FR2948245A1 - Earth observation device i.e. satellite grid, for e.g. defense field, has management module adapted such that stations are cooperated to provide access to observation data for rendering data to be accessible and viewed as single resource - Google Patents

Abstract

The device has a set of terrestrial reception and storage stations (5) provided with a storage unit, and connected to other reception and storage stations via a public terrestrial digital network. Each station has a management module adapted such that different stations are cooperated according to a satellite grid architecture in order to provide a permanent and transparent shared access to observation data from a satellite for rendering the observation data to be accessible and viewed as a single computer resource from any access point in the network.

Description

i GRID OF TERRESTRIAL STATIONS FOR RECEIVING AND RECORDING SATELLITE DATA

The invention relates to a device, designated throughout the text by satellite grid, comprising a plurality of earth stations communicating with each other, receiving and recording data. A terrestrial data receiving and recording station is a station provided with means for receiving observation data from at least one satellite orbiting the Earth, and data storage means (memory (s)). ) massive).

The invention also extends to a particular Earth observation observation device comprising: at least one constellation of satellites deployed in orbit around the Earth, each satellite comprising at least one data acquisition device; observation, and at least one device for transmitting these observation data to receiving antennas located on the surface of the Earth, - a plurality of earth stations for receiving and recording observation data distributed at the surface of the Earth, each terrestrial receiving and recording station being connected to at least one receiving antenna - in particular to a reception antenna of its own -, these stations being communicating with each other, - the transmission device of each satellite being adapted to be able to transmit observation data to any receiving antenna situated in a field of view of this device. transmission, each reception antenna being adapted to receive observation data transmitted by a satellite when said receiving antenna is located in the field of view of the transmission device of said satellite. Generally speaking, throughout the text, the term observation refers to any data acquisition, including measurements of physical parameters (temperatures, radiation, topographic data, images in the different wavelengths visible or not, etc.), and the terms Earth observation refer to any acquisition of Earth observation data - particularly from the Earth -. The invention aims in particular (although not exclusively) at providing such an Earth observation device more particularly intended for the acquisition and supply of terrestrial observation images and having a high ground-level resolution (10). meters or less, especially of the order of one meter) and a high frequency of global coverage of the Earth (2 weeks or less, including the order of the day).

Throughout the text, the global coverage frequency of the Earth refers to the frequency with which an observation device allows a complete shooting of the Earth. The observation of the Earth by satellite instruments began in the 1950s with the development of dedicated instruments including meteorology. Such instruments have continued to develop since then, alternately favoring, depending on the applications concerned, the ground-based resolution or the refresh rate. Today there are a large number of terrestrial observation instruments including LANDSAT, MODIS, IKONOS, QUICK BIRD, EROS, SPOT-5, SPOT-4, etc. These instruments can meet a wide range of imaging needs in areas as diverse as agriculture, cartography, cadastre, defense, environment, urban planning, telecommunications, risk management, resource management renewable etc. In any case, it is expected that the observation data received by the ground stations from the satellites will be repatriated to a central processing and archiving site making it possible to rationalize these various data, to update them, and to put them in place. coherence elected with others. Such a central site also makes it possible to distribute the observation data to users in a coherent and homogeneous manner as to their date and content. Such a repatriation of satellite observation data to a central site most often poses connection and bandwidth problems, given the very large volume of these data. For example, GB 2432486 plans to reuse the satellites of the constellation to repatriate data to a user ground station. Such a solution is extremely expensive and complex, and not completely satisfactory.

The instruments IKONOS, QUICKBIRD, EROS, etc., are very high resolution satellites that allow ground resolutions of the order of one meter. On the other hand, they have global refresh rates of over a month. MODIS, MERIS instruments, etc. are instruments with low resolutions but high refresh rates throughout the globe, in the order of 3 days to a week. In other words, in the light of the state of the art, the design of an instrument for the acquisition and supply of satellite observation data - in particular for terrestrial observation - is subject to contradictory constraints. There is thus a choice between an instrument with a high spatial resolution of the order of a meter, but with a low overall coverage frequency of the order of a week or a month, and an instrument with a high overall coverage frequency of the order of the day, but with a low spatial resolution of around 100 meters. Alternative solutions have been proposed to be able to benefit from a high frequency of coverage of predetermined specific areas, while benefiting from an interesting spatial resolution. They consist of using one or more satellites equipped with optical image acquisition instruments adapted to allow misalignment of these instruments. Indeed, the fact of being able to acquire images outside the natural trace of a satellite makes it possible to observe, during several successive rotations of the satellite, the same geographical area. For example, the SPOT satellite constellation provides acquisition capability and refreshing rate that allows you to acquire an image of a predetermined area of the globe each day. This constellation comprises a plurality of satellites placed in a polar, circular, sun-synchronous, and in-phase orbit relative to the Earth. Each satellite has a 26-day cycle. Each satellite includes optical instruments, data loggers and image transmission systems to ground receiving stations. The optical instruments are adapted to provide parametric oblique sights, so that the same region can be observed several times during the 26-day cycle. Data loggers are used to store the images on board if the satellite is not in visibility of a ground station. This constellation can thus have a high frequency of coverage of a specific area of the Earth. Nevertheless, the overall coverage frequency can not be less than 26 days. Even more, if the constellation is programmed so that many misfires are done during the 26-day cycle, the Earth's overall coverage frequency can be much greater than 26 days. Another disadvantage of such a solution lies in the cost of manufacturing, installation, management and maintenance of a constellation of satellites with misalignment. In particular, such a constellation requires the installation and management on the ground of a plurality of ground stations operated autonomously relative to each other and adapted to send the received image data to a central server for saving images in view of their distribution. In addition, each instrument of each satellite is piloted from the ground by a team of specialists to determine and optimize, according to the requests, the misalignment of the optical instruments. In addition, each satellite must include recorders to compensate for a lack of visibility of a ground station. Each satellite further includes a specific ground transmission system. Moreover, such a solution faces a major practical difficulty. Indeed, the coverage of the entire terrestrial globe by such a constellation of satellites in order to provide images having a spatial resolution of the order of one meter and a frequency of global coverage of the order of the day requires the management by the central server of the order of 1 500 terabytes of data per day, or 170 gigabytes per second, far exceeding the capacity of satellite transmission and ground treatment accessible with technologies and server architectures currently available. In addition, the same problem arises for data coming from space observation instruments from satellites. The invention aims to overcome these disadvantages, to overcome these difficulties and to propose a new concept of satellite observation data recording device which allows the recording of extremely large data streams, in particular can be much greater than 100 giga -bytes per second. More particularly, the invention aims to propose such a device that does not require a central distribution and / or data storage server.

