SE518884C2 - Confirming addresses in cellular radio telecommunications systems - Google Patents

Abstract

The method comprises the steps of broadcasting system parameter values on the control channel of a base station, and receiving broadcast system parameters on the control channel at the mobile station (M1 to M10). The received parameter values are stored within the memory of the mobile station. The system parameter value indicative of the system within which the mobile station is currently registered is stored in the mobile station memory. A system access message is broadcast from the mobile to the base station. A system acknowledgement message, including system parameter values, is received at the mobile station. The values in the mobile are updated with the system values received in the acknowledgement.

Description

518 884 2 values established for each system. These values include a system identification number (SID), which identifies the particular system, a location identification number (LOCAID), which identifies a subdivision of the system within which the base station is located, a registration ID number (REGID), which is essentially a clock signal and a registration increment signal (REGINCR), which is a value indicating the time to the next periodic registration, which will be required by the mobile station for activity monitoring purposes_ The sum of the values for REGID and REGINCR is equal to a next registration value (NXTREG) which is the time value at which the next registration of the mobile station is required by the system.

Data received from the system by the mobile station is very important for the maintenance of the communication between the two. Mobile stations may include a first memory area in which each parameter received from a system is immediately stored and a second area in which semi-permanently stored certain parameter values indicating the system in which the mobile station is currently registered and with which it communicates. When a particular parameter value is received on the overall message line, this value is compared with the corresponding semi-permanently stored value to determine whether the mobile station is still operating in the system it believes it is operating in.

Another basic concept inherent in the maintenance of communication between a mobile station and a cellular radio telephone system is this with "re-scanning". Due to the criticality of the control data that the mobile station receives from the system, it is necessary to optimize the quality of the communication link that connects the base station and the mobile station.

Thus, a mobile radio station regularly re-scans all the control channels available to it and selects the channel with the highest transmission quality as the one over which it will communicate with the system. When a mobile station re-scans and selects from a plurality of control channels transmitted by base stations which form part of the same system or a subdivision thereof, which are indicated by identical values of SID and LOCAID, i.e., base stations which controlled by the same MSC or subdivision thereof, the MSC and the mobile station remain in continuous connection with each other. However, problems begin to arise when a mobile station operates in a boundary area between two service areas served by different MSCs or two subdivisions of the same MSC area. In such cases, a mobile station may alternatively be connected to control channels associated with different MSCs or subdivisions of an MSC, thereby creating clutter in the system.

For example, a mobile station located on the boundary of two systems may be registered in a system and its registration information consequently stored in its CPR, then upon decline of the signal in the control channel to which it is connected, re-scan and be connected to a control channel associated with that other system. Upon receiving OMT information from the new system, the mobile station would detect new system parameter values and would then attempt to re-register in this system. To do this, the mobile station would start a process of re-scanning all control channels. It can select a control channel on the old system and send the registration message to this old system. This registration information would then be updated in its home location register, and the registration would be acknowledged by the old system. Then, after receiving a registration acknowledgment message, this mobile station can be re-scanned and connected to a control channel on the new system. Upon receipt of the registration confirmation message, the mobile station.ha would have stored in its semi-permanent memory system parameter values for the new system, which were detected before the attempt to register. This leaves the mobile station lost within the system as any new calls received for this mobile station would be directed to the old system, with which it is now registered, while it is actually in communication with a base station located within the new system. ~. The system of the present invention avoids the problems associated with mobile registration in areas near the boundary of two or more interconnected systems or interconnected subdivisions of a system and prevents such clutter.

SUMMARY OF THE INVENTION For a purpose, the system of the present invention includes transmitting system parameter information of each system in the message sent to a mobile station acknowledging its registration as well as another message assigning voice channel to the mobile station. This enables the mobile station to compare this information with what is stored in its system registration data memory so that in the case of a system that acknowledges access or assigns a voice channel different from the one in which the mobile station believes itself to be registered, this can be corrected by avoiding that inaccurate registration information is stored in the CPR of a mobile station.

To an object, the system of the present invention includes a system and method for registering mobile stations within a cellular radio telecommunication system.

