FR3057984A1 - METHOD AND SYSTEM FOR AUTOMATIC EMERGENCY RELIEF CALLING IN DETECTION OF A PERSON IN A DISTRESS SITUATION - Google Patents

Abstract

The method according to the invention comprises a motion detection step (S2) by means of a motion sensor, a heart rate measurement step (S4) and an emergency call (S9) emergency step . According to the invention, the step of measuring the heart rate is performed when a first alert level is activated (NA1 = 1) following a lack of motion detection (S3) by the motion detection step during a no motion duration (Dsm) at least equal to a predetermined threshold duration (THsm).

Description

© Publication number: 3,057,984 (to be used only for reproduction orders)

©) National registration number: 16 70625 ® FRENCH REPUBLIC

NATIONAL INSTITUTE OF INDUSTRIAL PROPERTY

COURBEVOIE

©) Int Cl ⁸ : G 08 B 21/04 (2017.01), G 06 F 19/00, A 61 B 5/00

A1 PATENT APPLICATION

©) Date of filing: 25.10.16. (30) Priority: © Applicant (s): DOMANGE FRANÇOIS —FR. ©) Inventor (s): DOMANGE FRANÇOIS. ©) Date of public availability of the request: 04.27.18 Bulletin 18/17. ©) List of documents cited in the preliminary search report: See the end of this booklet (© References to other related national documents: ©) Holder (s): DOMANGE FRANÇOIS. ©) Extension request (s): @) Agent (s): CABINET l-PATVAL.

METHOD AND SYSTEM FOR AUTOMATICALLY CALLING EMERGENCY EMERGENCY DURING THE DETECTION OF A PERSON IN DISTRESS SITUATION.

FR 3 057 984 - A1 (6/2 The method according to the invention comprises a step of detecting movement (S2) by means of a movement sensor, a step of measuring the heart rate (S4) and a step of automatic call (S9) for emergency assistance In accordance with the invention, the step of measuring the heart rate is performed when a first alert level is activated (NA1 = 1) following a lack of motion detection (S3 ) by the motion detection step for a duration of absence of movement (Dsm) at least equal to a predetermined threshold duration (THsm).

AUTOMATIC EMERGENCY EMERGENCY CALLING METHOD AND SYSTEM

WHEN DETECTING A PERSON IN A DISTRESS SITUATION

The invention relates generally to emergency relief for people in distress, including people with heart attacks. More particularly, the invention relates to an automatic emergency call method for detecting a person in distress. The invention also relates to a system for implementing the method according to the invention.

The demographic growth of the elderly in developed countries is a real challenge in terms of public health and emergency aid. Indeed, the elderly are more frequently sick and isolated than the rest of the population. This results in an increased risk for the elderly population of being in critical or distress situations with an impossibility of asking for help.

Cardiovascular disease is a major cause of death. In fact, cardiovascular disease is the number one killer worldwide. Seventy-five percent of cardiac arrests occur at home and involve people with an average age of sixty-seven. Isolated elderly people constitute a population at significant risk with regard to cardiovascular diseases. Unfortunately, witnessless cardiac arrest to prevent rescue is often fatal. Elderly people in isolation constitute a vulnerable population, and are often anxious to live alone because they are aware of the risks involved.

Timeliness of emergency response is essential for the survival of a person facing cardiac arrest.

In the field, rescue teams are often faced with a lack of reliability of the information collected, because people are often in a state of panic. This results in difficult dialogues caused by stress or disabilities, incomplete or even false addresses, incorrect access codes, etc. These elements delay the arrival of emergency aid and directly affect the chances of survival of the person to be rescued.

Document EP2229665B1 discloses a method for detecting a subject in critical condition who attempts to provide a solution to the situation described above. The described method takes into account at least one physiological parameter and detects a critical state from a synthesis value based on the value of the physiological parameter and its rate of variation.

It is desirable to propose new solutions providing answers to the various problems set out above, and in particular a solution allowing rapid intervention of emergency aid and support for people in isolation.

