WO2002033855A1 - Method for calibrating return channel, and corresponding subscriber device - Google Patents

Abstract

The invention concerns a calibrating method which combines frequency and power calibration to ensure fast calibration of the device and to avoid any ill-timed interference during calibration. The invention consists in a method for calibrating a subscriber device communicating with a broadcasting station wherein the subscriber device repeats the transmission of a specific message addressed to the broadcasting station until it receives an acknowledgement. The message is sent at constant power over all the frequencies prior to increasing the power. The invention also concerns the use of a standby channel alternately with the assigned channel.

Description

RETURN TRACK CALIBRATION METHOD, AND CORRESPONDING SUBSCRIBER POSITIVE DIS

The invention relates to a return channel calibration method. The invention applies to radio or point-to-multipoint type satellite transmission systems composed of a broadcasting station and a plurality of subscriber terminals having a return channel.

Point-to-multipoint wireless transmission systems are known to those skilled in the art under the acronyms MMDS (from the English Microwave Multipoint Distribution System), LMDS (from the English Local Multipoint Distribution System) and MVDS (from the English Multipoint Video Distribution System). These systems used for broadcasting programs authorize a return path to subscriber terminals which allows the subscriber to interact with the received program. Figure 1 illustrates an LMDS type system. A broadcasting station 1 provided with a transmitter and a receiver broadcasts information to a plurality of subscribers 2. Each subscriber 2 has an outdoor unit 3, consisting of an antenna and means for transposing the signal received or the signal to be transmitted at an intermediate frequency, and from an indoor unit 4 which comprises means for channel selection in transmission and in reception as well as various coding / decoding means for exchanging data with at least one user device 5, for example a television or telephone.

In Europe, it is planned to implement a LMDS type system which has 24 broadcast channels (also called downlink) with a bandwidth of 33 MHz, and 25 return channels (or uplink) having a bandwidth of 2 MHz, these channels being located between 40.5 and 42.5 GHz (for more details on the distribution of channels, the skilled person can consult the MPT-1560-RA standard) . The system implemented must comply with standard ETSI 301,199 better known under the name DVB LMDS which provides inter alia for an oscillator drift of more or less 200 kHz for the uplink, the drift being mainly due to climatic conditions. On the other hand, the broadcasting station can receive the frequency of the uplink only if it deviates by at most 10 kHz.

The standard provides for an initialization sequence for devices placed at the subscriber's site in order to compensate for the drift of the outdoor unit 3. The broadcast station 1 sends on one of the downlink channels the service information necessary to connect subscribers. Among the service information, the uplink and downlink channels to be used for communication are indicated for each subscriber, as well as a frequency step to be used to calibrate the uplink frequency. The service information also indicates a backup uplink channel. Furthermore, in order to avoid a subscriber transmitting with too high a power, becoming a source of noise for the other subscribers, the standard also provides for a power calibration. To this end, the service information indicates the maximum power and the minimum power to be used as well as a step of power to increase or decrease the power, and a minimum number of attempts to be made before increasing the power.

The standard specifies how the frequency calibration should take place and how the power calibration should take place. The standard suggests that the frequency calibration must first be carried out and then the power calibration. However, to perform frequency calibration, you must be sure of being received by the broadcasting station and therefore transmit with a minimum of power to be sure that the signal is received. Frequency calibration carried out in this way can create a source of noise when each subscriber device is switched on as soon as the weather conditions have changed since the device was switched off.

The invention proposes a calibration method which combines frequency and power calibration in order, on the one hand, to ensure rapid calibration of the device and, on the other hand, to avoid any unwanted interference during the 'calibration. The invention is a method for calibrating a subscriber device communicating with a broadcasting station in which the subscriber device repeats the sending of a specific message to the broadcasting station until receipt of an acknowledgment reception from said station, characterized in that the subscriber device performs the following steps

E0: initialization of a transmission frequency F at a frequency F0, of a frequency step ΔF, of a transmission power P to a power PO and of a power step ΔP; - E1: sending a message at frequency F and at power P and waiting for a response for a predetermined period. ; E2: if there is no response, change the frequency F to a value F = F0 + N * ΔF, where N is an integer between 1 and Nmax, then send a message at the frequency F and at the power P and waiting for a response for a predetermined period. ; - E3: in the absence of a response, modification of the frequency F to a value F = F0 - N ^* ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ; E4: in the absence of response, repeating steps E2 and E3 by changing the value of N;

