EP3198886A1 - Architecture for observing a plurality of objects arranged in geographically separate locations and method of collecting the associated observation data - Google Patents

Abstract

The present invention relates to an architecture (10) for observing a plurality of objects (18A,..,18N) arranged in geographically separate locations, comprising: - a processing center (14) connected to a global computer network (29), - at least one airliner (15) comprising: + a cabin system (33) comprising a local network (47), + a first external communication module (41), + a second external communication module (42), and + an intermediate communication module (43) connected to the first external communication module (41) via the local network (47) and to the second external communication module (42) via the local network (47), where the intermediate communication module (43) sends digital data comprising observation data between the second external communication module (42) and the first external communication module (41) via the local network (47).

Description

 Observation architecture of a plurality of objects arranged in distinct geographical locations and method of collecting associated observation data

The present invention relates to an observation architecture of a plurality of objects arranged in distinct geographic locations.

 Such an observation architecture notably makes it possible to collect observation data relating to objects remote from a data processing center and possibly located in geographical locations that are difficult to access by other radio or data link means.

 Each object includes any living or non-living object whose remote observation is of interest for scientific, commercial, military, and other purposes.

 Such an object is, for example, an animal of an endangered species moving in a predetermined geographical area. The observation of this animal can then include the analysis of geographic coordinates of its movements, or the temperature of its body.

 Another example of such an object is a predetermined ground zone whose humidity is observed for agricultural purposes, in particular for watering adapted to plants grown in this zone.

 According to yet another example, such an object is a meter of gas, electricity or water whose readings are observed at a distance.

 There exist in the state of the art, different observation architecture for collecting observation data relating to these objects.

 To do this, it is known the use of electronic tags associated with each of these objects and for generating and transmit to the processing center the observation data relating to each of the objects.

 In general, the transmission of these data to the processing center is effected by means of radio signals in a predetermined bandwidth, in particular using low-orbiting satellites. This is particularly the case of ARGOS observation architectures.

 Thus, for this type of architecture, each electronic beacon is provided with a transmission unit for transmitting radio signals corresponding to observation data to one or more traveling satellites at a frequency in the corresponding bandwidth.

After receiving a radio signal corresponding to these data, the or each satellite retransmits the information collected on the ground via radio stations. reception. The data is then routed to treatment centers through specialized data communications networks or the internet.

 The processing of these data generally comprises an initial step of extracting the observation data generated by the electronic beacons from the radio signal received and transmitted by the satellite.

 However, this solution has a number of disadvantages.

 In particular, the radiated power of the radio signals by emission units corresponding to the objects must be relatively high so that these signals can be detected by the satellite or satellites located at high altitudes.

 To achieve such transmission power, the emission units are provided with a relatively powerful power source and an antenna whose performance is critical.

 In addition, the coverage area of a satellite comprises an area of a few thousand square kilometers which sometimes makes it difficult to extract observation data from a radio signal retrieved by this satellite.

 Indeed, when the number of electronic beacons in the coverage area of the satellite exceeds the processing or discrimination capacity of the satellite and / or the receiving station, the observation data can no longer be received normally.

 The purpose of the present invention is to propose an observation architecture that overcomes these disadvantages.

 For this purpose, the subject of the invention is an observation architecture of the aforementioned type, comprising:

 for each object, an electronic beacon comprising an observation unit capable of generating at least one observation datum relating to the corresponding object, and a transmission unit able to transmit a radio signal corresponding to at least one data item; generated observation,

 a processing center connected to a global computer network,

 at least one airliner comprising:

 + a cab system with a local network,

 + a first external communication module able to communicate with the processing center via the global computer network,

+ a second external communication module defining a field of visibility of the airliner for receiving and / or transmitting radio signals, and able to receive at least one electronic beacon located in the visibility range of the plane, at least one radio signal corresponding to at least one observation datum, and + an intermediate communication module connected to the first external communication module by the local network and the second external communication module by the local network, the intermediate communication module communicating digital data comprising observation data between the second communication module external and the first external communication module via the local network.