According to a first aspect, the invention relates to a method of automatic emergency call when detecting a person in distress comprising a step of detecting movement, a step of measuring the heart rate and a step automatic emergency call. According to the invention, the step of measuring the heart rate is performed when a first alert level is activated following an absence of motion detection by the motion detection step for a period of absence of motion. at least equal to a predetermined threshold duration.

According to a particular characteristic of the method of the invention, the step of measuring the heart rate measures the pulse of the person.

According to another particular characteristic of the method of the invention, if the step of measuring the heart rate measures a heart rate greater than a predetermined minimum heart rate threshold, the first alert level is consecutively deactivated and the step of measuring the rate heart rate is interrupted, and if the step of measuring the heart rate measures a heart rate equal to or less than a predetermined minimum heart rate threshold, a second alert level is consecutively activated, a predetermined delay time is activated and means for alarm intended for the person are activated.

According to yet another particular characteristic of the method of the invention, if the person performs a predetermined action during the predetermined delay time, the second alert level is consecutively deactivated and the alarm means are deactivated, and if the person does not perform not the predetermined action during the predetermined delay time, the second alert level remains activated and the automatic call for emergency assistance step is activated consecutively.

According to yet another particular characteristic of the method of the invention, the predetermined action is a pressing on a predetermined key of a mobile unit carried by said person or a pressing on another predetermined key of a base located in a place of residence of the person.

According to yet another particular characteristic of the method of the invention, the step of automatically calling emergency assistance includes dialing a pre-recorded emergency assistance call number until the establishment of a communication with emergency assistance, and a looping of pre-recorded information relating to the person and necessary for the intervention of emergency assistance.

According to yet another particular characteristic of the method of the invention, the motion detection step uses a motion sensor in the form of an accelerometer.

According to another aspect, the invention also relates to an automatic emergency call system for the detection of a person in distress, comprising a mobile unit in the form of a bracelet worn by the person and a base connected to a voice communication network, the bracelet and the base being able to establish radio communication between them. According to the invention, the bracelet and the base respectively comprise first and second software modules implanted in respective microcontrollers and capable of executing a functional algorithm for the implementation of the method described briefly above.

According to a particular characteristic of the system of the invention, the bracelet comprises a movement sensor, a heart rate sensor, man-machine interface means comprising at least one key and a loudspeaker and a microphone and / or a buzzer and / or a vibrator, and a radio transceiver, and the base comprises a radio transceiver, a voice communication modem connected to the voice communication network, and other man-machine interface means comprising at least a button, a speaker and a microphone.

According to another particular characteristic of the system of the invention, the base comprises a screen included in the other man-machine interface means and a Wi-Fi transceiver.

According to yet another particular characteristic of the system of the invention, the bracelet and the base include means for direct calling and establishing communication with the emergency assistance by pressing a button on the bracelet and / or pressing a key on the base.

According to another particular embodiment, the system of the invention comprises a mobile unit in the form of a bracelet worn by the person and a geolocation and call center connected to a voice communication network, the bracelet and the geolocation and call center being able to establish communication through a cellular voice and data network, the bracelet comprising a geographic positioning sensor, the geolocation and call center comprising geolocation means of the bracelet and means for calling emergency assistance, and the bracelet and the geolocation and call center comprising respectively first and second software modules capable of executing a functional algorithm for implementing the method described briefly above.

Other advantages and characteristics of the present invention will appear more clearly on reading the description below of several particular embodiments with reference to the appended drawings, in which:

- Fig.1 is a block diagram showing the architecture of a first particular embodiment of the automatic emergency call system according to the invention;

- Fig.2 is a simplified view showing a mobile unit, in the form of a bracelet, worn by the person in an automatic emergency call system according to the invention;

- Fig.3 is a functional algorithm implementing the method implemented in an automatic emergency call system according to the invention;

- Fig.4 is another functional algorithm relating to a direct call to the emergency services by the person; and

- Fig.5 is a block diagram showing the architecture of a second particular embodiment of the automatic emergency call system according to the invention.

The hardware architecture and the operation of a first particular embodiment 1a of the automatic emergency call system when detecting a person in distress according to the invention are now described in detail in reference to Figs. 1 to 4.

This first embodiment 1a is intended for use at home.

