WO2009050392A2 - Method for discovering the cover of a broadcasting network by a multimode terminal, and corresponding computer software product, signal and terminal - Google Patents

Abstract

The invention relates to a method for discovering the cover of a second broadcasting network by a multimode terminal that comprises first and second operation interfaces allowing said terminal to be connected respectively to a first radiocommunication cellular network and to a second broadcasting network, the first network including a set of first cells (10) and the second network including a set of second cells (20) having a surface area larger than that of the first cells (10). The method comprises a reception step, in which the terminal receives from the first network and via the first operation interface, at least one piece of information describing the cover of the second network.

Description

 Method of discovering the coverage of a broadcast network by a multimode terminal, computer program product, signal and corresponding terminal. FIELD OF THE INVENTION The field of the invention is that of cellular radiocommunication networks (also called cellular wireless data transmission networks), such as in particular, but not exclusively: two-way radio networks, voice and data networks. point-to-point, such as telecommunication networks using one of the following technologies: GSM (Global System for Mobile

Communications), 3G (third generation), 4G (fourth generation), DECT (Digital Enhanced Cordless Telecommunications), Code Division Multiple Access (CDMA), Wi-Max (Worldwide Interoperability for Micro Wave Access) ...; and - unidirectional broadcast networks, such as broadcast networks using one of the following technologies: DVB-H (Digital Video Broadcasting - Handheld), TNT (Digital Terrestrial Television), S / T-DMB (Satellite / Terrestrial - Digital Multimedia Broadcasting), DVB-SH (Digital Video Broadcasting - Satellite to Handheld) ... More precisely, the invention relates to a technique for discovering the coverage of a second broadcast network by a multimode terminal comprising first and second operating interfaces enabling the terminal to connect respectively to a first cellular radio network and a second broadcast network. It applies only in cases where the coverage of the first cellular network is greater than that of the second broadcast network.

The first network is for example a two-way radio communication network and the second network is a unidirectional broadcast network.

Thus, one of the many possible applications of the invention is, for example, the discovery of the coverage of a DVB-H network by a dual-mode 3G / DVB-H terminal using a 3G interface by default, the discovery of the broadcast network enabling immediate access to the broadcast network present in the service area of the two-mode terminal.

2. TECHNOLOGICAL BACKGROUND

The cellular radiocommunication networks consist of a set of cells which, juxtaposed with each other, make it possible to create a larger network.

A cell represents the area covered by a base station (telecommunication network). The base station (GSM terminology) is also called node B

(or NODE-B in English) in the terminology 3G (UMTS).

The broadcast networks consist of a set of cells which, juxtaposed with each other, make it possible to create a coverage area of the larger broadcast service.

A cell represents the area covered by, in a first case, a single scattering transmitter, or, in a second case, by several scattering transmitters allowing the construction of a larger cell elaborated by juxtaposition of the cells defined in FIG. first case, totally synchronized with each other, transmitting on the same frequency with the same transmission characteristics (frequency, bandwidth, signaling ...). The union of these cells thus specified contributes to the creation of a SFN (Single Frequency Network) which in the case of the invention is simply referred to as cells. An SFN is the union of several broadcast transmitters whose set of juxtaposed covers creates a larger cell.

In the case where two broadcast cells of the same technology (for example DVB-H) do not have the same characteristics (different frequencies), these cells are not part of the same network. These cells then form an MFN network. Two SFN or MFN broadcast network cells may not be joined

(eg presence of a geographical area not covered by a broadcast network) Depending on the nature of the networks (modulation, transmission power, etc.) or according to the network planning put in place to increase the communication capacity of the network. a cell, the densitication of the cells is more or less important and the cells which constitute the network are of more or less large sizes. Multimode mobile terminals have several physical interfaces. They thus make it possible to have different services according to the network used, even to obtain the continuity of service between two networks. The presence of several reception / transmission interfaces allows the terminal to synchronize on one or the other network. Conventionally, multimode terminals have a default operating interface associated with a first dense deployment network (called the "G network"). The other interfaces are complementary to the default interface. They are associated with second networks (let's call this type of network "network H") whose deployment is less dense than the first network (network G), may present in places geographical areas not covered by the network H. In other words, some parts of the territory are covered by the G network and are not covered by the H network.

