FR2932933A1 - Data packets transmitting method for e.g. wired or wireless communication network, involves varying size of redundancy sequence of transmitted symbol based on information representative of reception quality of transmitted symbol - Google Patents

Abstract

The method involves initializing a size value of a redundancy sequence of a symbol of data packets to be transmitted, and transmitting the data packets and the size value of the redundancy sequence. A notification coming from a receiver node comprising information representative of reception quality of the transmitted symbol is received, and the size of the redundancy sequence of the transmitted symbol is varied based on the information. Independent claims are also included for the following: (1) a device for transmitting data packets by a transmitter node in a communication network (2) a method for receiving data packets by a transmitter node in a communication network (3) a device for receiving data packets by a transmitter node in a communication network (4) a telecommunications system comprising a set of terminal devices connected through a telecommunications network (5) an information storage unit comprising a set of instructions for implementing a method for transmitting data packets by a transmitter node in a communication network (6) a computer program product comprising a set of instructions for implementing a method for transmitting data packets by a transmitter node in a communication network.

Description

The present invention relates to a method and a data transmission device and to a method and an associated receiving device. The invention applies in the context of a communication network consisting of at least one transmitting node and at least one receiving node, where the modulation technique used to enable the transmission of the data comprises the insertion of periods issuing redundant data or null data between the payloads. Such periods are added in order to combat inter-symbol interference, which results in particular from the time delay ("delay spread") of the signals coming from the multiple propagation paths arriving at a given receiving node of the network. Depending on the modulation technique used, the intervals between the useful data transmissions may be guard time, in which no data is transmitted, or sequences called cyclic prefixes. Prefix '), which will be referred to in the rest of the text as CP, or else sequences called cyclic suffixes (in English "Cyclic Suffix"). Thus, for example, the transmission of a data packet through a radio channel according to the OFDM (Orthogonal Frequency Division Multiplexing) modulation technique requires the addition of a CP to the beginning of each symbol of the packet. This sequence does not carry new data; it duplicates already existing data. Typically, the last bits of a symbol are listed at the beginning of the symbol to constitute the CP. Thus, the addition of this sequence results in a decrease in the useful rate, because the same data are transmitted at different times of the transmission. The smaller the size of the CP, the higher the payload data rate, but the more the risk of interference, and hence the probability of error per symbol, increases. This can quickly lead to the loss of the packet because the number of errors per symbol is multiplied by the number of symbols per packet, and therefore the total number of errors per packet may be greater than the coding correction capacity implemented. in the communication system. In conventional OFDM systems, the length of the CP is calculated to cope with inter-symbol interference having the longest possible duration in a given spatial configuration. A common design rule is to dimension the length of the CP at twice the RMS value (Root Mean Squared) of the time spread corresponding to the envisioned spatial configuration.

If the configuration actually implemented produces a time spread greater than that chosen for CP sizing, inter-symbol interference will appear and the rate of transmission errors will increase, which will cause either a decrease in the transmission rate. (by repetition of incorrectly transmitted frames), or loss of data (if incorrectly transmitted frames are not repeated and the number of errors exceeds the coding correction capability). Conversely, if the configuration actually implemented produces a time spread lower than that chosen for the design of the CP, the system will work but will not be optimal in terms of transmission rate, because the redundancy introduced by the CP will be greater than that which is necessary. Z. ZHANG and L. LAI, in an article entitled "A nove / OFDM transmission scheme with length adaptive Cyclic Prefi", published in "Journal of Zhejiang University Science", 2004 5 (11), pages 1336 to 1342, propose to make vary the length of the CP based on an estimate of the duration of the spectral spread. In particular, this article describes the calculations to be made to obtain an estimate of the duration of the spectral spreading, these calculations being based on the value of the pilot data inserted in the useful data. This method has several drawbacks: in particular, it requires additional calculations, it only applies to receivers employing a coherent demodulation scheme and it is only applicable in point-to-point transmission systems.

US-A-7,227,890 discloses a method of optimizing CP length. The estimation of the optimal length of the CP is based on an operation of calculating the correlation between samples of the CP and samples belonging to the data.

This method has the disadvantage of requiring additional calculations. In addition, the choice of CP length is based on an estimate of the optimal length and not on the actual error rate related to the chosen CP value. Moreover, this method can only be used in point-to-point communication systems.

