• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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  • 优先权
    • 专利摘要:
    A satellite communications network (100) as well as transmitting, receiving and repeating methods and associated equipment, wherein transmitting a signal between a transmitting station and a receiving station is performed by a plurality of satellites in common visibility of these two stations, at least one of the transmitting station (110), the receiving station and said satellites comprising signal separation means (111, 112, 113) transmitted to or from the satellites (131, 132, 133) used for transmission, and is configured to calculate for each of the signals at least one offset provided by the propagation of the signal, from the position of the transmitting station, the receiving station, and the satellite through which it is transmitted, then to apply to the signal an inverse shift of said calculated offsets.
    公开号:FR3046313A1
    申请号:FR1502676
    申请日:2015-12-23
    公开日:2017-06-30
    发明作者:Thibaud Calmettes;Michel Monnerat
    申请人:Thales SA;
    IPC主号:
    专利说明:

    The invention is in the field of satellite communications, and more particularly relates to a method of satellite communications in which the communication links are made by a plurality of satellites.
    Several recent initiatives aim to deploy "massive" satellite constellations. Massive means that they include more than 100 satellites. This is the case, for example, for two public initiatives aiming for deployment by 2020: OneWeb and SpaceX.
    However, the telecom technology approach for these solutions remains very close to known technologies. It relies in particular on the realization of satellite spots, each of the spots being served by one of the beams of a particular satellite.
    This approach does not really take advantage of the massive aspect of the constellation: at a given moment, a receiver is in connection with only one satellite, while several satellites are generally in visibility. The link budget is therefore dimensioned as part of this single link.
    For antenna design constraints relating to the desired size of satellite spots, this approach is rather oriented towards constellations in low Earth orbit (or Low Earth Orbit, or LEO). However, the use of LEO satellites leads to stronger Doppler effects, shorter visibilities, and therefore more handover. LEO satellites have less coverage than satellites in higher orbit, and thus require Inter Satellite Links (or ISLs), and / or more ground-based satellite gateways.
    The size of the spots can not be reduced as much as desired for reasons of congestion of the antenna on the satellites. This therefore also generates the need to manage a residual multiple access, and thereby causes a reduction in availability for the user.
    Finally, the implementation of satellite spots impacts the design of the satellite, and in particular the design of its antenna. It requires a strong intelligence in the management of networking. The invention relates to a new mode of deployment of a satellite network, adapted to the use of "massive" satellite constellations, and which consists in completing or abandoning the traditional beam distribution, to exploit the fact that the size constellations allows to simultaneously have several satellites in visibility of the various points of the globe.
    For this, it proposes to transmit the signals jointly through several separate satellites. The transmission by each of the satellites takes into account the position of the transmitter, the receiver and the satellite itself, compensation of the offsets related to the propagation of the signal being carried out so that the signals are recombined at the receiver without generating interference. The invention is indifferently placed on transmission or reception, and proposes a coupled system in which the location of each of the actors of the transmission and the recombination of the signals go hand in hand. The invention therefore consists of a satellite communications network comprising at least one transmitting station, at least one receiving station, and a plurality of satellites. The network according to the invention is characterized in that a signal transmission between the transmitting station and the receiving station is performed by a plurality of satellites in common visibility of these two stations. It is also characterized in that at least one of the transmitting station, the receiving station and the said satellites comprise means for separating the signals transmitted to or from the satellites used for transmission. The network according to the invention is configured to calculate for each of the signals at least one offset provided by the propagation of the signal, from the position of the transmitting station, the position of the receiving station, and the position of the satellite by which it is transmitted, then to apply to the signal at least one inverse offset of said calculated offsets.
    According to one embodiment of the communications network according to the invention, the calculation of the offset or shifts is furthermore carried out from at least one of a speed vector of the transmitting station, a speed vector of the receiving station. , and a velocity vector of the satellite through which the signal is transmitted.
    Thus, the satellite velocity vector is necessary when it is not a geostationary satellite, in order to calculate and compensate for the Doppler effect introduced by the displacement of this satellite.
    The knowledge of the speed vector of the transmitting and / or receiving station is appreciable when that (s) is moving at a speed that is significant relative to the speed of the satellite.
    According to different embodiments of the communications network according to the invention, the calculation of the offset or shifts comprises at least one of the calculation of a time shift, a frequency offset, a phase shift and an offset. in power.
    According to one embodiment of the communications network according to the invention, the signal separation means comprise an active antenna for separating the signals transmitted by each of the satellites used for transmission.
    According to another embodiment of the communications network according to the invention, the signal separation means comprise a plurality of directional antennas making it possible to separate the signals transmitted by each of the satellites used for transmission.
    According to another embodiment of the communications network according to the invention, the transmitted signal is modulated according to a direct sequence spectrum spreading technique, the transmission station having means for separating the signals sent to the satellites used to the transmission, each of the signals being modulated with a distinct sequence, the receiving station being configured to separate the signals received from each of the satellites used for transmission from the sequence used on transmission.
    According to another embodiment of a communications network according to the invention, a carrier frequency of the signal transmitted by the transmitting station is adapted according to the satellite used for the transmission, the transmitting station having separation means signals sent to the satellites used for transmission, the receiving station being configured to separate the signals received from each of the satellites used for transmission from their carrier frequency.
    According to the other embodiment of a communications network according to the invention, the transmitting station has means for separating the signals sent to the satellites used for transmission, the transmitted signal being repeated, the inverse offsets applied to the signals for each repetition being calculated from different assumptions of a direction of movement of the receiver.
    Advantageously, the transmitting station is configured to transmit a signal dedicated to a calibration of the inverse offsets applied to the signals.
    Advantageously, the transmitting station and the receiving station are further configured to exchange a synchronization message by each of the selected satellites successively before transmitting the signal.