With particular reference to Figs. 1 and 2, the system 1a comprises at least one mobile unit 2 and a fixed unit 3 called "base" thereafter. According to the invention, the system 1a may include several mobile units, for example, as shown in Fig.1, two units 2 and 2 ₂ to equip two people at risk living under the same roof.

As shown in Fig.2, the mobile unit 2, 2 ₂ is here in the form of an equipped bracelet that the person wears on his wrist. The mobile unit 2, 2 ₂ may be in other forms in different embodiments of the system of the invention.

The mobile unit 2, 2 ₂ and the base 3 are connected to each other by a wireless link L23, L23 ₂ , typically a link of the radio type in the RF range of the radio frequencies. Such a radio link makes it possible to guarantee robust and always possible communication between the mobile units 2, 2 ₂ and the fixed base 3 when the mobile units 2, 2 ₂ are distant from the base 3, for example by being located in a different room. the one where the base 3 is installed.

In this embodiment, the radio links L23, L23 ₂ are established in point-to-point mode between the mobile units 2, 2 ₂ and the base 3. The topology of the radio network is of star type and the communications between the units mobiles 2, 2 ₂ are not authorized.

In this embodiment, the links L23, L23 ₂ are of the RF radio link type with a carrier frequency of 868 MHz. Preferably, a standard protocol of the OSI type with seven layers will be used to implement a radio network allowing simultaneous communications between the base 3 and the mobile units 2, 2 ₂ and a coexistence between the mobile units. However, a proprietary communication protocol is not excluded and could be implemented in certain applications of the invention.

The different mobile units, here 2 and 2 ₂ , have an identical architecture. The mobile unit 2 is described below.

The mobile unit 2 essentially comprises a microcontroller 20, a movement sensor 21, a heart rate sensor 22 of the photoplethysmographic type, man-machine interface means 23, an RF transmitter-receiver 24 and a power supply unit 25. The term "emitter-receiver" is replaced in the remainder of the description by the English term "transceiver" widely used by those skilled in the art.

The motion sensor 21 is an accelerometer in this embodiment. Of course, other types of sensor can be used.

Conventionally, the microcontroller 20 notably comprises a processing unit in the form of a microprocessor, a read only memory and a random access memory and input / output interface means, these various known components of a microcontroller n ' not being shown in Fig. 1.

A software module 200 is installed in the microcontroller 20 and controls the operation of the mobile unit 2 in accordance with the method of the invention.

The accelerometer 21 is connected to the microcontroller 20 through its input / output interface means and allows detection of the person's movements, that is to say, his physical activity and therefore his state of consciousness . According to the method of the invention, the detection of an absence of movement activates a first level of alert in the mobile unit 2, since this absence of movement can be consecutive to a loss of consciousness of the person.

The heart rate sensor 22 is connected to the microcontroller 20 through its input / output interface means and allows the person's pulse to be taken. The measurement of a weak or absent pulse, that is to say, less than a predefined threshold value, activates a second level of alert in the mobile unit 2, since such a measurement may be consecutive to a crisis or cardiac arrest.

It will be noted that the use in the invention of an accelerometer and a photoplethysmographic sensor is favorable to a reduction in the cost of the mobile unit 2, these components being marketed at very affordable prices.

In this embodiment of the invention, the machine interface means 23 comprise two control keys 230 and 231, a vibrator 232, a speaker 233 and a microphone 234. It will be noted that in other embodiments of the system 1a, not providing for voice communication through the mobile unit or bracelet 2, the speaker 233 and the microphone 234 will be replaced by a simple buzzer or buzzer.

The components 230, 231, 233 and 234 of the bracelet 2 appear in external view in FIG. 2, the vibrator 232 integrated in the body of the bracelet not being visible in this figure.

The functions of the various components of the human machine interface means 23 will appear more clearly below, with the description of the operation of the system 1a with reference to FIGS. 3 and 4.

The transceiver 24 is connected to the microcontroller 20 through its input / output interface means and authorizes the establishment of a radio communication link with the fixed base 3. As shown in FIG. 1, the transceiver 24 is equipped with an antenna 240. The radio frequency used of 868 Mhz authorizes the realization of the antenna 240 in a form known as “microstrip” (in English terminology), directly by engraving of a copper track on the printed circuit of the mobile unit 2.

