Title of Invention

INFORMATION STORAGE MEDIUM AND METHOD AND APPARATUS FOR RECORDING/ REPRODUCING DATA ON/FROM THE SAME

Abstract An information storage medium on which data is recorded after performing optimum power control (OPC) and a method and apparatus to record/reproduce data on/from the information storage medium, wherein the recordable information storage medium has a plurality of recording layers and a pickup irradiates a beam onto the information storage medium, utilize operations of: recording data on at least a portion of a recording layer through which a test beam to find an optimum recording power passes before performing optimum power control (OPC) on a desired recording layer and performing OPC on the desired recording layer. The method and apparatus allow data to be recorded after performing a test to determine an optimum recording power, thus providing effective recording/reproducing quality.
Full Text FORM 2
THE PATENTS ACT, 1970
(39 of 1970)
&
THE PATENTS RULES, 2003
COMPLETE SPECIFICATION
(See section 10, rule 13)
INFORMATION STORAGE MEDIUM AND METHOD
AND APPARATUS FOR RECORDING REPRODUCING
DATA ON/FROM THE SAME
SAMSUNG ELECTRONICS CO., LTD., a Korean Corporation, of 416, Maetan-dong, Yeongtong-gu, Suwon-si, Gyeonggi-do 442-742, Republic of Korea
The following specification particularly describes the invention and the manner in which it is to be performed.

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Description
INFORMATION STORAGE MEDIUM AND METHOD AND
APPARATUS FOR RECORDING/REPRODUCING DATA ON/
FROM THE SAME
Technical Field
[1] The present invention relates to an information storage medium and a method and
apparatus to record/reproduce data on/from the information storage medium, and more particularly, to a method and apparatus to record/reproduce data on/from an information storage medium having a plurality of recording layers after performing optimum power control (OPC).
Background Art
[2] An optical pickup performs non-contact recording/reproducing to/from an in-
formation storage medium. Optical disks that are one type of information storage media are classified into compact disks (CDs) and digital versatile disks (DVDs) depending on data recording capacity. Examples of optical disks capable of writing and reading information include CD-Recordable (CD-R), CD- Rewritable (CD-RW), and 4.7GB DVD+RW. Furthermore, a high Definition-DVD (HD-DVD) or blu-ray disk (BD) with recording capacity of over 15 GB and a super-resolution optical disk that may read data recorded in a pattern of marks below the resolution limit are currently being developed. Disclosure of Invention
Technical Problem
[3] While only single layer 4.7 GB DVD-Recordable disks are commercially available,
dual layer 8.5 GB DVD-ROM disks are being sold in the market. To back up data recorded on the 8.5 GB DVD-ROM disk, a DVD recordable disk with the same capacity is required; Thus, to realize a need for a recordable disk having at least first and second recording layers, it is highly desirable to have techniques for maintaining the same recording/reproducing characteristics on a recordable information storage medium having a plurality of recording layers. One of the most important recording/ reproducing characteristics is called optimum power control (OPC).
Technical Solution
[4] The present invention provides a method and apparatus to record/reproduce data on
a recordable information storage medium having a plurality of recording layers after performing optimum power control (OPC) and an information storage medium to which data is written by the method.
[5] According to an aspect of the present invention, a method records/reproduces data

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PCT/KR2005/000587

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which data Is written by the method.
According to an aspect of the present invention, a method records/reproduces data on/from a recordable information storage medium having a plurality of recording layers using a pickup. The method includes recording data on at least a portion of a recording layer through which a test beam for finding the optimum recording power passes before performing optimum power control (OPC) on a desired recording layer and performing OPC on the desired recording layer. The portion of the recording layer corresponds to tracks contained in the test beam.
Where SL, TP, NA, and n denote the thickness of a spacer layer between the plurality of recording layers, a track pitch, a numerical aperture of an objective lens, and a refractive index of the information storage medium, respectively, a number of tracks is determined using the following equation:

Data may be recorded in an order of recording layers from closest to farthest from the pickup.
When the plurality of recording layers include first and second recording layers and the first recording layer is located closer to the pickup, data may be recorded on a portion of the first recording layer through which the test beam passes before performing OPC on the second recording layer.
At least one of jitter, asymmetry, degree of modulation, or reflectivity is recorded on each recording layer.
According to another aspect of the present Invention, an information storage medium comprises first and second recording layers, either containing a lead-in area, a user data area, and a lead-out area, wherein data is recorded from the first recording layer to the second recording layer. In the information storage medium, the first and second recording layers respectively include OPC areas. Data is recorded on the inner or outer circumference of the OPC area In the first recording layer, and OPC is performed on a region of the OPC area in the second recording layer disposed opposite the region on which data is recorded to determine an optimum recording power.
In another embodiment of the present invention, a recordable information storage medium comprises a plurality of recording layers, wherein OPC information is stored
SUBSTITUTE SHEET (RULE 26)


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includes a lead-in area, a user data area, and a lead-out area, and the OPC information is recorded on at least one of the lead-in area and the lead-out area. The lead-in area contains a read-only region and a recordable region, and the OPC information is recorded on the recordable region.
[12] According to another aspect of the present invention, an apparatus records/
reproduces data on/from a recordable information storage medium including a plurality of recording layers. The apparatus includes: a pickup irradiating a beam onto the information storage medium; a recording/reproducing signal processor receiving abeam reflected from the information storage medium through the pickup for signal processing; and a controller detecting whether data has been recorded on a portion of a recording layer through which a test beam to determine an optimum recording power passes and performs optimum power control (OPC) on a desired recording layer for recording through the pickup.
[13] In another embodiment, the present invention provides an apparatus to record/
reproduce data on/from a recordable information storage medium including a plurality of recording layers wherein the apparatus includes a pickup irradiating a beam onto the information storage medium, a recording/reproducing signal processor receiving a beam reflected from the information storage medium through the pickup for signal processing, and a controller to read information indicating whether data has been recorded on a portion of a recording layer through which a test beam to determine optimum recording power passes and performs optimum power control (OPC) on a desired recording layer to record through the pickup using the information.
[14] When data has not been recorded on the portion of the recording layer, a pickup is
controlled to record data on the portion of the recording layer through which the test beam passes to determine an optimum recording power to record on the desired recording layer. Information indicating that data has been recorded on the portion of the recording layer through which the test beam passes may be recorded on the information storage medium.
[15] The information storage medium contains information indicating optimum
recording power conditions that may be applied when data is recorded on the portion of the recording layer through which the test beam passes and when data is not recorded on the same. When the data is not recorded on the portion of the recording layer, OPC is performed using the optimum recording power conditions instead of separately recording the data to find the optimum recording power.
[16] Additional aspects and/or advantages of the invention will be set forth in part in the
description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.
Advantageous Effects

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[17] The present invention also provides an apparatus to record/reproduce data on the
information storage medium to perform a test on a desired recording layer to find (he
optimum recording power.
[ 18] The present invention also provides information on recording of data needed for
OPC so as to select recording conditions for OPC according to a type of a drive, thus
enabling more efficient OPC.
Description of Drawings
[19] These and/or other aspects and advantages of the invention will become apparent
and more readily appreciated from the following description of the embodiments, taken
in conjunction with the accompanying drawings of which:
[20] FIG. 1 illustrates a layout of a dual layer information storage medium to illustrate a
method to record/reproduce data on/from the information storage medium according to
an embodiment of the present invention;
[21] FIG. 2 is a schematic diagram of an apparatus to record/reproduce data on/from an
information storage medium according to an embodiment of the present invention;
[22] FIG. 3 illustrates a layout of an information storage medium according to an
embodiment of the present invention;
[23] FIG. 4 illustrates another layout of an information storage medium on which disk
related information has been recorded according to an embodiment of the present
invention;
[24] FIGs. 5 A and 5B are layouts illustrating a method to perform a test on an in-
formation storage medium according to an embodiment of the present invention to
determine an optimum recording power, and
[25] FIGs. 6A and 6B are flowcharts illustrating processes of performing OPC in a
method to record/reproduce data on/from an information storage medium according to
an embodiment of the present invention.
Mode for Invention
[26] Reference will now be made in detail to the embodiments of the present invention,
examples of which are illustrated in the accompanying drawings, wherein like
reference numerals refer to the like elements throughout The embodiments are
described below to explain the present invention by referring to the figures.
[27] A method to record/reproduce data on/from an information storage medium having
a plurality of recording layers according to an embodiment of the present invention
allows data to be prerecorded on a portion of another recording layer through which a
beam passes when irradiating a target recording layer with the beam to find the
optimum recording power.
[28] A recordable information storage medium performs optimum power control (OPC)