    Advantageously, the transmitting station and the receiving station are further configured to exchange a synchronization message by each of the selected satellites simultaneously before transmitting the signal. The invention also addresses a method of transmitting a signal from a transmitting station to a receiving station in a satellite communications network, said network comprising at least two satellites in common visibility of the transmitting station and the receiving station, said transmitting station knowing its position as well as those of the receiving station and the satellites in common visibility, and having means for separating the signals transmitted to the satellites in common visibility. The method according to the invention is characterized in that it comprises the steps of: • selecting, among the satellites in common visibility, a plurality of satellites used for the transmission of the signal, • calculation, for each of the selected satellites, at least one offset related to the propagation of the signal from the position of the transmitting station, the position of the receiving station, and the position of said satellite, • calculating, for each of the selected satellites, a signal pre-compensated by applying at least one inverse offset of the calculated offset (s), and sending, to each of the selected satellites, the precompensated signal associated therewith. The invention then addresses a method of receiving a signal transmitted between a transmitting station and a receiving station in a satellite communications network, said network comprising at least two satellites in common visibility of the transmitting station and of the receiving station, said receiving station knowing its position and those of the transmitting station and satellites in common visibility, and having means for separating the signals received from the satellites of the network, the signal being transmitted through of a plurality of satellites among the satellites in common visibility. The method according to the invention is characterized in that it comprises the steps of: • selecting, among the satellites in common visibility, a plurality of satellites used for the reception of the signal, • calculation, for each of the selected satellites, at least one offset related to the propagation of the signal from the position of the transmitting station, the position of the receiving station, and the position of said satellite, receiving the signal from each of the selected satellites, Calculating, for each of the selected satellites, a compensated signal by applying to the signal received at least one inverse offset of the calculated offset (s), and summation of the set of compensated signals. The invention finally addresses a method of repeating a signal in a satellite during the transmission of a signal between a transmitting station and a receiving station in a satellite communications network, said satellite being one of a plurality satellites of the network in common visibility of the transmitting station and the receiving station, said satellite knowing its position, the position of the transmitting station, and the position of the receiving station, and having separation means signals received from the transmitter and the receiver. The method according to the invention is characterized in that the signal is transmitted by a plurality of satellites, and in that it comprises the steps of: • reception of the signal transmitted from the transmitting station, • calculation of at least one first offset related to the propagation of the signal between the transmitter and the satellite from the position of the satellite, and the position of the transmitter, • calculation of at least one second offset related to the propagation of the signal between the satellite and the receiver from the position of the satellite and the position of the receiver, • computation of a compensated signal, by applying to the received signal inverse offsets at the first and second calculated offsets, and • emission of the compensated signal to the station reception. The invention also applies to the following equipment: Transmitting station configured to implement a method of transmitting a signal as described above. • Receiving station configured to implement a method of receiving a signal as described above. • Satellite configured to implement a method of repeating a signal as described above.
    Description The invention will be better understood and other features and advantages will appear better on reading the description which follows, given by way of non-limiting example, and with reference to the appended figures in which: FIG. 1 shows a satellite network in which transmitter has signal separation means, and wherein the invention is implemented according to a first embodiment, • Figure 2 shows a satellite network in which the receiver has signal separation means, and where the The invention is implemented according to a second embodiment, • FIG. 3 presents a satellite network in which each of the satellites has signal separation means, and wherein the invention is implemented according to a third embodiment, FIG. 4 presents a diagram of the steps performed by the communication method according to the invention when it is executed at the transmission, and • Figure 5 shows a diagram of the steps performed in the communication method according to the invention when it is executed on reception, • Figure 6 shows a diagram of the steps performed in the communication method according to the invention when executed by a satellite. The invention is placed within the framework of a satellite network, in particular but not necessarily when it is massive, that is to say when it comprises a number of satellites such that several of them are generally in visibility of the same geographical area. The invention can replace a satellite network whose deployment is achieved by beams, but can also be integrated in addition to such a satellite deployment.
    In the following, we will talk about transmitter and receiver. Transmitter means the equipment at the origin of the transmission, and by receiver the equipment receiving the transmission. These devices may be transmitting or receiving stations, such as satellite gateways, terminals, satellite telephones, distress beacons, or any other equipment adapted to satellite communications. In addition, the invention also applies to satellite remote control telemetry signals for monitoring and programming the satellite itself. In this case, the receiver and the satellite are one and the same entity, the diversity coming from several transmitting stations transmitting the same remote control, or from the same transmitting station having antennas at different geographical positions, which allows the device to be applied to several satellites at a time by combining the signals on the antenna array so that the in-phase recombination is coherent only in the desired direction.
    We will also talk about rising and descending. Communications having the path from a transmitter to a satellite, and the retransmission of the signal from the satellite to a receiver, the uplink refers to the transmitter - satellite segment, while the downlink refers to the satellite - receiver segment.
    Finally, we will speak of satellite in common visibility when a satellite is visible both by the transmitter and the receiver. These satellites are not necessarily in the same area, and are not necessarily in visibility of each other. To date, due to the novelty of deployment of massive satellite constellations, only one solution is known that uses multiple visibilities, and not for the purpose of implementing a communication network, but to enable locating a distress beacon of unknown position. This solution is presented in the French patent application FR 1401510. In this system, implemented under the name MEOSAR (acronym for Medium Eart Orbit Search And Rescue), a distress signal is transmitted by a beacon, and retransmitted to a satellite gateway by all the satellites in visibility of the beacon and the station.
    The gateway traverses a grid of possible positions of the distress beacon, and applies, for each point of the gate, different offsets to each of the signals received, the offsets being a function of the position of the grid tested, the satellite, and the position of the satellite gateway. The signals are then recombined.
    The present invention proposes an alternative satellite communication solution to conventional satellite beam deployment techniques, which is less expensive, more efficient, and adapted to so-called "massive" satellite constellations. For this, it extends the process of the French application FR 1401510 beyond the mere localization of a beacon, and applies it to both the uplink and the downlink. Several embodiments applicable to the uplink and the downlink are described, as well as a method for calibrating transmissions and receptions. All of the embodiments are based on the basic assumption that the position of the various actors of the network (transmitter, satellites used for the relay and receiver) is known. Unlike the patent application FR 1401510 which requires exactly 4 satellites in common visibility of the beacon and the satellite gateway, the invention applies regardless of the number of satellites in visibility used for transmission. The performance gain is relative to this number of satellites, and is approximately 10.log (N), where N is the number of satellites in visibility.
    FIG. 1 shows a satellite network 100 in which the transmitter has signal separation means, and in which the invention is implemented according to a first embodiment.