FIG. 1 shows an example of such networks G and H to which a multimode terminal can connect. In this example, the particular case in which the network G consists of a set of cells (of which that referenced 1 in FIG. 1) whose size is smaller than that of the cells of the network H (of which that referenced 2 in Figure 1).

A dual-mode terminal wishing to connect to the network H must detect the coverage of the network H. For this, according to the current technique, the terminal must analyze the entire frequency band to find the one on which the service he wishes to receive is located. This analysis of the frequency band takes time (of the order of 5 minutes), in particular in the case where no service is found on the network H. Indeed, the terminal will scan (scan) the entire band of frequencies corresponding to the country where it is, to synchronize itself on a frequency and to check that it is of nature of a network H. If it is not the case, the terminal continues its scanning (scan), until find the right H network. In the case where the terminal is located in an area where coverage of network H is absent, the terminal will have scanned the entire frequency band for not having discovered any service, which will lead to needlessly consume the terminal's battery, and present a perceived poor quality of customer service by presenting a service outage after several minutes of service search. The aforementioned current technique of discovering the coverage of a broadcast network by a multimode terminal is therefore not optimal, both in terms of speed of access to the network (search time of a service), in terms of consumption of energy, - in terms of cell change for MFN networks, in terms of perceived quality of customer service. 3. STATEMENT OF THE INVENTION

The invention provides a method of discovering the coverage of a second broadcast network by a multimode terminal having a bidirectional link with a first network whose cell size is smaller than the size of the cells of the second aforementioned network. This invention makes it possible to optimize the search in terms of the search and availability time of a second broadcast network, to optimize access to the second network by providing the two-mode terminal with the description information of the second network needed to reach the second network. connect to the second network (frequency, bandwidth), to participate in an optimization of the handover 3G to DVB-H for the common services available on the two networks avoiding time of discovery of the second network as mentioned above, - contribute to improving the handover between two broadcasting networks of the same type but having different transmission characteristics (in the case of broadcast networks MFN), to improve the consumption of the battery, by suppressing the search times of the second network, by optimizing and significantly decreasing the discovery time of the second network or a second cell of the second network for an MFN network to improve the customer experience and perceived user service quality by providing access times to the services delivered on the second network faster or by presenting to the user messages of unavailability of service information on the second network in very short time. In the embodiment of the invention, there is provided a method of discovering the coverage of a second broadcast network by a multimode terminal comprising first and second operating interfaces allowing said terminal to connect respectively to a first a cellular radio network and a second broadcast network, the first network comprising a set of first cells and the second network comprising a set of second cells having larger areas than those of the first cells.

In a first embodiment of the invention, the method comprises a reception step, according to which the terminal receives from the first network, via the first operating interface, information describing the coverage of the second network which is broadcast information. in signaling data, by a device associated with the first current cell to which the terminal is connected, and if said information indicates a presence of the coverage of the second network, then the terminal receives the following additional information of description of the second network coverage: frequency information and bandwidth information of the channel.

The description information also indicates, for example, the presence or absence of a (second) broadcast network of a particular type (for example a DVB-H broadcast network).

Thus, the signaling broadcast by the first network is used to transmit information relating to the coverage of the second network in each first cell.

The general principle of the proposed technique is therefore to take advantage of information transmitted by the first network (called network G in the aforementioned context) to detect the coverage of the second network (called network H in the aforementioned context). Thus, in this particular embodiment, the invention is based on a completely new and inventive approach allowing the terminal to determine that it is under cover of the second network (network H) without its interface with it. second network is active; it uses the information of its active interface with the first network (network G), which is for example its default network.

In this way, compared to the conventional technique mentioned above, the time of access to the second network by the terminal and the power consumption of the terminal are reduced. It also improves the perception of quality of service for the end user of the terminal.

