WO2011001106A1 - Method for managing a frequency resource corresponding to a channel allocated to a device, and corresponding computer program, device, and signal - Google Patents

Abstract

The invention relates to a method for managing a frequency resource corresponding to a channel allocated to at least one device. According to the invention, such a method includes: a step of generating (11) a signal having a specific radar-type structure, that is, a so-called decoy signal, for changing the behavior of at least one device transmitting the signal in said channel; and a step of transmitting (12) said decoy signal in said channel.

Description

 A method of managing a frequency resource corresponding to a channel allocated to a corresponding equipment, computer program, equipment and signal.

 1. Field of the invention

 The field of the invention is that of radiofrequency communications.

 More precisely, the invention relates to the management of the frequency resources allocated to equipment transmitting in the same radio frequency channel, and makes it possible to adapt the behavior of these devices as a function of the signals transmitted in this channel.

 The invention finds particular applications in the management of frequency resources of equipment emitting in a frequency band around 5GHz, in which equipment including IEEE 802.11 or its revised versions, also called Wifi.

 The term "equipment" here refers to an element belonging to a basic service set (BSS) formed by an access point ("access point") and the stations associated with this point of service. access, that is to say the stations located in the coverage area of this access point.

 2. Prior Art

 The following is a description of the prior art relating to the management of frequency resources of equipment of a network operating according to Wifi technology as defined in the IEEE 802.11a standard.

 Indeed, although operating conventionally in the frequency band around 2.4GHz (still called ISM band for "Industrial, Scientific and Medical"), the equipment of a Wifi network according to the IEEE 802.11a standard can operate in the free band around 5GHz (still called U-UNII band for "Unlicenced- National Information Infrastructure"), on 20MHz radiofrequency channels.

 When allocating the frequency resources to a device of a Wi-Fi network, a known dynamic frequency selection (DFS) mechanism is activated, in order to prevent the equipment from transmitting information on a channel when at least one radar is already active in this channel.

This DFS mechanism makes it possible, in particular, to detect the presence of radar-type signals in the channel that one wishes to allocate (or already allocated) to a piece of equipment of a Wifi network, and to force the equipment to change the radio frequency channel in the event of presence of a radar signal. It is recalled that a radar (RAdio Detection And Ranging) is a device for determining the distance and direction of an obstacle by reflection of radio waves. This is for example a radar weather, radiolocation radar, etc.

 Such a DFS mechanism is more precisely described in the EEEE 802.11-2007 standard, 5.4.4 "Spectrum management services", 5.4.4.2 "DFS". It avoids interference with a radar system by:

 - verifying that a radiofrequency channel is free of radar signals before using it;

 - monitoring the radar signals when a radio frequency channel is used, and releasing the channel if a radar signal is detected;

 - remaining outside the channels in which the radars operate;

 - transmitting only the power required for communications (according to a power control mechanism, in English "Transmit Power Mechanism").

 However, such a mechanism is restricted to the detection and protection of radar signals in the frequency band around 5 GHz.

 Apart from this frequency selection mechanism, each equipment (access point or stations located in the coverage area of this access point) can choose any channel for transmissions in the 5GHz band.

 Frequently, several Wifi points are found on the same channels and in the same spatial environment. These are called overlapping Base Station Subsystems (or "overlapping Base Station Subsystems"). Under these conditions, the radio frequency channel must be shared between the different sets of basic services (BSS).

 This is done conventionally using the CSMA-CA access mode, as described in the 802.11 -2007 standard, 9.1 "MAC architecture", 9.1.1 "DCF ".

 The CSMA-CA mechanism ensures sharing of access to the channel according to a so-called contention principle: each equipment must listen that the channel is free (ie no signal is transmitted / received in this channel). channel) for a certain period (called "backoff" in English) before transmitting data.

However, the greater the number of equipment sharing the channel, the greater the probability of collision between simultaneous transmissions is significant, which degrades the flow performance. Indeed, if a transmission is not acknowledged (because of a transmission error on the channel or a collision), the retransmission is performed with a doubled backoff period. In addition, the most recent Wi-Fi devices operate on radiofrequency channels of increasing width, for example having a width equal to 40MHz (corresponding to the aggregation of two channels of 20MHz) or more, in which a greater number of equipment emit. This leads to an increased risk of collisions.

 There is therefore a need for a new technique to best manage the frequency resources of different equipment transmitting in the same radio frequency channel.

 3. Presentation of the invention

 The invention proposes a new solution that does not have all of these disadvantages of the prior art, in the form of a frequency resource management method corresponding to a channel allocated to at least one equipment, said first equipment.