The invention also aims at providing such a device - particularly an observation device - adapted to feed the mass information vectors available on the Internet. To this end, the invention relates to a device comprising a plurality of earth receiving and data recording stations provided with means for storing this data, each terrestrial receiving and recording station being associated with means for receiving data. observation data from at least one satellite orbiting the Earth, characterized in that: - the observation data received from at least one satellite - in particular from each satellite - are and remain distributed in the means for storing the different receiving and recording terrestrial stations, - each receiving and recording terrestrial station is functionally connected to the other terrestrial reception and recording stations by at least one digital network, and is provided with at least one a module, called a management module, adapted so that the different terrestrial receiving and recording stations are interposed nnected to each other by the various management modules via the digital network (s), according to an architecture, called satellite grid, adapted to allow permanent transparent shared access to said observation data from at least one satellite -particularly of each satellite- recorded distributed in the means (13) of storage of the different terrestrial stations (5), said satellite grid being adapted to make the set of recorded observation data distributed in the various earth stations reception and recording system accessible and viewed as a single observation dataset from any access point of the digital network (s) (15). Such a satellite grid according to the invention wherein a plurality of terrestrial receiving and recording satellite observation data stations are functionally interconnected with one another to automatically, permanently, and completely transparently share observation data which are and remain recorded in each station, and therefore distributed within the various receiving and recording terrestrial stations without being repatriated to a central site, constitutes a new object totally upsetting the design and the mode of operation of the observation instruments incorporating it. Indeed, such a satellite grid according to the invention is a constituent element of one or more device (s) of observation, in that such an observation device becomes totally inoperative in the absence of the satellite grid according to the invention. In addition, a device according to the invention has novel features: the recording capacity of such a device is virtually unlimited, since it is sufficient to multiply the number of terrestrial receiving and recording stations to increase the capacity of the device. recording and flow (in the limit of the flux that can be transmitted by the corresponding satellites); no central data referencing or data distribution server is needed; all observation data is accessible from any access point to the satellite grid, immediately and in real time; the operation of the device is automatically ensured without requiring any specific maintenance (in particular, a failure on any of the receiving and recording terrestrial stations does not affect the operation of the other receiving and receiving terrestrial stations; registration and the device in general); it can be dynamically associated with one or more satellites and / or one or more satellite constellations; it can be made available to users in an extremely simple, secure and reliable manner, with all possible and appropriate variants of access control for reading and / or writing and / or administration of the data recorded in the various stations. Advantageously, a device according to the invention is also characterized in that each terrestrial receiving and recording station is furthermore associated with means for transmitting data to at least one satellite, and in that it comprises at least one a remote control module adapted to be able to generate at least one command to at least one satellite and issue such a command on the satellite grid. Thus, the device according to the invention can be used not only for the reception of satellite observation data and their distributed recording, but also for the control of each satellite associated with the device according to the invention. Advantageously and according to the invention, said digital network of said satellite grid is a digital terrestrial network, in particular a public digital terrestrial network such as the Internet network.

Moreover, a device according to the invention is advantageously also characterized in that it comprises at least one terrestrial server, said geoportal server, connected by said digital network to said grid, this geoportal server being accessible to users via this digital network, and being adapted to manage permissions to access the grid by users. Such a geoportal server is however not a central server for recording or referencing data. A device according to the invention is thus free of any server or central site for recording and / or referencing and / or distribution of the observation data. The invention extends to an observation device as mentioned above, characterized in that it comprises a terrestrial device according to the invention formed by said terrestrial receiving and recording stations. In other words, in an observation device according to the invention, all the terrestrial receiving and recording stations are interconnected to form a terrestrial device (satellite grid) according to the invention.

