• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to a method (50) for transmitting, by a terminal (10), a message to a reception station (20) of a wireless communication system, said message to be broadcast on a shared channel on which the sending of messages is performed at the beginning of predetermined time intervals, called "slots", characterized in that said transmission method (50) comprises: - an encoding (51) of data to include in the message to be sent, - a distribution (52) of the encoded data between Nb sub-messages of the message to be sent, Nb being an integer greater than or equal to two, - a selection (53) of a slot for the transmission of said message, - a selection (54) of Nb transmission frequencies, respectively associated with the Nb sub-messages of the message, - a transmission (55) of the message at the beginning of the selected slot, successively transmitting the sub-messages on their frequencies related emission issues.
    公开号:FR3056867A1
    申请号:FR1659363
    申请日:2016-09-29
    公开日:2018-03-30
    发明作者:Benjamin Gadat;Vincent Deslandes
    申请人:Airbus Defence and Space SAS;
    IPC主号:
    专利说明:

    TECHNICAL AREA
    The present invention belongs to the field of wireless communication systems, and more particularly relates to an access protocol, by a terminal, to a channel shared with other terminals to communicate with a reception station.
    STATE OF THE ART
    The present invention finds a particularly advantageous application, although in no way limiting, in the case of a satellite communication system in Earth orbit.
    In satellite communication systems, there are many known protocols for accessing a shared channel.
    In particular, in the ALOHA protocol, access is random, and each terminal randomly selects the time of issue of a message. With such an approach, collisions between messages sent by different terminals can occur, and the ALOHA protocol also aims to introduce mechanisms making it possible to resolve collisions.
    The ALOHA protocol has given rise to numerous evolutions, and in particular the evolution known as “Slotted ALOHA”, in which the instant of emission, always selected randomly by each terminal, can however only take a certain number of discrete values, which correspond to the instants of the beginning of predetermined time intervals, called "slots". Compared to the ALOHA protocol, the Slotted ALOHA protocol improves the usability of the shared channel.
    An evolution of the Slotted ALOHA protocol, known under the name of CRDSA ("Contention Resolution Diversity Slotted ALOHA"), is for example implemented in the DVB-RCS2 standard. In the CRDSA protocol, the same message is replicated several times, and each replica of this same message is sent at the start of a randomly selected slot, all the replicas being sent inside a window containing a number N s predetermined slots (N s being greater than the number of replicas).
    Nowadays, it is envisaged to collect messages sent by terrestrial or aerial connected objects from satellites in earth orbit.
    Since many objects of everyday life are intended to become connected objects, many connected objects will be likely to try to access the shared channel substantially at the same time. It is therefore understandable that, even by randomly selecting the time of issue of a message, many collisions are likely to occur.
    To resolve these collisions, it is for example possible to implement, at the reception station, well-known techniques for suppressing interference. In particular, the successive interference suppression technique ("Successive Interference Cancellation" or SIC in Anglo-Saxon literature) makes it possible to resolve certain collisions, that is to say, to decode messages even in the presence of collisions.
    However, in the case of a collection of messages sent by connected objects, the number of collisions, in the case of existing access protocols, is potentially so large that many messages are likely to be lost, even when applying interference suppression techniques.
    STATEMENT OF THE INVENTION
    The aim of the present invention is to remedy all or part of the limitations of the solutions of the prior art, in particular those set out above, by proposing an access protocol to a shared channel which makes it possible to reduce the duration of collision between two messages given.
    To this end, and according to a first aspect, the present invention relates to a method of transmitting, by a terminal, a message intended for a reception station of a wireless communication system, said message having to be transmitted. on a channel shared with other terminals on which the transmission of messages to said receiving station is carried out at the start of predetermined time intervals, called "slots". Said issuing process includes:
    - encoding of data to be included in the message to be sent by means of a channel coder,
    a distribution of the encoded data between Nb sub-messages of the message to be sent, Nb being an integer greater than or equal to two,
    - a selection of a slot for the transmission of said message,
    - a selection of Nb transmission frequencies, associated respectively with the Nb sub-messages of the message,
    - a transmission of the message at the start of the selected slot, by successively transmitting the sub-messages on their respective associated transmission frequencies.