The two prior art methods mentioned above have the common disadvantage of determining the length of the CP from an estimate of the time spread, instead of determining it on the basis of the efficiency of the CP to combat interference. inter-symbols and thus to guarantee the bit error rate or BER (in English "Bit Error Rate") of the communication. The present invention aims to overcome the disadvantages of the prior art. In general, the purpose of the invention is to optimize the size of the CP to have the largest possible payload data rate while avoiding packet loss. In particular, in the case of a mesh-type communication network, the purpose of the invention is to choose a minimum CP size that makes it possible to have the highest possible data rate. while making it possible to guarantee a predetermined number of redundant packets for each receiving node of the network. For this purpose, the present invention provides a method of transmitting data packets by a transmitting node in a communication network, each packet having a plurality of symbols, each symbol being preceded or followed by a redundancy sequence, this method being remarkable in that it comprises steps according to which: the value of the size of the redundancy sequence of at least one symbol of a packet to be transmitted is initialized; the packet is sent and the value of the size of the redundancy sequence; receiving from at least one receiving node a notification including information representative of the reception quality of the transmitted symbol (s); and the size of the redundancy sequence of the transmitted symbol (s) is varied according to the aforementioned information. Thus, the invention makes it possible to choose the redundancy sequence, for example the cyclic prefix (CP), optimally. The invention also makes it possible to optimize the length of the CP dynamically without disturbing the communications. This method of variation of the CP can be used in the case of a multipoint system and in particular in the case of a mesh network, where a minimum number of redundant packets per receiving node is thus guaranteed. In a particular embodiment: if the aforementioned information indicates that the reception quality is not satisfactory, the size of the redundancy sequence of the symbol (s) transmitted is incremented and the transmission steps are reiterated package and receipt of the notification; or if the above information indicates that the reception quality is satisfactory, a timer variable is initialized, packets are issued until the timer has elapsed, and then the size of the redundancy sequence of the symbol (s) issued and repeating the steps of packet transmission and reception of the notification. Thus, the system can follow a temporary variation of the communication channel and automatically restart an optimization phase of the length of the redundancy sequence once the time has elapsed. In a particular embodiment, all of the steps are performed for a single symbol having a predetermined position in the packet that contains it. This particular embodiment offers the advantage of allowing the reception of data even during the optimization phase, during which the length of the redundancy sequence may be insufficient to correctly transmit data. In a particular embodiment, the information representative of the quality of reception of the transmitted symbol (s) consists of the number of redundant copies validly received by the receiving node (s) and the aforementioned information. indicates that the reception quality is satisfactory when the number of redundant copies is greater than a predetermined threshold. This particular embodiment offers the advantage of ensuring that the optimization of the length of the redundancy sequence will be the best possible by maintaining the number of redundant copies to the minimum allowed by the mesh network. Indeed, if we define in another way the information representative of the reception quality of the symbol (s) issued, we do not enjoy the advantages of the mesh network and "optimization" may be suboptimal. According to a particular characteristic, the method further comprises a step according to which, if the aforementioned information indicates that the reception quality is not satisfactory, it is checked whether this is due to the change in size of the redundancy sequence.

This makes it possible to avoid restarting an optimization sequence of the length of the redundancy sequence when the reception quality problem is due to a phenomenon outside this optimization (of the masking type, for example). This verification step may consist in analyzing pilot signals or in transmitting a packet in which the size of the redundancy sequence of at least one symbol is equal to the maximum expected value of the time spreading and in checking the good reception of this package. For the same purpose as that indicated above, the present invention also proposes a device for transmitting data packets by a transmitting node in a communication network, each packet comprising a plurality of symbols, each symbol being preceded or followed by a redundancy sequence, this device being remarkable in that it comprises: a module for initializing the value of the size of the redundancy sequence of at least one symbol of a packet to be transmitted; a module for transmitting the packet and the value of the size of the redundancy sequence; a module for receiving from at least one receiving node a notification comprising information representative of the reception quality of the symbol (s) transmitted; and a module for varying the size of the redundancy sequence of the symbol (s) transmitted according to the aforementioned information.

For the same purpose as that indicated above, the present invention proposes correlatively a method of receiving data packets by a receiving node in a communication network, each packet comprising a plurality of symbols, each symbol being preceded or followed by a redundancy sequence, this method being remarkable what it comprises steps according to which: a packet is received from a transmitting node; decoding data representing the size of the redundancy sequence of at least one symbol of the received packet; the received payload is demodulated on the basis of the decoded size data of the redundancy sequence; generating a notification comprising information representative of the quality of reception of the symbol (s) of the received packet; and this notification is sent to the sending node. In a particular embodiment, the step of generating the notification is performed for a single symbol having a predetermined position in the packet that contains it. In a particular embodiment, the information representative of the quality of reception of the symbol (s) of the received packet consists of the number of redundant copies validly received. For the same purpose as that indicated above, the present invention also proposes a device for receiving data packets by a receiving node in a communication network, each packet comprising a plurality of symbols, each symbol being preceded or followed by a redundancy sequence, this device being remarkable in that it comprises: a module for receiving a packet from a transmitting node; a module for decoding data representing the size of the redundancy sequence of at least one symbol of the received packet; a module for demodulating the received payload based on the decoded size data of the redundancy sequence; a module for generating a notification comprising information representative of the reception quality of the symbol (s) of the received packet; and a module for transmitting this notification to the sending node.

Still for the same purpose, the present invention also aims at a telecommunications system comprising a plurality of terminal devices connected through a telecommunications network, remarkable in that it comprises at least one terminal device equipped with a transmission device and / or a receiving device as succinctly described above. Still for the same purpose, the present invention also aims at a means for storing information readable by a computer or a microprocessor retaining instructions of a computer program, remarkable in that it allows the implementation of a method of transmission and / or reception method as briefly described above. Still for the same purpose, the present invention also provides a computer program product that can be loaded into a programmable apparatus, which is remarkable in that it includes sequences of instructions for implementing a transmission method and / or a method as briefly described above, when this program is loaded and executed by the programmable apparatus.

