ALERT AND DISASTER MANAGEMENT SYSTEM AND METHOD FOR OPERATING SUCH A SYSTEM

Abstract

The alert and disaster management System (100) comprises: at least one radiocommunication terminal (105), the terminal comprising: a means (106) for communicating, via a data network, with a central computer system, —a sensor (110) for sensing a value of a physical variable that is representative of the operation of the network connected to the terminal, a means (115) for determining a network failure according to the captured value, a transmitter (120) of radio signals in the event a failure is determined and —the central computer system (300), connected via the data network to at least one terminal, comprising: a memory (304) of geographical positioning information of at least one terminal, a detector (305) for detecting network connection anomalies between the computer system and at least one terminal, a means (310) of providing an alert in the event of an anomaly, a means (315) of providing a piece of information that represents the stored positioning of at least one said terminal having a network connection anomaly and at least one mobile radiocommunication receiver (125) configured to receive the radio signals transmitted by at least one terminal.

Claims

1. A system for alert and disaster management, comprising: at least one radiocommunication terminal, the terminal comprising: a means of communication, via a data network, with a central computer system, a sensor of a value of a physical quantity representative of the operation of the network connected to the terminal, a means for determining a failure of the network as a function of the sensed value, a transmitter of radio signals in case of failure determination and the central computer system, linked via the data network to at least one terminal, comprising: a memory for information in respect of geographical positioning of at least one terminal, a detector of anomaly of network link between the computer system and at least one terminal, a means for providing an alert in case of anomaly, a means for providing an item of information representative of the stored positioning of at least one said terminal exhibiting a network link anomaly and at least one mobile radiocommunication receiver configured to receive the radio signals emitted by at least one terminal.

2. The system as claimed in claim 1, wherein the computer system comprises a device configured to prepare an itinerary of at least one receiver, the itinerary being established as a function of at least one item of geographical positioning information provided.

3. The system as claimed in claim 1, in which the computer system comprises a satellite control device configured to control a satellite, said satellite being a mobile radiocommunication receiver.

4. The system as claimed in claim 1, wherein the sensor is configured to sense a physical quantity representative of an Internet network.

5. The system as claimed in claim 1, in which the sensor is configured to sense a physical quantity representative of an electrical grid.

6. The system as claimed in claim 1, wherein the transmitter of radio signals is configured to implement a time division multiple access communication protocol.

7. The system as claimed in claim 6, wherein at least one terminal is configured to maintain the phase-wise timing of timeslots of the time division multiple access communication protocol in case of outage of access of the terminal to an external signal allowing the terminal to determine a timing phase for the timeslots.

8. The system as claimed in claim 6, wherein at least one terminal comprises a clock as well as a synchronization device linked to the Internet network, the synchronization device being configured to synchronize the clock with the Internet network.

9. The system as claimed in claim 6, wherein at least one terminal comprises a clock as well as a synchronization device linked to a clock radio-transmission system, the synchronization device being configured to synchronize the clock with the clock radio-transmission system.

10. The system as claimed in claim 6, wherein at least one terminal comprises a clock as well as a synchronization device linked to a satellite-based position system, the synchronization device being configured to synchronize the clock with the satellite-based position system.

11. The system as claimed in claim 6, wherein at least one radiocommunication terminal is configured to dispatch radiocommunication signals in a shared frequency band, said terminal comprising a sensor of phase of an electrical grid connected to the terminal, said terminal being configured to carry out a temporal division of the shared frequency band into several timeslots per period of the electrical grid, each timeslot having a known ratio to the phase of the electrical grid, the transmitter being configured to transmit on the shared frequency band in the timeslots in compliance with a time division multiple access schedule.

12. The system as claimed in claim 11, wherein at least one terminal comprises a phase synchronization device linked to the sensor of phase of the electrical grid.

13. The system as claimed in claim 12, wherein at least one terminal comprises an energy reserve allowing the terminal to operate in an autonomous manner, the at least one terminal configured to maintain the phase-wise timing of the timeslots in case of outage of the electrical grid or in case of abrupt change of the phase of the electrical grid.

14. (canceled)

15. The system as claimed in claim 11, wherein the sensor of phase of the electrical grid comprises at least one of a connector that can be hooked up to the electrical grid and an antenna to pick up the oscillations of the electrical grid.

16. (canceled)

17. The system as claimed in claim 11, wherein at least one terminal comprises a wired or wireless communication module to connect to a local network and/or to the Internet.

18. The system as claimed in claim 11, wherein at least one terminal comprises a wired or wireless communication module configured to connect to sensors, receive data from these sensors and upload the data to a serving station via the radiocommunication signals in the shared frequency band.

19. (canceled)

20. (canceled)

21. The system as claimed in claim 11, wherein the receiver is configured to listen to the shared frequency band and in which at least one terminal and the receiver are synchronized with one and the same electrical grid.

22. The system as claimed in claim 1, wherein the receiver is mounted on a vehicle.

23. (canceled)

24. (canceled)

25. The system as claimed in claim 1, which comprises at least one sensor linked to at least one terminal, the transmitter being configured to emit an item of information representative of a value sensed by at least one said sensor, the at least one sensor comprising a mobile telephone presence sensor.

