WO2005043801A2

WO2005043801A2 - Method for transmitting estimation data of at least one propagation channel of a receiver to a transmitter

Info

Publication number: WO2005043801A2
Application number: PCT/FR2004/002805
Authority: WO
Inventors: Frank Bietrix; Nicolas Ibrahim
Original assignee: Wavecom
Priority date: 2003-10-31
Filing date: 2004-10-29
Publication date: 2005-05-12
Also published as: WO2005043801A3; FR2861928B1; FR2861928A1

Abstract

The invention relates to a method for transmitting an estimation of at least one propagation channel of a receiver to a transmitter. According to the invention, said receiver is used to implement the following stages: estimation of said transmission channel; projection of said estimation onto a two-dimensional (time/frequency) function base, delivering a set of projection coefficients; transmission of data representing said set of projection coefficients to the transmitter such that the transmitter can reconstruct a profile of said transmission channel as seen by the receiver.

Description

Method for transmitting an estimate of at least one propagation channel from a receiver to a corresponding transmitter, transmitter and receiver. 1. Field of the invention The field of the invention is that of radiocommunications. More specifically, the invention relates to a technique making it possible to forward, from a receiver to a transmitter, information representative of an estimate of a transmission channel, as well as various uses, in the transmitter, of this information. The invention applies more particularly in the context of a mobile radiotelephony system, between a base station and one or more user terminals. It applies in particular, but not exclusively, in the context of an OFDM downlink (in English "Orthogonal Frequency Division Multiplexing" for "Multiplexing with orthogonal frequency distribution"). 2. Previous solutions There are several configurations in which it is advantageous for the transmitter to know an estimate of the transmission channel produced by a receiver. Indeed, the transmitter can thus adapt the data which it transmits to the receiver according to the characteristics of the channel. At the present time, in multicarrier systems, there is no effective technique allowing the base station to know precisely the state of the channel seen by the terminals. One approach could be that the receiver transmits to the transmitter the complete estimate of the transmission channel which it has produced, in the form for example of the set of channel coefficients in the time / frequency plane. In the case where the channel varies rapidly in time and / or in frequency, it would be necessary for such a transmission to be carried out frequently and regularly. In certain UMTS systems ("Uni versai Mobile Telecommunications Standard", "Universal mobile telecommunications standard"), information concerning the quality of the channel (power reception estimates, estimation signal-to-noise ratio, etc.) are however reassembled towards the base station. According to other techniques, the base station can have access to information concerning the preprocessing to be carried out before the transmission of the data to the receiver. 3. Drawbacks of the Prior Part A drawback of current methods is that only an indication of the quality of the channel is returned to the base station, which is insufficient or restrictive, especially for OFDM type systems. "Orthogonal Frequency Division Multiplexing"). If it were envisaged to transmit, from the receiver to the transmitter, a complete channel estimate, this would be costly in resources, and in particular in bandwidth. Indeed, the set of channel coefficients in the time / frequency plane represents a large amount of information. Such a cost is all the more important as the channel varies, and it is therefore necessary to transmit a new channel estimate at frequent and regular intervals. However, the need for communication resources, and in particular bandwidth, is becoming more and more pressing, and current radiotelephony systems must meet the bandwidth needs of an ever increasing number of users. 4. Objectives of the invention The object of the invention is in particular to overcome these drawbacks of the prior art. More specifically, an objective of the invention is to provide a technique which makes it possible to transmit information relating to the channel estimation from a receiver to a transmitter, while consuming little resources, and in particular bandwidth. Another objective of the invention is to propose such a technique, which is simple and inexpensive to implement. Another object of the invention is to provide such a technique which is particularly well suited to systems implementing OFDM type multicarrier modulation. The invention also aims to propose such a technique which makes it possible to improve the total cellular throughput of a cellular radiocommunications system compared to the techniques of the prior art. More specifically, an objective of the invention is to provide such a technique which makes it possible to simultaneously satisfy the requests for access to the network of a larger number of users. Another object of the invention is to provide such a technique which makes it possible to improve the performance of a radio link within the framework of a system using several transmitting antennas, and in particular which maximizes the signal to noise ratio at reception. for all terminals served. Another objective of the invention is to propose such a technique which advantageously exploits the signal structures provided for by the UMTS standard, in the case of a radiotelephony system operating according to this standard. 