 According to the invention, such a method comprises:

 A step of generating, by said first equipment, a signal having a particular radar-type structure, called a decoy signal, intended to modify the behavior of at least one second equipment emitting in the channel;

a step of transmission, by said first equipment, of the decoy signal in the channel.

 Thus, the invention is based on a new and inventive approach to the management of frequency resources assigned to at least one equipment transmitting in a radio frequency channel.

 In the context of Wi-Fi type communications for example, such equipment corresponds to an element belonging to a set of basic services, formed by an access point and the stations associated with this access point.

 In addition, the term "equipment transmitting in a radio frequency channel" here means a device already transmitting in this channel, or wishing to transmit in this channel.

 In particular, according to the invention, a "decoy" signal is generated, imitating a radar signal, and intended to modify the behavior of at least one equipment emitting in a radiofrequency channel. This modification of behavior means that this equipment can be constrained for example to change the radio frequency channel, to change the frequency band inside this channel, to stop transmitting in this channel, to modify its transmission power etc.

It is considered that such equipment (second equipment) disturbs the operation of other equipment (first equipment) transmitting in the same channel, and that this disturbing equipment must change channels or stop transmitting in this channel for example.

 For example, the decoy signal is emitted by this other equipment emitting in the same channel, and makes it possible to force the "disruptive" equipment located within the range of this equipment to change channels. It is noted that no known technique to date relies on the use of equipment belonging to a set of basic services to force equipment belonging to another set of basic services to change channels.

 Such a decoy signal has a particular structure of the radar type, which is known from other equipment operating in the radiofrequency channel. Thus, other equipment operating in this radiofrequency channel know that when a signal having such a structure is detected in a radio frequency channel, they must for example leave this radio frequency channel.

 Such a radar type structure is conventionally composed of successive bursts, each comprising one or more pulses.

 In particular, in a "BSS overlapping" situation as described in relation with the prior art, the channel had to be shared between the different BSSs, using the CSMA-CA access mode for example.

 In a radiofrequency channel having a width greater than 20 MHZ in particular, because of the number of equipment emitting in this channel, it is desirable for some devices to modify their access mode in order to "unload" the radio frequency channel used.

 However, new generation Wi-Fi equipment (as defined in the forthcoming IEEE 802.1 lake standard, for example) can not modify their access mode, since they must remain compatible with previous generations of Wifi equipment (as defined in the standard 802. l in or 802.11a for example, still called "legacy" in English), and in particular equipment belonging to the BSS of the same channel and located within the scope of a device of a new generation BSS , also called "adjacent BSS".

 The solution proposed by the invention to allow a modification of the access mode is then to force the adjacent BSS, especially those that do not understand the new access mode, to change the channel.

Thus, the behavior of the equipment emitting in a specific radiofrequency channel can be modified according to the type of equipment. For example, if said at least one second piece of equipment is a first-generation type of equipment, said to be of older generation, capable of transmitting in a narrower frequency band than a second type of equipment, called a new generation, the management method comprises:

 a step of receiving the decoy signal by the equipment of the first type, and

a step of changing the channel allocated to the equipment of the first type.

 Thus, the reception of a decoy signal, in the specific radiofrequency channel, by an old generation equipment as defined according to the 802.11a or 802.1 In standard, can cause the assignment to this old generation equipment of a new radio frequency channel.

 In other words, if we consider an old generation Wifi equipment, not including the new access mode, this equipment will be forced to change radio frequency channel.

 According to another example, if said at least one second piece of equipment is a second type of equipment, said new generation, able to transmit in a wider frequency band that a first type of equipment, called old equipment generation, the management method comprises:

 a step of receiving the decoy signal by the equipment of the second type,

a step of detecting that the received signal is a decoy signal, and

 - A decision step of maintaining or not the channel allocated to the second type of equipment.

 On the other hand, the receipt of a decoy signal, in the specific radio frequency channel, by new generation equipment as defined by a new standard to be defined (such as the 802.1 lake standard), may not lead to an interruption of this new generation equipment in the specific channel.

 In other words, if we consider a so-called new generation Wifi equipment, including the new access mode, this equipment will not necessarily have to change radio frequency channel.

 In this way, it is possible to "clean" a radio frequency channel, forcing previous generation Wi-Fi equipment to change channels.

 According to a particular aspect of the invention, the step of generating a decoy signal implements the following substeps:

generating a random signal and inserting null elements in the random signal, so as to obtain a signal having pulses; - Modification of the power and / or the bandwidth of the pulses, delivering the decoy signal.

