FR2974961A1 - Method for activating multi-band communication entity e.g. access point, in wireless fidelity network, involves receiving request to activate radio module of entity associated with transmission band, and triggering activation of module - Google Patents

Abstract

The method (1) involves receiving, in a signaling band, a request for activation of a radio module of a multi-band communication entity (EC-T) associated with a transmission band (4), and triggering the activation of the radio module by the activation request. A frame including description of the activation request of the radio module is sent (6), where the activation request includes information on the availability of pending data, and the pending data is transmitted (9). The radio module is deactivated after transmission of the data. Independent claims are also included for the following: (1) a method for transmission of a data frame (2) a multi-band communication entity for receiving an activation request (3) a multi-band communication entity for sending an activation request (4) a signal representing an activation request sent by a multi-band communication entity (5) a computer program comprising instructions for activating a multi-band communication entity (6) a computer program comprising instructions for transmission of a data frame (7) a data carrier comprising instructions for activating a multi-band communication entity.

Description

Method for waking up a multi-band communication entity, corresponding device and computer program

Field of the Invention The present invention relates to the field of telecommunications. Within this field, the invention relates more particularly to the field of radio communications, also called wireless, which includes WiFi networks (Wireless Fidelity according to the English terminology) whose standardization is the subject of 802.11 standards. and following of the IEEE. These standards ensure interoperability between wireless communication equipment that conforms to these standards. The invention is described in a context of WiFi network infrastructure in which a terminal establishes a communication by means of an access point, Access Point according to the English terminology. However, the invention is used just as well in an ad hoc network. Terminals that establish communications with an access point are often nomadic or mobile which requires them to operate regularly on battery. Autonomy is therefore vital and consequently energy consumption is an important problem for these communication entities. This problem of energy consumption is however not limited to the terminals because the access points are also energy consumers. In particular, even if an access point is not associated with any terminal, it must nevertheless regularly broadcast frames (beacon according to the English terminology) to be detectable by a possible terminal positioned in the radio coverage of the access point . Since the radio module contributes significantly to the access point's consumption, this recurrent broadcasting has a significant impact on this consumption. It therefore seems important to provide mechanisms to save this energy at terminals and access points. PRIOR ART Various modes of energy saving, known as "power save", have been defined, in particular by the 802.11 standards. A first mode called "Beacon listen interval" consists in sending a signaling frame from a station to the access point to indicate that it goes into standby mode for a duration equal to N intervals between two " Beacon ". According to this mode, the watch can be almost total with a power failure of some analog modules.

By nature, this mode is particularly suitable for transmissions at regular intervals. Therefore, the arrival of desynchronized packets causes packets to be stored with a risk of memory congestion and therefore the introduction of an increase in the transmission delay and the risk of introduction of jitter. In addition, the station can wake up and remain inactive until its next standby, its consumption between phases of standby is in this case wasted. Furthermore, when the cell defined by the BSS (Basic Service Set in English terminology), has a significant load to flow related to a traffic involving the station, it can be difficult to effectively synchronize the phases of awakening of the station with transmission periods.

The risk is therefore to reduce or even wipe out the efficiency of the standby mode by lengthening the waking hours of the station. Finally, this mode does not allow emergency alarm. A second mode called "magic packet" causes a partial standby because the station must be able to detect the "packet magic" issued by another entity, typically an access point, which consists of a repetition of its MAC address. The station must therefore maintain reception and detection capabilities during its standby mode. More generally, the existing energy saving mechanisms define energy saving modes for the mobile receiving entities by alternating standby (in which energy is saved) and activity phases. The various existing protocols and techniques define the exchanges between entities and access point to manage these different phases without packet loss: they provide for buffering of the packets during the standby phase and transmission or reception of the packets during the activity phase. DESCRIPTION OF THE INVENTION The invention has advantages over the methods of the prior art.