5. Essential characteristics of the invention These objectives, as well as others which will appear subsequently, are achieved using a method for transmitting an estimate of at least one propagation channel of a receiver. to a transmitter. According to the invention, said receiver implements the following steps: - estimation of said transmission channel; - projection of said estimate on the basis of functions with at least one frequency or time dimension, delivering a set of projection coefficients; transmission of data representative of said set of projection coefficients to said transmitter, so that said transmitter can reconstruct a profile of said transmission channel as seen by said receiver. Thus, the invention is based on a completely new and inventive approach to the transmission, from a receiver to a transmitter, of an estimation of the transmission channel. spread. Indeed, it is not necessary to carry out a costly transmission in terms of bandwidth of the complete estimate of the channel carried out by the receiver, in the form of all the channel coefficients in the time / frequency plane. On the contrary, after having estimated the channel at the positions of the pilot symbols, according to a technique which will be described in more detail in the remainder of this document, the receiver proceeds to a projection of this estimate on the basis of functions, also known to the transmitter. This base of functions can be, for example, a base of functions with a frequency dimension, with a time dimension, or even a base of functions with two time / frequency dimensions. It then transmits to the transmitter only data representative of the set of corresponding projection coefficients, which is much less costly in time and in bandwidth. The transmitter can, from this data and from the function base which it knows, regenerate the channel profile seen and estimated on the mobile side (or more generally on the receiver side). Preferably, said base of functions is a base of functions with two time / frequency dimensions. According to a first advantageous alternative embodiment, said representative data comprise at least part of said set of projection coefficients. Thus, instead of returning all the channel coefficients in the time / frequency plane, the receiver can be satisfied with sending all or part of the projection coefficients to the transmitter. The transmitter can then reconstruct, from the function base (two-dimensional time / frequency) that it knows, and from the projection coefficients received in whole or in part, an estimate of the channel seen by the receiver. According to a second advantageous alternative embodiment, said representative data comprise at least one index referring to a table of values of possible coefficients, stored by said transmitter and by said receiver. This second variant is even less costly in terms of volume of information to be transmitted. The table of values stored jointly by the transmitter and the receiver then lists a set of projection coefficients associated with a set of predetermined channel profiles, to which the index transmitted by the receiver refers. Advantageously, according to this second variant, such a method comprises a step of comparison between the projection coefficients and sets of coefficients stored in said table, so as to identify the set of coefficients closest to said set of projection coefficients. Thus, after having estimated the channel and carried out the projection, the receiver determines, in the table of values which it stores, the projection coefficients which most closely approximate the projection coefficients which it has actually calculated. It then sends to the transmitter the index which corresponds in the table to these closest coefficients. Preferably, said base of functions is a base of flattened spheroidal functions (DPSS), which constitutes, unlike other bases, the best representation of the signal in its bandwidth. It can also be any other time / frequency two-dimensional function base, such as for example the base of the orthogonal frequencies obtained by FFT (for "Fast Fourier Transfom") or the base of orthogonal polynomials. Advantageously, said receiver is a terminal and said transmitter is a base station, in a radiotelephony system. Preferably, said radiotelephone system implements OFDM modulation. Advantageously, said data representative of said projection are transmitted using the bits of the channel quality indicator (CQI -

