FR3006529A1 - MANAGING A CELLULAR RADIO ACCESS POINT - Google Patents

Abstract

The invention relates to a method for controlling (PIF) a radio access point (PAF, 2) of a radio cell (femtocell picocell) of a radio telecommunications network (9). The access point is capable of accepting the connection of mobile radio terminals (3,5). The method is characterized in that it comprises the following steps: a step of receiving (E11, E12, E'11, E'12) a datum (REQ) relative to the operating state (NB_CX, TYP_CX ) the access point (PAF); A comparison step (E13, E'13) of the data item (REQ) relating to the operating state of the access point to a predetermined value (BP_MAX, NB_MAX, NB_MIN); • Depending on the results of the comparison, a step of sending a command (OK, NOK, DISC) to the access point (PAF, 2), for the modification of its operating state.

Description

Management of a cellular radio access point. The field of the invention is that of telecommunications and more precisely that of radio telecommunications networks.

More particularly, the invention relates to the configuration of a base station, or access point, of a cellular mobile radio telecommunication network, in particular in the context of small mobile cells. A second, third or fourth generation cellular mobile radio network uses radio technologies to enable a subscriber's mobile equipment to establish communication with other mobile equipment connected to the network. The radio link between the equipment and a mobile network must be of sufficient quality, which requires the establishment in the network of a set of intermediate stations, called base stations, or BTS (of the English Base Transceiver Station ), which allow a user of the network to connect at any time, throughout the territory concerned. A cell is thus the surface on which the mobile terminal can establish a link with a given base station. Recently, small-sized cells generated by a femto access point have appeared in this context, as opposed to the large cells generated by the BTS base stations, also called femto cells (prefixes emphasizing the very small size) or pico cells (in English: femtocell or picocell). A femto access point is therefore a basic element of a low-power mobile cellular system, intended to offer limited radio coverage in a small-sized femto cell, often dedicated to residential, or domestic, use. , or company. The base station, also called the access point, of the femto cell generally connects to a mobile operator's network over a broadband Internet connection (eg a router, a home gateway, etc.) and can, depending on the model, support two to eight simultaneous communications or Internet access for voice and / or data. Although they can simply and effectively extend the coverage of a mobile network to provide good quality communications in areas -2 poorly covered, such cells have, for a user, two types of disadvantages: Firstly, femto cells generate electromagnetic radiation linked to the presence of the radio transmitter, adding to that of any existing devices and networks in a home (GSM, Wifi, DECT, CPL, etc.). more, risks of interference with these digital communication devices already existing in the perimeter of the cell. However, the inventors have found that, unlike BTS stations which must operate constantly to provide coverage of the network of the operator, a femto cell is not necessarily required permanently.

There is therefore a need for automatic management of a home radio base station, overcoming the aforementioned drawbacks. For this purpose, according to a functional aspect, the subject of the invention is a method for controlling a radio access point of a radio cell of a radio telecommunication network, the access point being able to accept the connection of mobile radio terminals, said method being characterized in that it comprises the following steps: receiving a datum relating to the operating state of the access point; comparing the data relating to the operating state of the access point with a predetermined value; - according to the results of the comparison, sending a command to the access point, for the modification of its operating state.

The invention makes it possible to control a radio access point, by exchanging messages between a manager implementing the method and the access point, in order to know the state of the access point and to transmit to it appropriate orders. The invention offers the advantage of automatically communicating the operating status of the femto access point to the device to which it is connected, typically a home gateway: access point occupation, consumption, etc. The master equipment (gateway) can then make decisions regarding the access point and provide it with appropriate commands.

According to a particular embodiment of the invention, a method as described above is further characterized in that the command towards the access point is a command relating to a state of operation of the access point. . By operating status is meant the on or off status of the access point.