    The satellite network comprises a transmitter 110, transmitting a message to a receiver 120. The transmission is performed by means of three satellites 131, 132 and 133, in common visibility of the transmitter and the receiver. The transmitter comprises means for separating the signals transmitted to each of the satellites. These signal separators make it possible to geometrically separate and process the signals transmitted to each of the satellites. In FIG. 1, these means are embodied in the form of three directional antennas 111, 112 and 113, each of the antennas being pointed towards a different satellite. Other implementations are possible, such as the use of an active antenna. Active antennas are antennas comprising a multitude of radiating elements for controlling the radiation pattern of the antenna so as to form beams in one or more given directions. More precisely, the same signal is emitted on each of the radiating elements, but by first applying a phase shift on each of them. Thus only the satellites in the direction where the optical path difference of the signal is equal to the opposite of the applied phase shifts (which corresponds to a precise direction in azimuth and elevation) will receive the sum signal in a coherent manner, the sum signal. being zero in the other directions. It is thus possible to differentiate the pointing directions of the beams, and to transmit a different signal to each of the beams. The transmitter 110 knows its own position, as well as the position of the satellites 131, 132 and 133. It also requires knowledge of the speed vector of the satellites, that is to say their ground travel speeds associated with their directions of travel. displacement. This knowledge of the velocity vector is not necessary when the satellites are geostationary satellites, their velocity of displacement then being considered as null. The information concerning the positions and displacements of the satellites are transmitted by the ephemeris, according to methods well known to those skilled in the art. The transmitter also knows the position of the receiver 120. When the topology of the network is fixed, then this position can be programmed in advance. When the topology of the network is likely to evolve, this position can for example be acquired by the receiver through GNSS positioning (or acronym for Global Navigation Satellite System), and transmitted by a low-speed message during the entry phase into the terminal network, then regularly updated. For this, we can consider that this low bit rate exchange for the initial position (and its possible evolutions) can be done on a separate channel frequency, time (with periodic reporting windows for example), or code spreading . In a CDMA environment, it can also be done with low bandwidth narrow modulation without spreading over CDMA modulations. From the knowledge of these positions, the transmitter is able to calculate, for each of the satellites used for transmission, the offsets applied to the signal during its propagation.
    These offsets are of several types: - time offset, related to the travel time relative to the propagation between the transmitter and the satellite, and then to the propagation between the satellite and the receiver. By calling E the position vector of the transmitter, and R the position vector of the receiver, the propagation time (in seconds) is | R - E \ / c, with c speed of light in vacuum. The calculation is to be made a first time for the time shift between the transmitter and the satellite, then a second time for the time shift between the satellite and the receiver, the total time offset being the sum of these two travel times. - Frequency offset, or Doppler shift, associated with the relative displacement of the satellite relative to the transmitter, and the relative displacement of the satellite relative to the receiver. Using the same notation as above, and taking VE as the velocity vector of the transmitter, and VR as the velocity vector of the receiver, the Doppler shift, expressed in Hz, is given by:
    with f the transmission frequency, the dot operator being the dot product. The calculation is to be made a first time for the frequency shift between the transmitter and the satellite, then a second time for the frequency shift between the satellite and the receiver, the total frequency offset being the sum of these two values.
    Ground speed is generally negligible compared to satellite speed, which is in the order of 5km / sec for a Medium Earth Orbit (MEO) constellation and 7 to 8km / dry for a LEO (Low Earth Orbit) constellation. Thus, the value of the frequency offset can be calculated quite accurately by taking into account only the displacement of the satellites. The speed of movement of the transmitter or the receiver can nevertheless be taken into account when at least one of them moves rapidly, as for example in the case of a station on board an airplane, or when the satellites envisaged are geostationary satellites, for which the speed of travel can be considered as zero, - power offset, related to the signal power variation of, on each of the ground-satellite and satellite-ground segments, link loss losses These are losses of free space, but also antenna gains on transmission and reception, the antenna gains depending on the elevation and the azimuth of transmission and reception. A total power offset, sum of the power offset on the uplink and the power offset on the downlink, can then be calculated, - phase offset, related to the center frequency used for transmission, and the distance traveled. by the signal, the phase shift observed at the reception of a signal emitted from E and received at R being the remainder of the Euclidean division of | R - Ε \ / λ, with λ the wavelength of the signal .
    For each of the satellites, the transmitter is able to calculate at least one or all of the offsets mentioned above, and to apply the inverse (or opposite) offset to the signal transmitted through this satellite.
    The inverse offset of a time offset is to advance the time of emission of the signal of a duration equivalent to that calculated for the satellite. According to an alternative embodiment, it is possible to calculate a reference offset, for example an average offset, between the signals transmitted via the different satellites, and then to calculate, for each of these satellites, a relative offset with respect to this offset. reference, and shift the transmitted signal from the inverse of this relative offset.
    The inverse offset of a frequency offset consists of shifting the transmitted signal by a frequency of a value opposite to that calculated for the satellite.
    The inverse offset of a power offset is to increase the power of the transmitted signal by a power level equal to the measured power attenuation for the satellite.
    An alternative to the power shift indicated above is to set a target power level, and to amplify or attenuate the power of the signal transmitted through each of the satellites so that all signals are received with the level of power. predefined power.
    The inverse offset of a phase shift is to apply a phase shift on the reverse transmitted signal to the calculated phase shift.
    An alternative to the phase shift indicated above is to define a target phase upon reception of the transmitted signal through each of the satellites, and to modify the initial phase of the transmitted signals so that all the signals are received with a substantially identical phase. The precise estimation of the phase shift, particularly when the signals are transmitted over high carrier frequencies and over long distances, as is the case for satellite links, is very sensitive, a poor estimate can be a source of error.
    Thus, the transmitter 110 is able to calculate at least one, or all the offsets mentioned above, for each of the satellites 131, 132 and 133, and to calculate for each of these satellites, a pre-compensated signal.