"Channel Quality Indicator"), on the HS-DPCCH channel (in English "High Speed- Dedicated Physical Control CHannel", in French "canal de contrôle physique dedicated high speed ") of the HSDPA uplink (in English" High Speed Data Packet Access ", in French" high speed data packet access "). According to the current specifications of the UMTS-HSDPA system, each mobile has 20 bits all the TTI (for "Transmission Time Interval"), namely every 2 ms. In an advantageous embodiment of the invention, the receiver estimates at least two separate transmission channels, corresponding to as many separate transmit antennas of said transmitter. Such an embodiment is part of the Closed Loop Diversity Scheme provided by the UMTS standard to improve the performance of a radio link on a time-varying multipath propagation channel, in the case where several antennas are used for transmission on the side of the base station. Preferably, the signal received by the receiver is a multipore signal teuse, comprising a plurality of carrier frequencies, said transmission channels are estimated for each of said carrier frequencies, or for subsets of said carrier frequencies. Indeed, the channel may have different characteristics depending on the frequencies used, and may in particular have fading at certain frequencies. According to an advantageous application of the invention, said base station implements a step of allocating at least one frequency of communication with a terminal, as a function of said one or more channel estimates, so that the allocated frequencies correspond , on average, to areas in which the corresponding channel estimation has characteristics which conform to at least one predetermined criterion. Thus, the base station takes into account one or more channel estimate (s) when allocating the communication frequencies, both to the terminals already served by the network and to the new terminals asking to access them. It could also be envisaged that the base station would implement such a frequency allocation technique, regardless of how it learned about the channel estimation. In other words, such a frequency allocation technique could be implemented by the base station even if the receiving terminal has not communicated the channel estimation by return channel (for example in the case where the base station has performed the channel estimation by it- even). When a terminal wishes to establish a new communication within the network, the base station is no longer satisfied with determining whether there is at least one free communication frequency: it also takes account of one or more estimates. channel of which it is aware to choose whether or not to accept the request from the incoming terminal, and to determine the frequency band which must be allocated to it. As will be seen in more detail in the remainder of this document, such a technique therefore makes it possible to increase both the total throughput of each cell and the total number of users that the base station can satisfy. In addition, taking into account the channel estimates when allocating communication frequencies makes it possible to improve the overall quality of communications, and avoids untimely communication degradations induced by the random frequency hopping technique (recalled below). after). Advantageously, said allocation step selects, for a given terminal, one or more frequencies available and for which the said channel estimate (s) have a maximum level and / or greater than a predetermined threshold. Such a level can for example be expressed in terms of signal-to-noise ratio, or take account of the fading phenomena affecting the channel. The base station thus selects, from the available frequencies that it has identified, those that will establish the best quality of communication, and will therefore best meet user expectations. Preferably, said allocation step implements a step of frequency hopping, said frequency hopping taking into account said channel estimates so as to allocate frequencies to each communication so as to limit, as far as possible, the effect of channel fading on these communications. Instead of performing a random frequency hopping, the invention proposes to determine beforehand whether the new frequency band that the base station wishes to allocate to the terminal is affected by fading or not. For example, the base station can, from the channel estimate, identify that the new frequency band it intended to allocate to the terminal to improve its performance is in fact more strongly affected by fading, and choose to maintain the original frequency band, or search for another available higher quality frequency band. According to an advantageous characteristic of the invention, said allocation step implements one of the operations belonging to the group comprising: acceptance or refusal of a new communication, a communication being refused if there is not at least one a frequency band, formed of at least one available frequency, for which said one or more channel estimates have a level greater than a predetermined threshold; putting at least one calling terminal on hold; determination of a quality of service for at least one service requested by a terminal; allocation, to a new communication, of a band of at least one frequency, previously allocated to a terminal in communication for which said channel estimation has a level lower than said predetermined threshold. Thus, in the case where the number of requests for access to the network is greater than the resources available, the base station can postpone the transmission to one or more receiving terminals in favor of a new incoming terminal, if the transmission channel for the former is very degraded. This amounts to assigning a priority rank depending, among other