When turned off, it no longer generates a femto cell and consumes no more electricity. This embodiment of the invention therefore makes it possible to manage the power consumption of the access point. In particular, if no terminal is connected to the femto access point, this information can be transmitted to the control method according to the invention and the subsequent sending of an appropriate command allows to command the access point of s 'switch off. Indeed, if the access point is inactive, the femto cell is not useful; it may be interesting to disable it, temporarily, waiting for a new solicitation. Advantageously, such a deactivation also makes it possible to avoid electromagnetic radiation which can be harmful for the human body. Following this deactivation command, an activation command may be issued by the pilot according to the invention in order to restart the apparatus. According to a second particular embodiment of the invention, which may be implemented alternatively or cumulatively with the previous one, a method as described above is further characterized in that the command to the access point is a command relating to a state of standby of the access point. With this embodiment, the breakpoint can be put on standby if no terminal is connected to it, or go into a deeper sleep mode, or instead switch from a deep sleep mode to a sleep mode. watch more superficial. This embodiment of the invention allows fine management of the power consumption of the access point. According to a third particular embodiment of the invention, which may be implemented alternatively or cumulatively with the above, a method as described above is further characterized in that the command to the access point is a command to connect a new terminal to the access point. -4 It is thus possible to decide which terminals can connect to the access point. For example, thanks to the invention, it is possible to assign to a first terminal a higher priority than that of a second terminal, in order to privilege the connection of the first terminal, possibly to the detriment of the second terminal. It is also possible to control the automatic connection of a new terminal that has not issued a prior request to the access point, but which is known to the control module. According to a fourth particular mode of implementation of the invention, which can be implemented alternatively or cumulatively with the previous ones, the data relating to the operating state of the access point is a data relating to a bandwidth and the step of comparing a step of comparing said data with a maximum bandwidth. There is usually a maximum bandwidth for a femto cell. It is therefore sufficient for the method according to the invention to account for the bandwidth used by the various terminals connected to the access point in order to be able to determine what is the remaining bandwidth available at a given moment and to deduce from this fact, effectively and without ambiguity. , if a new connection request can be accepted, and if so under what conditions: a voice and data connection request can be accepted for the voice part and refused for the data, or accepted, or rejected , for both types of communication. It is therefore advantageously possible to finely manage the communications in the femto cell.

According to a fifth particular mode of implementation of the invention, which may be implemented alternatively or cumulatively with the previous ones, the datum relating to the state of the access point is a datum relating to the number of connected terminals and the comparison step a comparison step of said data to a maximum number of connectable devices.

In this way also, the saturation of the access point can be easily detected: instead of the maximum bandwidth, it is often the maximum number of connections that is given for a femto cell (of the order of 2 to 8 ). It is therefore sufficient for the method of the invention to count the number of terminals connected to the access point to be able to determine how many connections remain possible and decide whether a new connection request can be accepted. According to a sixth particular mode of implementation of the invention, which can be implemented alternatively or cumulatively with the previous ones, the datum relating to the state of the access point is a datum relative to the number of connected terminals and the comparison step a comparison step of said data to a minimum number of connectable devices. This embodiment allows the control method of the access point to take an initiative such as its disconnection, or its standby, if no connection is active on the access point at a given time. This advantageously allows to manage, as explained above, the power consumption of the access point.

According to a seventh particular mode of implementation of the invention, which may be implemented alternatively or cumulatively with the previous ones, the datum relating to the state of the access point is a datum relating to the type of connection of a terminal. This embodiment allows the access point control method to accept or reject an incoming connection, depending on its type: a communication using voice and data, for example, consumes more resources than the voice alone and can therefore be judged to be less priority by the control method.

Advantageously, the access point and its control module can be made compatible with the UPnP standard in order to communicate via a standardized mechanism. The UPnP (Universal Plug and Play) standard is intended to allow peripheral terminals to easily connect and communicate simply within a home network. It is a set of communication protocols based on the Internet Protocol (IP) and promulgated by the UPnP Forum ("UPnP Forum").

According to a hardware aspect, the invention also relates to a device for controlling a radio access point of a radio cell of a radio telecommunication network, the access point being able to accept the connection of radio terminals. mobile, said device being characterized in that it comprises the following modules: a module for receiving data relating to the operating state of the access point; a module for comparing the data relating to the operating state of the access point to a predetermined value; a module for sending a command to the access point, according to the results of the comparison, for the modification of its operating state. According to another material aspect, the invention also relates to a home gateway comprising a control device as claimed above. According to another functional aspect, the subject of the invention is a method for managing the state of a radio access point of a radio cell of a radio telecommunication network, said access point being capable of accepting the connection of mobile radio terminals, said method being characterized in that it comprises the following steps: obtaining data relating to the operating state of the access point; transmission of the data relating to the operating state of the access point; receiving a command to change the operating state of the access point; change in the operating state of the access point.

