FR2938148A1 - METHOD AND SYSTEM FOR LOCATING RADIO COMMUNICATION TERMINALS IN SLEEP MODE IN A CELLULAR RADIO COMMUNICATION NETWORK. - Google Patents

Abstract

A method is dedicated to the location of radio communication terminals (T1-T4) in standby mode in a cellular radio communication network (RC) subdivided into location zones (ZL1-ZL2) associated with zone identifiers and comprising minus one cell (C11-C23). This method comprises, when a radio communication terminal (T1) in standby mode enters a radio coverage area of a local radio access point (FB112), implanted in a cell (C11) of a radio zone. location (ZL1) having a surface radio coverage area greater than its own, and associated with an area identifier different from that of the location area (ZL1) including its cell (C11), i) a recovery step the zone identifier of this local radio access point (FB112), ii) a step of connecting this terminal (T1) to this local radio access point (FB112), and iii) an initiation step by this terminal (T1), a procedure for updating a location area near the network (RC) with the recovered area identifier, so that the network associates with the terminal (T1) the zone identifier recovered.

Description

FIELD OF THE INVENTION The invention relates to the location of radio communication terminals in cellular radio communication networks, and more specifically the location within such networks. radio communication terminals placed in a sleep mode (or idle). Certain applications, such as emergency call or information delivery or real-time advertisement applications depending on the location (or geographical position), need to be known in a fairly precise manner and more often than not. possible location (geographical position) where users of terminals (radio communication) are located.

This location information can be obtained in different ways. Thus, they can be obtained by satellite positioning devices (for example of the GPS type) which are located in the terminals of the users. Unfortunately, few terminals are equipped with such devices, especially because of their cost. In addition, these devices do not work

20 well, if at all, when they are inside buildings. In addition, the acquisition of location information by these devices may be relatively slow (especially because of the length of what the skilled person calls in English the Time to First Fix). They can also be obtained by the access points of a

WiFi network whose coverage area is superimposed on the area of the cellular network in which a terminal is located. Unfortunately, there is still no localization solution that can be implemented with all the different WiFi technologies. In addition, the number of terminals with dual communication mode (cellular and WiFi) is very limited, especially because of the cost.

They can also be obtained by the cellular (radio communication) network. Indeed, a cellular network being broken down into cells associated with cell identifiers and covering known geographical areas, it is therefore possible to estimate the position of a terminal from the identifier of the cell to which it is connected. (provided that it is not in standby mode). The accuracy of the location of the terminal (in connected mode) depends on the size of the cell to which it is connected. This accuracy can be significantly increased by implementing triangulation techniques. If the terminal is in standby mode, the accuracy is generally well Zo less. Indeed, it depends on the size of the localization area (or localization area) in which the terminal in standby mode is located, which depends on the number of cells that constitute it and the dimensions of these cells. It is recalled that in a 3G-type network each time a terminal is powered on it retrieves the zone identifier of the location zone to which the cell in which it is located belongs in the messages which are broadcast by this cell on its beacon channel (called BCCH), then communicates to the network this zone identifier so that the network stores its terminal identifier (for example the IMSI code) in correspondence with said zone identifier (registration procedure). As long as a registered terminal remains inside one of the cells of a location area it does not have to report its movements to the network. On the other hand, when a registered terminal leaves a location area to enter a new location area, it must initiate a location area update procedure to the network so that the latter replaces with the area identifier. from this new location area the area identifier of the old location area which was previously stored in correspondence of its terminal identifier. When a terminal is in standby mode, the only location information that can be obtained about it from the network is the geographical position 3o which corresponds to the zone identifier of the location area which is stored by the network in correspondence of its terminal identifier. It will be understood that the accuracy of this location information may be (very) insufficient for some applications. The invention therefore aims to improve the situation. It proposes for this purpose a method, dedicated to the location of radio communication terminals in idle mode (or idle) in a cellular radio communication network subdivided into location zones associated with zone identifiers and comprising at least one cell, and comprising, when a standby radio communication terminal enters a radio coverage area of a local radio access point, implanted in a cell of a location area having a radio coverage area

i0 greater than his own, and associated with a zone identifier different from that of the localization zone to which his cell belongs, a step of recovering the zone identifier of this local radio access point, - a step of connection of this terminal to this local radio access point, and 15 - a step of initiation, by this terminal, of a procedure for updating the location area with the network with the area identifier retrieved from so that the network associates with the terminal this retrieved area identifier (which corresponds to the known geographical position of the local radio access point to which it has just connected). The method according to the invention can comprise other characteristics that can be taken separately or in combination, and in particular: the procedure for updating the current location area of a mobile terminal in standby mode can be automatically performed by the network (for example by its core network) only when this mobile terminal