26. (canceled)

27. The system as claimed in claim 1, wherein at least one terminal comprises: a receiver of a message emitted on a local network including said terminal; and a memory for at least one said message, the transmitter being configured to emit at least one signal representative of at least one said message.

28. The system as claimed in claim 1, which comprises a plurality of terminals, at least two of which terminals are linked together by a radiocommunication link, at least one terminal forming concentrator of signals emitted by the two said terminals.

29. (canceled)

Description

BRIEF DESCRIPTION OF THE FIGURES

[0116] Other advantages, aims and particular characteristics of the invention will emerge from the nonlimiting description which follows of at least one particular embodiment of the device and of the method which are the subject of the present invention, in relation to the appended drawings, in which:

[0117] FIG. 1 is a basic illustration of a telecommunications system according to one embodiment of the invention,

[0118] FIG. 2 is schematic illustration of an “intelligent” house equipped with a terminal according to one aspect of the invention,

[0119] FIG. 3 is a schematic illustration of a use of a telecommunication system according to one embodiment of the invention within the framework of an emergency situation,

[0120] FIG. 4 is a schematic illustration of a house equipped with intelligent electricity gas and water meters, configured as terminals compliant with an aspect of the invention,

[0121] FIG. 5 is a timechart illustrating the synchronization of a telecommunication system with the electrical grid,

[0122] FIG. 6 is a schematic illustration of the system which is the subject of the present invention and

[0123] FIG. 7 is a schematic illustration of the method which is the subject of the present invention.

DESCRIPTION OF EXEMPLARY EMBODIMENTS OF THE INVENTION

[0124] The present description is given without implied limitation, each characteristic of one embodiment being able to be combined with any other characteristic of any other embodiment in an advantageous manner.

[0125] It is noted henceforth that the figures are not to scale.

[0126] A particular embodiment of the system 100 which is the subject of the present invention is observed in FIG. 6. This alert and disaster management system 100, comprises: [0127] at least one radiocommunication terminal 105, the terminal comprising: [0128] a means 106 of communication, via a data network, with a central computer system, [0129] a sensor 110 of a value of a physical quantity representative of the operation of the network connected to the terminal, [0130] a means 115 for determining a failure of the network as a function of the sensed value, [0131] a transmitter 120 of radio signals in case of failure determination and [0132] the central computer system 300, linked via the data network to at least one terminal, comprising: [0133] a memory 304 for information in respect of geographical positioning of at least one terminal, [0134] a detector 305 of anomaly of network link between the computer system and at least one terminal, [0135] a means 310 for providing an alert in case of anomaly, [0136] a means 315 for providing an item of information representative of the stored positioning of at least one said terminal exhibiting a network link anomaly and [0137] at least one mobile radiocommunication receiver 125 configured to receive the radio signals emitted by at least one terminal.

[0138] The term “terminal” 105 designates any device able to emit, and optionally to receive, communication signals according to two channels: [0139] according to a first channel formed by the means 106 of communication and the data network and [0140] according to a second channel formed by the transmitter 120 of radio signals and of the receiver 125.

[0141] In variants, the means 106 of communication and the transmitter 120 can be merged.

[0142] Preferentially, each terminal 105 is unitary, that is to say that the set of components of this terminal is integrated into a single casing. However, the terminal 110 can also be modular and, in this case, each component can be distributed in a plurality of devices communicating with one another. Each terminal 105 can, thus, implement a nano-computer, of Raspberry PI (trademark) type.

[0143] Preferentially, the terminal 105 comprises a thermally insulating casing which is fireproof and/or gastight and/or watertight. The person skilled in the art can, here, draw inspiration from the characteristics of black boxes in the field of aeronautics.

[0144] In a schematic manner, the function of each terminal 105 consists in tracking the evolution of a value which is determined, as a function of the terminal 105, and of determining as a function of this value the presence of a failure of a network. When a failure is detected, the terminal 105 passes to an “alert” mode and transmits an item of information representative of the detection of this failure or else an item of information representative of a value sensed elsewhere by the terminal 105. Said value depends on at least one third-party sensor, external or internal, to the terminal 105. Each third-party sensor can be of any type, such as: [0145] a presence sensor, [0146] a sensor of a determined physical quantity, [0147] a sensor of presence of mobile telephones in proximity, [0148] a sensor of presence of peripherals associated with a Wifi or Bluetooth network in proximity.

[0149] According to the applications, the terminal 105 can also communicate the values sensed by the third-party sensors by virtue of the means 106 of communication. This means 106 of communication is of wired or wireless type and suitable for communicating over the Internet or a cellular data network, for example.

[0150] This allows the terminal 105, in case of disaster, to continue to emit signals toward the central computer system, through at least one receiver 125.

[0151] The central computer system 300 is customarily linked to at least one terminal 105 by way of the data network considered. Thus, computer system 300 and terminals 105 exchange data in a usual manner, in a unilateral or bilateral manner.