Thus, the invention offers the advantage of giving an intelligence to the access point which was previously devoid of it. Today, according to the state of the art, the femto access point handles only its incoming and outgoing connections and it alone makes the decisions to accept or reject a request from a terminal. He never disconnects. He is often limited in abilities and knowledge of his environment. The invention makes it possible to remedy this situation by transmitting to the access point appropriate commands for taking into account or refusing a connection, putting on standby, deactivating, activating the access point, and so on. According to yet another material aspect, the invention relates to a device for managing the state of a radio access point of a radio cell of a radio telecommunications network, the access point being able to accept the connection of mobile radio terminals, the device being characterized in that it comprises the following modules: a module for establishing data relating to the operating state of the access point; a module for transmitting the data relating to the operating state of the access point; a module for receiving a command for modifying the operating state of the access point; a module for modifying the operating state of the access point. According to another hardware aspect, the invention also relates to a radio-mobile access point comprising a device for managing the status of a radio access point as claimed above. According to yet another material aspect, the invention relates to a computer program for a home gateway comprising the software instructions for controlling the implementation by said gateway of the steps of the control method described above when the program is executed by the bridge. According to yet another material aspect, the invention relates to a computer program for a radio access point comprising the software instructions for controlling the implementation by said radio access point of the steps of the management method described above. when the program is executed by the access point. Other features and advantages of the present invention will become more apparent upon reading the following description, given by way of example and with reference to the accompanying drawings, in which: FIG. 1 shows a radio configuration with a femto type domestic cell, - Figure 2 is a schematic view of a device for automatic management of a femto access point according to the invention, - Figure 3 shows the steps of the method according to a particular embodiment. of the invention, - Figure 4 shows another example of the process steps according to another particular embodiment of the invention.

FIG. 1 represents an example of a typical network architecture of a mobile operator deploying home stations or access points (femtocell or picocel), in this example a home (H1) in which a local area network is deployed. is connected directly to the Internet (10) via a home gateway (1) and indirectly to the equipment (8) of a telecommunications operator who is themselves connected to the Internet. is not perfectly covered by the operator's standard radio-mobile network (9), and therefore requires additional coverage via one or more femto-type home-cells, the femto access point (2), hereinafter referred to as PAF (for Femtocell Access Points), is an access point, or home radio base station, connected to the home gateway (1) for example via an Ethernet link (6), and capable of providing voice and accessory services at the terminals (3,4,5) of the house. The access point is connected via the gateway to the mobile network management equipment (8) of the operator, among which is in particular a femto cell management server. In a known manner, the PAF access points have a limited power and thus offer a limited bandwidth, or maximum bandwidth (BP_MAX) acceptable by the access point. The limitation is often expressed by the operator in terms of the number of connectable terminals (CX_MAX) simultaneously, so that multiple users can establish communication in the cell. The PAF (2) of the house (H1) is for example capable of supporting the equipment 3 and 5 (respectively a mobile telephone and a smattphone) to provide them with voice and data communications services. On the contrary, the PC (4) of house H1, represented by way of example, is connected directly to the gateway (1) to establish its data communications (it could also be connected to it by Wifi, or Bluetooth, etc. .) The mobile network (9) of the operator is for example a third generation network called "3G" or "3G +", based on a set of UMTS standards (for "Universal Mobile Telecommunications System" in English) or HSPA ( "High Speed Packet Access"); Naturally, the invention is not limited to this type of network and also applies to so-called second generation (2G), fourth generation (4G) mobile networks, or any other type of radiocommunication network. No limitation is attached either to the type of terminal used. The mobile terminal (5) can be for example a telephone, a tablet, or any other terminal, fixed or mobile, capable of establishing a radio communication with the mobile network. This type of architecture, while effectively extending the coverage of the mobile network (9) of the operator, has a number of disadvantages: the number of simultaneous connections is limited, if additional equipment is trying to connect at the access point (PAF) when it has reached the maximum acceptable, it fails. Moreover, the user does not necessarily want the access point (PAF) to be switched on all the time, in particular for health reasons: the access point emits radiation which, if it remains limited compared to that generated by some other equipment of the house (Wifi, bluetooth, etc.), is none the less present. It would be better to be able to turn it off when not in use. The invention therefore proposes an access point management mechanism (PAF) by a control module (PIF for "Femto cell control") capable of establishing bidirectional communication with the PAF (s) for which it is responsible. Such a module can be located in the network (for example on an operator's server, or in the private network, also called "cloud", of the user of the home network), or in the home gateway, or in any terminal of the local network. In this embodiment, the home gateway (1) according to the invention supports the control module. This module is particularly capable of knowing the state of the PAF (s) connected to it (PAF activated or not activated, number of terminals connected, etc.), to calculate the remaining bandwidth available at a given instant , and to transmit orders to the PAF. Such a module can rely for example on the protocols of the UPnP standard if the gateway and the access point (PAF) are connected to Ethernet. To control the network equipment, the UPnP standard uses control points (in English: "Control Points" or CP). A control point conventionally transmits to the various terminals of the network so-called discovery messages in order to retrieve a description of the terminals corresponding to the request. A UPnP compliant terminal responds to these request messages, and additionally transmits presence messages at regular intervals to indicate that it is active and connected on the UPnP network.