 According to other advantageous aspects of the invention, the observation architecture comprises one or more of the following characteristics, taken in isolation or in any technically possible combination:

 the intermediate communication module is able to communicate with the second external communication module to collect each received observation data, and with the first external communication module to transmit all the observation data collected to the treatment center via the global computer network.

 the airliner furthermore comprises a computer, and the intermediate communication module is software capable of being executed by the computer.

 the cabin system is an in-flight entertainment system, the local area network is a local multimedia network capable of transmitting multimedia data, and the in-flight entertainment system also comprises at least one multimedia terminal connected to the local multimedia network , the intermediate communication module is a software capable of being executed from the at least one multimedia terminal.

 - The intermediate communication module is a portable computer having a connection connection to the local network.

 the at least one electronic beacon comprises a control unit able to control the operation of the transmission unit according to a plurality of predetermined transmission rules.

the at least one electronic beacon further comprises a storage unit capable of storing a transit table comprising at least one time slot in which the corresponding electronic beacon is in the visibility range of the airliner, the transmission rules comprise the transmission of at least one radio signal corresponding to at least one observation data item in at least one time slot determined by the passing table. the at least one electronic beacon further comprises a reception unit able to receive at least one radio signal corresponding to a transmission instruction, and the transmission rules comprise transmitting at least one radio signal corresponding to an observation data item after receiving the transmission instruction.

 - The radio signal corresponding to a transmission setpoint is adapted to be transmitted by the second external communication module in the visibility field of the airliner.

 the at least one electronic beacon further comprises a reception unit able to receive at least one radio signal corresponding to a control setpoint, and the control unit is able to process the steering setpoint received by the receiving unit for modifying at least some of the transmission rules.

- The radio signal corresponding to a control setpoint is adapted to be transmitted by the second external communication module in the visibility field of the airliner.

 the architecture comprises a communication station capable of communicating with a roup of electronic beacons for collecting observation data generated by each of the group's electronic beacons, the intermediate communication module being able to communicate with the communication station to collect the observation data collected by the communication station.

 the first external communication module is connected to the global computer network via one or more satellites.

 each transmission unit is capable of transmitting radio signals according to a predetermined transmission protocol according to at least one bandwidth and at least some of the transmission protocols and / or bandwidths used by different transmission units are different.

 The subject of the invention is also a collection method implemented by such an observation architecture as previously described, comprising the following steps:

 generating observation data by the observation unit of at least one electronic beacon located in the visibility range of the airliner,

 - transmission of at least one radio signal corresponding to the observation data, by the corresponding transmission unit,

receiving the at least one radio signal by the second external communication module, - conversion of the received radio signal into the corresponding observation data and transmission of the observation data to the intermediate communication module via the local network,

 transmission of the observation data to the first external communication module by the intermediate communication module via the local network, and

 - Transmission of the observation data to the processing center by the first external communication module via the global computer network.

 These features and advantages of the invention will appear on reading the following description, given solely by way of nonlimiting example, and with reference to the appended drawings in which:

 FIG. 1 is a schematic view of an example of an observation architecture, the observation architecture comprising an intermediate communication module and a plurality of electronic beacons,

 FIGS. 2, 4 and 5 are diagrammatic views of various embodiments of the electronic beacons of FIG. 1,

 FIG. 3 is a schematic view of the intermediate communication module of FIG. 1, and

 FIG. 6 is a schematic view of another example of observation architecture.

 An observation architecture 10 is illustrated in FIG.

 The observation architecture makes it possible to observe at a distance a plurality of objects arranged in distinct geographical locations. The observation architecture 10 more particularly makes it possible to generate observation data relating to each of the objects, to collect all the observation data generated and to analyze the observation data collected in a centralized manner.

Each object is marked in FIG. 1 by a reference sign of the type 18 ^* where " ^* " is a letter that can vary between A and N. Also, according to the example of FIG. 1, fourteen objects are considered, only four being represented for convenience. Of course, depending on the case, other numbers of objects are possible.

 By "object" 18A to 18N is meant a living or non-living object having at least one physical parameter, whose remote observation is of interest for scientific, commercial, military, etc. purposes.

An example of such an object 18A to 18N is a predetermined agricultural ground area whose moisture is observed for agricultural purposes, or a boat whose position is observed for purposes of maritime surveillance. The objects 18A to 18N are arranged, for example, on the Earth's surface or in the oceans in different geographical locations.

 The objects 18A to 18N are arranged in a fixed or mobile manner in a predetermined mobility zone.

 The objects 18A to 18N are of the same nature or of different natures.

