FR3067556A1 - WIFI DIAGNOSTIC METHOD AND ASSOCIATED WIFI STATION - Google Patents

Abstract

The present invention relates to a WiFi access point (AP) of a basic service set comprising at least one station associated with the access point. It comprises: - a means (WiFi_CHIP, PIL) for acquiring a level (RSSI) of received WiFi signal from at least one station associated with the access point with the identifier of the station and a physical data rate (DataRate, MCS). in the downstream direction, - means (μP) for detecting a lack of correlation between the received WiFi signal level and the physical rate and deciding on scrambling of the cell.

Description

WiFi diagnostic method and associated WiFi station

The present invention relates to the field of telecommunications. Within this field, the invention relates more particularly to WiFi networks and to domestic or public gateways comprising an access point to a WiFi network.

A WiFi network notably uses wireless transmission technology based on the radio network standard IEEE 802.11 and its evolutions commonly grouped under the name WiFi (for “Wireless Fidelity”).

A function of a gateway is to provide the interface between the client terminal, later called a station, and a broadband access network, most often fixed, for example of the ADSL type for a private gateway. To this end, the gateway includes at least one WiFi access point to the broadband network. A gateway also provides modem and router functions. The access point is set on one of the different WiFi channels of the band considered (2.4GHz, 5GHz, etc.). The channel can be 20MHz, 40MHz, 80MHz or 160MHz.

A set of basic service (“Basic Service Set” according to English terminology) is formed by an access point (“Access Point” according to English terminology) and stations associated with this access point, that is to say ie the stations located in the WiFi cell or coverage area of this access point. These stations are client terminals.

Within the same BSS set of stations of a wireless radio system illustrated in FIG. 1, conforming to the basic specifications of the IEEE 802.11 standard defined in the document IEEE 802.11-2016, the access point AP and the stations STA1, STA2 associated with it exchange information on the same frequency band and the same channels.

Given that access to the WiFi channel is based on shared access it requires an access protocol, the most common is the collision avoidance access protocol CSMA / CA ("Carrier Sense Multiple Access-Collision Avoidance") according to English terminology), as described in the IEEE 802.11-2016 standard, paragraph 10.2 "MAC architecture", 10.2.2 "DCF" [1]. Its operation illustrated in Figure 2 is as follows.

Each station, access point or client terminal that has information to transmit competes for access to the channel during the Con_Wd contention phases. The station listens to the channel during this contention phase. If no signal is detected during a predefined waiting time specific to each station and of random duration Backoff preceded by a fixed duration DEFS, the station can start transmitting TRA data on the channel at the end of its countdown of time.

This mechanism is based on the CCA (Clear Channel Assessment) function which, on each station, indicates whether the channel is busy or free. The CCA threshold corresponds to a power threshold. If the received signal is higher than this threshold the channel is occupied otherwise the channel is free. These thresholds are set by the IEEE 802.11 standards.

A beacon (“Beacon” according to English terminology) is a management frame (for example according to the IEEE 802.11 standards) containing all the information of the communication network, in particular the information of the channel on which it is transmitted. These beacons are transmitted periodically by the access point on a channel, the operational channel.

They play a stamping role and allow synchronization of all the stations of the same channel attached to the same access point. These tags contain information making it possible to know the characteristics of the sets of basic services offered by the access point, for example the identity of the access point (SSID, “.Service Set Identification” according to English terminology), the frequency band, bandwidth (20MHz, 40MHz, 80MHz, 160MHz), channel number in this frequency band, short / long guard interval, number of streams, ... , usable physical rates (“Supported Rates”).

Prior art

Before accessing the channel, the access point can perform a passive scan by means of listening to broadcasts or perform an active scan by means of an exchange of "probe request / response" frames, on the whole of the band for all the transmission channels, in order to recover the occupation of a channel on the different scanned channels. This occupation information can be obtained by a long-term measurement thanks to the CCA mechanism which makes it possible to calculate the time during which the channel is occupied and the time during which the channel is free. However, this measurement can be disrupted by hidden equipment, that is, stations or access points that can transmit without being heard by other stations or other access points.

With reference to FIG. 1, when two stations STA1 and STA2 are on either side of an access point AP and sufficiently distant from each other not to detect the transmission originating from the other station in the absence of activation of an RTS / CTS mechanism; we are talking about hidden stations. In this case the station STA1, respectively the station STA2, considers the channel as free and accesses the channel while the hidden station STA2, respectively STA1, can occupy the channel; there is then a collision. In the event that the devices collide but cannot see each other, we also speak of co-channel interference. This can happen in high density networks where the access points are not seen and send frames simultaneously. A station served by a first access point sees the superimposition of the signals of the first access point and a second access point.