Thus, in an observation device according to the invention, each terrestrial receiving and recording station is connected to at least one digital network and is provided with at least one module, called management module, adapted so that the different terrestrial reception and recording stations are interconnected to each other via said digital network according to an architecture, called satellite grid, adapted to allow permanent transparent shared access to the observation data recorded in the storage means of the various earth stations of receiving and recording, said satellite grid being adapted to be accessible and viewed as a single computing resource from any access point of said digital network. The management modules of each terrestrial station for receiving and recording a device according to the invention may be formed of grid modules, known in themselves, making it possible to produce computer grids, that is to say network-based computer architectures that enable the transparent sharing, by heterogeneous systems and applications, of data and / or computing resources (see in particular http://en.wikipedia.org/wiki/Grid Computing, Globus ToolKit, or the software suites gLite (EGEE), UNICORE, or Synfiniway (Fujitsu), or the e-mule software). However, nothing also prevents the development of specific grid modules.

In particular, computer grid technologies enable the distribution and sharing of significant computing capabilities by networking and interconnecting powerful computing resources. They are therefore used mainly by research centers and companies needing high processing power.

Although computational power is not a determining factor in the design of an observation device -especially an Earth observation instrument - the inventor has determined that the use of a grid technology for the permanent interconnection of terrestrial receiving and observational data recording stations makes it possible to confer new functionalities and, in reality, to obtain a distributed observation device enabling unmatched performance at a cost extremely reduced. In particular, the observation data can be distributed among the various receiving and recording terrestrial stations, and nevertheless be accessible from any network access point, immediately and in real time. Also, the observation data can be transmitted and / or exchanged between the receiving and recording terrestrial stations in a completely transparent manner, according to the needs or imposed constraints. Similarly, the interconnection of the receiving and recording terrestrial stations in the form of a grid facilitates the remote control of the satellite constellation from the ground.

The invention is particularly advantageously applicable to the recording of Earth observation data. In particular, advantageously, a device according to the invention is also characterized in that the observation data acquisition device of each satellite has a predetermined field of view corresponding to an area of the Earth's surface in visibility of that satellite. acquisition device, and in that each terrestrial receiving and recording station comprises means for storing observation data from at least one terrestrial area, called the recorded observation area, comprising at least the envelope fields of view of the acquisition device of each satellite in which the receiving antenna of the receiving and recording terrestrial station is located, the number and distribution of the different receiving and recording terrestrial stations being adapted to that said corresponding recorded observation areas are complementary and allow coverage of a terrestrial surface to observe, the different observation data corresponding to this surface to be observed being distributed in the storage means of the different terrestrial receiving and recording stations, said satellite grid being a storage gate adapted so that all the observation data stored by the different terrestrial receiving and recording stations are permanently accessible as a single computer resource from any access point of the digital network of said satellite grid. It should be noted that in a device according to the invention, it is possible to create recorded observation zones associated with a terrestrial receiving and recording station in a virtual manner, which does not necessarily correspond to the circle of visibility. the reception antenna of the receiving and recording terrestrial station nor the fields of view of the satellites flying over this antenna. Thus, advantageously and according to the invention, the recorded observation zone of at least one terrestrial receiving and recording station comprises at least one zone situated outside the envelope of the fields of view of the satellites containing the antenna. reception station of the land receiving and recording station. This allows, on the one hand, that the observation data can be optimally distributed between the different terrestrial receiving and recording stations, both from the point of view of the storage capacity and the efficiency of the data. the use of the observation data (in particular by minimizing the distance between each potential user and the receiving and recording terrestrial station where the corresponding observation data are recorded so as to reduce the occupation of the network). But this also makes it possible to provide that a satellite can transmit observation data to any of the reception and recording terrestrial stations, these observation data then being stored in memory means of any station. terrestrial reception and recording, identical or not to that which initially received these observation data from the satellite. The grid architecture of the different receiving and recording terrestrial stations makes it possible to route automatic, simple and transparent observation data to the appropriate receiving and recording terrestrial station, according to a predetermined protocol which may be arbitrary. In an advantageous variant of the invention, each terrestrial receiving and recording station is adapted to search and incorporate in its storage means the observation data of each terrestrial receiving and recording station whose area of ?? The recorded observation is adjacent to its own, so that each terrestrial receiving and recording station incorporates a local mosaic of the different recorded observation areas adjacent to its own. Furthermore, advantageously and according to the invention, the observation data are transmitted by each transmission device of a satellite in a format incorporating metadata and / or data, called geolocation data, representative of the location of the area. observed and the date of observation. Thus, in the case of terrestrial observations, the Earth observation data as transmitted by each satellite are geolocalised, that is to say, incorporate the information making it possible to determine to which portion of the Earth's surface they correspond, so that they can be automatically routed through the grid to the receiving and recording terrestrial station on which they are to be recorded, and subsequently automatically selected via the grid in response to a user request. As such, it should be noted that the observation data transmitted by a satellite undergo at least one processing from a receiving and recording terrestrial station (that associated with the receiving antenna where they are received and / or the one in which they are recorded) before they are recorded in the storage means of a reception and recording terrestrial station. But, in any case, this process retains the geolocation data. Furthermore, in an advantageous variant, a device according to the invention is also characterized in that each terrestrial receiving and recording station is furthermore associated with a transmitting antenna towards a satellite, and in that the antennas At the receiving and transmitting stations, the satellite transmission devices and the receiving and recording terrestrial stations are adapted to allow bi-directional exchanges between the satellites and the receiving and recording terrestrial stations. In particular, this allows a control of the satellite constellation in a simple and decentralized way, so that it is no longer necessary to provide a single control center, and commands can be sent to each satellite at any time since any access point to the grid.

