DE102006017347B4 - A method of receiving a DVB-T broadcast reception signal - Google Patents

Abstract

A method for decoding a digitized transmitted broadcast signal, which is transmitted symbol-oriented and has a symbol duration (T _S ), wherein the symbol duration (T _S ) in a guard interval (T _G ) and a user data area (T _U ) is divided and the decoding of in the symbol duration (T _S ) transmitted data on the basis of an evaluation window (2) obtained signals, wherein the evaluation window (2) extends into the guard interval (T _G ) of the symbol duration (T _S ) of the broadcast signal and the evaluation window (2) in the symbol duration (T _S ) is shifted such that disturbances in the user data area (T _U ) are not in the evaluation window (2).

Description

The The present invention relates to a method for receiving a DVB-T Broadcasting signal according to the features of the preamble of claim 1.

DVB-T transmission method and related Data is sufficient known (ETSI EN 300 744). The source coding is done with MPEG 2 or MPEG 4. Due to this data compression, several Transmit programs in one channel become. The channel bandwidth is between 6 MHz and 8 MHz, dependent from the frequency grid. The whole data of a multiplex will be subjected to channel coding after channel coding. this happens in that by a special modulation method, the COFDM method, the bandwidth is divided into several individual carriers. Everyone this single carrier will then use one of the three modulation methods defined for DVB-T, QPSK, 16 QAM or 64 QAM modulated.

Problematic in the transmission The DVB-T signals is the multipath propagation, the functional in the case of radiation due to multiple reflection. Multipath are unavoidable and technically conditioned in terrestrial networks. This results in the recipient appropriate echoes or disturbances, which by the recipient or in the receiver to compensate.

Around to ensure a certain error protection, is in DVB-T multiple fault protection installed. There is an external error protection (block Code), with each data packet consisting of 188 bytes, respectively 16-byte redundancy added become.

Furthermore, a bit interleaving takes place against burst errors. In addition, an internal error protection is provided, which is carried out by means of a convolutional coding. This allows the robustness against disturbances to be set, as is necessary for the various intended reception paths, for example for mobile reception, portable reception or stationary reception of DVB-T signals. In addition, there is an "inner-interleaving" to increase the robustness of the transmission.However, it should be noted that with a suitable choice of the COFDM single-carrier mode, the transmitter network and the receiver must be matched to each other with the symbol duration T _S. the useful symbol duration T _U is in a fixed proportion to the distance of the individual carriers to one another. the total symbol duration T _S is divided into a so-called guard interval T _g and a useful range of T _U. the guard interval has Principle the task to give the receiver a certain settling time until the useful data can be evaluated in the useful range of the signal and they can be decoded.

Of the The subject of this invention is concerned with the OFDM technique, more specifically said with the intelligent use of guard interval and payload of the sent symbol. The methods of channel coding remain unaffected.

As already shown, is the useful range in the transmission of DVB-T signals firmly defined. For evaluation of the symbol duration and the useful signals of the working area, the working area must be taken from the symbol period become. In conventional recipients this is done by detecting the beginning of the guard interval and upon detection of the end of the guard interval from this Time a decoding of the signals of the useful area is done.

The present invention takes a different approach. The symbol duration T _{S of} a DBV-T signal, which is composed of the guard interval and the useful range, is no longer considered static.

Out EP 1 331 783 A2 there is disclosed a method and apparatus for symbol clock recovery in an OFDM receiver. Out EP 1 276 289 A2 For example, an OFDM receiving system for clock synchronization with a guard interval and a corresponding method are known. In this known prior art, the evaluation window is in each case pushed to the guard interval of the next symbol. Subsequently, an interference interference is detected and due to this interference interference, the evaluation window is pushed back to position it in the payload area. A deliberate shift of the evaluation window into the guard interval is not carried out. The aim and purpose of this known prior art is to position the evaluation window exactly over the payload area. A shifting of the evaluation window and a continuous comparison, so that disturbances in the user data area are not in the evaluation window, are not considered in this prior art.

Out DE 697 28 831 T2 is a system known with distribution stations. This system forms a completely different system approach to the present invention. The individual symbols have a different temporal positioning and the symbol intervals are synchronous for all subcarriers.

From Li, Y .; Cimini, LJ, Jr .; Sollenberger, NR: Robust channel estimation for OFDM systems with rapid dispersive fading channels; in: IEEE Inter National Conference on Communications, Vol. 3, 7-11. June 1998, pages 1320-1324, a method for channel estimation is known. A stochastic estimation takes place there by evaluating the frequency, the periodicity and the probability of the signals.