Change of location area, - the connection of a terminal to a local radio access point can be done by correlation of received signals with access codes associated respectively with local radio access points; the connection of a terminal to a local radio access point can also be done by analyzing the power of the signals emitted by the local radio access points and by selecting the local radio access point which transmits the signals the most powerful; • when a standby terminal enters the radio coverage area of a local radio access point, and if it is received by that terminal which is otherwise connected to a radio access point (or radio station); base) of a signal cell transmitted by this radio access point with a power greater than that of the signals transmitted by the local radio access points, the network can suppress the connection between this terminal and this radio access point , in order to force this terminal to connect to the local radio access point whose signals are the most lo powerful among those that have been issued by the local radio access points; the terminal can analyze the received radio spectrum and perform a correlation of the received signals with the access codes which are respectively associated with the local radio access points implanted in the cells which are part of the known location area in which it is located; alternatively, the terminal can analyze the received radio spectrum and correlate the received signals with the access codes which are respectively associated with the local radio access points whose associated geographical positions are contained in the known location area. in which it is located; the access codes of the local radio access points which are located in the cells which are part of the known localization area in which it is located can be transmitted to a terminal; alternatively, it is possible to transmit to a terminal the access codes of all the local radio access points which are located in the cells of the network; - Once the procedure for updating the location area of a terminal is completed, it can compel the terminal to transfer its connection to a radio access point of the cell in which the access point is located. local radio to which he connected. The invention also proposes a system dedicated to the location of radio communication terminals in standby mode in a cellular radio communication network subdivided into location zones associated with zone identifiers and comprising at least one cell. This system is characterized in that it comprises: at least one local radio access point implanted in a cell of a location zone having a radio coverage area with a surface area greater than the

sien, and associated with a zone identifier different from that of the localization zone to which its cell belongs, charged connection means, when a radio communication terminal in standby mode enters the radio coverage area of this point

local radio access lo, retrieve the zone identifier of this local radio access point, and connect this terminal to this local radio access point, and update means responsible for initiating the local radio access point; a terminal location location update procedure within the network with the retrieved area identifier, so that the network associates with this terminal 15 the retrieved area identifier. The system according to the invention can comprise other characteristics that can be taken separately or in combination, and in particular: its connection means can be responsible for analyzing the received radio spectrum and for correlating the received signals with data codes. 'access

20 respectively associated with local radio access points, so as to connect a terminal to one of these local radio access points; its connection means can be responsible for analyzing the power

signals transmitted by the local radio access points and received by the terminal

and connect the latter to the local radio access point which transmitted the received signals with the greatest power; Its connection means can be loaded, in the event of the network deleting a connection between a terminal and a radio access point of a cell following the reception by this terminal of signals transmitted by this access point; radio under a power superior to those