The subject of the invention is a method for waking up a multi-band communication entity adapted to a multi-band wireless access network, a first band being intended for data transmission, a second band different from the first band being intended for at the signaling. According to the invention, such a method comprises - a step of reception in the signaling band of a wake-up request of at least one radio module of the entity associated with the transmission band, - an alarm clock of the radio module triggered by The method according to the invention is particularly noteworthy in that it allows energy savings for both mobile and fixed stations as well as for access points, which is generally not possible by the methods of the invention. known which are more particularly adapted to the terminals. The method applies to at least dual communication entities, one of the bands is more particularly used for signaling and another of the bands is more particularly used for the transmission of data. The signaling band is typically advantageously selected with greater radio coverage and less power than the band for data transmission. The band for the data transmission is advantageously chosen with a higher rate than the band for the signaling. For example, the communication network is a WiFi network with a transmission band that corresponds to a 5GHz band in reference to a network compliant with the IEEE802.1ln standard and with a signal band that corresponds to a band 868-868.6MHz with reference to a network compliant with the IEEE802.11ah standard. According to one embodiment of the invention, the method further comprises: a step of sending an alarm signaling frame comprising a signaling of the alarm of the radio module associated with the transmission band and a transmission step; pending data. This mode provides the equivalent of an acknowledgment following the wake request of the dormant entity which allows the entity that issued the wake up request to be informed of the change of state of the destination entity. The transmitted data are data waiting for transmission that have been previously stored. This mode makes it possible to quickly and quickly unblock the packets waiting for the receiving entity of the wake up request, packets stored by the entity issuing the wake up request. According to another embodiment, the data is waiting in the receiving entity of the wake up request. After its change of state, the entity transmits its data pending. According to one embodiment of the invention, the method further comprises a step of putting the radio module associated with the transmission band to sleep, after transmission. pending data. This mode makes it possible to limit the wakeup state to the period of transmission of the waiting data and consequently to avoid unnecessary consumption of the radio module. According to one embodiment of the invention, the wakeup request includes a piece of information. on the availability of pending data. This mode enables the destination entity to be informed, before the wakeup of its transmission module linked to the transmission band, that it must prepare to receive data. According to one embodiment of the invention, the method further comprises a step of standby of the radio module associated with the signaling band.

The standby differs from the dormant in that the entity retains the ability to receive at least some signaling frames in the signaling band. This ability can be periodic with alternating standby and wake up. Given that the power consumption of the entities is strongly dimensioned by the consumption of the radio modules, this mode makes it possible to increase the reduction of the consumption. According to one embodiment of the invention, the method comprises a start-up of a power supply of at least the radio module associated with the transmission band of the entity to be woken up. Thus, any consumption of the radio module associated with the transmission band is suppressed until the awakening of the entity. The invention further relates to a method of transmitting a data frame by a multi-band communication entity adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band band different from the first being intended for signaling, comprising: - a step of constructing a wakeup request of at least one radio module associated with a transmission band of a destination multiband entity, - a step of transmission of the frame including the wake up request in the signaling band. The invention furthermore relates to a multi-band communication entity adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first band being intended for signaling, comprising means for receiving in the signaling band a wake-up request from at least one radio module of the entity associated with the transmission band, means for putting at least one associated radio module at sleep to the transmission band of the entity. A multi-band communication entity implementing the invention can wake up on receipt of a request received in the signaling band. Thus, the sleep of the radio module associated with the transmission band can be total.

The invention furthermore relates to a multi-band communication entity adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first band being intended for signaling, comprising transmission means in the signaling band of a wake-up request of at least one radio module associated with the transmission band of a destination entity; means for storing data intended to be transmitted in the transmission band to the destination entity, waiting for the receiving entity to wake up. The invention furthermore relates to a signal representative of a wake-up request sent by a multi-band communication entity adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first being intended for signaling, such that its frequency spectrum is included in the signaling band and such as the request to wake up at least one radio module associated with the transmission band of a communication entity, it represents, contains the identification of the transmission band of the communication entity receiving the request. The invention furthermore relates to a computer program on an information carrier, said program comprising program instructions adapted to the implementation of an awakening method according to the invention when this program is executed by a user. processor. The invention further relates to a computer program on an information carrier, said program comprising program instructions adapted to the implementation of a transmission method according to the invention when this program is executed by a processor. The subject of the invention is furthermore an information carrier comprising program instructions adapted to the implementation of a wake-up method according to the invention, implemented by a multi-band communication entity adapted to a communication network. multi-band wireless communication when said program is loaded and executed in the entity for implementing the wakeup method. The implementation of the invention is compatible with the use of existing single-band equipment: in fact, it does not affect single-band access points or single-band terminals (compatible with a single-band standard) because they are by nature ignorant of the signaling band since data and signaling are exchanged on one and the same band, the transmission band. List of Figures Other features and advantages of the invention will appear more clearly on reading the following description of a particular embodiment, given by way of a simple illustrative and nonlimiting example, and the following appended drawings.