 In the example illustrated in FIG. 1, the observation architecture 10 comprises a plurality of electronic beacons, a processing center 14 and an airliner 15.

 Each electronic beacon is associated with an object 18A to 18N and makes it possible to generate at least one observation datum relating to this object 18A to 18N and to transmit it to the processing center 14.

Each tag is marked in FIG. 1 by a reference sign of the type 12 ^* where " ^* " is a letter that can vary between A and N as a function of the object 18 to 18N, to which this tag 12 ^* is associated.

 Each of the electronic beacons 12A to 12N comprises an observation unit connected to the corresponding object 18A to 18N, a transmission unit connected to the observation unit and a power supply source.

 In FIG. 2 illustrating the electronic beacon 12A associated with the object 18A, the observation unit is designated by the reference 20, the transmission unit by the reference 22 and the power supply source by the reference 24. .

 Since the electronic tags 12A to 12N are substantially identical, the references

20, 22 and 24 may subsequently be used in connection with any of the tags 12A-12N.

 The observation unit 20 is a detector capable of generating at least one observation data relating to the corresponding object 18A to 18N. This observation data item comprises, for example, a numerical value corresponding to one or more physical parameters observed in relation with this object 18A to 18N.

 Thus, for example, for an object 18A to 18N corresponding to an agricultural zone on the ground, the observation unit 20 of the corresponding tag 12A to 12N comprises a humidity detector able to measure the humidity of this zone and to generating an observation data item comprising a numerical value of this measurement.

For an object 18A to 18N corresponding to a vessel to be monitored, the observation unit 20 of the corresponding beacon 12A to 12N comprises a detector capable of locating the boat from a geolocation system and generating a data item. observation including, for example, three numerical values corresponding to the geographical coordinates of this boat. The transmission unit 22 is an emitter capable of transmitting one or more radio signals corresponding to digital data.

 The transmission unit 22 is more particularly capable of transmitting one or more radio signals corresponding to each observation datum generated by the observation unit 20.

 The transmission of digital data by the transmission unit 22 is in accordance with one of the wireless digital data transmission protocols known per se.

 More particularly, this transmission protocol defines several bandwidths for a range of for example up to 20 km.

 The power source 24 supplies power to the electronic beacon 12A at 12N corresponding and in particular, the observation unit 20 and the transmission unit 22 of this beacon.

 The power source 24 is, for example, an electric battery of capacity adapted to a life cycle and / or maintenance of the tag 12A to 12N corresponding.

 Alternatively, at least some of the transmit units of the tags 12A-12N differ by the transmission protocols and / or the bandwidths used.

 The processing center 14 is a centralized processing calculator comprising a software for analyzing all the observation data generated by the set of electronic beacons 12A to 12N.

 The observation data are processed according to an analysis technique known per se. This analysis technique depends in particular on the nature of the object 18A to 18N observed.

 The processing center 14 is connected to a global computer network 29. The processing center 14 is able to receive the observation data generated by the set of electronic beacons 12A to 12N and transmitted via the global computer network 29 via the airliner 15 as will be explained by the after.

 The global computer network 29 comprises any computer network linking the processing center 14 with one or more computers external to the observation architecture 10.

 The global computer network 29 is implemented via one or more ground stations, and / or one or more satellites. An example of such a global computer network 29 is the Internet.

According to FIG. 1, the airliner 15 comprises a computer 31, a cabin system 33, a first external communication module 41, said first module 41 in the following, a second external communication module 42, said second module 42 in the following, and an intermediate communication module 43, said intermediate module 43 in the following.

 The computer 31 includes a memory 45 able to store a plurality of multimedia files and a plurality of software, and a processor 46 capable of executing at least some of these software.

 The cabin system 33 is an in-flight entertainment system corresponding, for example, to an IFE type system (known as In-Flight Entertainment). The in-flight entertainment system is used in particular in airliners for the entertainment of passengers during the flight, including long-term.

 The in-flight entertainment system comprises a local area network 47 and a plurality of multimedia terminals connected to the computer 31 by the local area network 47.

 Each multimedia terminal is associated, for example, with a passenger to enable him to read the multimedia files stored in the memory 45 of the computer 31.

 Each multimedia terminal also makes it possible to control the execution of one or more software stored in the memory 45 of the computer 31.