[0152] The computer system 300 is furnished with a detector 305 of anomaly of network link between the computer system and at least one terminal 105. This anomaly detector 305 depends on the type of data network considered. For example, this anomaly detector 305 can be software embedded in an electronic card linked to an interface, wired or wireless, for receiving signals arising from the data network. This software, detecting an absence of signals originating from a terminal 105, subsequent to the emission or otherwise of a request by the system 300, detects an anomaly. When a determined number of anomalies is detected by the detector 305, the system 300 passes to an alert mode, representative of a break of link with at least one terminal 105.

[0153] In case of alert, the means 310 for providing an alert provides, for example, a signal allowing the emission of an audible and/or visual alert signal to an operator. This allows the operator to command the setting into operation of at least one receiver 125 with a view to collecting data arising from at least one terminal 105 under break of link.

[0154] In case of alert, the means 315 for providing an item of geographical positioning information provides an item of information, stored by the computer system 300, in respect of geographical positioning of at least one terminal 105. This item of information can be: [0155] displayed on a screen, [0156] transmitted to a device for preparing an itinerary of a receiver 125, for example mounted on an autonomous vehicle such as a drone, [0157] transmitted to a satellite control device.

[0158] In case of display on a screen, an input by a user can serve as confirmation of emission of a command for deploying at least one receiver 125. The device for preparing a receiver 125 itinerary is, for example, a GPS navigation system embedded onboard the receiver 125.

[0159] Thus, as is understood, in embodiments, the computer system 300 comprises a device 306 for preparing an itinerary of at least one receiver 125, the itinerary being established as a function of at least one item of geographical positioning information provided.

[0160] This preparation device 306 is, for example, software configured to transmit the geographical coordinates of the terminals to a receiver 125 and/or to transmit an itinerary calculated at the level of the computer system 300. This device 306 includes, in variants, the system for communication between the computer system 300 and the receiver 125.

[0161] Thus, as is understood, in embodiments, the computer system 300 comprises a satellite control device 307, said satellite forming receiver 125.

[0162] This preparation device 307 is, for example, software configured to transmit the geographical coordinates of the terminals to a satellite forming receiver 125. This device 307 includes, in variants, the system for communication between the computer system 300 and the receiver 125.

[0163] In variants, the computer system 300 comprises a means for receiving a command (not referenced) for deployment of at least one receiver 125, such as a man-machine interface of any type. When a deployment command is received by the system 300, at least one receiver 125 is put into operation by the computer system 300. If this receiver 125 is mounted on an automatic vehicle, such as a drone, this automatic vehicle is directed toward a geographical zone where the terminal 105 is situated. Preferentially, at least one terminal 105 is thus geolocated. Alternatively, the receiver 125 can be a satellite placed in a state of active listening to the geographical zone.

[0164] Thus, as is understood, the system 100 which is the subject of the present invention makes it possible to measure the geographical impact of a disaster as a function of geographically distributed terminals 105 and to react immediately by deploying receivers 125 able to collect data emitted by said terminals 105.

[0165] This manner of operation is represented in FIG. 7.

[0166] In two particular embodiments envisaged, the function of the terminal 105 is to determine a failure of the Internet network or of the electrical grid.

[0167] When the function of the terminal 105 is to determine the failure of the Internet network, the sensor 110 is, for example, a network card coupled to a micro-processor, the micro-processor periodically commanding the network card to emit a request of “ping” type to a determined IP address. Alternatively, the network card can simply measure the periodic reception of packets contained in signals emitted by an Internet network access point, such as a set-top box within the framework of a Wifi link of the terminal 105. Thus, any value intrinsic to the Internet network can be sensed by the sensor 110, according to the preferences of the person skilled in the art to the case of application of the system 100.

[0168] The determination means 115 is in this case, for example, formed of software embedded on board the micro-processor and charged with ensuring the tracking of the value sensed by the sensor 110. As a function of a predetermined evolution, or adaptive evolution, that is to say evolving slowly with respect to the evolutions of the sensed value, the determination means 115 determines a failure of the Internet network.

[0169] For example, if the sensor 110 senses the reception of a response to a request of ping type to a determined IP address, the request being emitted at a regular interval by the terminal 105, an absence of response to the request for several consecutive intervals gives rise to the determination of a failure of the Internet network by the determination means 115.

[0170] When the function of the terminal 110 is to determine the failure of an electrical grid to which the terminal 110 is linked, the sensor 115 comprises, for example, a connector 145 that can be hooked up to the electrical grid and/or an antenna 150 to pick up the oscillations of the electrical grid. The sensed value is, for example, the oscillation phase of the voltage of the electric current or the power of said electric current. Thus, for example, in case of strong phase variation, the determination means 115 is liable to determine that a generator has been turned on.

[0171] The determination means 115 is in this case, for example, formed of software embedded on board the micro-processor and charged with ensuring the tracking of the value sensed by the sensor 110. As a function of a predetermined evolution, or adaptive evolution, that is to say evolving slowly with respect to the evolutions of the sensed value, the determination means 115 determines a failure of the electrical grid.

[0172] For example, if the sensor 110 senses an oscillation phase of the electrical voltage provided by the electrical grid, a gross change of said phase of the voltage gives rise to the determination of a failure of the electrical grid by the determination means 115.

[0173] An example of such a terminal 105 is provided in FIG. 1, at the reference 12 and 12′.

[0174] It is noted, moreover, that the terminal 105 can also be configured to detect the failure of a telephone network or of a cellular data network.

