KR100629489B1 - Method for optimizating ws according to ws calibration in recording information area medium chracteristic of which is similar to that of user data recording point and apparatus thereof - Google Patents

Abstract

Provided are a WS optimization method through WS learning in a recording information area having similar characteristics of a user data recording point and a medium, and an optical recording apparatus using the same. The WS optimization method comprises the steps of: determining a state of a recording point which is a point at which user data is to be recorded on a user data area of a rewritable optical disc; recording information which is information on user data is recorded based on the state of the determined recording point. Determining a partial area of the recording information area, which is an area, as a WS learning area, which is an area to be used for WS learning, and obtaining an appropriate WS by allowing WS learning to be performed in the determined WS learning area. This makes it possible to obtain the optimum WS for the UDA which has already been rewritten several times and to record the UD according to the obtained optimal WS, thereby improving the recording quality of the optical disc.

WS, WS Learning, UDA, TA, RIA, RIB

Description

Method for optimizating WS according to WS calibration in recording information area medium chracteristic of which is similar to that of user data recording point and apparatus

1 illustrates the format of a rewritable optical disc that can be used in practicing the present invention;

2 is a block diagram of an optical recording apparatus for performing WS optimization by performing WS learning in a recording information area having similar characteristics of a user data recording point and a medium according to an embodiment of the present invention;

3 is a view for explaining the record information record frequency limit for the record information block;

4 is a flowchart provided to explain a WS optimization method through performing WS learning in a recording information area having similar characteristics of a user data recording point and a medium according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

UDA: User Data Area UD: User Data

TA: Test Area RIA: Recording Information Area

RIB: Recording Information Block 150: RIA Analysis Unit

160: UDA state determination unit 170: WS learning area determination unit

180: control unit

The present invention relates to a WS (Write Strategy) optimization method and an optical recording device using the same, and more particularly, to a WS optimization method through WS learning in a recording information area similar to a user data recording point and a medium characteristic, and an optical recording using the same. Relates to a device.

The optical recording apparatus performs WS learning prior to recording the user data in the user data area of the mounted optical disc. WS learning is a procedure performed to obtain an optimal WS. The reason for preceding WS learning prior to recording user data is to improve recording quality by recording user data according to a more optimal WS.

WS learning is performed in the test recording area of the optical disc. The test record area is an area on the optical disc that is separately prepared for WS learning, and the test record is not performed again at the point where the test record has already been performed. That is, the point on the test record area where WS learning is performed corresponds to the point where the test record has never been made.

On the other hand, there is an optical disk capable of rewriting user data over a number of times in the user data area, which is called a rewritable optical disk. In the case of such a rewritable optical disc, the WS learning is performed in the test recording area, and the WS learning is performed at a point on the test recording area that has never been recorded.

However, it is problematic that WS learning to optimize the WS used to record user data in a user data area that has already been rewritten over a number of times is performed at a point on the test record area that has never been recorded so far. have.

This is because the media characteristics of the user data area that has been rewritten over several times and the point on the test recording area that has never been recorded so far are different. This is because the media properties of the user data area change due to the rewriting over several times. Due to

Therefore, the WS acquired through the WS learning in the test recording area is not suitable for use in recording user data in the user data area in which rewriting has been performed for several times. Such incompatibility becomes more serious as the number of times of rewriting of user data in the user data area increases.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to learn WS in a recording information area having similar characteristics to a user data recording point and a medium in order to prevent a WS that is not suitable for user data recording. The present invention provides a method for optimizing WS and an optical recording device using the same.

According to the present invention for achieving the above object, a WS optimization method includes: determining a state of a recording point which is a point where user data is to be recorded on a user data area of a rewritable optical disc; Determining a partial area of a recording information area, which is an area in which recording information, which is information on the user data, is recorded, as a WS learning area, which is an area to be used for WS (Write Strategy) learning, based on the determined recording point state; ; And acquiring a proper WS by performing WS learning in the determined WS learning area.

In the determining step, the medium characteristic of the recording point is determined, and the determining step includes, in the recording information area, a partial area having a medium characteristic similar to that of the determined recording point as the WS learning area. You can decide.