Another case of collision illustrated in FIG. 3 occurs when the second station STA2 is served by a second access point AP2 different from the first access point API serving the first station STA1 and the transmissions from the second station STA2 to the second access point AP2 are received by the first station STA1 and exceed its sensitivity threshold but are not received by the first access point API. The second STA2 station is a jammer from the first STA1 station and remains hidden from the first API access point.

Consider the case where a third or more STA3 station is served by the first API access point. Even if this station STA3 does not receive communications from the second station STA2, communications from the third station STA3 with the first access point API are nevertheless slowed down due to the jammer STA2. In fact, by jamming the station STA1, the jammer slows down the transmissions in the downward direction between PLC and STA1. And since the transmission channel is unique, this slowing down causes a slowing down of the transmissions in the downward direction between PLC and ST A3.

The interference may be due to a device which is not WiFi and which impacts the first station STA1 as illustrated by FIG. 4 and more generally the whole cell as illustrated by FIG. 5. There are indeed various devices which generate signals in the 2.4 GHz or 5 GHz WiFi band and can disrupt WiFi communications. Examples include a microwave oven, a DECT telephone, a radio controlled flying object.

Another case of interference occurs when a neighboring AP2 access point is configured on a channel adjacent (+ -1, 2) to that of the API access point. Such a case can only occur in the 2.4 GHz band, some channels overlapping. There is then a degradation of the capacity of the channel. There is no longer channel sharing but interference from the adjacent channel. The impact is often greater than that observed when sharing the same channel between two access points.

A more or less comparable case of interference may occur in the 5 GHz band when a 40 MHz channel is interfered with by another 40 MHz or 20 MHz channel. The secondary channel of a 40 MHz channel can be disturbed by a 20 MHz channel for example.

Conventionally, a minimum power detection threshold is defined in the IEEE 802.11 standards. Thus, at the end of the listening phase, a channel is considered to be unoccupied if the measurement of the power of a signal received on this channel during this listening phase is less than a predefined threshold. In other words, a station must be able to detect that a transmission is in progress on this channel if the signal strength received exceeds this threshold. For the CSMA-CA access mechanism and for high speed transmission, this power detection threshold is fixed at -82dBm for a 20MHz channel [2].

The links between the equipment of the telecommunications network and the access points can be established by a wired link. Conventionally, this link is a copper pair on which an xDSL technique is based. Substantial investments are increasingly being made to replace the copper pair by deploying optical fiber. Fiber optics transforms the xDSL model according to which the access rates are lower than the speed of the local network RLD (Local Domestic Network or Home Nework according to English terminology) of the subscriber ie private network of the access point into a model according to which access rates are higher than the local network speed of the RLD subscriber. The fiber optic thus increases the capacity of fixed access networks tenfold and makes it possible to offer users very high speed access, above the Giga Bit.

RLD users have more and more varied mobile terminals (smartphones, tablets, game consoles, etc.) allowing them to connect via WiFi to the local network and activate applications that consume bandwidth and require speed.

As the spectral resource of the WiFi channel is limited, the greater the number of devices sharing the channel, the greater the probability of collisions between simultaneous transmissions. In addition to the problem of collisions due to hidden stations, there are interference problems due to neighboring access points or interference which may have its origin in the operation of a microwave oven, etc.

Collisions and interference degrade the flow performance of the entire cell. In fact, if a transmission is not acknowledged (due to a transmission error on the channel or a collision), the retransmission is carried out with a doubled backoff period.

When their display freezes, when the hourglass displayed turns endlessly, users of the RLD do not understand these difficulties and their frustration is all the greater since their substantial subscription is in return for a so-called very high speed access network.

Main features of the invention

The present invention provides a diagnostic method implemented by a WiFi access point comprising:

acquisition of a level of a WiFi signal received from at least one station associated with the access point with an identifier of the station and a physical transmission rate in the downward direction, detection of an absence of correlation between the level of the signal received and the physical rate to decide on cell interference.

The invention takes place in the context of at least one station associated with a WiFi access point. This access point can be both residential and located in a business. The station typically accesses the channel using a CSMA / CA mechanism to transmit its data to the access point if it determines that the channel is free. The station transmits its data with a power level which must be compatible with the requirements of the IEEE 802.11 standards. The access point that receives the transmitted data determines the level of WiFi signal received by evaluating the energy received in the transmission channel when receiving a frame. The acquisition of the RSSI level of received WiFi signal results from a measurement at the level of the physical layer. The time interval between two acquisitions of received WiFi signal levels can be a parameter which depends on the temporal sampling of the data. This setting can possibly be modified remotely via a maintenance application or locally by an authorized user of the access point.