Figure 1 is a diagram illustrating the steps of the wake up method according to a particular embodiment of the invention. FIG. 2 is a diagram of an entity adapted to the implementation of the wake-up method according to the invention.

FIG. 3 is a diagram of an entity adapted to the implementation of the transmission method according to the invention. DESCRIPTION OF AN EMBODIMENT OF THE INVENTION The invention relates to a method of waking up (or "activation" according to the English terminology) of at least the radio module associated with the transmission band of a multi-communication entity. bands adapted to a wireless communication network. Such a network is said to infrastructure when it allows access via an access point to a telecommunication network that allows the deployment of services, the best known of which is access to web pages. More commonly, the telecommunication network is called the Internet. A network is said ad hoc when the communication takes place in the absence of an access point, the communication is said in point-to-point. The communication network may comprise several entities, for example access points or communication terminals. In wireless communication systems of the prior art, the methods of reducing power consumption ("Power Save") concern terminals only.

The invention proposes on the contrary a method implemented by a communication entity which can be an access point as well as a terminal, having multi-band capabilities, that is to say having the capabilities of a communication entity. transmit and receive simultaneously in at least two different frequency bands. A method according to the invention is also applicable to a multi-band communication entity which can play different roles (access point or terminal) depending on the band or as a function of time. According to a particular embodiment, the communication network is a WiFi network with a transmission band that corresponds to a 5GHz band with reference to a network compliant with the IEEE802.I standard and with a signal band that corresponds to a band. 868-868.6MHz in reference to a network compliant with the IEEE802.11ah standard.

The IEEE802.11ad standard defines a multi-band mode that is applicable to all WIFI systems (lla, b, g, n, ac, ad, af, ah, ...) even if its definition only intervenes in this standard with specific bands. This mode is used when a communication entity has two WiFi modules operating in two different bands.

The text from the standard IEEE802.11ad in its provisional version describes the element "Multi-band element" whose content is reproduced below in Table 1. Element Length Multiband Band Regulatory Channel BSSID Beacon Control ID Class Number Interval Bytes : 1 1 1 1 1 1 6 2 TSF Multiband FST STA MAC Pairwise Pairwise Offset STA Session Address Cipher Suite Cipher Suite Capability TimeOut (optional) Count List (optional) (optional) Bytes: 8 2 1 6 2 4 * m Table 1 This element provides guidance on the capabilities of entities with the multi-band feature. Broadcast in one of the bands, it makes it possible to signal the existence of the other band and to identify it by means in particular of the band ID field. The "multi-band STA capability" field defines in particular the role played by this entity in this other band: access point (AP) or terminal (STA). It can be transmitted with beacons, with association request / response, with probe request / response. FIG. 1 illustrates a wake-up method 1 according to the invention, implemented by a multi-band communication entity of a communication network. The simplified structure of a communication entity EC_T implementing a wake-up method according to the invention is illustrated in FIG. 2. Such an entity EC_T comprises a power supply PW of the radio module MR-Bt associated with the transmission band Bt. a memory BFF buffer or buffer, a processing unit UT, equipped for example with a microprocessor μP driven by the computer program Sw_t, two channels transmission / reception CH-Bs and CH-Bt for transmission / reception respectively in the signaling and transmission bands. The CH-Bs chain, respectively CH-Bt, comprises a radio module MR-Bs, respectively MR-Bt. At startup and more generally during the initialization or the reinitialization of the entity, the code instructions of the computer program Sw_t are for example loaded in a memory, RAM or any other suitable type, before be executed by the microprocessor μP of the processing unit UT. The microprocessor μP of the processing unit UT implements the wake-up method according to the instructions of the computer program Sw_t.