In the determining step, the number of rewrites of the recording point is determined, and the determining step is to determine a partial area of the recording information area as the WS learning area based on the number of rewrites of the determined recording point. desirable.

In the determining step, it is preferable to determine, as the WS learning area, a section including blocks having recording information recording times close to the rewrite times of the determined recording points among the blocks constituting the recording information area. Do.

In the determining step, when the number of rewrite times of the recording point is less than a predetermined number of times, the WS learning area is undetermined, and the WS obtained through the WS learning performed in the test recording area provided on the optical disc is determined as an appropriate WS. It is preferable.

The WS optimization method may further include limiting the number of recording information recording times for the blocks constituting the recording information area to a predetermined number of times.

On the other hand, according to the present invention, an optical recording apparatus includes: a discriminating unit for determining a state of a recording point which is a point at which user data is to be recorded on a user data area of a rewritable optical disc; WS learning, which is a region to be used for WS (Write Strategy) learning, using a partial area of the recording information area, which is an area where recording information which is information on the user data is recorded, on the basis of the state of the recording point determined by the discriminating unit. Determining unit to determine the area; And a controller configured to perform WS learning in the determined WS learning area, thereby obtaining a proper WS.

The determining unit may determine a medium characteristic of the recording point, and the determining unit may determine a partial area having a medium characteristic similar to the medium characteristic of the recording point determined by the determining unit in the recording information area. It can be decided as a learning area.

The determining unit may determine the number of times of rewriting of the recording point, and the determining unit may convert a partial area of the recording information area into the WS learning area based on the number of times of rewriting of the recording point determined by the determining unit. It is desirable to decide.

The determination unit may include, from the blocks constituting the recording information area, a section including blocks having recording information recording times close to the rewrite times of the recording points determined by the determining unit, to the WS learning area. It is desirable to decide.

In addition, the determination unit, if the number of rewrite times of the recording point is less than a predetermined number of times, the WS learning area is undetermined, and determine the WS obtained through the WS learning performed in the test recording area provided on the optical disc as an appropriate WS It is preferable.

The controller may limit the number of times of recording of the record information for the blocks constituting the record information area to a predetermined number of times.

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

1 shows a format of a rewritable optical disc that can be used in practicing the present invention. Referring to FIG. 1, an 'rewritable optical disc' (hereinafter, referred to as 'optical disc') is formed from inner to outer, IDA (Lead Drive Area), LIA (Lead In Area), and UDA. (User Data Area), Lead Out Area (LOA), and Outer Drive Area (ODA) are provided.

The UDA is an area in which 'User Data' (hereinafter, abbreviated as 'UD') such as AV data is recorded.

In IDA, LIA, LOA, and ODA, data related to management, reproduction, and recording of the optical disc are recorded. In particular, IDA is provided with a test area (TA) and a recording information area (RIA). TA is a test record area used for WS (Write Strategy) learning, and RIA is an area where recording information (hereinafter, abbreviated as 'RI'), which is information about UD recorded in UDA, is recorded.

The RIA is composed of a plurality of recording information blocks (RIBs) (first to Nth RIBs). The record of RI is performed in parallel with the record of UD. Specifically, when a certain amount of UD is recorded in the UDA, information about the UD recorded until then is initially recorded in the RIB as an RI. Thereafter, if a certain amount of UD is further recorded in the UDA, information about the UD recorded until then is rewritten to the RIB as a new RI. That is, the RI is continuously updated in the process of recording the UD.

On the other hand, since RI is information about the recorded UD, it plays an important role in reproducing the UD. Therefore, when the 'RI initial recording or rewriting' (hereinafter abbreviated as 'RI recording') is abnormally performed, the UD cannot be reproduced even if the UD is normally recorded.

Therefore, when the RI recording is completed, it is determined whether the RI recording is normally performed. If it is determined that the RI recording is normally performed, RI rewriting is continuously performed in the RIB in which the RI recording is performed. However, if it is determined that the RI recording has been abnormally performed, the RIB on which the RI recording has been performed is no longer used, and the RI recording is performed to the RIB located next. That is, if RI recording is performed on the first RIB, and the RI recording is abnormally performed, RI recording is performed on the second RIB.

