BROADBAND MULTI-STAGE SATELLITE SATELLITE RADIOCOMMUNICATION SYSTEM WITH IMPROVED FREQUENCY REUSE, A

专利摘要:
A broadband multibeam satellite radio system is configured to cover a geographical service area (22), broken down into a plurality of emission spots (26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46 , 48, 50), each consisting of a central inner area (106, 108, 110, 112, 114, 116, 118) and a peripheral area (126, 128, 130, 132, 134, 136, 138) . A first polarization state and a second polarization state are respectively allocated to the spots of a first gate G1 and the spots of the second gate G2; one and the same main frequency band BP is allocated in full to each central internal area. The coverage of the quadruple point service area is a tiling of elementary useful surfaces or cover meshes in the shape of a parallelogram.
公开号:FR3035287A1
申请号:FR1500785
申请日:2015-04-15
公开日:2016-10-21
发明作者:Antonin Hirsch；Pierre Bosshard；Boulc'h Didier Le；Judicael Pressense
申请人:Thales SA；
IPC主号:

专利说明:

[0001] The present invention relates to a high capacity broadband multibeam satellite radiocommunication system configured for fractional or complete reuse of forward and reverse frequencies. an improved frequency reuse method. Current high-bandwidth and second-generation Ka-band radiocommunications satellites offer high transmission capacities, in the order of a hundred Gbps, through the use of fine antenna bundles or brushes, combined with spatial reuse of frequency resources in a fixed broadband and an efficient adaptive modulation and coding strategy for transmission channels. Among the conventional patterns of frequency reuse, the scheme which corresponds to an allocation of four distinct subbands on all the coverage spots of the multibeam antenna in a four-color pattern is well known. A four-color frequency reuse scheme, denoted by the abbreviation 4-FR (Frequency Reuse), divides the entire band allocated to the system into four separate frequency sub-bands or four colors, and leaves adjacent beams of the transmitting or receiving satellite antenna, transmitting on the different subbands in a forward path from the satellite to the ground, or receiving on the different subbands in a return path from the ground to the satellite. A 4-FR four-color frequency reuse scheme makes it possible to have a constant minimum inter-beam distance between beams of the same color, and consequently to obtain a reasonable compromise between the reuse factor of the strip and the insulation between the beams. However, when, with a fixed number of beams of a geographical coverage, it is sought to reduce the number of colors, the frequency reuse Cil, determined by the distance between two spots of the same color decreases, which reduces the spectral efficiency. and limit, see prevents, a gain in communication capacity of the system. 3035287 2 same color decreases, which decreases the spectral efficiency and limit, see prevents, a gain of communication capacity of the system. To improve the total capacity of the system in a forward path context, i.e. satellite antenna transmit spots, the article of O.
[0002] 5 Vidal et al., Entitled "Fractional Frequency Reuse in Fixed Boadband High Throughput Satellite Systems" and published in the Proceedings of 31st AIAA International Satellite Communications Systems Conference, October 14-17, 2013, Florence, Italy, describes a solution that increases the bandwidth used by spot for each spot of a cover. This solution takes advantage of Fractional Frequency Reuse schemes, which are used in terrestrial mobile networks such as WiMAX and LTE. The FFR technique applied in a satellite radiocommunication system in a forward path context is a frequency reuse technique which overlays the conventional color patterns, i.e., for example, 3, 4, 7, 12 colors. combining them with more dense frequency reuse schemes within each beam. O. Vidal's document describes, without limitation of generality, a conventional 7-color reuse scheme (7-FR) combined with a full sub-band reuse scheme (1-FR). In this configuration, the FO sub-band of scheme 1-FR and the sub-bands Fi of scheme 7-FR are used permanently in their assignment beams but at any point in the coverage, the ratio C / I observed in the sub-band Fi will be greater than the C / I observed in the sub-band FO due to a lower re-use factor for 25 F0. The technical problem is to increase the satellite capacity or the forward path capacitance of a multibeam satellite radio system for a fixed transmit band and satellite edge power using a fractional FFR reuse scheme or complete frequency according to which a sub-band common to all the reception spots is allocated to the inner area of each emission spot. More particularly, the technical problem is to increase the area of the internal area of each emission spot without decreasing the C / I signal to interference ratio or for a surface of the internal area of each emission spot. fixed increase the signal to interference ratio Cil. To this end, the subject of the invention is a broadband multibeam satellite radio system configured for fractional frequency reuse of a total BT band allocated to a forward channel, comprising: a satellite having an antenna system; multibeam emission, configured to cover a geographical service area, broken down into a plurality of emission spots, with a first gate G1 of spots and a second gate G2 of emission spots, the emission spots of the first gate G1 and the emission spots of the second gate G2 being positioned and their radiation pattern being configured so that there are points of intersection between the iso-roll-off contours of an integer number m, greater than or equal to three, adjacent overlapping spots, the number m denoting the order of multiplicity of the points of intersection; and a set of receiver terminals distributed over all the emission spots, each receiver terminal comprising a geographical positioning means and a reception means according to an allocated transmission resource; 20 .- a scheduler and allocator of forward path transmission resources, realized in the form of one or more electronic computers, configured to assign to a receiving terminal when it requests a transmission resource go way in terms of a sub a frequency band of the total band BT and of a polarization state taken from a first polarization state P1 and a second polarization state P2 as a function of the geographical position of the receiver terminal and a plan for allocating forward path transmission resources, wherein each transmitting spot consists of a central inner zone and a peripheral zone surrounding the central inner zone; and the first state of polarization and the second state of polarization are respectively allocated to the spots of the first gate G1 and the spots of the second gate G2; and a same main band BP of single or multi-piece frequencies, forming a predominant part of the total band BT in terms of occupied band, is allocated in full to each central inner zone of the spots of the first and second grids. ; and the frequencies of the total band BT which are not part of the main band BP form a secondary band BS in one piece or in several pieces which is decomposed into an integer n, greater than or equal to 2, of sub-strips of a single piece each, separated or adjacent, distributed over all the peripheral zones of the emission spots in a multicolored pattern with n colors of secondary subbands, characterized in that the dots intersection between the spots of the first and second grids are quadruple points of intersection that is to say having an order of multiplicity equal to 4.
