KR20040042251A - A channel data demodulation method and apparatus therefor, and a channel data error correction method and apparatus therefor - Google Patents

Abstract

PURPOSE: A method and a device for modulating channel data, and a method and a device for correcting the channel data are provided to obtain the reliable playback data by effectively demodulating a data symbol having no error in case that an error is present in a symbol synchronization code. CONSTITUTION: A frame synchronization code detector(930) detects a frame synchronization code from the channel data. The first demodulator(950) demodulates the demodulated data symbol without referring to a symbol synchronization code if the frame synchronization code is detected. The second demodulator(960) demodulates the modulated data symbol by referring to the symbol synchronization code if no frame synchronization code is detected.

Description

A channel data demodulation method and apparatus therefor, and a channel data error correction method and apparatus therefor}

The present invention relates to a method and apparatus for demodulating modulated channel data using a symbol synchronization code for synchronizing data symbols, and a method and apparatus for correcting channel data errors.

As storage devices become more dense, the difficulty of recording and reproducing data is growing. In most storage devices, the original user data is recorded through various steps such as ECC encoding, sync code insertion, and modulation. In particular, the ECC encoded user data is modulated by a predetermined modulation code, which modulation is intended to reduce the high frequency component and suppress the direct current component of the recording pulse train recorded on the optical recording medium. Eight (Eight to Fourteen Demodulation), which converts the original 8 bits of data into 14-bit code, uses an 8/16 modulation method that converts the original 8 bits of data into 16-bit code using a modulation table. have.

In order to smoothly detect the modulated data, the sync code information is inserted into a specific pattern or a portion for indicating a sync code number distinguished from the user data at regular intervals. That is, when the modulated data is recorded as the physical sector, the sync code is inserted and recorded every predetermined unit, i.e., frame. Such frame sync codes indicate a certain interval so that the channel bit boundary is not wrong at the time of demodulation, and the frame position in the sector so that the demodulated data can be stored at the correct position in the ECC correction arrangement when the sync code is captured after a burst error. It is intended to point to.

At the time of reproduction, the start of the modulated data is detected by detecting sync code information inserted in a specific pattern, and demodulated into reliable data using this. However, if the detection of the synchronization code information fails, it is very likely that all data will be lost when demodulating data corresponding to the period.

On the other hand, the recording medium includes a lead-in area, a data area, a lead-out area, etc. The lead-in area contains important information such as information about the disc and copyright information or copy protection information. Therefore, modulation methods are required in the lead-in area of the DVD or the lead-in area of the BCA area 110 of the Blu-ray disc as shown in FIG. Can be.

FIG. 2 illustrates a modulation method in which a symbol synchronization code is assigned and modulated for every data symbol. However, this modulation method is effective in the case of important information that requires a lot of overhead but requires reliability of data. Those skilled in the art will fully understand that such a modulation method is not limited to the lead-in area or the like and can be used in any area where data reliability is required.

An example of a method of reliably modulating data will now be described with reference to FIG. 2. A k-bit data symbol 21 is modulated into a k2 bit modulated data symbol (m_data) 222 by a predetermined modulation method, and a k1 bit data symbol sync code (m_sync) is preceded by the modulated data symbol 222. 221 is added to generate modulated channel data 220.

3 shows a frame having data symbols modulated by such a modulation method. The original data 310 consisting of data symbols 0 311,... Data symbols n-2 312 and data symbols n-1 313 is modulated with modulated channel data 320, which is frame 320. ) Is the frame sync code 321 of the s bit, the symbol sync code m_sync0 322, the modulated data symbol m_data0 323, the symbol sync code m_sync n-2 324, the modulated data symbol m_data n- 2 325, symbol sync code m_sync n-1 326, and modulated data symbol m_data n-1 327. Although this modulation method gives a symbol synchronization code for every data symbol, it is effective in the case of important information requiring a lot of data reliability, although there is a lot of overhead.

A conventional method of demodulating channel data modulated by the modulation method for giving such a data symbol sync code will be described with reference to FIG.

First, when the reproduced data is received (S410), it is determined whether a frame sync code is detected from the reproduced data (S420). Next, when the frame sync code is detected, the data is demodulated using the symbol sync code (S430).

However, if the frame sync code is not detected, then an error flag is generated regardless of whether the symbol sync code is detected (S440).

The error flag generated as described above and the demodulated data symbol are stored in the memory (S450), and error correction is performed (S460).

An example of a frame result performed by the demodulation method according to FIG. 4 will be described with reference to FIGS. 5A and 5B.