 In addition, each multimedia terminal is a local computer including a connector allowing the passenger to connect a suitable type of electronic equipment such as, for example, a mobile phone or a laptop, to connect this electronic equipment to the local computer network 47.

 In the example illustrated, the local network 47 is a multimedia network comprising a wired network enabling the multimedia terminal to access in particular the computer 31 and for transmitting, for example, multimedia data between the multimedia terminal and the computer 31.

 Alternatively, the local area network 47 comprises a wireless network based, for example, on a Wi-Fi type communication protocol and allowing the passenger to connect a suitable type of electronic equipment such as, for example, a mobile phone or a mobile phone. laptop, at least one multimedia terminal and / or the computer.

 The first module 41 is for example an on-board electronic equipment allowing the airliner 15, and in particular the computer 31, to communicate with the global computer network 29 via radio signals.

 More particularly, the first module 41 is connected to the global computer network 29 via a satellite 50 when the aircraft 15 is in a coverage area thereof.

Alternatively or additionally, the first module 41 is connected to the global computer network 29 via terrestrial terminals according to one or more communication protocols known per se. These protocols correspond, for example, to those used by mobile telephony according to 3G or 4G type standards.

 The first module 41 is able to send and receive digital data via the global computer network 29.

 The first module 41 is in particular able to communicate with the processing center 14 via the global computer network 29.

 The first module 41 is further connected to the local network 47 to allow the multimedia terminals or any other equipment connected to the local network 47 to communicate with the global computer network 29 at least during certain phases of operation of the aircraft. line 15.

 The second module 42 is for example an on-board electronic equipment allowing the airliner 15, and especially the computer 31, to communicate with land or sea stations via radio signals.

 The second module 42 is connected to the local network 47 and comprises an antenna 48 and a conversion unit 49.

 The antenna 48 defines a DVR field of visibility of the aircraft for receiving radio signals in which the antenna 48 is able to receive radio signals.

 The antenna 48 further defines a DVE field of visibility of the aircraft in radio signal transmission in which the antenna 48 is able to transmit radio signals.

 The antenna 48 is in particular adapted to receive radio signals emitted by the transmission unit 22 from at least one electronic beacon 12A to 12N located in the DVR reception visibility range of the airliner 15.

 The antenna 48 is particularly adapted to receive radio signals emitted by the transmission units 22 of the beacons 12A to 12N according to one or more transmission protocols and / or one or more bandwidths used by the transmission units 22.

 In projection on the terrestrial surface, the field of visibility in DVR reception is delimited, for example, by a circle of diameter included, for example, between 300 and 400 km.

 The field of visibility in DVE transmission is, for example, substantially equal to the field of view in DVR reception.

Furthermore, the range of the transmission unit 22 of each of the beacons 12A to 12N is adapted so that the radio signals emitted by this transmission unit 22 can reach the receiving antenna 48 when the corresponding tag 12A to 12N is in the DVR reception range of view of the airliner 15.

 The conversion unit 49 converts the received radio signals into digital data and transmits this digital data in the local area network 47.

 The intermediate module 43 makes it possible to collect observation data received by the second module 42 from one or more electronic beacons 12A to 12N and to transmit the observation data collected to the processing center 14 via the global computer network 29 via the computer. intermediate of the first module 41.

 The intermediate module 43 is, according to the example of Figure 3, a portable computer 51 adapted to be connected to the local network 47.

 According to another exemplary embodiment, the intermediate module 43 is in the form of software stored in the memory 45 of the computer 31 and adapted to be executed by this computer 31. Its execution is, for example, controlled from a multimedia terminal.

 According to FIG. 3, the intermediate module 43 comprises a connection unit 52, a processing unit 54 and a control unit 56.

 The connection unit 52 makes it possible to connect the intermediate module 43 to the local network 47 via the connections of the multimedia terminal or, if necessary, via the Wi-Fi type protocol.

 The connection unit 52 makes it possible in particular to connect the intermediate module

43 to the second module 42 and to the first module 41 via the local network 47.

 The connection unit 52 is able to receive digital data coming from the local network 47 and in particular digital data corresponding to observation data transmitted by the second module 42.

 The processing unit 54 is able to process the received observation data, to memorize these observation data, and to transmit them to the first module 41 via the connection unit 52.

 The control unit 56 controls the operation of the connection unit 52 and the processing unit 54.

 An observation data collection method implemented by the observation architecture 10 according to the invention will now be described.