System parameter values are transmitted on a base station control channel and received on the control channel at a mobile station. The received system parameter values are stored in the memory of the mobile station and a system parameter value indicating the system within which this mobile station is currently registered is stored in the memory of the mobile station. A system access message is sent from a mobile station to a base station and a system acknowledgment message from a base station is received at the mobile station.

The system acknowledgment message includes system parameter values.

The system parameter values are updated in the memory of the mobile station with the system parameter values received in the system acknowledgment message in response to the reception of these values.

For a further purpose, the system acknowledgment message includes a registration confirmation message. BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the present invention and for further objects and advantages thereof, reference will now be made to the following description made in conjunction with the accompanying drawings in which: FIG. 1 is a pictorial representation of a cellular radio communication system including a mobile exchange center, a plurality of base stations and a plurality of mobile stations, FIG. 2 is a diagrammatic representation of a subset of the overall message line information transmitted by a base station to a mobile station, FIG. 3 is a diagram illustrating registration parameters stored in a mobile station's memory, FIG. 4 is a block diagram illustrating the operation of a mobile station in the area adjacent to two adjacent telephone communication systems, and FIG. 5 is a flow chart illustrating a sequence of recording information exchange in accordance with the principles of the present invention.

DETAILED DESCRIPTION Referring first to FIG. 1, there is illustrated a conventional cellular radio communication system of the type to which the present invention pertains. In FIG. J. an arbitrary geographical area can be divided into a plurality of interconnected radio coverage areas, or cells C1 - C10. While the system of FIG. 1 illustratively shown to include only 10 cells, it should be clearly understood that in practice the number of cells will be much larger. Associated with and located within each of the cells C1 - C10, a base station is designated as corresponding to one of a plurality of base stations B1 - B10. Each of the base stations B1-B10 includes a transmitter, receiver and base station controller, which is well known in the art. In Fig. 1, the base stations B1 - B10 are shown illustratively in the center of each of each cell B1 - B10 and are equipped with omnidirectional antennas. In other configurations of a cellular radio system, however. Therefore, the representation of the cellular radio system of FIG. 1 is for illustrative purposes only and is not intended as a limitation on the possible application of a cellular radio system in which the system of the present invention is applied.

With further reference to FIG. 1, a plurality of mobile stations M1 - M10 can be found in the cells C1 - C10. Again, only 10 mobile stations are shown in FIG. 1, but it should be understood that the actual number of mobile stations will be much larger in practice and will constantly exceed the number of base stations. Furthermore, while none of the mobile stations M1 - M10 can be found in any of the cells C1 - C10, the presence or absence of the mobile stations M1 - M10 in any particular of the cells C1 - C10 should be understood to depend in practice on the wishes of the individual mobile stations M1 - M10. , which can drift around from one position in the cell to another or from one cell to a nearby cell or a neighboring cell, and from a cellular radio system served by an MSC to another such system served by a separate MSC. In particular, the present invention addresses problems associated with mobile stations operating in cells that form interconnected boundary cells for adjacent systems served by different MSCs or by a subdivision of an MSC. Each of the mobile stations M1 - M1O is capable of initiating or receiving a telephone call through one or more of the base stations B1 - B10 and a mobile exchange center MSC. A mobile exchange center MSC is connected by communication links, for example, cables to each of the illustrated base stations B1 - B10 and to the fixed public exchange telephone network (PSTN), not shown, or a similar network which may include an integrated digital operating network equipment (ISDN). The relevant connections between the mobile exchange center MSC and the base stations B1 - B10, or between the mobile exchange center and the PSTN or ISDN are not fully shown in FIG. l, but are well known to those of ordinary skill in the art.

In the same way, it is also known to include more than one mobile exchange center in a cellular radio system network and to connect each additional: mobile exchange center to a separate group of base stations and to other mobile exchange centers via cable or radio links.

Current location data for each of the mobile stations shown in Fig. 1 is maintained in a database for a home location register (CPR) which may be associated with a particular MSC. Data stored for each mobile station includes the identity of the MSC serving the area within which the mobile station is currently located. The MSC also stores data related to subdivisions of its service area where a mobile subscriber is currently located.