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prior to recording data to determine an optimal recording power. To perform OPC, data is written in an OPC area at a predetermined recording power and read back to test the reproducing characteristics. Once the optimum recording power has been found during the test, data is recorded at the optimum recording power during each recording session.
[29] When OPC is implemented in a recordable information storage medium having a
plurality of recording layers, recording/reproducing characteristics exhibited after performing OPC may vary from one recording layer to another, for example, depending on the recording sequence or recording power. Since these variations may lead to inaccuracy in OPC, it is necessary to detect conditions that may cause recording/reproducing characteristics to change depending on the state of each recording layer and perform OPC considering the conditions.
[30] To find conditions that affect the recording/reproducing characteristics, ex-
periments were made to write data on an information storage medium of FIG. 1, wherein the information storage medium has first and second recording layers LI and L2 in a different order and at different recording power levels.
[31] Recording conditions of the information storage medium are a linear velocity of
3.8 m/s, laser wavelength of 650 nm, and objective lens numerical aperture (NA) of 0.60. The information storage medium uses multipulse write strategies. While a recording power of 15.1 mW, Ttop of 1.45 T, Tmp of 0.65 T, and Tdtp 3T of -0.03T are used for the first recording layer LI, a recording power of 20mW, Ttop of 1.65T, Tmp of 0.70T, Tdtp 3T of -0.03T are used for the second recording layer L2. Ttop, Tmp, and Tdtp denote the duration of a top pulse, the duration of each pulse, and time shifted from a reference, respectively. Here, basic recording conditions are set as recording power and write strategy adjusted for minimum jitter by writing data only on a desired recording layer, and IT denotes 38.5 ns.
[32] Table 1 shows jitter, 13/114 modulations, asymmetries, and reflectivities measured
after writing data on the first and second recording layers LI and L2 under the above-mentioned conditions. A pickup is located closer to the first recording layer LI, and reference numeral 10 denotes an objective lens.
[33] Table 1
[34]


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Recording First recording layer (L1) Second recording layer (L2) Recording state
Jitter I3/I14 Asym. Reft. Jitter 13/114 Asym. Refl.
L1unrecorded, L2 recorded 7.9% 0.270 0.085 17.0% 8.1% 0.255 0.030 17.5% L1 unrecorded, L2 recorded
Recording L2 after recording LI 8.0% 0.250 0.093 16.8% 8.3% 0.240 0.023 18.9% Recording L1 after recording L2
Recording L1 after recording 12 8.1% 0.2B7 0.091 1B.5% B.B% 0.244 0.060 188% Recording L2 after recording LI
As is evident from Table 1, the first recording layer LI maintains almost the same values of jitter, 13/114, asymmetry (Asym.), and reflectivity (Refl.), regardless of the recording state or sequence while the second recording layer L2 exhibits varying characteristics depending on the recording sequence. That is, when data is written sequentially from the first recording layer LI to the second recording layer L2, the second recording layer L2 suffers from significant variations in jitter, asymmetry, and reflectivity. When data is written in the reverse order, the second recording layer L2 suffers from less variations in such characteristics.
[35] Table 2 shows recording/reproducing characteristics measured after data is written
at recording powers that are 120% and 150% of the normal power. During OPC, a test is performed at different recording power levels to determine an optimum recording power value. In particular, since the information storage medium once used for a predetermined period of time may require a recording power higher than a normal power due to surface contamination, it is necessary to perform the test at a higher power.
[36] Table 2
[37]
Recording state First recording layer (L1) Second recording layer L2) Recording state
Jitter 13/114 Asym. Refl. Jitter 13/114 Asym. Refl.
Recording L1 after recording L2(120%) 8.2% 0.259 0.087 16.3% 9.3% 0 250 0.052 18.8% Recording L2 after recording L1
Recording L1 after recording L2(150%) 3.2% 0.272 0 096 16.4% 9.8% 0.261 0.060 19.1% Recording L2 after recording L1






