KR20020034349A - Data recoding and reproducing method on a storing medium with ternary pit structure - Google Patents

Abstract

PURPOSE: A method for recording and reproducing data on a ternary pit structured storage medium is provided to use a ternary pit structure and a ternary modulation code, so that recording density on the storage medium is improved, thereby storing more data with the same pickup. CONSTITUTION: Analog data read from a storage medium configured with a ternary pit structure are converted into digital data(500). Pseudo-deconvolution is performed for the converted digital data(510), wherein the pseudo-deconvolution is performed to calculate an intermediate value between a corresponding signal and adjacent 2m signals centered on the corresponding signal and the pseudo-deconvolved signals are turned to be similar to signals passing a wavelength equalizer. Ternary code demodulation is performed for the pseudo-deconvolved digital data(520). The demodulated ternary code data are converted binary code data(530). And ECC(Error Correcting Code) is performed for the binary code data(540), thereby recovering data from the storage medium.

Description

Data recoding and reproducing method on a storing medium with ternary pit structure}

The present invention relates to a method of recording and reproducing data on a storage medium, and more particularly, to a method of recording and reproducing data on a storage medium having a ternary pit structure.

The conventional storage medium has a pit structure (binary pit structure) as shown in FIG. 1 to record data, and reproduces the data in the same manner as shown in FIG. In FIG. 2, first, data on a storage medium having a binary pit structure is read out by a pickup head (step 200), waveform-equalized (step 210), and then binarized and demodulated (step 220). The error of the demodulated binary coded signal is removed by ECC decoding (step 230) to finally recover the signal on the storage medium.

If a single slice is used to detect the transition of the signal, the greater the modulation, the easier it is to detect.However, as the recording density increases, the laser spot size does not change, resulting in a lower modulation. The rate is just enough to secure 30%. In particular, when playing back using a single slice after waveform equalization, there is a need to add additional steps to control the DSV of the code.

For example, CDs and CD-ROMs record data by converting 8 data bits into 14-channel bit codewords using Right to Fourteen Modulation (EMF) modulation. The combination bit may be selected from “000”, “001”, “010”, or “100” to increase detection performance by controlling a digital sum value (DSV), which is a measure of DC component. It is done. The EFM + modulation code used in the recently released DVD is an improvement of the EFM modulation code. The state / grouping method is used to secure the margin codes (88 to 256) and substitute the margin codes for DSV. By performing the control, the recording density ratio is improved by 6.3%.

In the conventional recording and reproducing method, the data is reproduced using a finite sized optical spot given by the wavelength of the light, and the data is recovered from the reproduced signal by a given modulation transfer function, thereby limiting the improvement in recording density. There is no choice but to receive. In particular, the binary modulation method can not improve the density because only '0' and '1' should be used.

An object of the present invention is to provide a pit structure, a data modulation code, and a data recovery method according to the present invention.

1 illustrates a pit structure on a conventional storage medium.

2 illustrates a method of reproducing data from a storage medium having the structure of FIG.

3 illustrates a pit structure of a storage medium according to the present invention.

4A-4J illustrate the ternary modulation code table of the present invention.

5A is a flowchart of a method for reproducing data from a ternary pit storage medium of the present invention.

FIG. 5B shows the magnitudes of the coefficients b _k determined for increasing the resolution of the signal in the case of convolution and pseudo deconvolution.

Fig. 6A shows an example of a signal read out from a ternary pit, (b) shows a signal that reads data recorded at a high density on a storage medium, and (c) shows a signal of (b). Pseudo deconvolution.

7A is a state diagram of codes and replacement codes recorded on the storage medium.

7B is a flowchart of a ternary code recording method on a storage medium.

8 is a distribution of zero run length in the ternary modulation of random data without DC component control.

A storage medium capable of recording / reproducing data for solving the above problem is characterized in that it comprises tracks of pit rows embodied by pit depth and storing at least three teeth or more.

