FR3088793A1 - METHOD AND DEVICE FOR DETECTING A PORTABLE DEVICE FOR "HANDS-FREE" ACCESS TO A MOTOR VEHICLE - Google Patents

Abstract

The present invention relates to a method (100) for detecting a portable device (20) for “hands-free” access to a motor vehicle (30) carrying a detection device (10). To detect if the portable device is in a predetermined detection zone (Z1, Z2, Z3), the method comprises: • a determination (111) of a predefined noise level to be generated as a function of a power level d transmission of an interrogation message by the detection device intended for the portable device, • a generation (112) of noise at the level determined during the emission of the interrogation message, • a verification (113) if a message response from the portable device is received by the detection device. The portable device is detected in the detection area if a response message is received in response to the interrogation message.

Description

The present invention belongs to the field of “hands-free” access systems for a motor vehicle. In particular, the invention relates to a method and a device making it possible to detect whether a user is located in an area near or inside the vehicle.

A hands-free access system to a motor vehicle allows an authorized user to lock and / or unlock the doors of his vehicle or to start the vehicle without using a key. To do this, the vehicle identifies a portable device worn by the user, such as a badge or a remote control, when said portable device is detected in a predetermined area near or inside the vehicle. If the portable device is identified as being associated with the vehicle, then the vehicle automatically locks / unlocks its doors or starts on a command from the user, without the latter having to use a key.

Such a "hands-free" access system is known to those skilled in the art. It generally involves a detection device on board the vehicle, and a portable device such as a badge or a remote control worn by the user of the vehicle.

An identification procedure by wireless communication between the portable device and the detection device allows the user to be authenticated by the vehicle and to trigger the locking / unlocking of the doors or the starting of the vehicle.

The identification procedure is generally carried out by an exchange of messages between the detection device and the portable device over a radio link using electromagnetic waves whose frequencies are between 30 kHz and 300 kHz (LF or “Low” type radio waves Frequency "in English). The detection device first transmits an interrogation message, and if the portable device is located in an area close enough to receive the interrogation message, the portable device transmits in response a message containing its identifier.

It is advantageous to define several zones more or less distant from the vehicle, and to determine in which zone the portable device is located in order to adapt the behavior of the motor vehicle according to the position of the user. For this purpose, it is known for the detection device to estimate in which zone the portable device is located as a function of a level of received power ("Received Signal Strength Indicator" or RSSI in the Anglo-Saxon literature) of a message from the portable device. The stronger the RSSI, the more the portable device is located in an area close to the vehicle. Conversely, the lower the RSSI, the more the portable device is located in an area remote from the vehicle.

More and more portable devices, such as mobile phones, connected watches, etc. now have the Bluetooth® or Bluetooth Low Energy (BLE) communication standard. This Ultra High Frequency communication standard (UHF radio waves, or “Ultra High Frequency” in English, whose frequencies are between 300 MHz and 3 GHz), has the particular advantage of being universal and not require country-specific approval, as can be the case with current LF systems, the operating frequencies of which differ from country to country.

UHF signals have a greater range (up to 250 m for the BLE standard for example), but the RSSI measurement of a UHF signal is however unstable insofar as it varies significantly depending on the environment (humidity, obstacles, interference, etc.). It is then no longer possible to estimate with sufficient precision the position of the portable device relative to the vehicle when a UHF radio link is used instead of the LF radio link.

Patent application FR1558007 proposes a solution consisting in creating one or more “connectivity bubbles” by limiting the range of messages exchanged between the detection device and the portable device with one or more attenuation modules placed on the electrical track separating the communication module and antenna of the detection device. The attenuation module (s) must therefore make it possible to limit the range of UHF communications between the detection device and the portable device at distances ranging from a few centimeters to a few meters. Each attenuation module is associated with a predetermined area in or around the motor vehicle. The detection of the portable device in a given zone is then determined according to whether the detection device receives or not a response to a query message sent with the attenuation module associated with said zone.

However, it appears that the transmission power of an interrogation message by the detection device can vary significantly. For example, when the BLE standard is used, and when the portable device and the detection device are in connected mode, an automatic power control is operated between the portable device and the detection device. The transmitting power of the detection device can then be adjusted differently depending on the portable device. For example, if the portable device is a mobile telephone, the transmission power level of the detection device may be imposed by the mobile telephone in connected mode, and said transmission power level may vary depending on the model of mobile telephone, and as a function of the BLE standard management software layers installed on the mobile phone (the latter may notably vary depending on the version of the environment system installed on the mobile phone).