Each of the cells C1 - C10 is assigned a plurality of voice or voice channels and at least one access or control channel, such as a forwarding control channel (FOCC). The control channel is used to control or monitor the operation of the mobile stations using information transmitted to and received from these devices. Such information may include incoming call signals, outgoing call signals, paging signals, paging response signals, location registration signals, voice channel assignments, and maintenance instructions. The control or voice channels can work either with an analog or digital mode or a combination of these. Although not specifically shown in FIG. 1, the cellular radio system has been served by special MSC conventionally the cells organized in groupings to enable the more efficient use of system resources. For example, there may be defined in the system a plurality of locating areas with each locating area including one. or several individual cells and which are identified by a locating area number (LOCAID). These localization areas define subdivisions into a service area for an MSC, as mentioned above.

As discussed above in the background section, in order to provide terminating call service for mobile stations operating within a cellular radio communication network, the network maintains a record of location data for each subscriber in its associated home location register (CPR). Data stored in CPR normally includes the identity of the MSC where the mobile station was last known to be located. Thus, calls received by the network to the mobile station can be routed to the MSC specified by current location data stored in its associated CPR. Location data for each mobile subscriber has been conventionally updated with each type of access to the system by the mobile station, whether this access was for the purpose of registering the mobile station or in response to an attempt to place a call from the mobile station. In U.S. Pat. Patent Application No. 07 / 797,548, filed November 25, 1991, entitled "Call Routing in Mobile Telephone Systems" by Sawyer et al., And assigned to the signatory of the present invention, subscriber shall only be updated in response to registration accesses. This proposed limitation is related to issues associated with call access procedures defined in the media adaptation specification specified by EIA / TIA-553 and EIA / TIA Is-54.

The mobile station recording process is controlled by the MSC using data transmitted to the mobile station by its fixed radio base stations on their forwarding control channels as part of an overall message. Such data are illustrated in FIG. 2 and includes the system identification number 21 (SID), the location area identification number: 22 (LOCAID), the registration identification number 23 (REGID), and the registration increment parameter 24 (REGINCR). SID 21 and LOCAID 22 are used to define the special mobile telephone system (SID) or its subdivisions (LOCAID) defined by the reasons to increase the efficiency of. Location: no mobile stations within the system. A particular system as defined by the SID may form part of the service area of an MSC and in some cases more than one service area of an MSC will form a system as defined and specified by a particular SID.

A LOCAID can then be used to identify boundaries of the MSC independent of boundaries of the SID. REGID acts as a clock in the system for periodic registrations, while REGINCR is an indication for the mobile station of the periodicity in the registration process. Mobile stations are instructed by the system to register upon detection of a new system or any part thereof based on data transmitted to them over the control channel.

That is, a mobile station must register upon detection of a new SID or a new LOCAID, which forms part of the data in the overall message line received on its control channel.

Mobile stations are also instructed to register periodically in accordance with the parameters set out in sections REGID 23 and REGINCR 24 of the overall message line received by them on the control channel. These parameters are determined in the data diagram of the overall message line shown in FIG. 2.

When a mobile station decides to register in the system, it temporarily stores in its memory 25 values for SID 26, LOCAID 27, REGID 28 and REGINCR 29 received by it in the overall message line on the forwarding channels it receives. It re-scans the available control channels to individually select the best available channel, which is determined as the control channel with the highest detected signal strength received by the mobile station. Following the re-scan 518 884, the mobile station can then select a control channel that does not carry the same SID, LOCAID, REGID and REGINCR if the control channel selected after re-scan is broadcast by a different base station. This can occur when the mobile station operates at the boundary between two nearby base stations that form part of two different systems. A registration access is then transmitted by the mobile station on the reverse control channel and received by the fixed radio base station. The base station then transmits the information to the MSC with which it is associated and the MSC informs the CPR of the subscriber's current location. The MSC also instructs the base station to send a registration confirmation to the mobile station, indicating to it that it has been registered in the system.