E5: in the absence of response and when all the values of N have been used, addition of ΔP to the power P and repetition of steps E1, E2, E3, E4 and E5 as long as there is no response and as long that the power P is less than the maximum power. According to a variant, the invention proposes to use an emergency channel alternating with the allocated channel. The invention then becomes a method of calibrating a subscriber device communicating with a broadcasting station in which the subscriber device repeats the sending of a specific message to the broadcasting station until receipt of a acknowledgment from said station, characterized in that the subscriber device performs the following steps

E0: initialization of a transmission frequency F at a frequency F0, of a backup transmission frequency FS at a frequency FSO, of a frequency step ΔF, of a transmission power P to a power PO and a power step ΔP;

E1: sending a message at frequency F and at power P and waiting for a response for a predetermined duration. ; E1 ': if there is no response, send a message at the frequency

FS and at power P and waiting for a response for a predetermined duration. ;

E2: if there is no response, change the frequency F to a value F = F0 + N * ΔF, where N is an integer between 1 and Nmax, then send a message at the frequency F and at the power P and waiting for a response for a predetermined period. ; - E2 ': in the absence of response, modification of the frequency FS to a value FS = FSO + N * ΔF, where N is an integer between 1 and Nmax, then sending a message at frequency F and at power P and waiting for a response for a predetermined duration. ;

- E3: in the absence of a response, modification of the frequency F to a value F = F0 - N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ;

- E3 ': in the absence of response, modification of the frequency FS to a value FS = FSO - N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ;

- E4: in the absence of response, repeating steps E2, E2 ', E3 and E3' by changing the value of N;

- E5: in the absence of response and when all the values of N have been used, addition of ΔP to the power P and repetition of steps E1, E1 ', E2, E2', E3, E3 ', E4 and E5 as long there is no response and as long as the power P is less than the maximum power.

The invention also relates to the subscriber device of a data broadcasting system with return channel, said device comprising means for implementing one of the methods set out above.

The invention will be better understood, and other features and advantages will appear on reading the description which follows, the description referring to the accompanying drawings, in which: FIG. 1 represents a diffusion system with return channel, FIG. 2 represents a subscriber device of the system of FIG.

1, as implemented in the context of the invention, FIG. 3 represents a calibration algorithm according to a first embodiment of the invention, FIG. 4 represents a calibration algorithm according to a second embodiment of the invention, FIG. 5 represents a variant of the subscriber device of FIG. 2, and FIG. 6 represents a calibration algorithm according to a third embodiment.

Figure 1 having been previously described, it will not be described in more detail. Figure 2 shows the subscriber device in more detail. The outdoor unit 3 comprises an antenna and means for transposing the useful signal to an intermediate frequency. As those skilled in the art know, the oscillators used in the outdoor units exhibit a drift due to climatic variations. However, when the frequency of the transmitted signal is very high, for example around 40 GHz, it is not possible to transmit the signal over a cable without suffering significant losses. The transposition is done for example on a frequency band located between 400 MHz and 2.2 GHz. The indoor unit 4 includes demodulation means 10 and modulation means 11 which make it possible to select a channel and to transpose between the intermediate frequency and the baseband. The demodulation means 10 and the modulation means 11 each comprise at least one oscillator 12 and 13 connected to at least one mixer 14 and 15 and filters 16 to 20 intended to select a more or less wide frequency band according to the 'place where they are placed. For more details, a person skilled in the art can refer to the figure and to the numerous documents of the state of the art describing modulation and demodulation circuits. Oscillators 12 and 13 are much more precise than those used in the outdoor unit and their drifts are negligible compared to the precision necessary for proper operation.

The indoor unit 4 has a decoding circuit 21 which checks the integrity of the data and routes the data either to a user device 5 via an interface 22 or to a control circuit 23 which manages the operation of the indoor unit 4. An encoder circuit 24 receives data from the user device 5 via an interface 25, either directly from the control circuit 23 in order to format it before modulation. The control circuit 23 has a memory 26 which contains various information on the system. The memory 26 is preferably an EEPROM or Flash type memory which makes it possible to store data when the power is off.