    Thus, the data to be sent in a message are encoded by means of a channel coder, and the encoded data are distributed in Nb different sub-messages constituting the message to be sent. The submessages forming said message are then transmitted successively on different respective transmission frequencies.
    In other words, in the access protocol thus defined, the transmission of a message can only take place at predetermined times, corresponding to the start of slots, and said transmission also includes jumps in transmission frequency. intra-message.
    On the one hand, because the transmission frequency varies from one sub-message to another of the same message, the probability of having, between two messages sent by two different terminals, collisions on several sub-messages is greatly reduced.
    On the other hand, the fact that the encoded data are distributed in different sub-messages makes it possible to exploit the frequency diversity introduced by the hopping frequency of intra-message transmission, which makes it possible to improve the decoding of the message in presence of partial collisions concerning only certain sub-messages.
    In particular modes of implementation, the transmission method may also include one or more of the following characteristics, taken in isolation or in any technically possible combination.
    In particular modes of implementation, each sub-message transmission frequency is selected randomly by said terminal within a predetermined frequency band.
    In particular modes of implementation, the transmission method includes an insertion, only in the sub-message to be transmitted first on the channel, of a predetermined detection pattern.
    In particular embodiments, the transmission method comprises a fragmentation of a predetermined detection pattern into Nb fragments of the detection pattern, each fragment of the detection pattern being included in one of the sub-messages of the message to emit.
    In particular modes of implementation, the detection pattern is a Gold sequence.
    In particular modes of implementation, the message is entirely emitted inside the selected slot.
    In particular modes of implementation, each submessage is an ultra-narrowband signal.
    According to a second aspect, the present invention relates to a terminal for transmitting a message intended for a reception station of a wireless communication system, said message having to be transmitted on a channel shared with other terminals. on which the transmission of messages to said receiving station is carried out at the start of predetermined time intervals, called "slots". Said terminal comprises:
    - means configured to encode data to be included in the message to be sent,
    means configured to distribute the encoded data between Nb sub-messages of the message to be sent, Nb being an integer greater than or equal to two,
    - means configured to select a slot for the transmission of said message,
    - means configured to select Nb transmission frequencies, associated respectively with Nb sub-messages of the message,
    - means configured to transmit the message at the start of the selected slot, by successively transmitting the sub-messages on their respective associated emission frequencies.
    According to a third aspect, the present invention relates to a wireless communication system comprising at least one reception station and a plurality of terminals according to any one of the embodiments of the invention.
    In preferred embodiments, the receiving station is on board a satellite in Earth orbit.
    PRESENTATION OF THE FIGURES
    The invention will be better understood on reading the following description, given by way of nonlimiting example, and made with reference to the figures which represent:
    - Figure 1: a schematic representation of an exemplary embodiment of a wireless communication system,
    - Figure 2: a diagram representing the main steps of a process for sending a message on a shared channel,
    - Figure 3: an illustration of the progress of the different stages of a particular example of implementation of the transmission method of Figure 2.
    In these figures, identical references from one figure to another denote identical or analogous elements. For the sake of clarity, the elements shown are not to scale, unless otherwise stated.
    DETAILED DESCRIPTION OF EMBODIMENTS
    FIG. 1 schematically represents an exemplary embodiment of a wireless communication system comprising a plurality of terminals 10 and a reception station 20.
    In the following description, and as illustrated by FIG. 1, we place ourselves in a nonlimiting manner in the case where the reception station 20 is on board a satellite 30 in earth orbit, and where the terminals 10 are located substantially on the surface of the Earth. By “substantially on the surface of the Earth”, it is meant that each terminal 10 is on the ground (terrestrial or maritime), or else aloft in the terrestrial atmosphere (on board an airplane, a drone, a balloon, etc.) . Nothing excludes, however, according to other examples, from having for example a reception station on board a spacecraft or air vehicle (plane, drone, balloon, etc.). The receiving station can also, according to other examples, be on the ground (land or sea).