[0175] Upstream or downstream of the determination of a failure of the network, the terminal 105 can also implement a sensor (not referenced) of any physical value, such as a presence detector, a thermometer, a barometer or other according to the operator's desired application of the terminal 105.

[0176] If the terminal 105 determines a failure of the network, an item of information representative of this detection and/or an item of information representative of the sensed physical value is transmitted to the receiver 125. The transmitter 120 is, for example, an antenna configured to emit wireless signals destined for the receiver 125. This transmitter 120 is configured to transmit wireless signals on a frequency band lying between 222 and 225 MHz, for example. Preferentially, the transmitter 120 is an omnidirectional antenna making it possible, irrespective of the positioning and the inclination of the terminal 105, to emit radio signals.

[0177] In variants, if the terminal 105 determines a failure of the network, this terminal 105 actuates a human-presence detector and transmits an item of information representative of the number of presences detected to the receiver 125. Such a detector is, for example, a sensor of presence of mobile telephones in proximity to the terminal 105. Such a presence sensor implements, for example, an antenna configured to receive signals emitted on a cellular telephone network frequency and a detector of a signal power received by said antenna, a presence being determined for each signal whose said signal power received is greater than a determined limit value.

[0178] The receiver 125 is a communication means able to receive the signals emitted by each transmitter 120. This receiver 125 comprises, for example, an antenna for receiving wireless signals. The term “receiver” 125 is synonymous with the term “serving station” such as described in relation to FIGS. 1 to 5. Thus, it is noted that the receiver 125 can comprise a memory for received information and/or a means for transmitting said information destined for a dedicated computer system, such as an antenna for transmitting wireless signals for example. In variants, the receiver 125 also comprises a dynamic spectrum detector and/or a modulation presence detector. Such a receiver 125 is, for example, a drone comprising a broadband receiver, of “airspy” type.

[0179] In embodiments, the system 100 comprises a concentrator of information transmitted by at least one transmitter 120, this concentrator comprising a transmitter of information directed to the receiver 125.

[0180] Preferentially, the receiver 125 is mobile with respect to the terminals 105. This mobility is conferred on the receiver 125 by embedding said receiver 125 aboard a vehicle. Such a vehicle is, for example, a drone, an airplane, a motorbike or a satellite. When the receiver 125 is on board an automatic vehicle, this vehicle can exhibit a road plan, or flight plan, determined automatically as a function of positioning data in respect of the terminals 105 of the system 100.

[0181] Preferentially, at least one transmitter 120 is a narrowband transmitter and the receiver 125 is a broadband receiver, configured to pick up the information transmitted by the set of transmitters 120 of the system 100. Preferentially, at least one transmitter 120 is a very-high-frequency or ultra-high-frequency transmitter.

[0182] In embodiments, the signal transmitter 120 implements a time division multiple access communication protocol. These embodiments make it possible to avoid a collision of packets emitted by various terminals 105. The transmitter 120 may, or may not, be associated with a clock. In the case of an association of a terminal 105 with the phase of an electrical grid, the transmitter 120 is synchronized with the phase of said electrical grid, for example by detecting the zero-crossing of an alternating current. This phase can, moreover, be stored within the terminal 105, in a computer memory, so as to be able to be implemented even in case of failure of the electrical grid.

[0183] In embodiments, at least one terminal 105 is configured to maintain the phase-wise timing of timeslots of the time division multiple access communication protocol in case of outage of access of the terminal to an external signal allowing the terminal to determine a timing phase for the timeslots.

[0184] These embodiments are embodied, for example, by a memory implemented in said terminal 105 configured to store an item of information representative of a phase sensed at an instant at which access to the external signal was available.

[0185] Alternatively, this phase can be detected on the basis of packets received from the Internet network, from a satellite-based positioning system.

[0186] In embodiments, at least one terminal 105 comprises a clock as well as a synchronization device 130 linked to the Internet network, the synchronization device being configured to synchronize the clock with the Internet network.

[0187] The clock can be stored at the level of a network card or of a microprocessor, for example. The synchronization device 130 is, for example, a computer program embedded inside the network card or the micro-processor, this computer program controlling the synchronization of the clock with a clock external to the terminal 105.

[0188] In embodiments, the terminal 105 is linked to a clock radio-transmission system, by way of a radio signals receiver (not referenced). The synchronization device 130 is then configured to synchronize the clock with the clock radio-transmission system. To carry out this action, the synchronization device 130 reads, in a packet transmitted by the radio-transmission system, a clock value and applies this clock value to the terminal 105. Clock synchronization mechanisms are well known to the person skilled in the art and are not repeated here.

[0189] In embodiments, the terminal 105 is linked to a satellite-based position system, of GPS (for “Global Positioning System”) type for example, the synchronization device 130 being configured to synchronize the clock with the satellite-based position system. In these embodiments, the terminal 105 preferentially comprises a receiver (not referenced) of signals emitted by the satellite-based positioning system. To carry out this synchronization, the synchronization device 130 reads, in a packet transmitted by the satellite-based positioning system, a clock value and applies this clock value to the terminal 105. Clock synchronization mechanisms are well known to the person skilled in the art and are not repeated here.

