FR2973616A1 - SYSTEM AND METHOD FOR DEMODULATING SYMBOLS OF A DIGITAL TERRESTRIAL TELEVISION SIGNAL - Google Patents

Abstract

A method of processing a digital terrestrial television signal comprising symbols carried within frames, comprising detecting (201) and decoding (202) a preamble symbol contained in a first frame, and demodulation processing ( 204, 207, 208) frames using information contained in the preamble symbol. In this method, a first delay (203) of a duration at least equal to the detection duration of the preamble symbol is applied to the signal.

Description

B 10-4935 1 System and method for demodulating symbols of a digital terrestrial television signal

The invention relates to digital terrestrial television and more particularly to the demodulation of the digital terrestrial television signal, for example a signal comprising frames defined in the DVB-T2 standard. In communication systems carrying digital data, frames of data are generally used, each of which can carry multiple symbols. Among these symbols, the frames generally include one or more preambles that are used by the receiving equipment to decode or process the remaining portion of the frame. In the case of the DVB-T2 (Digital Video Broadcasting - Second Generation Terrestrial) standard, one of the preamble symbols used is the symbol Pl. Detection and decoding of this symbol is necessary to demodulate the remaining part of the DVB frame T2. Also in the DVB-T2 standard, guard intervals are used between each of the frames. It is also necessary to delete these intervals before applying demodulation operations. To delete the guard intervals, it is necessary to detect the length of these guard intervals. However, the detection and decoding of the symbol Pl take a longer time than the duration of the symbol Pl. It is then impossible to demodulate the rest of the frame in which the symbol P1 has been detected. It is then planned to continue the demodulation in the frame following the one in which the symbol Pl has been detected. An expectation of a complete frame, that is to say approximately 250 ms is therefore necessary. The problem is similar for the detection of the size of guard intervals which has a duration greater than that of a symbol. This detection can not be performed on the frame in which the symbol Pl has been detected, but only in the next frame.

According to an embodiment and embodiment, there is provided a method and a treatment system for minimizing or overcoming the disadvantages mentioned above. According to one aspect, there is provided a method of processing a digital terrestrial television signal comprising symbols conveyed within frames, comprising a detection and decoding of a preamble symbol contained in a first frame, and a processing of demodulation of frames using information contained in the preamble symbol.

According to a general characteristic of this aspect, a first delay of a duration at least equal to the detection duration of the preamble symbol is applied to the signal. In this way, it is not necessary to wait for the next frame to perform the demodulation. On the contrary, it is possible to process the remainder of the frame, and in particular another preamble symbol, the symbol P2 in the DVB-T2 standard, which includes signaling information. Thus, the synchronization time on the frames is much less important. According to one embodiment, the signal comprises guard intervals separating the different symbols, and said processing further comprises a detection and a suppression of the guard intervals, and a second delay of a duration at the signal is applied to the signal. less than the detection time of guard interval size.

Thus, in the case of demodulation processing including interval detection and deletion, it is also no longer necessary to wait for the next frame. For this it suffices simply to delay the signal during the duration of detection of the size of the guard intervals. Typically it is a time equal to a few OFDM symbols (for example 3 OFDM symbols), this time is therefore also less than the time of a T2 frame. According to one embodiment, the method further comprises a Fourier transform operation on the signal cleared of the guard intervals using a memory, and said memory is also used to temporally delay said signal. Thus, it is not necessary to add additional memory to obtain a reduced synchronization time on the frames. In another aspect, there is provided a system for processing a digital terrestrial television signal comprising symbols conveyed within frames, comprising: a detection block of a preamble symbol contained in a first frame; a decoding block of the detected preamble symbol; frame demodulation means using information contained in the preamble symbol; According to a general characteristic of this aspect, the detection block of a preamble symbol comprises first time delay means capable of delaying said signal by a duration at least equal to the detection duration of the preamble symbol. According to one embodiment, the signal comprises guard intervals separating the different symbols and the demodulation means comprise a guard interval size detection block and a guard interval suppression block, said interval blanking block. guard comprises second time delay means for delaying the signal at its input for a duration at least equal to the duration of detection of the size of the guard intervals. According to one embodiment, the demodulation means furthermore comprise, downstream from the guard interval suppression block, a processing block able to perform a Fourier transform which uses the second delay delay means, said second delay delay means include a memory. Other advantages and features of the invention will appear on examining the detailed description of embodiments and embodiments, in no way limiting, and the accompanying drawings, in which: FIG. 1 illustrates a principle of operation of FIG. a DVB-T2 receiver, - Figure 2 illustrates an exemplary demodulation method according to the invention, - Figure 3 illustrates an embodiment of demodulation means according to the invention. FIG. 1 represents a device SYS for reception of terrestrial digital reception signals, for example in accordance with the DVB-T2 standard defined in particular in the document ETSI TR 102831 V0.9.6 (2009-01). The skilled person can refer for all purposes to this standard. It comprises signal pre-processing means MREC, demodulation means MDEM, and processing means MT. The MREC means of conventional structure and known per se, include for example amplifiers, filters and frequency transposition means. They are configured to receive the STV digital terrestrial television signal and perform pretreatments such as baseband frequency transposition, and deliver a baseband SR pretreated signal to the tuner error including a phase I component. and a Q quadrature component. The output of the MREC means therefore comprises two I and Q channels which have been represented for purposes of simplification in this figure by a single line. For the following processes, the signal SR can be likened to a complex signal whose component I forms the real part and the component Q the imaginary part. The signal processing system SR may have undergone a spectrum inversion, essentially comprises the demodulation means MDEM configured to demodulate this signal SR.