The track is preferably embodied as a pit three levels deep.

The strikeout pit is preferably laminated to the photoresist of this layer on the storage medium and to a three layer structure.

In the storage medium in which data is recorded, to solve the other problem, the data is characterized as being recorded as a ternary modulation code.

The ternary modulation code preferably uses a predetermined alternative code to satisfy a zero run length condition between the codes.

Preferably, the ternary modulation code uses a predetermined second replacement code capable of minimizing the DC component of the signal to be recorded.

In a storage medium in which data is recorded, in order to solve the other problem, the pit of the storage medium is formed of a three-layered ternary pit, and the data is recorded as a ternary modulation code on the ternary pit. It is characterized by.

In order to solve the another problem, a method for reproducing data from a ternary pit storage medium includes the steps of: digitally converting analog data recorded on the storage medium; Pseudo-deconvolution of the digitally converted data; Performing ternary code demodulation from the pseudo deconvolved data; Converting data of the ternary code into data of the binary code; And performing error correction from the converted binary code data.

The pseudo deconvolution step may be performed as in Equation 1 below.

Multiply the signal r _{k + n} at the adjacent sampling point from -m to m by the coefficient b _k determined to increase the resolution of the signal ( It is preferable that the step is taken.

In order to solve the above another problem, a recording and reproducing method of a storage medium having a ternary pit structure for high density data recording includes: recording data in the pit as a ternary modulation code; Reading and digitally converting the data from the pit during playback; Pseudo de-convolution of the digitally converted data; Demodulating the pseudo deconvolved data into a ternary code; Converting the demodulated ternary code into a binary code; And recovering recorded data by performing error correction (ECC) on the binary-converted data.

The data recording step may include: a first step of determining whether one code satisfies a minimum zero run length when writing a ternary code; If the code satisfies the minimum zero run length in the first step, if the sub-code of the corresponding ternary code exists and the digital sum value (DSV) is small when the code is used, the sub-code is replaced with the sub-code. Second step; A third step of selecting another substitute code of the corresponding ternary code if the zero run length is not satisfied in the first step; And a fourth step of substituting the sub-code of the other substitute code if the sub-code of the other substitute code exists and the digital sum is small when the sub code is used.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 illustrates a pit structure of a storage medium according to the present invention. In a storage medium in which data is recorded, the pit of the storage medium is formed of a ternary pit having a three-layer structure. In order to take the pit of the disk into the three-layer structure, there may be a method of making a three-layer structure by controlling the power first. Alternatively, there may be a method of forming a three-layer pit structure by stacking two photoresistors having different sensitivity to photos. have.

4A to 4J illustrate a ternary modulation code table of the present invention, in order to increase the recording density on a storage medium, a non-binary state is introduced in a minimum unit unlike a conventional one, and it is a ternary digit. )to be. The ternary modulation code of FIGS. 4A-4J may be written to the pit of the three-layer structure of FIG. In the tables of FIGS. 4A to 4J4, the items represented by the 'A code' items correspond to the ternary modulation codes. Shown in items such as 'B code', 'C code' and 'D code' are alternative codes made to satisfy the zero run length condition between codes for A code. 'A sub code' 'B sub code' 'C sub code' 'D sub code', etc. are designed to minimize the DC component of the recorded signal for A code, B code, C code, and D code, respectively. Car replacement codes.

