FR2947135A1 - METHOD AND SYSTEM FOR LOCATING A MOBILE COMMUNICATION DEVICE. - Google Patents

Abstract

A mobile communication device is in an environment comprising at least two communication networks respectively defined by at least two groups of cells (Cj) and comprising several passage points (Pn) between the communication networks. A locating method comprises a step of detecting (S3) the passage of the mobile communication device between a cell of a first communication network and a cell of a second communication network; an identification step (S5) of the cell (Cj) to which the mobile communication device belongs in one of the communication networks; and a detection (S6) and locating step (S7) in the identified cell (Cj) of a passage point (Pn) between said at least two communication networks. Use in particular for an underground communication network and a surface communication network.

Description

The present invention relates to a method for locating a mobile communication device in an environment. It also relates to a localization system adapted to implement the location method. In general, the present invention relates to the location of a mobile communication device in an environment equipped with a communication network. In known manner, a communication network consists of several base stations or antennas adapted to communicate with the mobile communication devices and distributed in the space so as to ensure full coverage of the environment equipped with the communication network. A communication network is thus defined by a group of cells, each cell corresponding to the coverage space of a base station associated with this cell. A mobile communication device moving in the environment thus moves from cell to cell, the communication network being adapted to ensure the continuity of communications during the movement of the mobile communication device, by changing the adapted base stations. to communicate with the mobile communication device. By knowing the location of the base stations and each associated cell, it is possible to know the location of a mobile communication device in an environment. However, the fineness of this location is dependent on the density of the base stations and the dimensions of the cell covered by each base station.

Thus, in practice, a mobile communication device in connection with a base station can be located at a reference point of this base station in the environment, with a radius of uncertainty around that reference point.

When the environment is equipped with several distinct communication networks, for example a surface communication network and an underground communication network, it is possible to locate the mobile communication device in one or the other network. communication, always thanks to the cells.

The present invention aims at improving the accuracy of the location of a mobile communication device by proposing a location method in the context of an environment comprising at least two distinct communication networks. For this purpose, the present invention relates, according to a first aspect, to a method of locating a mobile communication device in an environment comprising at least two communication networks defined respectively by at least two groups of cells, each cell being associated with a station. base station adapted to communicate with the mobile communication device, and the environment comprising several points of passage between said at least two communication networks. According to the invention, the location method comprises the following steps: detecting the passage of the mobile communication device between a cell of a first communication network and a cell of a second communication network; identifying the cell to which the mobile communication device belongs in one of said at least two communication networks; - Detecting in the identified cell at least one point of passage between said at least two communication networks; and 30 - locating said mobile communication apparatus at a detected waypoint.

Thus, by coupling the information concerning the points of passage existing between the communication networks in the environment and the cell to which the mobile communication device belongs, it is possible to precisely locate a mobile communication device at one end. existing points of passage between the communication networks when detecting a change of communication networks of a mobile communication device. This location information is more accurate than the simple location information provided by the cell to which the mobile communication device belongs. This fine position of the mobile communication device in its environment can then be taken into account for the generation of different services or applications for the mobile communication device. In particular, the location method further comprises a step of determining a direction of passage of the mobile communication device between the first communication network and the second communication network in association with the location point of passage. This information thus makes it possible to manage the applications available at the level of the mobile communication device or the messages to be addressed according to its entry into one or other of the communication networks of the environment. In practice, the location method further comprises a step of sending an information message to the mobile communication device, the information message sent being selected according to the location point of passage and the direction of the message. determined passage. In one embodiment, the information message is further selected according to a temporal and / or spatial context related to the environment and / or to an individual provided with said mobile communication device. According to a feature of the invention, the location method further comprises a step of storing the location of the passage points for a mobile communication device moving in the environment.

This memorized information makes it possible to track the movements of a mobile communication device. The locating method according to the invention is particularly applicable when a first communication network is a surface network and a second communication network is an underground network and for example an underground transport network of the metropolitan network or network type. rail. According to a second aspect, the present invention relates to a system for locating a mobile communication device in an environment comprising at least two communication networks defined respectively by at least two groups of cells, each cell being associated with a suitable base station. to communicate with the mobile communication device. This locating system comprises: means for storing the coordinates of each cell associated with a base station of each communication network in the environment; means for storing the points of passage between said at least two communication networks and coordinates of the points of passage in the environment; means for detecting the passage of a mobile communication device between a cell of a first communication network and a cell of a second communication network; means for identifying the cell to which the mobile communication device belongs in one of said at least two communication networks; detection means in the identified cell of at least one passage point between said at least two communication networks; and means for locating said mobile communication device 30 at a detected point of passage.