Given the technical requirements of the IEEE802.il standards, the emission level by the station (uplink) is correlated with the physical transmission rate of the access point (downlink). The establishment of the diagnosis thus makes it possible to determine whether a jammer disturbs the cell and interferes the transmissions within this cell. From this knowledge, it is then possible to alert the user, to indicate to him which of his stations is directly scrambled and possibly to provide him with additional indications for him to intervene.

If the jammer is one of its terminals, it can move it relative to the access point and prevent this jammer from being a hidden station.

If the jammer is not one of these terminals, it may be household appliances.

By establishing a diagnosis of interference in the cell, the invention differs greatly from known techniques which give a list of WiFi access points in the environment of the access point with a mapping of the occupied channels. In addition, this diagnosis according to the invention is established on the sole local database at the access point. The diagnosis does not require any particular data transmission, nor any particular signaling. No overload (Overload according to English terminology) therefore accompanies the establishment of the diagnosis.

Station means any device capable of communicating with a WiFi access point, such as a laptop, a PDA type device (for "Personal Digital Assistant"), a Smart Phone, etc.

According to a particular embodiment, the method is such that the detection of an absence of correlation comprises the comparison over a given time interval of the level of WiFi signal received and of the physical speed with at least a pair of determined thresholds.

The pair of thresholds is determined for example during measurement campaigns carried out with a given access point and station arranged in a controlled environment. Activating and deactivating a jammer makes it possible to observe its impact on the evolution of physical throughput.

The establishment of the pair of thresholds after measurements carried out in the same environment for different access points and different stations makes it possible to take into account the variations due solely to the different equipment or to the fluctuations in signal power levels received for the same connection.

According to a particular embodiment, several stations being associated with the access point, the method is such that the access point determines which at least one of the stations is directly scrambled.

According to this mode, the method acquires over a given time window the downward physical bit rate of the different stations. If a station has a downward physical flow which collapses during a certain time interval included in the window, this station is directly scrambled. The process can inform the user by displaying the characteristics of this station (trademark, etc.).

According to a particular embodiment, the received WiFi signal level is further acquired with a bandwidth, and / or a guard interval and / or a number of spatial streams.

According to this mode, the method acquires not only the identifier associated with the transmitting station but also one or more additional parameters used to format the frames transmitted and received by the access point. Knowledge of these parameters such as band, guard interval, number of spatial flows is necessary depending on the performance of the access points or stations to determine exactly the correspondence between downward physical bit rate and expected received signal level and vice versa.

In addition, the invention relates to a WiFi access point of a basic service set comprising at least one station associated with the access point. The access point includes:

a means for acquiring a level of WiFi signal received from at least one station associated with the access point with the identifier of the station and a physical transmission rate in the downward direction,

- a means for detecting an absence of correlation between the level of WiFi signal received and the physical speed and deciding on interference of the cell.

List of Figures

Other characteristics and advantages of the invention will become apparent from the following description given with reference to the appended figures given by way of non-limiting example.

Figure 1 is a diagram of a BSS set of stations in a wireless radio system.

Figure 2 is a timing diagram illustrating the operation of the CSMA / CA collision avoidance access protocol.

FIG. 3 is a diagram of two BSS assemblies, the typology of which includes hidden stations with risk of collisions.

FIG. 4 is a diagram of a residential environment in which a BSS assembly is deployed comprising an access point and a station associated with jamming of this station by a non-WiFi jammer.

FIG. 5 is a diagram of a residential environment in which a BSS assembly is deployed comprising an access point and two stations associated with interference of the entire cell by a non-WiFi jammer.

FIG. 6 is a diagram of the simplified structure of a WiFi access point according to the invention,

Figure 7 is a diagram illustrating the composition of a physical frame

FIG. 8 is a diagram of a residence in which a first API access point, a second AP2 access point and two stations STA1 and STA2 are installed,

Figure 9 is a curve of the application throughput (Throughput) when the API access point only serves the station STA1.

Figure 10 is a curve of the application throughput (Throughput) when the API access point only serves the STA2 station.

FIG. 11 represents two application flow curves (Throughput) of the stations STA1 and STA2 respectively when the access point API serves these stations simultaneously and in the absence of interference,

FIG. 12 is a diagram of the residence in FIG. 8 when the station STA2 is directly scrambled by the access point AP2.

FIG. 13 represent two application flow curves (Throughput) of the stations STA1 and STA2 respectively when the access point API serves them simultaneously and in the presence of interference from the station STA2 due to the access point AP2.

FIG. 14 is a curve of the physical flow going down towards the station STA2.

FIG. 15 is a curve of the RSSI level of the WiFi signal received by the API access point relating to the station STA2.

FIG. 16 is a curve of the physical flow going down towards the station STA1.