5A is a flowchart of a method for reproducing data from a ternary pit storage medium of the present invention. In this method, first, analog data read from the storage medium is digitally converted (step 500). Pseudo-deconvolution is performed on the digitally converted data as shown in Equation 1 (step 510). Pseudo deconvolution calculates the median value of the signal and 2m of adjacent signals around the signal. The pseudo deconvoluted signal becomes a signal similar to the signal passed through the waveform equalizer. FIG. 5B illustrates the case of convolution and pseudo deconvolution in Equation 1 described above with respect to the magnitude of the coefficient b _k determined to increase the resolution of the signal. Fig. 6A shows an example of a signal read out from a ternary pit, (b) shows a signal that reads data recorded at a high density on a storage medium, and (c) shows a signal of (b). Pseudo deconvolution. Trinity code demodulation is performed from the pseudo deconvolved result data (step 520). The ternary demodulation signal is represented by a sequence of '222111222111000222111 ....' from the result of FIG. 6A, and is changed to an array of '200100200 ..' by NRZI (Non-Return Zero Inversion). Then, the demodulated ternary code data is converted into binary code data (step 530). Finally, error correction (ECC) is performed from the binary code data (step 540) to recover data from the storage medium.

7A is a state diagram of codes and replacement codes recorded on the storage medium. There must be a number of '0's between the codewords and the codewords that do not violate Run Length Limited (RLL). If this is violated (for example, one' 0 'at the end of a codeword, followed by a codeword) The replacement code is used at the beginning of when no zero is present. 4A to 4J, the B and D codes do not have '0' in the tail of the codeword, and the A and C codes have '0' in the tail.

7B is a flowchart of a ternary code recording method on a storage medium. Referring to the table of FIGS. 4A to 4J, the code (A code) of data b _n at the time of ternary code recording is at least 0. It is determined whether the run length is satisfied (step 700). That is, the A code of the data determines whether or not the next code ending in or following '00' corresponding to the minimum run length is a code starting with '0' or no next code. If the condition is satisfied, i.e., if the minimum 0 run length is satisfied, it is determined whether a sub-code exists in the A code of the D _n data (step 702), and the digital sum value (DSV) when the sub-code is used. If it is small (step 704), if it is small, the A code of D _n data is replaced with an A sub-code (step 706). If not, the A code is used as it is (step 708). In step 700, if the zero run length is not satisfied, it is determined whether there is a B sub-code of D _n data that can satisfy the zero run length (step 710). If there is a B-sub code, it is determined whether the digital sum is small when the sub codes are used (step 712). If it is small, the A code of D _n data is replaced with the sub-code (step 714). Step 716). When the A code of D _n data is replaced with a B code or a B sub code, a C code or a C sub code or a D code or a D sub code is used for the next data, D _{n + 1} data. If the C codeword of D _{n + 1} data ends with '10' or '20' and the A code of the next byte (D _{n + 2} ) starts with a bit other than '0' (step 718) If the code exists (step 720) and the DSV absolute value is small when using the C subcode (step 722), then the D _{n + 1} data is converted to the C subcode (step 724), and the DSV value is replaced when the C subcode does not exist. If not small, the D _{n + 1} data is converted into a C code (step 726). If the corresponding condition is not satisfied in step 718, it is determined whether the sub-code of the D _{n + 1} data can be replaced with the D sub code (step 728). If it is small, replace D _{n + 1} data with a D sub code (step 732), and n to indicate the next data to apply the C code or C sub code, D code, or D sub code again to the next data. Increase by 1 (step 734). If the D sub code does not exist for the A code of the D _{n + 1} data or the absolute value of the DSV is not small when the D sub code is replaced, the D _{n + 1} data is converted into the D code (step 736). When a D code or a D sub code is used, the following data is applied to a C code or a C sub code, a D code or a D sub code.

8 is a distribution of zero run length in the ternary modulation of random number data without DC component control. Basically, it has a condition of ternary RLL (2, 20), but can be controlled by RLL (2, 18) by using alternative code well. The sub-code of each code reduces the DSV (Digital Sum). The present invention satisfies the conditions of the RLL (2, 20), and can reduce the maximum RLL (k) by 1-2 when using a replacement code. The probability of existence of a replacement code is about 17%.