Thus, advantageously a device according to the invention comprises at least one remote control module adapted to be able to transmit commands to each satellite, and each remote control module is connected to said digital network and to the grid of reception and recording terrestrial stations. to which he addresses each command to be transmitted to a satellite.

In a first variant, the remote control module determines at least one terrestrial receiving and recording station to which the command is intended, responsible for issuing this command to the destination satellite. In another variant, said command is sent simultaneously by all the receiving and recording terrestrial stations associated with a transmitting antenna. Such a command is then received by each satellite from the terrestrial receiving and recording station connected to the transmitting antenna closest to that satellite. Since the command includes an identification code of the satellite for which it is intended, each satellite can determine whether this command is intended for it or not.

The spatial constellation of satellites can be connected to the satellite grid of the terrestrial receiving and recording stations according to specific communication and communication means that are not part of the digital network forming the satellite grid. Nevertheless, according to an advantageous and preferred variant of the invention, each satellite itself also comprises a grid module so as to be incorporated in the satellite grid formed by the different terrestrial receiving and recording stations and the digital network which connects them. Thus, in a device according to the invention, each satellite, like each terrestrial receiving and recording station, is a node of the satellite grid, so that the communications are greatly facilitated and can benefit from all the advantages and all the advanced functionalities allowed by such a satellite grid (simplified and transparent management of data sharing, simplified management of the accesses of the different satellites to the different terrestrial receiving and recording stations and conversely, robustness of operation, for example in the event of a breakdown of one of the satellites or one of the terrestrial receiving and recording stations ...).

Advantageously and according to the invention, the digital network of said satellite grid is a public digital terrestrial network, in particular the Internet network supporting in particular the links between the various terrestrial receiving and recording stations. It should be noted in this respect that the nature of the physical communication links between the different nodes of a grid does not matter and can be arbitrary and variable within the same grid (wired links, fiber links optical, links via communications satellites, cellular links of GSM type or other ...). Indeed, a grid module is a software layer reported on one or more networks (x) in operation and compatible with all formats of networks and platforms. Furthermore, an observation device according to the invention advantageously comprises a terrestrial server, said geoportal server, connected by said public digital network to said satellite grid, this geoportal server being accessible to users via this public digital network, and being adapted for Manage permissions to access the grid by users. As such, it should be noted that such a geoportal server does not constitute a central site or a central server in which the observation data to be delivered to the users are recorded, or which would be necessary to determine the recording location of the observation data subject to a user request and / or to repatriate said observation data to each user. In fact, in a device according to the invention, the grid makes it possible to share observational data in a transparent and automatic manner with each user connected to this grid without requiring any central site for selecting or transmitting information. In an observation device according to the invention, the geoportal server therefore only has the function of managing the control of the access by the users to the grid forming the device. Preferably, in an observation device according to the invention, said observation data being data that can be viewed in the form of images, each terrestrial receiving and recording station is adapted to process the observation data. it receives from each satellite, so as to form and record in its storage means corresponding images directly usable by a user, the grid thus formed making directly accessible to the user all of the observation images resulting from different satellites for the different observation areas recorded in the different ground receiving and recording stations. In particular, each terrestrial receiving and recording station maintains in its own storage means a local mosaic consisting of its own recorded observation area and the different recorded observation areas adjacent to other receiving terrestrial stations. different corresponding observation data are formatted, calibrated and processed in a homogeneous manner so that they can be directly exploited by the users. As such, several variants of the invention are possible. According to a first embodiment according to the invention, the management module of each terrestrial receiving and recording station is adapted to dynamically provide the observation data as recorded last in the storage means. on the satellite grid. In other words, in this variant embodiment, each user can obtain, via the geoportal server, the most recent observation data of any observation zone, as they are received and lastly recorded in the station. terrestrial reception and registration. This variant embodiment makes it possible to permanently provide a most recent image of the different observation zones scanned by the constellation of satellites, and therefore of the Earth if the number of satellites of the constellation is sufficient. In a second variant, nothing prevents the provision on the contrary that the various observation data received by the different receiving and recording terrestrial stations are the subject of a periodic collective treatment, for example every day or all weeks, so as to be dated to form a complete set of up-to-date observation data made available to users, for example by providing data via geoportal servers, in the form of a representation of the global Earth dated different observation areas.