Since the particular features and advantages of the transmission device, the method and the receiving device, the telecommunications system, the information storage means and the computer program product are similar to those of the transmission method, they are not not repeated here. In the following, the terms "packet" and "frame" are synonymous. Other aspects and advantages of the invention will appear on reading the following detailed description of particular embodiments, given by way of non-limiting examples. The description refers to the accompanying drawings, in which: - Figure 1 schematically illustrates the principle of insertion of a cyclic prefix; FIGS. 2a, 2b and 2c schematically illustrate examples of application of the invention and the gain obtained by its use; FIG. 3 schematically represents the content of the frames exchanged between a transmitting node and a receiving node according to the present invention, in a first particular embodiment; FIG. 4 is a flowchart illustrating the main steps of the procedure for optimizing the length of the cyclic prefix in accordance with the present invention, in the first particular embodiment; FIG. 5 schematically represents the content of the frames exchanged between a transmitting node and a receiving node according to the present invention, in a second particular embodiment; FIG. 6 is a flowchart illustrating the main steps of the procedure for optimizing the length of the cyclic prefix according to the present invention, in the second particular embodiment; FIGS. 7a, 7b and 7c illustrate an exemplary implementation of the present invention in a mesh-type communication network; FIG. 8 schematically represents the content of the frames exchanged between a transmitting node and a receiving node according to the present invention, in a particular embodiment where the network is of the mesh type; FIG. 9 is a flowchart illustrating the main steps of the procedure for optimizing the length of the cyclic prefix in accordance with the present invention, in a particular embodiment where the network is of mesh type; and FIG. 10 schematically represents a particular embodiment of an apparatus capable of implementing the present invention. The invention applies to a wired or wireless network. It will be described here in the case where the modulation used for the transmission of the data is an OFDM type modulation. However, this case is only a non-limiting example. The invention can equally well be applied in a communication system using any other modulation technique adapted to wired or wireless transmission and involving the insertion of a specific redundancy sequence comparable to a cyclic prefix (CP) between useful data, to avoid inter-symbol interference related to multiple propagation paths. The principle of the insertion of a CP in connection with FIG. 1 is first presented. The signals transmitted on the radio channel can reach the receiver by following a direct path or indirect paths. At the receiver input, even if the antenna is directional, signals that have multiple paths may be superimposed and the resulting signal is transmitted to the demodulator input. The dispersion of the transmission delays of the different propagation paths creates inter-symbol interference, a so-called phenomenon because each transmitted symbol acts as a source of distortion towards the following symbol. Inter-symbol distortion degrades system performance by preventing the receiver from properly demodulating received data. The dispersion of transmission delays can be countered by inserting an interval between each symbol or, better still, as is done in the case of systems using OFDM modulation, by repeating the last portion of the symbol to be transmitted at the beginning of this symbol. symbol.

The portion of the symbol repeated upstream of the symbol itself is called the cyclic prefix (CP). In FIG. 1, the samples corresponding to the data 10 to be transmitted for the first symbol are numbered from k to N.

The last k samples 20 are copied upstream of the symbol (this copy is represented in the drawing by the samples 30) to form a total symbol 50 of length N. In this example, the length of the CP is chosen to be equal to 1 / 4 of the length of the symbol before inserting the CP. Thus, if the samples corresponding to the data to be transmitted by symbol come from a Fast Fourier Transform (FFT) on Nk = 128 points, the length k of the CP will be 32 points and the length of the total symbol will be N = 160 samples. Figures 2a, 2b and 2c illustrate examples of application of the invention and the resulting gain in terms of data throughput. As shown in FIGS. 2a and 2b, the data are transmitted during a frame 100 consisting of a preamble 110 followed by a number of OFDM symbols 160. The symbols are constructed as illustrated in FIG. therefore include the data 130 from the FFT operation and the CP 120. In the example of Figure 2a, the size of the CP is set at 25% of the duration of the data from the FFT operation. In the example of Figure 2b, the size of the CP is set at 12.5% of the duration of the data from the FFT operation.

Figure 2c shows a table that quantifies the flow gain obtained by reducing the size of the CP. Considering that the duration of the frame is 192 ps and the duration of the data from the FFT operation is 768 ns, it can be calculated that the duration of the CP for Figures 2a and 2b is 192 ns and 96 respectively. ns. The frame 100 will therefore transmit 190 symbols when the CP will last 192 ns and 212 symbols when it will last 96 ns.

With a size of the preamble set at 8.64 ps, the raw data rate obtained on this communication link will be 190 Mbps in the first case and 212 Mbps in the second case. The application of the invention will therefore save 11.5% of the flow on this link. Those skilled in the art can easily apply this principle to other systems using different values for the duration of the preamble, data from the FFT and the frame. The diagram of FIG. 3 illustrates the content of the frames exchanged between a transmitting node and a receiving node according to the invention, in a first particular embodiment. The transmitting node sends a frame consisting of a preamble 110, followed by the information 150 giving the length of the CP used and all the data symbols 160, this frame being constituted according to the method described above in connection with the Figure 1. The receiving node returns a reduced frame consisting of a preamble 115, identical or not to the preamble 110 transmitted by the transmitter and a notification information 170 which indicates to the transmitting node the reception quality of the data.