The power supply unit 25 comprises an electric battery 250 and a DC-DC converter 251 called DC-DC. The battery 250 is typically a lithium battery, of the so-called button or chip type, having a nominal voltage of 3 Volt. The DC-DC converter 251 authorizes a voltage adaptation by supplying, from the nominal voltage of the battery 250, the voltage values required for the various components of the mobile unit 2.

The base 3 here essentially comprises a microcontroller 30, man-machine interface means 31, an RF transceiver 32, a Wi-Fi transceiver 33, a voice communication modem 34 and a power supply unit 36.

Conventionally, like the microcontroller 20, the microcontroller 30 notably comprises a processing unit in the form of a microprocessor, a read only memory and a random access memory and input / output interface means, these various components known to a microcontroller not shown in Fig.1.

A software module 300 is installed in the microcontroller 30 and controls the operation of the base 3 in accordance with the method of the invention.

In this embodiment of the invention, the machine interface means 31 comprise two control keys 310 and 311, a speaker 312, a microphone 313 and a display screen 314, for example of the LCD type. The functions of the various components of the man-machine interface means 31 will appear more clearly below, with the description of the operation of the system 1a with reference to FIGS. 3 and 4.

An RF transceiver 32 is controlled by the microcontroller 30 through its input / output interface means and authorizes the establishment of a radio communication link L23, L232 with the mobile units 2, 2 ₂ . As shown in Fig.1, the transceiver 32 is equipped with an antenna 320. The transceiver 32 is, of course, of the same type as the transceiver 24 of the mobile units 2, 2 ₂ and uses the same carrier frequency and the same type of modulation as the latter. Like the antenna 240 of the mobile units 2, 2 ₂ , the antenna 320 is of the “microstrip” type and is produced directly on the printed circuit of the base 3.

The Wi-Fi transceiver 33 is of known type and is controlled by the microcontroller 30 through its input / output interface means. The Wi-Fi transceiver 33 allows integration of the base 3 into a home Wi-Fi network. It is thus possible to configure the base 3 and the mobile units 2, 2 ₂ by means of a computer or other means such as a tablet or a so-called “smartphone” smartphone, executing a dedicated software application for configuration. For the mobile units 2, 2 ₂ , the configuration data are transmitted from the base 3 through the radio network L23, L23 ₂ . It will also be noted that the fixed unit 3 and the mobile units 2, 2 ₂ may also be automatically configured remotely through the internet and / or cellular networks. For example, by filling in a dedicated internet platform with the fixed or mobile phone number corresponding to the base, the identity of the people and all the other relevant data to download.

The voice communication modem 34 is of known type and is controlled by the microcontroller 30 through its input / output interface means. The modem 34 allows a connection of the base 3 to a voice communication network RCV. According to the embodiment of the system 1a, the base 3 can be connected to the conventional switched telephone network, to the internet network for VoIP communications or to a cellular network such as a GSM, GRPS, UMTC or LTE network.

The power supply unit 36 includes a direct current alternating current charger (AC-DC) 360 and a direct current converter 361 (DC-DC). The AC-DC 360 charger is suitable for connecting to an alternative electrical supply network, such as the 220 Volt network, and for supplying a rectified direct voltage, for example 5 Volt. The DC-DC converter 361 authorizes a voltage adaptation by supplying, from the rectified direct voltage delivered by the charger 360, the voltage values required by the various components of the base 3.

With particular reference to Figs. 3 and 4, the operation of system 1a is now described in detail.

The functional algorithms of Figs. 3 and 4 are executed in the software modules 200 and 300 installed in the microcontrollers 20 and 30, respectively.

The algorithm A1 of FIG. 3 implements the method according to the invention of automatic emergency rescue call when a distress situation is detected by the system 1a in one of the people wearing the bracelets 2, 2 ₂ .

Step S1 is a prior step of initializing variables and parameters involved in the algorithm A1. The following steps S2 and S3 are steps for monitoring the person's state of consciousness.