 During an initial step, each of the tags 12A to 12N is associated with one of the objects 18A to 18N.

In a next step, the observation unit 20 of each of these tags 12A to 12N generates one or more observation data relating to the corresponding object 18A to 18N. In a next step, the transmission unit 22 of each of these beacons 12A to 12N emits a radio signal corresponding to one or more observation data generated.

 In a next step, the antenna 48 receives radio signals emitted by beacons 12A to 12N located in the DVR reception visibility range of the airliner 15.

 The conversion unit 49 transforms the received radio signals into digital data for transmission to the intermediate module 43 via the local network 47.

 In a next step, the intermediate module 43 receives the digital data corresponding to the observation data.

 After a suitable processing, the observation data are stored in the intermediate module 43.

 This treatment makes it possible, for example, to remove any noises likely to appear during the transmission of the radio signals corresponding to the observation data.

 The observation data are stored temporarily in the intermediate module 43 to, for example, avoid the loss of these data when a connection to the global computer network 29 is not accessible.

 In a next step, the intermediate module 43 transmits the observation data to the first module 41 via the local network 47.

 In a next step, the first module 41 transmits the observation data to the processing center 14 via the global computer network 29.

 The processing center 14 thus receives the observation data generated by the beacons 12A to 12N situated in the visibility range of the aircraft 15 during its flight, and processes them appropriately.

 It will be understood that the observation architecture 10 of FIG. 1 has a certain number of advantages.

 The field of view DVR in reception of the aircraft 15 flying over the beacons 12A to 12N is smaller than that of a satellite. This makes it possible to considerably reduce the risk of collisions between radio signals emitted by distinct beacons 12A to 12N in the same bandwidth.

In addition, the requirements on the range of radio signals transmitted by the beacons 12A to 12N to an intermediate module 43 on board an aircraft are less important than those on the range of radio signals transmitted to the satellite or satellites. This then reduces the power consumption of the transmission unit 22 and thus increase the life cycle and / or maintenance of the power source 24 of each of the beacons 12A to 12N, especially when this power source 24 is a battery.

 Unlike existing collection systems, the transmission of radio signals between the beacons 12A-12N and the second external communication module 42 may be performed according to different transmission protocols and / or bandwidths for different beacons 12A-12N. The architecture 10 therefore does not imply the use of tags implementing a specific or mixed transmission protocol as in the state of the art.

 Finally, the use of the local network 47 and in particular its connection to the global computer network 29 already proposed by many airlines, makes it possible to minimize the costs associated with the installation of the intermediate modules 43 in the airliners 15.

 If in addition, each of the intermediate modules 43 is made in the form of software, these costs are even less important.

 Moreover, the subscriptions of these intermediate modules 43 to the connection to the global computer network 29 provided by the airlines, make it possible to make profitable the often important costs incurred by these companies to install equipment implementing this connection.

 In addition, since the intermediate module 43 is visible by the calculator

As a simple multimedia terminal or as entertainment software, its certification on the airliner 15 is relatively simple. Thus, in some cases, only the certification of the second external communication module 42 is sufficient.

 According to a complementary aspect of the invention, at least one of the beacons 12A to 12N, for example the beacon 12B associated with the object 18B and illustrated in more detail in FIG. 4, comprises, in addition to the observation 20, the transmission unit 22 and the power source 24 as previously described, a control unit 60 and a storage unit 61.

 The control unit 60 makes it possible to control the operation of the transmission unit 22 of the beacon 12B according to a plurality of predetermined transmission rules.

 The emission rules include, for example, the emission of one or more observation data in a given time slot, for example from information relating to a probability of passage from the aircraft to another. above the beacon 12B or other known place.

As a variant or in addition, the transmission rules include the transmission of one or more observation data at a specific time of passage from the airliner 15. This passage time is determined, for example, according to a pass table stored in the storage unit 61 and known beforehand.

 According to yet another complementary aspect of the invention, at least one of the beacons 12A to 12N, for example the beacon 12C associated with the object 18C and illustrated in greater detail in FIG. 5, comprises, in addition to the observation unit 20, the transmission unit 22, the power source 24 and the control unit 60 as previously described, a reception unit 62.

 The reception unit 62 allows the electronic beacon 12B to receive radio signals from other land, sea or air stations.