    The satellite 30 is preferably in low altitude orbit LEO (“Low
    Earth Orbit ”). However, nothing precludes considering other types of orbit, for example a medium altitude orbit MEO ("Medium Earth Orbit"), a geostationary orbit GEO ("Geostationary Orbit"), etc.
    Each terminal 10 is capable of transmitting messages on a channel intended for the reception station 20. The channel between the terminals 10 and the reception station 20 corresponds to a predetermined frequency band, shared by all of the terminals 10. It should be noted that this frequency band, forming the shared channel, can consist of a single continuous range of frequencies or, alternatively, of several continuous ranges of frequencies which are disjoint from each other.
    The transmission of messages on the shared channel, intended for the receiving station 20, is carried out only at the start of predetermined time intervals, called "slots". Such an approach requires, in known manner, to ensure time synchronization between the terminals 10 and the reception station 20. The means capable of being implemented to ensure this time synchronization are considered to be known to those skilled in the art. and are outside the scope of the present invention.
    By "emit at the start of a slot" is meant that the terminal 10 seeks to start its emission at a predetermined instant, a slot being defined as the time interval delimited by two possible instants of consecutive emission. On the other hand, it is not necessary that the emission of a message starts exactly at the beginning of a slot. This depends in particular on the accuracy of the time synchronization between the terminals 10 and the reception station 20, whether or not the propagation time between a terminal 10 and the reception station 20 on board the satellite 30 is taken into account (to ensure that the message sent is received at a predetermined time), etc.
    Aside from the constraint on sending messages only at the start of predetermined slots, the terminals 10 preferably determine unilaterally when to send messages. In other words, the receiving station 20 does not know a priori whether it is likely to receive a message from a given terminal 10, said receiving station only knows that, if it is to receive a message from this terminal 10 or on the other, this can only happen at predetermined times.
    FIG. 2 represents the main steps of a method 50 for transmitting, by a terminal 10, a message on the shared channel intended for the reception station 20. As illustrated by FIG. 2, the method 50 Issuance mainly involves steps of:
    - 51 data encoding to be included in the message to be sent using a channel coder,
    52 distribution of the encoded data between Nb sub-messages of the message to be sent, Nb being an integer greater than or equal to two,
    - 53 selection of a slot for the transmission of said message,
    - 54 selection of Nb transmission frequencies, associated respectively with Nb sub-messages of the message,
    - 55 transmission of the message at the start of the selected slot, by successively transmitting the sub-messages on their respective associated transmission frequencies.
    Thus, the data to be sent in a message are encoded by means of a channel coder, having a coding rate R (R <1), and the encoded data are distributed in Nb different sub-messages constituting the message to be sent. The sub-messages forming said message are then transmitted successively on different respective transmission frequencies, making jumps in intra-message transmission frequency.
    Indeed, this breakdown of the message into Nb sub-messages is carried out by the physical layer protocol used for the exchange of data between the terminal 10 and the reception station 20, so that the transmission frequency varies within d 'the same message, regardless of whether said transmission frequency also varies from one message to another. It should also be noted that all the steps shown in FIG. 2 are steps executed within the framework of said physical layer protocol.
    Preferably, the channel coder and the distribution of the data encoded in the different sub-messages are such that it is always possible to decode the data from any (Nb-1) sub-messages among the Nb sub-messages, in the absence of noise and / or interference. In order not to have too low an R coding rate, the channel coder and the distribution of the encoded data in the different submessages are such that it is not possible to decode the data from a single sub-message. even in the absence of noise and interference.
    In the following description, we place ourselves in a nonlimiting manner in the case where Nb is equal to three (Nb = 3). The channel coder and the distribution of the data encoded in the different sub-messages are such that it is always possible to decode the data from any two of the three (Nb = 3) sub-messages, and such that it is not possible to decode the data from a single sub-message.