In step S2, the output signal supplied by the accelerometer 21 of the bracelet 2, 2 ₂ is analyzed by the microcontroller 20 so as to detect the movements of the person. This motion detection is performed continuously and is facilitated by the low electrical consumption of the accelerometer 21 which allows its continuous activation.

Step S3 is a conditional step authorizing the detection of an absence of movement during a duration of absence of movement Dsm which is greater than a duration of absence of maximum movement predetermined THsm. The maximum duration THsm is a detection threshold.

As long as the duration of absence of movement Dsm remains lower (output N) than the threshold duration THsm, a first alert level NA1 remains deactivated, NA1 = 0, and step S3 loops over step S2 so that algorithm A1 continues to monitor the person's state of consciousness.

When the duration of absence of movement Dsm reaches or exceeds the threshold duration THsm (output Y), the algorithm A1 activates the first level of alert NA1, NA1 = 1, and considers a possible loss of consciousness of the person who will trigger the execution of steps S4 and S5.

In step S4, the heart rate sensor 22 is activated to take the person's pulse, or heart rate.

According to the invention, it will be noted that the pulse measurement is not carried out continuously, but only after activation, NA1 = 1, of the first alert level. This way of proceeding allows a reduction in the electrical consumption, knowing that the consumption of the sensor 22 of the photoplethysmographic type is not negligible, unlike that of the accelerometer 21.

Step S5 is a conditional step authorizing the detection of a measured HR pulse which is less than a predetermined minimum pulse THhr. The minimum THhr pulse is a detection threshold.

If the measured HR pulse is higher (output N) than the THhr threshold pulse, the first alert level NA1 is deactivated, NA1 = 0, and the algorithm A1 returns to step S2 of monitoring the state of consciousness .

When the measured HR pulse is low, that is to say, equal to or lower (output Y) than the threshold pulse THhr, the algorithm A1 activates a second alert level NA2, NA2 = 1, and considers a possible distress state of the person who will trigger the execution of steps S6 and S7.

Steps S6 and S7 are intended to validate that the person is actually in a state of distress before calling the emergency services. For this, the person is warned by means of an alarm that an emergency call will be made and has a certain period of time to deactivate this call. In the absence of a deactivation action on its part within the allotted time period, emergency assistance is called.

Thus, in step S6, the vibrator 232 and the speaker 233 of the bracelet 2, 2 ₂ are activated, as well as the speaker 312 of the base 3, as alarm means. The alarm means 232, 233 and 312 emit a vibration and sound signals to warn the person of an imminent emergency call. Simultaneously with the activation of the alarm means 232, 233 and 312, a delay time DAL of these alarm means is also triggered. This DAL delay time is the time allocated to the person to deactivate the emergency call.

Step S7 is a conditional step authorizing the detection of a deactivation, DES = 1, during the delay time DAL or of a non-deactivation, DES = 0, during this same duration DAL.

During the DAL delay time, if the person presses the button 230 on the bracelet 2, 2 ₂ or the button 310 on the base 3, the deactivation DES is acquired DES = 1 (output Y). The second alert level NA2 and the alarm means 232, 233 and 312 are deactivated and the algorithm A1 returns to step S2 for monitoring the person's state of consciousness.

If the person does not press the 230 or 310 keys during the DAL delay time, no deactivation is recorded, DES = 0, and the second alert level NA2 = 1 is maintained. The emergency call is then activated (output N) and is carried out in step S9.

The call step S9 for emergency assistance is carried out by the base 3. The base 3 contains in the memory space of its microcontroller 30 a pre-recorded emergency assistance call number which is automatically dialed and redialed until the outcome of the call. Once communication has been established with the emergency services, pre-recorded information necessary to rescue the person in distress is sent in a loop by the base 3 in order to give the operator of the emergency center the time necessary to note all of the relevant data. This information sent in a loop will include the identity and address of the person's home as well as any other relevant information that may be useful for rescue such as the person's age, pathologies, state of distress detected, etc. .