The invention applies in particular to a device for obtaining an observation of the entire surface of the Earth with the characteristics mentioned above. Thus, advantageously and according to the invention, each satellite has a swath F and a low orbit so that it can describe a ORB number of orbits greater than 1 in one day, and the number of satellites is adapted so that the Earth's surface to be observed corresponds to the entire surface of the Earth. The invention nevertheless also applies to other satellite constellations which are more limited in their observation range and / or in the observation of space. The invention thus represents a break in the design of the Earth observation devices, based on a transparent, permanent, automatic interconnection grid of its various constituent bodies (terrestrial receiving and recording stations and / or satellites and / or antennas), this grid constituting the essential element of the observation device. The invention also relates to a device -particularly an observation device- characterized in combination by all or some of the characteristics mentioned above or below. Other characteristics, objects and advantages of the invention will become apparent on reading the following description which, by way of nonlimiting example, shows one embodiment of the invention, with reference to the appended drawings; in these drawings: FIG. 1 is a diagrammatic view of a device for acquiring and distributing Earth observation data according to one embodiment of the invention; FIG. 2 is a diagrammatic view of a terrestrial device forming a satellite grid according to one embodiment of the invention, - Figure 3 is a schematic view of a terrestrial station for receiving and recording a satellite grid according to an embodiment of the invention. invention. In the figures, the scales and proportions are not respected for purposes of illustration and clarity. As shown in FIG. 1, a device for observing the Earth according to the invention comprises a satellite constellation 4 and a plurality of terrestrial stations for receiving and recording data communicating with one another, forming a terrestrial device according to the invention. the invention, said satellite grid. Each satellite 4 furthermore comprises at least one device -particularly an optical-acquisition device for observation data with a fixed aim. Such an observation data acquisition device is for example a fixed camera oriented towards the Earth and adapted to acquire observation data-notably multispectral images of regions of the atmosphere and / or the terrestrial surface that satellite 4 flies over. According to a possible embodiment of the invention, such a satellite is an optical parachute as described for example by WO2005110848. Thus, a satellite 4 of a device according to the invention does not require a particular pointing program, which substantially reduces manufacturing and maintenance costs. Each satellite 4 furthermore comprises at least one observation data transmission module adapted to transmit after each acquisition of observation data by an observation data acquisition device of this satellite 4, the observation data. acquired to the terrestrial layer (station 5). Such a transmission module can be of any known type and is not described here in detail. The device according to the invention comprises a plurality of terrestrial receiving and recording stations forming a satellite grid. Each terrestrial recording station comprises at least one observation data receiving module 12 adapted to receive observation data from the observation data acquisition spatial layer. Each terrestrial recording station further comprises, as shown in FIG. 3, a processing unit 11 adapted to process the observation data received by the reception module 12 of this terrestrial recording station.

An observation data processing unit 11 of a terrestrial recording station is, for example, a computer processing unit, particularly a microcomputer-type one, comprising hardware and software means for processing information (microprocessor (s)). ), read-only memory (s) and associated user (s), operating system and other software applications, peripherals and peripheral drivers, corresponding cards and buses, human-machine interface, etc.). In particular, the unit 11 is adapted to perform the processing and recording of the observation data, and the connection to at least one digital network.

Each terrestrial recording station comprises in particular means 13 for storing the observation data processed by the processing unit 11. These storage means 13 are connected locally to the processing unit 11 and can be of any type. For example, these storage means 13 are formed of a mass memory such as a hard disk memory (s). Each terrestrial recording station also comprises a connection 14 to a digital network so as on the one hand to be connected to the other terrestrial recording stations, on the other hand to be able to put the observation data stored by its means 13 of storage available to users connected to this digital network, where appropriate after authorization by a server, said geoportal server, itself also connected to the digital network and allowing the administrative and financial management of access authorizations at the grid by users. This digital network connection 14 of each terrestrial recording station is managed by means of a module, called management module 8, loaded and executed by the processing unit 11 of each receiving terrestrial station and recording system, so that the different terrestrial recording stations are permanently interconnected to each other via said digital network according to a grid computing architecture permitting the permanent transparent sharing of computing resources, and in particular permanent transparent shared access to the observation data (from the constellation of satellites 4) recorded in the memory means 13 of the different terrestrial recording stations. The main function of each terrestrial recording station thus consists in allowing, on the one hand, the storage of observation data on a local mass memory (storage means 13), and on the other hand interconnection and sharing of data. reading these observation data via the satellite grid, so that they can be seen from any access point to this satellite grid. Thus, the different receiving and recording terrestrial stations interconnected via the digital network form a satellite grid accessible from any access point to said digital network, and seen from such an access point. as a single, global IT resource. In particular, a user authorized by the geoportal server to formulate a query concerning observation data, for example observation data of a given region of the terrestrial surface, accesses the geoportal server directly or via the geoportal server. the grid thus formed, so that the corresponding observation data are readable and, where appropriate, can be downloaded to the user, transparently via the grid, regardless of the terrestrial recording station of where this information is stored.

Therefore, in an observation device according to the invention, the satellite grid formed by the various terrestrial receiving and recording stations, as well as the digital network, are in fact an integral part of this observation device, this means that the functionality of the observation device is lost, or in any case very strongly degraded, if all or part of the grid is not functional. Such a satellite grid is shown schematically in FIG. 2. The management module 8 can be formed of any known computer grid module, in particular Globus ToolKit, or else chosen from the software suites gLite (EGEE), UNICORE, or Synfiniway (Fujitsu). ), or the e-mule software (www.emule-project.net).

Each terrestrial receiving and recording station is connected to at least one receiving antenna 6, in particular to one and only one reception antenna 6 of its own, via a link 7. This link can be of any type. For example, this link 7 may be a wired link, a wireless radio link, wifi, etc. The receiving antennas 6 may be more or less distant from the terrestrial recording stations. Preferably, each terrestrial recording station locally comprises a receiving antenna 6. Alternatively, each receiving antenna 6 is part of an independent receiving station comprising a computer processing unit to which reception antenna 6 is connected and which is separate from that of the terrestrial recording station. In this case, each receiving station is connected to the digital network and also comprises a management module 8 so as to be incorporated in the satellite grid and thus interconnected with the terrestrial recording stations.