The size of a "connectivity bubble" associated with an attenuation module then becomes variable, and the estimation of the position of the portable device remains imprecise.

The present invention aims to remedy all or part of the drawbacks of the prior art, in particular those set out above, by proposing a solution making it possible to detect the presence of a portable device in or around a motor vehicle. reliably and accurately.

To this end, and according to a first aspect, it is proposed by the present invention, a method of detecting a portable device intended to be worn by a user of a motor vehicle and allowing “hands-free” access to said motor vehicle. . A detection device on board the motor vehicle can exchange messages by wireless communication with the portable device. The method includes the following set of steps to test whether the portable device is in a predetermined detection area:

A determination, by the detection device, of a predefined level of noise to be generated as a function of a power level of transmission of an interrogation message by the detection device to the portable device, generation of noise, by the detection device, at the determined noise level, during the transmission of the interrogation message, • a check whether a response message transmitted by the portable device is received by the detection device in response to the message question mark.

The portable device is detected in the detection area if a response message is received in response to the query message.

Such arrangements make it possible to reliably detect whether the portable device is located inside or outside of a predetermined detection zone, regardless of the power of transmission of the interrogation message by the detection device. .

In particular modes of implementation, the invention may also include one or more of the following characteristics, taken in isolation or in any technically possible combination.

In particular modes of implementation, several detection zones are predetermined. The noise level to be generated as a function of the transmission power level of the interrogation message is predefined for each detection zone. The set of steps for testing whether the portable device is in a detection zone is repeated repeatedly for the various predetermined detection zones.

In particular modes of implementation, as long as the portable device is not detected in a first detection zone including a second narrower detection zone, the set of steps for testing whether the portable device is in the second detection zone is not executed.

In particular embodiments, as long as the portable device is detected in the second detection zone included in the first detection zone, the set of steps for testing whether the portable device is in the first detection zone is not executed.

Such provisions make it possible to limit the number of tests to be carried out to detect in which detection zone the portable device is located.

In particular modes of implementation, the interrogation message and the response message are exchanged via Ultra High Frequency wireless communication.

In particular implementation modes, said Ultra High Frequency wireless communication respects a Bluetooth® Low Energy standard.

According to a second aspect, the present invention relates to a device for detecting a portable device in a predetermined detection area. The portable device is intended to be worn by a user of a motor vehicle and allows "hands-free" access to said motor vehicle. The detection device is intended to be installed in the motor vehicle. The detection device includes a wireless communication module for exchanging messages between the detection device and the portable device. The detection device also includes a controllable noise generator and a control module configured to:

• determine a predefined noise level to be generated as a function of a power level of transmission of an interrogation message by the detection device to the portable device, • control the generation of noise, by the generator noise, at the determined noise level, during the transmission of the interrogation message, • check whether a response message transmitted by the portable device is received by the detection device in response to the interrogation message.

The portable device is detected in the detection area if a response message is received in response to the query message.

In particular embodiments, the invention may also include one or more of the following characteristics, taken in isolation or in any technically possible combination.

In particular embodiments, the query message and the response message are exchanged via Ultra High Frequency wireless communication.

In particular embodiments, said Ultra High Frequency wireless communication complies with a Bluetooth® Low Energy standard.

According to a third aspect, the present invention relates to a motor vehicle comprising a detection device according to any one of the preceding embodiments.

The invention will be better understood on reading the following description, given by way of nonlimiting example, and made with reference to FIGS. 1 to 5 which represent:

- Figure 1: a first schematic representation of a motor vehicle comprising a detection device and a portable device whose position is sought to detect in predetermined detection zones,

- Figure 2: a second schematic representation of a motor vehicle comprising a detection device and a portable device whose position is sought to detect in predetermined detection zones,

- Figure 3: a schematic representation of a detection device according to the invention,

- Figure 4: a schematic representation of the main steps of a detection method according to the invention,

- Figure 5: a schematic representation of a particular mode of implementation of a detection method according to the invention.

In these figures, identical references from one figure to another denote identical or analogous elements. For reasons of clarity, the elements represented are not necessarily on the same scale, unless otherwise stated.

FIG. 1 diagrammatically represents a motor vehicle 30 in which a detection device 10 is on board. The detection device has in particular the objective of detecting whether a portable device 20, such as a badge or a mobile phone, is present in an area detection Z1, Z2, Z3 predetermined.

