KR20010076877A - Tps extraction apparatus for dvb-t system - Google Patents

Abstract

PURPOSE: A TPS(Transmission Parameter Signalling) extraction device of a DVB-T(Digital Video Broadcasting-Terrestrial) receiver system is provided to detect exact TPS data, and to improve a reliability of the DVB-T receiver system by choosing only the reliable TPS carrier value on the basis of CSI(Channel State Information) data gotten through a pilot information. CONSTITUTION: A TPS(Transmission Parameter Signalling) extraction device of a DVB-T(Digital Video Broadcasting-Terrestrial) receiver system includes a CSI(Channel State Information) calculation part(201), a TPS extraction part(202), a TPS location information storing part(203), and a DBPSK(Differential Binary Phase Shift Keying) encoding part(204). The CSI calculation part(201) finds out current channel information by comparing values of a scattered pilot location or a continual pilot location. The TPS extraction part(202) decides a location of a TPS carrier by using the information transferred by the CSI calculation part(201), and outputs location information(POSI_INFO) according to the location of the TPS carrier. The TPS location information storing part(203) generates control information(CTL_INFO) for appointing a reliable TPS carrier by using the location information(POSI_INFO) transferred by the TPS extraction part(202). The DBPSK encoding part(204) extracts reliable TPS data(TPS_DATA) by using the control information(CTL_INFO) transferred by the TPS location information storing part(203).

Description

TPS EXTRACTION APPARATUS FOR DVB-T SYSTEM} of DVB-T receiving system

The present invention relates to a technique for extracting TPS (Transmission Parameter Signaling) data in a DVB-T (DVB-T) digital video brodcasting-terrestrial (DVB-T) receiving system, and is particularly suitable for extracting reliable TPS data. It relates to a TPS extraction device of a T receiving system.

1 is a block diagram of a TPS decoding apparatus of a DVB-T system according to the prior art, as shown therein, an FFT processing unit 101 for performing Fast Fourier Transform (FFT) on a received digital data at high speed; A TPS extractor (102) for extracting TPS carriers from the output data of the FFT processor (101); A DBPSK demodulator 103 for demodulating 17/68 TPS carriers in one symbol in a DBPSK scheme; A TPS synchronization detector 104 for finding a starting point for forming one TPS block; A TPS block generator 105 for generating one TPS block by collecting output values of the DBPSK demodulator 103 based on a synchronization signal and a flag; It is composed of a BCH decoder 106 for decoding the TPS block output from the TPS block generator 105, the operation thereof is as follows.

The FFT processor 101 converts the received digital data DATA at high speed in advance. The DVB-T system has 2k mode and 8k mode, which takes 2048-point FFT for 2k-mode and 8192-point FFT for 8k-mode. The FFT processed data is supplied on the one hand to the TPS decoding block for decoding the TPS and on the other hand to the block for other processing, where the TPS will be described for the decoding block.

Before describing the next blocks, the format of the TPS signal will be described.

First, the signals in the DVB-T system have only 1705 data out of 2048 data in the 2k-mode based on the signal of the FFT output. The 1705 data consists of data with actual information, a scattered pilot, a continuous pilot, and a TPS carrier. In the 8k-mode, only 6817 data are required, including scattered pilot, controlled pilot and TPS carrier, among the 8092 data.

The data form one orthogonal frequency decoding modulation (OFDM) symbol. The collection of 68 symbols is called one frame. 68 pieces of TPS data form one TPS block, and these 68 pieces of TPS data are allocated one TPS data to one symbol. There are 17 TPS carriers in one symbol (in 2k-mode) or 68 (in 8k-mode). These TPS carriers have the same information, and the TPS carriers and DBPSK (DBPSK: Differential Binary Phase Shift Keying). It is processed to extract some reliable TPS data even in harsh environments.

Meanwhile, the TPS extractor 102 extracts TPS carriers from the output data of the FFT processor 101. Since the positions of the respective TPS carriers are already determined, the TPS extractors 102 need only extract data at the positions.

The DBPSK demodulator 103 is for performing the reverse function since 17/68 TPS carriers in one symbol are modulated by the DBPSK scheme. The output of the DBPSK demodulator 103 corresponds to one TPS data.

The TPS synchronization detector 104 performs a function of finding a starting point for forming one TPS block. Through this, the symbol index INDEX indicating where the current symbol corresponds can be known, and a flag indicates the start of the operation of the TPS block generator 105 by the detected synchronization signal Sync. .

The TPS block generator 105 collects the output values of the DBPSK demodulator 103 according to the synchronization signal Sync and the flag to generate one TPS block.

Since one TPS block is coded with BCH (Bose Chaudhuri Hocpuenghem), decoding is performed through the BCH decoder 106 to output decoded TPS data. Various important functions are performed in the DVB-T system based on the symbol index INDEX output from the TPS synchronization detector 104 and the TPS data output from the BCH decoder 106.

However, such a conventional DVB-T receiving system does not have a function of detecting inaccurate TPS data, and such TPS data are output as it is. The TPS data is accompanied by information necessary for the DVB-T system. As such, incorrect TPS data is output as it is, and there is a defect that degrades the performance of the system.

Accordingly, an object of the present invention is to provide a TPS extraction apparatus of a DVB-T receiving system that extracts reliable TPS data using CSI (Channel State Information) information indicating a current channel condition.

1 is a block diagram of a TPS decoding apparatus of a DVB-T system according to the prior art.

Figure 2 is a block diagram of an embodiment of the TPS extraction apparatus of the DV-T receiving system according to the present invention.

3 is an explanatory diagram illustrating a TPS extraction process of the TPS extraction unit in FIG. 2.

4 is a detailed block diagram of a DBPSK demodulator in FIG. 2; FIG.