FIG. 17 is a curve of the RSSI level of WiFi signal received by the API access point relating to the station STA1.

Figures 18 and 19 are curves of a quality indicator corresponding respectively to the results for station STA2 and station STA1 of the correlation between each pair (RSSI, physical flow) and the thresholds.

Description of particular embodiments

FIG. 6 is a diagram of a WiFi access point implementing a diagnostic method according to the invention. The AP WiFi access point includes: a transmit and receive antenna, a WiFi_CHIP WiFi chip, a PIL driver for the WiFi chip, a μΡ with MEM memories to implement the operating system and application App software. Activation of the App software application implements the following operations:

- acquisition over a given time interval of an RSSI level of a WiFi signal received from at least one station associated with the AP access point,

- detection over the time interval of a lack of correlation between the RSSI level of the received signal and a downward DataRate physical rate to decide on cell interference.

The RSSI level acquired is associated with a © MAC identifier of the transmitting station and associated with the physical DataRate transmission rate in the downward direction to this transmitting station. The identifier can be the MAC address of the station. In the absence of a correlation between the RSSI level of the received signal and the downward DataRate physical rate, it is decided that the cell is scrambled.

A WiFi access point includes different parameters, one of which identifies a WiFi cell, this parameter is known by the abbreviation SS1D (for "Service Set Identifier"). Each cell is differentiated by its SSID. Although several cells can be associated with the same access point, in the description which follows it is considered that an access point corresponds to a single cell and vice versa.

In operation, an access point regularly broadcasts a radio beacon frame to demonstrate its presence, this frame is known by the abbreviation Beacon. This frame contains the SSID configured for the access point.

When a station wants to establish a communication via a WiFi access point, it must first discover such an access point. This discovery is made either by passive listening by scanning the radio band to detect the presence of Beacon and therefore a gateway with nearby access point, or by an active search by probing the channels of the radio band by l 'transmission of a probe request frame. In the first case, the station can subsequently issue a "probe request" addressed to the detected access point using the SSID of this access point to obtain additional information not broadcast in the "beacon" tag. The SSID access point responds with a "probe response" frame indicating the gateway's transmission capabilities, in particular given the number of users already connected to the gateway. In the second case, the access point, if it exists, responds with a "probe response" frame.

In a second step, the station and the access point generally carry out mutual identification.

An association step is then necessary so that the station can send data via the access point, typically to a remote recipient.

At the end of the association, the station and the access point know their different configurable physical bit rates (DataRate, “MCS: Modulation and Coding Scheme”), the 2.4 GHz or 5 GHz operating band on which they can communicate , the channels accessible for this operating band, the number of streams accessible. Table 1 in Appendix A gives the correspondence between MCS and DataRate in accordance with the IEEE802.11-2016 standard.

The value of the DataRate physical speed of the downlink is normalized in TXVECTOR DATARATE defined in 15.2.2.3, 17.2.2.3 (or L_Datarate in Table 19-3) of the IEEE802.11-2016 standard.

The access point can measure the received WiFi signal level ("RSSI: Receive

Signal Strengh Indicator ") using the WiFi_CHIP chip (" wifi chipset ") at the antenna output for each physical PPDU frame received.

Figure 7 is a diagram of a PPDU physical frame at the physical layer. Such a physical frame comprises a PHY HDR header, a PSDU data field, a TAIL tail field and a PAD stuffing field. The PSDU data field is the so-called MAC MPDU frame. The MPDU frame includes a MAC HDR header, an MSDU data field and an FCS frame verification field. In general, the MAC HDR header of a so-called MAC frame includes the address of the transmitting station as specified in 9.3.2.1 of the IEEE802.il2016 standard in the case of a data frame or in 9.3.1 in the case of control frames such as in particular RTS, CTS, ACK.

The measurement of the received signal is carried out on the preamble and the value of the RRSI is a monotonic function of the received power normalized in RXVECTOR RSSI defined in 15.2.3.3 and 17.2.3.3 of the IEEE802.11-2016 standard.

When transmitting with the access point with which it is associated, the station 30 transmits with standardized power. This power cannot exceed 20 dBm at 2.4 GHz, 23 dBm on channels 36 to 64 (5 GHz) and 30 dBm on channels 100 to 140 (5 GHz). Thus, the power received by the access point is the transmitted power from which the propagation losses supposed to be proportional to the distance between the station and the access point must be subtracted.

Thus, there is a correspondence between the RSSI level of signal received and the DataRate physical rate (or MCS) that can be used for transmission. Table 19-23 reproduced in Appendix A is taken from the IEEE802.11-2016 standard. This table gives this correspondence for a station called ŒEE802. linen.