In Fig. 5A, FS represents a frame sync code, FS "represents an error frame sync code, A represents a k-bit data symbol, B represents a k1 bit symbol sync code, and B" represents an error symbol sync code. , C represents a modulated data symbol of k2 bits.

The modulated channel data 510 shown in FIG. 5A is a first frame including a frame sync code FS 511, a 0 th data symbol 512, and an n-1 th data symbol 513, an erroneous frame sync code. FS "514, a second frame including a 0 th data symbol 515 and an n-1 th data symbol 516. Here, the 0 th data symbol 512 and n-1 of the first frame are included. The symbol sync code indicates an error in the first data symbol 513. As described above, data demodulated by demodulating the channel data shown in Fig. 5A by a conventional method is shown in Fig. 5B.

The conventional demodulation method is to demodulate data symbols according to a symbol sync code detection result when demodulating each modulated data symbol. In the case of the 0 th data symbol 515 and the n-1 th data symbol 516 of the second frame, when the symbol sync code is detected, the 0 th data symbol 525 and the n-1 th data symbol 526 are used. Demodulation is performed properly. However, in the case of the 0 th data symbol 512 and the n-1 th data symbol 513 of the first frame, there is an error in the symbol synchronization code. Therefore, even if there is no error in the actual data symbol C, the symbol synchronization code is not properly detected. There is a problem that demodulation of data symbols cannot be performed properly.

However, if the frame sync code FS 521 of the first frame is correctly detected, it can be assumed that even if the symbol sync code is not properly detected, that is, if there is an error, there are data symbols at regular intervals past the interval of the symbol sync code. In this case, data symbol demodulation may be performed.

The present invention solves the above problems and improves the reliability of the reproduction signal. The present invention provides a method for demodulating channel data including a frame synchronization code for synchronizing frames, a symbol synchronization code for synchronizing data symbols, and a modulated data symbol. It is an object to provide a method and apparatus.

The present invention also provides a channel data error correction method and apparatus comprising a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing a data symbol, and a modulated data symbol so as to effectively perform error correction. The purpose.

1 is a view showing an area of a disk where data reliability is required;

2 is a view for explaining a method of modulating a data symbol using a data symbol sync code;

3 is a view illustrating a channel data frame modulated by the modulation method shown in FIG.

4 is a flowchart illustrating a process of demodulating channel data modulated by the modulation method shown in FIG. 2 according to the prior art;

FIG. 5A illustrates channel data modulated by a modulation method for providing a data symbol sync code, and FIG. 5B illustrates demodulated data by demodulating the channel data shown in FIG. 5A by a conventional demodulation method.

6 is a flowchart illustrating a process of a demodulation method according to the present invention;

7 is a flowchart illustrating a detailed process of the first demodulation method illustrated in FIG. 6;

8 is a flowchart illustrating a detailed process of the second demodulation method illustrated in FIG. 6.

9 is a block diagram of an example of a configuration of a reproduction device including a demodulation device according to the present invention;

10 is a block diagram of a detailed configuration of the first demodulator shown in FIG. 9;

11 is a block diagram of a detailed configuration of the second demodulator shown in FIG. 9;

FIG. 12 illustrates a symbol data frame 1200 demodulated by the demodulation method according to the present invention for the modulated channel data 510 shown in FIG. 5A.

One feature of the present invention for solving the above problems is a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing data symbols, and a method for demodulating channel data including a modulated data symbol. (a) detecting the frame sync code from the channel data, and (b) demodulating the data symbol using the symbol sync code according to the frame sync code detection result.

According to another aspect of the present invention, there is provided a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing each data symbol, and an apparatus for demodulating channel data including a modulated data symbol, wherein the frame synchronization is performed on the channel data. And a demodulation section for demodulating the data symbols using the symbol synchronization code in accordance with the frame synchronization code detection result.

In still another aspect of the present invention, there is provided a method of correcting a channel data error including a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing a data symbol, and a modulated data symbol, the method comprising: (a) in the channel data; Detecting a frame sync code, (b) demodulating the data symbol using the symbol sync code according to the frame sync code detection result, and generating an error flag according to the data symbol demodulation result; c) performing error correction using the generated error flag.

In still another aspect of the present invention, there is provided a channel data error correction apparatus including a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing each data symbol, and a modulated data symbol, wherein the frame synchronization is performed in the channel data. A frame sync code detector for detecting a code, an error flag generator for generating an error flag according to a result of demodulating the data symbols using the symbol sync code according to the frame sync code detection result, and the error flag generator It includes a decoder for performing the error correction of the data symbol by using the error flag generated by the.