    This pre-compensation of the signals on transmission makes it possible to eliminate the interferences between them when they are received by the receiver. Indeed, a time difference between two signals received from different satellites can create inter-symbol interference which significantly degrades the link budget. A difference in phase between two received signals can be constructive if the phase shift is close to a multiple of π, the power of the equivalent signal received being then the sum of the powers of each of the received signals, but also destructive if it is close of N ^, N being an odd integer, the power of the received equivalent signal then being the difference between the powers of the received signals. Frequency shifting is manifested as changes in the phase shift between the signals, the recombinations between the oscillating signals then between constructive and destructive recombination, the rate of oscillation being related to the frequency difference. Finally, a power shift between received signals, if it is less restrictive than the other shifts mentioned, must be estimated and taken into account during the recombination under pain of adding uncorrelated noise but of different levels, the level the higher then becoming dominant.
    During transmission, it is therefore desirable to calculate and pre-compensate at least the time, frequency and phase offsets before transmitting the signals to all the satellites.
    The receiver 120 does not necessarily have channel separation means.
    When it does not have one, it receives a single signal, sum of the signals transmitted by each of the satellites. Because of the pre-compensations of the offsets carried out on transmission, the received signals do not exhibit time and frequency phase shifts. They are synchronized, in time, frequency, power and phase according to the estimated and pre-compensated offsets. They recombine optimally and constructively, the signals transmitted by the different satellites summing constructively without generating interference, allowing then to provide the signal a gain based on the number of satellites used for transmission.
    In the case where it has signal separation means, the reception is simplified in that, the received signals being synchronized to the position of the receiver, it is not necessary to implement synchronization processing on reception for to recombine the signals, a simple summation being sufficient. The invention is compatible with the use by the transmitting station of several satellite gateways located in remote geographical areas, provided that they are synchronized, and that they can exchange data by terrestrial means ( eg internet, fiber optic link, ...). This embodiment makes it possible to increase the number of satellites in common visibility of the transmitting station and of the receiving station, and therefore the transmission gain.
    In an alternative embodiment, whose representation is equivalent to that of FIG. 1, the signal is transmitted by a transmitting station using a direct sequence spread spectrum transmission technique. Direct sequence spread spectrum involves modulating the signal to be transmitted by a known higher frequency spreading sequence. The chosen sequence is similar to a code which, if it is known to the receiver, allows it to distinguish transmissions transmitted in the same frequency band.
    The receiver knows its position, the position of the transmitter, as well as the positions of all satellites in common visibility of the transmitter and the receiver. If necessary, it can also know its speed vector, the speed vector of each of the satellites, and / or the speed vector of the transmitter.
    In this embodiment, the transmitter 110 uses a different spreading sequence when transmitting the signal to each of the satellites used, but does not perform estimation and pre-compensation shifts.
    The receiver 120, which does not have multiple antennas or adaptive antenna, nevertheless separates the signals received from each of the satellites, from the sequence used during the transmission of these signals.
    Once the signals are separated, the receiver is able, knowing the positions (and velocity vectors) of all the actors of the transmission, to calculate for each of the signals the temporal, frequency, phase and / or power offsets to which it has been subjected during its propagation, and to compensate them in reverse.
    It is then possible to sum all these signals, which recombine constructively without generating interference, and exploit the resulting signal.
    If this embodiment is more expensive in terms of bandwidth, due to the use of a spread spectrum modulation, it makes it possible to gain in transmission power, the spread spectrum making it possible to implement links with noise levels much lower. However, it can not be applied to the return channel if the receiver does not have means of separating the signals it sends to the different satellites.
    In the case where the transmitter moves at a high speed, it can pre-compensate the Doppler shift generated by this displacement.
    According to another embodiment, the transmitter has means for separating the signals transmitted to the different satellites in charge of transmitting the signal between the transmitter and the receiver, but does not necessarily know the position of the receiver. It then applies a frequency shift to the transmitted signal, this shift being known and differ depending on the satellite in charge of the signal relay.
    The receiver, which does not have multiple antennas or adaptive antenna, nevertheless differentiates the signals received from each of the satellites, from their carrier frequency. The transmitter and the receiver both have means for separating the signals received from the different satellites. For the transmitter, these means are material (use of directional antennas), while for the transmitter, these means are either software (signal processing algorithms for separating the signals transmitted according to their carrier frequency), or hardware ( plurality of parallel radio channels positioned at different carrier frequencies), and to differentiate the received signals as a function of their carrier frequency.
    In this embodiment, the receiver has one or more radio channels whose total bandwidth is large enough to allow it to receive all the signals transmitted by each of the satellites on a different carrier frequency. It must also be able to reduce baseband and filter the signals transmitted on each of the carrier frequencies, thus separating the different signals received.
    Once the signals are separated, the receiver can, knowing the positions (and speeds) of all the actors of the transmission, calculate for each of the signals time, frequency, phase and / or power offsets, and compensate for them. reverse.
    It is then all these signals, which recombine constructively without generating interference.
    If this embodiment is more expensive in bandwidth and increases the complexity of the radio channel or the processing of the receiver, it makes it possible to implement the separation of the signals at the receiver without requiring the use of multiple antennas or active antennas on it.
    Finally, another embodiment, intended to allow operation to a receiver whose position, speed and direction of movement, are not known or known only in a rough way. This embodiment consists in producing, during the transmission, a repetition of the signal, by applying to each repetition offsets calculated from different displacement hypotheses.
    Thus, in the case for example of a plane moving at a high speed, several hypotheses of different directions of displacement are envisaged. An example consists of taking traveling direction hypotheses varying from 30 ° each and / or speed assumptions varying from 100km / h, and / or all the associated combinatorics. Each of these hypotheses leads to a different temporal, frequency, phase and / or amplitude offset calculation depending on the satellite used to transmit the signal. The signal is therefore transmitted several times to all the satellites, each repetition being made from signals compensated for the inverse of offsets calculated from different assumptions. At the reception, the repetitions of the signal will be summed up constructively or destructively, with or without interference, depending on the assumptions made. The receiver can then demodulate and process the signal corresponding to the most relevant hypothesis.
    This operating mode makes it possible to gain on the quality of the signal received when the hypothesis taken is close to the actual displacement of the receiver, and this at the expense of a decrease in the flow rate. This decrease is directly related to the number of hypotheses tested, and therefore to the precision sought on the offsets applied.
    FIG. 2 shows a satellite network 200 in which the invention is implemented according to a second embodiment. This embodiment differs from the first in that the transmitter has no means of signal separation, unlike the receiver.
    In this embodiment, the satellite network 200 comprises a transmitter 210, transmitting a message to a receiver 220. The transmission is performed by means of three satellites 231, 232 and 233.