[0003] According to particular embodiments, the multibeam satellite radiocommunication system comprises one or more of the following characteristics: the quadruple points define elementary useful coverage areas at the rate of one per spot which form a paving of the zone; cover, and each elementary useful surface constitutes a mesh of the same size and shape, and the shape of the mesh is a parallelogram; .- the shape of the mesh is a square or a rectangle or a diamond; each internal zone is inscribed in the elementary useful surface of its transmission spot; the number n of secondary subbands is an integer included in the set of numbers 2, 3, 4, 7 and 12, and preferably equal to 2; the first and second polarization states (P1, P2) are the left circular polarization and the right circular polarization or a first linear polarization along a first axis and a second linear polarization along a second axis orthogonal to the first axis; the antenna multibeam transmission system comprises first and second beam single source transmit antennas (SFPBs); the first antenna comprising a first array of sources distributed according to a mesh of first square array and a first main reflector; the second antenna comprising a second network of sources distributed in a mesh of second square array and a second main reflector; and the first and second source arrays and the first and second main reflectors are geometrically configured to form a coverage of the quad-dot service area and square coverage mesh; the antenna multibeam emission system comprises a single multi-beam emission antenna (MFPB); and the transmitting antenna comprises a main reflector and a network of several sources illuminating the reflector, the sources being distributed in a hexagonal or square antenna network mesh and associated in several groups offset with respect to each other in directions X and Y of a plane, each source comprising a radiating element 10 linked to a microwave chain; each source comprises a first port and a second transmission port of the same frequency (F) and polarizations (P1, P2) orthogonal to each other; the sources are associated in groups of four adjacent sources in X and Y directions; for each group of four adjacent sources, the first transmission ports or the second transmission ports corresponding to the same pair of frequency and polarization values (F, P1), (F, P2), are interconnected the four transmitting ports interconnected forming a transmission beam; for the formation of each beam, the links between the transmission ports of a group of four sources are realized by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other; the source network, the reflector and the distribution circuits are configured in terms of geometry and connectivity, so as to form a total coverage or a half coverage of the service area by emission spots distributed according to a cover mesh 25 included among the rectangular, diamond and square meshes; the mesh of the source network is a hexagonal antenna network mesh and the radiating aperture of the radiating element has a circular or square shape; and two adjacent consecutive groups (Cr1, Gr2) in the X direction are spaced apart from a first L1 pitch corresponding to a source in the X direction and share a source in common; two adjacent consecutive groups (Gr1, Gr3) in the Y direction are spaced apart by a second pitch L2 corresponding to a source in the Y direction and share a source in common; each group of four sources forming a substantially rectangular shaped emitting beam or rhombus for adjusting the associated distribution circuits; 6 .- the mesh of the network of the sources is a mesh of network hexagonal antenna and the opening radiating of the radiating element has a circular or square form; and two adjacent consecutive groups (Grp1, Grp2) in the X direction are spaced from a first pitch L1 corresponding to a source in the X direction and share two sources in common; and two adjacent consecutive groups (Grp1, Grp3) in the Y direction are spaced apart by a second pitch L2 corresponding to two sources in the Y direction and share no source in common; and each group of four sources forms a substantially diamond-shaped or rectangular emitting beam for adjusting the distribution circuits associated with said group; the mesh of the network of the sources is a mesh of square antenna network and the radiating opening of the radiating element has a square shape; and the two directions X and Y form a right angle; and two adjacent consecutive groups (Gr1, Gr2) in the X direction are spaced apart by a first pitch L1 corresponding to a source in the X direction and share a source in common; and two adjacent consecutive groups (Gr1, Gr3) in the Y direction are spaced apart by a second pitch L2 corresponding to a source in the Y direction and share a source in common; and each group of four sources forms a substantially square emitting beam for adjusting the distribution circuits associated with said group; and the source array, the reflector and the distribution circuits are configured in terms of geometry and connectivity, so as to form a total coverage of the service area by emission spots distributed in a square coverage mesh; the antenna multibeam emission system comprises a first transmitting antenna and a second multi-beam beam antenna (MFPB); and the first transmitting antenna comprises a first main reflector and a first array of plural sources illuminating the first main reflector; the second transmitting antenna comprises a second main reflector and a second network of several sources illuminating the second main reflector; the first and second networks have an identical architecture according to which, the sources of an antenna array are distributed according to a hexagonal network mesh associated in several groups, offset with respect to the others in directions of a plane X and Y, each source comprising a radiating element linked to a microwave chain; each source comprises a first port and a second transmission port of the same frequency (F1) and polarizations (P1, P2) orthogonal to each other; the sources are associated in groups of four adjacent sources in the X and Y directions; for each group of four adjacent sources, the first transmission ports corresponding to the same pair of frequency and polarization value (F1, P1), (F1, P2) are connected in pairs in the X direction and then two to two in the direction Y, the four transmission ports 10 interconnected forming a transmission beam; for the formation of each beam, the links between the transmission ports of a group of four sources are made by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other; the first and second source networks, the first and second main reflectors, and the distribution circuits are configured in terms of geometry and connectivity, so as to form a total coverage of the service area by emission spots distributed according to a rectangular or rhombic cover mesh; the mesh of the first network of the sources and the second network of sources is a hexagonal antenna network mesh and the radiating aperture of the radiating element of each source has the same circular or square shape; and for each network: two adjacent consecutive groups (Grp1, Grp2) in the X direction are spaced apart by a first pitch L1 corresponding to a source in the X direction and share two sources in common; two adjacent consecutive groups (Grp1, Grp3) in the Y direction are spaced apart by a second pitch L2 corresponding to two sources in the Y direction and share no source in common; each group of four sources forming a substantially diamond shaped emission beam for adjustment of the associated distribution circuits. the mesh of the first network of the sources and the second network of sources is a mesh of hexagonal antenna network and the radiating aperture of the radiating element of each source has the same circular or square shape; and for each network: two adjacent consecutive groups (Gr1, Gr2) in the X direction are spaced apart by a first step L1 corresponding to a source in the X direction and share a source in common; and two adjacent consecutive groups (Gr1, Gr3) in the Y direction are spaced apart by a second pitch L2 corresponding to a source in the Y direction and share a source in common; and each group of four sources forms a substantially rectangular shaped emission beam for adjustment of the distribution circuits associated with said group; the satellite is configured to radiate in each spot and over its entire extent, including its central zone and its peripheral zone, a transmitted transmission resource color formed of the main frequency band, the secondary band and the polarization state allocated to said spot by the frequency plane and polarization states; the satellite radiocommunication system further comprises an automatic system for correcting the misalignment of the antenna caused in particular by variations in attitude of the satellite platform; the satellite radiocommunication system further comprises a set of receiving terminals distributed over all the spots, and each terminal comprises a geographical positioning means that is sufficiently precise to determine in which transmission spot it is located, and it is in an internal zone or in a peripheral zone of said emission spot; the scheduler and allocator of forward channel transmission resources is distributed over all the terminals and / or one or more auxiliary stations or is centralized in a station (54) for controlling the resources and their planning; .- the size of the central zone varies according to the emission spot and the time, or the size of the central zone varies according to the emission spot and is independent of the time or, the size of the central zone is constant independently of emission spot and time; 30 .- The multibeam satellite radio system defined above is configured for forward transmission by the satellite in a band comprised in the set of C, X, Ku, Ka, L, S, Q and V bands. The invention also relates to a method of fractional frequency reuse of a total band allocated to a forward channel in a broadband multibeam satellite radio system, the system comprising: a satellite having an antennal system multibeam emission circuit configured to cover a geographical service area, broken down into a plurality of emission spots, with a first gate G1 of spots and a second gate G2 of emission spots, the emission spots of the first gate G1 and the emission spots of the second gate G2 being positioned and their radiation pattern being configured so that there are points of intersection between the contou rs iso roll-off of an integer m, greater than or equal to three, of adjacent spots partially overlapping, the number m designating the order of multiplicity of the points of intersection; and a set of receiver terminals distributed over all the transmission spots, each receiver terminal comprising a geographical positioning means and a reception means according to an allocated transmission resource; and .- a planner and allocator of forward path transmission resources, realized in the form of one or more electronic computers; the method comprising the steps of: determining a forward path transmission resource allocation plan wherein each transmitting spot is comprised of a central inner area and a surrounding area surrounding the central inner area. ; and the first polarization state and the second polarization state are respectively allocated to the spots of the first gate G1 and the spots of the second gate G2; and a same main band BP of single or multi-piece frequencies, forming a predominant part of the total band BT in terms of occupied band, is allocated in full to each central inner zone of the spots of the first and second grids. ; and the frequencies of the total band BT which are not part of the main band BP form a secondary band BS in one piece or in several pieces which is decomposed into an integer n, greater than or equal to 2, of sub-strips of a single piece each, separated or adjacent, distributed over all the peripheral zones of the emission spots in a multicolored pattern with n colors of secondary subbands; To assign to a receiving terminal, when it requests it, a forward path transmission resource in terms of a frequency sub-band of the total band BT and a state of polarization taken from a first polarization state P1. and a second polarization state P2 as a function of the geographical position of the receiver terminal; the method being characterized in that the points of intersection between the spots of the first and second grids are quadruple points, i.e. having an order of multiplicity equal to 4; and the quadruple points define basic coverage areas at one per spot that form a tiling of the coverage area; and each elementary useful surface constitutes a mesh of the pavement having the shape of a parallelogram; and each inner zone is inscribed in an elementary useful surface. According to particular embodiments, the fractional frequency reuse method comprises one or more of the following features: the frequency reuse method further comprising the steps of: for each terminal that wishes to have a transmission resource, determine in which transmission spot it is and whether it is in an internal zone or a in a peripheral zone, and then when the terminal is in an internal zone, allocate to the terminal a transmission resource of the main band and the state of polarization which have been allocated to the internal zone of the transmission spot in which the terminal is located, or when the terminal is in a peripheral zone, to allocate to the terminal a transmission resource of the auxiliary subband and the state of polarization which have been allocated to the peripheral area of the emission spot in which the termi nal is located; .