Signals transmitted by local radio access points, to connect this terminal to the local radio access point whose signals are the most powerful among those which have been transmitted by the local radio access points; its connection means can be responsible for analyzing the received radio spectrum and correlating the received signals with the access codes associated with the local radio access points implanted in the cells that are part of the zone, respectively. of known location in which the terminal is located; alternatively, its connection means may be responsible for analyzing the received radio spectrum and correlating the received signals with the access codes associated with the local radio access points, the associated geographical positions of which are contained in the known localization area in which the terminal is located. The invention also relates to a radio network controller, i) intended to be part of a radio communication network, ii) able to control at least one radio access point of a cell of this network in which is implanted at least one local radio access point, and iii) arranged, when a radio communication terminal (in standby mode and connected to this radio access point of the cell) enters the radio coverage area of the radio point local radio access, and in the event of reception by this terminal of signals emitted by this radio access point 20 at a power greater than that of the signals transmitted by the local radio access point, to order the deletion of the connection between the terminal and the radio access point, so as to constrain the terminal to connect to this local radio access point. The invention also relates to a local base station, firstly, intended to act as a local radio access point in a cell of a location area (having a radio coverage area greater than its own area). , associated with a zone identifier and forming part of a radio communication network), and a second part, associated with a zone identifier different from that of this localization zone to which its cell belongs, and of a third part, arranged when a standby radio communication terminal has attached to it and a location area update procedure has been performed within the network for this terminal with its own identifier of zone, to constrain the terminal to transfer its connection to a radio access point of this cell. Other features and advantages of the invention will appear on examining the detailed description below, and the accompanying drawings, in which: FIG. 1 very schematically and functionally illustrates a cellular radio communication network comprising two location areas and a location system according to one embodiment of the invention, and Figure 2 schematically illustrates the main messages exchanged lo between network equipment and a mobile terminal during a localization procedure of this invention. mobile terminal according to one embodiment of the invention. The attached drawings may not only serve to complete the invention, but also contribute to its definition, if any. The object of the invention is to enable the location with good accuracy of a radio communication terminal in idle mode (or idle) within a cellular radio communication network. In the following, it is considered as a nonlimiting example that the cellular radio communication network (RC) is a so-called 3G network, such as for example a UMTS or CDMA 2000 type network. is not limited to this type of cellular network. It concerns indeed any type of cellular network that can implement the invention. Furthermore, it is considered in the following, by way of non-limiting example, that the radio communication terminals (Ti) are mobile phones (or cellular). However, the invention is not limited to this type of radio communication terminal. It concerns indeed any type of radio terminal (trans) carried by a mobile user, including laptops and digital personal assistants (or PDAs) capable of communicating via a radio link (eg type 3G). FIG. 1 shows schematically an example of a cellular network RC. This type of cellular network RC can, in a very schematic manner but nevertheless sufficient to the understanding of the invention, be summarized to a core network (or Core Network) CR coupled to a radio access network RAR. The radio access network RAR firstly comprises nodes (radio network controllers) NC coupled to the core network CR, via an interface (called a lu), and called RNC (for Radio Network Controller), in the case of a network of UMTS type, and BSC (for Base Station Controller), in the case of a network of GSM or GPRS type. It also includes radio access points or base stations (transmission / reception) SBjk which are, lo on the one hand, associated with each (e) s at least one cell Cjk having a coverage area radio, and, secondly, coupled alone or in groups of at least one to one of the aforementioned NC nodes, via a logical interface (called lub). These SBjk base stations are called Node B, in the case of a UMTS network, and BTS, in the case of a GSM type network (or GPRS). The radio access network RAR is further subdivided into localization areas ZLj which each include a set of at least one cell Cjk and which are each associated with a clean zone identifier (or LAC (for Localization Area Code)) IZj. In the nonlimiting example illustrated in FIG. 1, the cellular network RC 20 comprises two localization zones ZL1 and ZL2 (j = 1 or 2). The first location area ZL1 groups together two cells C11 and C12 (j = 1 and k = 1 or 2) which are both associated with the area identifier IZ1 of their location area ZL1 and whose base stations SB11 and SB12 respectively broadcast this zone identifier IZ1 on their respective BCCH beacon channels. The second location area ZL2 groups together three C21, C22 and C23 cells (j = 2 and k = 1 to 3) all of which are associated with the zone identifier IZ2 of their ZL2 location area and whose base SB21, SB22 and SB23 respectively diffuse this zone identifier IZ2 on their respective BCCH beacon channels. The invention proposes in particular to implant in at least some of the cells Cjk of the radio access network RAR, and if possible in all, local radio access points FBjkn freely accessible (or in English open access), coupled at the aforementioned NC nodes (radio network controllers (BSC or RNC)) each having a radio coverage area significantly smaller than that of the SBjk base station of their Cjk cell. It should be noted that these local radio access points FBjkn are sometimes called femto BTS and constitute femto FC cells (in this case they are said to be associated with sub-cells called s femto cells and constituting subsets of cells called macros cells). In Figure 1, only two femto FC cells were shown so as not to overload the drawing. It will be understood that each local radio access point FBjkn constitutes for a terminal, because of its free access, network equipment similar to a base station (or radio access point) SBjk and thus allowing it to access to the RC network. It is recalled that a conventional Femto BTS is usually designed to provide residential access, ie limited to a limited and predetermined number of users. Therefore, each local radio access point FBjkn also has a beacon channel (BCCH) which allows it to broadcast in its (femto) radio coverage area useful information to the terminals Ti to connect to the RC network or to continue ongoing communications. However, unlike a base station SBjk which is associated with the zone identifier IZj of its location zone ZLj, and therefore which diffuses in its (macro) radio coverage area this zone identifier IZj, a point of local radio access FBjkn is associated with a zone identifier IZ'jkn which is of the same type as the zone identifier IZj of its location zone ZLj but which differs from the latter and from those of the location zones ZLj 'Q' 4j ) neighbors. Consequently, a local radio access point FBjkn, according to the invention, broadcasts on its beacon channel (BCCH) the zone identifier IZ'jkn which has been specifically associated with it and not that of its location zone ZLj . It is important to note that the geographical position of a local radio access point FBjkn is perfectly well known to the RC network. Therefore, when the area identifier IZ'jkn is known which is specifically associated with a local radio access point FBjkn, the corresponding geographical position of this radio access point can be determined within the network RC. local FBjkn. As a result, when a terminal Ti (in standby mode) is located in a cell Cjk and has already registered with the network RC by providing the zone identifier IZj of the location area ZLj to which belongs to this cell Cjk, then, when it is in the radio coverage area of a local radio access point FBjkn of this cell Cjk, it can recover (receive) the zone identifier IZ'jkn of this cell local radio access point FBjkn.