The control circuit 23 is for example a processor having a program for example placed in the memory 26. It is the control circuit 23 which will ensure the agreement of the controlled oscillators 12 and 13 according to a command received of a user, or as a function of a decoded message which indicates a particular channel to be selected, or as a function of information stored in the memory 26. By way of example, a user can select the downlink according to the content he wishes to obtain. The return channel, on the other hand, is determined by the broadcasting station 1. It is advisable, during the first use and at each change of channel allocation, to memorize the channel to be used in the memory 26 and to position the oscillator 13 according to the information received. The control circuit 23 also acts on an amplifier 27 in order to adjust the transmission power of the return channel. The control circuit 23 also receives messages from the decoder 21 containing acknowledgments of reception and synchronization information which indicate, for example, when the subscribed device is authorized to transmit when the latter is connected.

The control circuit 23 is responsible for calibrating the transmission frequency whenever necessary. This calibration is generally done when using the subscriber device for the first time or when the subscriber device is powered up, but can be done at another time, as long as there is no longer any acknowledgment on messages. sent. Also, the control circuit 23 will adjust the transmission power in order to limit this power to the minimum necessary to ensure good transmission without interfering with other subscribed devices. FIG. 3 illustrates an algorithm implemented by the control circuit 23 for the frequency and power calibration. The calibration algorithm begins with an initialization step 100 in which the transmission frequency F is fixed at a frequency F0 which corresponds either to a frequency received from the broadcasting station 1, if it is a first commissioning of the subscriber device, either at a stored frequency which corresponds to the last frequency used for the uplink channel. The initialization step 100 also fixes the transmission power P at a level PO which corresponds either to the minimum power indicated by the broadcasting station 1 or to the last transmission power used. During the initialization step 100, the control circuit fixes the frequency steps ΔF and power ΔP to be used. The frequency steps ΔF and power ΔP are information sent by the broadcasting station 1, but may have been memorized during a previous use of the subscriber device. An index of N is initialized to the value 1, the index N being an integer. A value Nmax corresponding to the maximum value of the index N is calculated by dividing the drift range, for example 200 kHz, by the frequency step ΔF, the rounding being carried out on the higher value. Maximum transmit power Pmax is fixed at a value sent by the broadcasting station 1 or read in the memory 26.

During a step 101, an identification message of the subscriber device is sent on the carrier frequency F to the power P. The control circuit 23 goes into the standby position for a predetermined duration, for example 90 ms.

At the end of the predetermined duration, a test 102 is carried out. If the result of the test 102 indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs a storage step 103, otherwise it performs a message sending step 104.

During the storage step 103, the control circuit 23 stores in the memory 26 the frequency F used during the last message sending and possibly corrected by a value indicated in the acknowledgment message of the station. based. The transmission power P used during the last message sending is also modified, possibly corrected by a value indicated in the acknowledgment message of the base station. The calibration is then complete.

During step 104, the frequency F is fixed at a value equal to F0 + N * ΔF. An identification message of the subscriber device is sent on the carrier frequency F to the power P. The control circuit 23 goes into the standby position for the predetermined duration.

At the end of the predetermined duration, a test 105 is carried out. If the result of the test 105 indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs the storage step 103, otherwise it performs a message sending step 106.

During step 106, the frequency F is fixed at a value equal to F0 - N * ΔF. An identification message of the subscriber device is sent on the carrier frequency F to the power P. The control circuit 23 goes into the standby position for the predetermined duration. At the end of the predetermined duration, a test 107 is carried out. If the result of the test 107 indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs the storage step 103, otherwise it performs a test 108.

Test 108 checks whether the value N is equal to Nmax or not. If N = Nmax, then a test 109 is carried out. If N is not equal to Nmax, then N is incremented by one during a step 110, then step 104 is carried out again. Test 109 checks whether the value of P is equal to the value Pmax. Yes

P = Pmax, then a step 1 1 1 indicates to the user that it is impossible to connect to the broadcasting station and the calibration ends. If P is not equal to Pmax, then, during a step 112, P is incremented by a value ΔP and N is set to the value 1, then step 101 is carried out.

If the calibration ends with the message from step 1 11, two causes are possible. A first cause is material, there may be a fault, a disconnected wire or a wrong orientation of the antenna of the subscriber device, in this case, it is necessary to bring a qualified technician to repair.

The second cause may be due to message collisions. Indeed, as long as the subscribed device is not declared to the broadcasting station, it does not have a specific transmission time, there can therefore be a collision between the message sent and a message sent by a other subscribed device. The DVB LMDS standard provides for this purpose an emergency channel for the uplink. Normally, the backup channel is rarely used because it is only used when a subscriber device cannot communicate via the channel which is normally assigned to it. The drift due to the oscillator of the external unit being the same whatever the channel, the calibration can be done on the backup channel as well as on the communication channel assigned to the subscriber device. In this case, the calibration algorithm should be performed again using the frequency of the backup channel.