- the size of the central area varies depending on the emission spot and time, or the size of the central area varies depending on the emission spot and is independent of the time or, the size of the central area is 30 constant regardless of emission spot and time. The invention will be better understood on reading the following description of several embodiments, given by way of example only and with reference to the drawings, in which: FIG. 1 is a view of a system satellite radiocommunications device, configured for reuse of frequencies and two polarization states according to the invention; FIG. 2 is a view of a diagram of geographic reuse of frequencies and polarizations according to a first embodiment of the invention in which a quadruple dot cover and square mesh of emission spots with circular roll off contours is realized; FIG. 3 is a synthetic view of spot transmittable transmission resource colors at a spot color in the frequency and polarization plane of FIG. 2, a transmission resource color being association of a polarization state and a frequency band composed of the same main band and a subband secondary band; FIG. 4 is a synthetic view of the transmission resource configurations that can be used by a receiving terminal according to the frequency and polarization plane of FIG. 2, a configuration of transmission resources that can be used by the terminal being the association of a polarization state and a frequency band of the main band and the secondary bands. FIG. 5 is a view of a conventional diagram of geographic reuse of the same main band of frequencies and of two polarization states by the emission spots of the satellite, using a hexagonal covering mesh of the emission spots, and serving as a reference in the evaluation of the transmission performance of a geographical reuse scheme of the same main frequency band and the two polarization states by the satellite emission spots, when the coverage mesh of the spots emission used is a parallelogram; FIG. 6 is a view of a geographical reuse scheme of the same main frequency band and of two polarization states by the satellite emission spots, in which the emission spot coverage mesh used is square, and which corresponds to the satellite transmission coverage and geographic allocation plan of the transmission resources by the system of the first embodiment of the system; FIG. 7 is a view of comparing the C / I performance of the main band reuse scheme and the two identical spot aperture polarization states between the configuration of the first embodiment of FIG. system of the invention in which the central operative surface of the emission spot or the cover mesh is square (FIG. 6) and the reference configuration in which the central operative surface of the emission spot or the cover mesh is hexagonal (Figure 5), the aperture angle of the spots being identical. Figures 8A and 8B respectively describe the geometry of a hexagonal cover mesh and the geometry of a square cover mesh, the meshes being inscribed in a fixed circular aperture emission spot; FIG. 9 is a view of comparing the C / I performance of the main band reuse scheme and the two states of polarization with the same pay surface area between the configuration of the first embodiment of the IBC system. wherein the central operative surface of the emission spot or the cover mesh is square and the reference configuration in which the central operative surface of the emission spot or the cover mesh is hexagonal, the areas of the elementary useful surfaces being identical;
[0004] FIG. 10A is a superimposed view of a first source array of a Single Feed Per Beam (SFPB) antenna first and a second source array of a second SFPB antenna, shifted with respect to first in the same image plane, this antenna configuration implementing the first embodiment of the system of Figure 2; Fig. 10B is a view of the optimal C / I color coverage of the first embodiment of the system of Fig. 2 and realized by the antenna configuration of Fig. 10A; FIG. 11 is a view of a first configuration of a hexagonal lattice MFPB antenna 35 and more particularly of its source network and its four-source array, suitably connected so as to realize a second embodiment of a system according to the invention wherein the cover mesh is rectangular; Figure 12 is a schematic view of the connections of first ports to each other and second ports to each other within each quadri-source array of Figure 11 for performing color coverage in terms of polarization states to rectangular mesh of the second embodiment of a system according to the invention; Figure 13 is a color coverage in terms of rectangular mesh polarization states of the second embodiment of a system according to the invention implemented by the configuration of the MFPB antenna described in Figures 11 and 12; FIG. 14 is a view of a second configuration of a hexagonal network mesh MFPB antenna and more particularly of its source network and four-source array, suitably connected so as to realize a third embodiment of a system according to the invention in which the cover mesh is diamond; Figure 15 is a schematic view of the connections of first ports to each other and second ports to each other within each four-source array of Figure 14 to provide half-coverage of the colored coverage in terms of diamond-shaped polarization states of the third embodiment of the system according to the invention; FIG. 16 is a cover colored in terms of diamond-shaped polarization states of the third embodiment of a system according to the invention implemented by two MFPB antennas 30 offset from one another and having a configuration as described in FIG. Figures 14 and 15; FIG. 17 is a view of a third configuration of a square network mesh MFPB antenna and more particularly of its source network and of its four-source groupings, connected in a suitable manner so as to achieve a fourth embodiment of a system according to the invention wherein the cover mesh is square; Figure 18 is a colored coverage in terms of square-mesh polarization states of the fourth embodiment of the system according to the invention implemented by the third configuration of the MFPB antenna described in Figure 17; Figure 19 is a flow chart of a method of frequency reuse and bi-state polarizations implemented by the various embodiments of the system according to the invention.
[0005] In the preamble, some terms used in the rest of the text are defined. By "antenna" is meant an assembly composed of a main reflector, sized by those skilled in the art according to criteria relating to the beams to be generated on a service cover and associated or not with one or secondary reflectors and a set of sources arranged along a planar network whose radiation image via the set of reflector (s) generates a beam grid ensuring all or part of the overlap of the emission zone. "Emitting spot" means a beam of radioelectric radiation emitted by an antenna following the forward path of the satellite or the footprint of this beam on the terrestrial ground, the beam being able to be generated by a single source in the case of an SFPB antenna or generated by several sources, grouped together in a group of sources provided with a beam forming network (BFN), in the case of an MFPB antenna. An emission spot is characterized on the ground by its center according to which the directivity is maximum and an iso-roll-off contour at a predetermined attenuation value. By "cover mesh" is meant a polygonal geometric pattern formed by connecting the multiple immediate points surrounding the center of each emission spot. For each emission spot, the coverage mesh defines a useful area of the spot in which is inscribed the internal zone of the emission spot. By "mesh network" is meant a geometric pattern describing the position of the sources of a network of an antenna, or more precisely the pattern established by connecting the centers of the sources of the network.
[0006] According to Figure 1, a broadband multibeam satellite radio system 2 is configured to implement full or fractional reuse of a total BT band allocated to a forward channel 4.
[0007] The satellite radiocommunication system 2 comprises a satellite 10, a set 12 of transmitting terminals 14, 16, and a forward-path transmission resource planner and allocator 18. The satellite 10 comprises a multibeam transmission antenna system 20, configured to cover a geographic service area 10 or service coverage 22, broken down into a plurality 24 of emission spots 26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50. 1 and by way of illustrative example, the set 24 of the emission spots of the terrestrial coverage 40 comprises thirteen emission spots 26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50 with the emission spot 38 arbitrarily selected for subsequent testing of the Cil performance of the system 2. The emission spots 26, 28, 30, 36, 38, 40, 46, 48, 50 , plotted in solid lines, form a first grid G1 emission spots while emission spots 32, 34, 42, 44, drawn in dashed lines form a second grid G2 of emission spots. The emission spots of the first gate G2 and the emission spots of the second gate G2 are positioned globally and their radiation pattern are configured so that there are points of intersection between the iso roll-off contours. an integer m equal to 4, of adjacent emission spots partially overlapping, the number m designating the order of multiplicity of the points of intersection. Here, in FIG. 1 only the quadruple points 62, 64, 66, 68 of the test spot 38 are represented, the point 62 being the point of intersection of the contours of the spots 32, 36, 38, 42, the point 64 being the point of intersection 30 of the contours of the spots 28, 32, 34, 38, the point 66 being the point of intersection of the contours of the spots 34, 38, 40, 44 and the point 68 being the point of intersection of the contours spotlights 38, 42, 44, 48. The quadruple points define basic coverage areas at the rate of one per emission spot which form a tiling of the service geographical area 22, and each elementary useful area 3035287 is a mesh of the same size and shape, the shape of the mesh being generally that of a parallelogram. According to Figure 1 and by way of example the cover mesh is square. The receiving terminals 14, 16 of the set 12, two of them only 5 being shown in FIG. 1 for the sake of simplification, are distributed over the set 24 of the emission spots, here the test spot 38 and spot 46. Each receiving terminal 14, 16 comprises a geographical positioning or geolocation means 72 and a reception means 74 according to a forward path transmission resource. The forward path resource planner and allocator 18, embodied in the form of one or more electronic calquellers 82, is configured to assign to a receiving terminal when it requests it, for example the receiver terminal 14, a transmission resource. forward path, generally a frequency sub-band in the total band BT and a state of polarization among a first state of polarization P1 and a second state of polarization P2, as a function of the geographical position of the receiving terminal, determined by the geographical positioning means 72, and a transmission resource allocation plan which completely or fractionally reuses the frequencies of the total allocated BT band to the forward channel 4. Here, the resource scheduler and allocator of forward path transmission 18 is centralized in a station 84 resource control and planning.
[0008] As a variant, the forward channel transmission resource planner and allocator is distributed over all the terminals and / or one or more auxiliary stations. According to FIG. 2 and a first embodiment of a plane 102 for reuse of the frequencies and polarization states of the forward channel 4 according to the invention, corresponding to a first embodiment of the system 2, each spot of emission consists of a central internal area in one piece and a peripheral area in one or more pieces surrounding the central inner area.
[0009] Here, in FIG. 2, only the central internal zones 104, 106, 108, 110, 112 of the emission spots 38, 32, 34, 42, 44 are represented in the form of disks. In general, the central internal zone each emission spot 5 is inscribed in the elementary surface area of coverage of said spot of the form of a parallelogram. Here in FIG. 2, only the square shaped useful surfaces of the emission spots 104, 106, 108, 110, 112 are represented and designated respectively by the numerals 124, 126, 128, 130, 132.
[0010] Overall, the effective surfaces 124, 126, 128, 130, 132 of the emission spots 104, 106, 108, 110, 112 form a cross 134 whose arms are arranged diagonally in FIG. 2. The central internal zones 104 , 106, 108, 110, 112 are respectively written in the useful surfaces 124, 126, 128, 130, 132.
[0011] For each emission spot, the peripheral zone is the zone complementary to the central zone of said spot with respect to its elementary useful surface. Here, in FIG. 2 and by way of example, the peripheral zone of an emission spot is formed of four corner surfaces disjunct from the elementary useful surface of the emission spot.