[0190] An exemplary transmitter 120 is described, but not referenced, in relation to FIGS. 1 to 5, as regards the terminals 12 and 12′.

[0191] In alert mode, the terminals 105 preferentially emit the frames with a periodicity corresponding at the minimum to the sum of all the durations of the time windows, thereby corresponding to the case where a complete message can fit inside a single frame. In the other cases, the periodicity is the product of the sum of all the durations of the time windows with the number of frames which constitute a complete message.

[0192] Techniques for optimal sharing of frequencies can be combined with time sharing techniques, since the frames to be transmitted are short compared with the duration of visibility of a black box by the vector carrying the receiver. The number of RF transmission channels is then the product of the possible number of frequency-wise channels and the number of time windows.

[0193] If the duration of the visibility of a terminal 105 by the mobile receiver 125 equals several times the emission periodicity of the terminal 105, then there is redundancy of messages, and techniques, of accumulation in particular, can exploit this redundancy to improve the signal-to-noise ratio and the RF detection of the frames.

[0194] Preferentially, at least one receiver 125 operates in broadband and picks up the totality of the signals in radio visibility. The separation of the frequency channels and/or temporal channels, being able to be carried out subsequently, either within the receiver 125 so as to reduce the data volume to be transmitted, or downstream by a computer system 300, by decomposition of the dynamic spectrum of the raw signal recorded. The reduction of the volume of data to be retransmitted decreases greatly which is useful for the use of satellites.

[0195] At least one terminal 105 can be used as concentrator to group together the information originating from other, so-called “auxiliary”, terminals, in which cases these terminals are connected together, either by wired link, or by wireless link (Wifi, radiofrequencies), so as to limit the number of emitters in a geographical sector.

[0196] In embodiments, at least one radiocommunication terminal 105 is configured to dispatch radiocommunication signals in a shared frequency band, said terminal comprising a sensor 135 of phase of an electrical grid connected to the terminal, said terminal being configured to carry out a temporal division of the shared frequency band into several timeslots per period of the electrical grid, each timeslot having a known ratio to the phase of the electrical grid, the transmitter 120 being configured to transmit on the shared frequency band in the timeslots in compliance with a time division multiple access TDMA schedule.

[0197] Such a terminal 105 is described in relation to FIGS. 1 to 5, under the references 12 and 12′.

[0198] In embodiments, at least one terminal 105 comprises a clock and/or a phase synchronization device 130 linked to the electrical grid phase sensor 135. Such a synchronization is described in relation to FIGS. 1 to 5.

[0199] In embodiments, at least one terminal 105 comprises a reserve 140 of energy allowing the terminal to operate in an autonomous manner. This energy reserve 140 is, for example, a battery or an electrical energy accumulator.

[0200] In embodiments, at least one terminal 105 is configured to maintain the phase-wise timing of the timeslots in case of outage of the electrical grid or in case of abrupt change of the phase of the electrical grid.

[0201] In embodiments, at least one receiver 125 comprises an emitter 126 of a command to stop transmission directed to at least one terminal 105, each terminal 105 ceasing to transmit signals on receipt of said command.

[0202] Preferentially, at least one terminal 105 is associated with a terminal identifier, determined during the manufacture of said terminal 105 or allotted by the computer system 300. The receiver 125 may, or may not, know at least one terminal identifier and associate at least one of said identifiers with the stop command. When a terminal 105 receives a stop command, a verification of the correspondence between the terminal identifier of the command and the terminal identifier recorded in the terminal 105 takes place. If the terminal 105 determines that the identifiers correspond, the transmission of signals ceases. This cessation can be carried out at the level of the transmitter or of a central processor for actuation of said terminal 105.

[0203] Such an embodiment is described in relation to FIGS. 1 to 5.

[0204] In embodiments, the electrical grid phase sensor 135 comprises a connector 145 that can be hooked up to the electrical grid.

[0205] Such an embodiment is described in relation to FIGS. 1 to 5.

[0206] In embodiments, the electrical grid phase sensor 135 comprises an antenna 150 to pick up the oscillations of the electrical grid.

[0207] Such an embodiment is described in relation to FIGS. 1 to 5.

[0208] In embodiments, at least one terminal 105 comprises a wired or wireless communication module 155 to connect to a local network and/or to the Internet.

[0209] Such an embodiment is described in relation to FIGS. 1 to 5.

[0210] In embodiments, the system 100 which is the subject of the present invention comprises at least one sensor 400 linked to at least one terminal 105, the transmitter 120 being configured to emit an item of information representative of a value sensed by at least one said sensor 400. At least one sensor 400 is, for example: [0211] a presence sensor, [0212] a sensor of a determined physical quantity, such as smoke, fire, water or gas for example [0213] a sensor of presence of mobile telephones in proximity, [0214] a sensor of presence of peripherals associated with a Wifi or Bluetooth network in proximity.

[0215] In embodiments, at least one sensor 400 is a mobile telephone presence sensor. Such a sensor 400 implements, for example, an antenna configured to receive signals emitted on a cellular telephone network frequency and a detector of a signal power received by said antenna, a presence being determined for each signal whose said signal power received is greater than a determined limit value.