The flowchart of FIG. 4 describes the main steps of the algorithm for optimizing the length of the CP according to the invention. The left and right parts of FIG. 4 illustrate the different steps performed respectively in the transmitter and receiver nodes. In step 210, the variables "length of the CP used for the emission of the symbols" (LCPF) and "good value of the CP" (GoodLCP) are initialized to the maximum expected value of the temporal spreading (LCPMax) or, in the absence of information on the latter, to an arbitrary value estimated higher than this one. A timeout value marked Temp is initialized to the value Tinit.

The next step 220 is to decrease the LCPF value, i.e., to reduce the duration of the CP. The variation step of this variable can be either fixed and unitary (for example, a step of 1 ns), or variable and dependent on the convergence of the algorithm (large steps at startup and small steps when the result of the test 300 described later will be alternately positive and negative). The next step 230 consists in sending the frame 180 as constituted as illustrated in FIG. 3, using the value of the variable LCPF calculated during the step 220. The ACK notification returned by the receiver is received during the step 240 and tested during step 250. If the notification indicates a good reception quality (result of the positive test), the GoodLCP variable is assigned the value of LCPF in step 260. At the end of this step, we return in step 220. If the result of the test 250 is negative, the value LCPC is assigned the GoodLCP value in step 270. The next step 280 is to transmit the frame 180 using the value of the LCPF variable defined in step 270.

The new ACK returned by the receiver is received during step 290 and tested during step 300. If the result of the test 300 is positive, step 350 is taken during which the time delay variable Temp is decremented. Then, in step 370, the value of the variable Temp is compared to zero (i.e., testing whether the time-out is reached); if the result of the test is positive, the value of the variable LCPF is decremented in step 380 and then goes to step 360, during which the variable Temp is reset to the value Tinit, before returning to step 280 If the result of the test 370 on the variable Temp is negative, we return directly to the step 280. If the result of the test 300 is negative, we verify in the step 310 whether the bad transmission is due to problems of inter-symbol interference. If the result of this check is negative (in other words, there is no reason to change the value of the LCPF variable), we return to step 280. If the result of the test 310 is positive (it is that is, the CP is too short to avoid inter-symbol interference), we go to step 320, during which the value of the variable LCPF is incremented. The next step 325 is to transmit the data frame of the type of the frame 180 of FIG. 3 using the value of the LCPF variable defined in step 320. The new ACK notification returned by the receiver is received during the step 330 and tested during step 340. If the result of the test 340 is positive, we go to step 360 during which the variable Temp is reset to the value Tinit, before returning to step 280. If the result of the test 340 is negative, it returns to the step 320, during which the value of the variable LCPF is incremented. The test 310 makes it possible to check if the bad reception of the symbols is due to the change in the length of the CP or to another phenomenon. Several solutions exist to make this verification: analysis of the pilot signals, re-sending of a frame with a length LCPMax and verification of its good reception. This test step is optional; it is not essential to the invention. On the right side of Figure 4 appear the essential steps of the algorithm of the invention performed in the receiver. In step 410, the receiver receives a frame of data of the type of frame 180 of FIG. 3. It then extracts at step 420 the value LCPF, which indicates the duration of the CP used by the transmitter for sending this frame. In the next step 430, the receiver demodulates the received data based on this LCPF parameter. Then at step 440, according to the result of the demodulation, the receiver sets the value of the ACK notification (positive or negative) and returns a frame of the type of the frame 190 of Figure 3 to the transmitter. The receiver then returns to step 410, waiting to receive a new frame. The calculation of the value of the ACK notification is based for example on the bit error rate of the frame. However, it can be defined differently, for example by choosing a criterion related to the use of this communication network. For example, in the case of a video data transmission, the value of the ACK notification can be determined with respect to the ability of the video decoder to reconstruct a correct image despite the insertion of errors during the transmission. The diagram of FIG. 5 illustrates the content of the frames exchanged between a transmitting node and a receiving node according to a second particular embodiment of the invention. In this particular embodiment, optimization of the size of the CP is performed by first varying the size of the CP of a single symbol. After determining the optimum CP size on this symbol, the optimum CP size is applied to all symbols in the frame.

The sending node sends a frame 181 consisting of a preamble 110, followed by the information 155 giving the length of the CP used for the symbol whose length has been modified, information 150 giving the length of the CP used for the others. symbols and the set of data symbols 160 constituted according to the method shown schematically in FIG.

The receiving node returns a reduced frame consisting of a preamble 115, identical or not to the preamble 110 transmitted by the transmitter and a notification information 170 which indicates to the transmitting node the reception quality of the data contained in the symbol whose length has been changed.

The position in the frame of the symbol whose CP is modified can be chosen indifferently at the beginning, at the end or during the frame. Alternatively, one can consider increasing the number of symbols whose size of the CP is changed. However, this is done at the expense of the guaranteed data rate.