parameters, on the quality of the downlink transmission channel, both for users already served by the network and for new entrants. More precisely, the base station can choose to accept a communication request from a new terminal if the corresponding channel estimate is of good quality, in order to be able to interchange the frequency bands allocated to this new terminal on the one hand , and to a terminal whose propagation channel is very degraded on the other hand. After having inverted the frequencies allocated to each of these two terminals, the base station can in fact better satisfy the demand of the mobile terminal in degraded channel. In addition, the total number of users is increased. The base station can also take account of the service to which a terminal wishes to access (voice communication, data transmission, etc.) to determine the level of quality necessary, and therefore the frequency band which it is possible to allocate, based on the associated channel estimate. Preferably, said base station implements at least two transmit antennas, and such a method comprises a weighting step according to which the respective weight associated with each of said antennas for a given communication is a function of the corresponding channel estimates. The operation of the radiocommunication system considered is then said to be in diversity mode, which makes it possible to improve the performance of the radio links, within the framework of propagation channels with multiple paths variable in time. From the channel estimates, the base station knows the state of reception of the signals from the two antennas, and can apply a phase shift, possibly accompanied by a gain, to the two antennas, in order to compensate for the difference between the two. received signals, due to the characteristics of each of the propagation channels associated with the antennas. According to an advantageous variant of the invention, the signal transmitted to said terminal being a multicarrier signal formed by a plurality of frequencies carriers, said weighting step selectively assigns separate complex weights to each of said carrier frequencies, or to subsets of carrier frequencies. Advantageously, said base station implements a step of pre-processing, in particular of pre-equalization, of a signal transmitted to said receiver, according to said one or more channel estimates. The invention also relates to a receiver comprising means for transmitting an estimate of at least one propagation channel to a transmitter, comprising: - means for estimating said transmission channel; - means for projecting said estimate on the basis of two-dimensional time / frequency functions, delivering projection coefficients; - Data transmission means representative of said projection coefficients towards said transmitter, so that said transmitter can reconstruct a profile of said transmission channel as seen by said receiver. Such a receiver is, in an advantageous variant of the invention, a radiotelephone terminal. The invention also relates to a transmitter comprising means for taking into account an estimate of at least one propagation channel transmitted by a receiver in the form of data representative of projection coefficients obtained by projection of an estimate of said transmission channel. transmission on the basis of two-dimensional time / frequency functions. According to the invention, such a transmitter includes means for analyzing and processing said projection coefficients, so as to reconstruct a profile of said transmission channel as seen by said transmitter. In an advantageous variant of the invention, such a transmitter is a base station of a radiotelephony system. 6. List of figures Other characteristics and advantages of the invention will appear more clearly on reading the following description of a preferred embodiment, given by way of simple illustrative and nonlimiting example, and of the appended drawings, among which: - the figure 1 shows a block diagram of the projection principle of the channel estimation on the basis of flattened spheroidal functions, allowing the receiver to determine a set of projection coefficients; FIG. 2 illustrates an application to the diversity of antennas in closed loop mode for the UMTS standard; - Figure 3 describes an adaptation of the technique of Figure 2 to OFDM modulation; FIG. 4 illustrates an application of the invention to "intelligent" planning of the use of frequencies by frequency hopping; FIG. 5 illustrates, in the context of FIG. 4, an example of interchangeability of the frequency sub-bands allocated to two separate mobile terminals. 7. Description of an embodiment of the invention The general principle of the invention is based on the projection of an estimate of the propagation channel on the basis of functions with at least one time or frequency dimension, so that a receiver can send information relating to the channel to a transmitter, in the form of data representative of the coefficients of this projection. This base of functions can be a base of functions with a temporal dimension, with a frequency dimension, or even for example a base of functions with two time / frequency dimensions. In the rest of this document, we will endeavor to describe an embodiment of the invention in which a base of 2D time / frequency functions is implemented. Those skilled in the art will easily extend this teaching to the case of any base of functions, in one or more dimensions. We present, in relation to FIG. 1, an embodiment of such a projection of the channel estimate on a DPSS basis. First of all, it is recalled that the receiver can proceed to the estimation of the propagation channel thanks to the pilot symbols, or reference symbols, the value and the position of which at transmission