The satellite grid thus formed of a device according to the invention has firstly as a function to make available on the digital network automatically, transparently and in real time, the observation data stored in each mass memory 13 of each terrestrial recording station.

Furthermore, in the most frequent case where these observation data are adapted to be visualized in the form of images, these observation data are processed as images directly available to the user, and each station 5 The recording terrestrial is adapted to memorize in its mass memory 13 not only the observation data corresponding exactly to its circle of visibility, but also all the observation data corresponding to the immediately adjacent recording terrestrial stations. that is to say, whose circle of visibility is adjacent to that of the terrestrial recording station. Thus, each terrestrial recording station holds in its mass memory 13 a local mosaic of all the observation data corresponding to its recorded observation area and the boundaries between this area in its recorded relation and the immediately adjacent areas. In addition, this local mosaic of each terrestrial recording station is directly accessible via the grid for a user. The satellite grid thus formed also makes it possible, in the opposite direction, to achieve, in an extremely simple and reliable manner, a remote control of the satellites 4. To do this, each terrestrial recording station (or at least a part of them) is also associated to a transmitting antenna able to establish an uplink towards any satellite 4 passing in the visibility zone of this transmitting antenna. Such a transmitting antenna may be an integral part of the terrestrial recording station, or, alternatively, as described above in relation to the receiving antenna 6, be part of a separate independent transmitting station. , itself connected to the satellite grid and equipped with a management module 8. The transmission of such a remote control to a satellite 4 via the satellite grid is extremely simple. Indeed, this remote control can be first developed by a suitable remote control module and well known in itself, to one or more satellites 4. The remote control module can determine itself on the one hand each destination satellite, on the other hand each terrestrial station responsible for transmitting this remote control, and insert identification data of each destination satellite and / or each terrestrial receiving and recording station in the address and / or metadata and / or data from the remote control. In a preferred variant, the remote control module broadcasts the remote control on the gate, and each of the terrestrial stations of the gate that is associated with at least one transmitting antenna is adapted to transmit this remote control to each satellite passing through the field of view. transmission of this transmitting antenna, the different satellites 4 receiving the remote control, each satellite 4 determining whether this remote control is or not intended. The number and distribution of receiving antennas 6 and, if applicable, transmitting antennas, on the Earth's surface and the constellation of satellites 4 are adapted so that: - each satellite 4 flies over at least one antenna 6 of reception, and if necessary, at least one transmitting antenna, each receiving antenna 6 and, if appropriate, each transmitting antenna, is overflown by at least one satellite 4. According to a preferred embodiment of the invention, the invention further comprises M land receiving and recording stations ic2 where m = a. , r being the average radius of the conspicuity circles associated with the receiving antennas 6 connected to the reception modules 12 of the terrestrial recording stations and a, a predetermined coefficient making it possible to ensure coverage of the visibility circles. a is a coefficient which makes it possible to ensure recovery of the different circles of visibility of the antennas associated with the reception modules. In practice, a is between 1.1 and 1.25, which makes it possible to obtain coverage area coverage rates of between 10% and 25%. Thus, a satellite is, whatever its position, in visibility of at least one receiving antenna 6.

According to a preferred embodiment, the coefficient a is set at 1.2, which makes it possible to obtain a recovery rate of 20%. According to a preferred embodiment of the invention, the number of terrestrial recording stations of the earth observation data recording device is equal to the number of satellites 4 of the spatial data acquisition layer 1. observation. A receiving antenna 6 associated with a receiving module 12 of a terrestrial recording station may be of any type. In particular, an antenna 6 may have various circles of visibility, depending in particular on its elevation. According to one embodiment of the invention, each antenna 6 has a visibility circle of 2500 km. According to this embodiment, a device according to the invention may comprise twenty-five antennas 6 associated with twenty-five terrestrial receiving and recording stations distributed on the surface of the Earth. In the case where the digital network is the Internet, setting up a device according to the invention is particularly easy and economical. Moreover, in the case where the reception and / or transmission antennas 6 are distant from the terrestrial recording stations, the links between the reception and / or transmission stations of these antennas, and the terrestrial stations The recording network is also advantageously formed by the digital network, and preferably by the grid formed by the terrestrial recording stations and the digital network, that is to say that the stations of the antennas are themselves connected to the digital network and provided with a gate module 8 configured so that all the information and data transiting through each antenna are managed by this management module 8, and therefore shared on the satellite grid. In particular, the management modules 8 are configured to present at least one directory of the processing unit 11 dedicated to recording the observation data, and to allow at least read access to this directory from any user access on the satellite grid. Advantageously and according to the invention, the satellites 4 are themselves each equipped with a processing unit with a management module 8, such that they are integrated in the grid formed by the terrestrial recording stations. and the digital network, via communication links established between the satellites 4 and the terrestrial recording stations. Thus, in a device according to the invention, the satellites 4 can be configured to provide observation data on the grid, so that this information can be directly accessed by the terrestrial recording stations, which can then be process to record in their means 13 specific storage, especially as images directly accessible to users. In other words, an observation device according to the invention can be seen as a network gate comprising a plurality of servers formed on the one hand by terrestrial recording stations, receiving antennas 6 and / or transmitting antennas and, on the other hand, by satellites 4 in orbit for acquiring observation data.