[0216] In embodiments, at least one terminal 105 comprises: [0217] a receiver 121 of message emitted on a local network including said terminal 105, preferentially wireless and [0218] a memory 122 for at least one said message,
the transmitter 120 being configured to emit at least one signal representative of at least one said message.

[0219] The receiver 121 is, for example, a wireless antenna operating on a local network of Wifi type. Alternatively, the local network is a wired local network. The transmitter emits, for example, the stored messages or an indicator of a stored message accessible on request of the receiver 125.

[0220] In embodiments, the system which is the subject of the present invention comprises a plurality of terminals 105, at least two of which terminals are linked together by a radiocommunication link, at least one terminal forming concentrator of signals emitted by the two said terminals.

[0221] The term “concentrator” signifies that the so-called concentrator terminal records signals to be transmitted on behalf of each non-concentrator terminal associated with said concentrator terminal. The transmission of these signals can be done in full, or limited to the transmission of an indicator of these signals.

[0222] In embodiments, at least one terminal 105 comprises a wired or wireless communication module 155 to connect to sensors 400, receive data from these sensors and upload the data to a serving station via the radiocommunication signals in the shared frequency band.

[0223] Such an embodiment is described in relation to FIGS. 1 to 5.

[0224] In embodiments, at least one terminal 105 comprises a buffer memory 160 to save data of connected sensors.

[0225] Such an embodiment is described in relation to FIGS. 1 to 5.

[0226] In embodiments, the receiver 125 is configured to listen to the shared frequency band.

[0227] Such an embodiment is described in relation to FIGS. 1 to 5.

[0228] In embodiments, at least one terminal 105 and the receiver 125 are synchronized with one and the same electrical grid.

[0229] Such an embodiment is described in relation to FIGS. 1 to 5.

[0230] In embodiments, the receiver 125 is mounted on a vehicle 200.

[0231] Such an embodiment is described in relation to FIGS. 1 to 5.

[0232] In embodiments, the vehicle 200 is a drone or a car.

[0233] Such an embodiment is described in relation to FIGS. 1 to 5.

[0234] Thus, as is understood, the system 100 operates in the following manner:

[0235] A set of terminals 105 is positioned geographically on a site to be protected by operators. An item of positioning information in respect of the terminals 105 is thereafter stored at the level of the system 100, either in a memory of each said terminal 105, or in a memory of a dedicated computer system, embedded in the receiver 125 or linked to said receiver 125. This item of positioning information associates an identifier of terminal 105 with an item of positioning information. This item of positioning information can be geographical, via the incorporation of a device of GPS type in the terminal 105, or of positioning on a data network, such as an IP address for example. The identifier of terminal 105 can be determined during the manufacture of said terminal 105 or configured manually by an operator or automatically, via the computer system generating identifiers.

[0236] These terminals 105 thus operate in the manner of aeronautical black boxes. When a terminal 105 determines a failure of a network to which this terminal 105 is connected, this terminal 105 emits an alert signal directed at the receiver 125. The receiver 125 then notifies a human operator or another data system connected to the receiver 125. This notification allows, for example, the dispatching of emergency aid into priority zones, or the dispatching of additional receivers 125.

[0237] We detail, hereinafter, an exemplary manner of operation of the system 100 which is the subject of the present invention:

[0238] To cope with an earthquake in California, the city of San Francisco equips certain buildings with a network of prepositioned fixed terminals 105. These terminals 105 permanently collect physical parameters, for example the ambient temperature, as well as the presence of mobile telephones in proximity.

[0239] During a disaster, electricity and the usual means of communication are out of service.

[0240] A large number of terminals 105 are then disconnected from the Internet and/or detect a strong phase shift on the electrical energy, due to an electrical energy generator being turned on. These terminals 105 pass to “alert” mode. These terminals 105 emit, in a loop, signals around 225 MHz, in the temporal and frequency channel which they were allotted beforehand as a function of their location, and, as long as there is energy available in the batteries.

[0241] A computer system, linked to mobile receivers 125, detects the absence of response of a large number of terminals 105 on a data network linking terminals 105 and computer system. Human intervention may be necessary to validate the presence of an event. In case of absence of response, the computer system configures flight plans for drones, furnished with receivers 125, to collect data preferentially in the zone of the calamity and record the information thus collected for the ground segment.

[0242] In less than two hours, the first data are collected. The modulation traces which were detected on board are analyzed, for example to remove redundancies, detect evolutions, etc. It is possible to indicate, on a map, human presence, fires, floods etc. Detection and processing remain possible as long as there is energy in the terminals 105 when terminals 105 and receivers 125 are within range of one another.

[0243] If the receiver 125 is embedded on board a satellite, each satellite must preferentially be of a the size of a few cubic decimeters and weigh less than ten kilograms. The dimensioning factor is the receiving antenna since the link budget presents management difficulties. Such satellites preferentially fly at low altitude (500-800 km) so as to limit energy consumption, to pass back frequently over one and the same zone and to be economical to launch. The number of satellites depends on the geographical expanse to be covered with the system 100.

[0244] Preferentially, a 2 GHz transceiver is necessary for the remote control, telemetry of the terminals 105.