In the example illustrated in FIG. 1, the portable device 20 is present in a detection zone Z3 which has a coverage radius ranging for example up to two meters around the motor vehicle 30. When the portable device 20 is detected in this detection zone Z3 then authenticated, the motor vehicle 30 unlocks its doors. When the portable device 20 is not detected in this detection zone Z3, the motor vehicle 30 locks its doors.

In the example illustrated in FIG. 2, the portable device 20 is present in a detection zone Z1 inside the passenger compartment. The detection zone Z1 has for example a coverage radius of a few centimeters, or even a few tens of centimeters, around the detection device 10. When the portable device 20 is detected in this detection zone Z1 and then authenticated, the motor vehicle 30 authorizes starting the vehicle. When the portable device 20 is not detected in this detection zone Z1, the motor vehicle 30 prohibits the starting of the motor vehicle 30.

It should be noted that the different detection zones Z1, Z2, Z3 shown in FIGS. 1 and 2, as well as the behavior of the motor vehicle 30 associated with the presence or absence of the portable device 20 in one of these detection zones Z1, Z2, Z3 are given by way of nonlimiting example. Thus, in variants, only one detection zone can be used, or a greater number of detection zones can be used. Also, the association of a different event with the presence or absence of the portable device 20 in a detection zone Z1, Z2, Z3 is only a variant of the invention.

FIG. 3 schematically represents the detection device 10.

The detection device 10 comprises a wireless communication module 11 and an antenna 14 making it possible to exchange messages by wireless communication with the portable device 20. Thus, the detection device 10 can send messages to the portable device 20 and receive messages from the portable device 20 by wireless communication. The communication module 11 comprises means considered to be known to those skilled in the art (local oscillator, amplifier, modulator, analog / digital filters, analog / digital converter, signal processing processor, microcontroller ensuring the management of radio resources , etc.) to ensure wireless communications between the detection device 10 and the portable device 20.

The messages exchanged between the detection device 10 and the portable device 20 are for example exchanged by Ultra High Frequency wireless communication, that is to say radio waves of the UHF type, or “Ultra High Frequency” in English, including frequencies are between 300 MHz and 3 GHz or even higher than 3GHz.

In the following description, by way of non-limiting example, it is considered that the portable device 20 is a mobile telephone and that the UHF wireless communication between the detection device 10 and the portable device 20 complies with the Bluetooth® Low standard. Energy (BLE). This standard currently uses frequencies between 2400 MHz and 2480 MHz.

The detection device 10 also includes a controllable noise generator 12. This noise generator 12 can be, for example, a diode mounted in reverse installed on or near the electronic card of the communication module 11. A diode mounted in reverse generates a noise, in particular a noise of shot, which depends on the voltage applied across the diode. It is therefore possible to control the level of noise generated by the diode by controlling the voltage applied to the terminals of the diode.

In variants, the noise generator 12 can be produced by an electrical track electro-magnetically coupled to the track connecting the communication module 11 to the antenna 14, or by a dedicated transmitter generating more or less strong interference depending the transmitting power of the transmitter, either by a passive component generating a more or less strong thermal noise depending on the intensity of an electric current flowing through it, or by a more or less strong random variation of the voltage communication module 11, etc.

The purpose of the noise thus generated is to limit the range of a message sent by the detection device 10 without having to modify the communication module 11, in particular the software layers for managing wireless communication.

Thus, in the solution according to the invention, the limitation of the range of a message transmitted by the detection device 10 is not linked to a limitation of the transmission power (this would require modifying the management software layers of the wireless communication of the communication module 11). The limitation of the range is also not linked to a limitation of the gain of the antenna 14 on the transmission of the message (as it is the case with the modules for attenuation of the request FR1558007). In the solution according to the invention, the limitation of the scope of a message is due to a limitation of a signal-to-noise ratio at the level of the transmission of the message.

It is indeed possible, by calibration methods, to define a certain level of noise to be generated, as a function of the power of transmission of a message by the detection device 10, in order to limit the range of the message to a certain distance.