 In this way, a signal is constructed that has a set of pulses that can be grouped into bursts, which, by its structure, resembles a "true" radar signal, as defined by the regulators. However, the power and / or the bandwidth of at least one pulse can be varied, so that the equipment receiving this decoy signal can detect that it is not a true radar signal, but an "imitation" of a radar signal.

 According to a first particular characteristic, such a decoy signal may have a bandwidth of less than 10 MHz.

 In this way, it has a bandwidth less than the bandwidth of a Wifi signal according to the 802.11a standard. For example, the bandwidth of such a decoy signal is between 5MHz and 10MHz, while that of a Wifi signal is at least

20MHz (possibly 40MHz, 60MHz, 80MHz or more), and that of a true radar signal is strictly less than 5MHz.

 It is noted that such a decoy signal can advantageously be generated by reusing most elements of a conventional Wifi transmitter.

 However, because it has a bandwidth of less than 10MHz, this decoy signal can not be confused with a conventional Wifi signal.

 According to a second particular characteristic, such a decoy signal may have a predetermined duration, greater than a first threshold established for a dynamic frequency selection type mechanism to be triggered in at least second equipment emitting in the channel, and less than one second predetermined threshold.

 In this way, the decoy signal is long enough for a DFS-like mechanism (or equivalent recognized functionality) to fire, but not long enough to "decoy" the radars. Indeed, it seeks to emit the decoy signal for the shortest possible time. Radars receiving such a decoy signal thus detect that this signal is not a real radar signal, which avoids scrambling.

 According to a third particular characteristic, the decoy signal comprises at least one signaling information indicating that the signal is a decoy.

 For example, this signaling information is present in a specific field of the decoy signal, dedicated to the signaling of a decoy.

In this way, the different equipment emitting in the same radiofrequency channel can quickly recognize a decoy signal, and adapt accordingly their behaviour. In particular, if these devices detect that the received signal is a "real" radar signal, and not a decoy, they can quickly change radio frequency channel or stop transmitting.

 According to a fourth particular characteristic, the decoy signal is generated from a specific sequence known from the second equipment emitting in the channel.

 In this way again, the different equipment emitting in the same radiofrequency channel can quickly recognize a decoy signal, and adapt their behavior accordingly.

 Of course, these different particular characteristics are not necessarily cumulative, and may constitute variants, implemented independently of one another.

 According to another variant embodiment, the management method comprises a step of issuing a warning signal, implemented prior to the decoy signal transmission step.

 Such a warning signal makes it possible in particular to inform the second equipment emitting in the channel of the emission of a decoy signal.

 Again, this variant allows different equipment transmitting in the same radio frequency channel to quickly recognize a decoy signal, and adapt accordingly their behavior.

 In particular, the step of transmitting the decoy signal is implemented periodically and / or when assigning, to new equipment, a frequency resource corresponding to the channel concerned.

 In this way, it is possible to regularly monitor a particular channel, and to force certain equipment transmitting in this channel, or wishing to transmit in this channel, to change the transmission channel. This makes it possible, for example, to "clean" a radio frequency channel by forcing all the old generation equipment to change the radio frequency channel.

 Another aspect of the invention relates to a computer program product comprising instructions adapted to the implementation of the management method described above, when the program is executed by a processor. Such a program can use any programming language.

In particular, the method according to the invention can be implemented in various ways, in particular in cabled form or in software form. In another embodiment, the invention relates to a first device comprising:

 means for generating a signal having a particular radar-type structure, called a decoy signal, intended to modify the behavior of at least a second equipment transmitting in a radiofrequency channel allocated to said equipment;

 Means for emitting the decoy signal in the channel.

 Such a first piece of equipment is advantageously of a second type, called a new generation type, capable of transmitting in a wider frequency band than an equipment of a first type, referred to as "old generation", and makes it possible to generate a decoy signal. intended to modify the behavior of at least one second equipment (first or second type) transmitting in the radio frequency channel allocated to the equipment of the second type.

 Such equipment is particularly suitable for implementing the management method described above, and in particular the step of emitting a decoy signal in the radio frequency channel. This is for example an access point or a station of a set of basic services, in the case of Wifï transmission.

 This equipment may of course include the various features relating to the management method according to the invention. Thus, the characteristics and advantages of this equipment are the same as those of the management method, and are not detailed further.

 The invention also relates to a decoy signal intended to modify the behavior of at least one equipment emitting in a radiofrequency channel, generated according to the management method described above.

 Such a signal according to the invention has a particular structure of the radar type, as described above.

 In particular, such a decoy signal has pulses, possibly grouped in bursts, whose width and / or power have been modified so as to have a structure similar to that of a radar signal, without being completely identical to that of a radar signal.