As indicated above, the base 3 is configurable by computer, or other means, through the Wi-Fi link established through the transceiver 33. During this configuration, telephone numbers and information to be broadcast to the emergency services emergency are downloaded to the base 3. In certain embodiments of the system of the invention, configuration data may also be downloaded to the wristbands 2, 2 ₂ from a computer, or other means, through the Wi-Fi connection, base 3 and the radio network L23, L23 ₂ .

With reference to FIG. 4, a functional algorithm A2 is now described for a direct call for emergency assistance from the bracelet 2, 2 ₂ , by pressing the key 231. It will be noted here that such a call direct emergency assistance can also be carried out from base 2 by pressing the 311 key. The functional algorithm A2 therefore also applies to direct calls from base 2, knowing that the pressing the 311 key then replaces pressing the 231 key.

In algorithm A2, step S10 is a preliminary step for initializing variables and parameters. The next step S11 is a conditional step which detects a press on the key 231. As long as no press is detected on the key 231,231 = 0, the step S11 loops on itself (output N). When a press is detected (output Y) on the key 231, 231 = 1, the algorithm A2 performs the following step S12. Step S12 is analogous to step S9 of the algorithm A1 in Fig.3 and performs an emergency call. The base 3 receives an instruction in this direction through the radio network L23, L23 ₂ and then proceeds as described above for step S9.

The system 1a also authorizes voice calls to telephone numbers prerecorded in base 3, such as the telephone number of a relative or a home assistance service.

These voice calls can be made from bracelet 2, 2 ₂ or from base 3, by means of loudspeaker 233 and microphone 234 for a call from bracelet 2, 2 ₂ , and by means of loudspeaker 312 and microphone 313 for a call from base 3.

In this embodiment, the bracelet 2, 2 ₂ does not include a screen. Voice calls are launched by predefined pressing sequences on the key 230. These pressing sequences are recognizable by the microcontroller 20 and must be memorized by the person. Thus, for example, the voice call mode is activated here by a long press on the key 230 until a beep is emitted by the speaker 233. The selection of the call number to dial is then performed by the person by short presses on the 230 key. Thus, for example, a single short press to dial the first pre-recorded call number, two successive short presses to dial the second pre-recorded call number, etc. Of course, in other embodiments, the bracelet 2, 2 ₂ may be equipped with a screen displaying a name associated with the selected call number, so as to reduce the memory effort required of the person and d 'all the more if this one is old. The selection made from the bracelet 2, 2 ₂ is transmitted to the base 3 by the radio network L23, L23 ₂ and the latter then dials the corresponding prerecorded call number.

The voice calls from base 3 are launched in a similar manner by predefined press sequences on the key 310. The operation of selecting the telephone number is here facilitated by the presence of the screen 314 provided in the base 3.

The hardware architecture and the operation of a second particular embodiment 1b of the automatic emergency call system when detecting a person in distress according to the invention are now described with reference to the Fig. 5.

This second embodiment 1b is intended for use in a so-called nomadic mode, which means that the person is mobile outside his home. Its location is therefore variable.

As shown in Fig. 5, the system 1b comprises a plurality of mobile units 2 ', 2 ₂ ' and a geolocation and call center 4.

As in system 1a, the mobile unit 2 ′, 2 ₂ ′ is preferably produced in the form of a bracelet. The heart rate sensor integrated in the bracelet is thus perfectly located on the person's wrist for taking a pulse.

In the system 1b, the bracelet 2 ', 2 ₂ ' has an architecture and an operation very close to those of the bracelet 2, 2 ₂ of the system 1a. Similar components retain the same benchmarks with an added "bonus".

The bracelet 2 ′ detailed in FIG. 5 therefore comprises a microcontroller 20 ′, a motion sensor 21 ′, here in the form of an accelerometer, a heart rate sensor 22 ′ of photoplethysmographic type, man-machine interface means 23 'and a power supply unit 25'. Bracelet 2 ’differs from bracelet 2 by a GRPS transceiver 26 and a miniature geographic positioning sensor 27 such as a GPS sensor.

In the microcontroller 20 ’is installed a software module 200’ which controls the operation of the bracelet 2 ’in accordance with the method of the invention.