[0012] According to the plan 102 for allocating the transmission resources, the same main frequency band BP, here in one piece and forming part of the total band BT at the beginning of the band, is allocated in full to each central internal zone. emission spots, in particular at the central zones 104 108, 110, 112, 114, 116, 118.
[0013] In general terms, the same main band BP of frequencies in one piece or in several pieces, forming a predominant part of the total band BT in terms of occupied band, is allocated in totality to each central inner zone of the spots of the first ones. and second grids C1, G2.
[0014] The frequencies of the total band BT which are not part of the main band BP form a secondary band BS in one piece or in several pieces which is decomposed into an integer n, greater than or equal to 2, of sub- one-piece sub-strips each, separate or adjacent, distributed over all the peripheral zones of the emission spots in a multicolored pattern with n colors of sub-subbands. Here in FIG. 2 and by way of example, the number n of secondary subbands is equal to 2 and the secondary band BS is decomposed into a first secondary subband BS1 and a second subband secondary BS2. Independently of the frequency bands allocated to each of the spots, the first state of polarization P1 and the second state of polarization P2 are respectively allocated to the spots of the first gate and the spots 10 of the second gate. According to FIG. 3, the colors of transmission resources that can be emitted per spot at the rate of one color per spot, according to the plane of frequencies and polarizations 102 of FIG. 2, are coded by color bands C1, C2, C3. and C4 wherein a first downward hatched pattern of the Figure corresponds to emission in the first polarization state P1 while a second hatched pattern to the left towards the bottom of the Figure corresponds to emission in the second polarization state P2. The first color C1 is an electromagnetic radiation emission in the main band BP and in the first secondary band BS1, associated with the first state of polarization P1. The second color C2 is an electromagnetic radiation emission in the main band BP and in the second secondary band BS2, associated with the first state of polarization P1. The third color C3 is an emission of electromagnetic radiation in the main band BP and in the second band. first secondary band BS1 associated with the second polarization state P2. The fourth color C4 is an electromagnetic radiation emission in the main band BP and in the second secondary band BS2, associated with the second state of polarization P2.
[0015] According to FIG. 2, the radiation colors C1 and C2 are respectively assigned to the first group of spots 28, 36, 40, 48 and to the second group of spots 26, 30, 38, 46, 50 of the first gate G1. the radiation colors C3 and C4 are respectively assigned to the third group of spots 34, 42 and the fourth group of spots 32, 44 of the second gate G2.
[0016] Preferably, the second number n of secondary subbands is an integer comprised in the set of numbers 3, 4, 7 and 12. The first and second polarization states P1, P2 are the left circular polarization. and the right circular polarization or a first linear polarization along a first axis and a second linear polarization along a second axis orthogonal to the first axis. According to FIG. 4, the different planned reserves of resources attributable to a terminal according to its geographical location 10 according to the frequency and polarization plan of FIG. 2 are codified by transmission reserve bands P11, P12, P13, P14. , PI51, P16. When the receiving terminal is in a central inner zone of a color emission spot C1 or C2, it will be allocated a transmission resource of the reservoir P11, consisting of the main frequency band BP associated with the first state of polarization. P1. When the receiving terminal is in a peripheral zone of a color emission spot C1, it will be allocated a transmission resource of the reservoir P12, consisting of the first secondary frequency band BS1 associated with the first state of polarization P1.
[0017] When the receiving terminal is in a peripheral zone of a color emission spot C2, it will be allocated a transmission resource of the reservoir P13, consisting of the second secondary frequency band BS2 associated with the first state of polarization P1. When the receiving terminal is in a central inner area of a C3 or C4 color emission spot, it will be allocated a reservoir transmission resource P14, consisting of the main frequency band BP associated with the second state of polarization. P2. When the receiving terminal is in a peripheral zone of a C3 color emission spot, it will be allocated a transmission resource of the reservoir P15, consisting of the first secondary frequency band BS1 associated with the second polarization state P2. When the receiving terminal is in a peripheral zone of a C4 color emission spot, it will be allocated a transmission resource of the reservoir PI6 consisting of the second secondary frequency band BS2 associated with the second state of polarization P2.
[0018] According to FIG. 5, a reference configuration of a resource allocation plan 202 forming part of the state of the art is illustrated in order to highlight the improvement of the transmission capacity provided to the system by the system. 2 is a conventional geographical reuse of the same main band of frequencies and two states of polarization by the spots of satellite broadcast. The cover uses a first gate G1 of emission spots 204, 206, 208, 210, 212, 214, 216, 218, 220 at a first polarization state P1 and a second gate G2 of emission spots 232, 234 , 236, 238, 240, 242, 244, 246 to a second state of polarization P2. The gates G1 and G2 are shifted between them so as to optimally cover the geographic service area 22. Thus the centers of the spots of the grid G2 are positioned in the holes of the cover made by the spots of the first grid G1. The triple points of any spot, in particular the triple points 252, 254, 256, 258, 260, 262 of the emission spot 212 chosen here for example as a reference spot, define an elementary useful area 264 or 20 mesh of hexagonal shaped cover. Thus, the transmission resource allocation plan 202 that is used as reference differs from the main band reuse plane 102 and the two polarization states of FIG. 2 in that the coverage achieved is a triple-point coverage using a mesh. hexagonal cover.
[0019] The evaluation of the C / I performance will be performed along a horizontal path segment 266 in Figure 5 of the elementary usable area 264 from the center O of the spot 212 to the edge of the elementary usable surface 264. The sources of interference taken into account in the calculation of the C / I are the emission spots 214, 210, 206, 218, 208, 204, 216, 220, numbered from 1 to 8 according to a degree order. decreasing contribution. Thus the contributions in terms of interference of the spots 214, 210 are preponderant compared with those of the spots 206, 218 and even more than those of the spots 208, 204, 216, 220.
[0020] According to FIG. 6, the frequency and polarization reuse plane 102 of FIG. 2 is recalled by describing the horizontal path segment 282 along which C / I performance in the square elementary useful surface 124 is evaluated. and indicating the sources of interference taken into account in calculating the C / I. The route segment 282 starts from the center O of the spot 38 to the edge of the elementary useful surface 124. The sources of interference taken into account in the calculation of the C / I are the emission spots 40, 36, 48 , 28, 26, 46, 50, 30, numbered from 1 to 8 in decreasing order of degree of contribution. Thus, the contributions in terms of interference of the spots 40, 36 are preponderant compared with those of the spots 28, 48 and even more than those of the spots 26, 46, 50, 30. According to FIG. 7, the performances in C / I of the diagram of frequency reuse and polarization 102 of FIG. 2 or 6 according to the invention with quadruple points and square coverage mesh, and the performance of the conventional scheme serving as reference for reuse of frequencies and polarizations 202 of FIG. 5 with triple points and hexagonal mesh cover are compared.
[0021] Diagrams 102 and 202 here each use a different pair of beam source (SFPB) antennas whose sources have the same radiation pattern and in particular the same aperture, here equal to 0.45 degrees. A first curve 292 represents the evolution of the C / I, observed in the case of the reuse plane 202 of FIG. 5 and a triple point coverage and hexagonal covering mesh for a mobile moving along the segment 266. , as a function of the distance of the mobile from the center of the spot 212, normalized with respect to the radius of the spot 212. A second curve 294 represents the evolution of the C / I, observed in the case of the plane 102 of FIG. and quadruple-dot coverage and square coverage mesh for a moving mobile along the segment 282, depending on the distance of the mobile from the center of the spot 38, normalized with respect to the spot radius 38. The comparison Curves 294 and 292 show an improvement in C / I over almost all of the elementary usable area between 3 and 4 dB when switching from a triple-point blanket and hexagonal blanket to a blanket with a blanket. poin quadruple ts and square coverage mesh. This result is generalizable to a cover with quadruple points and 5 mesh coverage of the shape of a parallelogram. According to FIGS. 8A and 8B, the geometry of a hexagonal cover mesh and the geometry of a square coverage mesh are shown, the meshes being inscribed in a fixed aperture emission spot of radius R1 for the mesh of hexagonal and radius coverage R2 10 for the square coverage mesh. The usable area S1 in the case of a triple point mesh and a hexagonal mesh inscribed in a spot of radius R1 is expressed by the equation: sl = 3 * -N / J * Ri2 / 2 The usable area S2 in the the case of a quad-point mesh and a square mesh inscribed in a spot of radius R2 is expressed by the equation: S2 = 2 * R22 To have the same useful area in terms of area, it is necessary to satisfy the relation ( R2 / R1) = ('13 * Nr§ / 2) = 1.14, i.e. the spot radius R2 of the quad square mesh should be 14% larger than the radius spot R1 of the triple point hexagonal mesh. The C / I corresponding to a quadruple point coverage and square mesh with larger spots (ie spots of 0.45 °) is compared in Fig 9 to C / I corresponding to a triple point cover and hexagonal mesh with smaller spots (ie spots of 0.40 °).