 Such a decoy signal may of course include the various characteristics relating to the management method according to the invention, such as for example a predetermined duration, and / or a field dedicated to the signaling of a decoy, etc.

4. List of figures Other features and advantages of the invention will appear more clearly on reading the following description of a particular embodiment, given as a simple illustrative and nonlimiting example, and the appended drawings, among which:

 Figure 1 shows the main steps implemented by the management method according to a particular embodiment of the invention;

 FIG. 2 illustrates an example of a transmission scheme implemented in a Wifi equipment for the generation of a decoy signal according to a particular embodiment of the invention;

 FIG. 3 illustrates an example of a decoy signal according to a particular embodiment of the invention;

 FIG. 4 shows the structure of a device implementing a frequency resource management technique according to a particular embodiment of the invention.

 5. Description of an embodiment of the invention

 5.1 General principle

 The general principle of the invention is based on the generation and emission of a signal having a particular radar-type structure, known equipment emitting in a specific radio frequency channel, used to "lure" some of these equipment and force them to change channels.

 The use of a decoy signal having a radar type structure according to the invention allows in particular to trigger a dynamic frequency selection type mechanism (DFS or equivalent recognized mechanism). The activation of such a mechanism makes it possible to use equipment operating on radiofrequency channels in the 5GHz band having a width greater than 20MHz, for example equal to 40MHz (corresponding to the aggregation of two channels of 20MHz), 60MHz (corresponding to the aggregation of three channels of 20MHz), 80MHz (corresponding to the aggregation of four channels of 20MHz), etc.

 A known mechanism is thus used for a new purpose, to "clean" some radio frequency channels around 5GHz, forcing certain equipment emitting in such channels to change channels or frequency bands within this channel, or to interrupt their transmissions. It is recalled to this effect that the DFS mechanism is initially provided for an equipment to change channel during the detection of a radar signal, in order to protect this radar signal.

We seek in particular to: 1. keep in a specific channel only equipment of a second type, also referred to as new generation equipment, as defined in a future standard such as the 802.1 lake standard, and

 2. Require equipment of a first type, also called old generation equipment, as defined in the 802.11a or 802.1 In for example, to change radio frequency channel.

 FIG. 1 illustrates in particular the main steps implemented by the frequency resource management technique according to the invention.

 More specifically, this management technique of a frequency resource corresponding to a channel allocated to at least one equipment, comprises:

 a generation step 11, by a first equipment, of a decoy signal having a particular radar-type structure, intended to modify the behavior of at least one second equipment emitting in the channel;

a transmission step 12, by the first equipment, of the decoy signal in the channel.

 It is noted that several decoy signals can be transmitted in the same radio frequency channel, in order to clean a band of variable width.

 In addition, several radio frequency channels can be "cleaned" according to the invention, by emitting one or more decoy signals on each channel to be cleaned.

 5.2 Example of implementation of the invention

 A particular embodiment of the invention is described below, according to which the different steps of generation 11 of a decoy signal and of emitting 12 of the decoy signal are implemented by a first equipment transmitting in a radio frequency channel ( that is to say, already emitting in the channel or wishing to emit in the channel), and make it possible to force at least a second piece of equipment, transmitting in this same radio frequency channel (that is to say, transmitting already in the channel or wishing to emit in the channel) and located in the scope of the first equipment, to change channels.

 In other words, the first equipment emits a decoy signal having a particular structure of the radar type, and the method according to the invention implements a management of at least a second equipment according to the decoy signal.

For example, the first device is an APl access point of a first set of basic services BSS1, and the second or second devices are AP2, AP3, AP4 access points of a second set of basic services. BSS2, a third set of basic services BSS3 or a fourth set of basic services BSS4 respectively.

 The purpose of the invention according to this particular embodiment is then to force the sets of basic services BSS2, BSS3, BSS4 whose access points AP2, AP3 and

AP4 are located within the range of the access point AP1 of the BSS1 emitting the decoy signal, to change channels, if these basic service sets use the same channel as the BSSI.

 This is based on the DFS mechanism that is implemented by all Wifi systems in the 5GHz band.

 Thus, according to this particular embodiment:

 the access point AP1 of the BSS1 emits a decoy signal having the same properties as one of the types of radar signals to be detected by the DFS mechanism, as described hereinafter. In other words, this lure signal assimilated "radar" has the same temporal characteristics, and possibly spectral, a real radar signal conventionally detected by the DFS mechanism, and thus allows to activate the DFS mechanism of the equipment present in the channel;

 the access points AP2, AP3 and AP4 of the adjacent BSS2, BSS3 and BSS4, situated within the range of the access point AP1 of the BSS1, listen to the channel and detect the decoy signal coming from the access point AP1 of the BSSl as if it were a radar. The DFS mechanism starts and the adjacent BSS2, BSS3, and BSS4 modify their behavior. For example, adjacent BSS2, BSS3, and BSS4 perform a channel change. According to another example, the decoy signal is understood and detected by the new generation Wi-Fi equipment as a decoy signal, and these devices do not change channels.