The condition on the cell sizes (first cells smaller than the second cells) is imperative for each first cell to broadcast the complementary frequency and channel band information. An additional advantage over the condition of the sizes of the first cells smaller than the sizes of the second cells makes it possible to guarantee 100% the presence of service or the lack of service offered by the second network. Indeed, the cells of the first network are totally included in the second network or totally included, or even partially included. The second network is constantly superimposed by cells of the first network.

In a second particular embodiment of the invention, the method comprises a step of transmission by the terminal to the first network of a request. In addition, in said receiving step, the description information of the coverage of the second network received by the terminal is a response to said request, from the first network and function of at least one location information of said terminal.

Thus, in this second embodiment, a request / response mechanism is used between the terminal and the first network. A first embodiment of the request / response mechanism allows the terminal to ask the first network for the said information necessary for the terminal to know the absence or the presence of said second network, and to have said additional information to connect to said second network. This first mode realizes the location of the terminal by the network with a precision related to the size of the cell of the first network. A second embodiment in query / response mode allows, if the location information used by the terminal is sufficiently accurate (coordinates from a positioning system present in the terminal such as GPS or the Galileo system, known from the terminal and up to said first network) and if the correspondence between the positions of the terminal and the coverage of the second network is also sufficiently accurate, a discovery much finer than with the first embodiment by signaling or the first mode of the query mode / response (with the first mode, the discovery granularity of the second network coverage is the size of the first cell). Advantageously, in said receiving step, if said first information indicates a presence of the coverage of the second network, then the terminal receives the following additional information of description of the coverage of the second network: a frequency information and a bandwidth information of the canal.

According to an advantageous characteristic of this second embodiment, said request is accompanied by at least a first location information of said terminal, and said response is a function of said at least first location information of said terminal.

Advantageously, said at least one location information of said terminal belongs to the group comprising: an identifier of the first current cell to which the terminal is connected; and location information provided by a geographical location means internal or external to the terminal.

According to another advantageous characteristic of this second embodiment, the method comprises a step of determination by the first network of at least a second location information of said terminal, and said response is a function of said at least one second location information of said terminal.

Said first and second networks respectively belong to the group comprising two-way radio communication networks and to the group comprising unidirectional broadcast networks. In another embodiment, the invention relates to a computer program product downloadable from a communication network and / or recorded on a computer readable medium and / or executable by a processor, said computer program product comprising instructions program code for implementing the aforementioned method of discovery, when said program is run on a computer.

In another embodiment, the invention relates to a signal transmitted from a first cellular radio network to a multimode terminal comprising first and second operating interfaces enabling said terminal to connect respectively to said first network and to a second broadcast network. . The signal comprises at least one field containing at least one information description of the coverage of the second network, so as to allow the discovery of the coverage of the second broadcast network by the terminal.

Advantageously, the signal comprises at least a first field containing a first description information of the coverage of the second network, indicating a presence or absence of the coverage of the second network.

Advantageously, the signal comprises at least a second field containing the following additional information describing the coverage of the second network: a frequency information and a bandwidth information of the channel, if said first information indicates a presence of the cover the second network.

In another embodiment, the invention relates to a multimode terminal comprising first and second operating interfaces enabling said terminal to connect respectively to a first cellular radiocommunication network and a second broadcast network. The terminal comprises means for discovering the coverage of the second network comprising: means for receiving, via the first operating interface, at least one information describing the coverage of the second network; and means for analyzing said at least one information to access the second network. More generally, the multimode terminal according to one embodiment of the invention comprises means for implementing the discovery method as described above (in any one of its various embodiments).

