station controller BSC stores the BSIC8 of the base station BTS8 as the new contact cell identifier of the mobile station MS.

Figure 3 illustrates, as method steps, the location management of a mobile station in a preferred embodiment. From step 30 to step 31, if the mobile station MS is running any network activity. At the end of the network connection between the base station BTS1 and the mobile station MS in step 31, the identifier of the last accessed base station BTS1, e.g. the base station identifier BSIC1, is stored in the mobile station MS and the fixed network, e.g., the mobile switching center MSC or the base station controller BSC. If the mobile station MS has no network activity in progress, at step 33, the base station information received from the base station in the mobile station MS is compared with the contact cell identifier stored. While in cell C7 of Figure 2, the mobile station MS compares base station information BSIC7, BSIC2, BSIC1, BSIC6, etc. with a contact cell identifier BSIC1. Because the data to be compared have both • · ·. 30 identifier BSIC1, no contact cell update is performed. The mobile station can continue to travel without connection to the network. When the mobile station MS enters the cell C8 region of Figure 2, the comparison at step 33 does not find any common identifier for the data to be compared. The mobile station MS then transmits. contact cell update message via base station BTS8. The fixed network and the mobile station MS 103556 stores the base station identifier BSIC8 as a new contact cell identifier (step 34).

In a secondary embodiment of the cellular radio system according to the invention, the contact area is the contact cell and cells indicated by the cell contact information of the contact cell base station na-5. The invention will now be described in more detail in the light of a secondary embodiment with reference to Figure 4, in which the geographical area covered by the network is divided into cells C1-13. In connection with the mobile activity of the mobile station MS in the fixed network and the mobile station MS, upon termination of the network connection, the base station identifier BSIC1 of the 10 cell contacts and the neighboring base station identifiers BSIC2, BSIC3, BSIC4, BSIC6 and When the mobile station MS moves to cell C7 according to route 40 of FIG. 4, the mobile station MS receives base station information of base station BTS7 as described above in connection with FIG. The Travel-15 message compares the received base station information BSIC7, BSIC2, BSIC1, BSIC6, etc. with the base area identifiers BSIC1, BSIC2, BSIC3, BSIC4, BSIC5, BSIC6 and BSIC7 in its contact area. The result of the comparison is four common base station information BSIC1, BSIC2, BSIC6 and BSIC7. No action is required on location management. Similarly, in the cell C6 region, the mobile station finds the base station identifiers BSIC1, BSIC5, BSIC6 and BSIC7 as a result of the comparison. Even when moving to the area of cell C8, the comparison of the mobile station MS results in common base station identifiers BSIC5 and BSIC6, so that no action is needed to update the contact area. According to route 40, when entering the C11 area of the cell, the mobile station MS receives from base station 25 BTS11 base station information BSIC11, BSIC12, BSIC8, ·:: BSIC10, etc. When comparing these symbols with the stored area IDs, the mobile station MS does not find the same. In this case, the mobile station MS transmits a contact area update message to the network via the base station ...... BTS11. Fixed Networks Mobile Station · · * 30 MS updates base station identifier BSIC11 and neighbor base station identifiers BSIC12, BSIC8, BSIC10, etc.

In the preferred embodiment of the cellular radio system according to the invention, the paging of a mobile station MS is, if necessary, transmitted in two steps. Initially, a fixed * · call is sent to the mobile station MS. 35 through a contact cell stored in a network, for example a mobile services switching center MSC or a base station controller «· 103556 12 BSC. When the stored contact cell is C1 in the case of Figure 2, an invitation is transmitted to the mobile station MS via the base station BTS1. If the mobile station MS does not respond to the transmitted call within the preset time, the call is transmitted to the mobile station in cells C2, C3, C4, C5, C6 and C7 of the contact cell C1 indicated by neighbor cell information via the base stations BTS2, BTS3, The latter step of the call can also be implemented by sending the call in both the contact cell and the neighboring cell of the contact cell.

Figure 5 illustrates method steps for a primary embodiment of a mobile station MS ha-10 ku. At step 51, an invitation is sent to the mobile station MS in a contact cell stored in the network. In step 53, it is monitored whether the mobile station MS is responding to the transmitted call. If the mobile station MS does not respond within a preset time, an invitation is sent to the mobile station MS in the cells indicated by the contact cell neighbor cell information (step 55).

In the secondary embodiment of the invention, the paging of the mobile station MS is carried out in three steps, if necessary. Figure 6 illustrates, as method steps, the paging of a mobile station MS in a secondary embodiment. Initially, at step 61, a call is transmitted to the mobile station MS via the base station of the contact cell stored in the network, in the case of the contact cell C1 of FIG. 4 via base station BTS1. In step 62 of Figure 6, it is monitored whether the mobile station MS is responding to the transmitted call. If the mobile station MS does not respond within a preset time, an invitation is sent to the mobile station MS in the cellular information of the contact cell C1 stored in the network in cells C2, C3, C4, C5, C6 and:.: C7 (FIG. 6, point 63). In addition to the above-mentioned cells, the second-stage invitation can also be sent in contact cell C1. In step 65, it is monitored whether the mobile station MS answers the transmitted second-stage call. If the mobile station MS still does not respond, a call is sent to the mobile station MS according to step 67 in all cells indicated by the neighbor cell information of base station base stations BTS1, BTS2, BTS3, BTS4, BTS5, BTS6 and BTS7 outside the contact area, in FIG. C8, C12 • · », and other neighboring cells in the contact area not shown in Figure 4. Alternatively, the final step of the call may be implemented by sending an invitation to each of the cells indicated by the neighbor cell information, including those which:. are in the contact area.