[0245] FIG. 1 shows, in a schematic manner, a telecommunications system 10 comprising terminals 12 and 12′, a drone 14 acting as mobile serving station, a pylon 16 acting as stationary serving station and a control center 18.

[0246] In the embodiment illustrated, the terminals 12, 12′ are connected to sensors 20 (by wire or wirelessly) and act as telecommunications relay. The terminals 12, 12′ may be connected to the Internet 22 and may possess an IP address. According to a preferred embodiment, the terminals 12, 12′ are configured as domestic routers.

[0247] The terminals 12, 12′ are hooked up to the electrical grid 24. They have an energy reserve, for example an accumulator or a battery 26 powered by a charger 28, which allows them to operate in case of current outage.

[0248] The terminals 12, 12′ can be configured to transmit their messages using the Internet network 22.

[0249] In the case where Internet access is unavailable or prohibited (this could be the case permanently for a given terminal), the terminals 12, 12′ place themselves in a mode of operation (for example an alert mode) in which the messages containing the data to be transmitted destined for the control center 18 are dispatched through a common frequency resource, that is to say a shared radiofrequency band. In this case, the terminals 12, 12′ transmit their messages in the form of radioelectric signals which are received by a serving station 14, 16 and relayed by the latter to the control center 18.

[0250] This second mode of operation will be described in greater detail hereinafter. Each terminal is equipped with a sensor of phase of the electrical grid, thereby allowing it to synchronize with the electrical grid 24. The frequency of the electrical grid 24 being maintained tightly at its nominal frequency (normally 50 Hz or 60 Hz) by the operators, all the terminals 12, 12′ are mutually synchronized by transitivity. In preferential variants, the terminals 12, 12′ emit on the shared frequency band while complying with a TDMA schedule.

[0251] FIG. 5 illustrates how a TDMA schedule can be synchronized with the electrical grid. The reference number 30 designates the sinusoidal voltage of the phase conductor taken as reference. The electrical grid is assumed to employ three phases (three-phase current) mutually shifted by 120°. As explained above, there therefore exists a priori an uncertainty as regards the phase to which a terminal is synchronized. To take account of this, each period of the alternating current is divided into N slots, N being a multiple of 3 (in the case of FIG. 5, N=12) and the number of independent TDMA channels is fixed at n=N/3. In FIG. 5, the TDMA channels, which are 4 in number, are denoted A to D. The base pattern A-B-C-D repeats at triple the frequency of the alternating current. Henceforth, each terminal synchronizing in this way with one of the three phases of the three-phase network produces the same division of the time.

[0252] The TDMA schedule defining which terminal is entitled to use which timeslot(s) for the transmission of its messages is known to the control center and possibly to the serving stations. On the terminals side, each terminal knows at least which timeslot it is entitled to use at which moment. For a given terminal, the schedule is advantageously static, that is to say fixed once and for all, for example when brought into service at the place of installation, preferably as a function of the assignment of the slots to the geographically neighboring terminals. For example, if, in the neighborhood of the place of installation of a terminal, there exists another terminal which uses channel A, channel C will preferably be assigned to the new terminal, the latter being furthest from channel A. If there are other terminals in the neighborhood, their transmission slots are also taken into account. According to one embodiment of the telecommunication method, each terminal can emit on its allocated channel at any moment. It is however clear that onward of a certain geographical density of the terminals, collisions between messages of various terminals having access to the same channel cannot be excluded with certainty, except by taking additional measures to adjust access. Other embodiments of the telecommunication method can therefore make provision for additional restrictions on the transmission of messages so as to reduce the probability of collisions. For example, the maximum length of a message can be defined as can the maximum number of messages that a terminal is entitled to emit per unit time.

[0253] The TDMA schedule is stored in a database 32 of the control center 18. The database 32 can be a centralized database (as shown by FIG. 1) or decentralized database. Authorized users, for example the serving stations 14, 16, can consult the TDMA schedule (or a part of the latter) by way of a server 34 connected to the Internet 22 and/or to a local network.

[0254] Preferably, each serving station knows the timeslots and possibly the frequency sub-bands liable to contain messages of the terminals in their coverage zone. This allows them to monitor the radiofrequency band more effectively than without a priori knowledge of the TDMA schedule. However, it is also possible to use a broadband serving station capable of monitoring the whole electromagnetic spectrum liable to be used by the terminals.

[0255] In variants, the terminals 105 emit on a shared frequency band according to an FDMA mode where frequency sub-bands are allotted to each terminal 105, either during manufacture, or dynamically. This allotting can be carried out automatically by the central computer system 300 when setting the system 100 into operation. This allotting can be carried out subsequent to a step of determining the frequency sub-bands to be allotted to each terminal, so that as a function of the geographical positioning of each said terminal 105 and of the effective range of radio communication envisaged, two terminals 105 do not emit in one and the same frequency sub-band if these two terminals 105 are close. The allotting can be carried out by the implementation of the data network linking terminals 105 and central computer system 300.

[0256] In variants, the terminals 105 emit on a shared frequency band according to an FDMA mode and a TDMA mode. In variants, the terminals 105 emit on a shared frequency band according to a CDMA mode. In these variants, the same allotting mechanics can be carried out to avoid collisions.