According to this table 19-23, if the received RSSI level is less than -79 dBm, the recommended MCS consists of a BPSK modulation with 1/2 coding efficiency for a channel width of 20MHz. In other words, if the MCS recommended in the downlink transmission consists of a BPSK modulation with a coding efficiency ’/ î then the expected received RSSI level must be greater than -82dBm. If it is below this threshold, then there is a problem with the uplink. If the MCS recommended in downlink transmission consists of 64QAM modulation with 2/3 coding efficiency for a channel width of 20MHz then the expected RSSI received level must be greater than -66dBm. If it is ever below this threshold, then there may be a problem with the uplink.

As the RSSI level is associated with the MAC address @MAC of the transmitting station, the access point has knowledge of the transmitting station of the measured WiFi signal.

The access point includes a PIL driver (WiFi) chip WiFi_CHIP which provides the application of the application layer either the value of RSSI or the value of SNR. When only the SNR is raised to the Appli application, the RSSI is recalculated using the value of the thermal noise power raised by the PIL pilot.

The thermal noise P _b expressed in dBm describes the imperfections of the components of the RF stages of a communication entity. This thermal noise P _b presents very different variations from one transmission mode considered to another as a function of the bandwidth B _w of transmission, the noise temperature T of the receiver and the spectral efficiency. The thermal noise P _b is often expressed as a function of a reference value P _o = —114dBm corresponding to a reference noise temperature T _o = 290K and to a transmission band B _w0 = 1MHz. The thermal noise contribution is given by:

P _b = 10 \ og (KTB _w ) + L _o = 10 log (Kr ₀ ) + 10 Iog (ξ) + 10 log (B _w ) + L _o

P _b = -114 (dBm) + 10 log ₁₀ (F _M , (MHz »+ NF + L ₀ (dBm)

P _b = —114 (dBm) + 10log ₁₀ (D) - 10 log ₁₀ (£ · //) + NF + L ₀ (dBm)

Eff = D / B _w with T the noise temperature of the communication entity, NF the noise factor (NF = 10log (T / T ₀ ), B _w the effective bandwidth of the transmission mode, L _o the losses cables,

K the Boltzmann constant and Eff the spectral efficiency of the transmission mode, D the transmission rate with a given target BER (QoS).

The RSSI value is expressed in dBm. The measurement can be performed at a given set rate. To be consistent with the evaluation of the SNR, the determination of the RSSI is usually made on the channel bandwidth (20MHz, 40MHz, ...).

According to the invention, the detection of a lack of correlation comprises the comparison of the RSSI level received and the downward DataRate physical throughput with at least a pair of determined thresholds.

According to one embodiment, the diagnostic method takes into account only one RSSI threshold taken equal by default to one of the thresholds given in the IEEE802.11-2016 standard, for example according to table 19-23 reproduced in Appendix A .

According to one embodiment, the threshold or thresholds are determined after measurements made according to a given configuration and in a controlled environment.

The operation of the access points and stations considered during the detailed measurements below complies with the IEEE802.1 ln standard. The given configuration includes a single stream and a 20 MHz band.

FIG. 8 illustrates a residence in which is installed a first API access point which defines a Cell cell, a second AP2 access point and two stations STA1 and STA2. The API access point serves STA1 and STA2 stations.

Measurements are made while the AP2 access point is inactive and then activated over a certain time period. The two mobiles are from different brands: STA2 = Sony Xperia Z3 compact, STAi = Samsung Galaxy Ace4.

The curve in Figure 9 gives the application throughput (Throughput) when the API access point serves only the STA1 station, the target throughput target rate is 30 Mb / s and the Measured throughput measured throughput of 28 Mb / s.

The curve in Figure 10 gives the application throughput (Throughput) when the API access point only serves the STA2 station, the target throughput target rate is 30 Mb / s and the Measured throughput measured throughput of 24 Mb / s

The difference in measured application rates is mainly explained by the fact that the STA2 station is further from the API access point than the STA1 station.

The curves in FIG. 11 respectively give the application throughputs (Throughput) when the API access point serves simultaneously the station STA1 and the station STA2 and in the absence of interference. For STA1 station the target throughput target is 30 Mb / s and the measured measured throughput of 26 Mb / s, for STA2 the target throughput target flow is 30 Mb / s and the measured measured throughput of 15 This figure 11 illustrates the peculiarity of the WiFi channel which performs only one transmission at a time unlike the channel of a mobile radio standard; there is time sharing of channel access between the two stations.

A local jamming phenomenon at the station STA2 occurs when the access point AP2 is active: the station STA2 undergoes jamming without the other equipment API, STA1 of its cell Cell not feeling the effects of it directly as illustrated by the figure 12.