The reception in the signaling band Bs of the wake request Req_R by the entity EC T triggers the awakening of its radio module MR-Bt associated with the transmission band Bt. According to the illustration in FIG. 2, the request Req_R is received by the MR-Bs radio module, formatted by the CH-Bs chain, then processed by the processing unit UT to generate a Trig_PW control signal of a 1/0 switch controlling the power supply of the radio module MR -Bt supplied by the PW power supply unit. The alarm is obtained by switching the I / O switch. According to the embodiment illustrated in FIG. 2, the means of putting to sleep include a processing unit and a 1/0 switch. The microprocessor μP, microprogrammed by the program Sw_t, of the processing unit UT drives the switch 1/0. According to the illustrations of FIGS. 1 and 2, the entity EC_T receives in the signaling band Bs a wake-up request Req_R of its radio module associated with the transmission band Bt. This wake up request Req_R does not require a systematic return " Acknowledge "of the EC_T entity.

In the particular mode illustrated in FIG. 1, it is a request sent by the access point EC_AP. According to a particular mode, the access point transmits 4 this wake up request after reception 2 of Data data intended for the entity EC_T. According to one embodiment, the wake up request Req_R contains the following fields: Category Action Delivery time Buffer size Power save (optional) band ID Bytes: 1 1 XX 2 bits Table 2 The "Category" field refers to a table specified in the standard IEEE802.l in which defines the general category to which the request belongs: spectrum management, QoS (Quality Of Service), etc ... The field "Action" refers to a table specified in the standard that defines 25 precisely the type of action covered by the request. The "Delivery time" field determines the duration before sending by the access point AP in the data transmission band, buffered data awaiting transmission. The optional "Buffer size" field indicates the size of the data waiting for transmission. When the size is different from one, this informs the recipient of the request that data destined for it is put on hold and available for transmission.

The "Power save band ID" field indicates the data transmission band that must exit sleep mode. This transmission band is intended for the transmission of data buffered by the access point. According to another embodiment, the "Delivery time" field can be replaced by a "Buffer duration" field which indicates the duration during which the access point guarantees that it keeps in its buffers the data waiting for transmission. After this time, the data may be lost, for example if other data to be transmitted to the terminal arrive after this time. According to an embodiment illustrated in FIG. 1, the entity EC_T sends a mode reporting frame Tr_ps entitled "multiband ps frame action mode" comprising a signaling of the alarm of the radio module associated with the transmission band; the frame Tr_ps signals the transition to the energy saving mode. According to one embodiment, the alarm signaling frame Tr_ps contains the following fields: Category Action Multiband ps Signaling Power Details active mode Band ID save band element ID Bytes: 1 1 1 bit 2 bits 2 bits x Table 3 The "Multiband" field ps active mode "to indicate if the energy saving mode is activated or not, ie the entity is dormant or not. When activated, the "Signaling Band ID" field references the band used as the signaling channel and the "Power save band ID" field references the band used as a data transmission channel. The "Details element" field makes it possible to define more precisely the characteristics of the mode: for example, the data transmission band can restart in sleep directly after the transmission / reception of the data following the alarm or return to sleep after reception of a frame control. According to one particular mode, the alarm signaling frame Tr_ps is the equivalent of an acknowledgment following receipt of a wake-up request. The reception 7 by the access point AP of this Tr_ps frame informs it of the change of state of the entity EC T. In the case where the access point EC_AP has waiting in its buffers data intended for the EC_T entity, this information triggers 8 transmission 9 of these data.

In another case, the entity EC_T may have put data in its buffers. In this case, its change of state triggers the sending to the access point EC_AP of these data. According to one embodiment, the radio module associated with the transmission band automatically changes state and goes into a state of sleep. The change occurs either after reception of the pending data buffered by the access point EC_AP, or after transmission of the pending data buffered by the entity EC_T. The change of state according to the embodiment illustrated in FIG. 2 is controlled by the processing unit. The processing unit is informed of the transmission of data pending. As soon as this transmission is completed, the processing unit sends a Trig_PW command to change the position of the switch 1/0 and position it in the open position to interrupt the power supply of the radio module MR-Bt associated with the transmission band. . This makes it possible to avoid consumption of the radio module MR-Bt associated with the transmission band while no data is to be transmitted (transmission and / or reception).

Switching to the entity's power-saving mode (sleep state) may trigger the sending of a Tr_ps mode reporting frame labeled "multiband ps frame action mode" including a report of status equal to sleep of the radio module associated with the transmission band: the "Multiband ps active mode" field is activated. The sending is done in the signaling band.