4. LIST OF FIGURES Other features and advantages of embodiments of the invention will become apparent on reading the following description, given by way of indicative and nonlimiting example (not all the embodiments of the invention are not limited to the features and advantages of the embodiments described hereinafter), and the accompanying drawings, in which: - Figure 1 shows an example of first and second networks (3G and DVB-H) to which a multimode terminal can connect ; Figures 2 and 3 illustrate the concept of a first embodiment of the invention, wherein each cell of the first network (3G) broadcasts information describing the coverage of the second network (DVB-H); FIG. 4 illustrates the concept of a second embodiment of the invention, in which the transmission to the terminal of information describing the coverage of the second network (DVB-H) results from the implementation of a request / response type mechanism; FIG. 5 shows an exemplary signal structure for transmitting information describing the coverage of the second network (DVB-H), according to a particular embodiment of the invention; and FIG. 6 shows the structure of a multimode terminal according to one particular embodiment of the invention.

5. DETAILED DESCRIPTION In all the figures of this document, the elements and identical steps are designated by the same numerical reference.

The invention therefore relates to a discovery technique, by a multimode terminal capable of connecting to a first cellular radio network and a second broadcast network, the coverage of the second network. The principle is as follows: via a first operating interface, the terminal receives from the first network information relating to the coverage of the second network. Thus, the terminal can determine whether or not it is under cover of the second network without its operating interface with this second network being active. In other words, the terminal is assisted by the first network to obtain the necessary information to access the second network. This allows the terminal to optimize its access time to the second network, reduce battery consumption and improve the perception of quality of service for the end user.

By way of example, the application of the invention is subsequently considered in the discovery of the coverage of a DVB-H network by a dual-mode 3G / DVB-H terminal using by default a 3G interface for the telephony or data transfer. It is therefore assumed that the first cellular radio network is a 3G telecommunication network, and that the second broadcast network is a broadcast network.

DVB-H. It is clear however that many other applications of the invention can be envisaged, including: as a first network a telecommunications network or as a first network a broadcast network.

A first embodiment of the invention, in which each cell of the 3G network broadcasts information describing the coverage of the DVB-H network is now presented in connection with FIGS. 2 and 3.

As illustrated by FIG. 2, the network 3 G consists of a set of cells (including that referenced 10) whose size is smaller than that of the cells of the DVB-H network (of which that referenced 20).

In operating mode, the dual-mode terminal is by default listening on the 3G network. Since the coverage of the 3G network is greater than that of the DVB-H network and a cell of the 3G network is smaller than a cell of the DVB-H network, the node B of each cell of the 3G network broadcasts: a DVB-H network coverage presence information if this 3 G network cell is intersecting (i.e., in double coverage) with the DVB-H network; an information of absence of the coverage of the DVB-H network if this cell of the 3G network is not in double coverage with the DVB-H network. Thus, and as illustrated in FIG. 3, the terminal T receives, via its 3G operating interface, the information describing the coverage of the DVB-H network, which are broadcast (as symbolized by the arrow referenced 30) by the node. B of the 3G cell to which it is synchronized. Figure 2 also illustrates this concept. Hatched cells in the 3G network carry signaling that indicates the presence of DVB-H signal. The non-hatched 3 G network cells that are not in intersection with the DVB-H network, carry a signaling that indicates the absence of DVB-H signal.

It is recalled that in such a context of discovery of the coverage of a DVB-H network by a dual-mode 3G / DVB-H terminal using a 3G interface by default, the technique of the prior art is as follows. The terminal starts scanning (scanning) the entire frequency band (about 50 channels for DVB-H technology on UHF bands in France). When synchronizing with a channel, the terminal checks whether the signal is of a DVB-T or DVB-H nature by analyzing two bit fields in the information bits (TPS bits) transmitted by the DVB-T signal or DVB-H. If the bits do not indicate that it is a DVB-H signal, the terminal resumes scanning the frequency band. When it finds a frequency broadcasting a DVB-H service, by analysis of the MPEG2-TS transport layer information system tables (SI / PSI tables), the terminal is then autonomous to find its IP service. This process can take a long time (about 5 minutes to scan the entire tape) and is battery-consuming. Indeed, the autonomy gain provided by the DVB-H only appears when the terminal accesses its IP service (for example audiovisual service broadcast in IP multicast on the DVB-H network). The scanning (scanning) of the frequencies and the reading of the signaling broadcast in the broadcasting network is carried out, in an initial phase of DVB-T type reception and not in DVB-H reception mode, the DVB-H reception providing then an optimization on the consumption of the battery.