Each mobile station has a semi-permanent memory 31 which contains inputs 33-34 indicating the cellular system in which the mobile station last successfully logged in, together with an associated value NXTREG 35 for the cellular system used to determine when it is scheduled to re-enroll in this cellular system. Upon receipt of a registration confirmation message from a system, the mobile station then stores in its semi-permanent memory 31 either LOCAID and / or SID. In the event that a new SID is stored, a next registration parameter (NXTREG) is calculated from the parameters REGID and REGINCR previously received together with this new SID and then stored in the semi-permanent memory 31. The mobile station then scans the control channels again to ensure that it operates on the control channel with the highest possible signal strength available to it.

While the mobile station is in its idle state, it continuously monitors the system parameters transmitted in the overall message line on the control channel it receives. When it determines that a registration access is to be transmitted, it scans the set of system control channels defined. If the mobile station is located near the border of two systems controlled by two different MSCs, it can select a control channel from the nearby MSC as a result of the re-scan process. The registration is then sent in such a case to 518 884 ll an MSC other than the one it was intended to be sent to. This MSC then initiates the process of updating the location. for the mobile subscriber in their CPR and then sends a registration confirmation to the mobile station. The mobile station re-scans again to select a control channel and becomes dormant.

If, following this last re-scan, the mobile station happens to return to a control channel for the MSC to which the registration was originally intended, the mobile station will not detect that the registration access has been sent to a separate system. The result of this mess is that the mobile station is lost in the system and is connected to and served by a different MSC than the one its CPR believes it is served by. Thus, when an incoming call is received by the network intended for the mobile station, it will be searched by the system in the area as the service number MSC identified in: the registration information and will not be able to be located. A less serious problem occurs when the correct MSC is identified in the registration information but an incorrect subdivision of the MSC is indicated. Current means of overcoming this problem include searching all subdivisions of the MSC, but such actions are extremely ineffective and do not serve the purpose of having subdivisions of the MSC.

To prevent the loss of mobile stations in the system, a proposed approach is to transmit all relevant system parameters at a high data rate and to instruct all mobile stations to read these parameters on the control channels after the re-scan process and before sending their registration access to the system. This approach is fully supported by the standard specification EIA / TIA IS-54 and the only disadvantage is that such data transmission requires a substantial part of the capacity of the forwarding control channel. This capacity must be used as economically as possible as it supports a large amount of traffic for the search of mobile stations, registration confirmations, traffic channel assignments and other such functions. The system according to the present invention performs for the same purpose, but uses much less of the capacity of the retransmission channel. Referring again to FIG. 3, the memory in the mobile station contains both a temporary area 25 in which data received on the forwarding control channel from the system is immediately stored and a separate area 31 in which information is semi-permanently stored by transferring data from the temporary area 25 to the semi-permanent area. 31 once registration confirmations have been received from the system by the mobile station.

In the system according to the present invention, the relevant system parameters (SID, LOCAID and an updated value of NXTREG for a mobile station) are included in the registration confirmation sent by the system to the mobile station. The mobile station receives this new data and updates its internal data accordingly. In this way, the storage of permanent values for SID, LOCAID and NXTREG by the mobile station would not necessarily be in accordance with what is received on the channel where the mobile station was originally dormant, but rather in accordance with the control channel that has actually received and processed the registration access. . This control channel is the one belonging to the MSC that has updated the subscriber's location data in the CPR. This thus eliminates the ambiguity that currently exists in the registration process and ensures that in the circumstances where a mobile station operates in a border area served by two nearby MSCs, the mobile station will not be lost and will not be able to be located in the system.

The system of the present invention, including system data in the registration confirmation message to the system sent to the mobile station and then processed by the mobile station to ensure that it is properly registered, may be included as an additional feature in the system. For example, data fields included in registration confirmation messages indicate the number of system parameters included in the message. 518 884 13 System data could, for example, be included in all registration confirmation messages. Alternatively, it could be included in all registration confirmation messages sent by control channel serving cells located near MSC boundaries.

This could also be included only in a registration confirmation sent to a mobile station that has accessed a system or a subdivision thereof a first time detected by the internal logic of the MSC based on data stored therein.