As is evident from Table 2, while the first recording layer LI exhibits almost the same recording/reproducing characteristics even at higher recording powers, the second recording layer L2 suffers from significant variations in reflectivity, asymmetry, and jitter when data is written sequentially on the first and second recording layers LI and


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L2. As compared with recording at a normal power, the jitter increases, but reflectivity and asymmetry remain almost constant.
[38] As may be seen in Tables 1 and 2 above, the first recording layer LI is little
affected by a recording sequence or a recording power, whereas the second recording layer L2 is significantly affected by the same. In particular, when data is written sequentially on the first and second recording layers LI and L2, the second recording layer L2 suffers from significant variations in the recording/reproducing characteristics. Such variations result from transmittance that may change, depending on whether a recording beam passes through a recorded or unrecorded portion of a recording layer. Low transmittance reduces the effect of the recording power.
[39] Meanwhile, it is necessary to perform a test under the conditions that cause
significant variations in recording/reproducing characteristics. That is, if there is insignificant change in the recording/reproducing characteristics under any conditions, it is possible to find the accurate optimum recording power without any special test conditions for determining the same. However, if the recording/reproducing characteristics vary according to the recording conditions, a test needs to be performed under, conditions that cause significant variations in the characteristics to determine the optimum recording power.
[40] Thus, when a test beam is emitted to find the optimum recording power, generally,
data has been written on at least a portion of a recording layer through which the test beam passes.
[41 ] Referring to FIG. 2, an information storage medium D includes a first recording
layer LI and L2, and a pickup 50 to record data is disposed below the first recording layer LI. Before a test beam is irradiated to perform OPC on the second recording layer L2, data is recorded on a portion of the first recording layer LI through which the test beam passes. In this case, data may be recorded in an area corresponding to tracks contained in the beam irradiated on the first recording layer LI.
[42] Referring to FIG. 1, the number of tracks contained in the portion of the first
recording layer irradiated by the test beam is given by Equation (1):
[43]
... (1)
where SL and TP denote the thickness of a space layer 15 between the first and second
information storage layers LI and L2 and a track pitch, respectively.
[44] Where n is a refractive index of the information storage medium and NA is a
numerical aperture of the objective lens 10, using the relational expression NA=nsin θ , Equation (1) is summarized as:

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layer L1. Before a test beam is irradiated to perform OPC on the second recording layer L2, data is recorded on a portion of the first recording layer L1 through which the test beam passes. In this case, data may be recorded in an area corresponding to tracks contained in the beam irradiated on the first recording layer L1.
Referring to FIG 1, the number of tracks contained in the portion of the first recording layer irradiated by the test beam is given by Equation (1):



where SL and TP denote the thickness of a space layer 15 between the first and second information storage layers L1 and L2 and a track pitch, respectively.
Where n is a refractive index of the information storage medium and NA is a numerical aperture of the objective lens 10, using the relational expression NA=nsinθ , Equation (1) is summarized as:


Data may be written on an area of the first recording layer L1 corresponding to the number of tracks defined by Equation (2) before irradiating a test beam for OPC onto the second recording layer L2.
Where SL tanθ =41.25(pm) and TP=0.7µm, the number of tracks contained in the test beam is about 112.
In the case of a DVD-ROM drive, a pickup Is disposed below a first recording layer and data is written from the first recording layer to the second recording layer. To maintain consistency with the DVD-ROM drive, the recordable information storage medium may be designed to allow data to be written from the first recording layer L1 to the second recording layer L2.
The same method to record/reproduce data according to an embodiment of the present invention may apply when the pickup is located above the second recording layer L2. In this case, data is first recorded on the second recording layer L2. Before performing OPC for recording on the first recording layer L1, data is recorded on at least a portion of the second recording layer L2 through which a test beam passes.
Furthermore, the method may be applied to both opposite track path (OTP) and
SUBSTITUTE SHEET (RULE 26)