With the above-mentioned particular embodiment of the present invention, the 3G network support decreases the search time of the broadcast service, improves the quality of perceived customer service, allows optimization for the vertical handover between a service provided in 3G. to the same service available in DVB-H, participates in optimizing horizontal handover between broadcast cells in an MFN network and therefore optimizes battery consumption. When the terminal wishes to access the DVB-H network, by analyzing the signaling transmitted on the 3G network, the terminal is informed of the presence or absence of DVB-H signal (ie of the presence or not) coverage of the DVB-H network). In this case, it does not need to turn on its DVB-H interface to check for the presence of DVB-H signal in the zone. If, through 3G signaling, it is informed of the presence of the DVB-H network coverage, additional information (frequency and channel width) allows it to directly access the correct DVB-H frequency and with the correct signal. channel width.

In the case of a 3G / DVB-H terminal, each node B of a network cell

3G transmits for example the information of description of the coverage of the network

DVB-H in a "System Information Element" (or SIE for "System Information")

Element "in English) distributed in a" system information block "(or SIB for" System Information Block "in English) that this node B broadcasts in its 3G cell.

As illustrated in FIG. 5, the information describing the coverage of the DVB-H network, which is transmitted in the signaling of the 3G network, is for example the following: coverage by a broadcasting network (first information II): yes / no ; - type of broadcast network (second piece of information 12): DVB-H; the reception frequency of the DVB-H signal (third piece of information 13): f (for example, f = 602000000 Hz); the bandwidth of the channel (fourth piece of information 14): L (equal to 5, 6, 7 or 8 MHz.) A second embodiment of the invention, in which the transmission is presented, is now presented in connection with FIG. to the description terminal of the coverage of the DVB-H network results from the implementation of a request / response type mechanism.

Via its 3G operating interface, the terminal T transmits a request (as symbolized by the arrow referenced 41) to the node B of the 3G cell to which it is synchronized (also called current 3G cell). According to a first implementation, the terminal attaches to the query a location information. This is for example an identifier of the current 3G cell or GPS type information (or any other equivalent geolocation system) provided by a location module (internal or external to the terminal). According to a second implementation, the terminal does not attach location information to the request but this is done by the node B or other equipment of the 3G network (as symbolized by the arrow referenced 42). For example, in the case of a 3G cell comprising three angular sectors, a device in the 3G network can know in which angular sector is a mobile terminal and can therefore add this location information to a request from this mobile terminal. In another example, the node B or equipment in the network 3 G may have means for calculating the position of the terminals (location by triangulation for example).

Then, the request and the location information are transmitted to a device, for example a server S (as symbolized by the arrow referenced 43).

This server S obtains information describing the coverage of the DVB-H network that is a function of the location information attached to the request (as symbolized by the arrow referenced 44).

For example, in the case where the location information is the identifier of the current cell 3 G, the server S consults a correspondence table indicating for each cell 3 G 3 G network information description of the coverage of the network DVB-H in this 3G cell.

Then, the server S returns to node B these description information of the coverage of the DVB-H network (as symbolized by the arrow referenced 45). Finally, the node B sends to the terminal a response containing this description information of the coverage of the DVB-H network (as symbolized by the arrow referenced 46).

The information describing the coverage of the DVB-H network, which is transmitted in the response, is for example the same as those II to 14 (see Figure 5) detailed above in the first embodiment of the invention. FIG. 6 shows the simplified structure of a multimode terminal implementing the discovery method according to the invention (for example one of the first and second embodiments described above in relation to FIGS. 2 to 6). This terminal comprises a RAM 63, a processing unit 61, equipped for example with a microprocessor, and controlled by a computer program stored in a ROM 62. At initialization, the code instructions of the program of For example, the computers are loaded into the RAM 63 before being executed by the processor of the processing unit 61. The processing unit 61 receives, as input, via a first operating interface of the terminal on the first network (for example: example the 3G network), information 60 for describing the coverage of the second network (for example the DVB-H network). The microprocessor of the processing unit 61 analyzes the received information 60, according to the instructions of the program 62. The processing unit 61 outputs signals 64 to access the second network.