According to one embodiment, the radio module associated with the signaling band is put on standby. The transition to standby mode is according to the illustration of Figure 2 driven by the UT processing unit. The processing unit directly controls the power supply of certain components of the radio module associated with the signaling band or the entire MR-Bs radio module by means of the Cde_R command. The control ensures at least a periodic wake up of the radio module MR-Bs so as to listen regularly to the signaling channel. The periodicity is such that the terminal is able to regularly receive beacon beacons transmitted by the access point. Thus, according to a particular mode the access point can issue the information element entitled "Multiband TIM" whose content is as follows. Element Length Band Multiband Multiband Bitband Multiband ID ID DTIM DTIM partial partial control period periodical virtual bitmap Bytes: 1 1 2 bits 1 2 2 x Table 4 This element takes over the operation of the TIM element defined in the IEEE802.11 standard for a radio system single band by extending it to multiband operation. The "Multiband TIM" element is regularly transmitted by the access point AP in the signaling band to inform a communication entity, a terminal in particular, of the holding on or not of data intended for it. It can be part of a "Beacon" tag issued by the access point. The "Band ID" field indicates the identifier of the data transmission band. In the case where there are several data transmission bands, the access point can send several "Multiband TIM" information elements, typically one per transmission band. The other fields have the same operation as the one defined for the TIM elements. More particularly, the fields "Multiband DTIM count" and "Multiband DTIM period" make it possible to signal transmissions in broadcast or multicast and the duration before their transmission in the data transmission band. The "Multiband partial virtual bitmap" field indicates the portion of bitmap virtual memory held by the access point. The field "Multiband partial virtual bitmap" is a bit vector whose index corresponds to the identifier AID of the communication entity, a terminal in particular, in the data transmission band, each bit signaling the existence ( bit = 1) or the absence (bit = 0) of data to be delivered to the communication entity concerned. The identifier AID of the communication entity in the data transmission band can either be identical to the identifier AID of the communication entity in the signaling band or be different. In the second case, the receiving communication entity must also know its AID identifier in the data transmission band in order to recover the correct information in the "Multiband TIM" information element. Transmission of only a portion of the bitmap virtual memory, "Multiband partial virtual map", and not all available fields is performed to limit the information transmitted to the active communication entities. The "Multiband partial virtual bitmap" field corresponds to the partial transmission of a mapping table for all users. The transmission is partial in the sense that the only information corresponding to the users having something to receive is transmitted. The "Bitmap control" and "Length" fields are then used to define the frame of this "Multiband partial virtual bitmap" field. According to one embodiment, the "Multiband TIM" information element provides information on the duration during which the access point commits to keeping the data waiting for a communication entity. Beyond this time the data is lost. If multiple data packets are queued, the duration may be relative to the oldest packet on hold. This information may allow the recipient communication entity to delay its wake up according to this duration. The power consumption of a WIFI component in data reception mode is of the order of 400mA. By taking a power supply at 3.3V, we can calculate the power saving obtained. According to the invention, the power supply of the components of the radio module associated with the signaling band is cut off, the energy saving is therefore important since the radio frequency transmission / reception component is not powered at all. It does not consume power. In the embodiment where the radio module associated with the signaling band is put on standby, the saving is lower than that obtained for the transmission band since the power failure is not total; the terminal having to be able to listen regularly to the signaling band. The wake up method according to the invention not only saves energy but also prolongs the use of the terminal.