However, if the number of subscribers is high, the calibration will be done systematically on the backup channel. In order to avoid a too long wait and also in order to avoid transmitting at too high a power on the allocated channel, FIG. 4 presents an algorithm performing the calibration alternately between the backup channel and the channel allocated to the subscribed device. The algorithm of figure 4 corresponds to the algorithm of figure 3 modified. The steps with the same numbers correspond to identical or similar steps.

The calibration algorithm begins with an initialization step 100b in which the transmission frequency F is fixed at a frequency F0 which corresponds either to a frequency allocated by the broadcasting station 1 if it is a first commissioning of the subscriber device, i.e. at a stored frequency which corresponds to the last frequency used for the uplink channel A transmission frequency FS is fixed to the frequency FSO which corresponds either to the frequency of the backup channel sent by the broadcasting station 1 if it is the first commissioning of the subscriber device, or to the frequency of the backup channel memorized during a previous use The initialization step 100b also fixes the transmission power P at a level PO which corresponds either to the minimum power indicated by the broadcasting station 1 or to the last transmission power used During the initialization step 100b, the control circuit fixes the frequency steps ΔF and power ΔP to be used The frequency steps ΔF and power ΔP are information sent by the broadcasting station 1, but may have been memorized during a previous use of the subscriber device An index of N is initialized to the value 1, the index N is an integer A value Nmax corresponding to the maximum value ale of the index N is calculated by dividing the drift range, for example 200 kHz, by the frequency step ΔF, the rounding being done on the higher value The maximum power Pmax of emission is fixed at a value sent by broadcast station 1 or read from memory 26

During a step 101, an identification message of the subscriber device is sent on the carrier frequency F to the power P The control circuit 23 goes into the standby position for a predetermined duration, for example 90 ms

At the end of the predetermined duration, a test 102 is carried out If the result of the test 102 indicates that an acknowledgment of receipt has been received then the control circuit 23 performs a storage step 103, otherwise it performs a step of sending a message 101 b

During the storage step 103, the control circuit 23 stores in the memory 26 the frequency F used during the last message sending and possibly corrected by a value indicated in the acknowledgment message of the station. base The transmission power P used during the last message transmission is also modified, possibly corrected by a value indicated in the acknowledgment message of the base station The frequency FS corresponding to the frequency F possibly corrected can also be memorized Calibration is then finished During step 101b, an identification message from the subscriber device is sent on the carrier frequency FS at power P The control circuit 23 goes into the standby position for the duration predetermined At the end of the predetermined duration, a test 102b is carried out. If the result of the test 102b indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs a storage step 103, otherwise it performs a message sending step 104. During step 104, the frequency F is set to a value equal to

F0 + N * ΔF. An identification message of the subscriber device is sent on the carrier frequency F to the power P. The control circuit 23 goes into the standby position for the predetermined duration.

At the end of the predetermined duration, a test 105 is carried out. If the result of the test 105 indicates that an acknowledgment has been received, then the control circuit 23 performs the storage step 103, otherwise it performs a message sending step 104b.

During step 104b, the frequency FS is fixed at a value equal to FSO + N * ΔF. An identification message of the subscriber device is sent on the carrier frequency FS at the power P. The control circuit 23 goes into the standby position for the predetermined duration.

At the end of the predetermined duration, a test 105b is carried out. If the result of the test 105b indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs the storage step 103, otherwise it performs a message sending step 106.

During step 106, the frequency F is fixed at a value equal to F0 - N * ΔF. An identification message of the subscriber device is sent on the carrier frequency F to the power P. The control circuit 23 goes into the standby position for the predetermined duration. At the end of the predetermined duration, a test 107 is carried out. If the result of the test 107 indicates that an acknowledgment has been received, then the control circuit 23 performs the storage step 103, otherwise it performs a test 106b.

During step 106b, the frequency FS is fixed at a value equal to FSO - N * ΔF. An identification message of the subscriber device is sent on the carrier frequency FS at the power P. The control circuit 23 goes into the standby position for the predetermined duration.