[0022] According to Figure 9, a first curve 297 represents the evolution of the Cil, observed in the case of the plane 202 of Figure 5 and a triple point coverage and hexagonal covering mesh for a mobile moving along the segment 266, as a function of the distance of the mobile relative to the center of the spot 212, normalized with respect to the radius of the spot 212 30 (ie a radius corresponding to 0.40 ° of opening). A second curve 299 represents the evolution of the Cil, observed in the case of the plane 102 of FIG. 6 and a quadruple point coverage and a square coverage mesh for a mobile moving along the segment 282, as a function of the distance of the mobile relative to the center of the spot 38, normalized with respect to the spot radius 38. The comparison of the curves 299 and 297 always shows an improvement in the Cil on almost the entire elementary useful surface, between 3 and 4 dB towards the edge of the surface, and significantly higher towards the center of the spot when passing to the same floor area of a triple-point blanket and hexagonal cover mesh to a quad-point blanket and cover mesh square.
[0023] This planning and reuse of the frequencies and of the two polarization states thus makes it possible to obtain a Cil gain and consequently to enlarge the central inner zone of each emission spot on a criterion of C / I. According to FIG. 10A, the images 304, 306 of a first source network of a first SFPB antenna and a second source network of a second antenna are shown superimposed in the same image plane 302. SFPB offset from the first in the same image plane, the first and second antennas forming the antennal system implementing the first embodiment of the system 102 of Figure 2. The first antenna comprises the first network of sources distributed according to a mesh of first square array and a first main reflector, not shown in Figure 10A but assumed in the background of Figure 10A to the observer of Figure.
[0024] The second antenna comprises the second array of sources distributed according to a mesh of second square array and a second main reflector. The first and second source arrays as well as the first and second main reflectors are geometrically configured so as to form useful coverage spots distributed on the ground in a square mesh. 10B is a view of the cover 312 paved and colored by the square-shaped elementary surfaces, a first grid of elementary surfaces of the same polarization P1 being generated by the spots of the first grid of spots G1, in particular the spots 314, 316, 318, 320, 322, 3035287 24 themselves generated by the first array of sources of which an image 304 is provided in Figure 10A, a second grid of elementary surfaces of the same polarization P2 being generated by the spots of the second grid G2 spots, including spots 332, 334, 336, 338, themselves generated by the second source array of which an image 306 is provided in Figure 10A. This colored paving by elementary square-shaped useful surfaces according to the first embodiment of the system 102 of FIG. 2, realized by the antenna configuration of FIG. 10A, allows for improved coverage in terms of the Cil of the Geographical Service Area 22. Figure 11 is a partial view of a first configuration of an MFPB 352 antennal system (ie having multiple sources per beam) with hexagonal network mesh and more particularly a view of its network of sources 354 and its groupings, quad-sources, suitably connected so as to achieve a second embodiment of a system according to the invention wherein the cover mesh is rectangular. The antennal multibeam transmission system 352 is provided by a single multi-beam emission antenna (MFPB which has a main reflector and the grating 354 of a plurality of sources illuminating the reflector, here only 10 sources 356 are shown, 358, 360, 362, 364, 366, 368, 370, 372, 374. The sources are distributed in a hexagonal array network and associated in several groups 382, 384, 386, 388, 392, 394, 396, 398 four sources, shifted relative to each other in X and Y directions of a plane, each source having a radiating element linked to a microwave chain.The sources may have a circular or square opening.
[0025] It should be noted that it is known from patent FR 2 939 971 to produce a very compact radiofrequency chain by using an orthomode transducer, called OMT, asymmetrical with two branches associated with an unbalanced branch coupler. This radiofrequency system operates in bipolarization on transmission and reception and comprises radio frequency components and combination circuits whose overall size does not exceed the diameter of the horn. Here in Figure 11, two adjacent X-directional adjacent groups are spaced apart from a first L1 pitch corresponding to a source in the X direction and share a source in common, and two adjacent consecutive groups in the Y direction are spaced apart from each other. a second step L2 corresponding to a source in the direction Y and share a source in common. Here in FIG. 11, only the three groups 382, 384, 386 are explicitly described here. The first group 382, designated Gr1, comprises the sources 356, 360, 362, 366. The second group 384, designated by Gr2, comprises the sources 358, 362, 364, 368, is adjacent to the first group 382, Gr1, and spaced from the latter group by the pitch L1 in the direction X. The first and second groups Gr1, Gr2 share the source 362. The third group 386 comprises, designated Gr3, comprises the sources 366, 370, 372, 374, is adjacent to the first group 382, Gr1, and is spaced from the latter group L2 in the direction Y. The first and third groups Gr1, Gr3 share source 366 together. Each source comprises a first port T1 and a second transmission port T2 of the same frequency F, the first polarization P1 for the first port T1 and the second polarization P2 for the second port, the first and second nth polarizations P1, P2 being orthogonal to each other, and the frequency F designating in a simplified manner the total band of BT frequencies. For each group of four adjacent sources, the first four transmission ports T1 or the four second transmission ports T2 corresponding to the same pair of frequency and polarization value, 30 (F, P1) or (F, P2) , are interconnected, the four transmitting ports interconnected forming a transmission beam. For the formation of each beam, the links between the transmission ports of a group of four sources are made by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other.
[0026] The source array, the reflector and the distribution circuits are configured in terms of geometry and connectivity, so as to form elementary useful surfaces of spots distributed in a rectangular cover mesh.
[0027] According to FIG. 12, a schematic 392 of the first T1 port connections to each other and the second T2 ports to each other within each quadri-source array of the network of FIG. 11 is partially illustrated with corresponding a tessellating 394, also illustrated. partially, from the coverage area. This scheme makes it possible to produce a colored cover in terms of polarization states P1, P2 and rectangular cover mesh of the second embodiment of the system according to the invention. Here, four first ports T1, 396, 400, 402, 406 belonging respectively to the sources 356, 360, 362, 366 of the first group Gr1, 15 are connected together to form an elementary surface spot or rectangular cover mesh, associated with the transmission resource (F, P1) and designated by the reference numeral 407. Four second ports T2, 398, 412, 414, 418 belonging respectively to the sources 358, 362, 364, 368 of the second group Gr2, are connected together to form an elementary spot surface or rectangular cover mesh, associated with the transmission resource (F, P2) and designated by the reference numeral 419. Four second ports T2, 420, 422, 424, 426, respectively of the sources 366, 370, 372, 374 are connected together to form a rectangular spot surface or rectangular cover mesh, associated with the transmission resource (F, P2) and designated by the reference numeral 427. These examples the connections can be extended to the other groups to achieve the quad-point coverage and the reuse plane of the same main band and two polarization states according to the second embodiment of the system according to the invention. According to FIG. 13, the coverage 394 colored in terms of rectangular mesh polarization states of the second embodiment of the system according to the invention, realized by the configuration of the antenna MFPB 3035287 27 described in FIGS. 11 and 12, is illustrated over a larger geographic extent. According to a third embodiment of the system according to the invention, a quadruple dot cover, colored in terms of the reuse of the same main frequency band BP and two polarization states uses a diamond cover mesh. To achieve this diamond-mesh coverage, the antennal multibeam transmission system has a first transmit antenna and a second multi-beam beam antenna (MFPB). The first transmitting antenna comprises a first main reflector and a first network of several sources illuminating the first main reflector. The second transmitting antenna has a second main reflector and a second array of multiple sources illuminating the second main reflector. According to FIG. 14 and a second antenna configuration, the first and second networks have an identical architecture according to which the sources of an antenna array 502 are distributed in a hexagonal network mesh associated in several groups, shifted relative to each other. 20 others in X and Y directions of a plane, each source having a radiating element linked to a microwave chain. Here, only ten sources 504, 506, 508, 510, 512, 514, 516, 518, 520, 522 are represented. The sources are distributed according to a hexagonal antenna network mesh and associated in several groups 532, 534, 536, 538 Four sources, shifted relative to each other in X and Y directions of a plane, each source having a radiating element linked to a microwave chain. The sources may have a circular or square opening. Two adjacent consecutive groups in the X direction are spaced apart by a first pitch L1 corresponding to a source in the X direction and share two sources in common. Two adjacent consecutive groups in the Y direction are spaced apart by a second pitch L2 corresponding to two sources in the Y direction and share no source in common.
[0028] Here, in FIG. 14, only the three groups 532, 534, 536 are explicitly described here. The first group 532, designated Grp1, comprises the sources 504, 506, 508, 510.