Hereinafter, with reference to the accompanying Figures 6 to 12 will be described in detail the present invention.

First, the process 600 by the demodulation method according to the present invention will be described with reference to FIGS. 6 to 8.

When receiving the frame data reproduced from the recording medium (S610), it is checked whether the frame sync code is detected (S620).

If the frame sync code is not detected, the m_data i is demodulated by the first demodulation method referring to the symbol sync code m_sync i while looping the number n corresponding to the number of data symbols included in the frame ( S630).

The first demodulation method will be described in detail with reference to FIG. 7. If the symbol synchronization code m_sync i is detected (S631), if detected, it is determined whether m_data I can be demodulated (S632). M_data i is demodulated (S634), and if not demodulated, an error flag is generated for the corresponding data symbol (S633). If m_sync i is not detected, an error flag is generated for the corresponding data symbol (S633).

6, when the frame sync code is detected, the second demodulation method does not refer to the symbol sync code m_sync i by looping as many times n as the number of data symbols included in the frame. M_data i is demodulated by (S640).

As described above in detail with reference to FIG. 8, the second demodulation method that does not refer to m_sync i is discarded as is (S641), and it is determined whether m_data i is demodulated (S642). As a result of the determination, if m_data i is capable of demodulation, demodulation is performed (S643), and if not, an error flag is generated for the corresponding data symbol (S644).

Next, the data symbols or error flags demodulated by performing S630 or S640 are stored in the memory (S650), and error correction is performed using the data symbols and the error flags stored in the memory (S660).

9 shows a reproduction device including a demodulation device according to the present invention.

The reproducing apparatus includes a reading unit 920 for reading data from the disc 910, a demodulation unit 900 for demodulating the read data, a memory 970 for storing the demodulated data, and data stored in the memory. A decoder 980 for decoding and error correction is included.

The demodulator 900 includes a frame sync code detector 930, a frame sync error flag generator 940, a first demodulator 950, and a second demodulator 960.

The frame sync code detector 930 receives serial data reproduced from the reader 920 and detects the frame sync code to synchronize data in accordance with the period of the recording frame. The fake synchronization is applied to the length corresponding to the period from the position where the frame synchronization code is detected. When the frame sync code is detected, the received channel data is transmitted to the second demodulator 960. When the frame sync code is not detected, a signal is sent to the frame sync error flag generator 940.

The frame sync error flag generator 940 receives a signal and generates a frame sync error flag indicating that the frame sync code detection has failed and transmits the signal to the first demodulator 950.

When demodulating the channel data, the first demodulator 950 demodulates the channel data according to the symbol sync code detection result by referring to the symbol sync code. A detailed configuration of the first demodulator 950 is shown in FIG. 10.

The first demodulator 950 illustrated in FIG. 10 includes an m_sync detector 951, an m_data demodulator 952, and a data symbol error flag generator 953.

The m_sync detector 951 detects m_sync by receiving channel data 951 including a symbol sync code m_sync of k1 bits and a modulated data symbol m_data of k2 bits. The data symbol error flag generator 953 generates and outputs an error flag when m_sync is not detected as a result of the detection of the m_sync detector 951. The m_data demodulator 952 demodulates m_data when m_sync is detected as a result of the detection of the m_sync detector 951. If the demodulation is possible, the m_data demodulator 952 outputs a demodulated k-bit data symbol, and if the demodulation is not possible, the data. The symbol error flag generation unit 953 is instructed to generate an error flag for the corresponding data symbol.

The second demodulator 960 demodulates the data symbols without referring to the symbol sync code when demodulating the channel data. A detailed configuration of such second demodulator 960 is shown in FIG.

The second demodulator 960 illustrated in FIG. 11 includes an m_sync discard unit 961, an m_data demodulator 962, and a data symbol error flag generator 963.

The m_sync discard unit 961 receives the channel data 961 consisting of the k1 bit symbol sync code m_sync and the k2 bit modulated data symbol m_data, and discards the k1 bit symbol sync code m_sync. In fact, the symbol sync code m_sync of k1 bits may be referred to as don't care bits.

The m_data demodulator 962 demodulates m_data. If demodulation is possible, the m_data demodulator 962 outputs a demodulated k-bit data symbol. If the demodulation is not possible, the m_data demodulator 962 instructs the data symbol error flag generator 963 to indicate the data symbol. Generate an error flag for.