The link budget for the transmission of a message by the detection device 10 to a portable device 20 can in fact be written:

Prx = Ptx - Ltx - N + Gtx - Lp + Grx - Lrx where:

• Prx is the power level received when the message is received by the portable device 20, • Grx is the gain of the receiving antenna of the portable device 20, • Lrx is the loss observed at the receiver of the portable device 20 , • Ptx is the transmission power of the message by the detection device 10, • Gtx is the gain of the transmission antenna 14 of the detection device 10, • Ltx is the loss observed at the level of the emission from the detection device 10, • N is the noise generated at the detection device 10 (this noise increases the loss Ltx of the emission chain of the detection device 10), • Lp is the propagation loss which takes a more or less strong value depending on the distance of propagation of the message.

The Prx, Ptx, Ltx, N, Gtx, L _p , Grx, and L _rx values are expressed in decibels (dB). In order for the message to be decodable by the portable device 20, the received power level Prx must be greater than a certain sensitivity threshold. We can consider that the values Gtx, Ltx, Grx and Lrx are constant whatever the level of transmission power or the distance of propagation of the message. The value of the propagation loss Lp depends on the propagation distance.

To limit the scope of a message, the solution in request FR1558007 proposes to modify the Gtx factor. For a particular distance, and therefore for a given value of the propagation loss Lp, an attenuation module makes it possible to modify the gain Gtx so that the reception power P _RX is equal to the sensitivity threshold. In this case, a message will only be received by the portable device 20 if it is at a distance less than said particular distance.

As indicated previously, a problem with the solution of request FR1558007 is that the transmission power Ptx of a message by the detection device 10 can vary. It then does not seem possible to reliably limit the range of a message sent by the detection device 10 to a particular distance only by modifying the gain Gtx ·

In the solution according to the invention, in order to limit the range of a message to a particular distance, the idea is to generate noise whose value N is such that the received power level Prx is equal to the sensitivity threshold when a portable device 20 is located at said particular distance. The noise level is predefined on the one hand as a function of the particular distance desired, and on the other hand as a function of the transmission power Ptx of the message by the detection device 10.

Thus, the idea is to control the magnitude (Ptx - Ltx - N) so that the reception power Prx is equal to the sensitivity threshold when the portable device 20 is located at a particular distance. The quantity (Ptx - Ltx - N) corresponds to a signal to noise ratio at the level of the detection device 10 for the transmission of a message.

Advantageously, the noise generator 12 is located close to the electronic card of the communication module 11, so that the noise generated adequately affects the signal carrying the message to be transmitted without impacting the performance of any other electronic systems.

The detection device 10 also includes a control module 13. The control module 13 is connected to the communication module 11 to order the sending of an interrogation message to the portable device 20, to take note of the power transmission of such a message, and to know if a message is received from the portable device 20. The control module 13 is also connected to the noise generator 12 to control the noise level generated by the noise generator 12 .

The control module 13 comprises for example a processor capable of executing a computer program product in the form of a set of program code instructions. Alternatively or in addition, the control module comprises one or more programmable logic circuits (FPGA, PLD, etc.), and / or one or more specialized integrated circuits (ASIC), and / or a set of discrete electronic components, etc. The control module 13 thus comprises a set of means configured in software (specific computer program product) and / or hardware (FPGA, PLD, ASIC, discrete electronic components, etc.) to implement a method making it possible to detect if the portable device 20 is located in a predetermined area Z1, Z2, Z3.

FIG. 4 represents such a method 100 for detecting a portable device 20.

Prior to the execution of the method 100, one or more detection zones Z1, Z2, Z3 are predetermined and a noise level to be generated is predefined for each detection zone Z1, Z2, Z3 as a function of a transmission power of a message. For a detection zone Z1, Z2, Z3 and for a given transmission power, the noise level to be generated is defined so that the message transmitted is received by a portable device 20 only if the portable device 20 is found inside said detection zone Z1, Z2, Z3.

For a detection zone Z1, Z2, Z3 and for a given transmission power, the noise level to be generated can be determined by calibration methods. The noise level can for example be defined as the noise level above which a portable device 20 placed at the limit of a detection zone Z1, Z2, Z3 is not capable of decoding a message sent by the detection device 10 at said transmission power. For each detection zone Z1, Z2, Z3, the noise level to be generated thus defined by calibration as a function of the transmission power can, for example, be stored in a memory of the control module 13 of the detection device 10.

Thus, after calibration, the memory of the control module 13 contains, for each predetermined detection zone Z1, Z2, Z3, different noise levels to be generated corresponding to different possible values of the power level Ptx of a message by the communication device. detection 10.