So far, the format of the optical disc that can be used in practicing the present invention has been described. The optical discs that can be used in practicing the present invention include rewritable compact discs (CDs), digital video discs (DVDs), blue-ray discs (BDs), HD-DVDs, and the like, as well as other types of rewritable optical discs. Of course, it can be used in practicing the present invention.

Meanwhile, although the terminology for the area constituting the optical disk may vary according to the type of optical disk, the terms shown in FIG. 1 will be used below. For example, the term RIA shown in FIG. 1 is a term used for a DVD-RW. The RIA corresponds to a table of contents zone (TCZ) for DVD + RW, and DIZ (for DVD-RAM). Disk Identification Zone), hereinafter, the term 'RIA' shown in FIG. 1 is used as a generic term for RIA, TCZ, and DIZ. Similarly, the term TA shown in FIG. 1 corresponds to PCA (Power Calibration Area) for DVD-RW and inner disk test zone (IDTZ) for DVD + RW. Hereinafter, PCA and IDTZ are referred to below. As a generic term, it is meant to use the term 'TA' shown in FIG. 1.

2 is a block diagram of an optical recording apparatus according to an embodiment of the present invention. The optical recording device optimizes WS by performing WS learning in RIA. More specifically, the optical recording apparatus optimizes WS by performing WS learning on RIBs that are expected to be unused in recording UDs among the RIBs constituting the RIA and have similar characteristics to the UD recording points. . Here, the 'UD recording point' means a point at which the UD is to be recorded on the UDA.

As shown in FIG. 2, the optical recording apparatus includes a PU (Pick Up) 110, a PU driver 120, a recording processor 130, a playback processor 140, a RIA analyzer 150, and a UDA state. The determination unit 160, the WS learning area determination unit 170, the control unit 180, and the memory 190 are provided.

The PU 110 is driven by the PU driver 120, reads data recorded on the mounted optical disc D, and outputs an electric signal corresponding to the read data to the reproduction processor 140. The playback processor 140 performs signal processing on the electrical signal output from the PU 110. In addition, the PU 110 records the UD signal-processed by the recording processing unit 130 on the mounted optical disc D. FIG.

The RIA analyzer 150 analyzes the RIA through the output signal of the reproduction processor 140 and outputs an RIA analysis result.

The UDA state determination unit 160 determines the state of the UD recording point by using the RIA analysis result output from the RIA analysis unit 150.

The WS learning area determiner 170 determines a partial area of the RIA as the WS learning area based on the determination result output from the UDA state determination unit 160 and the RIA analysis result output from the RIA analyzer 150.

The controller 180 controls the PU 110 driving operation of the PU driver 120 to perform WS learning in the WS learning area or TA determined by the WS learning area determiner 170, and the WS acquired by WS learning. To the memory 190. In addition, the controller 180 controls the PU 110 driving operation of the PU driver 120 so that the UD is recorded according to the WS stored in the memory 190.

Meanwhile, the controller 180 may limit the number of RI records for the RIB constituting the RIA. This is possible by controlling the driving operation of the PU 110 by the PU driver 120 such that the controller 180 performs only a predetermined number of times of RI recording on the RIB. According to this, even if it is determined that RI recording is normally performed in the RIB, when a limited number of RI records is reached, RI recording is performed to the next RIB located thereafter. That is, when the number of RI records for the first RIB is limited to '10', even if the 10th RI recording is normally performed in the first RIB, the RI recording is performed in the second RIB.

In this case, the limited number of RI records may be different for each RIB. For example, as shown in FIG. 3, the first to fifth RIBs are in the first interval I ₁ , the sixth to tenth RIBs are in the second interval I ₂ , and the eleventh to 15th RIBs. Are divided into a third section I ₃ , and RIBs constituting the first section I ₁ have a RI record number of ten times, and RIBs constituting the second section I ₂ are RI records. RIBs constituting the third section I ₃ may be limited to 30 times, and the number of RIs may be limited to 30 times.