    The various steps illustrated in FIG. 2 are preferably all executed by the terminal 10.
    For example, the terminal 20 has for this purpose a processing circuit (not shown in the figures), comprising one or more processors and storage means (magnetic hard disk, electronic memory, optical disk, etc.) in which is stored a computer program product, in the form of a set of program code instructions to be executed to implement all or part of the steps of the method 50 for sending messages. Alternatively or in addition, the processing circuit comprises one or more programmable logic circuits (FPGA, PLD, etc.), and / or one or more specialized integrated circuits (ASIC), and / or a set of discrete electronic components, etc. , adapted to implement all or part of said steps of the method 50 for sending messages.
    The terminal 20 also includes wireless communication means, implemented during the transmitting step 55, allowing the said terminal 10 to transmit the messages in the form of radio signals. The wireless communication means are conventionally in the form of a radio circuit comprising equipment (antenna, amplifier, local oscillator, mixer, analog filter, etc.) considered to be known to those skilled in the art.
    In other words, the processing circuit and the radio circuit of the terminal 10 form a set of means configured in software (specific computer program product) and / or hardware (FPGA, PLD, ASIC, discrete electronic components, etc. .) to implement all the steps of the method 50 for sending messages. These means include a channel coder, a data distributor, a slot selector, a transmission frequency selector and a transmitter of sub-messages.
    In step 51, the data to be included in the message is encoded using a channel coder. The channel coder is part of the processing of the physical layer protocol used for communications between the terminal 10 and the receiving station 20, and the data to be encoded corresponds to a service data unit ("Service Data Unit" or SDU). in Anglo-Saxon literature) received from the protocol layer located above the physical layer.
    In general, any type of channel coder known to a person skilled in the art can be implemented during the encoding step 51, and the choice of a particular channel coder constitutes only one variant implementation of the invention. In preferred embodiments, the channel coder corresponds to a turbo code. Nothing excludes, however, according to other examples, from considering other types of channel coders, and / or from considering a combination of different channel coders. In particular, it is possible, according to a variant of the invention, to consider a channel coder implementing a repetitive code.
    During step 52, the encoded data are distributed between Nb sub-messages. It should be noted that this distribution step 52 can consist of a simple fragmentation of the encoded data or, in preferred modes of implementation, can also comprise, in particular, an interleaving of the encoded data before fragmentation. Preferably, each sub-message includes the same amount of encoded data. In such a case, if the number of encoded data obtained at the end of the encoding step 51 is equal to Nc, then the number of encoded data included in each sub-message is equal to Nc / Nb. Nothing excludes, however, according to other examples, from distributing the encoded data so that the sub-messages do not all contain the same amount of said encoded data and do not necessarily all have the same duration when sent. Preferably, the respective durations of the sub-messages are known a priori from or determinable by the reception station 20 or by an equipment in charge of the extraction.
    In the case where the encoded data has been obtained by means of a channel coder implementing a repetitive code, preferably with an encoding rate R equal to 1 / Nb consisting in replicating Nb times the data received before being put in work of the code repeatedly, said encoded data are preferably distributed so that each sub-message includes a replica of said received data. In such a case, the transmitted sub-messages are at least partly identical, and it is possible, at the reception station 20, to detect the sub-messages transmitted by the same terminal 10 by comparing said sub-messages with one another.
    In step 53, the terminal 10 selects a slot for sending the message. The slot to be used, from among the possible slots, is for example randomly selected by said terminal 10. In general, any method for selecting a slot can be implemented, and the choice of a particular method corresponds only to to a variant implementation of the invention.
    During step 54, the terminal 10 selects Nb transmission frequencies, associated respectively with the Nb sub-messages constituting the message to be transmitted on the shared channel.
    Preferably, the Nb emission frequencies are all different. Nothing excludes, however, according to other examples of implementation, from having certain equal emission frequencies, since the Nb emission frequencies are not all identical.