are known to the receiver, inserted in the data stream. useful received. To find out the value of the transfer function of the propagation channel at a particular position in time / frequency space, the receiver divides the value of the pilot received by its known value on transmission. It can also divide the pilot symbols received by a predetermined coefficient, corresponding to the ratio of the power of the pilots to the power of the useful symbols. To find out the transfer function of the propagation channel over the entire time / frequency plane, it is then necessary to perform an interpolation between the different values of the channel thus calculated at the positions of the pilots. For more information on this channel estimation technique, reference may be made, for example, to French patent document No. 2 820 574, in the name of the same Applicant as the present patent application, which is incorporated here by reference. Several methods can be used to estimate the propagation channel in the entire time / frequency plane of interest. A first method consists in carrying out the interpolation between the pilots by a projection on a certain predetermined basis only in time. Another interpolation method can consist in performing this frequency projection only. Finally, a last method consists in performing a joint interpolation in time and frequency. According to a preferred embodiment of the invention, the base used for the projection consists of discrete flattened spheroidal functions ("Discrete Prolate Spheroidal Sequences" in English) in two time / frequency dimensions, as illustrated by FIG. 1. In this figure, we are attached to the particular case where the signal received and processed by the receiver undergoes a multicarrier modulation of OFDM type. As indicated above, it is of course also possible to use a function base with a time or frequency dimension. Consider the time / frequency OFDM propagation channel 10 seen by a receiver, for example a mobile terminal, of a radiocommunication network. This propagation channel 10 is projected mathematically on the basis of flattened spheroidal functions, of which only the first eight elements 11 to 18 have been shown in time / frequency space. Channel 10 can thus be expressed in the form of a linear combination of the different DPSS 11 to 18, whose coefficients are the projection coefficients C, to C ₈ listed in table 19. Instead of returning the coefficients of the channel in time / frequency plan (which constitutes a fairly high amount of information), the receiver can then be content to send to the transmitter all or part of the projection coefficients or any other information linked to these coefficients C, to C ₈ . This information is used at the base station (transmitter) in order to regenerate the channel profile seen and estimated on the mobile side (receiver). More generally, the set of projection coefficients determined by the receiver can comprise between 5 and 20 coefficients, depending on the severity of the propagation channel considered. The more complex the channel is to describe, the more the number of projection coefficients must be. However, this information to be transmitted requires more bits than the FBI ("FeedBack Information", which is a field reserved for this purpose in the UMTS-HSDPA system). In a preferred embodiment of the invention, therefore, the bits of the CQI ("Channel Quality Indicator") on the HS-DPCCH channel of the HSDPA uplink are used for this transmission. According to the current specifications, each mobile has 20 bits every TTI ("Transmission Time Interval", with a duration of 2 ms). In a possible implementation of the invention, these bits can index a table of predefined values, stored on either side (ie on the transmitter side and on the receiver side) which includes the projection coefficients of different channel realizations (or any other values related to them). In this case, the receiver identifies the set of coefficients in this table which best approximates the coefficients C, to C ₈ actually found by the projection, and sends the index of this set to the CQI. The CQI field comprising 20 bits, the coefficient table stored on the transmitter and receiver sides can contain up to 2 ²⁰ fields, corresponding to 2 ²⁰ sets of pre-recorded projection coefficients. The receiver then compares the -C ₈ projection coefficients to all or part of the 2 ²⁰ sets of coefficients table for identifying the set having the largest resemblance with the game C _t -C ₈ actually computed coefficients. It then sends the 20-bit coded index referring in the table to the set of coefficients identified. Knowledge of the information related to the propagation channel on the OFDM downlink makes it possible to improve the performances concerning the total cellular throughput. According to the invention, two main applications are envisaged: the first application concerns the diversity of antennas with feedback (in "closed loop"mode); the second application concerns a multiple access management strategy. These two cases target uses where the terminal speed is limited, which makes it possible to assume a slow variation of the channel over time, compared to the TTI. We first of all set out to describe an application of the invention to diversity in closed loop mode, in relation to FIGS. 2 and 3. According to the UMTS standard, diversity is a means of improving the performance of a radio link on a time-varying multipath propagation channel ("Delay Spread-Doppler Channel"). One of the techniques is based on the use of several antennas 21, 22 for transmission, on the side of base station 20: this number is limited to two for the current UMTS specifications. A single antenna 23 is provided for reception on the side of the mobile 24.