[0029] The second group 534, designated Grp2, comprises the sources 508, 510, 512, 514, is adjacent to the first group 532, Grp1, and is spaced from the latter from the pitch L1 in the direction X. The first and second groups Grp1, Grp2 share sources 508, 510 together.
[0030] The third grouping 536 comprises, designated Grp3, comprises the sources 516, 518, 520, 522, is adjacent to the first group 532, Grp1, and spaced from the latter from the pitch L2 in the direction Y. The first and third groups Grp1 , Grp3 do not share any source in common. Each source comprises a first port T1 and a second transmission port T2 of the same frequency F, the first polarization P1 for the first port T1 and the second polarization P2 for the second port, the first and second polarizations P1, P2 being orthogonal to each other, and the frequency F designating in a simplified manner the total band of frequencies BT.
[0031] For each group of four adjacent sources, the first four transmission ports T1 or the four second transmission ports T2 corresponding to the same pair of frequency and polarization value, (F, P1) or (F, P2) , are interconnected, the four transmitting ports interconnected forming a transmission beam.
[0032] For the formation of each beam, the links between the transmission ports of a group of four sources are made by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other. The first and second source networks, the first and second main reflectors and the distribution circuits, the distribution circuits are configured in terms of geometry and connectivity, so as to form useful coverage spots distributed in a diamond cover mesh. . According to FIG. 15, a diagram 552 of the first T1 port connections to each other and second ports T2 to each other within each four-source array of the network 502 of the Figurel4 corresponding to an antenna is partially illustrated with corresponding a pavement 394, also partially illustrated, of the coverage area. This scheme makes it possible to achieve a colored coverage in terms of polarization states P1, P2 and rectangular cover mesh of the second embodiment of the system according to the invention. Here, the first four ports T1, 554, 556, 558, 560, respectively belonging to the sources 504, 506, 508, 510 of the first group Grp1, are connected together to form an elementary surface of spot or 10 mesh of diamond cover, associated with the transmission resource (F, P1) and designated by the reference numeral 561. Four second ports T2, 562, 564, 566, 568 belonging respectively to the sources 508, 510, 514, 512 of the second group Grp2, are connected together to forming an elementary spot surface or diamond covering mesh, associated with the transmission resource (F, P2) and designated by the reference numeral 569. Four first ports T2, 572, 574, 576, 578 respectively of the sources 516, 518, 520, 522 are connected together to form an elementary spot surface or rectangular cover mesh, associated with the transmission resource (F, P1) and designated by the numeral 579. These examples of The exions may be extended to the other groupings of each of the two antennas to provide for each one half coverage of the total coverage with quadruple points respecting the plan for reuse of the same main band and of two states of polarization according to the third embodiment. realization of the system according to the invention. By shifting the first and second antennas in the Y direction by a step equal to a source in the image plane, the antenna system 30 provides the total coverage of the system is obtained. According to FIG. 16, the total coverage 602 colored in terms of diamond-shaped polarization states of the third embodiment of the system according to the invention, realized by the configuration of the antennas MFPB antennas described in FIGS. 14 and 15, is illustrated on a larger geographical extent integrating in particular the diamond meshes covering 561, 569, 579 belonging to the first antenna. According to FIG. 17, a partial view of a third configuration of an MFPB 652 square network mesh antennasystem and more particularly a view of its source network 654 and its four-source arrays connected in a idoine so as to achieve a fourth embodiment of a system according to the invention wherein the cover mesh is square. The antenna multibeam emission system 652 is provided by a single multi-source MFPB beam source antenna which includes a main reflector and the array 654 of a plurality of sources illuminating the reflector. Here, only four sources 656, 658, 660, 662 are represented. The sources are distributed in a square array array and associated in several groups 672, 674, 676, 678, 680 from four sources, shifted relative to each other. to the others in X and Y directions of a plane orthogonal to each other, each source comprising a radiating element linked to a microwave chain. The radiating aperture of the radiating element of each source has a square shape.
[0033] Two adjacent consecutive groups in the X direction are spaced apart from a first L1 step corresponding to a source in the X direction and share a source in common. Two adjacent adjacent groups in the Y direction are spaced apart by a second L2 step corresponding to a Y-direction source and share a source in common.
[0034] Here, in FIG. 17, only the group 672 which includes the sources 656, 658, 660, 662 is explicitly described here. Each source comprises a first port T1 and a second transmission port T2 having the same frequency F, the first polarization P1 for the first port T1 and the second polarization P2 for the second port, the first and second polarizations P1, P2 being orthogonal to each other, and the frequency F designating in a simplified manner the total band of frequencies BT. For each group of four adjacent sources, the first four transmission ports T1 or the four second transmission ports T2 corresponding to the same pair of frequency and polarization value 3035287 31 (F, P1) or (F, P2), are interconnected, the four transmission ports interconnected forming a transmission beam. For the formation of each beam, the links between the transmission ports of a group of four sources are made by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other. The source array, the reflector and the distribution circuits are configured in terms of geometry and connectivity, so as to form elementary useful surfaces of spots distributed in a square coverage mesh. Here, for each group 672, 674, 676, 678, the first ports of the respective sources that compose them are interconnected to radiate the electromagnetic resource associated with the pair (F, P2). For example the first ports of the sources 656, 658, 660, 662 are interconnected.
[0035] The second ports of the four sources, forming the group 480 and shared respectively with the groups 672, 674, 676, 678, are interconnected. According to FIG. 18, the coverage 692 colored in terms of square-mesh polarization states of the fourth embodiment of the system 20 according to the invention, realized by the third configuration of the MFPB antenna described in FIG. 17, is illustrated. partially by the partial coverage 494. The cross-shaped partial cover 694 comprises four square elementary useful surfaces 695, 696, 697, 698, each associated with the resource pair (F, P2), which surround the square elementary useful surface 699 , associated with the pair (F, P1). The square elementary surface areas 695, 696, 697, 698, 699 are formed and radiated respectively by the source groups 672, 674, 678, 676 and 680. The partial coverage 694 naturally extends to the total coverage 699, colored in terms of polarization states in the form of a checkerboard. Generally speaking, the forward path scheduler and resource allocator is configured to allocate to a transmitting terminal when it requests it a forward path forwarding resource in terms of a frequency subband and a forward bias. the geographical position of the transmitting terminal and a transmission resource allocation plan. In the case of insufficient control of the attitude of the satellite platform may cause a crippling misalignment of the receiving antenna 5 of the satellite, an automatic system for correcting the misalignment of the receiving antenna may be used. The geographical positioning means of each transmitting terminal is sufficiently precise to determine in which reception spot it is, if it is located in an inner zone or in a peripheral zone 10 of the spot. The geographical positioning means is, for example, a receiver of a global satellite positioning system. It can also be a receiver of the predetermined internal channel power levels of the radio communication system which, related to a ground station of the radiocommunication system will allow said ground station to determine the geographical position of the receiver. Alternative allocation schemes are possible depending on the local variability of the traffic, translated into local traffic density, and the temporal dynamics of the traffic on the coverage. For example, in a first case, the size of the central inner zone, representative of a scale factor, varies according to the reception spot and the time. In a second case, the size of the central zone varies according to the reception spot and is independent of the time. In a third case, the size of the central zone is constant, independently of the reception spot and the time.
[0036] According to FIG. 19, a method 702 of complete or fractional reuse of frequencies of a total BT band allocated to a forward channel is implemented in a satellite radiocommunication system such as that described in FIGS. 1 to 18. The system satellite radio communication system comprises a satellite 30 having an antenna multibeam transmission system, configured to cover a geographical coverage, broken down into a plurality of emission spots, and a set of transmitting terminals distributed over all the spots, each terminal comprising a means geographical positioning.
[0037] The satellite radio system also includes a scheduler and allocator of forward link transmission resources. The method 702 comprises a set of successively executed steps.
[0038] In a first step 704, a forward path transmission resource allocation plan is determined according to which each transmission spot consists of a central inner zone and a peripheral zone surrounding the central inner zone. In addition, according to the reuse plane, the first polarization state P1 and the second polarization state P2 are respectively allocated to the spots of the first gate G1 and to the spots of the second gate G2. The same main band BP of frequencies in one piece or in several pieces, forming a preponderant part of the total band BT in terms of occupied band, is also allocated in full to each central inner zone of the spots of the first and second gratings. . The frequencies of the total band BT which are not part of the main band BP form a secondary band BS in one piece or in several pieces which is decomposed into an integer n, greater than or equal to 2, of sub-bands side-by-side secondary cells each, separate or adjacent, distributed over all the peripheral zones 20 of the emission spots in a multicolored pattern with n subband colors. The points of intersection between the spots of the first and second grids are quadruple points, that is to say having an order of multiplicity equal to 4.
[0039] The quadruple points define one-per-square elementary coverage areas that form a tiling of the coverage area. Each elementary useful surface constitutes a mesh of the paving having the shape of a parallelogram.