 The duration of transmission of the signal deceived by the access point AP1 of the BSS1 can in particular be determined as a function of the time required for the detection of this decoy signal by the adjacent BSS2, BSS3 and BSS4, and the activation of the DFS mechanism.

 In particular, this duration must be greater than a first threshold set for the DFS mechanism to be triggered in the access points AP2, AP3 and AP4, and below a second predetermined threshold set so that the radar devices do not consider this signal lure like a real radar signal.

For example, this transmission can be done at the start (ie at launch) of the BSSl and also during operation to guard against the arrival of new BSS in the channel. Thus, the emission of the decoy signal can be implemented periodically, for example every half hour, and / or when assigning, to a new equipment, a frequency resource corresponding to the channel.

 Of course, the decoy signal can be emitted by the access point AP1 of the BSS1 as well as by the stations of the BSS1 concerned, in order to extend the zone which will be "cleaned", or only by a station of the BSSl. concerned.

 It is thus considered that certain BSSs incorporating the invention are capable of discriminating between a "true" radar signal and a decoy radar signal generated by an adjacent BSS. In particular, it is considered that BSSs implementing a standard in which such a mechanism is integrated can distinguish the "true" radar signals from

"False" radar signals.

 Several solutions are possible to wait for this result.

 Thus, according to a first example, the decoy signal comprises at least one signaling information indicating that said signal is a decoy. In this case, the decoy signal may be preceded by a specific header, in which a field is dedicated to the signaling of a decoy signal (PLCP header of the physical layer for "Physical Layer

Convergence Protocol "for example). In another example, the beacon frame (or

"Beacon") of the access point of a BSS which will emit the decoy signal can inform a new field that informs that a decoy signal will be emitted (for example a field named "information element").

 In a second example, the decoy signal is generated from a specific sequence known from adjacent BSSs. According to this example, the random signal used to generate the decoy signal may be a sequence known by all the BSSs that implement the invention. Thus, each BSS that receives a signal having a radar-like structure can correlate the received signal with the known signal to separate "true" radar signals from "false" radar signals (decoys).

 According to a third example, a warning signal is emitted before the decoy signal transmission step, informing the adjacent BSS of the emission of a decoy signal.

According to a fourth example, in the case where the bandwidth of the signals having a radar-type structure has no impact on the DFS detection mechanisms, it is possible to choose a bandwidth for the decoy signal different from conventional radar signals (for example by choosing a bandwidth for decoy signal of 10 or 20MHz, as in Wifi) to distinguish the "real" radar signals from "false" radar signals.

 If we consider that the equipment implementing a standard in which this mechanism is defined can differentiate a "real" radar signal from a decoy, these so-called new generation devices can react to the reception of a decoy signal in a certain way. different equipment implementing the standards 802.11a, 802.1 In, etc., called old generation (still called "legacy").

 Specifically, so-called old generation equipment will automatically change channels, when the DFS mechanism will start. In other words, upon receipt of the decoy signal by a legacy equipment, a new channel will be allocated to this equipment.

 The so-called new generation equipment implementing the standard can for their part:

 - change channels by letting the DFS mechanism work;

 - either stay on the same channel to share it with the BSS emitting the decoy signal.

 It is thus considered that new generation equipment "understands" that the signal received is a decoy signal. These devices are not necessarily forced to change channels, since they are able to understand the new access mode of the equipment emitting the decoy signal.

 In other words, upon receipt of the decoy signal by a new generation equipment, the equipment can detect that the received signal is a decoy, and decide to change channel or to stay in the channel that has been allocated.

 In this way, it is possible to "clean" part of the band, forcing old generation equipment to change channels. This gives a part of the band (80MHz for example) used only by new generation BSS and operating at very high speed.

 Since only BSSs implementing the standard are present on this part of the band, since legacy BSSs have changed channels, no retrograde compatibility is needed. The problem of retrograde compatibility that can occur in a context of overlapping ("overlapping") BSS is resolved.

Moreover, the BSS emitting the decoy signal can use in this part of the band an access mode only understood by new Wifi generations or an advanced "greenfield" mode, as defined in the IEEE 802.1 In standard for example. Thus, in this part of the band, the new generation BSSs can use the "greenfield" mode, which is a much more efficient mode of operation than the current operating modes, but which is not compatible with the existing modes, and so with old generation equipment.