[0257] A system as shown by FIG. 1 can serve as infrastructure for multiple applications, for example telemonitoring, remote logging of meters, launching of alerts, etc. Service providers can, for example, install sensors 20 and connect them (by wire or wirelessly) to a terminal 12. The data of the sensors 20 are processed by the microprocessor 36 of the terminal 12 for retransmission to the control center 18. This retransmission can be done through the Internet 22 or by radiocommunication to a serving station 14, 16. At the control center 18, the data of all the terminals 12, 12′ are processed, stored and/or forwarded (for example to the service providers). It is noted that the data of the sensors 20 could be encrypted so that only the service provider can read them.

[0258] FIG. 2 shows an “intelligent” house 38 equipped with numerous devices capable of communicating. These connected devices comprise, in the case illustrated, smoke detectors 40, presence detectors 42, a meter 25 for electricity 44, a gas meter 46, a water meter 48, a refrigerator 50, a washing machine 52, a television 54 and a domestic router 56 which is configured as a terminal such as described above and also representing a Wifi access point.

[0259] The router 56 can operate in different modes of operation. In a first mode of operation, the router 56 retransmits the data of the sensors via an Internet link 23. In a second mode of operation, the router 56 retransmits all or only some of the data of the connected devices by radio to a serving station 14, 16, by using a TDMA protocol such as described above. The router 56 is programmed so as to place itself in the second mode of operation as soon as there is an outage of the Internet link 23 and/or of the supply of current.

[0260] The router 56 comprises an internal clock that it synchronizes to the electrical grid 24 as well as an energy reserve (see FIG. 1). In case of outage of the current, the energy reserve allows the router to operate, in particular, to supply its internal clock with energy, to receive data of connected devices capable of operating in an autonomous manner, to process these data and to retransmit them by radio. The internal clock allows it to maintain synchronization with the other terminals and the serving stations at least for a certain time.

[0261] The capacity of the terminals to operate in an autonomous manner has a beneficial application in the field of search and rescue of people in case of natural catastrophe or catastrophe of human origin (for example earthquake, tornado, tsunami, flood, explosion, fire, etc.). In such an application, the terminals act as radiobeacons for locating people or relaying other critical information. Each terminal stores the data of the connected presence detectors in a buffer memory. As and when new data are received, they are recorded and replace the older data. The collection of new data is, however, interrupted as soon as the terminal passes to the alert mode so as to prevent potentially corrupted data overwriting the latest valid data. Thus, in case of calamity, the terminals can transmit messages indicating, for example, the number of people present and their location. The emergency aid services preferably use a drone 14 configured as a serving station to overfly a ravaged zone and to collect information. The coordination of search and rescue operations will be able to be based, inter alia, on this information.

[0262] FIG. 3 illustrates the use of a telecommunication system according to one embodiment of the invention within the framework of an emergency situation. In risk zones, for example around the Seveso site 58 and its surroundings, in a nuclear installation 60 and its surroundings, etc. the telecommunication system is particularly useful for conveying information to an intervention and rescue coordination center 62. In case of accident 64, the emergency aid services can overfly the calamity-stricken zone with a drone 14 and thus collect the messages transmitted by the terminals 12.

[0263] FIG. 4 shows another application of a telecommunication system according to a very beneficial embodiment of the invention. In the examples of FIGS. 1 and 2, the terminals serve as relays or as information routers. In the example of FIG. 4, the terminals are integrated into the devices from which the information to be transmitted originates, in particular into an electricity meter 64, a gas meter 66 and water meter 68. Each of these devices communicates its information to a serving station in an individual manner. Each of the devices synchronizes with the electrical grid and emits while complying with the TDMA schedule. The fact that the terminals are synchronized is of great benefit, since the probability of collisions is thereby automatically reduced with respect to an asynchronous system. It should be noted that the probability of collisions is already reduced on account of the simple fact of introducing a granularity of the time, that is to say on account of the fact of imposing slots to be complied with. The probability of collisions can be yet further reduced by the intelligent allocation of slots or of groups of slots to the terminals. The meters are preferably read with the help of a mobile serving station, mounted e.g. on a drone 14 or a car 70. Optionally, the mobile serving station can emit a signal triggering the emission of the messages by the terminals that have received the signal. An advantage of this approach would be that the terminals concerned do not need to emit their messages regularly but can remain silent most of the time.

[0264] Like the terminals, the serving stations can also be designed to synchronize to the mains. A mobile serving station can be synchronized to the mains before embarking on its mission—in this case, the internal clock of the mobile station is synchronized with the mains for a certain time. When the mobile station is unplugged, the internal clock will allow it to remain synchronized with the terminals for a certain time, which depends on the quality of the internal clock. Another possibility of keeping a mobile station synchronized while it is on its mission is to establish a communication channel transmitting a clock signal from a monitoring center to the mobile station.

[0265] Whilst particular embodiments have just been described in detail, the person skilled in the art will appreciate that diverse modifications and alternatives to them can be developed in the light of the overall teaching afforded by the present disclosure of the invention. Consequently, the specific arrangements and/or methods described herein are presumed to be given solely by way of illustration, with no intention of limiting the scope of the invention.