The GRPS 26 transceiver allows connection of the bracelet 2 ’to a cellular voice and data network 5 according to the GRPS standard. Of course, the bracelet 2 ’is provided with a SIM card 260 which is associated with the GRPS transceiver 26 and which is recognized by the cellular network 5.

It will be noted that networks other than the GRPS network may be used in variants of the system 1b, such as for example the networks of connected objects Sigfox (registered trademark) or LoRa (registered trademark).

In the system 1b, the detection of the person's state of distress is carried out according to the same algorithm A1 as that of the system 1a. On the other hand, the call for emergency assistance is provided by the center 4 which is connected to an RCV voice communication network and performs this task for all of the bracelets 2 ′, 2 ₂ ′ of the system 1 b.

As shown in Fig. 5, the geolocation and call center 4 includes a software module 400 installed in a central unit (not shown) thereof and authorizing the implementation of the method of the invention according to algorithm A1. To this end, the geolocation and call center 4 performs two functions 40 and 41. The first function 40 consists in geolocating the person in distress wearing the bracelet 2 ', 2 ₂ '. The second function 41 consists in calling emergency aid.

GD geolocation data is provided by the sensor 27 housed in the bracelet 2 ', 2 ₂ '. When a distress state is detected, the geolocation data GD is associated with an identification number ID identifying the bracelet 2 ′, 2 ₂ ′ and are transmitted to the center 4 through the network 5.

In the center 4, the identification number ID makes it possible to retrieve from a database all the pre-recorded information necessary to rescue the person in distress. The location of the person to be rescued, deduced from the GD data transmitted by the bracelet 2 ', 2 ₂ ', is attached to the prerecorded information recovered so as to format the message to be transmitted to the emergency services. The operating mode is then analogous to that implemented in step S9 of the algorithm A1. A pre-recorded emergency call number is dialed and redialed automatically until the call is completed. Once communication has been established with emergency assistance, the formatted message is sent in a loop and includes the identity of the person, his location and any other relevant information that may be useful for emergency assistance such as the age of the person, his pathologies, the state of distress detected, etc.

The system 1b also authorizes a direct call for emergency assistance from the bracelet 2, 2 ₂ , by pressing the key 231 '. The geolocation data GD and the identification number ID are transmitted to the center 4 which then proceeds as indicated above by dialing the pre-recorded emergency assistance call number and by looping the formatted message comprising all information necessary for emergency assistance.

Voice calls from the 2 ', 2 ₂ ' bracelet are also possible with the 1b system. Analogously to the system 1a, voice calls can be launched by predefined pressing sequences on the key 230 '. The selection of the call number obtained with the press sequence made on the key 230 'is transmitted to the center 4 accompanied by the identification number ID of the bracelet 2', 2 ₂ '. In the center 4, this information makes it possible to retrieve a corresponding pre-recorded call number which is dialed to establish the desired voice communication. The center 4 performs a gateway function between the bracelet calling 2 ', 2 ₂ ' and the called party for the bidirectional transit of voice signals throughout the duration of the voice communication.

It will also be noted that the bracelet 2 ′, 2 ₂ ′ can be automatically configured remotely, and the geolocation and call center 4 informed with the necessary data, through the communication networks. For example, the person will be able to enter on a web platform at center 4 the telephone number of the SIM 260 card on their 2 ', 2 ₂ ' bracelet, their identity, the data required for emergency assistance and for calls from relatives. , home help services or others.

0 Of course, the invention is not limited to the embodiments which have been described more particularly here by way of example. Those skilled in the art, depending on the applications of the invention, may make various modifications and variants which fall within the scope of the appended claims.