The curves in FIG. 13 give the application throughputs of the stations STA1 and STA2 respectively when the access point API serves them simultaneously and in the presence of interference from the station STA2 due to the access point AP2. When the access point AP2 is active, not only does the application rate of the station STA2 collapse but also that of the station STA1 also collapses.

The API access point does not receive beacon frames from the AP2 jammer which shares the same channel. The AP2 access point directly scrambles only the STA2 station. The API access point detects an error rate in its transmissions with the STA2 station, for example in the absence of an acknowledgment frame (ACK: acknowledge) coming from the STA2 station when it sends a frame to it. Consequently, the API access point undertakes to dialogue with more robust modulations and occupies the channel ("airtime") longer, leaving less time for the other STA1 station in the cell to transmit. The station STA1 is therefore indirectly impacted because it has shorter access to the common medium.

The curve in FIG. 14 gives the physical bit rate descending towards the station STA2 and FIG. 15 gives the level RSSI of signal received by the access point API relating to the station STA2. When the STA2 station is directly scrambled, the downward physical bit rate collapses and the RSSI level changes without any apparent link with the scrambling windows.

The curve in FIG. 16 gives the physical bit rate descending towards the station STA1 and FIG. 17 gives the level RSSI of signal received by the access point API relating to the station STA1. The downward physical rate to station STA1 remains constant for the duration of the interference.

The communications between the API access point and the STA2 station occupy the channel much longer since this STA2 station is scrambled. Consequently, the time during which the station STA1 can access the channel is reduced and its application throughput collapses although its downward physical throughput remains constant in the absence of direct interference from this station STA1.

The detection of the decorrelation between the RSSI and the downward physical DataRate rate is based on the definition of RSSI thresholds corresponding to given physical rates. The measurements are used to define these sensitivity thresholds.

Thus, the following table gives examples of threshold values determined with respect to the 52 Mb / s (64 QAM 2/3), 13 Mb / s (QPSK 1/2) modulations following the previous measurements.

Threshold RSSI (dBm) Physical speed Mbits / s IF -84 52 S2 -89 13

FIGS. 18 and 19 represent quality indicators corresponding to the results respectively for the station STA2 and the station STA1 of the correlation between each pair (RSSI, physical throughput) and the thresholds. Thus, a flag is raised, ie an alarm is triggered only for the station STA2 when there is no correlation between the two values of the torque ie the quality indicator has a low value compared to a high value the rest of the time.

The determination of the thresholds must be made so as to avoid the effects of thresholds causing instability when the RSSI is close to the threshold value. In fact, taking into account the fluctuations in the flow rate, there can be non-correlation detections when there is no interference (false positive). These false detections can be avoided by applying a margin in dB relative to the defined thresholds or by making the RSSI / DataRate area airtight in a “no interference” situation from that with interference.

The measurements show that in some cases, the DataRate physical rate drops and an absence of correlation is detected (false positive) even though the transmission conditions are good (absence of interference). This type of situation can be avoided by running a rolling average over a number of samples of the quality indicator before raising the flag or over a number of samples of the DataRate physical throughput values.

Since RSSI levels are not always stable (variations can reach 8dB on certain points), the thresholds can be defined by type of modulation (64-QAM, QPSK, BPSK / HR / DSSS) instead of being defined by MCS. A larger margin than at MCS allows to take into account variations on measurements and threshold effects. For example, if the method acquires an RSSI> —64dBm then the expected MCS physical bit rate must consist of a 64QAM modulation with a 5/6 coding efficiency. If the modulation is I6QAM 3/4 or less, the method then considers that the cell is scrambled.

According to one embodiment, the value of the RSSI can be filtered to limit fluctuations. Like the RSSI, the DataRate physical throughput value can be filtered to limit fluctuations.

In the case of a configuration of one or more transmissions using a bandwidth greater than 20 MHz, a guard interval (GI) different from 800ns (specified in particular in TXVECTOR and RXVECTOR in Table 21-1 or Table 22-1 of the IEEE201.11-2016 standard) or of a number of spatial streams (ux) greater than one, the method takes these parameters into account (bandwidth, number of spatial streams, interval of guard) to determine the correspondence between the physical flow and the RSSI level in accordance with Table 1 and Table 21-25 or Table 22-22 from the standard 1EEE802.11-2016 reproduced in Annex A.

To increase the reliability of the diagnosis, the following indicators can be taken into account: list of stations connected, level of signal with which they are received by the access point, number of packets transmitted / received by the access point to a station , modulation speed with which frames are transmitted / received, number of retransmitted packets (information), information on neighboring SSIDs, "Capabilities" of the access point, measurement of the channel occupancy rate as a whole (all stations confused), measures the channel occupancy rate per station, checks that the stations in the cell do not occupy the channel too intensely, measures the frame re-transmission rate per station.