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[53] When the material or the type of the information recording medium changes,
control information such as asymmetry, degree of modulation, and jitter may be recorded together. The control information may be recorded on either or both of the lead-in and lead-out areas 20 and 30.
[54] Alternatively, referring to FIG. 4, asymmetry information about first and second
recording layers each may be recorded on a different space in the control data zone. In this case, while the asymmetry information about the first recording layer is recorded along with information representing layer number, i.e, the first recording layer, the asymmetry information concerning the second recording layer is recorded along with information representing the second recording layer. The disk related information may be recorded in the same way on both the first and second recording layers.
[55] Referring to FIG. 5A, first and second recording layers L0and L1 respectively
include first and second OPC areas LO-23 and Ll-23. A region 21b of the first recording layer LO on which OPC is performed is not disposed opposite a region 22a of the second recording layer LI on which OPC is performed. When a beam is incident through the first recording layer L0, data is prerecorded on a region 21a disposed directly below the region 22a before performing OPC on the second recording layer LI.
[56] A region 22b of the second recording layer LI disposed opposite the region 21b of
the first recording layer L0 subjected to OPC may be allocated for a reserved area. For recording onto the region 21a of the first recording layer LO through which a beam to perform OPC on the second recording layer LI passes, a prerecording process may be performed during fabrication of a disk, or data may be recorded in a predefined manner on a predetermined region of the first recording layer LO prior to recording of user data.
[57] Referring to FIG. 5B, first and second recording layers LO and LI respectively
include first and second OPC areas LO-23 and Ll-23. While a region 21'a of the first recording layer LO where OPC is performed is positioned on the inner circumference of the first OPC area LO-23, a region 22'b of the second recording layer LI where OPC is performed is located on the outer circumference of the second OPC areas Ll-23.
[58] When a beam is incident through the first recording layer LO, data is prerecorded
on a region 211? disposed directly below the region 22'b before performing OPC on the second recording layer LI.
[59] A region 22'a of the second recording layer LI disposed opposite the region 21'a of
the first recording layer LO subjected to OPC may be a reserved area. The same recording mechanism may apply to the outer circumference of the information storage medium as well as the inner circumference.
[60] Referring to FIG. 6A, a method to perform OPC for each recording layer in an in-


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formation storage medium having a plurality of recording layers includes performing OPC on a recording layer from the lowermost recording layer upward when the information storage medium is inserted into a drive, and recording user data on the same recording layer subjected to OPC before performing OPC on an overlying recording layer. In this case, after recording on a first recording layer, OPC is performed on a second recording layer. However, since the method allows user data to be input continuously during OPC for the second recording layer, a memory or buffer is required to store a predetermined amount of data until OPC is finished.
[61] Referring to FIG. 6B, an alternative method to perform OPC for each recording
layer includes sequentially performing OPC on each recording layer when the information storage medium is inserted into the drive, and sequentially recording data on each recording layer. This method does not require a memory or buffer and is advantageous in continuously recording data without interruption.
[62] Referring to FIG. 2, an apparatus (i.e., a disk drive) to record/reproduce data on/
from the information storage medium D according to an embodiment of the present invention includes a pickup 50, a recording/reproducing signal processor 60, and a controller 70. More specifically, the pickup 50 includes a laser diode 51 that emits a beam, a collimating lens 52 that collimates the beam emitted by the laser diode 51 to a parallel beam, abeam splitter 54 that changes the propagation path of an incident beam, and an objective lens 56 that focuses the beam passing through the beam splitter 54 onto the information storage medium D.
[63] The beam reflected from the information storage medium D is reflected by the
beam splitter 54 and is incident on the photodetector 57 (e.g., a quadrant pho-todetector). The beam received by the photodetector 57 is converted into an electrical signal by an "operational circuit 58 and output as a RF or a sum signal through channel Chi and as a push-pull signal through a differential signal channel Ch2.
[64] Before recording data on the information storage medium D having the first and
second recording layers LI and L2, the controller 70 performs a test on a test area in the information storage medium D to determine the optimum recording power. To achieve this function, after recording data on die first recording layer LI, the controller 70 detects whether data has been written on a portion of me first recording layer LI irradiated by a test beam during an OPC test for the second recording layer L2 and controls the pickup 50 to record data on at least a portion of (he first recording layer LI through which the test beam passes before performing the test.
[65] During the OPC test, the controller 70 also reads control information such as re-
flectivity, jitter, degree of modulation, or asymmetry through the pickup 50 and determines the optimum recording power using the control information. Then, the controller 70 allows a recording beam to be irradiated from the pickup 50 at normal