 It is thus possible to reserve part of the band for advanced modes of high-speed operation (new generation Wifi operating in a greenfield mode for example). It is even possible to define this part of the band for an entire territory.

 5.3 Generation of the lure signal

 A) General principle

 An example of implementation of the decoy signal generation step 11 is described in more detail below.

 Specifically, it is recalled that the decoy signal obtained must have the same temporal and spectral characteristics as a real radar signal, so that the DFS mechanism is triggered, but must be sufficiently different from a real radar signal to prevent radar devices be lured too.

 It is thus sought to obtain a decoy signal having a width less than that of a Wifi signal (typically of the order of 20 or 40 MHz), and greater than that of a real radar signal (typically strictly less than 5 MHz). For example, it is desired to obtain a decoy signal having a bandwidth of between 5 and 10 MHz.

 In addition, it seeks to obtain a decoy signal having a transmission structure in the form of pulses (English "tap"). Indeed, the radar signals are conventionally formed of a signal for a duration ranging from 1 to 20 μs (pulse), followed by a silence time ranging from 200 to 1500 μs.

 To generate such a decoy signal, the following steps are implemented according to this example:

 Generating a random signal and inserting null elements in the random signal, so as to obtain a signal having pulses;

 - Modification of the power and / or the width of the pulses, delivering the decoy signal.

 B) Recall on the structure of the radar signals

As indicated above, it is sought according to the invention to generate a decoy signal having the same properties as one of the types of radar signals to be detected by the DFS mechanism. To this end, a "true" radar signal is formed of a series of pulses, taking the form of pulses of pulses. The main characteristics of these signals are defined by different regulatory bodies:

 - pulse width;

 - Delay between each pulse, also called pulse repetition interval (or PRJ for "Pulse Repetition Interval" in English), or frequency between each pulse, also called pulse repetition frequency (or PRF for "Pulse Repetition Frequency" in English). );

- total number of pulses;

 - amplitude of the pulses;

 - modulation of each pulse, if modulation there is.

 Various waveforms can be defined according to geographical areas by the different regulatory bodies, such as the Federal Communications Commission (FCC) in the United States, or the European Telecommunications Standards Institute (FCC). ETSI for

European Telecommunications Standards Institute) in Europe.

 For example, the FCC has defined six radar signals triggering the DFS mechanism, numbered from 1 to 6. These signals are more precisely defined in the "Federal Communications Commission FCC 06-96, Revision of Parts 2 and 15 of the Commission" standard. 's Unlicensed National Information Infrastructure (U-NII) devices in the 5 GHz band -ET Docket No. 03-122', and their features are recalled in Appendix A, which forms an integral part of this specification.

 ETSI has also defined six radar signals triggering the DFS mechanism, numbered from 1 to 6. These signals are more precisely defined in EN 301 893 v1.3.1, and their characteristics are recalled in Annex A.

 It is recalled that two frequency subbands are currently defined in Europe for the transmission of radar signals:

 - 5150 to 5350 MHz;

 - 5470 to 5725 MHz.

 The various regulatory bodies also define a set of constraints that these signals must respect for a DFS mechanism to be triggered. These constraints are recalled in Appendix B, which forms an integral part of the present description.

C) Example of generating a lure signal FIG. 2 illustrates more precisely an example of a transmission scheme implemented in a Wifi equipment for the generation of a decoy signal according to the invention. We place ourselves in the context of a Wifi equipment emitting in a frequency channel located around 5GHz.

 Note that this transmission scheme for the physical layer reuses, as much as possible, the conventional WiFi transmission channel, in order to limit the costs associated with the generation of the decoy signal.

 According to the example illustrated in FIG. 2, the transmission diagram comprises:

 A digital processing module 21;

 A digital / analog conversion module 22;

 A power control and amplification module 23; and

A signal conditioning filter module 24 of the signal on the frequency band used, for example on 20/40 MHz channels.

 The digital processing module 21 conventionally comprises channel coding sub-modules 211, binary conversion to M-ary or "mapping" 212, and OFDM modulation 213.

 The conventional WiFi transmission scheme, takes as input to the digital processing module 21 a binary signal to be transmitted, originating from the Media Access Control (MAC) layer, and delivers in output of the formatting filtering module 24 a multicarrier signal type Wifi.

 In the case of the generation of a decoy signal, the modules of the conventional Wi-Fi emission scheme are used as much as possible. Thus, compared to the conventional wireless transmission scheme, only modifications of the incoming signal (pulses) and possibly power control and amplification modules 23 and shaping filtering 24 are necessary. In addition, the digital processing module 21 may be reduced to a simple "mapping" 212.