Two antenna diversity modes are used in UMTS: - the first mode is called "diversity in open loop mode" (in English "Open Loop Diversity Scheme"). According to this first mode, which is not the subject of the present invention, there is no feedback from the receiver (mobile) to the transmitter (the base station). This first mode covers in particular the following techniques: spatio-temporal diversity (STTD: Space Time Transmit Diversity), time distribution diversity (TSTD: Time Switched Transmit Diversity) and orthogonal transmission diversity (OTD: Orthogonal Transmit Diversity) ; the second mode is called "diversity in closed loop mode" (in English "Closed Loop Diversity Scheme"), and provides feedback from the receiver to the transmitter. This information 25 relates to the state of reception of the signals coming from the two antennas 21, 22. The base station can then take account of the information 25 transmitted by the mobile 24 to generate 26 weights W ,, W ₂ applicable to each of the two transmit antennas 21, 22. These weightings Wj, W ₂ can consist in applying a simple phase shift between the two antennas 21, 22 (mode 1), or in jointly applying a phase shift and a gain (mode 2). Figure 2 illustrates this principle for the UMTS standard. The coefficients W; represent the coefficients related to the propagation channel. The calculation of these coefficients W, and W ₂ to be applied can be done in the mobile 24, in order to maximize a certain quantity linked to the two propagation channels (associated respectively with each of the two antennas 21, 22), or, in a mode of preferred embodiment of the invention, in the base station, from the projection coefficients communicated by the mobile 24. It should be noted that the coefficients W, and W ₂ to be applied will take concrete values according to the information contained in FBI bits. The multiplication by the weights of the two antennas 21, 22 serves to make the sum of the two signals, transmitted by the two antennas 21, 22 and received at mobile level 24 by the antenna 23, as consistent as possible. The values of W, and W ₂ are calculated from the projection coefficients of the propagation channel estimated on the pilot symbols on the chosen base. These projection coefficients which are used for the calculation of Wj and W ₂ are stored in a table, indexed by the values of the FBI bits. The present invention is particularly applicable in the context of the application of the “diversity in closed loop mode” mode to multicarrier modulations, and in particular to OFDM modulations. In fact, since UMTS ("Universal Mobile Telecommunications Standard") is a single carrier transmission system, the coefficients of the propagation channel can be considered constant over the entire frequency band. In a multicarrier system such as OFDM for example, the profile of the propagation channel changes with frequency, which makes the multiplication of each transmitting antenna obsolete by a single coefficient Wj. The correction must therefore be made individually for each subcarrier. The implementation of this technique, illustrated in Figure 3, can be done in frequency before 1TFFT 30 ("Inverse Fast Fourier Transform", "Transforming Fourier Rapide Inverse") by multiplying each subcarrier d, to d _N by a complex coefficient W /, where the index j represents the index of the transmitting antenna 21, 22, and where i is the index of the subcarrier considered. These coefficients W being intended to compensate for the difference, induced by the propagation channels, between the two signals received on the receiving antenna 23 of the mobile 24, it can be envisaged that only the coefficients W ² associated with the antenna 22 are complex . The other coefficients W ¹ ; associated with the transmit antenna 21 may be real, or even be of identity. The base station 20 having reconstructed an estimate of the channels corresponding to each antenna 21, 22, it has all the freedom to apply the algorithm of his choice for the calculation of the coefficients ¹ ; and W ² ;. The pilot symbols being treated on transmission as the free symbols, the information returned by the terminal 24 concerns either the propagation channel, or the coefficients previously applied, or a combination of the propagation channel and the coefficients W, and W ₂ previously applied. The base station 20 then knows how to find the information of the channel. The base station can thus distribute the powers between several subcarriers relating to each antenna in a manner inversely proportional to the corresponding transmission channel, which it knows thanks to the data transmitted by the associated receiver. By way of example, if H _kl is the channel seen by the subcarrier k transmitted by the antenna 1, the power P _kl allocated to the antenna 1 for the subcarrier k can then be Pm / | H _kl | ² , Pm being the average power. The symbol emitted on the subcarrier k will then for example be multiplied by the quantity H ^* _k , / | H _k , | ² . Note, in Figure 3, the possible presence of blocks 31 _1; 31 ₂ associated with each of the two antennas 21, 22, intended to add a guard interval in the stream of symbols transmitted, and this, in a conventional manner, in order to reduce the interference between symbols. In addition to closed-loop diversity, the invention can also be applied to the management of multiple access in a cellular radiotelephony network, as described in more detail below in relation to FIGS. 4 and 5. This multiple access management technique can be implemented during normal transmission (without antenna diversity); it aims to increase the total throughput of the cell, by controlling the transmission of packets according to the following strategy: during the initialization of the OFDM link, the receivers (or UEs) transmit the information concerning their respective transmission channels to the station base; the base station then makes a comparison between the different propagation channels for which it has information in comes from the receiver and tries to find the best placements in the time / frequency plane of the packets (which are in the form of two-dimensional time / frequency blocks), so that the signal to noise ratio is maximized at reception for the all the UEs served. This technique can be called "Closed Loop Frequency Hopping", and is illustrated in FIG. 4. FIGS. 4A and 4C relate to the frequency sub-band 41 allocated to a first mobile terminal UE1. FIGS. 4B and 4D relate to the frequency sub-band 42 allocated to a second mobile terminal UE2. FIGS. 4A and 4B illustrate these two frequency sub-bands 41 _A , 42 _B , and in particular any fading which affects them, at a first instant t = 0. FIGS. 4C and 4D illustrate these two frequency sub-bands 41 _c , 42 _D after temporal evolution, at an instant t = 100 ms. As shown in FIG. 4A, the sub-band 41 _A assigned to the first receiver UE1 is of poor quality at t = 0. On the other hand, the sub-band 42 _B allocated to the receiver UE2 at the same time is of satisfactory quality, so that it is easy to satisfy, with good quality, the requests of the user of