    The receiver comprises means for separating the signals transmitted to each of the satellites. In FIG. 2, these means are embodied in the form of three directional antennas 221, 222 and 223, each of the antennas being pointed towards a different satellite. Other implementations are possible, such as the use of an active antenna whose beams are directed to each of the satellites.
    The receiver 220 knows its own position (and velocity vector), as well as the position (and the velocity vector) of the satellites 131, 132 and 133. This latter information is transmitted to it by the ephemeris, according to a method well known to man of career. The receiver also knows the position (and velocity vector) of the transmitter 210.
    The transmitting station transmits the signal undifferentially to all the satellites. These return the signal to the receiver, which uses its separation means to receive them in a differentiated manner. From the positions of all the actors of the transmission, and possibly the speed vectors of the satellites, the receiver is then able to calculate, for each of the satellites, offsets relating to the propagation of the signal, and to compensate these offsets. As for the example presented in FIG. 1, these offsets can be time, frequency, phase and / or power offsets.
    When the receiver moves, it knows its position, direction and speed, and can also compensate for the Doppler effect generated by its displacement. It can also compensate for the Doppler effect generated by the displacement of the transmitter when the velocity vector thereof is known.
    The signals that have been compensated for the calculated offsets are then summed and exploited normally by the receiver.
    The signal reconstruction logic at the receiver will most often rely on coherent and inconsistent correlation techniques.
    In a preferred embodiment, the receiving station compensates for shifts in time, frequency, and power. After compensation for these offsets, the signal is received identically on each channel, except for its phase. Indeed, the phase offsets are easy to correct at the receiver, as long as the sources there are differentiated, and more complicated to correct at the system level because they require a very good control of the geometry, typically a few percent of the wavelength (either in the frequency range traditionally used for satellite transmissions, a few centimeters), or a calibration process leading to the same performance.
    In the case of this embodiment where the phase is not compensated from the geometry of the network, it can be corrected from the correlation properties between the signals. Thus, to return two received signals to different channels in phase, it is possible to perform the complex multiplication between the first signal and the conjugate of the second signal. The result of the correlation over any time domain is a complex number whose phase represents the phase difference between the two signals over that interval. By proceeding with windows of correlations of size consistent with the possible residual error in time and frequency, it is possible to estimate the relative phase periodically, without having to know the content of the signals. Once these relative phases are known, they are compensated and the sum signal is coherent and constructed for demodulation. This operation is only possible because the signals are synchronized in time and frequency.
    The same correlation process can also be used to identify the presence of the signal, and to refine the estimates of time, frequency and power, in its so-called "incoherent" approach, ie where only the module of the Complex correlation is evaluated. This module is maximum when the signals are correctly aligned in time and in frequency, its amplitude being the product of the powers of the two satellites. Put simply, the result of the correlation contains on its argument the phase difference, and on its module the general alignment information of the signals off phase shifts. Several hypotheses of time / frequency offsets can then be tested, to keep only the one with the maximum correlation amplitude, without worrying about the phase difference in this first step. Once the maximum is found, the phase differences will be given by the correlation arguments.
    These correlation methods are very much at the basis of contemporary communication and satellite navigation technologies, such as GPS (Global Positioning Satellite), and in this sense are widely used. in mobile terminals. In particular, there are ASIC chips (acronym for Application Specific Integrated Circuit, or integrated circuits with specific application) very low consumption and very low cost adapted to these treatments (the capacities reach thousands of correlators). An industrial implementation in a miniaturized receiver could therefore on the one hand rely on this heritage to define and develop an efficient solution and at a lower cost, and on the other hand be integrated in a single chip that would take care of the correlations necessary to the localization, correlations necessary for the recombination of signals, and even correlations necessary for the demodulation of the communication signals in the case of spread spectrum signals.
    According to another embodiment, the transmitter and the receiver both have means for separating the signals transmitted by each of the satellites. In this embodiment, the transmitter knows its position and the position of all the satellites used for the transmission of the signal. It can thus pre-compensate the signal of the shifts related to the propagation on the upstream link. The receiver also knows its position, and the position of all the satellites used for the transmission of the signal. It then performs the postcompensation of the signals received from the shifts related to the propagation on the downlink.
    FIG. 3 shows a satellite network 300 in which each of the satellites 301, 302 and 303 has means for separating the signals, and in which the invention is implemented according to a third embodiment.
    In this embodiment, the satellites used to relay the signal between the transmitter 310 and the receiver 320 know their position, as well as the position of the transmitter and the position of the receiver. When it comes to non-geostationary satellites, they also know their speed vector. They also have means of separation between the uplink and the downstream path. In Figure 3, these means consist of an active antenna having several beams, the transmitter and the receiver being in different beams. Other solutions are possible, such as the use of orthogonal polarizations. It is also possible to use omnidirectional antennas at the level of the satellites (omnidirectional means that it covers the earth with a uniform gain, the antenna not emitting preferably in the directions other than towards the earth), the means of separation between the upstream channel and the downstream channel being the signal transmission instants.
    In this embodiment, each of the satellites is able - from its knowledge of the positions of the transmitter, the receiver, and its own position (and if appropriate its velocity vector, as well as those of the transmitter and / or the receiver) - to compensate the signals received from the transmitter from the shifts due to the propagation between the transmitter and it, and to pre-compensate the same signal before its retransmission of the future offsets related to the propagation between him and the receiver.
    The signals received by the receiver from each of the satellites 301, 302 and 303 are then synchronized, and recombine constructively.
    This reception mode makes it possible to lighten the antenna constraint on the transmitter or the receiver, which can then be content with omnidirectional antennas. However, this reduction in stress results in an increase in the stress on the satellite: multi-beam antenna, the need for knowledge of the position of the transmitter and the receiver, and realization of offsets calculations to be applied. The invention also comprises a method of transmitting a signal by a transmitting station, the transmission of this signal being carried out by means of a plurality of satellites in parallel, the signal transmitted to each of these satellites being -compensated so that it reaches the receiver from all the satellites synchronously. The transmitter has knowledge of its position, the position of the receiver, as well as the position (and velocity vector) of each of the satellites used for the transmission of the signal. It also has means allowing it to be able to transmit the signal independently to each of the satellites used.