 More precisely, a random signal replaces the binary signal at the input of the digital processing module 21.

According to the invention, sets of zeros are inserted in this random signal in order to model the decoy signal, which must be in the form of bursts (burst) of pulses. The signal at the input of the digital processing module 21 is thus formed of a random signal for a duration corresponding to the duration of a burst of pulses, followed by zeros for a duration corresponding to the interval between several pulse bursts. . The power control and amplification modules 23 and shaping filtering 24 are optionally modified, so as to allow a modification of the power and / or the width of the pulses, delivering the decoy signal.

 More precisely, the power control and amplification module 23 can modify the amplitude and / or the power of the signals according to the different equipment, so that the power of the decoy signal is high enough for the DFS mechanism to trigger in the coverage area of a BSS and can detect the decoy signal.

 The shaping filtering module 24 can modify the coefficients of the shaping filters in order to respect the bandwidth of the real radar signals (1 MHz, 5 MHz). This last constraint is not always necessary, given certain DFS mechanisms that are triggered as soon as a signal with pulses and sufficient power is detected, regardless of its bandwidth.

 FIG. 3 illustrates an example of a decoy signal obtained according to the invention, aimed at "imitating" the radar signal numbered 2 according to the FCC.

 According to this example, the decoy signal is formed of thirty bursts R1 to R30, each comprising twenty-three to twenty-nine pulses I. Each pulse has for example a duration of 1 to 5 μs, and the repetition interval of the pulses PRI is of the order of 150 to 230 μs.

 According to this example, the bursts are not necessarily identical to each other. In particular, in order to differentiate from the radar signal numbered 2 according to the FCC, the decoy signal pulses are modulated according to a different modulation of the radar signal pulses. For example, the pulses of the "true" radar signal are modulated by a single carrier while the decoy signal pulses can be modulated according to a phase or amplitude modulation, which makes it possible to detect that the signal is a decoy.

 Finally, we note that the proposed solution does not disturb existing radars.

Indeed, the radars function classically by emitting a signal and then listening to the response of this signal, corresponding to the reflections of this signal on the various obstacles. It is therefore not possible for a decoy signal ("false" radar signal) according to the invention to be understood by a radar as being its own. The jamming of radars by the emission of a false radar signal is therefore not possible, except in a very unlikely case that can occur when the "false" radar signal and the "true" radar signal are transmitted exactly at the same time. moment. However, this situation is unlikely for several reasons.

First, the radars emit a radar signal for a certain duration, under form of gusts. They do not stop broadcasting and listening to the channel. When a radar is active, it transmits and listens to a specific channel. As the DFS mechanism is triggered for a device (access point for example) wishing to transmit a decoy signal in this specific channel, this equipment detects the presence of a "real" radar signal, and will not interfere with the radar signal emitting a decoy signal, but instead change channel.

 For more protection, it is possible to reserve a channel listening time in search of radar (DFS mechanism) more refined (longer), before allowing a device to transmit a decoy signal on the channel.

 In addition, the only case where a scrambling of a real radar signal could occur corresponds to the case where the decoy signal is transmitted at the same time that a radar system initiates its first transmission (first burst). In this case, it could indeed be considered that the decoy signal scrambles the true radar signal during the period of time corresponding to its transmission, which is short at the scale of a radar signal frame, since the decoy signal is emitted only for the time necessary to activate the DFS mechanism on the BSS range. Moreover, this "scrambling" corresponds to the interference generated by any Wifi equipment equipped with the DFS mechanism. Indeed, the radar signal is always scrambled while the DFS mechanism detects the radar signal.

 In conclusion, the potential interference of a real radar signal is not greater according to the proposed solution than the interference generated by any Wifi equipment, even equipped with the DFS mechanism.

 5.4 Structure of equipment

 Finally, in connection with FIG. 4, the simplified structure of a device implementing a technique for managing the frequency resources according to the particular embodiment described above is presented. Such equipment is for example a so-called new generation equipment.

 Such equipment comprises a memory 41 comprising a buffer memory, a processing unit 42, equipped for example with a microprocessor μP, and driven by the computer program 43, implementing the management method according to the invention.

At initialization, the code instructions of the computer program 43 are for example loaded into a RAM before being executed by the processor of the processing unit 42. The processing unit 42 receives as input a signal random and zeros to model gusts. The microprocessor of the processing unit 42 implements the steps of the management method described above, according to the instructions of the computer program 43, to generate a decoy signal and transmit this signal in the channel allocated to the equipment.