The terminal Ti comprises connection means MC including reception means responsible for receiving the radio signals that are transmitted by the equipment of the radio access network RAR, analyzing these received radio signals (of the radio spectrum) and recovering (After demodulation) the information that is contained in these demodulated signals, and in particular a possible zone identifier IZ'jkn of a local radio access point FBjkn. When the retrieved area identifier IZ'jkn is different from that (lZj) of the location area ZLj in which the terminal Ti is located (and to which its terminal identifier (for example an IMSI) has previously been associated by the network RC during recording), then said terminal Ti is forced to connect to the local radio access point FBjkn (by means of its connection means MC) in order to allow MM update means that it comprises initiating a standard Location Area Code Update (or LAC_Update) procedure for the standardized 3GPP procedure from the RC network with this area identifier IZ'jkn retrieved. It will be recalled that during this update procedure the network RC will replace the zone identifier IZj of the location area ZLj, hitherto associated with the terminal Ti, with the zone identifier IZ'jkn newly recovered by the latter (Ti). Thus, once the identifier (for example the IMSI) of a terminal Ti is registered with the network RC in correspondence of the zone identifier IZ'jkn of a local radio access point FBjkn, it is possible to know with a margin of (very) limited error the geographical position of this terminal Ti, since this margin of error is at most equal to the radius (schematically speaking, if we approximate the radio coverage of the cell Cjk to a circle) of the radio coverage area of the local radio access point FBjkn. It is recalled that in a 3G RC network the identifiers (for example IMSI) of the registered Ti terminals are generally stored in correspondence of zone identifiers IZj in a core network equipment CR called GMLC (Gateway Mobile Location Center) GM or in a database of customer information HV (including position) called HLR (Home Location Register). It is also recalled that this recording (in the so-called CS domain), just like each location area update procedure, involves several other network equipment of the core network CR, such as for example at least one node (or equipment ) called MSCNLR (Mobile Switching CenterNisited Location Register). FIG. 2 schematically illustrates the main messages that are exchanged between the aforementioned network devices (SBjk, FBjkn, SGSN, HV and GMLC) and a terminal T1 during a procedure for locating the latter (Ti). It is considered here that the terminal T1 is in standby mode (idle), is located in the first cell C11 of the first location area ZL1 of the network RC and that it has already registered with said network RC in association with the zone identifier IZI of this first location zone ZL1. Consequently, the identifier (IMSI) of the terminal Ti is stored in correspondence of the zone identifier IZI in the equipment GMLC (here referenced GM). It is also considered that the terminal Ti has just entered the (femto) radio coverage area of the second local radio access point FB112 of the first cell C11 and thus receives both the channel base station SB11 beacon of the first cell C11 (arrow FI) and the beacon channel of the second local radio access point FB112 (arrow F2). It can therefore recover the zone identifier IZ'112 that this second local radio access point FB112 broadcasts on its beacon channel (arrow F2). As indicated above, the terminal T1 comprises connection means MC loaded, in particular, to recover in the radio signals received the zone identifier IZ'112. These connection means MC realizing that this zone identifier IZ'112 is not the one (IZ1) with which their terminal T1 is associated, they connect their terminal T1 to the second local radio access point FB112 (arrow F3). . Once the connection is established between the terminal Ti and the second local radio access point FB112, MM update means that it comprises initiate a location area update procedure within the network RC with the retrieved area identifier IZ'112, so that other MM (complementary) network update means RC associate the terminal T1 this retrieved area identifier. It will be understood that these other update means MM are responsible for replacing the area identifier IZ'112 retrieved with the zone identifier IZI of the location area ZL1 which was previously associated with the network RC at the terminal T1. . As partially illustrated in FIG. 1, the other means of updating MM are notably distributed in the local radio access points FBjkn, the base stations SBjk, the radio network controllers NC, the devices (nodes) MSCNLR, and the HV database (HLR). It will be noted that the local radio access points FBjkn, the update means MM and the connection means MC together constitute a location system according to one embodiment of the invention. As is well known to those skilled in the art, the updating procedure takes place in five successive parts when it concerns the CS domain. It should be noted that this update procedure is in particular standardized. It is for example described in the UMTS book Origins, Architecture, the Pierre Lescuyer Standard, 2nd Edition, Dunod Edition, especially in section 8.2.2 relating to the Update of Location Area in the CS Domain. . It is recalled that at least one location area is associated with a node (or equipment) MSCNLR. Since the zone identifier of a local radio access point FBjkn is different from the zone identifier of the localization zone ZLj comprising this local radio access point FBjkn, the latter and its location zone ZLj can therefore be attached to either the same MSCNLR equipment or to different MSCNLR equipment. In what follows, we consider the case where the local radio access point FBjkn and its location zone ZLj are attached to different MSCNLR equipment. In this nonlimiting case, the first part of the updating procedure (arrow F4) consists in transmitting from the terminal T1 to the (new) node MSCNLR with which the second local radio access point FB112 is associated (via the second one). local radio access point FB112, the base station SB11 and the NC radio network controller which is coupled to the base station SB11) an update message, for example of the LAC Update (TLLI) type. TLLI stands for Temporary Logical Link Identifier and designates a signaling address. s The second part of the update procedure (arrow F5) is to exchange update messages between the new MSCNLR node and the old MSCNLR node, in a secure manner, so that the new MSCNLR node retrieves information about the terminal T1 and that the old node MSCNLR deletes the record relative to said terminal T1. The third part of the update procedure (arrow F6) consists in updating the database HV (HLR) with the new zone identifier IZ'112. This can for example be done by transmission of an update message, for example LAC Update type (IMSI, IZ'112) between the new node MSCNLR and the database HV (HLR). It will be understood that the new MSCNLR node is for example arranged to determine the IMSI identifier which corresponds to the TLLI of the terminal T1, as well as the zone identifier IZ'112 which corresponds to the access point identifier (Femto Cell Id) of the second local radio access point FB112. In particular, it has a correspondence table for this purpose. The fourth part (arrow F7) consists in transmitting from the new MSCNLR node to the terminal T1 an update message intended to inform it of the success of the location area update procedure that it has initiated. The fifth part (arrows F8 and F9) consists of releasing the connection (RRC) previously established between the terminal T1 and the base station SB11. For this purpose, the new node MSCNLR may for example address (arrow F8) a message to the radio subsystem (or RNS (Radio Network Subsystem)), and for example to the radio network controller NC which controls the radio station. SB11 base, ordering it to release the connection due to an attachment of the terminal T1 to another radio access point (here the second local radio access point 30 FB112), and then the radio network controller NC can for example, to send (arrow F9) a message to the base station SB11 ordering it to release the connection established with the terminal T1.