At the end of the predetermined duration, a test 107b is carried out. If the result of the test 107b indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs the storage step 103, otherwise it performs a test 108. Test 108 checks whether the value N is equal to Nmax or not. If N = Nmax, then a test 109 is carried out. If N is not equal to Nmax, then N is incremented by one during a step 110, then step 104 is performed again. The test 109 checks whether the value of P is equal to the value Pmax . Yes

P = Pmax, then a step 111 indicates to the user that it is impossible to connect to the broadcasting station and the calibration ends. If P is not equal to Pmax, then, during a step 112, P is incremented by a value ΔP and N is set to the value 1, then step 101 is carried out. the realization of this algorithm, the message of the step

1 11 essentially indicates a hardware-type problem, the probability of chances that there have been message collisions becomes very low. In addition, during the calibration of the subscriber device, the transmission power always remains below the threshold necessary for good transmission, thus limiting interference from other subscriber devices.

Other variants are possible: one can, for example, send the message first on the backup channel before sending it on the specific channel of the user device. Another possibility is to scan all the values of N for the frequency F and then to scan all the values of N for the frequency FS at constant power.

It is also possible to send the identification message simultaneously on the channel allocated to the subscriber device and on the backup channel. For this, it is necessary to modify the indoor unit 4, as indicated in FIG. 5, by doubling the transmission means 11b so that the same message can be sent on two frequencies at the same time.

The corresponding calibration algorithm is illustrated in FIG. 6. The calibration algorithm begins with an initialization step 100c in which the transmission frequency F is fixed at a frequency F0 which corresponds either to a frequency assigned by the broadcasting station 1 if it is a first commissioning of the subscriber device, ie at a stored frequency which corresponds to the last frequency used for the uplink channel. A transmission frequency FS is fixed at the frequency FSO which corresponds either to the frequency of the backup channel sent by the broadcasting station 1 if it is a first commissioning of the subscribed device, or to the frequency of the backup channel memorized during a previous use. The initialization step 100c also fixes the transmission power P at a level PO which corresponds either to the power minimum indicated by broadcasting station 1 or the last transmission power used. During the initialization step 100c, the control circuit 23 fixes the frequency steps ΔF and the power ΔP to be used. The frequency steps ΔF and power ΔP are information sent by the broadcasting station 1, but may have been memorized during a previous use of the subscriber device. An index of N is initialized to the value 1, the index N being an integer. A value Nmax corresponding to the maximum value of the index N is calculated by dividing the range of drift, for example 200 kHz, by the frequency step ΔF, the rounding being carried out on the higher value. The maximum transmission power Pmax is fixed at a value sent by the broadcasting station 1 or read in the memory 26.

During a step 101c, an identification message of the subscriber device is sent on the carrier frequency F at the power P and simultaneously on the carrier frequency FS at the power P. The control circuit 23 goes into the standby position for a predetermined duration, for example 90 ms.

At the end of the predetermined duration, a test 102c is carried out. If the result of the test 102c indicates that an acknowledgment of receipt has been received, then the control circuit 23 performs a storage step 103c, otherwise it performs a message sending step 104c.

During the storage step 103c, the control circuit 23 stores in the memory 26 the frequency F used during the last message sending and possibly corrected by a value indicated in the acknowledgment message of the station. based. The transmission power P used during the last message sending is also modified, possibly corrected by a value indicated in the acknowledgment message of the base station. The frequency FS corresponding to the frequency F possibly corrected can also be memorized. The calibration is then complete. During step 104c, the frequency F is fixed at a value equal to

FO + N * ΔF and the frequency FS is fixed at a value equal to FSO + N * ΔF. An identification message of the subscriber device is sent on the carrier frequency F at the power P and simultaneously on the carrier frequency FS at the power P. The control circuit 23 goes into the standby position for the predetermined duration.

At the end of the predetermined duration, a test 105c is carried out. If the result of test 105c indicates that an acknowledgment has been received, then the control circuit 23 performs the storage step 103c, otherwise it performs a message sending step 106c.

During step 106c, the frequency F is fixed at a value equal to F0 - N ^* ΔF and the frequency FS is fixed at a value equal to FSO - N * ΔF. An identification message of the subscriber device is sent on the carrier frequency F at the power P and simultaneously on the carrier frequency FS at the power P. The control circuit 23 goes into the standby position for the predetermined duration.

At the end of the predetermined duration, a test 107c is carried out. If the result of the test 107c indicates that an acknowledgment has been received, then the control circuit 23 performs the storage step 103c, otherwise it performs a test 108c.

The test 108c checks whether the value N is equal to Nmax or not. If N = Nmax, then a test 109c is carried out. If N is not equal to Nmax, then N is incremented by one during a step 110c, then step 104c is carried out again.