The flowchart of FIG. 6 illustrates the main steps of the algorithm for optimizing the length of the CP in the second particular embodiment. The left and right parts of FIG. 6 illustrate the different steps of the algorithm performed respectively in the transmitter and receiver nodes in this second embodiment. In step 510, the variables "length of the CP used for the emission of the symbol used for the optimization of the CP" (LCP1), "length of the CP used for the emission of the symbols" (LCPF) and "good value "CP" (GoodLCP) are initialized to the expected maximum value of the time spread (LCPMax) or, in the absence of information on it, to an estimated arbitrary value greater than this.

The Temp timeout value is initialized to the Tinit value. The next step 520 is to decrease the value of LCP1, that is to say to reduce the duration of the CP of the symbol used for the optimization of the CP. The step of variation of this variable can be either fixed and unitary (for example, a step of 1 ns), or variable and dependent on the convergence of the algorithm (large steps during startup then small steps when the result of the test 600 described later will be alternately positive and negative). The next step 530 consists of sending the frame 181 constituted as illustrated in FIG. 5, using the value of the variable LCP1 calculated during step 520 for the symbol used for optimizing the CP and the value of the LCPF variable. for other symbols. The ACK notification which indicates the reception quality of the symbol used for optimization of the CP is then returned by the receiver and is received during step 540 and tested during step 550. If the notification indicates a good reception quality ( result of the positive test), the GoodLCP variable is assigned the value of LCP1 in step 560. At the end of this step, we return to step 520. If the result of the test 550 is negative, we assign to the LCP1 variable the GoodLCP value in step 565 and then the LCPF variable is assigned the value of GoodLCP in step 570. The next step 580 is to transmit frame 181 using these new values of LCP1 and LCPF variables . The new ACK notification returned by the receiver is received during step 590 and tested during step 600. If the result of test 600 is positive, step 665, during which the time delay value Temp is decremented, is passed. Then, in step 670, the value of the variable Temp is compared to zero (i.e., it is checked whether the end of timing is reached); if the result of the test 670 is positive, the value of the variable LCP1 is decremented in step 680, then proceed to step 625, where a new frame is issued with the new value of LCP1 and the unmodified value of LCPF. The new ACK notification returned by the receiver is received during step 630 and tested during step 640. If the result of this test is negative (new value of inadequate LCP1), proceed to step 620, during which LCP1 is incremented, before returning to step 625 for a new broadcast. If the result of the test 640 is positive (new value of LCP1 adequate), the GoodLCP variable receives the value of LCP1 in step 650 then the variable Temp is reset to the value Tinit in step 660, then returns to the step 570. If the result of the test 600 is negative, it is verified in step 610 whether the poor transmission is due to intersymbol interference problems. If the result of this check is negative (in other words, there is no reason to change the value of the variable LCP1), we return to step 570. If the result of the test 610 is positive (this is that is, the CP is too short to avoid inter-symbol interference), we go to step 615, during which the value LCPMax is assigned to the variable LCPF, then to step 620, during which the value of variable LCP1 is incremented.

If the result of the test 670 on the variable Temp is negative, we return directly to step 570 and a new frame is sent. The 610 test is used to check whether the bad reception of the symbol used for the optimization of the CP is due to the change in the length of the CP or to another phenomenon. This test step is optional; it is not essential to the invention. In this particular embodiment, this test can be done, for example, by asking the receiver to return two notifications: one for the symbol used for optimizing the CP and another for another symbol that may for example have been issued with a CP of maximum length.

On the right part of Figure 6 appear the essential steps of the algorithm performed in the receiver, in this second particular embodiment.

In step 710, the receiver receives a frame of data of the type of the frame 181 of FIG. 5. It extracts at step 715 the value LCP1 which indicates the duration of the CP used by the transmitter for the emission of the symbol used for optimizing the CP then, in step 720, the LCPF value which indicates the duration of the CP used by the transmitter for sending the other symbols of this frame. During the following steps 725 and 730, the receiver demodulates respectively the data received in the symbol used for the optimization of the CP and the data received in the other symbols, based on the parameters LCP1 and LCPF, respectively.

In step 740, according to the result of the demodulation of the symbol used for the optimization of the CP, the receiver defines the value of the ACK notification (positive or negative) and returns a frame of the type of the frame 191 of FIG. to the transmitter. The receiver then returns to step 710, waiting to receive a new frame.

In this second embodiment, the calculation of the value of the ACK notification is based for example on the correspondence between the values of the data transmitted in the symbol used for the optimization of the CP and those received. This symbol being unique, it can indeed affect a fixed and predetermined content without significantly penalizing the flow of useful data.

FIGS. 7a, 7b and 7c show an exemplary implementation of the invention in the particular case of a mesh type communication network. The lines of communication between the five communication nodes of a system have been materialized by lines. Indeed, a mesh network consists of a set of nodes connected by communication lines allowing the choice or combination of several routes from a network input to an output. In this type of network, the data transmitted by a node can travel on different paths and thus, multiple copies of the same data can be received by the destination node.