Furthermore, the same system data (SID, LOCAID and NXTREG) could be added to the initial voice channel or the initial digital traffic assignment sent to a mobile station at call initiation. This feature would be especially useful when a mobile station accesses an MSC for the first time by transmitting a type of access other than registration. Other types of system data could be sent to a mobile station at registration confirmation, initial voice channel assignment or initial traffic channel assignment. It would thus be possible to indicate to a mobile station which SID or LOCAID it is allowed to access. In this way, the system would ensure that a mobile station which is part of an indoor cellular system will not inadvertently access the outdoor cellular system.

Referring then to FIG. 4, there is shown an illustrative diagram showing two service areas 121 and 122 controlled by different MSCs, MSC1 and MSC2. Within the service area 121 served by the MSCI, there is shown a base station 123 which transmits certain control parameters in the overall message line for its control channel. These include the parameters SID1, LOCAID1, REGID1 and REGINCR1. Similarly, the service area 122 served by the MSC2 includes a base station 124 which transmits certain system parameters on its control channel. These parameters include SID2, LOCAID2, REGID2 and REGINCR2. A mobile station 125 is shown operating in the boundary area between the two service areas 121 and 122 and stores in its memory a set of system parameters received at regular intervals on the overall message line of the control channel to which it is currently tuned. . The location data of the mobile station 125 is stored in a CPR 126, this data including the identity of the MSC within which the mobile station is currently registered. CPR 126 receives data from both MSCI and MSC2 via signaling links that work, for example, via signaling system protocol number 7 or 'protocol X.25 depending on the special circumstances.

As shown in FIG. 4, the mobile station 125 listens to the control channel it receives which has the highest measured signal strength according to its last re-scan of the available channels. Radio propagation characteristics are such that the mobile station 126 can often change its tuning from one control channel to another depending on the signal quality of the channels it receives. The mobile station 126 regularly detects system parameters transmitted in the overall message line for the control channels which it receives. The mobile station 126 will decide to register if any of the following conditions exist: (a) SID (MS) is # SID (CC), or (b) LocAImMs) is k LocAnucc), or (C) NXTREG <REGID (CC) That is, since the mobile station constantly stores in its temporary memory values of the registration parameters received on the overall message line of the control channel it is currently receiving, it compares these values with the values stored in its semi-permanent memory so that it can then determine whether or not it is appropriate to re-register based on both location parameters and time parameters.

After a mobile station decides to register and before sending its registration message on the reverse control channel it is currently receiving, the mobile station re-scans and selects a control channel. It may be the same channel it just received or a different control channel depending on the quality of the signal transmitted on the different control channels 518 884 available at the time of the re-scan. The registration message sent by the mobile station is sent on the new control channel which it receives after its re-scan.

After sending a registration message on the new control channel, the mobile station receives a registration confirmation message on the same new control channel and stores either the values for LOCAID or for SID and NXTREG in its semi-permanent memory based on the last values it received on a control channel. . In many cases, where the mobile station operates at the boundary area between two systems, the mobile station can store registration values transmitted to it by the old control channel it previously received before sending its own registration message. After receiving the registration confirmation message on the new control channel, the mobile station can re-scan and return to the old control channel if the signal quality on that channel is higher than that on the new control channel on which it sent its registration message and on which it received its registration confirmation message. sharing. If the old control channel to which it returned belongs to MSCI and the new control channel belongs to MCS2, the mobile station then considers itself registered in MCS1. However, since MCS2 has received a registration message from the mobile station, it considers that it is serving the mobile station at this time. Thus, MCS2 informs CPR 126 about such via the signaling link and CPR stores the information sent to it by the service area 122 for MCS2. HLR 126 then informs MCS1 that MCS1 no longer serves the mobile station via data transmitted over the links between them.

This sequence of events results in great confusion in the system and leads to the loss of the mobile station for handover of calls.

A similar situation may occur in the case that the mobile station is initially dormant in the service area 121 served by MSCI and seeks to initiate a call. In the event that the mobile 518 884 station re-scans and selects a control channel transmitted by base station 124, the mobile station would then transmit an origin on the new control channel, i.e., one associated with base station 124 and MSC2, and would store the values for SID, LOCAID and NXTREG associated with MSCI and previous transmissions of base station 123 at initial voice channel assignment (IVCD) or initial traffic channel assignment (ITCD).