*** Description of the symbols for the main parts of the drawings ***

201: CSI calculation unit 202: TPS extraction unit

203: TPS location information storage 204: DBPSK demodulation unit

FIG. 2 is a block diagram illustrating an embodiment of a TPS extraction apparatus of a DVB-T receiving system for achieving an object of the present invention. As shown therein, current channel information is compared by comparing values of a scattered pilot or a continuous pilot position. CSI calculation unit 201 to obtain a; A TPS extracting unit (202) for determining the location of a currently available TPS carrier using the information received from the CSI calculating unit (201) and outputting the location information (POSI_INFO) accordingly; A TPS location information storage unit (203) for generating control information (CTL_INFO) for designating a reliable TPS carrier using the location information (POSI_INFO) received from the TPS extraction unit (202); The DBPSK demodulation unit 204 extracts reliable TPS data TPS_DATA using the control information CTL_INFO received from the TPS location information storage unit 203. The operation of the present invention configured as described above is attached. A detailed description with reference to FIGS. 3 and 4 is as follows.

The CSI calculation unit 201 obtains a current channel using a scattered pilot and a continuous pilot (hereinafter, referred to as a pilot in two kinds of pilots), and based on this, the current data position and related data Information of the CSI value is obtained and transmitted to the TPS extractor 202. Since the pilots have constant position information, channel information about the entire data is obtained using these pilots. In this process, frequency interpolation and time interpolation are used.

In addition, since the values of the pilots are already determined by the standard, CSI, that is, the current channel information is obtained by comparing known pilot values with current values. The CSI information for each data location thus obtained is transmitted to the TPS extractor 202.

The TPS extractor 202 determines the location of the currently available TPS carrier using the information received from the CSI calculator 201. 3 schematically illustrates this process, showing current valid data and current CSI values. In other words, a high CSI indicates that the current channel environment is in a good state, and the value is determined by the CSI calculation unit 201.

3 shows that the input of valid data and the value of CSI for each valid data are compared to take TPS carriers higher than the threshold and discard TPS carriers below it. 3 shows that the TPS carrier at the P1 position is taken out and the TPS carrier value at the P2 position is discarded. In this way, the TPS extractor 202 transfers the position information on the TPS carriers to the TPS position information storage unit 203. And all valid data is transferred to the DBPSK demodulator 204.

The TPS location information storage unit 203 generates a control information (CTL_INFO) for designating a reliable TPS carrier using the received location information (POSI_INFO) and delivers it to the DBPSK demodulator 204. The TPS location information storage unit 203 generates control information CTL_INFO using the location information of the TPS carriers previously available and the location information of the TPS carriers currently available.

For example, if a previously available TPS carrier becomes unavailable due to a bad channel condition, the TPS carrier at that location should be informed to the control information CTL_INFO. On the contrary, the control information (CTL_INFO) should be informed that the TPS carrier at this position cannot be used even though the channel condition was previously unusable and cannot be used. This is because the TPS data is modulated by the DBPSK scheme, so that the values of the previous symbol and the current symbol must be used to obtain the value of the TPS data.

The DBPSK demodulator 204 extracts reliable TPS data TPS_DATA using the control information CTL_INFO, and its function will be described with reference to FIG. 4 as follows.

4, similar to the DBPSK demodulator of the conventional DVB-T receiving system, but selectors 402A-402N are added, and these use control information (CTL_INFO) input from the TPS location information storage unit 203. The only difference is that only reliable TPS data is extracted. The plurality of DBPSK demodulators 401A-401N perform demodulation functions in a DBPSK manner at each position of the TPS carriers. The reason why several DBPSK demodulators 401A-401N have the same function is because 17 (2K-mode) or 68 (8K-mode) have TPS information in one symbol as described above.

The values obtained by the respective DBPSK demodulators 401A-401N are transferred to the selectors 402A-402N, respectively, in which the value of the position is determined according to the control information CTL_INFO received from the TPS location information storage unit 203. To enable or disable them in the next step. Only data that is processed as available here is used in subsequent processing.

As a result, by using the present invention, it is possible to extract only reliable TPS data from TPS data having important information in the DVB-T receiving system. As is well documented in the DVB-T specification, the absence of forward error correction (FEC) without these TPS data does not work properly. Therefore, extracting reliable TPS information has significant significance for the reliability of the system.

As described in detail above, the present invention obtains CSI data using pilot information, and based on this, discards TPS carriers having a bad CSI and takes only reliable TPS carrier values to detect accurate TPS data. As a result, the reliability of the DVB-T receiving system is ultimately improved.

Claims (4)

Information transmission detecting means for obtaining current channel information by comparing the values of the scattered pilot or the continuous pilot position, and determining the position of the currently available TPS carrier and outputting the position information accordingly; And a demodulation means for generating control information for designating a reliable TPS carrier using the position information and extracting reliable TPS data using the location information. PS extraction device. 2. The apparatus of claim 1, wherein the information transmission detecting means comprises: a CS eye calculation unit for comparing current values of scattered pilot or continuous pilot positions to obtain current channel information; And a TPS extraction unit configured to determine a location of a TPS carrier currently available based on the channel information and output a location information according to the TPS carrier. The apparatus as claimed in claim 1, wherein the demodulation means comprises: a TPS location information storage unit for generating control information for designating a reliable TPS carrier using the location information; A TPS extraction apparatus of a DVB-T receiving system, characterized by comprising a DBP demodulation unit which extracts reliable TPS data using the control information. The demodulation demodulation unit of claim 3, wherein the DBS demodulation unit includes a plurality of selectors for processing the TPS data so that only reliable TPS data can be used in the next stage based on the control information input from the TPS location information storage unit. TIPS extraction apparatus of the DVB-tee receiving system.