As shown in FIG. 3, when the number of RI recordings is limited for each section, the first section I ₁ is similar to the UD recording point and the media characteristics in which the UD rewrite is performed ten times, and the second section I ₂ is the UD. It can be inferred that the rewrite is similar to the UD recording point and the medium characteristic performed 20 times, and the third section I ₃ can be deduced that the UD rewriting is similar to the UD recording point and the medium characteristic performed 30 times.

Hereinafter, a process of optimizing the WS by performing the WS learning in the RIA in which the optical recording apparatus shown in FIG. 2 has similar characteristics to the UD recording point will be described in detail with reference to FIG. 4. 4 is a flowchart provided to explain a WS optimization method through performing WS learning in an RIA having similar characteristics of a UD recording point and a medium according to an embodiment of the present invention.

Referring to FIG. 4, first, the controller 180 stores the WS acquired through the WS learning performed in the TA of the optical disc D (S210). Specifically, in step S210, the controller 180 controls i) the PU driver 120 so that the PU 110 performs WS learning in the TA of the optical disc D, and ii) obtained through WS learning. The WS is stored in the memory 190.

Thereafter, the UDA state determination unit 160 determines the state of the UD recording point using the RIA analysis result (S220). In detail, in step S220, the UDA state determination unit 160 sets the UD of the UD recording point by using the 'information on the number of times of the UD rewriting of the UD recording point', which is output from the RIA analysis unit 150 as the RIA analysis result. Re-recording frequency can be determined.

Then, the WS learning area determiner 170 determines a partial area of the RIA as the WS learning area based on the determined state of the UD recording point (S230). Determining the WS learning area based on the state of the UD recording point means that the WS learning area is selected from the RIBs of the RIA, which are composed of RIBs having the most similar characteristics to the UD recording point.

For a detailed description of the step S230, it is assumed that the RIBs constituting the RIA of the optical disc D are limited in the number of RI recording times as shown in FIG. That is, the first to fifth RIBs constituting the first section I ₁ have an RI record number of ten times, and the sixth to tenth RIBs constituting the second section I ₂ have an RI record number. It is assumed that the 'twice' is the 20th, and the eleventh to fifteenth RIBs constituting the third section I ₃ are limited to the '30 times' of the RI recording times.

When the state of the UD recording point, that is, the number of UD rewrites of the UD recording point is 10 times, the first section I ₁ is the section where the UD recording point has the most similar media characteristics. Therefore, it is most preferable that the WS learning for the WS to be applied in recording the UD at the UD recording point is performed in the first interval I ₁ . Therefore, in step S230, the first section I ₁ is determined as the WS learning area.

Similarly, when the UD rewrite times of the UD recording point are 20 times, the section having the most similar media characteristics to the UD recording point is the second section I _{2. In} step S230, the second section I ₂ is the WS learning area. If the UD rewrite times of the UD recording point is 30 times, the section having the most similar media characteristics to the UD recording point is the third section I ₃ , and in step S230, the third section I ₃ is WS. It is determined by the learning area.

On the other hand, if there is no section having the RI record count that matches the UD rewrite count of the UD recording point, it is preferable to determine the section having the RI record count closest to the UD rewrite count as the WS learning area. For example, when the UD rewrite number of the UD recording point is 12 times, the first section I ₁ , which is a section having the RI record number ('10 times ') closest to '12 times', is determined as the WS learning area. will be.

After the step S230, the controller 180 stores the WS acquired through the WS learning performed in the WS learning area determined in step S230, so that the previously stored WS is updated (S240). Detailed description of the step S240, it can be inferred as a detailed description of the step S210, it will be omitted.

Next, the controller 180 causes the UD to be recorded according to the updated WS (S250). In detail, operation S250 may be performed by the controller 180 controlling a driving operation of the PU 110 of the PU driver 120 so that the UD is recorded according to the WS updated in the memory 190.