    FIG. 4 presents a diagram of the steps performed by the communication method according to the invention when it is executed by the transmitter.
    This method comprises a first step 401 for selecting, from among all the satellites in common visibility of the transmitter and the receiver, at least two satellites used for the transmission of the signal. This step makes it possible to limit this number to the needs required for the transmission, and to adapt the number of satellites to the capabilities of the signal separation means of the transmitter. In the case where all satellites are used for transmission, this step is similar to the selection of all satellites, and is transparent.
    The method also comprises a second calculation step 402, for each of the satellites selected in the first step to carry out the transmission, of at least one offset. This involves calculating at least one offset from a time offset, a frequency offset, a phase shift and a power offset. These offsets are related to the position (and displacement) of the satellite, as well as to the respective positions of the transmitter and receiver (and their displacements).
    The method further comprises a third step 403 for calculating a pre-compensated signal to be transmitted by the transmitter to the satellite, the pre-compensation being the application of inverse offsets to the offsets calculated in the second step.
    Finally, the method comprises a fourth step 404 for transmitting, by the transmitting station, all the signals calculated during the third step. Each of the pre-compensated signals is transmitted to the corresponding satellite, which repeats it to the receiver. Thus, all the signals arrive at the receiver in a synchronized manner, and sum up constructively.
    The first step can be performed only periodically, the period of completion of this step varying as a function of the time required for satellites in visibility of the receiver and the transmitter to vary so as to influence the results of the first step of satellite selection.
    Likewise, the emission of several precompensated signals can be performed by taking as input the same calculation of offsets, the period of implementation of the step of calculating the offsets varying as a function of the time required for the displacement of the satellite, the The transmitter and receiver vary to influence the results of the offset calculations performed in the second step. The invention furthermore comprises a method of receiving a signal in a reception station, the transmission of this signal being carried out by means of a plurality of satellites in parallel, the signals received from each of these satellites being post- compensated for shifts during propagation so that they can be combined constructively.
    The receiver has knowledge of its position, the position of the transmitter, and the position (and velocity vector) of each of the satellites used for the transmission of the signal. It also has means allowing it to be able to receive the signal differentially from each of the satellites used.
    FIG. 5 presents a diagram of the steps performed by the communication method according to the invention when it is executed by the receiver.
    This method comprises a first step 501 for selecting, from among all the satellites in common visibility of the transmitter and the receiver, at least two satellites used for the transmission of the signal. This step makes it possible to limit this number to the needs required for the transmission, and to adapt the number of satellites to the capabilities of the signal separation means of the receiver. In the case where all satellites are used for transmission, this step is similar to the selection of all satellites, and is transparent.
    In the case where all satellites are used for transmission, this step is similar to the selection of all satellites, and is transparent.
    The method then comprises a second calculation step 502, for each of the satellites selected in the first step to carry out the transmission, of at least one offset. This involves calculating at least one offset from a time offset, a frequency offset, a phase shift and a power offset. These offsets are related to the position (and velocity vector) of the satellite, and the positions of the transmitter and the receiver.
    It further comprises a third step 503 for receiving the signal, differentially from each of the satellites selected in the first step.
    The method also comprises a fourth step 504 for calculating, for each of the selected satellites, a post-compensated signal using the offsets calculated during the third step. Inverse offsets at these offsets are then applied to the signal received in the third step for each of the satellites selected for transmission.
    Finally, the method comprises a fifth step 505 of summing the various post-compensated signals during the fourth step. The signals are then synchronized, they are summed constructively, without generating interference.
    In a manner similar to the transmission method, the steps for selecting the satellites used and for calculating the offsets can be carried out at a slower rate than that of receiving the messages. The invention also comprises a method of repetition by a satellite of a signal, the transmission of this signal being carried out by means of a plurality of satellites in parallel, of which the satellite on which the method is made, the signals received from each of these satellites being compensated in order to arrive synchronized to the receiver.
    The satellite has knowledge of its position (and of its velocity vector when it is a non-geostationary satellite), as well as the position and potentially the velocity vector of the transmitter and / or the receiver. It also has means allowing it to receive the signal in a differentiated manner between the transmitter or the receiver. These means may be for example a multi-beam antenna, or simply a time multiplexing of the transmitted signals, distinct time slots being assigned to each of the stations of the network.
    Figure 6 shows a diagram of the steps performed by the communication method according to the invention when executed by a satellite.
    This method comprises a first step 601 for receiving, by the satellite, the signal emitted by the transmitting station.
    It then comprises a second calculation step 602, from the position (and speed) of the satellite, as well as from the position (and if available of the speed and direction) of the transmitter, of at least one offset linked to the propagation of the signal between the transmitter and itself. This involves calculating at least one offset from a time offset, a frequency offset, a phase shift and a power offset.
    It comprises a third step 603, similar to step 602 but which this time concerns propagation between the satellite and the receiver.
    The method also comprises a fourth step 604 for calculating a compensated signal, from the received signal, to which inverse offsets are applied to the offsets calculated during the second and third steps.
    Finally, the method comprises a fifth signal transmission step 605 thus compensated to the receiving station.
    Thus, the signal is received by the receiving station synchronously with the signals transmitted through the other satellites in common visibility of the two stations, the signals then recombine constructively.
    As with the other methods presented, the offset calculation steps can be performed at a lower rate than the repetition of the messages.
    The methods shown in FIG. 4, FIG. 5 and FIG. 6 are intended to be executed respectively by a transmitter, a receiver and a satellite. They may be implemented, for example, in a reprogrammable calculation machine, such as a processor, a DSP (Digital Signal Processor), or a microcontroller. They can also be implemented in a dedicated computing machine, such as a set of logic gates such as an FPGA (Field-Programmable Gate Array or programmable gate network) or an ASIC, or in the form of any other hardware module for performing calculations.
    The methods described can be adapted to implement the alternative embodiments described above, such as for example the use of a direct sequence spread spectrum modulation, the addition of a frequency shift dependent on the satellite operating the relay of the signal, the repetition of the signal with different hypotheses of displacement, etc.