With reference to FIG. 1, the access point EC_AP issues a wake up request Req_R of at least one radio module associated with a transmission band of a destination multiband entity. This transmission of the wake-up request occurs in the signaling band in the form of a signal. The signal takes the content of the request in another format, most often analog. The frequencies that make up the spectrum of the signal are for the most part included in the transmission band. The wake-up request is constructed by the access point according to the format of Table 2. The access point informs in particular the "Power save band ID" field with the identifier of the transmission band woken up. Before sending, the request is encapsulated in a frame that includes the address of the recipient. If the access point has pending data to the entity to wake up, the access point informs the fields "Delivery time" or "Butler duration" and possibly the "Butler size" field. An EC_AP communication entity adapted to implement a transmission method according to the invention comprises means illustrated by FIG. 3. The entity EC_AP comprises a memory BFF buffer or buffer, a processing unit UT, equipped for example with a microprocessor 43 controlled by the Swap computer program, two transmission / reception CH-Bs and CH-Bt channels for transmission / reception respectively in the signaling and transmission bands. The CH-Bs chain, respectively CH-Bt, comprises a radio module MR-Bs, respectively MR-Bt. At startup and more generally during the initialization or the reinitialization of the EC_AP entity, the code instructions of the Swap computer program are for example loaded into a RAM memory before being executed by the microprocessor μP. of the UT processing unit. The microprocessor μP of the processing unit UT implements the steps of the transmission method, according to the instructions of the computer program Swap. For this purpose, the means BFF stores the data intended to be transmitted in the transmission band to the destination entity, waiting for the receiving entity to wake up. The entities EC_T and EC_AP can be identical or played successively one of the two roles by implementing a method of transmitting the wake up request or a method of receiving the wake up request. The EC_T and EC_AP communication entities may be a terminal or an access point or play successively both roles. The term station is sometimes used to designate a terminal or an access point.

Claims (12)

REVENDICATIONS1. Method (1) of waking up a multi-band communication entity (EC_T) adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first band being intended for the transmission of data, signaling, characterized in that it comprises: a step of reception in the signaling band of a wake-up request of at least one radio module of the entity associated with the transmission band; an alarm clock of the radio module triggered by the wake up request. 2. Method (1) for waking a communication entity (EC_T) according to claim 1, further comprising: - a step of sending a wake up signal frame including a signaling alarm of the radio module associated with the transmission band and - a data transmission step waiting. 3. Method (1) for waking up a radio module of a communication entity (EC_T) according to claim 2, further comprising a step of putting the radio module associated with the transmission band to sleep, after transmission of the data. waiting. 4. Method (1) of waking a radio module of a communication entity (EC_T) according to claim 1, wherein the wakeup request includes information on the availability of data pending. 25 5. Method (1) for waking a radio module of a communication entity (EC_T) according to claim 1, further comprising a step of standby of the radio module associated with the signaling band. 6. A method of transmitting a data frame by a multi-band communication entity 30 adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first one being for signaling, characterized in that it comprises: a step of constructing a wake-up request of at least one radio module associated with a transmission band of a destination multi-band entity, a step ( 4) transmission of the frame including the wake request in the signaling band. 7. Multi-band communication entity (EC_T) adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first band being intended for signaling, characterized in that it comprises: - receiving means (CH-Bs) in the signaling band of a wake-up request (Req_R) of at least one radio module (MR-Bt) of the entity associated with the transmission band, means (UT, UO) for putting at least the radio module (MR-Bt) associated with the transmission band of the entity to sleep. 8. Multi-band communication entity (EC_AP) adapted to a multi-band wireless communication network, a first band being intended for data transmission, a second band different from the first band being intended for signaling, characterized in that it comprises: means (CH-Bs) for transmitting in the signaling band a wake-up request of at least one radio module associated with the transmission band of a destination entity, - means (BFF) storing data intended to be transmitted in the transmission band to the destination entity, waiting for the receiving entity to wake up. 9. Signal representative of a wake-up request (Req_R) sent by a multi-band communication entity (EC_AP) adapted to a multi-band wireless communication network, a first band (Bt) being intended for data transmission, a second band (Bs) different from the first one being intended for signaling, characterized in that its frequency spectrum is included in the signaling band and in that the wakeup request of at least one radio module associated with the band A transmission entity of a communication entity, which it represents, contains the identification of the transmission band of the communication entity receiving the request. 10. Computer program (Sw_T) on an information medium, said program comprising program instructions suitable for implementing an alarm method according to any one of claims 1 to 5 when this program is executed. by a processor. 11. Computer program (Sw_AP) on an information carrier, said program comprising program instructions adapted to the implementation of a transmission method according to claim 6 when the program is executed by a processor. 12. Information carrier comprising program instructions adapted to the implementation of an alarm method according to any one of claims 1 to 5, implemented by a multi-band communication entity adapted to a communication network wireless multi-band when said program is loaded and executed in the entity (EC_T) for implementing the waking process.