This property of mesh networks is used in some systems to improve the reliability of the received data; for example, if a node receives three different versions of the same data, it can decide which are the most relevant copies for the number of identical copies received. According to the decision algorithms used to select the data to be stored (data deemed relevant), a minimum number of copies is necessary for the receiver. Copies that arrive at the receiver in different ways use different relay nodes. They will not all be disturbed in the same way by the phenomena of inter-symbol interference appearing in each of the relay nodes.

In the particular embodiment of FIGS. 7a, 7b and 7c, the transmitting node and the receiving node are connected through a plurality of relay nodes allowing a plurality of paths and leading to reception by the receiving node of at least two copies of the same package. These two copies (at least) form a first copy called useful packet and at least one other copy called redundant packet. According to the present invention, it is sought here to choose a minimum CP size that allows for a highest possible payload data rate while ensuring a predetermined number of redundant packets per receiving node.

In the system illustrated in FIGS. 7a, 7b and 7c, a node C transmits data to four nodes N1, N2, N3 and N4. The data received by each node is systematically repeated so as to maximize the probability of correct data reception for each of the nodes (spatial redundancy).

In these figures are also illustrated three reflections numbered 1,2et3. These reflections create inter-symbol interference which, by increasing the number of errors beyond the possibility of correcting the error correction code, can break the communication link between two nodes. FIG. 7a illustrates the communication links in the case where the size of the CP is greater than the maximum time spread of these reflections.

In this case, no link is broken and each node receives four good quality copies of the signal transmitted by the node C. FIG. 7b illustrates the communication links in the case where the size of the CP is less than the time spreading minimal of these reflections.

In this case, the reflection 1 creates significant interference on the symbols received by the node N2 when the node C transmits and the link node C-node N2 is broken. In the same way, the reflection 2 creates significant interference on the symbols received by the node N3 when the node C sends and the link node C node N3 is broken and the reflection 3 creates significant interference on the symbols received by the node N3 when the node N2 sends and the node link N2-node N3 is broken. In this configuration, the nodes N2 and N3 receive only two good quality copies of the signal transmitted by the node C.

FIG. 7c illustrates the communication links in the case where the size of the CP has been optimized (value intermediate between the value used for FIG. 7a and that used for FIG. 7b) to ensure the reception of at least three copies of good quality of the signal transmitted by the node C. The links node C-node N2 and node C-node N3 are still broken, but the size of the CP is sufficient to fight against the reflection 3 and the node link N2-node N3 is retained. It is thus possible to reduce the size of the CP and thus increase the bit rate of the transmitted data, while maintaining a desired number of good quality copies of the signal transmitted by the node C.

For the implementation of the invention in the particular case of a mesh type communication network, it will therefore be necessary to choose as the notification sent by the receivers N1 to N4 to the source node C the number of redundant copies received. The node C will then define the length of the cyclic prefix according to an algorithm similar to that described below in connection with FIG. 9, which will make it possible to have a number of redundancies greater than a predefined threshold (three, in the example illustrated on FIGS. Figures 7a, 7b and 7c).

The diagram of FIG. 8 illustrates the content of the frames exchanged between a transmitting node and a receiving node according to a third particular embodiment of the invention, which envisages the case of a mesh-type communication network.

In this embodiment, the optimization of the size of the CP is performed so as to guarantee a minimum number of redundant packets per receiving node. The constitution of the frame is similar to that described in the embodiment of FIG. 3, with the exception of the content of the notification returned by the receivers and the retransmission by the receiving nodes of all or part of the received data. In this particular embodiment of the invention, the information contained in the notification sent by the receivers N1 to N4 to the source node C will be the number of redundant copies received.

The sending node sends a frame 182 consisting of a preamble 110, followed by the information 150 giving the length of the CP used for the frame and all the data symbols 160. Each receiving node transmits a frame consisting of a preamble 115, identical or not to the preamble 110 transmitted by the transmitter, a notification information 170 which indicates to the issuer node the number of redundant copies received (designated by NCR in the drawing), any own data (such as control data) 172 and data 174 consisting of all or part of the received data. The flowchart of FIG. 9 illustrates the main steps of the algorithm for optimizing the length of the CP in the particular embodiment in which the communication network is of mesh type. This algorithm is identical to that described above in connection with FIG. 4, with the exception of steps 240, 250, 290, 300, 330, 340, 440, 445 and 450.

On the left-hand side of FIG. 9, which illustrates the steps performed in the transmitter, steps 240, 290, 330 are the steps of receiving the notification returned by the receivers. In this embodiment, during these steps 240, 290, 330, the transmitter stores all redundant copy number (NCR) information returned by the receivers. During steps 250, 300, 340 which respectively follow steps 240, 290, 330, the receiver checks whether all returned NCR information is greater than the minimum number of redundant copies (designated NCmin in the drawing), which is a parameter of system. On the right-hand side of FIG. 9, which illustrates the steps performed in the receiver, at step 440, the notification is calculated from the number of redundant copies (NCRs) received. In the next step 445, the frame 192 (as described above in connection with FIG. 8) to be transmitted is constituted by concatenation of the NCR notification, possible data specific to the receiver (control data for example) and data. receipts that will be re-transmitted to other receivers. The next step 450 is to transmit this frame.