The signal SR comprises orthogonal frequency division multiplexing (OFDM) symbols conveyed within frames called T2 frames in the ETSI standard TR 102 831 V0.9.6 (2009-01). . The demodulation of the signal SR comprises in particular the application of a fast Fourier transform. However, to achieve this Fast Fourier Transform (FFT) according to an English acronym well known to those skilled in the art, it is necessary to delete guard intervals. Each of the OFDM symbols of the SR signal is indeed spaced from the OFDM symbol following a guard interval so as to avoid inter-symbol interference. It is necessary to suppress this guard interval to correctly perform the Fourier transform. On the other hand, OFDM symbols have an FFT size that is variable; it is necessary before realizing their Fourier transform to dispose of this information. This information is contained in a particular symbol of the frame T2, called the symbol Pl. Finally, because of the error of the tuner, the OFDM symbols have a non-zero center frequency which causes a loss of orthogonality of the carriers, which it is therefore necessary to correct in order to preserve the performance of the system.

The demodulation means MDEM comprise a DetPl block for detecting the symbol P1, a DecP1 decoding block of the symbol P1, a decay block DecaFreq for frequency translation, a DetGI block for detecting the size of the guard intervals, a block SuppG1 for suppressing the symbol. guard interval and a processing block App1iFFT, configured to apply a fast Fourier transform. The blocks DecaFreq, SuppGl and App1iFFT are processing blocks placed one after the other on a signal processing path SR. That is, the signal SR will be processed by the DecaFreq block outputting the signal SRA. The signal SRA will be processed by the block SuppG1 outputting the SARS signal and the SARS signal will be processed by the App1iFFT block outputting the signal SAT. The DetPl, DecPl, DetGI blocks are detection or decoding blocks that will perform processing in order to obtain information. This information will be provided to the DecaFreq, SuppGI and App1iFFT blocks so that they can process the SR, SRA and SARS signals respectively. After detecting the symbol P1, the DetP1 block delivers to the DecaFreq block the fractional value Fine_freq of the central frequency of the OFDM symbols and informs the SuppGI block of the start time of the frame (Synchro_frame). The DetP1 block also transmits the detection information of a Pl symbol to the DecPl block. The DecPl block, by decoding the symbol Pl, determines the integer value Coarse_freq of the central frequency and transmits this information to the frequency shift block. The DecPl block also determines an EnableGID information to mark the samples of the signal SRA belonging to a conventional OFDM symbol and those belonging to a symbol P1 so that the interval detection takes into account the symbol Pl and an information FFT_size corresponding to the size of the Fourier transform FFT. I1 delivers this information to the DetGI block for detecting the size of the guard intervals. From this information and the received SRA signal, the DetGI block determines the size of the GIsize guard intervals and the start time of a SynchroSymbol symbol. I1 transmits this information to the block SuppGI delete guard intervals. With information about the center frequency (Fine_freq, Coarse_freq), the frequency shift block DecaFreq applies a frequency transposition on the SR signal so as to obtain an SRA signal whose spectrum is recentered. The suppression block SuppGI of intervals can from the information of frame time (Synchro_Frame), symbol instant (SynchroSymbol) and the length of the guard interval (GIsize), delete in the signal SRA, the intervals in order to obtain the SARS signal. Finally, with the FFT size information (FFT_size) the App1iFFT block can apply on the SARS signal a fast Fourier transform so as to obtain a SAT signal. The block App1iFFT uses to make the Fourrier transform a circular buffer CIRC BUFF present in the deletion block SuppGI. This memory has a size corresponding to the maximum FFT size of the OFDM symbols of the SR signal. For example, in the case of the DVB-T2 standard, a circular buffer size may be 32kbit. The size of FFT is related to the size of the OFDM symbols of the SR signal, with the following relation: "OFDM symbol size = FFT size + guard interval" For example in the case of a symbol having an 8kbits FFT size and a 1/4 interval (ie 2kbits, 1/4 being the length expressed as a function of the FFT size), the size of the OFDM symbol is lOkbits. The means DetP1, DecP1, DetG1, SuppG1, DecaFreq and AppliFT are generally made in the form of software blocks, controlled by a microprocessor.