    In the examples presented in FIGS. 1, 2 and 3, the prerequisite is that the position of the receiver is known to the transmitter, or that the position of the transmitter is known to the receiver, or that the two positions are known to the receiver. each of the satellites. However, this position may be known only in an approximate manner, because it varies over time, or it is not precisely localized.
    The offsets calculated in order to pre-compensate or post-compensate the signals can thus be tainted by errors, the recombination of the signals being then no longer optimal. In particular, the phase recombination of the different signals is very sensitive to this type of error.
    In order to more precisely estimate the offsets applied to the signals, it is proposed to supplement the methods presented above by a specific signaling protocol of the positions, carried out prior to the transmission of the signal itself. This protocol can be realized in different ways. One of them is to use a spread spectrum type waveform, allowing better robustness to collisions and a very good synchronization in time and frequency, to transmit through each of the satellites successively taken a weak message flow rate between the transmitter and the receiver, the receiver responding to the message with a dedicated low rate message, including information on time, frequency, phase and power offsets observed on reception. The message can be retransmitted periodically to limit drift. Advantageously, the bit rate (and thus the necessary link budget) of this message will be set so that it can be transmitted by a single satellite.
    In another embodiment, the message is transmitted from the transmitter to the receiver by each of the satellites used for transmission simultaneously. It has a means for the receiver to differentiate the source of the messages, such as the transmission on a particular frequency, or the use of a direct sequence spread spectrum modulation, with a sequence specific to the satellite used. The receiver responds by means of a dedicated message including information on time, frequency, phase and / or arrival power offsets of each of the received signals. Here too, advantageously, the rates of the messages are fixed so that they are transmitted only by a single satellite to go and return.
    Another method, applicable in particular when the receiver is in charge of the compensation of the signals received on each of the satellites, consists in transmitting a dedicated signal, typically a pure carrier type signal, in parallel with the useful signal, in order to facilitate the estimation of the relative phases. When the signal compensation is performed on transmission, a low rate message may be transmitted by the receiver to the transmitter containing information on the arrival phase of the calibration carrier. Advantageously, the rate of these messages is set so that they are transmitted only by a single satellite to go and return.
    These calibration techniques make it possible to improve the signal compensation when the control of the positions and displacements of the different actors of the transmission is not perfect.
    The satellite network according to the invention is an alternative to satellite networks based on the formation of beams known from the state of the art. It has the following advantages: • It improves the link budget in a way directly proportional to the number of satellites used for transmission. For example, the use of 10 satellites provides a gain of about 10 dB in the link budget; • By improving the link budget, it makes it possible to reduce the transmission power of each of the satellites; • It does not require prerequisites on the number of satellites used: the invention operates from a satellite without particular gain, an additional gain being provided by each of the additional satellites used as relay of the transmission; • It is compatible with LEO, MEO and GEO (Geostationnary Earth Orbit) deployments: the high Doppler constraints of deployment on LEO satellite networks are removed because these offsets are compensated directly at the transmitter or receiver according to the knowledge of the speed of the satellites, and potentially that of the transmitter and / or the receiver; • It does not require the implementation of complex antennal systems at the satellite level, an omni-directional antenna (or more precisely directed towards the earth, that it covers in a single beam of uniform gain) or limited to a few spots allowing implement the invention, thereby reducing the payload on the satellite; • The simplification of the antenna system on board the satellite makes it compatible with a deployment on a network of MEO satellites; The invention is robust to jamming, masking and failures, due to the diversity provided by the use of several satellites. By way of example, a gain of 10 dB could be obtained by the invention when it is deployed on a network of 35 MEO satellites. The same gain could be obtained when the invention is deployed on a network of 500 LEO satellites. The invention requires the use of signal separation and parallel processing means thereof. The use of active digital beamforming antennas, allowing the detection and simple formation of beams, on satellite gateways or satellite receivers, is well known to those skilled in the art. For this purpose, the invention is particularly adapted to the case of deployment of a network according to a star network topology (in English STAR network), in which all the transmissions are done through a central equipment of the network. network, hub type, switch or router. This equipment is also generally used as a gateway to external networks. The invention adapts very simply to such a network topology, because it requires, to be implemented according to one of the embodiments, to provide the central equipment means for separating transmissions to and from destination of each of the satellites. These separation means are generally present at the level of the central equipment, the advantage of the star topology being to provide this equipment with highly directive antennas in order to improve end-to-end link budgets in order to be able to use diagrams. spectrally efficient modulation and coding, and exchange high-speed data.
    Access management between the different users within the satellite network according to the invention is then done according to methods known to those skilled in the art, such as time division multiplexing (TDMA), the Frequency Division Multiple Access (FDMA), code multiplexing (or CDMA), or contention access. The invention can also be used in addition to a beam deployment, thus making it possible to increase the size of the satellite spots, thus reducing the stresses related to the antenna on board the satellite.
    权利要求:
    Claims (17)
    [1" id="c-fr-0001]
    A satellite communications network (100, 200, 300) comprising at least one transmitting station, at least one receiving station, and a plurality of satellites, the network being characterized in that a signal transmission between the transmitting station and the receiving station are made by a plurality of satellites in common visibility of these two stations, and in that at least one of the transmitting station (110), the receiving station (210) and said satellites (301, 302, 303) comprise signal separation means (111, 112, 113) transmitted to or from the satellites (131, 132, 133) used for transmission, and configured to calculate for each of the signals at least one offset provided by the propagation of the signal, from the position of the transmitting station, the position of the receiving station, and the position of the satellite through which it is transmitted, then to apply to the signal at the least one dec inverse of the one or more calculated offsets.
    [2" id="c-fr-0002]
    A satellite communications network, wherein the calculation of the offsetting (s) is further performed from at least one of a transmission station velocity vector, a reception station velocity vector, and a vector speed of the satellite through which the signal is transmitted.
    [3" id="c-fr-0003]
    3. The satellite communications network according to one of the preceding claims, wherein the calculation of the offset or shifts comprises at least one of the calculation of a time shift, of a frequency shift, of a phase shift and of a power shift.
    [4" id="c-fr-0004]
    4. Satellite communications network according to one of the preceding claims, wherein the signal separation means comprise an active antenna for separating the signals transmitted by each of the satellites used for transmission.
    [5" id="c-fr-0005]
    5. The satellite communications network according to one of claims 1 to 3, wherein the signal separation means comprises a plurality of directional antennas (111, 112, 113) for separating the signals transmitted by each of the satellites used. for transmission.