 The reception unit 62 is in particular adapted to receive radio signals corresponding to at least one transmission set point triggering the emission of the radio signals corresponding to at least one observation data item by the transmission unit 22.

 Thus, the transmission rules of the control unit 60 of this beacon 12C comprise the transmission of one or more observation data after receiving the transmission instruction.

 The transmission setpoint is, for example, generated by the control unit 56 of the intermediate module 43 and transmitted in the form of radio signals by the antenna 48 in the DVE transmission visibility range.

 Thus, when the beacon 12C is in the emission visibility range

DVE of the aircraft 15, it receives via its reception unit 22 the transmission instruction and sends in response one or more observation data via its transmission unit 62.

 This then makes it possible to warn the beacon 12C on the presence of the aircraft 15 nearby to then collect one or more observation data.

 In addition, the reception unit 62 is able to receive radio signals corresponding to control instructions.

 The control setpoints are intended for the control unit 60 and make it possible to modify one or more transmission rules.

 The control instructions are, for example, generated by the control unit 56 of the intermediate module 43 and transmitted in the form of radio signals by the antenna 48 of the aircraft 15.

 In a variant, the emission and / or piloting instructions are generated by any other equipment on board the aircraft 15 or placed on the ground near the corresponding beacon 12A to 12N.

The emission rules thus make it possible to adapt the emission of radio signals corresponding to observation data at the times of passage of In particular, this saves the electrical energy supplied by the power source 24.

 These emission rules are programmable and can be modified during the operation of the tags 12A to 12N.

 Another example of observation architecture 10 is illustrated in FIG.

 The observation architecture 10 of FIG. 6 is similar to the observation architecture 10 of FIG.

 However, unlike the observation architecture 10 of FIG. 1, the observation architecture 10 of FIG. 6 comprises, in addition, a communication station 70.

 This communication station 70 is placed near a group 72 of the beacons 12A to 12C in a fixed or mobile manner, and makes it possible to collect the observation data generated by each of the beacons 12A to 12C of this group 72.

 The communication station 70 includes a communication unit 74 for communicating with the beacons 12A to 12C. This allows in particular to reduce the range of communication compared to that used by tags 12A to 12N of Figure 1.

 The communication unit 74 of the communication station 70 furthermore allows communication with the intermediate communication module 43 of the aircraft 15 when the station is in the DVR reception and DVE emission visibility domains. plane 15.

 The observation data collection method implemented by the observation architecture 10 of FIG. 6 is similar to that of the observation architecture 10 of FIG.

 Indeed, the collection method implemented by the architecture of FIG. 6, further comprises a step in which the communication station 70 communicates with each of the beacons 12A to 12N of the group 72 to collect the data of observation, and a step in which the communication station 70 communicates with the intermediate module 43 to transmit the collected observation data.

 Of course, other examples of observation architecture are also possible.

Thus, according to an exemplary embodiment, the observation architecture 10 comprises a plurality of airliners each comprising an intermediate module 43. According to this embodiment, it is possible to ensure the visibility of each of the 12A to 12N beacons by at least one of the airliners 15 permanently or at least for a significant time slot of up to 12 hours per day .

 Of course, with the increase in the number of airliners equipped with an intermediate module 16, the probability of loss of observation data transmitted by the beacons 12A to 12N decreases which makes the operation of the architecture of observation 10 more effective.

Claims

1. - Architecture (10) for observing a plurality of objects (18A, .., 18N) arranged in distinct geographical locations, comprising:

 - for each object (18A, .., 18N), an electronic beacon (12A, .., 12N) comprising an observation unit (20) able to generate at least one observation data relating to the object (18A) , .., 18N), and a transmission unit (22) adapted to transmit a radio signal corresponding to at least one generated observation datum,

 a processing center (14) connected to a global computer network (29), - at least one airliner (15) comprising:

 + a cabin system (33) comprising a local area network (47), + a first external communication module (41) able to communicate with the processing center (14) via the global computer network (29), + a second module external communication device (42) defining a field of view (DVR, DVE) of the airliner (15) for receiving and / or transmitting radio signals, and adapted to receive at least one electronic beacon (12A, .., 12N) being in the field of visibility of the aircraft, at least one radio signal corresponding to at least one observation datum, and

+ an intermediate communication module (43) connected to the first external communication module (41) by the local network (47) and to the second external communication module (42) by the local network (47), the intermediate communication module ( 43) communicating digital data comprising observation data between the second external communication module (42) and the first external communication module (41) via the local area network (47).