EU2. To predict the evolution, and therefore the possible degradation, of the frequency sub-band 41 _A allocated to UEl, it is possible to envisage performing a frequency hopping, so as to allocate a new frequency sub-band to the receiver UEl . According to the techniques of the prior art, this was done by performing a random jump of frequency 40. However, as illustrated in FIG. 4C, such a random jump can lead to assigning to the receiver UE1 a frequency sub-band 43 affected by a fading similar to that of the sub-band 41 _c of the UEl, before frequency hopping. According to the invention, thanks to the knowledge of the channel estimation carried out by the mobile terminals, the base station can carry out intelligent frequency planning, so as to allocate to the receiver UE1 a new frequency sub-band 44 which does not either not affected by fainting (or at all case less than the band 41 _c which the receiver UE1 would have had without frequency hopping). The choice of the new allocated frequency sub-band depends for example on the instantaneous power on a frequency, or on the average power of a frequency sub-band. As regards the receiver UE2, it is not necessary to carry out such an "intelligent" frequency hopping, the frequency sub-band 42 _D being of quality substantially similar to that of the frequency sub-band 42 _B. In the event that the number of requests for access to the OFDM link is greater than the resources, the base station can postpone the transmission to one (or more) UE (s) in favor of a new incoming UE if the first channel is very degraded. In this case, the total number of UEs served by the base station increases on average, as does the total throughput of the cell. Indeed, this strategy limits the misuse of HARQ (in English "Hybrid Automatic Repeat Request"). This amounts to assigning a priority rank depending, among other parameters, on the quality of the downlink transmission channel, the allocation of this priority concerning users already served, as well as new entrants. Figure 5 illustrates in more detail the principle set out above. FIGS. 5A and 5C show the propagation channel associated with a receiver UE1 at two distinct times t = 0 and t = 100. The base station can note that the frequency sub-band 51 allocated to the UEl at t = 0 is of poor quality, and fear a degradation of this quality in the following instants. The base station can then choose to accept to serve a new receiver UE2, the frequency sub-band of t = 0 of which is of satisfactory quality, in order to carry out an exchange of frequency sub-bands, at time t = 100, between the two receivers UE1 and UE2. Thus, at t = 100, the receiver UE1 is allocated the frequency sub-band 53, close to 200 kHz, previously allocated to the receiver UE2. Conversely, the receiver UE2 is allocated the frequency sub-band 54, close to 100 kHz, previously allocated to the receiver UE1. Such an exchange of frequency sub-bands makes it possible, on average, to maintain a satisfactory transmission quality for each of the two receivers UE1 and UE2 at t = 100. Without such an exchange, the frequency sub-band 51 allocated to the receiver UE1 would have undergone a deep fading at t = 100. Such a frequency jump is determined by comparison by the base station of the criteria for selecting the frequencies mentioned above, such as the instantaneous power on a frequency or the average power of a frequency sub-band.