The test 109c checks whether the value of P is equal to the value Pmax. Yes

P = Pmax, then a step 111c indicates to the user that it is impossible to connect to the broadcasting station and the calibration ends. If P is not equal to Pmax, then, during a step 112c, P is incremented by a value ΔP and N is set to the value 1, then step 101c is carried out.

In the above description, we first test the frequency

F0 + ΔF before testing the frequency F0-ΔF. It is obvious that we can do the opposite. A person skilled in the art can very well reverse steps 104, 104b and 104c with steps 106, 106b and 106c respectively, without changing anything in the invention.

Other variations are possible. In the description, it is indicated that we are waiting for the end of a predetermined period of time to check whether or not there is an acknowledgment message from the broadcasting station. A person skilled in the art may very well not wait for the end of the predetermined duration when there is a message. The passages indicated "at the end of the predetermined duration" can be replaced by "at the end of the predetermined duration or upon receipt of a message from the base station".

In the algorithms described, an increasing value of N is used. This choice was made because it appears to be the simplest. It is quite possible to use a value of N which is decreasing or even pseudo-random.

Claims

1. Method for calibrating a subscriber device (2, 3, 4) communicating with a broadcasting station (1) in which the subscriber device (2, 3, 4) repeats sending a specific message to the destination from the broadcasting station until receipt of an acknowledgment from said station, characterized in that the subscriber device performs the following steps

- E0: initialization of an emission frequency F at a frequency F0, of a frequency step ΔF, of a transmission power P to a power PO and of a power step ΔP;

- E1: sending a message at frequency F and at power P and waiting for a response for a predetermined period. ; - E2: in the absence of a response, modification of the frequency F to a value F = F0 + N ^* ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ; - E3: in the absence of a response, modification of the frequency F to a value F = F0 - N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ; - E4: in the absence of a response, steps E2 and

E3 by changing the value of N;

- E5; in the absence of response and when all the values of N have been used, addition of ΔP to the power P and repetition of steps E1, E2, E3, E4 and E5 as long as there is no response and as long as the power P is less than the maximum power.

2. Method for calibrating a subscriber device communicating with a broadcasting station in which the subscriber device repeats the sending of a specific message to the broadcasting station until receipt of an acknowledgment from of said station, characterized in that the subscriber device performs the following steps

- E0: initialization of a transmission frequency F at a frequency FO, of a backup transmission frequency FS at a frequency FSO, of a frequency step ΔF, of a transmission power P at a power PO and a power step ΔP;

- E1: sending a message at frequency F and at power P and waiting for a response for a predetermined period. ; - E1 ': in the absence of a response, sending a message at the frequency FS and at the power P and waiting for a response for a predetermined duration. ;

- E2: in the absence of response, modification of the frequency F to a value F = FO + N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ;

- E2 ': in the absence of a response, modification of the frequency FS to a value FS = FSO + N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ;

- E3: in the absence of a response, modification of the frequency F to a value F = FO - N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ;

- E3 ': in the absence of response, modification of the frequency FS to a value FS = FSO - N * ΔF, where N is an integer between 1 and Nmax, then sending of a message at the frequency F and at the power P and waiting for a response for a predetermined duration. ;

- E4: in the absence of a response, steps E2, E2 ', E3 and E3' are repeated by changing the value of N; - E5: in the absence of response and when all the values of

N were used, addition of ΔP to the power P and repetition of steps E1, E1 ', E2, E2', E3, E3 \ E4 and E5 while there is no response and as long as the power P is less than the maximum power.

3. Method according to claim 2, characterized in that steps E1 and E1 'take place simultaneously, in that steps E2 and

E2 'takes place simultaneously, and in that steps E3 and E3' take place simultaneously.

4. Method according to claim 2, characterized in that the steps E2 and E4 are carried out for all the values of N before performing a step E1 ', E2' or E3 '.

5. Method according to one of claims 1 to 4, characterized in that the frequency FO is equal to a frequency stored by the subscriber device.

6. Method according to one of claims 2 to 4, characterized in that the frequency FSO is equal to a frequency stored by the subscriber device.

7. Method according to one of claims 1 to 4, characterized in that the power PO is equal to a power stored by the subscriber device.

8. Method according to one of claims 1 to 7, characterized in that N is an integer which varies increasing between 1 and Nmax.

9. Device subscribed to a data broadcasting system with return channel, characterized in that it includes means for implementing the method of one of claims 1 to 8.