On the other hand, when the number of UD rewrites of the UD recording point is remarkably small (1-2 times), the section having the most similar media characteristics to the UD recording point is TA. Therefore, it is most preferable to perform the WS learning about the WS to be applied in recording the UD at the UD recording point in the TA. Therefore, in this case, by omitting step S240, it is of course possible to implement so that the UD is recorded according to the WS stored in step S210.

So far, the process of optimizing WS by performing WS learning in RIBs having similar UD recording points and media characteristics among RIBs constituting RIA has been described in detail.

In the present embodiment, it is assumed that the number of RI records is the same for every five RIBs, but this is merely an example for convenience of description, and the number may be different.

In addition, in the present embodiment, it is assumed that the number of RI records is limited to '10', '20', and '30', respectively, but this is just an example for convenience of explanation and the number of times Of course it can be different.

As described above, according to the present invention, WS optimization can be performed by performing WS learning in an RIA having similar characteristics of a UD recording point and a medium. As a result, it becomes possible to obtain an optimum WS for the UDA which has already been rewritten several times, and to record the UD according to the obtained optimal WS, thereby improving the recording quality of the optical disc. In addition, since the present invention can differently determine an area to perform WS learning according to the UD rewrite times of the UD recording points, it is possible to obtain an optimal WS in any case in the UD rewrite times of the UD recording points.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (12)

Determining a state of a recording point which is a point at which user data is to be recorded on the user data area of the rewritable optical disc; Determining a partial area of a recording information area, which is an area in which recording information, which is information on the user data, is recorded, as a WS learning area, which is an area to be used for WS (Write Strategy) learning, based on the determined recording point state; ; And WS learning is performed in the determined WS learning area, thereby obtaining a proper WS; WS optimization method comprising a. The method of claim 1, The determining step, Determine a media characteristic of the recording point, The determining step, And in the recording information area, a partial area having a medium property similar to the medium property of the determined recording point is determined as the WS learning area. The method of claim 1, The determining step, Determine the number of rewrites of the recording point, The determining step, And determining a partial area of the recording information area as the WS learning area based on the number of times of rewriting the determined recording point. The method of claim 3, wherein The determining step, And among the blocks constituting the recording information area, a section including blocks having recording information recording times close to the rewrite times of the determined recording points is determined as the WS learning area. The method of claim 4, wherein The determining step, If the number of rewrite times of the recording point is less than a predetermined number of times, the WS learning area is determined in advance, and a WS obtained by WS learning performed in a test recording area provided in the optical disc is determined as an appropriate WS. . The method of claim 4, wherein And limiting the number of times of recording information recording for the blocks constituting the recording information area to a predetermined number of times. A discriminating unit for determining a state of a recording point which is a point at which user data is to be recorded on the user data area of the rewritable optical disc; WS learning, which is a region to be used for WS (Write Strategy) learning, using a partial area of the recording information area, which is an area where recording information which is information on the user data is recorded, on the basis of the state of the recording point determined by the discriminating unit. Determining unit to determine the area; And And a controller configured to perform WS learning in the determined WS learning area, thereby obtaining a proper WS. The method of claim 7, wherein The determination unit, Determine a media characteristic of the recording point, The determining unit, And in the recording information area, a partial area having a medium property similar to the medium property of the recording point determined by the discriminating unit as the WS learning area. The method of claim 7, wherein The determination unit, Determine the number of rewrites of the recording point, The determining unit, And a partial area of the recording information area is determined as the WS learning area based on the number of times of rewriting of the recording point determined by the discriminating unit. The method of claim 9, The determining unit, Wherein, among the blocks constituting the recording information area, a section including blocks having recording information recording times close to the rewrite times of the recording points determined by the discriminating unit is determined as the WS learning area. Optical recording device. The method of claim 10, The determining unit, If the number of rewrite times of the recording point is less than a predetermined number of times, the WS learning area is determined in advance, and the WS obtained through the WS learning performed in the test recording area provided on the optical disc is determined as an appropriate WS. . The method of claim 10, The control unit, And the number of recording information recording times for the blocks constituting the recording information area is limited to a predetermined number of times.

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