    In preferred embodiments, the transmission frequencies are selected, at each terminal 10, at random. In such a case, it is understood that the Nb selected transmission frequencies are not known a priori of the receiving station 20. By thus selecting the Nb transmission frequencies, for two distinct terminals 10 having selected the same frequency transmission for a sub-message, the probability of reselecting the same transmission frequency for the next sub-message is low. However, nothing excludes, according to other examples, from using for a given terminal 10 a hopping sequence of predetermined transmission frequency, preferably known a priori from or determinable by the receiving station 20 or by an equipment in in charge of extracting the data included in the messages received by said reception station 20, said sequence of transmission frequency hops being further different from the sequences of transmission frequency hops of other terminals 10.
    In the case where the transmission frequencies are selected randomly, and are therefore not known a priori from the reception station 20 or by an equipment in charge of the extraction, it is possible, to facilitate the extraction of the data, to include in each sub-message control information making it possible to determine the frequency of transmission of the next sub-message (and / or of the previous sub-message, and / or of all the other sub-messages, etc. ).
    Then, during step 55, the message is transmitted at the start of the selected slot, by successively transmitting the sub-messages on their respective associated transmission frequencies.
    FIG. 3 schematically represents the progress of the different steps of the transmission method 50, from data D to be included in a message.
    As shown in Figure 3, the D data is encoded to obtain DE encoded data. As is well known, a channel coder adds redundancy to the data, and the number Ne of encoded data is greater than the number of data D to be included in the message.
    The data encoded DE is then distributed in Nb submessages. In the nonlimiting example illustrated in FIG. 3, Nb is equal to three (Nb = 3) and the sub-messages are designated by SM1, SM2 and SM3 respectively. Furthermore, in the example illustrated in FIG. 3, the distribution consists mainly of a fragmentation of the data encoded DE into Nb fragments, designated by DE1, DE2 and DE3 respectively.
    In general, control information, making it easier to detect and / or extract data from the message, can also be included in at least one of the sub-messages. In the example illustrated in FIG. 3, the control information comprises a detection pattern MD, making it possible to facilitate the detection of the message sent. The MD detection pattern is preferably the same for all the terminals 10, but nothing excludes considering different detection patterns associated with different terminals 10. Preferably, the MD detection pattern is a pattern having good correlation properties , such as a Gold sequence. In the example illustrated in FIG. 3, the detection pattern is fragmented into Nb fragments, designated by MD1, MD2 and MD3 respectively:
    - the MD1 fragment of the MD detection pattern is included in the SM1 sub-message with the DE1 fragment of the encoded data,
    - the MD2 fragment of the MD detection pattern is included in the SM2 sub-message with the DE2 fragment of the encoded data,
    - the MD3 fragment of the MD detection pattern is included in the SM3 sub-message with the DE3 fragment of the encoded data.
    However, there is nothing to exclude, according to other examples, from transmitting the detection pattern MD entirely in the same sub-message of the message sent, for example in the sub-message SM1.
    Because the MD detection pattern is fragmented, or included entirely in a single sub-message of the transmitted message, it is understood that the amount of control information included to facilitate detection of the message is not increased compared to a prior art physical layer protocol not including intra-message frequency hopping.
    Nothing excludes, however, according to other examples, from including in each sub-message a predefined detection reason, preferably different from one sub-message to another in order to make it easier to distinguish the different sub-messages from the message sent.
    The message is then transmitted at the start of the selected slot (designated by “slot #i” in FIG. 3), by successively transmitting the sub-messages SM1, SM2 and SM3 on the transmission frequencies selected during the step 54, designated by F1, F2 and F3 respectively in FIG. 3.
    In the example illustrated in FIG. 3, the sub-message SM2 is sent immediately after the sub-message SM1, and the sub-message SM3 is sent immediately after the sub-message SM2. Nothing excludes, however, according to other examples, from introducing a silence interval between two consecutive sub-messages. Preferably, the time difference between the instants of the start of transmission of two consecutive sub-messages are predetermined, known a priori from or determinable by the reception station 20 or by an equipment in charge of the extraction. This time difference is for example constant over time and the same for all consecutive sub-messages. According to another example, each sub-message can include control information making it possible to determine when the next sub-message (and / or the previous sub-message, and / or all the other sub-messages, etc.) is likely to be received, to facilitate detection.