The communications between the spatial observation data acquisition layer and the terrestrial observation data recording device can be of any type. For example, according to a preferred embodiment of the invention, the communications between the spatial data acquisition acquisition layer 1 and the terrestrial observation data recording device use a UMTS protocol. In other embodiments, the communications may utilize other protocols, such as protocols based on future technologies such as Orthogonal Frequency Division Multiplexing (OFDM) technology or High Speed Downlink Package Acess (HSPA) technology. . According to a preferred embodiment of the invention, the observation data are compressed on board the satellites 4 before being sent to the terrestrial device for recording observation data. This compression can be of all types, such as JPEG compression. An observation device according to the invention makes it possible, for example, in a simple and economical way to take daily metric images of the whole of the Earth. These shots can advantageously be distributed via the grid, but if necessary under the control of a server to which authorized users are connected. To do this, and as indicated above, a device according to the invention advantageously comprises a server, said geoportal server, connected by the public digital network, to the grid of terrestrial recording stations. This server comprises means for receiving a connection request from a remote user, means for analyzing this request, means for verifying the access rights of this user, authorization means or forbidden to access the grid by this user. It should be noted, however, that such a geoportal server does not, however, in any way constitute a central site or a central server on which the various information is stored or managed, since, on the contrary, the various information or images accessible to the users are processed. and distributed in the means 13 for storing the different terrestrial recording stations interconnected by the gate.

The image of the Earth obtained by an observation device according to the invention is distributed on the surface of the Earth. On the other hand, for a user, this distribution is transparent since the observation data that is requested by a user via a grid module of the latter are automatically repatriated and made available to the user via Grid.

Such a geoportal server is for example a microcomputer comprising calculation means, storage means, query analysis and query processing software, etc. An observation device according to the invention makes it possible to acquire and supply information, especially images, of terrestrial observation which have high spatial and temporal resolutions, in particular of the order of one meter and one day respectively. An observation device according to the invention physically distributes all the observation data acquired on the Earth, which allows the repatriation and the processing of the data. In particular, the bandwidths used are compatible with today's available technologies. An observation device according to the invention does not require any misalignment of the observation data acquisition devices on board the satellites. In addition, an observation device according to the invention does not require any central server for recording and / or referencing and / or distributing the observation data. The observation data are constantly distributed on the Earth and stored in the storage means of the various terrestrial receiving and recording stations. A device according to the invention is particularly suitable for providing Earth observation data to users connected to a public digital network of the Internet type. In particular, a device according to the invention allows any user connected to this network, to recover an image of a portion of the Earth having a resolution of the order of one meter and dating less than a day. Therefore, the invention paves the way for many new applications, particularly in the fields of agriculture, cartography, security, defense, the environment, urban planning, telecommunications, risk management, management of renewable resources, etc. The invention can be the subject of many variants not specifically described. In particular, a device according to the invention may comprise other observation data acquisition devices arranged on board other flying machines, or even arranged at the top of land buildings, such as buildings, and transmit the data. observation data acquired to the observation data processing layer via the telecommunications layer. This telecommunications layer may also comprise various additional devices for conveying the observation data of the observation data acquisition layer to the terrestrial device according to the invention for recording observation data. These additional devices are, for example, relay antennas, intermediate networks, etc. The terrestrial device according to the invention for recording observation data can comprise a large variety of terrestrial receiving and recording stations distributed on the surface. of the earth. These reception and recording terrestrial stations may be microcomputers connected to a public network such as the Internet, and in general any device adapted to receive an image (or other observation data), to process the image, save it in mass memory, and make it available to network users.

Furthermore, the terrestrial recording stations can be connected to several digital networks, and in particular to at least one digital network other than the Internet network, for example to a specific digital network (although this specific digital network can be - even based in whole or in part on communications via the Internet). In addition, the terrestrial device according to the invention can be used not only with a satellite constellation 4 as described above, but, if necessary, with several satellite constellations in parallel. For example, the same terrestrial device according to the invention can receive both observation data from a first constellation of satellites performing observations in the visible range, and observations from a second constellation of satellites, for example making observations of the space and / or physical parameters of the terrestrial environment, for example magnetic field measurements and / or observations in the microwave domain ...