This locating system has characteristics and advantages similar to those described above in relation to the locating method according to the invention. Finally, the present invention also relates to a computer program comprising instructions for implementing the locating method according to the invention, when this program is executed by a processor. Other features and advantages of the invention will become apparent in the description below.

In the accompanying drawings, given by way of non-limiting examples: FIG. 1 is a diagrammatic sectional illustration of an environment with two communication networks in which the localization method according to the invention can be implemented; FIG. 2 is a schematic view from above of the environment of FIG. 1; FIG. 3 is an algorithm illustrating a localization method according to one embodiment of the invention; and - Figure 4 is a block diagram illustrating a location system according to one embodiment of the invention.

Firstly, with reference to FIGS. 1 and 2, an environment equipped with two communication networks will be described. The number of communication networks is given by way of non-limiting example in the remainder of the description, the invention being applicable to any environment comprising at least two communication networks.

In this embodiment, a first communication network R1 is a surface network disposed above the earth's surface and the second communication network R2 is an underground communication network located below the earth's surface. Such an underground communication network can in particular be realized in equipment (corridor, station, tunnel, ...) of a buried transport network, of the metropolitan transport type.

Each communication network is defined by several base stations or transmitting antennas adapted to communicate with mobile communication devices, of the mobile phone type, personal assistant (in English terminology "Persona / Digital Assistant"), ...

FIG. 1 illustrates, solely by way of nonlimiting example, three base stations A1, A2, A3 equipping the first communication network R1. Each base station A1, A2, A3 has a coverage area, called a cell, in which the base station A1, A2, A3 is adapted to communicate with a mobile communication device located in this coverage area. Thus, at each base station A1, A2, A3 is associated with a cell C1, C2, C3. Of course, the communication network R1 must have enough base stations A1, A2, A3 to be formed of a group of cells C1, C2, C3 adapted to cover the entire environment in which this first is located. communication network R1, that is to say here the whole of a surface area defined above the terrestrial layer. In practice, the first surface communication network may be a GSM network (acronym for the "Global System for Mobile Communication" terms) for which each base station A1, A2, A3 is produced by a BTS antenna (acronym for the terms Anglo-Saxon "Base Transceiver Station"), commonly known as relay antenna. Similarly, the second communication network R2 is defined by a set of base stations B1-B10 also adapted to communicate in transmission and reception with mobile communication devices located in the underground network. Similarly, each base station B1-B10 defines a cell (not shown) corresponding to its coverage area, the set of cells being adapted to cover the entire underground network to form the second communication network R2 .

By way of nonlimiting example, the second communication network R2 may consist of a UMTS network (acronym for the English terms "Universal Mobile Telecommunications System") whose base stations are nodes B (in English "node"). B ") equivalent to relay antennas.

Of course, the two communication networks R1, R2 may both be a GSM network or both a UMTS network, each network being partitioned into two separate communication networks in the environment. Moreover, the environment comprises several passage points P1, P2, P3, P4, P5 between the two communication networks R1, R2. Typically, these passage points P1, P2, P3, P4, P5 correspond to a physical zone of passage between the surface network R1 and the underground network R2, that is to say to a communication network change zone. between the first communication network R1 and the second communication network R2. As clearly illustrated in FIG. 2, these passage points P1, P2, P3, P4, P5 are discrete zones of the environment, independent of one another. By way of nonlimiting example, these passage zones P1, P2, P3, P4, P5 may consist of entry and exit accesses to the underground network R2 from the surface network R1 and are therefore distributed in the following manner: environment in a discontinuous manner. In practice, the same passage zone P1, P2, P3, P4, P5 may comprise several inputs / outputs between the networks R1, R2, located close to each other in the environment. A method of locating a mobile communication device m when it moves in the environment as described above with reference to FIGS. 1 and 2 will now be described with reference to FIG.

Conventionally, when a mobile communication device m is traveling in a communication network, information is exchanged between the mobile communication device m and the base stations of the network, this signaling corresponding to an automatic intercellular transfer implemented in the mobile communication device m. This signaling corresponds to the information concerning the mobility of the mobile communication device m in the communication network. It may be a location update procedure when there is a change of location area at the mobile communication device m while it is not in direct communication with a station basic.