    In the example illustrated in FIG. 3, the message sent is of duration shorter than the duration of a slot, so that the sub-messages SM1, SM2 and SM3 are all sent within the selected slot #i. Thus, the transmission frequency hops are both intra-message and intra-slot. Nothing excludes, however, according to other examples, from having a message of duration longer than that of the selected slot. In such a case, the transmission of the message continues at least on the slot following the selected slot. For example, the message is sent so that each sub-message is sent at the start of a slot. In the example illustrated in FIG. 3, this would amount to sending the sub-message SM1 at the start of the selected slot #i, then the sub-message SM2 at the start of the slot # i + 1, then the sub-message SM3 at the start of slot # i + 2. Preferably, however, the sub-messages are sent so that only the first sub-message is sent at the start of a slot.
    The extraction of the data received in one or more messages is carried out by the reception station 20 and / or by an equipment, such as a ground station, to which the reception station 20 transmits the received messages in any suitable form. Extracting data from a received message can implement any suitable method known to those skilled in the art and outside the scope of the invention.
    As indicated above, it is possible to integrate control information making it easier to detect and / or extract data from a message. In particular, the control information making it possible to determine the transmission frequencies and / or the transmission times of the different sub-messages of the same message makes it easier to identify the sub-messages belonging to the same message. Other types of control information can also be envisaged to identify the sub-messages belonging to the same message, such as for example including in each sub-message a sequence number of the message and / or an identifier of the terminal having sent said message. message. Alternatively or in addition, the sub-messages belonging to the same message can be identified by evaluating the consistency of certain physical parameters of the detected sub-messages. For example, if the time differences between consecutive sub-messages of the same message are known a priori, only sub-messages whose detection times verify these time differences are likely to belong to the same message. In addition, sub-messages belonging to the same message are subjected to substantially the same propagation conditions, so that they are in principle coherent in phase and are received with substantially the same power. By comparing the phases and / or the reception powers of the detected sub-messages, it is therefore also possible to identify the sub-messages which are likely to belong to the same message, even when no control information has been received. been included in the sub messages.
    The above description clearly illustrates that by its various characteristics and their advantages, the present invention achieves the objectives which it had set itself. In particular, because the data to be transmitted in a message encoded and distributed in several sub-messages which are transmitted on different transmission frequencies, the maximum duration of collision between two given messages is greatly reduced compared to the prior art, so that the collision between these two messages is easier to resolve. Consequently, the receiving station 20 can detect a larger number of messages received simultaneously.
    In addition, the fact that the breakdown into sub-messages takes place at the level of the physical layer and not at the level of an upper layer such as the medium access control layer (“Medium Access Control” or MAC in Anglo-Saxon literature), said decomposition can be advantageously carried out by inserting less control information than in the case of a decomposition at the level of an upper layer. Such a decomposition at the level of the physical layer can even, in preferred modes of implementation, be carried out without adding control information compared to a physical layer protocol according to the prior art which does not include frequency hopping. intra-message.
    The present invention finds a particularly advantageous application, although in no way limitative, in the case where each sub message is an ultra-narrow band signal. By “ultra narrow band” (“Ultra Narrow Band” or UNB in Anglo-Saxon literature), it is meant that the instantaneous frequency spectrum of each sub-message is of frequency width less than two kilohertz, or even less than one kilohertz . Indeed, the invention can then be implemented without having to consider a shared channel of too large frequency width, and can be implemented with a shared channel whose frequency width is of the order of a few tens of kilohertz to a few hundred kilohertz.