When recording on a storage medium as an M-ary non-binary modulation signal As much as recording density can be expected. However, in the case of optical storage media, modulation codes with d = 2 have been used due to demanding requirements such as reproduction compatibility and duplication. In the PDM system of the present invention, a code satisfying the same minimum run length resulted in a 45.45% increase in recording density over the conventional EFM + modulation method. The Mark Radial Width Modulation (MRWM) method proposed by Matsushita can be used to apply the present invention not only to a read-only storage medium but also to a rewritable phase change optical storage medium.

When the recording density on the storage medium is improved by a method other than optical improvement as in the present invention, a larger amount of data can be stored in the same pickup.

According to the present invention, the recording density on the storage medium can be improved by using the recording and reproducing method using the ternary pit structure and the ternary modulation code.

Claims (17)

A storage medium capable of recording / reproducing data, comprising: And a track of pit rows embodied by pit depth and storing at least three inches or more. The method of claim 1, wherein the track, Storage medium, characterized in that implemented in three layers of pit depth. The method of claim 2 wherein the pit is And photosensitive two photoresists having different sensitivity on the storage medium. The method of claim 2 wherein the strikeout pit is A storage medium, characterized by different recording optical powers. A storage medium in which data is recorded and reproduced, The data is, A storage medium characterized by being recorded as a ternary modulation code. The method of claim 5, wherein the ternary modulation code, And a predetermined replacement code for satisfying a zero run length condition between the codes. The method of claim 5, wherein the ternary modulation code, A storage medium characterized by using a predetermined secondary replacement code capable of minimizing the direct current component of the signal to be recorded. A storage medium in which data is recorded, A pit of the storage medium is formed of a ternary pit of a three-layer structure, and the data is recorded on the ternary pit as a ternary modulation code. The method of claim 8 wherein the strikeout pit is And a photoresist of this layer on the storage medium and formed into a three-layer structure. The method of claim 8, wherein the ternary modulation code, And a predetermined replacement code for satisfying a zero run length condition between the codes. The method of claim 8, wherein the ternary modulation code, A storage medium characterized by using a predetermined secondary replacement code capable of minimizing the direct current component of the signal to be recorded. In a method of reproducing data from a storage medium consisting of ternary feet, Digitally converting analog data read from the storage medium; Pseudo-deconvolution of the digitally converted data; And Performing ternary code demodulation from the pseudo deconvolved data; Converting data of the ternary code into data of the binary code; And And performing error correction from the converted binary code data. The method of claim 12, wherein the pseudo deconvolution step comprises: As shown in Equation 1 below [Equation 1] Multiply the signal r _{k + n} at the adjacent sampling point from -m to m by the coefficient b _k determined to increase the resolution of the signal ( And reproducing data from the ternary-foot storage medium. A recording and reproducing method of a storage medium having a ternary pit structure for high density data recording, Writing data to the pit as a ternary modulation code; Reading and digitally converting the data from the pit during playback; Pseudo de-convolution of the digitally converted data; Demodulating the pseudo deconvolved data into a ternary code; Converting the demodulated ternary code into a binary code; And And recovering the recorded data by performing error correction (ECC) on the binary-converted data. The ternary modulation code of the data recording step of claim 14, wherein A method of recording and reproducing a storage medium having a ternary pit structure, using a predetermined substitute code for satisfying a zero run length condition between codes. The ternary modulation code of the data recording step of claim 14, wherein A recording and reproducing method of a storage medium having a ternary pit structure, characterized by using a predetermined second replacement code capable of minimizing a direct current component of a recorded signal. The method of claim 14, wherein the data recording step, A first step of determining whether a code satisfies the minimum zero run length when writing the ternary code; If the code satisfies the minimum zero run length in the first step, if the sub-code of the corresponding ternary code exists and the digital sum value (DSV) is small when the code is used, the sub-code is replaced with the sub-code. Second step; A third step of selecting another substitute code of the corresponding ternary code if the zero run length is not satisfied in the first step; And And a fourth step of substituting the sub-code of the other substituting code if the sub-code of the another substituting code is present and the digital sum is small when using the sub code. Storage media and storage media.