In addition, the UPnP standard uses the Simple Object Access Protocol (SOAP) mechanism to allow a checkpoint to invoke actions on the terminal. The UPnP standard also defines a GENA (General Event Notification Architecture) mechanism that allows the control point to subscribe to receive notifications from the terminal.

Thus, according to this embodiment of the invention, a control point located on the home gateway communicates with the access point (PAF) through such messages, the access point (PAF) being compatible with the UPnP standard. In particular, the PAF could be controlled through a new UPnP service ("BaseTransceiver" service). Another possibility, within the abilities of those skilled in the art, would be to reuse the "Configuration Management" service which is defined in the "Device Management" UPnP profile. According to another embodiment, the control point may be located elsewhere in the local network. Alternatively, a proprietary communication protocol may be used for communication between the PIF management module and the PAF access point itself, whether the two supporting devices are connected in Ethernet or USB.

Thus, according to the diagram of FIG. 1, when the gateway (1) to which the access point (2) is connected receives a connection request from a radio terminal (3.5) of the home H1, the module The femto cell driver (PIF), installed in this example on the home gateway (1), calculates the bandwidth required to establish the connection with this terminal, then the remaining bandwidth availability; if the requested bandwidth is not available, the gateway may instruct the access point to refuse the connection. Moreover, when the control module (PIF) realizes that there is not, or that there is more mobile connected, it can take the initiative to turn off the access point PAF waiting for a new connection request from a terminal, in order to save energy. It can alternatively put it on standby, for example via a message of the UPnP standard called "Low Power" (reference UPnP Low Power Architecture for LJPnPTM Version 1.0, August 28, 2007, Version. '1.00. a home network consumes power, so it is customary to turn it off or put it to sleep when it is not necessary to use it A sleep mode is a mode in which some features are disabled the terminal, which allows to reduce its energy consumption while allowing a faster wake up.There are sometimes several levels of standby for the same equipment, as for example defined in UpnP "Low Power." Figure 2 represents a view schematic of a home gateway comprising a control module (PIF) of one or more access points (PAF) according to the invention, such as for example the gateway (1) of FIG. 1, connected to a point of access (PAF, 2) via Ethern link and (6) The gateway (1) conventionally comprises memories (M) associated with a processor (CPU). The memories can be ROM (Read Only Memory) or RAM (Random Access MemoM or Flash) The gateway (1) communicates with the local network and the Internet via the ADSL module. device further comprises a PIF control module (Femtocell control) of the femto access point (s), capable of connecting to the PAF access point (2) of FIG. 1 to manage the cell Femto radio, via a bidirectional communication of messages between the PIF module and the PAF access point, in particular to: - Acquire the state of the PAF: standby state (off / on / standby mode), number of connections (NB_CX ) in progress, new request in progress, etc. - Perform calculations based on information from the PAF: calculation of remaining bandwidth, number of remaining connections, etc. - Pause / wake up PAF - Enable (switch on / off / switch off a PAF) - Increase or decrease the number of c PAF Annexes; - etc. In this embodiment, the communication is managed via an Ethernet (ETH) connection. As mentioned above, this communication can be done on the basis of the UPnP protocol if the PAF is compatible with this standard and able to communicate with a control point located for example on the gateway. The control module (PIF) can be for example a software program running in the memory of the gateway, or a hardware and software package capable of controlling the PAF. The PIF module may, alternatively, be on another device of the local network, or on an external server. The access point (PAF), for its part, conventionally comprises memories (M ') associated with a processor (CPU'). The memories can be type ROM (English Read Only Memory) or RAM (English Random Access Memory) or Flash. It communicates with the gateway via an Ethernet link (ETH ') and with mobile radio terminals via an antenna and its pilot (ANT). With reference to FIG. 3, the access point control method (PIF) (PAF) is located on the home gateway (1) and links steps E11 to E13. A connection request (CX) is sent from the mobile terminal (5) to the access point (PAF) which receives it during a step El and retransmits it to the management module of the gateway. Thus, during a step Eh, the management method (PIF) of the access point (PAF, 2) receives a message from the PAF informing it that a new terminal wishes to connect. The message may take the form of the following GENA notification (it is recalled that GENA is a UPnP notification mechanism): NOTIFY delivery path HTTP / 1.1 HOST: delivery host: delivery CONTENT-TYPE port: text / xml CONTENT-LENGTH: Bytes in body NT: upnp: event NTS: upnp: propchange SID: uuid: subscription-UUID SEQ: event key <? Xml version = "1.0"?> <E: propertyset xmlns: e = "urn: schemas-upnp-org : event-1-0 "> <e: property> <PendingConnectionNumber> l </ PendingConnectionNumber> <PendingConnectionType> VoiceOnly </ PendingConnectionType> <PendingConnectionProtocol> 3G </ PendingConnectionProtocol> </ e: property> </ e: propertyset> 25 This message includes (gray fields of the message above): - the connection number (PendingConnectionNumbei tag), - the type of connection requested: data, voice and data, etc. (Here, a VoiceOnly attribute of the PendingConnectionType tag indicates a voice type message, without associated data), 30 - the type of mobile protocol (3G attribute of the PendingConnectionProtocol tag indicating here a third generation mobile network). This mechanism makes it possible, for example, to know that the terminal will use a network video or game service and thus consume a large bandwidth. According to another possible embodiment (not shown in FIG. 3), the management module PIF interrogates the access point PAF to ask it for the type of connection required and any other complementary information that could be useful to it. This message may take the form of the following UPnP SOAP action (it is recalled that the SOAP mechanism allows UPnP checkpoint to invoke actions on the terminal): POST path of control URL HTTP / 1.1 HOST : host of control URL: port of control CONTENT-LENGTH URL: bytes in body CONTENT-TYPE: text / xml; charset = "utf-8" SOAPACTION: "urn: schemas-upnp-org: service: BaseTransceiver: 1 # GetConnectionRequestStatus" <? xml version = "1.0"?> <s: Envelope xmlns: s = "http: // schemas .xmlsoap.org / soap / envelope / "s: encodingStyle =" http://schemas.xmlsoap.org/soap/encoding/ "> <s: Body> <u: GetConnectionRequestStatus xmlns: u =" urn: schemas-upnp - org: service: BaseTransceiver: 1 "> <ConnectionRequestIndex> 1 </ConnectionRequestIndex> </ u: GetConnectionRequestStatus> </ s: Body> </ s: Envelope> This message includes a status request (GetConnectionRequestStatus) that allows you to whether the polled UPnP terminal, in this case the PAF access point, is active or not.