    权利要求:
    Claims (10)
    [1" id="c-fr-0001]
    1 - Method (50) of transmission, by a terminal (10), of a message intended for a reception station (20) of a wireless communication system, said message having to be transmitted on a shared channel with other terminals on which the transmission of messages to said reception station is carried out at the start of predetermined time intervals, called "slots", characterized in that said transmission method (50) comprises:
    - an encoding (51) of data to be included in the message to be sent by means of a channel coder,
    a distribution (52) of the encoded data between Nb submessages of the message to be sent, Nb being an integer greater than or equal to two,
    - a selection (53) of a slot for the transmission of said message,
    a selection (54) of Nb transmission frequencies, associated respectively with the Nb sub-messages of the message,
    - a transmission (55) of the message at the start of the selected slot, by successively transmitting the sub-messages on their respective associated transmission frequencies.
    [2" id="c-fr-0002]
    2 - Method (50) according to claim 1, wherein each sub-message transmission frequency is selected randomly by said terminal (10) within a predetermined frequency band.
    [3" id="c-fr-0003]
    3 - Method (50) according to one of the preceding claims, comprising an insertion, only in the sub-message to be transmitted first on the channel, of a predetermined detection pattern.
    [4" id="c-fr-0004]
    4 - Method (50) according to one of claims 1 to 2, comprising a fragmentation of a predetermined detection pattern into Nb fragments of the detection pattern, each fragment of the detection pattern being included in one of the sub-messages of the message to be sent.
    [5" id="c-fr-0005]
    5 - Method (50) according to one of claims 3 to 4, wherein the detection pattern is a Gold sequence.
    [6" id="c-fr-0006]
    6 - Method (50) according to one of the preceding claims, wherein the message is entirely transmitted within the selected slot.
    [7" id="c-fr-0007]
    7 - Method (50) according to one of the preceding claims, wherein each sub-message is an ultra-narrow band signal.
    [8" id="c-fr-0008]
    8 - Terminal (10) for the transmission of a message to a reception station (20) of a wireless communication system, said message to be transmitted on a channel shared with other terminals on which the transmission of messages to said receiving station is carried out at the start of predetermined time intervals, called "slots", characterized in that said terminal (10) comprises:
    - means configured to encode data to be included in the message to be sent,
    means configured to distribute the encoded data between Nb sub-messages of the message to be sent, Nb being an integer greater than or equal to two,
    - means configured to select a slot for the transmission of said message,
    - means configured to select Nb transmission frequencies, associated respectively with Nb sub-messages of the message,
    - means configured to transmit the message at the start of the selected slot, by successively transmitting the sub-messages on their respective associated emission frequencies.
    [9" id="c-fr-0009]
    9 - Wireless communication system comprising at least one reception station (20), characterized in that it comprises a plurality of terminals (10) according to claim 8.
    [10" id="c-fr-0010]
    10 - System according to claim 9, wherein the receiving station (20) is on board a satellite (30) in Earth orbit.
    1/2
    Data
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    WO2020157033A1|2020-08-06|Method and system for achieving wireless communication between a sender device and a receiver device by means of a repeater device, without loss of information on a physical property
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    FR2969450A1|2012-06-22|ORIENTATION PROTOCOL PROCESS FOR STATIONARY, PARTIALLY STATIONARY, OR CYCLO-STATIONARY SIGNALS