For this, the equipment comprises, in addition to the buffer memory 41, means for generating a decoy signal having a particular structure of radar type, intended to modify the behavior of at least one other equipment transmitting in the same radio frequency channel, and means for emitting the decoy signal in the channel. These means are controlled by the microprocessor of the processing unit 42.

Appendix A - Safety Signals Recalls

 1) FCC Radar Signals

 The radar signals referenced 1 to 4 according to the FCC have the following characteristics:

 The radar signal referenced 5 according to the FCC, also called "long wave waveform" or "Long Duration Waveform" has a duration of 12 seconds. This signal is divided into n equal time intervals, where n is the number of bursts. Each burst therefore corresponds to a distinct time interval, and the bursts are not identical to each other (the width, the modulation, the number of pulses that can vary from one burst to another). Within the same burst, the pulses are of the same width, undergo the same modulation, but the interval between two pulses may be different and the first pulse occurs at a random time in the time interval corresponding to the burst.

 This radar signal referenced 5 has the following characteristics:

 The radar signal referenced 6 according to the FCC, also called "frequency hopping radar" or "Frequency Hopping Radar", covers a frequency band of 5250 to 5724 MHz, formed of 475 channels of width IMHz. The radar switches from one channel to another to browse the 475 channels in random order, without using the same channel twice.

 This radar signal referenced 6 has the following characteristics:

 2) Radar signals defined by EN 301 893 v 1.3.1

 The radar signals referenced 1 to 6 according to the standard EN 301 893 v1.3.1 have the following characteristics:

Appendix B - DFS Requirements Recalls

 The various regulatory bodies (FCC, ETSI, etc.) also define a set of constraints that radar signals must respect in order for a DFS mechanism to be triggered. These constraints are recalled below:

Claims

 A method of managing a frequency resource corresponding to a channel allocated to at least one piece of equipment, said first piece of equipment,

characterized in that it comprises:

 - A generation step (11), said first equipment, a signal having a particular radar-type structure, said decoy signal, for modifying the behavior of at least a second equipment transmitting in said channel;

 - A transmission step (12), said first equipment, said decoy signal in said channel.

 2. Management method according to claim 1, characterized in that said generating step implements the following substeps:

 Generating a random signal and inserting null elements in said random signal, so as to obtain a signal having pulses;

 Modifying (23, 24) the power and / or the bandwidth of said pulses, delivering said decoy signal.

 3. Management method according to claim 1, characterized in that said decoy signal has a bandwidth of less than 10MHz.

 4. Management method according to claim 1, characterized in that said decoy signal has a predetermined duration, greater than a first threshold set for a dynamic frequency selection type mechanism is triggered in at least said second equipment emitting in the channel, and less than a second predetermined threshold.

 5. Management method according to claim 1, characterized in that said decoy signal comprises at least one signaling information indicating that said signal is a decoy.

 6. Management method according to claim 1, characterized in that said decoy signal is generated from a specific, known sequence of said at least one second equipment transmitting in the channel.

7. Management method according to claim 1, characterized in that it comprises a step of transmitting a warning signal prior to said step of transmitting the decoy signal, informing said at least one second equipment transmitting in the channel of the emission of a lure signal.

8. Management method according to claim 1, characterized in that said at least one second equipment is an equipment of a first type, called old generation, capable of transmitting in a frequency band narrower than a second type of equipment, said new generation,

and in that said method comprises:

 a step of receiving said decoy signal by said first type equipment, and

a step of changing the channel allocated to said first type of equipment.

9. Management method according to claim 1, characterized in that said at least one second piece of equipment is a second type of equipment, said new generation, capable of transmitting in a frequency band wider than a piece of equipment. a first type, called old generation,

and in that said method comprises:

 a step of receiving said decoy signal by said second type of equipment,

a step of detecting that the received signal is a decoy signal, and

 - A decision step of maintaining or not the channel allocated to said second type of equipment.

 10. Management method according to claim 1, characterized in that said step of transmitting the decoy signal is implemented periodically and / or when assigning, to a new equipment, a corresponding frequency resource audit channel.

11. Computer program comprising instructions for implementing the management method according to claim 1 when said program is executed by a processor.

 12. Equipment of a second type, said new generation, capable of transmitting in a frequency band wider than a first type of equipment, called old generation, characterized in that it comprises:

 means for generating (11) a signal having a particular radar-like structure, called a decoy signal, intended to modify the behavior of at least one other equipment transmitting in a radiofrequency channel allocated to said second type of equipment;

 - Transmitting means (12) of said decoy signal in said channel.

 13. A decoy signal intended to modify the behavior of at least one equipment emitting in a radiofrequency channel, generated according to the management method of claim 1, characterized in that it has a particular structure of radar type.