FIG. 10 shows a particular embodiment of an information processing device able to function as a data transmission and / or reception device according to the present invention. The device illustrated in FIG. 10 may comprise all or part of the means for implementing a transmission and / or reception method 20 according to the present invention. According to the embodiment chosen, this device may be for example a microcomputer or a workstation 1000 connected to different peripherals, for example a digital camera 1001 (or a scanner, or any other means of acquisition or storage of images) connected to a graphics card (not shown) and thus providing information to be processed according to the invention. The microcomputer 1000 preferably comprises a communication interface 1002 connected to a network 1003 capable of transmitting digital information. The microcomputer 1000 also includes a permanent storage means 1004, such as a hard disk, as well as a temporary storage means reader such as a floppy disk drive 1005 for cooperating with a floppy disk 1006.

The floppy disk 1006 and the hard disk 1004 may contain software layout data of the invention as well as the code of the computer program (s) whose execution by the microcomputer 1000 implements the present invention. , this code being for example stored on the hard disk 1004 once it has been read by the microcomputer 1000. In a variant, the program (s) enabling the device 1000 to implement the invention are stored in a read-only memory (for example of the ROM type) 1007. According to another variant, this or these program (s) are received totally or partially through the communication network 1003 to be stored as indicated. The device 1000 is connected to an audio data source 1015 via an input / output card 1014. The data to be processed according to the invention will in this case be an audio signal. The microcomputer 1000 also includes a screen 1009 to display the information to be processed and / or to interface with the user, so that the user can for example set up certain processing modes using the keyboard 1010 or any other appropriate means of pointing and / or input such as a mouse, an optical pen, etc. A computing unit or central processing unit (CPU) 1011 executes the instructions relating to the implementation of the invention, these instructions being stored in the ROM 1007 or in the other storage elements described. In particular, the central processing unit 1011 is adapted to implement the algorithms illustrated on the flowcharts of FIGS. 4, 6 and 9. When the device 1000 is powered up, the programs and processing methods stored in a system are nonvolatile memories, for example the ROM 1007, are transferred into a random access memory (for example of the RAM type) 1012, which then contains the executable code of the invention as well as the variables necessary for the implementation of the invention. 'invention. Alternatively, digital signal processing methods may be stored in different storage locations. In general, a means for storing information that can be read by a computer or by a microprocessor, whether or not integrated into the device, possibly removable, can store one or more programs whose execution implements the transmission method and / or reception described above.

The particular embodiment chosen for the invention can be modified, for example by adding updated or improved processing methods; in such a case, these new methods can be transmitted to the device 1000 by the communication network 1003, or loaded into the device 1000 via one or more floppies 1006. Of course, the floppy disks 1006 can be replaced by any information medium deemed appropriate (CD-ROM, memory card, etc.). A communication bus 1013 allows communication between the various elements of the microcomputer 1000 and the elements connected thereto. Note that the representation of the bus 1013 is not limiting. Indeed, the CPU 1011 is, for example, capable of communicating instructions to any element of the microcomputer 1000, directly or via another element of the microcomputer 1000.

Claims (21)