The HV (HLR) database having been updated, it can then, if it is interrogated by an authorized application (or an authorized application server), communicate to the latter (or the latter) the geographical position of the terminal. T1 which corresponds to the access point identifier (Femto Cell ID) of the second local radio access point FB112. For example, it has a correspondence table between geographical positions and access point identifiers. We will now detail how a terminal T1 (in standby mode) proceeds to connect to a local radio access point FBijk of a cell Cjk, io while it is already attached to the base station SBjk of this Cjk cell. For a terminal Ti, located in a cell Cjk and attached to the base station SBjk of the latter (Cjk), to be able to connect to a local radio access point FBjkn of this cell Cjk, it is necessary that it listen to the frequency on which the beacon channel of this local radio access point FBjkn is sent. It is therefore advantageous that within the same cell Cjk, the base station SBjk and the different local radio access points FBjkn transmit their beacon channel on the same frequency. It is also necessary for the terminal Ti to have access codes, for example CDMA codes in the case of a UMTS network, respectively associated with the local radio access points FBjkn. Thus, the means of reception of the terminal Ti, which are part of its connection means MC, can scan the received radio spectrum by successively correlating the received signals with the various access codes, here CDMA, which they have on the transmission frequency of the local radio access points FBjkn. It should be noted that a terminal Ti may for example use, for its radio spectrum scan, only the access codes which are respectively associated with the local radio access points FBjkn which are located in the various cells Cjk which make part of the known location zone ZLj in which it is located, or even only of the cell Cjk in which it is momentarily located. To do this, the network RC may, for example, transmit to the terminals Ti which have registered with it the access codes of the local radio access points FBjkn which are implanted in the cells Cjk forming part of the known location areas ZLj. in which they are located respectively. The base station SBjk of each cell Cjk can for example be responsible for the radio broadcast of the access codes of at least the access points of its cell Cjk.