It is further considered that the control module 13 can control the noise generator 12 to generate noise at the desired level. For example if the noise generator 12 is a diode, the control module stores a table which associates a certain level of noise to be generated with a voltage value to be applied across the terminals of the diode.

As illustrated in FIG. 4, the method 100 for detecting a portable device 20 comprises the set 110 of following steps for testing whether the portable device 20 is in a detection zone Zi among the predetermined detection zones Z1, Z2, Z3 (in the example considered, i is an index equal to 1,2 or 3):

• a determination 111, by the detection device 10, of a noise level N (Zi, Ptx) to be generated during the transmission of an interrogation message intended for the portable device 20, • a generation 112 of a noise, by the noise generator 12, at the determined noise level, during the transmission of the interrogation message, • a verification 113 if a response message transmitted by the portable device 20 is received by the detection device 10 in response to the query message.

The noise level N (Zi, P _T x) to be generated is determined as a function of the detection zone Zi and as a function of the transmission power level P _T x of the interrogation message by the detection device 10.

The transmission power level Ptx of the interrogation message is for example obtained by the control module 13 via a request to the communication module 11.

As indicated previously, the noise level N (Zi, P _T x) to be generated is for example stored in a memory of the control module 13 after calibration.

To check whether a response message is sent by the portable device 20 and received by the detection device 10, the control module 13 can for example wait, for a predetermined time following the sending of the interrogation message, an indication from the communication module 11 that such a message has been received.

If a response message is received, then it means that the portable device 20 has received the query message. The portable device 20 is therefore probably in the detection zone Zi. Otherwise, the portable device 20 is probably outside the detection zone Zi.

In particular modes of implementation, it is possible to repeat in a loop all 110 of steps 111 to 113 for the different detection zones Z1, Z2, Z3 in order to detect if the portable device 20 is in the one of these detection zones.

Advantageously, as long as the portable device 20 is not detected in a first detection zone Z2, Z3 including a second detection zone Z1, Z2 which is narrower than the first detection zone Z2, Z3, the assembly 110 d steps 111 to 113 to test whether the portable device 20 is in the second detection zone Z1, Z2 is not executed.

For example, in the example considered and illustrated in FIGS. 1 and 2, as long as the portable device 20 is not detected in the widest detection zone Z3 including the detection zones Z1, Z2, the assembly 110 d steps to test whether the portable device 20 is in one of the detection zones Z1, Z2 is not executed.

According to another example, if the portable device 20 is detected in the widest detection zone Z3 including the detection zones Z1, Z2, but it is not detected in the narrower detection zone Z2 including the zone Z3 detection, then the set 110 of steps to test if the portable device 20 is in the narrower Z1 detection area is not executed.

Also, advantageously, as long as the portable device 20 is detected in a second detection zone Z1, Z2 included in a first detection zone Z2, Z3, the set 110 of steps 111 to 113 to test whether the portable device 20 is in the first detection zone Z2, Z3 is not executed.

For example, in the example considered and illustrated in FIGS. 1 and 2, as long as the portable device 20 is detected in the smallest detection zone Z1, it is not necessary to try to detect it in a zone of detection Z2, Z3 wider because it is necessarily there insofar as the detection zones Z2 and Z3 include the detection zone Z1.

The figures schematically represent a particular embodiment of the method 100 of detection of a portable device 20 by the detection device 10 according to the invention.

For this mode of implementation, it is considered that there are N predetermined detection zones Z1, Z2, ..., Zn. Each detection zone Z _L of a given rank L includes a detection zone Z1, Z2, ..., Zl-i of lower rank, and is included in a detection zone Zl + i, Zl + 2, .. .Zn of higher rank. The indices i, j, k identify detection zones Zi, Zj, Zk among the predetermined detection zones Z1, Z2, ..., Z _N. The indices i, j, k can take the values 1, 2, N. In the example described with reference to FIGS. 1 and 2, we then have N = 3.

The set 110 of steps 111 to 113 for testing whether a portable device 20 is in a detection zone Zi is identical to that described with reference to FIG. 4.

When the portable device 20 is detected in a detection zone Zi, then the method 100 determines, in a step 120, the widest detection zone Zj included in the detection zone Zi. If such a detection zone Zj exists, then the method 100 repeats the set 110 of steps 111 to 113 for the zone Zj. Otherwise, the method 100 repeats the set 110 of steps 111 to 113 for the zone Zi.