The simplified structure of an access point according to the embodiments described above is illustrated in FIG. 6. Such an access point comprises a WiFi chip connected to an antenna, a P1L pilot of the WiFi chip, a MEM memory comprising a buffer memory (RAM for example), a processing unit μΡ equipped for example with a microprocessor and controlled by the computer program to implement the diagnostic method according to the invention.

At initialization, the code instructions of the computer program are for example loaded into the buffer memory before being executed by the processor of the processing unit μΡ. The processing unit μΡ receives as input RSSI levels of a received WiFi signal, the address @MAC of the transmitting station, the downward physical bit rate and the thresholds S1_RRSI and Sl_DataRate / MCS. The microprocessor of the processing unit μΡ implements the steps of the diagnostic method described above, according to the instructions of the computer program.

Consequently, the invention also applies to a computer program (or its various modules), in particular a computer program on or in an information medium, suitable for implementing the invention. This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code such as in a partially compiled form, or in any other form desirable to implement a method according to the invention.

The information medium can be any entity or device capable of storing the program. For example, the support may include a storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or else a magnetic recording means, for example a floppy disk or a disc. hard.

Alternatively, the information medium can be an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the process in question.

On the other hand, the program can be translated into a transmissible form such as an electrical or optical signal, which can be routed via an electrical or optical cable, by radio or by other means. The program according to the invention can in particular be downloaded from a network of the Internet type.

The invention applies more particularly, but not only, to networks of the type

WIF1, i.e. compliant with one of the standards of the 802.1 lx group, or of the WP AN type (Wireless Personal Area Networks: Bluetooth, Infrared, Zigbee, ...). According to these standards, access to the radio channel is managed by the MAC layer.

[1] IEEE 802.11-2016, paragraph 10.2 “MAC architecture”, 10.2.2 “DCF” [2] IEEE802.1 ln-2009, paragraph 20.3.22.5.1 “CCA sensitivity in 20 MHz” (IEEE8O2.11-2016 , paragraph 19.3.19.5.3 “CCA sensitivity in 20 MHz”)

Annex A Table 1

MCS Spatial Modulated! we Codine Data rate tMbit / ï} index streams type missed ÎBMHzthânnei 40MHi SCO.nsGI fit »ns Lista. fit »ns. 0 1 BPSK "2 6.53 7.20 13.50 15.03 1 1 flEæ- I / 2 13.C3 14.40 27.00 33.03 2 3 BBS " 19.50 21.70 40.50 45 03 3 1 X6-QAM 1/2 26.00 28.33 54.03 E3.C3 ♦ 1 16-ΑΛΜ 3 / fi 39.00 43.33 81.C3 90.00: 5 1. M-.Q.UI 2/3 52.00 57.63 108.00 120.00 6 1 & WXI 3/4 58.50 65.00 121.50 135 "· 7 X AA® 5/6 65.03 72.20 135.00 150 ' 8 2 BPSK 1/2 13.03 14.40 27 " 30,": 9 ' 2 flesk 1/2 26.03 2S.SS 54 " 60.03 10 2 "SB 3/4 33.00 43.30 81 " 90.03 11 2 J5.QAM 1/2 52.C0 57.80 108.00 120.00 iis: 2 æasM 3/4 78.00 85,70 162 ' 130.03 13 2. 6 "BM mIT 104.00 315.50 216.03 24 0.03 " 2 M-OFTM; 3 / t 117.00 130.00 243.00 270.00 15 2. ΐ £ Ε · · χνι Η23ΗΙ || 130.00 144.40 270.00 330 03 16 3 BP5K " 19.50 21.70 40.53 45 03 17 3 < QPSK 1/2 39.00 ' 43.30 81.00 90,00 18 3 ace 3/4 5830 65.00 121.50 1 = 5.03 19 3 M 1/2 78.03 86.70 162 ' 183.03 20 3 "Smit 3 / fi 117.00 130.00 243.00 273.03 21 3 SfcffiffiL 2/3 156 ' 173.30 324.00 363.03 22 3 SfcSôB 3/4 175.50 195.00 364.50 405.00 23 3 Sfcûâtt: 5/6 195.00 216.70 405.00 450.00 24 4 BPSK 1/2 26.00 23.80 54.03 60.00 25 4 QPSK 1/2 52.00 57.60 103.03 120: ". 26 4 QESK 3/4 78.00 85.80 162.00 180.00 2? 4 16-OAM J / 2 104.00 115.60 216.00 240 ' 28 4 16-QAM " 156.00 173.20 324.00 360.00 29 4 fifcflffli 2/3 20S.03 231.20 432.00 480.00 " fi 64-am 3/4 234.00 260.00 485.00 540.00 31 fi - S " 260.00 288.80 540.00 600.00 32 1 BPSK 1/2 N / A N / A 6.50 7.20