Claims (1)

CLAIMS1 / - Device comprising a plurality of stations (5) terrestrial receiving and recording data provided with means (13) for storing these data, each station (5) terrestrial being associated with means for receiving data from observation from at least one satellite in orbit around the Earth, characterized in that: - the observation data received from at least one satellite are and remain distributed in the means (13) for storing the various stations ( 5) terrestrial reception and recording, - each terrestrial receiving and recording station (5) is functionally connected to the other terrestrial receiving and recording stations (5) by at least one digital network (15), and is provided with at least one module (8), said management module (8), adapted so that the different terrestrial reception and recording stations (5) are interconnected to each other by the diodes. different management modules (8) via the digital network (s) (15), according to an architecture, called a satellite grid, adapted to allow permanent transparent shared access to said observation data coming from least one satellite recorded distributed in the means (13) for storing the different terrestrial receiving and recording stations (5), said satellite grid being adapted to make the set of recorded observation data distributed in the different stations (5). ) terrestrial receiving and recording accessible and viewed as a single observation dataset from any access point of the digital network (s) (15), and in that the module (8) for managing each terrestrial reception and recording station (5) is adapted to dynamically provide the observation data as last recorded in the memory storage means (13). satellite grid. 2 / - Device according to claim 1, characterized in that each station (5) terrestrial receiving and recording is further associated with means (10) for transmitting data to at least one satellite (4), and in that it comprises at least one remote control module adapted to be able to generate at least one command to at least one satellite (4) and to issue such a command on the gate. 3 / - Device according to one of claims 1 or 2, characterized in that said network (15) of said digital grid satellite is a network (15) digital terrestrial public. 4 / - Device according to one of claims 1 to 3, characterized in that said observation data being data capable of being viewed in the form of images, each station (5) terrestrial receiving and recording is adapted to process the observation data it receives from each satellite (4), so as to form and record in its storage means (13) corresponding images directly usable by a user, the satellite grid thus formed making directly accessible to the user all of the observation images recorded in the various terrestrial receiving and recording stations (5). 5 / - Observation device according to one of claims 1 to 4, characterized in that it comprises: - at least one constellation of satellites (4) deployed in orbit around the Earth, each satellite (4) comprising at least one observation data acquisition device, and at least one device for transmitting said observation data to receiving antennas (6) located on the surface of the Earth, each station (5) terrestrial reception and recording being associated with at least one receiving antenna (6), the transmission device of each satellite (4) being adapted to be able to transmit observation data to any receiving antenna (6). located in a field of view of this transmission device, each reception antenna (6) being adapted to be able to receive observation data transmitted by a satellite (4) when said receiving antenna (6) is located in the field of view vi transmission device of said satellite (4). 6 / - Observation device according to claim 5, characterized in that the observation data acquisition device of each satellite (4) is adapted to acquire Earth observation data and has a field of view a predetermined area corresponding to an area of the Earth's surface in visibility of this acquisition device, and in that each terrestrial receiving and recording station (5) comprises means (13) for storing observation data from at least one terrestrial area, said recorded observation area, comprising at least the envelope of the fields of view of the acquisition device of each satellite (4) in which the antenna (6) receiving the ground station reception and recording is located, the number and distribution of the different terrestrial reception and recording stations (5) being adapted so that the corresponding recorded observation areas are are complementary and allow a coverage of a terrestrial surface to be observed, the different observation data corresponding to this surface to be observed being distributed in the means (13) of storage of the various terrestrial receiving and recording stations (5), said satellite grid being a storage grid adapted so that all the observation data stored by the different terrestrial receiving and recording stations (5) are permanently accessible as a single computer resource from any access point of the digital network (15) of said satellite grid. 7 / - Observation device according to claim 6, characterized in that the recorded observation area of at least one terrestrial reception and recording station (5) comprises at least one zone situated outside the envelope fields of view of the satellites (4) containing the receiving antenna (6) of the terrestrial reception and recording station (5). 8 / - Observation device according to one of claims 6 or 7, characterized in that each station (5) terrestrial receiving and recording is adapted to search and incorporate in its means (13) of storage data d observation of each terrestrial receiving and recording station (5) whose recorded observation area is adjacent to its own, so that each terrestrial reception and recording station (5) incorporates a local mosaic of the different zones observation devices recorded adjacent to it. 9 / - Observation device according to one of claims 5 to 8, characterized in that each satellite transmission device (4) is adapted to transmit the observation data. in a format incorporating metadata and / or data, called geolocation data, representative of the location of the observed area and the date of observation. 10 / - Observation device according to one of Claims 5 to 9, characterized in that each terrestrial receiving and recording station (5) is furthermore associated with an antenna (10) transmitting to a satellite ( 4), and that the receiving and transmitting antennas (10), the satellite transmission devices (4) and the terrestrial stations (5) are adapted to allow the establishment of two-way exchanges between the satellites ( 4) and terrestrial stations (5). 11 / - observation device according to claim 10, characterized in that it comprises at least one remote control module adapted to be able to transmit commands to each satellite (4), and in that each remote control module is connected to said network (15) and to the satellite grid of terrestrial receiving and recording stations (5) to which it addresses each command to be transmitted to a satellite (4), said command being transmitted simultaneously by all the terrestrial stations (5) of reception and registration. 12 / - Observation device according to one of claims 5 to 11, characterized in that each satellite (4) also comprises a management module (8) so as to be incorporated in the satellite grid formed by the different stations ( 5) terrestrial reception and recording and the digital network (15) that connects them. 13 / - Observation device according to one of claims 5 to 12, characterized in that said satellite grid is connected to a network (15) digital terrestrial public. 14 / - Observation device according to one of Claims 5 to 13, characterized in that each terrestrial receiving and recording station (5) is adapted to process the observation data it receives from each satellite ( 4), 30 so as to form and record in its storage means (13) corresponding images directly usable by a user, the satellite grid thus formed making directly accessible to the user all the observation images from different satellites for the different observation areas recorded in the different terrestrial receiving and recording stations (5).