Mobile stations operating in a cellular radio system routinely transmit system access messages which may include both registration access messages as well as call access messages.

The latter can occur as a result of either an original call or a search response from the mobile station.

As set forth above, the system of the present invention includes in any type of system acknowledgment message, including a registration confirmation message, an initial voice channel assignment message (IVCD) or an initial traffic channel assignment message (ITCD), from the system on the control channel to the mobile station, a or several system parameter values which may include SID, LOCAID and / or values for calculating a value NXTREG. These system parameter values would then be stored in the mobile station so that it had a correct indication of the current location for which it was currently registered and which system it believes it was operating within. This inclusion of additional data in a system acknowledgment message such as a registration confirmation message, IVCD or ITCD, sent by the system would ensure that the mobile station would immediately correct any incorrect information stored in its memory and ensure that it is not lost in the system.

Next, with reference to FIG. 5 there is shown a flow chart illustrating a sequence of steps in the operation of the system according to the present invention. The system starts at 131 at which the mobile station receives either a registration confirmation message, an initial voice channel assignment, or an initial traffic channel assignment in the messages sent on the control channel to which it is currently tuned. At 132, the mobile station determines whether there is no additional data present or not in the message received by the mobile station. If not, the system goes to 133 where normal system operation continues. it goes to 134 where it analyzes and determines what type of additional data is included.If additional data was a parameter SID (as determined at 134), the system goes to 135 and stores new semi-permanent value for SID in the semi-permanent memory in the mobile station.If the system determines at 134 that this additional data included value for LOCAID, it goes to 136 and stores a new semi-permanent value for LOCAID in the semi-permanent memory of the mobile station. Furthermore, if the system determines at 134 that the values included in this additional data included in the messages received by the mobile station included a value REGID, the system goes to 137 and determines whether a value REGINCR is also included or not in this additional data. If so, the system goes to 138 at which it calculates and stores a new semi-permanent value NXTREG in the semi-permanent memory of the mobile station. However, if at 137 the system determines that there was no value REGINCR included in this additional data in the message received by the mobile station, it goes to 139 and uses the previous value REGINCR stored in the mobile station and then to 141 where it calculates and stores the new semi-permanent value NXTREG in the semi-permanent memory of the mobile station. This sequence of operations is based on the inclusion of system parameter values in the registration confirmation message, the initial voice channel assignment message or the initial traffic channel assignment message sent on the control channel to a mobile station of a system. the mobile station is lost in the system due to the so-called re-scan problem inherent in the operation of mobile war 518 884 18 stations in the boundary area adjacent to two different systems or parts thereof.

As can be seen from the description above, the present invention enables a mobile station to be constantly aware of the system in which it has registered regardless of the fact that it can re-scan and receive registration confirmation on a different system than the one in which it had previously registered. .

This enables optimized use of system resources for locating mobile stations in a system and avoids loss of the system due to re-scanning unknowingly into an interconnected system.

It is believed that the function and construction of the present invention will be apparent from the foregoing description. While the method and apparatus shown and described have been characterized as being preferred, obvious changes and modifications may be made without departing from the spirit and scope of the invention as defined in the following claims.

Claims (1)