It can also be the mechanism conventionally implemented to allow a mobile communication device m to change cells without interruption of service while it is in communication. This mechanism, also called in English terminology "Handover", manages cell changes at a mobile communication device m moving in the environment. In practice, this signaling information Sig is received during a reception step S1. This signaling can be carried out by an interface A for a GSM communication network or by LUB interfaces for a UMTS communication network. The use of these interfaces for transferring signaling information is well known in these GSM and UMTS communication networks and need not be described in detail here. A test step S2 makes it possible to check whether the cells C (t) and C (t-F1), in which the mobile communication device m is located at two successive instants t and t + 1, belong to the same communication network. Ri. If so, there is no detection of a change of communication network at the mobile communication device m and the signaling reception step S1 is repeated until the arrival of new signaling information transmitted by the mobile communication device m.

If at the end of the test step S2, the cells at successive instants t, t + 1 do not belong to the same communication network, a detection step S3 is implemented, corresponding to the detection of the passage of the mobile communication device m between a cell of a first communication network, for example here the first communication network R1, and a cell of a second communication network, for example here the second communication network R2 .

A determination step S4 is also adapted to determine from the signaling information and the succession of cells in time, a direction of passage S of the mobile communication device m, between the communication networks R1, R2 . Thus, taking the example above, the determination step S4 is adapted to determine a direction of passage S of the surface network R1 to the underground network R2, that is to say an entry into the underground network R2. An identification step S5 is then implemented in order to identify the cell Cj to which the mobile communication device m belongs in one of the communication networks.

Preferably, this cell identification Cj is implemented among the cells of the first communication network R1, that is to say among the C1, C2, C3 cells as described above with reference to FIGS. 1 and 2. identification of the cell Cj can be easily performed from the knowledge of the base station A1, A2, A3 which corresponds to the coverage area in which the mobile communication device m is located. As well illustrated in FIG. 2, each cell Cj, j = 1 to 3, is defined by a reference point 01, 02, 03 and an uncertainty radius R around this reference point 01, 02, 03. This reference point 01, 02, 03 may substantially correspond to the coordinates at the terrestrial surface of a base station A1, A2, A3. Thanks to the knowledge of the passage points Pn existing between the two communication networks R1, R2, at the terrestrial surface, and their location in cells Cj defining the first communication network R1, it is possible to detect in the identified cell Cj one or more points of passage Pn in a detection step S6.

By way of nonlimiting example, as illustrated in FIG. 2, when the mobile communication device m changes communication networks R1, R2 through the waypoint P1, the cell C1, to which the mobile device belongs in connection with the base station A1, having as a reference point 01 and a coverage area of uncertainty radius R, is identified. The waypoint P1 is detected automatically when the mobile communication device m must both belong to the cell C1 and be located at a passage point Pn between the two communication networks R1, R2.

In order to allow the implementation of this detection step S6, a database BD1 is adapted to memorize in association the different passage points Pn existing between the two communication networks R1, R2 and their position in space, and in particular their coordinates on the terrestrial surface, in connection with the areas covered on the terrestrial surface by the cells Cj of the first communication network. The coordinates at the terrestrial surface of the various points of passage can be provided by a GPS system (acronym for the terms "Global Positioning System") or manually entered in the database BD1 by an operator from a localization plane. the crossing points on the Earth's surface. When there are several passage points Pn in the same cell of the communication network, and for example passage points P2, P4 in a cell C2, as shown in FIG. 2, the detection step S6 is adapted to detect the points of passage P2, P4 between the two communication networks R1, R2 from the identification of the cell C2, that is to say all the passage points P2, P4 belonging to the identified cell C2. In the locating step S7, the mobile communication device m is located at one of these points of passage P2, P4. When only one waypoint P1 belongs to the cell C1, the location of the mobile communication device m is automatically performed at this point of passage P1.

When there are several points of passage P2, P4, this location step S7 can be implemented from previously memorized context information, for example concerning the habits or preferences of the individual equipped with the mobile device. communication m.

By way of non-limiting example, these known and memorized habits may include the list of the points of passage (for example metro stations) frequented preferentially by the individual. In the absence of context information, the location step S7 is implemented by selecting a default waypoint from the passage points detected at the detection step S6. This default selection can be made for example by giving priority to the most frequent crossing point among the detected crossing points, on the basis of statistics and / or information stored from the behavior of individuals in the environment equipped with communication networks. R1, R2. A storage step S8 may furthermore be implemented in order to memorize all the set points of passage Pn for a mobile communication device m traveling in the environment. When the set of steps S1 to S8 is reiterated, it is possible, at the end of the storage step S8, to obtain a follow-up of all the successive points of passage of location for the mobile device of communication m. This type of data can in particular be used for the implementation of statistics on the use of an underground transport network or to know the frequentation of different areas of the environment, for example neighborhoods of a city. When this location information of the passage points Pn is stored for a mobile communication device in association with time data (day, hour, holiday period, ...), it is possible to obtain statistics over time on the use of an underground transportation network by the population.