REVENDICATIONS1. A method of transmitting data packets by a transmitting node in a communication network, each packet comprising a plurality of symbols, each symbol being preceded or followed by a redundancy sequence (CP), said method being characterized in that comprises steps of: initializing (210, 270, 510, 570) the size value (LCPF; LCP1) of the redundancy sequence (CP) of at least one symbol of a packet to be transmitted; transmitting (280; 580) the packet and the size value (LCPF; LCP1) of the redundancy sequence (CP); receiving (290; 590) from at least one receiving node a notification (ACK) comprising information representative of the quality of reception of said at least one transmitted symbol; and varying (320, 380; 620, 680) the size (LCPF; LCP1) of the redundancy sequence (CP) of said at least one transmitted symbol according to said information. A transmission method according to claim 1, characterized in that if said information indicates that the reception quality is not satisfactory, the size (LCPF; LCP1) of the redundancy sequence is incremented (320; 620). (CP) of said at least one transmitted symbol and repeating the packet sending and receiving (330; 630) (325; 625) steps (ACK); or if said information indicates that the reception quality is satisfactory, initiating (360; 660) a timer variable (Temp), transmitting (280; 580) packets until the timer has elapsed, then decrementing (380; 680) the size (LCPF; LCP1) of the redundancy sequence (CP) of said at least one transmitted symbol and repeating the packet (280; 580) and receiving (290; 590) transmission steps notification (ACK). 3. Transmission method according to claim 1 or 2, characterized in that the set of steps is performed for a single symbol (symb1) having a predetermined position in the packet that contains it. 4. Transmission method according to claim 1, 2 or 3, characterized in that said information representative of the quality of reception of said at least one transmitted symbol consists of the number of redundant copies (NCR) validly received by said at least one node. receiver and that said information indicates that the reception quality is satisfactory when said number of redundant copies (NCR) is greater than a predetermined threshold. 5. Transmission method according to any one of the preceding claims, characterized in that it further comprises a step according to which, if said information indicates that the quality of reception is not satisfactory, one checks (310; 610) if this is due to the change in size (LCPF; LCP1) of the redundancy sequence (CP). The transmission method according to claim 5, characterized in that said verifying step (310; 610) consists of analyzing pilot signals or transmitting a packet in which the size (LCPF; LCP1) of the redundancy sequence (CP ) of at least one symbol is equal to the expected maximum value of the time spread (LCPMax) and to check the good reception of this packet. 7. Device for transmitting data packets by a transmitting node in a communication network, each packet comprising a plurality of symbols, each symbol being preceded or followed by a redundancy sequence (CP), said device being characterized in that it comprises: means for initializing the size value (LCPF; LCP1) of the redundancy sequence (CP) of at least one symbol of a packet to be transmitted; means for transmitting the packet and the size value (LCPF; LCP1) of the redundancy sequence (CP); means for receiving from at least one receiving node a notification (ACK) comprising information representative of the reception quality of said at least one transmitted symbol; and means for varying the size (LCPF; LCP1) of the redundancy sequence (CP) of said at least one transmitted symbol according to said information. 8. Transmission device according to claim 7, characterized in that it further comprises: means for incrementing the size (LCPF; LCP1) of the redundancy sequence (CP) of said at least one transmitted symbol and means for repeating the transmission of the packet and the receipt of the notification (ACK), if the said information indicates that the quality of reception is not satisfactory; and means for initializing a timing variable (Temp), means for transmitting packets until the timer has elapsed, means for decrementing the size (LCPF; LCP1) of the redundancy sequence (CP) of said least one transmitted symbol and means for repeating the transmission of the packet and the receipt of the notification (ACK), if said information indicates that the reception quality is satisfactory. 9. Transmission device according to claim 7 or 8, characterized in that the set of means applies to a single symbol (symb1) having a predetermined position in the packet that contains it. 10. Transmission device according to claim 7, 8 or 9, characterized in that said information representative of the quality of reception of said at least one transmitted symbol consists of the number of redundant copies (NCR) validly received by said at least one node. receiver and that said information indicates that the reception quality is satisfactory when said number of redundant copies (NCR) is greater than a predetermined threshold. 11. Transmission device according to any one of claims 7 to 10, characterized in that it further comprises means for checking whether the fact that the quality of reception is not satisfactory is due to the change in size (LCPF LCP1) of the redundancy sequence (CP), if said information indicates that the reception quality is not satisfactory. 12. Transmission device according to claim 11, characterized in that said verification means are adapted to analyze pilot signals or to transmit a packet in which the size (LCPF; LCP1) of the redundancy sequence (CP) from minus one symbol is equal to the maximum expected value of the time spread (LCPMax) and to check the good reception of this packet. A method of receiving data packets by a receiving node in a communication network, each packet having a plurality of symbols, each symbol being preceded or followed by a redundancy sequence (CP), said method being characterized in that it comprises steps according to which: a packet (410; 710) is received from a transmitting node; decoding (420; 715) data representing the size (LCPF; LCP1) of the redundancy sequence (CP) of at least one symbol of the received packet; the received payload data is demodulated (430; 725) based on said decoded size data (LCPF; LCP1) of the redundancy sequence (CP); generating (440; 740) a notification (ACK) comprising information representative of the reception quality of said at least one symbol of the received packet; and said notification (ACK) is transmitted to said transmitting node. 14. Reception method according to claim 13, characterized in that the step of generating (740) said notification (ACK) is performed for a single symbol having a predetermined position in the packet that contains it. 25 15. Reception method according to claim 13 or 14, characterized in that said information representative of the quality of reception of said at least one symbol of the received packet consists of the number of redundant copies (NCR) validly received. 16. Device for receiving data packets by a receiving node in a communication network, each packet comprising a plurality of symbols, each symbol being preceded or followed by a redundancy sequence (CP), said device being characterized in that it comprises: means for receiving a packet from a transmitting node; means for decoding data representing the size (LCPF; LCP1) of the redundancy sequence (CP) of at least one symbol of the received packet; means for demodulating the received payload data based on said decoded size data (LCPF; LCP1) of the redundancy sequence (CP); means for generating a notification (ACK) comprising information representative of the reception quality of said at least one symbol of the received packet; and means for transmitting said notification (ACK) to said transmitting node. 17. Receiving device according to claim 16, characterized in that the means for generating said notification (ACK) apply to a single symbol having a predetermined position in the packet that contains it. 18. Receiving device according to claim 16 or 17, characterized in that said information representative of the reception quality of said at least one symbol of the received packet consists of the number of redundant copies (NCR) validly received. Telecommunication system comprising a plurality of terminal devices connected through a telecommunications network, characterized in that it comprises at least one terminal device equipped with a transmission device according to any one of claims 7 to 12 and or a receiving device according to any of claims 16 to 18. 20. Computer-readable information storage medium or microprocessor retaining instructions of a computer program, characterized in that it allows the implementation of a transmission method according to any one of claims 1 to 6 and / or a receiving method according to any one of claims 13 to 15. 21. Computer program product that can be loaded into a programmable device, characterized in that it comprises sequences of instructions for implementing a transmission method according to any one of claims 1 to 6 and / or a method receiver according to any one of claims 13 to 15, when this program is loaded and executed by the programmable apparatus.