During a step E12, the management module (PIF) of the gateway calculates the bandwidth required for the connection of this terminal. For example, a static table in the memory M of the gateway 1 (or any other suitable medium) can be used to determine the required bandwidth according to the type of connection requested (2G, 3G, voice or data, etc.). It can also easily calculate the remaining available bandwidth by a simple difference between the maximum bandwidth (BP_MA) () allowed for the femto cell (given by the operator) and the actual bandwidth used by the femto cell at a given time: for example, the PIF module has memorized the type of connection and the corresponding bandwidth for each connection previously established with the PAF.

During a step E13, the PIF management module interprets the results of the previous step: if the requested bandwidth is available, condition that is assumed to be fulfilled in this example, it means to the PAF the acceptance of the connection (message 01 <); in a step E2, the PAF accepts the connection and means to the terminal which can then connect normally and communicate on the mobile network from femto cell (radio communication symbolized by a flash). The table of the gateway 1 is then updated in order to be able to count down the bandwidth consumed. With reference to FIG. 4, the management method of the access point (PAF) is also located on the home gateway (1) and links the steps E'11 to E'13 similar to the steps E11 to E13 under conditions of different operation. It can be imagined that the steps of the method of FIG. 4 take place following those which have been carried out in support of FIG. 3. It is assumed in particular that the bandwidth (respectively the number of simultaneous connections) on the point of FIG. PAF access approaches the maximum possible and the PAF can no longer accept a new data connection. During a step E'11, the PAF (2) management method (PIF) receives a message from the PAF informing it that a new terminal wishes to connect. This time it is the terminal 3.

The request message sent by the PAF to the PIF management module may take the form of the following GENA event (UPnP): NOTIFY delivery path HTTP / 1.1 HOST: delivery host: delivery port CONTENT-TYPE: text / xml CONTENT-LENGTH : Bytes in body NT: upnp: event NTS: upnp: propchange SID: uuid: subscription-UUID SEQ: event key <? Xml version = "1.0"?> <E: propertyset xmlns: e = "urn: schemas-upnp- org: event-1-0 "> <e: property> <PendingConnectionNumber> 2 </ PendingConnectionNumber> <PendingConnectionType> VoiceAndData </ PendingConnectionType> <PendingConnectionProtocol> 3G </ PendingConnectionProtocol> </ e: property> </ e: propertyset> This message includes in particular the number of the connection (2), the type of the requested connection (VoiceAndData attribute indicating a voice and data type), and the mobile protocol (3G attribute indicating here a third generation mobile network). During a step E'12, the management module (PIF) calculates the bandwidth required for the connection of this terminal and the remaining bandwidth.

During a step E'13, the management module PIF interprets the results of the previous step: this time, the requested bandwidth is not available - 16 - for a connection of the "voice and data" type; a message is sent at the end of step E'13 to the PAF access point (NOK) to indicate that it does not accept the incoming connection.

According to a variant that is not shown, the PIF module for controlling the PAFs of the gateway can instruct an access point PAF to switch off (or go to sleep) if it realizes that no terminal mobile is connected to it. This standby or shutdown will be followed by an alarm clock as soon as one of the cell's mobile terminals requests a femto connection: the operator's femto (8) optimization server, which can be notified of this request via the network (9) mobile or via any other means within the reach of the skilled person. The gateway can, for example, detect the presence of the terminal in the cell via its WiFi module (or alternatively Bluetooth, Zigbee, etc.) and therefore give the order to wake up the radio access point.

It is also possible, according to another variant, to take into account certain priorities associated with the terminals: for example, a higher priority may be given to the terminals according to their subscription (type of subscription, operator, etc.). A priority terminal may be granted a connection on an access point while a non-priority terminal would not be accepted. It goes without saying that the embodiment which has been described above has been given for purely indicative and not limiting, and that many modifications can be easily made by those skilled in the art without departing from the scope of the invention.