Claims (12)

1. A method of automatic emergency call for emergency when a person in distress is detected, comprising a movement detection step (S2) by means of a movement sensor (21), a measurement step heart rate (S4) and an automatic call step (S9) of said emergency assistance, characterized in that said step of measuring the heart rate (S4) is performed when a first alert level is activated (NA1 = 1) following an absence of motion detection (S3) by said motion detection step (S2) during an absence of motion duration (Dsm) at least equal to a predetermined threshold duration (THsm). 2. Method according to claim 1, characterized in that said step of measuring the heart rate (S4) measures the pulse of said person. 3. Method according to claim 1 or 2, characterized in that if said step of measuring the heart rate (S4) measures a heart rate (HR) greater than a predetermined minimum heart rate threshold (THhr), said first alert level is consecutively deactivated (NA1 = 0) and said step of measuring the heart rate (S4) is interrupted, and if said step of measuring the heart rate (S4) measures a heart rate (HR) equal to or less than said predetermined minimum heart rate threshold (THhr), a second alert level is activated consecutively (NA2 = 1), a predetermined time delay (DAL) is activated and alarm means (232, 233, 312) intended for said person are activated (S6). 4. Method according to claim 3, characterized in that if said person performs a predetermined action (230, 310, DES = 1) during said predetermined delay time (DAL), said second alert level is deactivated consecutively (NA2 = 0) and said alarm means (232, 233, 312) are deactivated (S8), and if said person does not perform said predetermined action (230, 310, DES = 0) during said predetermined delay time (DAL), said second alert level remains activated (NA2 = 1) and said automatic call step (S9) of said emergency assistance is consecutively activated. 5. Method according to claim 4, characterized in that said predetermined action is a press on a predetermined key (230) of a mobile unit (2, 2 ₂ ) carried by said person or a press on another predetermined key (310 ) a base (3) located in a place of residence of said person. 6. Method according to any one of claims 1 to 5, characterized in that said step of automatic call for emergency assistance (S9) comprises a dialing of a pre-recorded call number of said emergency assistance until the establishment of a communication with said emergency assistance, and a looping of pre-recorded information relating to said person and necessary for the intervention of said emergency assistance. 7. Method according to any one of claims 1 to 6, characterized in that said movement detection step (S2) uses a motion sensor in the form of an accelerometer (21). 8. Automatic emergency call system when a person in distress is detected, comprising a mobile unit in the form of a bracelet (2, 2 ₂ ) worn by said person and a base ( 3) connected to a voice communication network (RCV), said bracelet (2, 2 ₂ ) and said base (3) being able to establish radio communication (L23, L23 ₂ ) between them, characterized in that said bracelet (2, 2 ₂ ) and said base (3) respectively comprise first and second software modules (200, 300) implanted in respective microcontrollers (20, 30) and able to execute a functional algorithm (A1) for the implementation of the method according to any one of claims 1 to 7. 9. System according to claim 8, characterized in that said bracelet (2, 2 ₂ ) comprises a movement sensor (21), a heart rate sensor (22), man-machine interface means (23) comprising at least one button (230, 231) and a speaker (233) and a microphone (234) and / or a buzzer and / or a vibrator (232), and a radio transceiver (24), and in this that said base (3) comprises a radio transceiver (32), a voice communication modem (34) connected to said voice communication network (RCV), and other man-machine interface means (31) comprising at minus a button (310, 311), a speaker (312) and a microphone (234). 10. System according to claim 9, characterized in that said base (3) comprises a screen (314) included in said other man-machine interface means (31) and a Wi-Fi transceiver (33). 11. System according to claim 9 or 10, characterized in that said bracelet (2, 2 ₂ ) and said base (3) comprise means (A2, 200, 300) for direct call and establishment of a communication with said emergency assistance by pressing a said button (231) of said bracelet and / or pressing a said button (311) of said base (3). 12. Automatic emergency call system for emergency when a person in distress is detected, characterized in that it comprises a mobile unit in the form of a bracelet (2 ', 2 ₂ j worn by said person and a geolocation and call center (4) connected to a voice communication network (RCV), said bracelet (2 ', 2 ₂ d and said geolocation and call center (4) being able to establish communication through a cellular voice and data network (GRPS, 5), said bracelet (2 ′, 2 ₂ d comprising a geographic positioning sensor (GPS, 27), said geolocation and call center ( 4) comprising geolocation means (40) of said bracelet (2 ′, 2 ₂ d and means of calling (41) of said emergency assistance, and said bracelet (2 ′, 2 ₂ d and said geolocation center and call (4) comprising respectively first and second software modules (200 ', 400) capable of executing a functional algorithm (A1) for implementing the method according to any one of claims 1 to 7. 1/3