It should be noted that the invention is not limited to a purely material implantation but that it can also be implemented in the form of a sequence of instructions of a computer program or any form mixing a material part and a part software. In the case where the invention is partially or totally implemented in software form, the corresponding instruction sequence can be stored in a removable storage means (such as for example a floppy disk, a CD-ROM or a DVD-ROM) or no, this storage means being partially or completely readable by a computer or a microprocessor.

Claims

A method of discovering the coverage of a second broadcast network by a multimode terminal (T) comprising first and second operating interfaces enabling said terminal to connect respectively to a first cellular radio network and a second broadcast network. , the first network comprising a set of first cells (10) and the second network comprising a set of second cells (20) with larger areas than those of the first cells (10), characterized in that it comprises a reception step (30; 46): - according to which the terminal receives from the first network, via the first operating interface, information (II to 14) describing the coverage of the second network broadcast within signaling data, by a device ( NODE-B) associated with the first current cell on which the terminal is connected and, - that, if said information (II, 12) indicates a presence of the second network coverage and a second network type, then the terminal receives the following additional description information of the coverage of the second network: frequency information (13) and channel bandwidth information (14) .

2. Method according to claim 1, wherein the information (II, 12) for describing the coverage of the second network indicates a presence or absence of the coverage of the second network.

3. Method according to any one of claims 1 to 2, characterized in that it comprises a step (41) of transmission by the terminal (T) to the first network, a request, and in that in said receiving step (46), said information describing the coverage of the second network received by the terminal is a response to said request, from the first network and function of a location information of said terminal.

4. Method according to claim 3, characterized in that said request is accompanied by a first location information of said terminal, and in that said response is a function of said first location information of said terminal.

5. Method according to claim 4, characterized in that said first location information of said terminal belongs to the group comprising: an identifier of the first current cell on which the terminal is connected; and location information provided by a geographical location means internal or external to the terminal.

6. Method according to any one of claims 4 and 5, characterized in that it comprises a step (42) of determination by the first network of a second location information of said terminal (T), and in that said response is a function of said second location information of said terminal.

7. Method according to any one of claims 1 to 6, characterized in that said first and second networks belong respectively to the group comprising two-way radio communication networks and to the group comprising unidirectional broadcast networks.

8. Computer program product downloadable from a communication network and / or recorded on a computer readable medium and / or executable by a processor, characterized in that it comprises program code instructions for the implementation of the method according to at least one of claims 1 to 7, when said program is run on a computer.

9. Signal transmitted from a first cellular radio network to a multimode terminal (T) comprising first and second operating interfaces enabling said terminal to connect respectively to said first network and to a second broadcasting network, said signal being characterized in that it comprises a field containing information (II, 12, 13, 14) describing the coverage of the second network, so as to allow the discovery of the coverage of the second broadcast network by the terminal.

10. Signal according to claim 9, characterized in that it comprises a first field containing a first information (II, 12) describing the coverage of the second network, indicating a presence or absence of the coverage of the second network.

11. Signal according to claim 10, characterized in that it comprises a second field containing the following additional information of description of the coverage of the second network: a frequency information (13) and a bandwidth information of the channel (14). ), if said first information (II, 12) indicates a presence of the coverage of the second network.

Multimode terminal (T) comprising first and second operating interfaces enabling said terminal to connect respectively to a first cellular radiocommunication network and a second broadcasting network, characterized in that it comprises means for discovering the coverage. second network comprising: means for receiving, via the first operating interface, at least one description information of the coverage of the second network; and means for analyzing said at least one item of information in order to access the second network.