The useful range T _U can be located arbitrarily in the symbol duration T _S , ie also at the beginning of the symbol. T _U is in a fixed relationship to the distance between the sub-carriers to each other. The start of the entire symbol of the DVB-T signal is detected. It will start decoding immediately after the symbol is recognized and will not wait until the guard interval has ended. For this purpose, a first window which corresponds to the width of the useful area T _U is evaluated. This first window is adjusted accordingly for each symbol that is received. It is begun, so to speak, even before the complete reception of the guard interval with the decoding of the user data from the useful signal from the useful range. In this case, it is particularly advantageous that, if echoes are present in the symbol duration, they can be corrected. If, for example, there is a disturbance in the rear area of the symbol, in the useful area, the region of the symbol to be evaluated can be pushed forward by skillful displacement of the first window, as it were into the area of the guard interval. It can be assumed that the signals can already be decoded before the useful range. The evaluation of the data of the entire symbol takes place before the actual useful range is present.

This surprisingly simple procedure evaluates the useful signals without waiting for the actual useful range T _U. The evaluation window of the width T _U can be moved freely over the entire symbol duration T _S. Thus, part of the guard interval T _{G is} already used for decoding.

In A further advantageous embodiment of the invention is continuous, offset in time, the evaluation window over the entire symbol duration shifted and evaluated. It will then create a statistic from which determines an optimal position of the evaluation window for the payload, which then for later Reception is used firmly. The basis for the statistics is the bit error rate after convolutional decoding and the waveform of a symbol in Time range and / or in the frequency domain.

The Evaluation is done in such a way that the data, respectively be taken from the evaluation window, stored and with each other be compared. In particular, this can be an error comparison done and it can be a stochastic evaluation of the received Data are made.

hereby can be a useful one Note for one Diversity evaluation and control of the reception take place. To step For example, in mobile reception disorders periodically on, so may a corresponding recipient, who proposed the Method used, predictive or with a prediction calculate these errors in advance or estimate these errors accordingly compensate.

The stochastic data can especially with a Kalman algorithm be evaluated and for to use intelligent diversity.

It In the described method, each symbol is evaluated accordingly and dynamically during of the reception the reception window is moved over the symbol.

in the Furthermore, a detection of disturbances or their evaluation takes place by means of a Viterbi decoding. Interference pattern, which over the Time thus be compensated.

Especially when using several antennas, which receive the same signal, Thus, an interference compensation can be carried out in an advantageous manner.

For every antenna the procedure described is carried out. For this purpose, then several receiving units provided. The received symbols are then transmitted via a further device compared with each other. Is now the For example, every thirtieth symbol when received over the first antenna disturbed is, then on further reception every 30th symbol in this antenna hidden and by data coming from another antenna and correspond to this symbol. In so far can through an intelligent interconnection of the antennas and a corresponding one Signal processing compensation of errors.

in the Further, the invention with reference to a specific embodiment explained with reference to figures.

It shows:

1 the construction of a DVB-T data signal,

2 the data signal off 1 with the evaluation of the prior art on a Time window,

3 the inventive method of the applicant, based on the DVB-T data signal according to 1 .

4 the modified method of the registration of the shift of the receiving window and

5 the schematic structure of a receiving unit with multiple receiving antennas.

In 1 the structure of a COFDM modulated data signal is shown schematically in the time domain, which is used in the DVB-T transmission. This data signal has a uniform symbol duration T _S. The symbol duration T _S is divided into the guard interval T _G and the useful range T _U. The guard interval T _G is used to wait until all signals (due to the multipath reception) lead to a stationary signal at the receiver after the beginning of the symbol, so that the signal evaluation can be started. A conventional receiver begins to decode the useful data from the useful range T _U after the end of the guard interval T _G.

In 2 this is shown in more detail. 2 again shows the COFDM modulated data signal, shown in the time domain, a temporal portion thereof, especially the symbol duration T _S and an evaluation window 1 , The evaluation window 1 begins with completion of the guard interval T _G and ends with the end of the useful range T _U. In this evaluation window 1 the decoding of the data of the usage area T _{U is} performed.

In 3 now the invention of the applicant is shown. In 3 is shown that the evaluation window 2 , which is the same length as the evaluation window 1 in 2 , does not begin with completion of the guard interval T _G , but extends into the guard interval T _G. The evaluation window 2 which is used here is the same length of time as the normally used evaluation window, but already extends into the guard interval T _G. This is particularly advantageous when there are problems. If, for example, there are disturbances in the useful range T _U at the end of this useful range T _U , then the evaluation window 2 be moved forward accordingly, so that the disturbances are not in the evaluation window 2 lie.

In a further advantageous embodiment of the invention, it is provided to start with two receivers initially earlier with decoding, wherein the decoding with the first receiver and a corresponding evaluation window 2 already in the guard interval T _G begins, in the following with a second receiver, the decoding until the end of the guard interval T _G and an evaluation window 1 to begin and analyze only the useful area T _U. Due to this parallel evaluation, any faults that are outside an evaluation window can be compensated by combining the data from both evaluation windows.