Next, the symbol data frame 1200 demodulated by the demodulation method according to the present invention will be described with reference to FIG. 12.

Since the frame sync code is detected in the case of the first frame, the data symbol is demodulated regardless of whether the symbol sync code is detected, and the 0 th data symbol 1220 and the n-1 th data symbol 1230 are correctly demodulated, and the second In the case of a frame, since a frame sync code is not detected, data symbols are demodulated according to whether a symbol sync code is detected. Since all symbol sync codes are detected, the 0 th data symbol 1250 and the n-1 th data symbol 1260 are decoded. It is properly demodulated.

When demodulating the channel data 510 shown in FIG. 5A, the conventional demodulation method relies only on whether the symbol synchronization code is detected. However, as shown in FIG. If demodulation is not performed properly, the data symbol can be correctly demodulated even if there is an error in the symbol synchronization code by considering whether the frame synchronization code is detected as well as the symbol synchronization code.

According to the present invention as described above, when the frame sync code is successfully detected, the data symbol is demodulated regardless of whether the symbol sync code of the modulated data symbol is an error and there is no error even if there is an error in the symbol sync code. By effectively demodulating the data, reliable playback data can be obtained.

In addition, according to the method of generating an error flag according to the present invention, error correction of channel data can be efficiently performed.

Claims (12)

A method of demodulating channel data comprising a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing a data symbol, and a modulated data symbol, (a) detecting the frame sync code in the channel data; and (b) demodulating the data symbol using the symbol sync code according to the frame sync code detection result. The method of claim 1, The demodulation step (b) is, (b1) when the frame sync code is detected, demodulating the modulated data symbol without referring to the symbol sync code; (b2) demodulating the modulated data symbol with reference to the symbol sync code if the frame sync code is not detected. The method of claim 2, Step (b1), (b11) discarding the symbol sync code; (b12) demodulating the modulated data symbols. The method of claim 2, Step (b2), (b21) detecting the symbol synchronization code; (b22) demodulating the modulated data symbol when the symbol sync code is detected; (b23) generating an error flag for the data symbol if the symbol sync code is not detected. An apparatus for demodulating channel data comprising a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing each data symbol, and a modulated data symbol, A frame sync code detector for detecting the frame sync code from the channel data; And a demodulator for demodulating the data symbols using the symbol sync codes according to the frame sync code detection result. The method of claim 5, The demodulation unit, A first demodulator for demodulating the modulated data symbol without referring to the symbol sync code when the frame sync code is detected; And a second demodulation unit for demodulating the modulated data symbol with reference to the symbol synchronization code if the frame synchronization code is not detected. The method of claim 6, The first demodulation unit, A discarding unit for discarding the symbol sync code; And a symbol demodulator for demodulating the modulated data symbols. The method of claim 6, The second demodulation unit, A symbol sync code detecting unit for detecting the symbol sync code; A symbol demodulator for demodulating the modulated data symbol when the symbol sync code is detected; And an error flag generator for generating an error flag for the data symbol if the symbol sync code is not detected. A channel data error correction method comprising a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing a data symbol, and a modulated data symbol, (a) detecting the frame sync code in the channel data; (b) demodulating the data symbol using the symbol sync code according to the frame sync code detection result, and generating an error flag according to the data symbol demodulation result; (c) performing error correction using the generated error flag. The method of claim 9, The demodulation step (b) is, (b1) when the frame sync code is detected, demodulating the modulated data symbol without referring to the symbol sync code to generate an error flag when data symbol demodulation is impossible; (b2) if the frame sync code is not detected, demodulating the modulated data symbol with reference to the symbol sync code to generate an error flag when data symbol demodulation is impossible; Correction method. In a channel data error correction apparatus comprising a frame synchronization code for synchronizing a frame, a symbol synchronization code for synchronizing each data symbol, and a modulated data symbol, A frame sync code detector for detecting the frame sync code from the channel data; An error flag generator for generating an error flag according to a result of demodulating the data symbol using the symbol sync code according to the frame sync code detection result; And a decoder for performing error storage of the data symbols by using the error flag generated by the error flag generator. The method of claim 11, The error flag generator, If the frame sync code is detected, an error flag is generated when demodulating the modulated data symbol without referring to the symbol sync code, and if data symbol demodulation is impossible, and if the frame sync code is not detected, the symbol sync code And demodulating the modulated data symbol to generate an error flag when data symbol demodulation is impossible.