[0040] Each inner zone is inscribed in an elementary useful surface. Then, in a second step 706, for each receiving terminal that wishes to have a transmission resource, it is determined in which transmission spot the receiving terminal is located and whether it is in an internal zone or in an area. peripheral.
[0041] Then, in a third step 708, the forward channel resource scheduler and allocator allocates to a receiving terminal, when requested, a forward path transmission resource in terms of a frequency sub-band of the total band BT and a polarization state taken from a first polarization state P1 and a second polarization state P2 as a function of the geographical position of the receiver terminal. When the receiving terminal is in an internal area, the terminal is allocated a transmission resource of the main band and the state of polarization which has been allocated by the reuse plan to the internal area of the transmission spot. in which the terminal is located. When the receiving terminal is in a peripheral zone, the terminal is allocated an auxiliary subband transmission resource and the polarization state which has been allocated to the peripheral area of the transmitting spot in which the terminal is located. In variants, the size of the central zone varies according to the emission spot and the time, or the size of the central zone varies according to the emission spot and is independent of the time. The satellite radio system and the frequency reuse method are configured for satellite return channel reception in a band within the C, X, Ku, Ka, L, S, Q, and V bands. A static planning of the cellular pattern corresponds to an optimum for a system with maximum load.
[0042] When the systems are not 100% loaded, a dynamic planning on a C11 criterion can be considered, notwithstanding that an optimum at a given moment is not necessarily consistent with the next instant and leads to a complexity in the planning management. Frequency reuse and polarization methods using quadruple-dot coverage as described above allow to increase the transmission capacity of a satellite but also the density of capacity, i.e. the bit rate. addressable per unit area. 35

权利要求:
Claims (2)
[0001]
REVENDICATIONS1. A multibeam broadband satellite radio system configured for fractional frequency reuse of a total BT band allocated to a forward channel (4), comprising: a satellite (10) having a multibeam transmitting antenna system (20), configured to cover a geographical service area (22), the first gate G1 and the emission spots (32, 34, 42, 44) of the second gate G2 being positioned and their radiation pattern being configured so that there are intersection points (62, 64, 66, 68) between the iso-roll-off contours of an integer m, greater than or equal to three, of adjacent spots partially overlapping, the number m denoting the order multiplicity of points of intersection; and a set of receiver terminals (14, 16) distributed over all the transmission spots, each receiver terminal (14, 16) comprising a geographical positioning means (72) and a reception means (74). following an allocated transmission resource; a scheduler and allocator of one-way transmission resources (18), realized in the form of one or more electronic computers (82), configured to assign to a receiving terminal (14, 16) when it requests it a transmission resource path in terms of a frequency sub-band of the total band BT and of a polarization state taken from a first polarization state P1 and a second polarization state P2 as a function of the geographical position of the terminal receiver (14, 16) and a forward transmission resource allocation plan (102, 302), wherein each transmit spot (26, 28, 30, 32, 34, 36, 38) is consisting of a central inner area (106, 108, 110, 112, 114, 116, 118) and a peripheral area (126, 128, 130, 132, 134, 136, 138) surrounding the central inner area; and decomposed into a plurality of emission spots (26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50), with a first gate G1 of spots (26, 28, 30, 36, 38, 40, 46, 48, 50) and a second gate G2 of emission spots (32, 34, 42, 44), the emission spots (26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50), the first state of polarization and the second state of polarization are respectively allocated to the spots of the first gate G1 and to the spots of the second gate G2, and the same main band BP of single or multi-piece frequencies, forming a predominant part of the total band BT in terms of occupied band, is allocated in total to each central internal area (106, 108, 110, 112, 114 , 116, 118) spots of the first and second grids; and the frequencies of the total band BT which are not part of the main band BP form a secondary band BS in one piece or in several pieces which is decomposed into an integer n, greater than or equal to 2, of one-piece sub-strips each, separate or adjacent, distributed over all the peripheral zones (126, 128, 130, 132, 134, 136, 138) of the emission spots according to a multicolor 15 pattern with n colors sub-band sub-bands, characterized in that the points of intersection between the spots of the first and second grids are quadruple points of intersection that is to say having an order of multiplicity equal to 4. .2 System of multibeam satellite radiocommunication system according to claim 1, wherein the quadruple points define one-per-square elementary coverage coverage areas which form a tiling of the coverage area, and each basic useful surface area Tituce a mesh of the same size and shape, and the shape of the mesh is a parallelogram. The multibeam satellite radio system according to claim 2, wherein the shape of the mesh is a square or a rectangle or a rhombus. 4. A multibeam satellite radiocommunication system according to any one of claims 1 to 3, wherein each inner zone is inscribed in the elementary useful surface of its emission spot. 5. A multibeam satellite radiocommunication system according to any one of claims 1 to 4, wherein the number n of sub-subbands is an integer included in the set of numbers 2, 3, 4, 7 and 12, and preferably equal to
[0002]
2. 10 .6 multibeam satellite radiocommunication system according to any one of claims 1 to 5, wherein the first and second polarization states (P1, P2) are the left circular polarization and the right circular polarization or a first linear polarization along a first axis and a second linear polarization along a second axis orthogonal to the first axis. A multibeam satellite radiocommunication system according to any one of claims 1 to 5, wherein the multibeam transmission antenna system comprises first and second beam single source transmit antennas (SFPB), the first antenna comprising a first network of sources distributed according to a mesh of first square network and a first main reflector; The second antenna having a second source array distributed in a second square lattice array and a second main reflector; and The first and second source arrays as well as the first and second main reflectors are geometrically configured to form a coverage of the quad-dot service area and square coverage mesh. A multibeam satellite radiocommunication system according to any one of claims 1 to 6, wherein the multibeam transmission antenna system comprises a single multi-beam beam emission antenna (MFPB); and the transmitting antenna comprises a main reflector and an array of several sources illuminating the reflector, the sources being distributed in a hexagonal or square antenna network mesh and associated in several groups offset from one another according to 5 X and Y directions of a plane, each source comprising a radiating element linked to a microwave chain; Each source comprises a first port and a second transmission port of the same frequency (F) and polarizations (P1, P2) orthogonal to each other. The sources are associated in groups of four adjacent sources in directions X and Y; for each group of four adjacent sources, the first transmission ports or the second transmission ports corresponding to the same pair of frequency and polarization values (F, P1), (F, P2) are connected between they, the four transmitting ports interconnected forming a beam of emission; for the formation of each beam, the links between the transmission ports of a group of four sources are formed by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other; 20 .- The source network, the reflector and the distribution circuits are configured in terms of geometry and connectivity, so as to form a total coverage or half coverage of the service area by emission spots distributed according to a mesh covering comprised of rectangular, rhombic and square meshes. 25 .9 A multibeam satellite radiocommunication system according to claim 8, wherein the source network mesh is a hexagonal array antenna mesh and the radiating aperture of the radiating element is circular or square in shape; and two consecutive adjacent groups (Gr1, Gr2) in the X direction are spaced apart by a first pitch L1 corresponding to a source in the X direction and share a source in common; Two consecutive adjacent groups (GO Gr3) in the Y direction are spaced apart by a second pitch L2 corresponding to a source in the Y direction and share a source in common; Each group of four sources forming a substantially rectangular shaped emitting beam or rhombus for adjusting the associated distribution circuits. .10 A multibeam satellite radiocommunication system according to claim 8, wherein the source network mesh is a hexagonal antenna network mesh and the radiating aperture of the radiating element is circular or square in shape; and two adjacent consecutive groups (Grp1, Grp2) in the X direction are spaced apart by a first pitch L1 corresponding to a source in the X direction and share two sources in common; and two adjacent consecutive groups (Grp1, Grp3) in the Y direction are spaced apart by a second pitch L2 corresponding to two sources in the Y direction and share no source in common; and each group of four sources forms a substantially diamond shaped or rectangular shaped emitting beam for adjustment of the distribution circuits associated with said group. The multibeam satellite radiocommunication system of claim 8, wherein: The mesh of the source array is a square antenna lattice and the radiating aperture of the radiating element is square in shape; and .