    [6" id="c-fr-0006]
    The satellite communications network according to one of claims 1 to 3, wherein the transmitted signal is modulated according to a direct sequence spectrum spreading technique, the transmitting station (110) having separation means ( 111, 112, 113) of the signals sent to the satellites (121, 122, 123) used for transmission, each of the signals being modulated with a separate sequence, the receiving station (120) being configured to separate the signals received from each satellites used for transmission from the sequence used on transmission.
    [7" id="c-fr-0007]
    7. A satellite communications network according to one of claims 1 to 3, wherein a carrier frequency of the signal transmitted by the transmitting station is adapted according to the satellite used for transmission, the transmitting station (110). having means for separating (111, 112, 113) signals sent to the satellites (121, 122, 123) used for transmission, the receiving station being configured to separate the signals received from each of the satellites used for transmission to from their carrier frequency.
    [8" id="c-fr-0008]
    8. A satellite communications network according to one of the preceding claims, wherein the transmitting station (110) has means (111, 112, 113) for separating the signals sent to the satellites (121, 122, 123). used for transmission, the transmitted signal being repeated, the inverse offsets applied to the signals for each of the repetitions being calculated from assumptions different from a direction of movement of the receiver.
    [9" id="c-fr-0009]
    9. The satellite communications network as claimed in one of the preceding claims, wherein the transmitting station is configured to transmit a signal dedicated to a calibration of the inverse offsets applied to the signals.
    [10" id="c-fr-0010]
    10. The satellite communications network according to one of the preceding claims, wherein the transmitting station and the receiving station are further configured to exchange a synchronization message by each of the selected satellites successively before transmitting the signal.
    [11" id="c-fr-0011]
    11. The satellite communications network according to one of the preceding claims, wherein the transmitting station and the receiving station are further configured to exchange a synchronization message by each of the selected satellites simultaneously before transmitting the signal.
    [12" id="c-fr-0012]
    12. A method of transmitting a signal from a transmitting station to a receiving station in a satellite communications network, said network comprising at least two satellites in common visibility of the transmitting station and the broadcasting station. reception, said transmitting station knowing its position and those of the receiving station and the satellites in common visibility, and having means for separating signals transmitted to satellites in common visibility, the method being characterized in that it comprises the steps of: • selecting (401), among the satellites in common visibility, a plurality of satellites used for the transmission of the signal, • calculating (402), for each of the selected satellites, at least one offset related to the propagation of the signal from the position of the transmitting station, the position of the receiving station, and the position of said satellite, ass (403), for each of the selected satellites, a signal pre-compensated by applying at least one inverse offset of the calculated offset (s), and • transmit (404), to each of the selected satellites, the pre-compensated signal associated therewith.
    [13" id="c-fr-0013]
    13. A method of receiving a signal transmitted between a transmitting station and a receiving station in a satellite communications network, said network comprising at least two satellites in common visibility of the transmitting station and the broadcasting station. reception, said receiving station knowing its position and those of the transmitting station and satellites in common visibility, and having means for separating the signals received from the satellites of the network, the signal being transmitted through a plurality of satellites among the satellites in common visibility, the method being characterized in that it comprises the steps of: • selecting (501), among the satellites in common visibility, a plurality of satellites used for receiving the signal, calculation (502), for each of the selected satellites, of at least one offset related to the propagation of the signal from the position of the transmitting station, the position of the receiving station, and the position of said satellite, • receiving (503) the signal from each of the selected satellites, • computing (504), for each of the selected satellites, a signal compensated by applying to the signal received at least one inverse offset of the calculated offset (s), and summing (505) all of the compensated signals.
    [14" id="c-fr-0014]
    14. A method of repeating a signal in a satellite during the transmission of a signal between a transmitting station and a receiving station in a satellite communications network, said satellite being one of a plurality of satellites of the network in common visibility of the transmitting station and the receiving station, said satellite knowing its position, the position of the transmitting station, and the position of the receiving station, and having means for separating signals received from the transmitter and the receiver, the method being characterized in that the signal is transmitted by a plurality of satellites, and in that it comprises the steps of: receiving (601) the signal transmitted from the transmitting station, calculating (602) at least a first offset related to the propagation of the signal between the transmitter and the satellite from the position of the satellite, and the position of the transmitter, alcul (603) at least one second offset related to the propagation of the signal between the satellite and the receiver from the position of the satellite and the position of the receiver, • calculating (604) a compensated signal, by applying the signal received from the inverse offsets at the first and second calculated offsets, and • transmitting (605) the compensated signal to the receiving station.
    [15" id="c-fr-0015]
    Transmission station configured to implement a method of transmitting a signal according to claim 12.
    [16" id="c-fr-0016]
    16. Receiving station configured to implement a method of receiving a signal according to claim 13.
    [17" id="c-fr-0017]
    Satellite configured to implement a signal repetition method according to claim 14.
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    同族专利:
    公开号 | 公开日
    FR3046313B1|2019-05-31|
    US10045318B2|2018-08-07|
    EP3185032A1|2017-06-28|
    US20170188322A1|2017-06-29|
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    法律状态:
    2016-11-28| PLFP| Fee payment|Year of fee payment: 2 |
    2017-06-30| PLSC| Search report ready|Effective date: 20170630 |
    2017-11-27| PLFP| Fee payment|Year of fee payment: 3 |
    2019-11-28| PLFP| Fee payment|Year of fee payment: 5 |
    2021-09-10| ST| Notification of lapse|Effective date: 20210806 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1502676|2015-12-23|
    FR1502676A|FR3046313B1|2015-12-23|2015-12-23|SOLID SPATIAL DISTRIBUTION SOLUTION FOR CONSTELLATION TELECOM|FR1502676A| FR3046313B1|2015-12-23|2015-12-23|SOLID SPATIAL DISTRIBUTION SOLUTION FOR CONSTELLATION TELECOM|
    EP16204101.6A| EP3185032B1|2015-12-23|2016-12-14|Compensation of the transmission path in a communication network using a plurality of satellites.|
    US15/379,335| US10045318B2|2015-12-23|2016-12-14|Solution with massive spatial distributing for telecom constellation|
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