Claims

1. Method for transmitting an estimate of at least one propagation channel from a receiver to a transmitter, characterized in that said receiver implements the following steps: - estimation of said transmission channel; - projection of said estimate on the basis of functions with at least one frequency or time dimension, delivering a set of projection coefficients; transmission of data representative of said set of projection coefficients to said transmitter, so that said transmitter can reconstruct a profile of said transmission channel as seen by said receiver.

2. Method for transmitting an estimate of a propagation channel according to claim 1, characterized in that said base of functions is a base of functions with two time / frequency dimensions.

3. Method for transmitting an estimate of a propagation channel according to any one of claims 1 and 2, characterized in that said representative data comprise at least part of said set of projection coefficients.

4. Method for transmitting an estimate of a propagation channel according to any one of claims 1 and 2, characterized in that said representative data comprise at least one index referring to a table of values of possible coefficients, stored by said transmitter and by said receiver.

5. Method for transmitting an estimate of a propagation channel according to claim 4, characterized in that it comprises a step of comparison between the projection coefficients and sets of coefficients stored in said table, so as to identify the closest set of coefficients to said set of projection coefficients.

6. Method for transmitting an estimate of a propagation channel according to any one of claims 1 to 5, characterized in that said base of functions is a base of flattened spheroidal functions (DPSS).

7. Method for transmitting an estimate of a propagation channel according to any one of claims 1 to 6, characterized in that said receiver is a terminal and said transmitter is a base station, in a radiotelephony system.

8. Method for transmitting an estimate of a propagation channel according to claim 7, characterized in that said radiotelephony system implements OFDM modulation.

9. Method for transmitting an estimate of a propagation channel according to claim 8, characterized in that said data representative of said projection are transmitted using the bits of the channel quality indicator (CQI - " Channel Quality Indicator "), on the HS-DPCCH channel of the HSDPA uplink.

10. A method of transmitting an estimate of a propagation channel according to any one of claims 1 to 9, characterized in that said receiver estimates at least two separate transmission channels, corresponding to as many transmit antennas separate from said transmitter.

11. A method of transmitting an estimate of a propagation channel according to any one of claims 9 and 10, characterized in that, the signal received by the receiver being a multicarrier signal, comprising a plurality of carrier frequencies, said transmission channels are estimated for each of said carrier frequencies, or for subsets of said carrier frequencies.

12. Method for transmitting an estimate of a propagation channel according to any one of claims 7 to 11, characterized in that said base station implements a step of allocating at least one communication frequency with a terminal, as a function of said one or more channel estimations, so that the allocated frequencies correspond, on average, to areas in which the corresponding channel estimation has characteristics which comply with at least one criterion predetermined.

13. Method for transmitting an estimate of a propagation channel according to claim 12, characterized in that said allocation step selects, for a given terminal, one or more frequencies available and for which the said channel estimate (s) have a maximum level and / or higher than a predetermined threshold.

14. Method for transmitting an estimate of a propagationselqcq channel 12 and 13, characterized in that said allocation step implements a frequency hopping step, said frequency hopping taking into account said channel estimates allocate frequencies to each communication in order to limit, as much as possible, the effect of channel fading on these communications.

15. Method for transmitting an estimate of a propagation channel according to any one of claims 12 to 14, characterized in that said allocation step implements one of the operations belonging to the group comprising: acceptance or refusal of a new communication, a communication being refused if there is not at least one frequency band, formed of at least one frequency, available for which the said channel estimate (s) present (s) a level higher than a predetermined threshold; putting at least one calling terminal on hold; determination of a quality of service for at least one service requested by a terminal; - allocation, to a new communication, of a band of at least one frequency, previously allocated to a terminal in communication for which said channel estimation has a level lower than said predetermined threshold.

16. Method for transmitting an estimate of a propagation channel according to any one of claims 12 to 15, characterized in that said station base implements at least two transmit antennas, and in that it comprises a weighting step according to which the respective weight associated with each of said antennas for a given communication is a function of the corresponding channel estimates.

17. Method for transmitting an estimate of a propagation channel according to claim 16, characterized in that, the signal transmitted to said terminal being a multicarrier signal formed by a plurality of carrier frequencies, said step of weighting selectively affects separate complex weights at each of said carrier frequencies, or at subsets of carrier frequencies.

18. A method of transmitting an estimate of a propagation channel according to any one of claims 7 to 17, characterized in that said base station implements a pre-processing step, in particular of pre-equalization, of a signal transmitted to said receiver, according to said one or more channel estimates.

19. Receiver comprising means for transmitting an estimate of at least one propagation channel to a transmitter, characterized in that it comprises: - means for estimating said transmission channel; - means for projecting said estimate on the basis of two-dimensional time / frequency functions, delivering projection coefficients; - Data transmission means representative of said projection coefficients towards said transmitter, so that said transmitter can reconstruct a profile of said transmission channel as seen by said receiver.

20. Receiver according to claim 19, characterized in that it is a radiotelephony terminal.

21. Transmitter comprising means for taking into account an estimate of at least one propagation channel transmitted by a receiver in the form of data representative of projection coefficients obtained by projection of a estimation of said transmission channel on the basis of two-dimensional time / frequency functions, characterized in that it comprises means of analysis and processing of said projection coefficients, so as to reconstruct a profile of said transmission channel such that it is seen by said transmitter.

22. Transmitter according to claim 21, characterized in that it is a base station of a radiotelephony system.