In one variant, a terminal Ti may for example use, for its radio spectrum scanning, only the access codes which are respectively associated with the local radio access points FBjkn whose associated geographical positions are contained in the localization ZLj known in which it is located, or even only the cell Cjk io in which it is momentarily located. For this purpose, the network RC may for example transmit to the terminals Ti which have registered with it the access codes of the local radio access points FBjkn whose geographic positions are included in the known location areas ZLj in which they located respectively. For example, the base stations SBjk of each location area ZLj may be responsible for the radio broadcast of the access codes of the access points of their own location area ZLj. It will be noted that, in a variant, the terminals Ti may, for example, store the access codes of all the local radio access points FBjkn which are implanted in the cells Cjk of the RC network to which they are attached. These access codes are for example transmitted to them by the SBjk base stations of the RC network. In this case, the terminal Ti (in standby mode) will select from among all the access codes that it stores those that correspond to radio access points that are located in the location zone ZLj in which it is located . This requires, for example, that the terminals Ti store the access codes corresponding to the zone identifiers IZj of the location areas ZLj in which the associated local radio access points FBjkn are located. The connection phase of a terminal Ti to a local radio access point FBjkn may also comprise, in addition to the scanning of the access codes, an analysis of the power of the signals that are emitted by the radio access points local FBjkn. This analysis is intended to select the local radio access point FBjkn which transmits the signals which are received by said terminal Ti with the highest power. These most powerful signals are, in principle, those emitted by the local radio access point FBjkn which is the closest to the terminal Ti considered, and therefore which will know with the smallest margin of error the geographical position of the terminal Ti.

It is important to note that in some cases it may happen that a terminal Ti (in standby mode) attached to a radio access point (or base station) SBjk of a cell Cjk receives signals transmitted by it. SBjk radio access point under a power that is greater than those signals that are emitted by the local radio access points FBjkn. In a conventional operating mode, the terminal Ti should normally continue to remain attached to this base station SBjk since it is the one that offers the most power. Therefore, in this situation the invention could not be implemented. In order to remedy this drawback, the network RC (and more specifically its radio access network RAR) can for example eliminate the connection between a terminal Ti and its radio access point SBjk of attachment. This deletion can for example be done at the request of the radio network controller NC which controls the radio access point SBjk attachment of the terminal Ti. It should be noted that the network RC can not differentiate between a terminal Ti in connected mode, attached to a radio access point SBjk and a terminal Ti in standby mode, attached to a radio access point SBjk. Therefore, the deletion of the connection or the radio link is imposed for all terminals Ti which are in the theoretical geographical coverage or radio coverage of a radio access point SBjk.

In order for the connection cancellation order to be given (triggered), for example by an NC radio network controller, the RC network must be aware of the input of a terminal T1 in the coverage area FC. a local radio access point FBjkn. For this purpose and failing to be able to finely locate the terminal Ti, two mechanisms, not necessarily exclusive, can be used. A first mechanism consists in using the stored access codes, which correspond to the current location area ZLj of the terminal Ti and from which the access codes associated with all the local radio access points FBjkn of this zone of access can be deduced. ZLj location, to scan all received radio signals that may emanate from local radio access points (corresponding to these access codes). If the reception of the signals coming from one of these local radio access points FBjkn is above a certain reception threshold and if the history of frequenting the local radio access points FBjkn (stored in a memory local) shows at least one previous attendance with it, it is considered statistically that the user wearing the terminal Ti will be introduced into a place (or zone) in which is implanted said local radio access point FBjkn. This consideration can be correlated with known mechanisms of profiling (for example storage of the user's profile of the terminal Ti and correlation with the interest that this user could bring to the place (or to the zone)) to deduce the point d local radio access FBjkn to which the terminal Ti must hang.

A second mechanism is to use the satellite location function (for example of the GPS type) of a terminal Ti (if provided) to determine (estimate) its position and its velocity vector, then to predict its entry. (or not) in the coverage area of a local radio access point FBjkn based on this position and this velocity vector.

Once a terminal Ti has clung to a local radio access point FBjkn, its connection (or link) with the radio access point SBjk of the cell Cjk where this point of entry is located is deleted. local radio access FBjkn. This deletion is performed by the radio access point SBjk by order of its NC radio network controller.