When the portable device 20 is not detected in a detection zone Zi, then the method 100 determines, in a step 121, the smallest detection zone Zk including the detection zone Zi. If such a detection zone Zk exists, then the method 100 repeats the set 110 of steps 111 to 113 for the zone Zk. Otherwise, the method 100 repeats the set 110 of steps 111 to 113 for the zone Zi.

The mode of implementation of the detection method 100 described with reference to the figures advantageously makes it possible to limit the number of tests to be carried out to detect in which detection zone Z1, Z2, ..., Zn is a portable device 20. The set 110 of steps 111 to 113 for a detection zone can for example be repeated after the expiration of a predetermined period.

The above description clearly illustrates that, by its various characteristics and their advantages, the present invention achieves the objectives set. In particular, it makes it possible to reliably determine whether a portable device 20 is located inside or outside a predetermined area by limiting the scope of an interrogation message sent by the detection device 10 of precisely whatever the transmission power Ptx of said interrogation message by the detection device 10.

Claims (10)

1. Method (100) for detecting a portable device (20) intended to be worn by a user of a motor vehicle (30) and allowing “hands-free” access to said motor vehicle (30), the motor vehicle ( 30) comprising a detection device (10), the detection device (10) and the portable device (20) capable of exchanging messages by wireless communication, said method (100) comprising a set (110) of steps to test whether the portable device (20) is in a predetermined detection zone (Z1, Z2, Z3), said method (100) being characterized in that said set (110) of steps comprises: • a determination (111), by the detection device (10), of a predefined noise level to be generated as a function of a power level of transmission of an interrogation message by the detection device (10 ) intended for the portable device (20), • a generation (112) of noise, by the detection device (10), at the determined noise level, during the transmission of the interrogation message, • a verification (113) if a response message sent by the portable device (20) is received by the detection device (10) in response to the interrogation message, the portable device (20) being detected in the detection zone (Z1, Z2, Z3 ) if a response message is received in response to the query message. 2. Method (100) according to claim 1 characterized in that several detection zones (Z1, Z2, Z3) are predetermined, and the noise level to be generated as a function of the transmission power level of the interrogation message is predefined for each detection zone (Z1, Z2, Z3), and the set (110) of steps for testing whether the portable device (20) is in a detection zone (Z1, Z2, Z3) is repeated by recurrent way for the different predetermined detection zones (Z1, Z2, Z3). 3. Method (100) according to claim 2 characterized in that as long as the portable device (20) is not detected in a first detection zone (Z2, Z3) including a second detection zone (Z1, Z2), the set (110) of steps for testing whether the portable device (20) is in the second detection zone (Z1, Z2) is not executed. 4. Method (100) according to claims characterized in that as long as the portable device (20) is detected in the second detection zone (Z1, Z2) included in the first detection zone (Z2, Z3), all (110) of steps for testing whether the portable device (20) is in the first detection zone (Z2, Z3) is not executed. 5. Method (100) according to any one of the preceding claims, characterized in that the interrogation message and the response message are exchanged via Ultra High Frequency wireless communication. 6. Method (100) according to claims characterized in that said Ultra High Frequency wireless communication meets a Bluetooth® Low Energy standard. 7. Detection device (10) of a portable device (20) in a predetermined detection area (Z1, Z2, Z3), said portable device (20) being intended to be worn by a user of a motor vehicle ( 30) and allowing “hands-free” access to said motor vehicle (30), said detection device (10) being intended to be installed in the motor vehicle (30), the detection device (10) comprising a communication module ( 11) wireless enabling messages to be exchanged between the detection device (10) and the portable device (20), said detection device (10) being characterized in that it further comprises a noise generator (12) controllable and a control module (13) configured to: • determining a predefined level of noise to be generated as a function of a power level of transmission of an interrogation message by the detection device (10) to the portable device (20), • controlling the generation of noise, by the noise generator (12), at the determined noise level, during the transmission of the interrogation message, • checking whether a response message transmitted by the portable device (20) is received by the detection device (10) in response to the interrogation message, the portable device (20) being detected in said detection zone (Z1, Z2, Z3) if a response message is received in response to the interrogation message. 8. Detection device (10) according to claim 7 characterized in that the interrogation message and the response message are exchanged via Ultra High Frequency wireless communication. 9. Detection device (10) according to claim 8 characterized in that said Ultra High Frequency wireless communication respects a Bluetooth® Low Energy standard. 10. Motor vehicle (30) characterized in that it comprises a detection device (10) according to any one of claims 7 to 9.