Claims (15)

REVENDICATIONS1. Control method (PIF) of a radio access point (PAF, 2) a radio cell (femtocell, picocell) of a radio telecommunication network (9), the access point being able to accept the connection of mobile radio terminals (3.5), said method being characterized in that it comprises the following steps: reception (E11, E12, E'11, E'12) of a datum (REQ) relative to the operating state (NB_CX, TYP_CX) of the access point ( PAF); - Comparison (E13, E'13) of the data (REQ) relative to the operating state of the access point to a predetermined value (BP_MAX, NB_MAX, NB_MIN); - Based on the results of the comparison, sending a command (OK, NOK, DISC) to the access point (PAF, 2), for the modification of its operating state. 2. Control method (PIF) of a radio access point (PAF, 2) according to claim 1, characterized in that the command towards the access point is a command relating to a state of operation of the point d access (2). 3. Control method (PIF) of a radio access point (PAF, 2) according to claim 1, characterized in that the command towards the access point is a command relating to a state of standby of the point of access. 'access. 4. Control method (PIF) of a radio access point (PAF, 2) according to claim 1, characterized in that the command to the access point is a command relating to the connection of a new terminal at the access point (3,5). 5. Control method (PIF) of a radio access point (PAF, 2) according to claim 1, characterized in that the data relating to the operating state of the access point is a data item relating to a bandwidth (TYP_CX, BP) and the step of comparing a step of comparing said data with a maximum bandwidth (BP_MAX). 6. Control method (PIF) of a radio access point (PAF, 2) according to claim 1, characterized in that the datum (REQ) relating to the state of the access point is a datum relative to the number of terminals connected and the step of comparing a step of comparing said data to a maximum number of connectable devices (CX_MAX). 7. A method of piloting (PIF) a radio access point (PAF, 2) according to claim 1, characterized in that the data (REQ) relating to the state of the access point is a data relating to the number of connected terminals and the step of comparing a step of comparing said data to a minimum number of connectable devices (CX_MIN, 0). 8. A method of piloting (PIF) a radio access point (PAF) according to claim 1, characterized in that the data (REQ) relating to the state of the access point is a data relating to the type of connection of a terminal. 9. Device for controlling a radio access point (PAF, 2) of a radio cell (femtocell, picocel) of a radio telecommunication network (9), said access point being able to accept the connection of radio-mobile terminals (3,5), said device being characterized in that it comprises the following modules: a receiving module (E11, E12, E'11, E'12) of a data item (REQ ) relating to the operating state (NB CX, TYP CX) of the access point (PAF); - A comparison module (E13, E'13) of the data (REQ) relating to the operating state of the access point to a predetermined value (BP_MAX, CX_MAX, CX_MIN); - A module for sending a command (OK, NOK, DISC) to the access point (PAF, 2), according to the results of the comparison, for the modification of its operating state. Domestic gateway (1) comprising a control device according to claim 9. 11. A method for managing the state of a radio access point (PAF, 2) of a radio cell (femtocell, picocel) of a radio telecommunication network (9), said access point being capable of accepting the connection of mobile radio terminals (3,5), said method being characterized in that it comprises the following steps: obtaining a data item (REQ) relating to the operating state of the access point (PAF); data transmission (REQ) relating to the operating state of the access point (PAF); - 19 - receiving a command (OK, NOK, DISC) to modify the operating state of the access point (PAF); change of the operating state of the access point (PAF). 12. Device for managing the state of a radio access point (PAF, 2) of a radio cell (femtocell, picocel) of a radio telecommunication network (9), the access point being capable of accepting the connection of mobile radio terminals (3,5), the device being characterized in that it comprises the following modules: a module for the establishment of a data item (REQ) relating to the operating state (TYP_CX, NB_CX) of the access point (PAF); a data transmission module (REQ) relating to the operating state of the access point (PAF); a module for receiving a command (OK, DISC) to modify the operating state of the access point (PAF); a module for modifying the operating state of the access point (PAF). A mobile radio access point (2) comprising a radio access point status management device according to claim 12. 14. Computer program for a home gateway comprising the software instructions for controlling the implementation by said gateway of the steps of the control method according to any one of claims 1 to 8 when the program is executed by the gateway. A computer program for a radio access point comprising the software instructions for controlling the implementation by said radio access point of the steps of the method of claim 11 when the program is executed by the access point.