On the other hand, to prevent the terminal Ti reconnecting (reconnaching) back to the base station SBjk of its cell Cjk just after being connected (attached) to a local radio access point FBjkn, because its power is greater than that of this local radio access point FBjkn, one can consider setting up a kind of hysteresis mechanism that prohibits the terminal Ti 30 such a reconnection for a chosen duration (sufficient to allow to perform the entire procedure locating zone update - for example, at least two seconds) and / or as a function of a maximum power threshold. In addition, once the procedure for updating the location area of a terminal Ti is completed, it is also possible to constrain the terminal Ti to transfer its connection to the radio access point SBjk of the cell Cjk in which is implanted the local radio access point FBjkn to which it has just connected (connect). For this purpose, the local radio access point FBjkn may, for example, send a message to the terminal Ti to order it to disconnect from it in order to attach itself to the radio access point SBjk of the cell Cjk in which it is momentarily located. . This end of connection message lo may for example be addressed to the terminal Ti by the local radio access point FBjkn after expiration of a timer, for example of a duration of a few seconds. This transfer constraint is intended to quickly discharge the local radio access points FBjkn, since the latter can generally support only a few connections simultaneously, typically less than five (in particular when they intervene in a communication), unlike stations basic SBjk whose connection capabilities are much larger. In addition, to prevent a local radio access point FBjkn from polluting a radio station SBjk bae, it can be envisaged that this local radio access point FBjkn is equipped with directional antenna (s) pointing towards selected directions, such as only to the inputs and / or outputs of a store. The connection means MC and / or the updating means MM according to the invention can be implemented in the form of electronic circuits, software (or computer) modules, or a combination of circuits and software. Advantageously, the connection means MC may consist of one or more software modules, possibly standardized. The invention is not limited to the embodiments of the location system, local radio access point and radio network controller described above, by way of example only, but encompasses all variants. that may be considered by those skilled in the art within the scope of the claims below.

Claims (19)