A method for the registration of mobile stations operating within a radio telecommunication system, the method comprising the steps of: transmitting a first system parameter value on a control channel of the system, receiving the first system parameter value in one of the mobile stations, storing the first system parameter value in a first memory in the mobile station, sending a system access message from the mobile station to the system, sending one to the system acknowledgment message in response to the system access message system acknowledgment message from the system mobile station, including a second system parameter value, storing the second system parameter value in a second memory in the mobile station, second with it comparing the system parameter value first system parameter value, and sending a registration message from the mobile station to the system if said first and second system parameter values are different. The method of claim 1, wherein the system acknowledgment message comprises a registration confirmation message. The method of claim 1, wherein the system acknowledgment message comprises an initial voice channel assignment message. according to claim 1, in which method the system acknowledgment message comprises an initial traffic channel assignment message. A method according to claim 1, a method according to claim 1, a method according to claim 1, a method according to claim 1, 518 8 8 4 's: ï': 20 in which method the step of storing the second system parameter value includes: analyzing the system acknowledgment message to determine which particular system parameter value is included in the message. in which method the first memory comprises a temporary memory in the mobile station the second memory comprises one and the semi-permanent memory in the mobile station. in which method the first and the uder kJ each ink El: V 'IL l. c, second value LOCAID. the system parameter value in which method the first and the second system parameter value each include a value SID. The method of claim 1, wherein the system access message comprises a registration access message. The method of claim 1, wherein the system access message comprises a call access message. The method of claim 1, wherein the system acknowledgment message further includes an indication of the type of the second system parameter value. method Method which comprises a plurality of locating areas each of claim 1, in the system according to including at least one cell and in which method it 10 15 20 25 30 13. 14. 15. 16. 17. 513 334 2! the second system parameter value is only included in -G11 4, pi »rested bfC system acknowledgment messages sent at the boundary between two location ranges. The method of claim 1, wherein the second system parameter value is included in the system acknowledgment message only if the mobile station was not registered in the location that received the access message. A method according to claim 1, in which method at least one further system parameter value is transmitted together with the and: ll) each of the first and the system parameter value. The method of claim 14, wherein the first and second system parameter values each comprise the SID and the additional REGID, a value of at least one system parameter value comprising the value REGINCR or LOCAID. The method of claim 14, wherein the system acknowledgment message includes an indication of the number and type of system parameter values included in the system acknowledgment message. Apparatus for registering mobile stations operating within a radio telecommunication system, the apparatus comprising: means for transmitting a first system parameter value on a control channel of the system, means for receiving the first system parameter value in one of the mobile stations,. 20 25 30 5 13 g 3 4 5.5 f = :. - I? Means for storing the first system parameter value in a first memory in the mobile station, means for sending a system access message from the mobile station to the system, means for sending, in response to the system access message, a system acknowledgment message from the system to the mobile station, the system acknowledgment message (I) Äv-š vCl_v «includes a second system parameter (b v a means for storing the second system parameter value in a second memory in the mobile station, second means for comparing the system parameter value with the first system parameter value, and means The apparatus of claim 17, wherein the apparatus acknowledgment message comprises a registration acknowledgment message The apparatus of claim 17, wherein the apparatus acknowledgment message comprises an initial voice channel assignment. Apparatus according to claim 17, in which apparatus the system acknowledgment message comprises an initial traffic channel assignment message. The apparatus of claim 17, wherein the means for storing the second system parameter value comprises: 23. 23. 24. 25. 26. 27. 28. 51 3 334 i. '23 means for analyzing the system acknowledgment message to determine which particular system parameter value is included in the message. The apparatus of claim 17, wherein the first memory comprises a temporary memory in the mobile station and the second memory comprises a semi-permanent memory in the mobile station. The apparatus of claim 17, wherein the apparatus ae: the first and second system parameter values each include a LOCAID value. The apparatus of claim 17, in which the first and second system parameter values each include a value SID. The apparatus of claim 17, wherein the apparatus system access message comprises a registration access message. The apparatus of claim 17, wherein the apparatus system access message comprises a call access message. The apparatus of claim 17, in which the system acknowledgment message includes an indication of the type of the second system parameter value. The apparatus of claim 17, wherein the apparatus system comprises a plurality of location areas each including at least one cell and in which apparatus the second system parameter value is included only in system acknowledgment messages sent in cells at the boundary between two location areas. An apparatus according to claim 17, in which apparatus the: second system parameter value is included in the system acknowledgment message only if the mobile station was not registered in the locality that received the access message. The apparatus of claim 17, wherein the apparatus transmits at least one additional system parameter value along with each of the first and second system parameter values. which Apparatus claim 30, in and according to the apparatus the second each value SID first system parameter value comprises one and the at least one further system parameter value comprises that value REGID, REGINCR or LOCAID. The apparatus of claim 30, wherein the system acknowledgment message includes an indication of the number and type of system parameter values included in the system acknowledgment message.