2. - Architecture (10) according to claim 1, wherein the intermediate communication module (43) is able to communicate with the second external communication module (42) to collect each received observation data, and with the first module external communication device (41) for transmitting all the observed observation data to the processing center (14) via the global computer network (29).

3. - Architecture (10) according to claim 1 or 2, wherein:

- The airliner (15) further comprises a computer (31); and the intermediate communication module (43) is software capable of being executed by the computer (31).

4. - Architecture (10) according to any one of claims 1 to 3, wherein the cabin system (33) is an in-flight entertainment system and wherein the local network (47) is a local multimedia network capable of transmitting multimedia data, and wherein:

 the in-flight entertainment system furthermore comprises at least one multimedia terminal connected to the local multimedia network,

 - The intermediate communication module (43) is a clean software to be executed from the at least one multimedia terminal.

5. - Architecture (10) according to claim 1 or 2, wherein the intermediate communication module (43) is a portable computer having a connection connection to the local network (47).

6. - Architecture (10) according to any one of claims 1 to 5, wherein at least one electronic tag (12A, .., 12N) comprises a control unit (60) capable of controlling the operation of the unit transmission (22) according to a plurality of predetermined transmission rules.

7. - Architecture (10) according to claim 6, wherein:

 - The at least one electronic tag (12A, .., 12N) further comprises a storage unit (61) capable of storing a pass table comprising at least one time slot in which the electronic tag (12A,. ., 12N) is within the range of visibility (DVE, DVR) of the airliner (15),

 - Emission rules include the transmission of at least one radio signal corresponding to at least one observation data in at least one time range determined by the pass table.

8. - Architecture (10) according to claim 6 or 7, wherein:

the at least one electronic beacon (12A,... 12N) further comprises a reception unit (62) able to receive at least one radio signal corresponding to a transmission instruction, and the transmission rules comprise the transmission of at least one radio signal corresponding to an observation datum after reception of the transmission instruction.

9.- Architecture (10) according to claim 8, wherein the radio signal corresponding to a transmission setpoint is adapted to be transmitted by the second external communication module (42) in the field of view (DVE, DVR) of the airliner (15).

10. Architecture (10) according to any one of claims 6 to 9, wherein:

 the at least one electronic beacon (12A,... 12N) further comprises a reception unit (62) able to receive at least one radio signal corresponding to a control setpoint, and

 - The control unit (60) is adapted to process the control set received by the receiving unit (62) to modify at least some of the transmission rules.

1 1. - Architecture (10) according to claim 10, wherein the radio signal corresponding to a control setpoint is adapted to be transmitted by the second external communication module (42) in the field of view (DVE, DVR) of the aircraft line (15).

12. - Architecture (10) according to any one of claims 1 to 1 1, further comprising a communication station (70) adapted to communicate with a group (72) of electronic tags (12A, .., 12N ) to collect observation data generated by each of the electronic beacons (12A, .., 12N) of the group (72), the intermediate communication module (43) being able to communicate with the communication station (70) to collect the observation data collected by the communication station (70).

13. - Architecture (10) according to any one of claims 1 to 12, wherein the first external communication module (41) is connected to the global computer network (29) via one or more satellites (50).

14. Architecture according to any one of claims 1 to 13, wherein each transmission unit (22) is capable of transmitting radio signals according to a predetermined transmission protocol according to at least one bandwidth, and

at least some of the transmission protocols and / or bandwidths used by different transmission units (22) are different.

15. A method of collecting observation data implemented by the observation architecture (10) according to any one of claims 1 to 14, comprising the following steps:

 - generating an observation data item by the observation unit (20) of at least one electronic beacon (12A,... 12N) located in the visibility range (DVE,

DVR) of the airliner (15),

 - transmission of at least one radio signal corresponding to the observation data, by the corresponding transmission unit (22),

 receiving the at least one radio signal by the second external communication module (42),

 - conversion of the received radio signal into the corresponding observation data and transmission of the observation data to the intermediate communication module (43) via the local network (47),

 transmitting the observation data to the first external communication module (41) via the intermediate communication module via the local network (47), and

 - Transmission of the observation data to the processing center (14) by the first external communication module (41) via the global computer network (29).