Table 19-23 from the IEEE802.I1-2016 standard

Table 19-23 — Receiver minimum inpuï level sensitivîty

Modula lion R tii? (IR admire dmiiit-l lejwrjiui "IBt XonatljiKcul clinisiicl Li-ji-riiou KiB) Minimum seinint in (20 MIL di.nuitd (dBui) Minimum sensitit itv (40 MHz iimuifi sp.-icinst (DBm BPSK 12 M  32 -52 -79 QPSK 1 2 B " -79 -76 QPSK 34 11 27 -77 -74 16-QAM 12 <8 24 -74 -71 16-QAM 3 4 < .20 -70 MO 64-QAM 2 3 0 16 -es -63 64-QAM 3 4 -1 15 -65 -52 64-QAM 5 6 14 -A4 -61

Table 21-25 from the IEEES standard

Table 21-25 — Receiver minimum tnput level sensitivity

Modulatiou Missed (R) Minimum follow-up (20 MHz PPDV) (tlBm) Minimum "• miriurv (40 MHz PPDV) UiBinj Minimum tentirivin ISO MHz PPDV) (tlBinl Minimum "iisitn itv il60 MHz oi 80 + S0 .MHz PPDV) (dBinl BPSK Iffl; -S2 -79 -76 -73 QPSK 1 2 -76 -73 -70; QPSK 3 4 -77 -74 -71 -68 16-QAM 1 2 -71 ~ 6S -65 16-QAM 3B -70 -67 ..- 64. t> 4-QAM 2 3 -66 <-63 ~ E> < -57 64-Q, V.! 34 -65 -62 -59 -56 64-QAM 5'6 -64 -61 -58 -55 256-QAM 3'4 -59 -56 -53 -50 256-QAM 56 -57 -54 -51 -48

Table 22-22 from standard IEEE8O2.11-2016

Table 22-22 — Receiver minimum input ievel sensitivity

Modulation Missed (R) Minimum senûtiviry UlBin) 6or7 MHz (TYHT MODE_1) 12714 MHz (TVHT MODE 2C 1 oi 6 + 6 + ”MHz (TVHT MODE_2N> 24 28 MHz (TVHT MODE 4C o) 12 + 12 14 + 14 MHz (Tvirr MODEJ.V) 8 MHz if ht MODEJ) 16 MHz (TVHT MODESC) oi S-S3HÎZ (TVHT MODEJN) 32 MHz (ΤΛΉΤ MODE 4Ci oi 16-16 16-16 MHz (ΤΛΉΤ modesm BPSK 3β : -88 -85 -s: -S7 -S4 -81 QPSK M -85 -82. -79 -S4 -IF -78 QPSK 3ft -83 -80 -77 -S2 -79 -76 16-QAM " -80 -77 ’ -74 -79 -76 -73 16-QAM 3 ' -76 -73 ' -70 -75 -72 -69 64-QAM ace -72 -69 -66 -71 -68 -65 64-QAM 3 4 -71 -68 -65 -70 -67 • mH 64-QAM 56 -70 -67 -64 -69 · "66 -63 256-QAM 3.4 -65 -62 -59 -64 -61 ~ 5S 256-QAM 5Λ -63 -60 -57 -62 -59 -56

Claims (5)

1. Diagnostic method implemented by a WiFi access point comprising: acquisition of a level (RSSI) of a WiFi signal received from at least one station associated with the access point (AP) with an identifier (@MAC) of the station and a physical speed (DataRate, MCS) of downlink transmission, detection of an absence of correlation between the level (RSSI) of the received signal and the physical bit rate (DataRate, MCS) to decide on cell interference. 2. The diagnostic method as claimed in claim 1, in which the detection of a lack of correlation comprises the comparison over a given time interval of the level (RSSI) of received WiFi signal and of the physical speed (DataRate) with at least one pair. set thresholds. 3. Diagnostic method according to one of claims I and 2, according to which, several stations being associated with the access point, the access point determines which at least one of the stations is directly scrambled. 4. Diagnostic method according to one of claims 1 to 3, according to which, the level (RSSI) is further acquired with a bandwidth, and / or a guard interval and / or a number of spatial streams. 5. WiFi access point of a basic service set (BSS) comprising at least one station associated with the access point characterized in that it comprises: a means (WiFi_CHIP, PIL) for acquiring a level (RSSI) of WiFi signal received from at least one station associated with the access point with the station identifier and a physical bit rate (DataRate, MCS) of transmission in the downward direction, a means (μΡ) to detect a lack of correlation between the level of WiFi signal received and the physical speed and decide on cell interference.