The arrangement of the mobile station according to the invention requires relatively minor changes to the structure of the prior art mobile station. The mobile location storage, comparison message generating means used in conventional location management can be modified to perform the contact area concept functionality of the present invention. The mobile station according to the invention receives all the information it needs for location management from the system base station, so that the mobile station itself does not have to produce anything other than contact area update messages. Only the most recent contact area identifiers are stored in the memory of the mobile station, so that the mobile station 10 does not have to maintain information on the cellular structure of the network.

The location management method described above may be used in a cellular radio system, alone or in combination with a prior art position updating method. Combined with a method using traditional location areas, the location management according to the invention achieves location management optimization for users in different ways.

The drawings and the description related thereto are only intended to illustrate the idea of the invention. The location management and paging method of the invention, the cellular radio system and the mobile station may vary in detail within the scope of the claims. In the cellular cellular diode system of the invention, the contact information may also be arranged to be stored in a separate auxiliary register.

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Claims (17)

103556 14 Patte was looking at the payment A location management method in a cellular radio system, comprising base stations (BTS1-8) transmitting at base station information its own base station identifier and neighbor cell information, and mobile stations (MS) receiving said base station information, deriving the contact area of the mobile station (MS) from the base station information, storing the contact area of the mobile station (MS) in connection with each network activity, and updating the contact area information when the mobile station (MS) does not receive base station information included in the base station information. A location management method according to claim 1, characterized in that the method for updating the contact area information compares the base station information received from the base station information received in the mobile station (MS) with the base station information stored in the contact area and the same contact base information is not found. Location management method according to claim 1 or 2, characterized in that the method for storing a new contact area comprises sending a contact area update message from the mobile station (MS), and storing the contact area in both the fixed network and the mobile station (MS). • · · Location management method according to claim 1, 2 or 3, characterized in that the contact area identifier of the mobile station (MS) is stored as the contact area. I .. 30 The location management method according to claim 1, 2 or 3, characterized by storing as a contact area the cell identifier of the mobile station (MS) and the cells of the cell showing the cell information of the neighbor cell. The location management method according to claim 4 or 5,. 35 securing that the access point identifier is stored as a cell identifier. 15 103556 7. A method for retrieving a mobile station (MS) in a cellular radio system, comprising base stations (BTS1-8) transmitting their base station information and neighbor cell information as base station information, characterized in that method 5 stores a contact area of a mobile station (MS). , calling the mobile station (MS) via the most recently stored contact area base stations, and calling the mobile station (MS) via the base station designated cell area neighbor information indicated by the stored contact area if the mobile station does not respond to the call sent through the contact area base stations. A method for retrieving a mobile station (MS) according to claim 7, characterized in that the mobile station (MS) via a stored contact cell base station is called to call the mobile station via the base stations of the stored contact area. The method of retrieving a mobile station (MS) according to claim 7, characterized in that calling the mobile station via stored contact area base stations comprises the steps of: calling a mobile station (MS) through a stored contact cell base station, and: calling a mobile station (MS). ; via cellular information indicated by cellular information, if the mobile station does not respond to a call made within a predetermined period of time through contact cell base stations. A method according to claim 7 for a mobile station • · ·: * · *; (MS), characterized by calling the mobile station (MS) via the base stations indicated by the neighboring cell information of the stored contact area, excluding the base stations belonging to the contact area if the mobile station does not respond within a predetermined time through the base station base stations. invitation. *** 11. A cellular radio system comprising base stations (BTS1-8) which transmit their own base station identifier and neighbor cell information as base station information, and mobile stations 4 103556 16 (MS) receiving said base station information for monitoring the base stations, derive the contact area of the mobile station (MS) from the base station information, the system is adapted to store the contact area of the mobile station (MS) with each network activity, the system is adapted to update the contact area information when the mobile station (MS) the system is adapted to send a call to the mobile station (MS) via the base stations of the most recently stored contact area, and the system is adapted to send the mobile station ( MS) call through the cell base stations of the cells in the contact area neighbor cell information if the mobile station does not respond within a preset time to the call transmitted through the base stations in the contact area. A cellular radio system according to claim 11, characterized in that the contact area comprises a contact cell of a mobile station (MS). The cellular radio system according to claim 11, characterized in that the contact area comprises the cells indicated by the contact cell information of the mobile station (MS) and the cell contact information of the contact cell 20. The cellular radio system according to claim 11, characterized in that the system is adapted to send a call to the mobile station (MS) via base stations of cells indicated by neighbor cell information of the contact area which are outside the contact area. 15. A mobile station adapted to receive a base station identifier and neighbor cell information transmitted by a base station *: (BTS) with its broadcasting frequency for monitoring base stations, characterized in that * »» v: a mobile station (MS) is adapted to derive a contact area from base station information. is adapted to store the contact area in connection with each network activity, and the mobile station (MS) is adapted to update the contact area information when it does not receive any identifier belonging to the contact area in the base station information on the base station (BTS) broadcast frequency. 17 103556 Mobile station according to claim 15, characterized in that for updating the contact area information, the mobile station (MS) is adapted to compare the received base station identifier and neighbor cell information base station information with the stored contact area base station information, and register a new contact area when no common base stations are found. A mobile station according to claim 16, characterized in that for registering a new contact area, the mobile station (MS) is adapted to send a contact area update message to the base station (BTS), and the mobile station (MS) is adapted to store the new contact area in its memory. • • • • • • • • • • • • • • • • • 1 · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · «« 103556