In a further advantageous embodiment of the invention according to 4 is provided that by an intelligent shift of the evaluation window, there denoted by F1 to FN, the respective evaluation window F1 to FN can be moved freely over the entire symbol duration T _S. This shift occurs at equidistant intervals over time. The evaluation window F1 to FN can thus use the entire symbol duration T _S. After each reception of a symbol duration T _S , evaluation windows F1 to FN are shifted in time. This takes place N times until the evaluation window N is present. Each signal received by each of the receiving windows F1 to FN is decoded and statistically analyzed. In this case, the optimum reception window F1 to FN can then be determined and this is used later for reception in the case of a static receiver. In this way, it is possible to compensate for disturbances that may be present in the useful range T _U by shifting the evaluation window F1 to FN within the symbol duration T _S.

Furthermore, according to 5 the schematic structure of a data terminal with multiple antennas A1 to AN shown with at least one receiving unit E and a control unit DE. The antennas A1 to AN are all connected in parallel with the reception to the receiving unit E. The receiving unit E is in communication with the control unit DE. The control unit DE controls the receiving unit E in such a manner that the receiving unit E uses the individual antennas A1 to AN respectively for reception.

The Initially inventive method is now applied as follows, especially in a mobile receiver.

The control unit DE controls the receiving unit E in such a way that over a predetermined period of time in each case with one of the antennas A1 to AN a reception is made. Thus, first of all, the control unit DE starts the receiving unit E in such a way that it receives the incoming signals, for example via the antenna A1 over a predefined period of time. After a predefined time, the control unit DE controls the receiving unit E such that the next antenna, for. B. the antenna A2 is used, etc., until the last reception via the antenna AN. While of the reception via each of the antennas A1 to AN, the evaluation window is shifted in accordance with the method and in accordance with the invention over the entire symbol duration TB of the received signal. The received data are statistically analyzed, in particular subjected to an error analysis. This is done as described by means of a Viterbi algorithm or another known stochastic evaluation algorithm. In this way, all antennas A1 to AN, which are connected, evaluated and recorded and evaluated in their receiving characteristic. In particular, in the case of mobile operation, this can also take place during the reception; in that respect, for each of the individual antennas A1 to AN and possibly for a plurality of available receivers, which are then controlled in parallel. The received data is stored and later compared and evaluated. In this way, it is possible over a period of time to obtain a statistical analysis of the quality of the received data signals.

provides It now turns out that there is a periodic disturbance in a data signal which is in particular over one of the antennas A1 to AN is received, so can via the Process this error be hidden, since in predictive recognition the presence of a fault the reception over another antenna takes place. The data terminal DE then controls the receiver E in such a way that that each predictive is determined from the outset, which of the antennas A1 to AN for Receiving the data signal is used. The receiving unit E thus switches on the basis of the predictive predetermined reception periods, where the default comes from the control unit DE, the individual Antennas A1 to AN on reception. This allows disturbances, which are present periodically to compensate.

Claims (11)

A method for decoding a digitized transmitted broadcast signal, which is transmitted symbol-oriented and has a symbol duration (T _S ), wherein the symbol duration (T _S ) in a guard interval (T _G ) and a user data area (T _U ) is divided and the decoding of in the symbol duration (T _S ) transmitted data by means of an evaluation window ( 2 ) obtained signals, wherein the evaluation window ( 2 ) extends into the guard interval (T _G ) of the symbol duration (T _S ) of the broadcast signal and the evaluation window ( 2 ) is shifted in the symbol duration (T _S ) such that disturbances in the user data area (T _U ) are not in the evaluation window ( 2 ) lie. Method according to Claim 1, characterized in that the evaluation window ( 2 ) is shifted over the entire symbol duration (T _S ). Method according to claim 1 or 2, characterized the broadcast reception signal is a DVB-T broadcast signal. Method according to one or more of the preceding claims, characterized in that from the evaluation window ( 2 ) and the temporal shift selbigem data are compared after their decoding and using an evaluation algorithm optimized position of the evaluation window ( 2 ) is determined. Method according to one or more of the preceding claims, characterized in that the time shift of the evaluation window ( 2 ) is made equidistant. Method according to one or more of the preceding claims, characterized in that all data, which by means of the evaluation window ( 2 ), stored and compared with each other. Method according to one or more of the preceding Claims, characterized in that in the presence of periodic interference noise compensation done by a diversity evaluation. Method according to one or more of the preceding Claims, characterized in that the method is applied to mobile receivers becomes. Method according to one or more of the preceding Claims, characterized in that in the presence of several receiving antennas (A1 to AN), a stochastic evaluation of the received data and with periodic disturbances each reception over the one antenna (A1 to AN), which is probably on Base of the previous receive data has the best reception. Method according to one or more of the preceding Claims, characterized in that the probability estimate via a Viterbi algorithm and / or a probability estimate of the symbol shape in the time domain and / or Frequency range occurs. Device for carrying out the method according to claim 1 having at least one antenna (A1 to AN), at least one receiving unit (E) and a control unit (DE), wherein the control unit (DE) the bit error rate after convolutional decoding and the waveform of a symbol in the time domain and / or monitored in the frequency domain and determines interference or their evaluation by means of a Viterbi decoding and thus interference pattern, which exist over time, are compensable.