The processing means MT include memories, multiplexers, demultiplexers and calculators. They are notably configured to perform final demodulation processing such as phase and amplitude corrections on the OFDM carriers, OFDM carrier symbol assignments (OFDM demapping according to an Anglo-Saxon term well known to those skilled in the art ), de-interleaving, error correction and video processing such as MPEG decoding on the SAT signal to output images for display on a television screen.

As indicated above, the duration of the operations performed by the detection and decoding blocks of the symbol P1 has an impact on the processing carried out by the processing blocks DecaFreq, SuppGI and App1iFFT. Indeed, it is necessary for the DecaFreq block to have the central frequency information (Fine_freq and Coarse_freq) to carry out the frequency transposition. Likewise, it is necessary for the SuppGI block to have information concerning the symbol and frame times as well as the length of the guard intervals to perform the deletion of the intervals. However, the operations carried out by the detection and decoding blocks of the symbol P1 have a significant duration compared to the duration of the processing carried out by the blocks DecaFreq, SuppGl and AppliFFT. More precisely, the detection duration DDetPl of a symbol P 1 is equal to the duration of the symbol P 1 to which is added the duration of a prefix (prefix C) of the symbol P1, that is to say 2560.T , T being an elementary period. The decoding duration DDecPl of the symbol P1 is in general less than the duration of a symbol P1, that is to say 2048.T. Finally, the DDetGI detection duration of the guard intervals is generally less than three times the duration of a symbol and this detection uses correlation-based algorithms including a mean of the guard interval length well known to the user. skilled person. It thus appears that the duration D_DetPl + D_DecPl which is greater than the duration of the symbol Pl, is too important for the DecaFreq block to be able to continue the demodulation on the part of the frame located after the symbol P1 and including in particular another symbol of preamble called P2. Similarly, the duration DDetGI is much longer than the duration of a symbol, for example the symbol Pl, and it is therefore not possible to continue the demodulation on the frame for which the symbol Pl has been detected. One solution is to wait for the next frame or frames to continue the demodulation. Another solution, more advantageous, makes it possible to continue the demodulation directly on the frame containing the detected symbol P1. An example of this other solution is illustrated in FIG. 2. The method comprises two branches, a first branch corresponding to the detection and decoding steps (these are the operations performed by the blocks DetP1, DecP1, DetG1) and a corresponding second branch. the processing steps carried out in particular by the DecaFreq, SuppGl and App1iFFT blocks. Step 201 of the first branch corresponds to the step of detecting a symbol P1, this step is performed by the DetPl block for detecting a symbol P1. The duration of this step is DDetP1. Step 202 corresponds to the decoding step of the detected P1 symbol. The duration of this step is DDecP 1. The step 203 of the second processing branch corresponds to a step of applying a first delay on the signal SR. This delay is at least equal to the duration DDetPl. Thus, at the end of step 203, step 201 is performed. Step 204 corresponds to the application of frequency transposition by the DecaFreq block. This transposition does not concern the symbol P1. The step 204 of frequency transposition can therefore begin after the arrival of the symbol P1, that is to say after the duration of the symbol P1. During this duration, the step 202 can be realized (because the duration DDecPl is less than the duration of the symbol Pl). Thus, at the beginning of step 204, thanks to step 203, all the information concerning the central frequency is then available at the DecaFreq block. Step 205 corresponds to the detection of the size of the guard intervals by the DetGI block. The duration of this step is D_DetGI. Step 206 of the processing branch corresponds to a step of applying a second delay on the signal SRA. This second delay is at least equal to the duration D_DetGI. Thus, at the end of step 206, step 205 is performed and the delete block Guard intervals SuppGl has information frame time (Synchro_Frame), symbol instant (SynchroSymbol) and the length of the guard interval (GIsize). Step 207 which corresponds to the deletion of the guard intervals by the block SuppG1 can then be performed. Similarly, the step 208 of applying a Fourier transform can be performed by the App1iFFT block.

It is therefore possible by applying a first and a second delay (203 and 206) of durations respectively equal to at least the duration DDetPl and at least equal to the duration DDetGI to avoid waiting for the next frame to perform the demodulation processing . A delay equal to DDetP1 + DDetGI, is less than the waiting time of a new frame, which makes it possible to accelerate the synchronization on the T2 frames. In the case of a DVB-T2 application, the user point of view mainly consists of two steps, namely those of searching for channels or "scanning" according to an Anglo-Saxon term well known to those skilled in the art "and that of the passage from one channel to another or "zapping according to an Anglo-Saxon term well known to those skilled in the art". During the channel search step, all steps 201, 202 and 203 must be performed. On the other hand, during the channel change step, the length of the guard interval is known and only the steps 201 and 202 must be performed. It therefore appears that one aspect of the invention makes it possible, in the case of a channel change, not to wait for the next frame, this step is therefore accelerated. It also appears that one aspect of the invention makes it possible, in the case of searching for channels, not to wait for the next frame, this step is therefore accelerated.