REVENDICATIONS1. A method of locating radio communication terminals (Ti) in a standby mode in a cellular radio communication network (RC) subdivided into location zones (ZLj) associated with zone identifiers and comprising at least one cell (Cjk), characterized in that it comprises, when a standby mode radio communication terminal (Ti) enters a radio coverage area of a local radio access point (FBjkn), implanted in a cell io (Cjk) a location area (ZLj) having a surface radio coverage area greater than its own, and associated with a zone identifier different from that of this location area (ZLj) including its cell (Cjk): a recovery step of the zone identifier of said local radio access point (FBjkn), ls - a step of connecting this terminal (Ti) to said local radio access point (FBjkn), and an initiation step, by said terminal (Ti), a zon update procedure e said location of said network (RC) with said recovered area identifier, so that said network associates said terminal (Ti) said retrieved area identifier. 2. Method according to claim 1, characterized in that said procedure for updating the current location area of a terminal (T1) in standby mode is automatically performed by said network (RC) only when said terminal (Ti ) changes location area. 25 3. Method according to one of claims 1 and 2, characterized in that the connection of a terminal (Ti) to a local radio access point (FBjkn) is by correlation of received signals with access codes associated respectively with local radio access points (FBjkn). 4. Method according to claim 3, characterized in that the connection 30 of a terminal (Ti) to a local radio access point (FBjkn) is also done by analyzing the power of the signals emitted by the access points. local radio (FBjkn) and by selecting the local radio access point (FBjkn) with the strongest signals. 5. Method according to claim 4, characterized in that, when a terminal (Ti) in standby mode enters the radio coverage area of a local radio access point (FBjkn), and in case of reception by this terminal (Ti) connected to a radio access point (SBjk) of a cell (Cjk) of signals transmitted by this radio access point (SBjk) under a power greater than those of the signals emitted by the points of local radio access (FBjkn), said network (RC) deletes the connection between said terminal (Ti) and said radio access point (SBjk), so as to constrain said terminal (Ti) to connect to the radio access point local (FBjkn) whose signals are the most powerful among those emitted by said local radio access points (FBjkn). 6. Method according to one of claims 3 to 5, characterized in that said terminal (Ti) analyzes the received radio spectrum and performs a correlation of the received signals with the access codes which are respectively associated with the radio access points local (FBjkn) implanted in the cells (Cjk) which are part of the known location area (ZLj) in which it is located. 7. Method according to one of claims 3 to 5, characterized in that said terminal (Ti) analyzes the received radio spectrum and performs a correlation of the received signals with the access codes which are respectively associated with the radio access points local (FBjkn) whose associated geographical positions are contained in the known location area (ZLj) in which it is located. 8. Method according to one of claims 3 to 7, characterized in that is transmitted to a terminal (Ti) access codes local radio access points (FBjkn) which are located in the cells (Cjk ) forming part of the known localization area (ZLj) in which it is located. 9. Method according to one of claims 3 to 7, characterized in that is transmitted to a terminal (Ti) the access codes of all local radio access points (FBjkn) which are located in the cells (Cjk) of said network (RC). 10. Method according to one of claims 3 to 9, characterized in that once the procedure for updating the localization area of a terminal (Ti) is completed, said terminal (Ti) is forced to transfer its connection to a radio access point (SBjk) of the cell (Cjk) in which is implanted the local radio access point (FBjkn) to which it has connected. 11. Method according to one of claims 1 to 10, characterized in that said terminal (Ti) is associated with the geographical position which is associated with the recovered area identifier of said local radio access point (FBjkn) to which he just connected. 12. System for locating radio communication terminals (Ti) in standby mode in a cellular radio communication network (RC) subdivided into location zones (ZLj) associated with zone identifiers and comprising at least one cell (Cjk). ), characterized in that it comprises: - at least one local radio access point (FBjkn) implanted in a cell (Cjk) of a localization area (ZLj) having a radio coverage area greater than his own, and associated with a zone identifier different from that of the localization zone (ZLj) of which his cell (Cjk) is part, - connection means (MC) arranged, when a radio communication terminal (Ti) ) in standby mode enters the radio coverage area of said local radio access point (FBjkn), to recover said zone identifier of said local radio access point (FBjkn), and to connect to said terminal (Ti) at this local radio access point (FBjkn), and - means of update (MM) arranged to initiate at said terminal (Ti) a location area update procedure within said network (RC) with said recovered area identifier, so that said network (RC) associates said terminal (Ti) said retrieved area identifier. 25 13. System according to claim 12, characterized in that said connection means (MC) are arranged to analyze the received radio spectrum and correlate the received signals with access codes associated respectively with local radio access points. (FBjkn) to connect a terminal (Ti) to one of these local radio access points (FBjkn). 30 14. System according to claim 13, characterized in that said connection means (MC) are arranged to analyze the power of signals emitted by said local radio access points (FBjkn) and received by said terminal (Ti) and to connect it. last (Ti) at the local radio access point (FBjkn) which transmitted the received signals with the greatest power. 15. System according to claim 14, characterized in that said s connection means (MC) are arranged, in the case of suppression by said network (RC) of a connection between a terminal (Ti) and a radio access point. (SBjk) of a cell (Cjk) subsequent to the reception by this terminal (Ti) of signals transmitted by this radio access point (SBjk) under a power greater than those of the signals emitted by local radio access points (FBjkn), for connecting said terminal (Ti) to the local radio access point (FBjkn) whose signals are the most powerful among those emitted by said local radio access points (FBjkn). 16. System according to one of claims 13 to 15, characterized in that said connection means (MC) are arranged to analyze the received radio spectrum and to correlate the received signals with the access codes which are associated respectively to the local radio access points (FBjkn) implanted in the cells (Cjk) which are part of the known location area (ZLj) in which said terminal (Ti) is located. 17. System according to one of claims 13 to 15, characterized in that said connection means (MC) are arranged to analyze the received radio spectrum and to correlate the received signals with the access codes which are associated respectively to the local radio access points (FBjkn) whose associated geographical positions are contained in the known location area (ZLj) in which said terminal (Ti) is located. 25 18. Radio network controller (NC) for a radio communication network (RC), said controller (NC) being able to control at least one radio access point (SBjk) of a cell (Cjk) of said network (RC ) in which is implanted at least one local radio access point (FBjkn), characterized in that it is arranged, when a radio communication terminal (Ti), in standby mode and connected to said access point radio (SBjk) of said cell (Cjk), enters the radio coverage area of said local radio access point (FBjkn), and if this terminal (Ti) receives signals transmitted by this radio access point (SBjk) under a power greater than that of the signals emitted by said local radio access point (FBjkn), to order the deletion of the connection between said terminal (Ti) and said radio access point (SBjk), so as to constraining said terminal (Ti) to connect to said local radio access point (FBjkn). 19. Local base station (FBjkn) for acting as a local radio access point in a cell (Cjk) of a location area (ZLj) having a radio coverage area of area greater than its own, associated with a zone identifier and forming part of a radio communication network (RC), characterized in that it is associated with a zone identifier different from that of said location zone (ZLj) of which its cell is part (Cjk ), and in that it is arranged when a radio communication terminal (Ti) in standby mode is attached to it and a location area update procedure has been carried out within said network (RC) for said terminal (Ti) with its zone identifier, for constraining the terminal (Ti) to transfer its connection to a radio access point (SBjk) of said cell (Cjk).