    FR2941125A1|2010-07-16|Antennas i.e. millimeter radio wave sending and receiving antennas, configuring method for source and receiver nodes of specific Home cinema, involves configuring antenna of receiver node by using antenna receiving configuration
    同族专利:
    公开号 | 公开日
    US11032817B2|2021-06-08|
    EP3488535A1|2019-05-29|
    US20190230658A1|2019-07-25|
    FR3056867B1|2020-01-24|
    WO2018060491A1|2018-04-05|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20110255570A1|2010-04-16|2011-10-20|Hitachi, Ltd.|Adaptive frequency hopping in time-slotted based wireless network|
    CN103220015B|2013-04-18|2015-01-07|电子科技大学|Fast frequency hopping receiver, fast frequency hopping system and fast frequency hopping method based on pilot frequency superposition|
    FR3019957A1|2014-04-09|2015-10-16|Actility|METHODS FOR ENCODING AND DECODING FRAMES IN A TELECOMMUNICATION NETWORK|
    WO2016132081A1|2015-02-19|2016-08-25|Sigfox|Method and system for wireless communication between terminals and half-duplex base stations|
    WO2016139408A1|2015-03-03|2016-09-09|Sigfox|Methods for transmitting data between a terminal and a frequency-synchronised access network on an uplink message from said terminal|
    GB0408383D0|2004-04-15|2004-05-19|Koninkl Philips Electronics Nv|A radio network and a method of operating a radio network|
    KR100876723B1|2006-03-16|2008-12-31|삼성전자주식회사|Method and apparatus for session negotiation in mobile communication system and system thereof|
    KR101423033B1|2008-02-01|2014-07-28|재단법인서울대학교산학협력재단|Apparatus and method for data transmitting in wireless communication system|
    US9641216B2|2009-04-07|2017-05-02|Battelle Energy Alliance, Llc|Monitoring devices and systems for monitoring frequency hopping wireless communications, and related methods|
    US9763253B2|2012-08-14|2017-09-12|University Of South Australia|Channel allocation in a communication system|
    WO2015135780A1|2014-03-11|2015-09-17|Sony Corporation|Communication device for lte communication within unused gsm channels|
    US9693172B2|2014-03-27|2017-06-27|Huawei Technologies Co., Ltd.|System and method for machine-type communications|
    JP2019169749A|2016-08-10|2019-10-03|シャープ株式会社|Transmitter and communication method|FR3080725A1|2018-04-26|2019-11-01|Finsecur|WIRELESS COMMUNICATION METHOD BETWEEN AT LEAST ONE ENERGETICALLY AUTONOMOUS RISK DETECTION TERMINAL AND A COMMUNICATING ORGAN|
    WO2019207261A1|2018-04-26|2019-10-31|Finsecur|Method for wireless communication between at least one energy-autonomous risk detection terminal and a communicating unit|
    US11108898B1|2019-12-05|2021-08-31|Amazon Technologies, Inc.|Packets with header replicas for contention resolution in communications systems|
    CN113472389A|2021-06-30|2021-10-01|中航光电科技股份有限公司|Low-delay configurable wireless rapid frequency hopping system based on FPGA|
    法律状态:
    2017-09-29| PLFP| Fee payment|Year of fee payment: 2 |
    2018-03-30| PLSC| Search report ready|Effective date: 20180330 |
    2018-09-28| PLFP| Fee payment|Year of fee payment: 3 |
    2019-09-30| PLFP| Fee payment|Year of fee payment: 4 |
    2020-09-28| PLFP| Fee payment|Year of fee payment: 5 |
    2021-09-29| PLFP| Fee payment|Year of fee payment: 6 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1659363|2016-09-29|
    FR1659363A|FR3056867B1|2016-09-29|2016-09-29|METHOD FOR TRANSMITTING, BY A TERMINAL OF A SLOT ACCESS COMMUNICATION SYSTEM, A MESSAGE WITH INTRA-MESSAGE FREQUENCY HOPPING|FR1659363A| FR3056867B1|2016-09-29|2016-09-29|METHOD FOR TRANSMITTING, BY A TERMINAL OF A SLOT ACCESS COMMUNICATION SYSTEM, A MESSAGE WITH INTRA-MESSAGE FREQUENCY HOPPING|
    PCT/EP2017/074894| WO2018060491A1|2016-09-29|2017-09-29|Method of transmission, by a terminal of a slot-based-access communication system, of a message with intra-message frequency hops|
    EP17772451.5A| EP3488535A1|2016-09-29|2017-09-29|Method of transmission, by a terminal of a slot-based-access communication system, of a message with intra-message frequency hops|
    US16/336,299| US11032817B2|2016-09-29|2017-09-29|Method of transmission, by a terminal of a slot-based access communication system, of a message with intra-message frequency hops|
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