FIG. 3 illustrates an embodiment of the MDEM demodulation means enabling the implementation of the method of FIG. 2. The MDEM means of FIG. 3 differ from the MDEM means of FIG. 1 in that the DetPl detection block is located on FIG. the signal processing path SR and outputs an SRR signal. The SRR signal will then be processed by the DecaFreq block with the SRA signal output. The DetPl detection block of FIG. 3 differs from the DetPl detection block of FIG. 1 in that it comprises a PlMEM memory. The memory PlMEM is used as a delay line so as to apply to the signal SR said first delay (at least equal to DDetPl). The block GIMl1 of FIG. 3 of the MDEM means differs from the Block G1G1 of FIG. 1 in that the BUFF buffer CIRC BUFF of the block SuppG1 normally used by the block App1iFFT to delay the signal SRA of a single OFDM symbol is used to delay the SRA signal of several OFDM symbols. More precisely, the CIRC BUFF buffer is configured to delay the SRA signal by an OFDM symbol number corresponding to the duration of said second delay (at least equal to DDetGI). This is only possible for OFDM symbols having an FFT size of less than or equal to 8kbits in the case, for example, of a CIRC BUFF memory of 32kbits. Indeed the duration D DetGI corresponds to 3 OFDM symbols, which represents 3. (8 + 2) = 30 kbits. Thus, the improvement of the channel search time mentioned above can not take place without hardware adaptation (conservation of the 32kbit size of the CIRC BUFF circular buffer) than for OFDM symbols having an FFT size of less than 16kbits. Of course, it is possible to provide a CIRC BUFFER memory size so as to obtain the improvement of the channel search time for all OFDM symbol sizes provided by the DVB-T2 standard.

The improvement of the channel changeover time mentioned above is possible in all cases with the addition of a PlMEM memory. Furthermore, for OFDM symbols having an FFT size of less than or equal to 8kbits, the capacity of the CIRC BUFF buffer of the SuppG1 block is better used. For example, for OFDM symbols having an FFT size of 8kbit, only about 1/4 of the 32kbits of the circular buffer of the SuppG1 block are used by the App1iFFT block. Whereas in the case of the Block G111, almost the entire CIRCBUFF buffer is used (3. (8 + 2) = 30 kbits). It is therefore possible at least in some cases to use at least a portion of the CIRCBUFF memory to delay the signal.

Claims (7)

REVENDICATIONS1. A method of processing a digital terrestrial television signal comprising symbols carried within frames, comprising detecting (201) and decoding (202) a preamble symbol contained in a first frame, and demodulation processing ( 204, 207, 208) frames using information contained in the preamble symbol, characterized in that a first delay (203) of a duration at least equal to the duration of detection of the preamble symbol is applied to the signal. . The method of claim 1, wherein the signal comprises guard intervals separating the different symbols, and said processing further comprises detecting (205) and deleting (207) guard intervals, and applying to the signal a second delay (206) of a duration at least equal to the duration of detection of the size of the guard intervals. The method of claim 2, further comprising a Fourier transform operation (208) on the signal cleared of guard intervals using a memory, and said memory is also used to temporally delay said signal. 4. A system for processing a digital terrestrial television signal comprising symbols conveyed within frames, comprising: a detection block (DetP1) of a preamble symbol contained in a first frame; a decoding block (DecP1) of the detected preamble symbol; demodulation means (MDEM) of frames using information contained in the preamble symbol; characterized in that the detection block (DetPl) of a preamble symbol comprises first time delay means (PlMEM) capable of delaying said signal by a duration at least equal to the detection duration of the preamble symbol. 5. System according to claim 4, wherein the signal comprises guard intervals separating the different symbols and the demodulation means comprise a detection block (DetGI) of the size of the guard intervals and a deletion block (SuppGI) of guard intervals, said guard interval suppression block comprises second time delay means (CIRCBUFF) for delaying the signal at its input for a duration at least equal to the duration of detection of the size of the guard intervals. 6. System according to claim 5, wherein the demodulation means (MDEM) further comprises downstream of the guard interval suppression block, a processing block adapted to perform a Fourier transform (App1iFFT) which uses a memory, at least a part of which forms the second time delay means (CIRC_BUFF). 7. Device for receiving a DVB-T2 signal comprising a system as defined in one of Claims 4 to 6.