- the two directions X and Y form a right angle; and two adjacent consecutive groups (Gr1, Gr2) in the X direction are spaced apart by a first pitch L1 corresponding to a source in the X direction and share a source in common; and two adjacent consecutive groups (Gr1, Gr3) in the Y direction are spaced apart by a second pitch L2 corresponding to a source in the Y direction and share a source in common; and each group of four sources forms a substantially square emitting beam for adjusting the distribution circuits associated with said group; and the source array, the reflector and the distribution circuits are configured in terms of geometry and connectivity, so as to form a total coverage of the service area by emission spots distributed in a square coverage mesh. A multibeam satellite radio system according to any one of claims 1 to 5, wherein the multibeam transmit antenna system includes a first transmit antenna and a second multi-beam beam antenna (MFPB); and - the first transmitting antenna comprises a first main reflector and a first array of plural sources illuminating the first main reflector; The second transmitting antenna comprises a second main reflector and a second network of several sources illuminating the second main reflector; the first and second networks have an identical architecture according to which, the sources of an antenna array are distributed according to a hexagonal network mesh associated in several groups, offset relative to each other in directions of a plane X and Y, each source comprising a radiating element linked to a microwave chain; Each source comprises a first port and a second transmission port 25 of the same frequency (F1) and with polarizations (P1, P2) orthogonal to each other. The sources are associated in groups of four adjacent sources according to the X directions. and Y .- for each group of four adjacent sources, the first transmission ports corresponding to the same pair of frequency and polarization values (F1, P1), (F1, P2), are connected in pairs according to the direction X then two by two in the direction Y, the four transmission ports interconnected forming a transmission beam; for the formation of each beam, the links between the transmission ports of a group of four sources are made by distribution circuits, the distribution circuits dedicated to the formation of different beams being independent of each other; The first and second source networks, the first and second main reflectors, and the distribution circuits are configured in terms of geometry and connectivity, so as to form a total coverage of the service area by distributed emission spots. according to a rectangular or rhombic cover mesh. .13 A multibeam satellite radio communication system according to claim 12, wherein the mesh of the first network of the sources and the second array of sources is a hexagonal array antenna mesh and the radiating aperture of the radiating element of each source has the same circular or square shape; and for each network: two adjacent consecutive groups (Grp1, Grp2) in the X direction are spaced apart by a first step L1 corresponding to a source in the X direction and share two sources in common; two adjacent consecutive groups (Grp1, Grp3) in the Y direction are spaced apart by a second pitch L2 corresponding to two sources in the Y direction and share no source in common; Each group of four sources forming a substantially diamond-shaped emission beam for adjustment of the associated distribution circuits. A multibeam satellite radiocommunication system according to claim 12, wherein the mesh of the first network of the sources and the second array of sources is a hexagonal array antenna mesh and the radiating aperture of the radiating element of each source has the same circular or square shape; and for each network: two adjacent consecutive groups (Gr1, Gr2) in the X direction are spaced apart by a first step L1 corresponding to a source in the X direction and share a source in common; and two adjacent consecutive groups (Gr1, Gr3) in the Y direction are spaced apart by a second pitch L2 corresponding to a source in the Y direction and share a source in common; and each group of four sources forms a substantially rectangular shaped emission beam for adjustment of the distribution circuits associated with said group. A multibeam satellite radio system according to any one of claims 1 to 14, wherein the satellite is configured to radiate in each spot and over its entire extent including its central zone and its peripheral zone, a color of transmission resources. transmitted, formed of the main frequency band, the secondary band and the state of polarization allocated to said spot by the frequency plane and polarization states. 16. A multibeam satellite radiocommunication system according to any one of claims 1 to 15, further comprising an automatic system for correcting the misalignment of the antenna caused in particular by variations in attitude of the satellite platform. 17. A multibeam satellite radiocommunication system according to any one of claims 1 to 16, further comprising a set of receiver terminals distributed over all the spots, and each terminal comprises a geographic positioning means (44) sufficiently precise for determine in which emission spot it is, and whether it is in an inner zone or in a peripheral zone of said emission spot. 18. A multibeam satellite radiocommunication system according to any one of claims 1 to 17, wherein the forward path resource scheduler and allocator (18) is distributed over all terminals and / or one or more auxiliary stations or is centralized in a station (54) for controlling resources and their planning. A multibeam satellite radio system according to any one of claims 1 to 18, wherein the size of the central area varies as a function of the emission spot and the time, or the size of the central area varies by depending on the emission spot and is independent of the time or, The size of the central area is constant regardless of the emission spot and time. 20. A multibeam satellite radiocommunication system according to any one of claims 1 to 19, configured for an emission of the forward path by the satellite in a band comprised in the set of bands C, X, Ku, Ka, L, S, Q and V. 21. A method of complete or fractional reuse of a total band allocated to a forward channel in a broadband multibeam satellite radio system, the system comprising: a satellite (10) having a system multi-beam emission antennas 20 25 of the first gate G1 and the emission spots (32, 34, 42, 44) of the second gate G2 being positioned and their radiation pattern being configured so that there are points d intersection (62, 64, 66, 68) between the iso roll-off contours of an integer m, greater than or equal to three, of partially overlapping adjacent spots, the number m denoting the order of multiplicity of points inte rsection; and a set of receiver terminals (14, 16) distributed over all the transmission spots, each receiving terminal (14, 16) comprising a geographical positioning means (72) and a receiving means (74) following an allocated transmission resource; and (20) configured to cover a geographical service area (22), broken down into a plurality of emission spots (26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50) , with a first gate G1 of spots (26, 28, 30, 36, 38, 40, 46, 48, 50) and a second gate G2 of emission spots (32, 34, 42, 44), the spots of transmission (26, 28, 30, 32, 34, 36, 38, 40, 42, 44, 46, 48, 50), 3035287 44 .- a scheduler and allocator of transmission resources go way (18), realized under the form of one or more electronic computers (82); The method comprising the steps of: - Determining (704) a transmission resource allocation plan (102, 302) forward path along which, each transmission spot (26, 28, 30, 32, 34, 36 , 38) comprises a central inner area (106, 108, 110, 112, 114, 116, 118) and a peripheral area (126, 128, 130, 132, 134, 136, 138) surrounding the area central internal; and the first state of polarization and the second state of polarization are respectively allocated to the spots of the first gate G1 and the spots of the second gate G2, and the same main band BP of frequencies in one piece or in several pieces, forming a predominant part of the total band BT in terms of occupied band, is allocated in full to each central inner zone (106, 108, 110, 112, 114, 116, 118) spots of the first and second grids; and the frequencies of the total band BT which are not part of the main band BP form a secondary band BS in one piece or in several pieces which is decomposed into an integer n, greater than or equal to 2, of single-side secondary bands, each separated or adjacent, distributed over all the peripheral zones (126, 128, 130, 132, 134, 136, 138) of the emission spots according to a multicolored pattern with n colors secondary subbands, 25-. assigning (706) to a receiving terminal (14, 16) when it requests a forward path transmission resource in terms of a frequency sub-band of the total band BT and a polarization state taken from a first state of polarization P1 and a second state of polarization P2 as a function of the geographical position of the receiving terminal (14, 16) characterized in that the points of intersection between the spots of the first and second grids are quadruple points, c that is, having an order of multiplicity equal to 4; and the quadruple dots define one-per-square coverage of the coverage area, and each elementary useful surface constitutes a parallelogram-shaped paving mesh. and each inner zone is inscribed in an elementary useful surface. 22. The frequency reuse method according to claim 21, further comprising the steps of: for each terminal that wishes to have a transmission resource, determine (708) in which transmission spot it is finds and if it is in an internal zone or in a peripheral zone, then. * when the terminal is in an internal zone, allocate to the terminal a transmission resource of the main band and the state of polarization assigned to the internal area of the transmitting spot in which the terminal is located, or. when the terminal is in a peripheral zone, allocating to the terminal an auxiliary subband transmission resource and the polarization state which have been allocated to the peripheral area of the transmission spot in which the terminal is located. 23. The method of frequency reuse according to any one of claims 21 to 22, wherein the size of the central zone varies according to the emission spot and the time, or the size of the central zone varies according to emission spot and is independent of the time or, The size of the central area is constant regardless of the emission spot 30 and time.

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2016-03-23| PLFP| Fee payment|Year of fee payment: 2 |

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2016-10-21| PLSC| Search report ready|Effective date: 20161021 |

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2017-03-27| PLFP| Fee payment|Year of fee payment: 3 |

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2018-03-27| PLFP| Fee payment|Year of fee payment: 4 |

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2020-01-10| ST| Notification of lapse|Effective date: 20191206 |

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FR1500785A|FR3035287B1|2015-04-15|2015-04-15|BROADBAND MULTI-STAGE SATELLITE SATELLITE RADIOCOMMUNICATION SYSTEM WITH IMPROVED FREQUENCY REUSE, AND REUSE METHOD THEREOF|FR1500785A| FR3035287B1|2015-04-15|2015-04-15|BROADBAND MULTI-STAGE SATELLITE SATELLITE RADIOCOMMUNICATION SYSTEM WITH IMPROVED FREQUENCY REUSE, AND REUSE METHOD THEREOF|

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EP16164766.4A| EP3082275B1|2015-04-15|2016-04-11|Broadband multibeam satellite radio communication system with improved reuse of frequencies on the forward channel, and associated method for reuse|

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CA2927223A| CA2927223A1|2015-04-15|2016-04-14|Broadband multibeam satellite radio communication system with improved reuse of frequencies on the forward channel, and associated method for reuse|