It will be noted in particular that the example described above relates to the location of a mobile communication device but that of course the localization method can be implemented for several mobile communication devices in parallel.

Moreover, if the location information thus stored is associated with different data relating to the individuals (or subscribers) provided with the different mobile communication devices, more elaborate statistics can also be obtained. In addition, a step of selecting and sending S9 a message information Mes to the mobile communication device m can be implemented from the information thus determined, including the location of a point of Pass Pn and the determined direction of passage S. The information message Mes can thus be selected according to the behavior of an individual equipped with the mobile communication device m.

Thus, the sending of a message selected at a particular time, corresponding to a precise location of an individual equipped with a mobile communication device can be made in a relevant and detailed manner so that the message sent and received on the mobile communication device has an interest for this individual.

Thus, the location of a passage point Pn associated with a direction of passage S may correspond to an event associated with the mobile communication device m. Returning to the previous example, when the mobile communication device m is located in a waypoint P1, in association with a direction of passage S corresponding to a passage from the surface network R1 to the underground network R2, the event detected corresponds to an entry into the underground transport network. This event can then be used to select one or more information messages and send these information messages to the mobile communication device m. These messages can be selected in a relevant manner to transmit information on the underground transport network, and more particularly on a transport line that can be used by the individual entering at this point of passage P1 in the underground transport network. By way of non-limiting example, this relevant information may correspond to information on the disturbances of service on the transmission line, the closing of a station, the hours of service, etc. Likewise, when an event of output of the underground transport network is detected at a passage point Pn, it is possible to address proximity information messages, corresponding to the environment close to the location point Pn, to which the mobile communication device is located. m. This proximity information may in particular correspond to opening and closing times of various local services or merchants, or include advertising messages on promotional operations carried out in the immediate vicinity of the localized crossing point Pn. The information messages addressed to the mobile communication device are chosen according to a temporal and / or spatial context related to the environment and / or the individual provided with the mobile communication device.

The time context related to the environment may be especially the time or the particular day at which the location of the mobile communication device takes place. The temporal context linked to an individual can be determined by usual hours of travel (work - home, leisure, activity ...).

The spatial context related to the environment or to the individual may include the location of such or such sign or trade or service near the location point or the preferential services or shops indicated by the individual and stored in a database. data. Of course, these examples of practical use and application for the implementation of services adapted to the localization provided by the localization method according to the invention are given solely by way of non-limiting examples and can be very varied. .

More generally, the precise location implemented by the method described above allows the sending of information on events related to the underground transport network when detecting an entry in this network, sending information of proximity to the external environment during the detection of the output of the underground network, or the coupling of the information stored at points of passage and the direction of passage with personal information associated with the individual equipped with the mobile device of communication for the development of statistics. FIG. 4 also illustrates a schematic embodiment of a positioning system adapted to implementing the locating method described above. This locating system 40 comprises in particular means 41 for detecting the passage of a mobile communication device m between a cell of a first communication network and a cell of a second communication network. These detection means 41 comprise, for example, one or more sensors Sr adapted to receive a signaling as described previously issued by the mobile communication device m, corresponding to an automatic intercell handover implemented during the movement of the mobile communication device. m in the environment. The locating system 40 also comprises storage means, consisting here of a database BD1 adapted to store the coordinates of each cell Cj associated with each base station A1, A2, A3, B1-B10 of each communication network. R1, R2.

These storage means BD1 are also adapted to memorize the passage points Pn existing between the two communication networks R1, R2 as well as the coordinates in space, and in particular the terrestrial surface of these passage points Pn. The locating system 40 further comprises a microprocessor 42 adapted to implement the steps of the locating method described above.

This microprocessor 42 thus comprises means for identifying the cell to which the mobile communication device m belongs in one of the communication networks, and for example one of the cells Cj of the surface communication network R1.

These identification means are adapted from the information provided by the sensors Sr to identify the cell to which the mobile communication device m belongs. In connection with the storage means BD1, the microprocessor 42 also comprises means for detecting and locating in the identified cell a passage point Pn between the two communication networks R1, R2. The microprocessor 42 is further adapted to integrate means for determining the direction of passage S of the mobile communication device between the two communication networks R1, R2, in particular from the signaling information addressed by the sensors Sr. previously, when the location information thus determined is used to select relevant messages to be sent to the individual equipped with the mobile communication device, the microprocessor 42 may also include means for selecting an information message to from a message database and sending means adapted to send the selected information message My to the mobile communication device m. Furthermore, in the applications described above, in which personal information related to the individual equipped with the mobile communication device m are used, second storage means, consisting of a database BD2, can be integrated into the location system 40 and be used by the microprocessor 42 in the generation of detailed messages to the individual or the development of statistics.

All these means integrated microprocessor 42 are implemented in a conventional manner by computer programs or software.

Of course, many modifications can be made to the previous examples without departing from the scope of the invention.

Claims (12)

REVENDICATIONS1. A method of locating a mobile communication device (m) in an environment comprising at least two communication networks (R1, R2) respectively defined by at least two groups of cells (Cj), each cell (Cj) being associated with a base station (A1, A2, A3, B1-B10) adapted to communicate with said mobile communication apparatus (m), said environment comprising a plurality of passage points (Pn) between said at least two communication networks (R1, R2) , characterized in that it comprises the following steps: - detection (S3) of the passage of said mobile communication device (m) between a cell of a first communication network (R1) and a cell of a second communication network (R2); identifying (S5) the cell (Cj) to which said mobile communication device (m) belongs in one of said at least two communication networks (R1); detecting (S6) in said identified cell (Cj) at least one passage point (Pn) between said at least two communication networks (R1, R2); and locating (S7) said mobile communication apparatus (m) at a detected waypoint (Pn). 2. A locating method according to claim 1, characterized in that it further comprises a step of determining (S4) a direction of passage (S) of said mobile communication device (m) between said first network of communication (R1) and said second communication network (R2) in association with said location point of passage (Pn). 3. Localization method according to claim 2, characterized in that it further comprises a step of sending (S9) to said mobile communication device (m) an information message (Mes), said message 30 of information sent (Mes) being selected according to the location point of passage (Pn) and the determined direction of passage (S). 18 4. Location method according to claim 3, characterized in that said information message (Mes) is further selected according to a temporal and / or spatial context related to the environment and / or to an individual provided with said mobile communication device (m). 5. Localization method according to one of claims 1 to 4, characterized in that it further comprises a step of storing (S8) said location passage points (Pn) for a mobile communication device (m) traveling in said environment. 6. Location method according to one of claims 1 to 5, characterized in that a first communication network is a surface network (R1) and a second communication network is an underground network (R2). 7. A localization method according to claim 6, characterized in that said step of identifying (S5) a cell (Cj) is carried out among the cells (C1, C2, C3) of the surface network (R1 ). 8. System for locating a mobile communication device (m) in an environment comprising at least two communication networks (R1, R2) defined respectively by at least two groups of cells (Cj), each cell (Cj) being associated a base station (A1, A2, A3, B1-B10) adapted to communicate with said mobile communication device (m), characterized in that it comprises: - means for storing (BD1) the coordinates of each cell (Cj) associated with a base station of each communication network in said environment; storage means (BD1) for passing points (Pn) between said at least two communication networks (R1, R2) and coordinates of said passage points (Pn) in said environment; means for detecting (41) the passage of a mobile communication device (m) between a cell of a first communication network (R1) and a cell of a second communication network (R2); identifying (42) the cell (Cj) to which said mobile communication apparatus (m) belongs in one of said at least two communication networks (R1, R2); and detection means (42) in said identified cell (Cj) of at least one passage point (Pn) between said at least two communication networks (R1, R2); and - locating means (42) of said mobile communication apparatus (m) at a detected passage point (Pn). 9. Location system according to claim 8, characterized in that the detection means (41) comprise one or more sensors (Sr) adapted to receive signaling corresponding to an automatic intercellular transfer implemented in said mobile device. communication (m). 10. Location system according to one of claims 8 or 9, characterized in that it further comprises means (42) for determining a direction of passage (S) of said mobile communication device (m). between a first communication network (R1) and a second communication network (R2). 11. Location system according to claim 10, characterized in that it comprises means (42) for selecting an information message (Mes) for said mobile communication device (m), said message d information (Mes) being selected according to said location point of passage (Pn) and the determined direction of passage (S), and sending means (42) to said mobile communication device (m) of said message 25; selected information (My). 12. Computer program comprising instructions for implementing the method according to one of claims 1 to 7, when the program is executed by a processor (42).