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power obtained during the test, so that data can be recorded on the information storage medium D using the recording beam.
[66] To reproduce the thus recorded data, a beam reflected from the information storage
medium D passes through the objective lens 56 and the beam splitter 54, and is incident on the photodetector 57. The beam input to the photodetector 57 is then converted into an electrical signal by the operational circuit 58 and output as an RF signal.
[67] A drive according to another embodiment of the present invention may include
OPC information on an information storage medium. For example, the OPC information may contain information on an effect on the OPC due to whether data has been recorded on a portion of the information storage medium through which a beam passes during OPC. The drive having such information eliminates a need to prerecord data on an area of the information storage medium through which a beam passes during OPC.
[68] That is, in this embodiment, the drive having the OPC information does not require
data to be recorded on an adjacent recording layer of the information storage medium before OPC. Recording data on the information storage medium for OPC, even in a drive having OPC information, may increase data recording time and reduce an OPC area due to data recording.
[69] Thus, by providing predetermined information with a drive having OPC in-
formation, recording data on an adjacent recording layer for OPC is unnecessary. Therefore, by using the predetermined information, the drive may perform OPC accurately and quickly using embedded OPC information, even if data has not been written on a portion through which a beam for OPC passes.
[70] For example, let a drive possessing OPC information representing an effect on the
OPC due to whether data has been recorded on an area through which a beam for OPC passes be a drive A, let a drive having no such information be a drive B, and let the area irradiated with a beam for OPC be an area Y.
[71] To record data on die information storage medium, the drive A reads disk related
information before performing OPC. In this case, when information indicating that data has been written on the area Y through which a beam for OPC passes is not recorded on the information storage medium, the drive A performs OPC using its embedded OPC information without the need to record separate data on the area Y, thus saving time spent in recording data on the area Y. Conversely, when information indicating that data has been written on the area Y is recorded on a predetermined area of the information storage medium, the drive A performs OPC at recording power that is adjusted considering that data has been written on the area Y.
[72] To record data on the information storage medium, the drive B reads disk related

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information and information written on a recordable region before performing OPC. In this case, when information indicating that data has been written on the area Y is not recorded on the information storage medium, the drive B first records data on the area Y of the information storage medium before performing OPC. When performing OPC, the drive B irradiates the area Y with an OPC beam and then records information indicating that data has been written on the area Y on a recordable region (e.g., an information zone) in a lead-in area or a lead-out area.
[73] For example, to perform OPC on a second recording layer, information indicating
whether data has been written on the area Y of a first recording layer may be recorded as follows, using a byte X in the information zone:
[74] Byte X: 0000 0000(00h) -> Not recorded
[75] 0000 0001(01h)--> Recorded
[76] Meanwhile, information on whether OPC data has been written on inner or outer
circumference of the OPC areas L0-23 and Ll-23 as shown in FIGs. 5A and 5B may be recorded as follows, using X bytes:
[77] Byte X: 0000 0000(00h) -> Not recorded on inner and outer circumferences,
[78] 0000 0001 (0lh) --> Not recorded on inner circumference, recorded on outer cir-
cumference
[79] 0001 0000(1 Oh) --> Recorded on inner circumference, not recorded on outer cir-
cumference
[80] 0001 0001(1 lh) --> Recorded on inner and outer circumferences
[81] As described above, the first four bits of one byte represent information on the
inner circumference, and the following 4 bits represent information on the outer circumference. Alternatively, either information may be recorded using two bytes.
[82] Specifically, an information storage medium includes first and second recording
layers L0 and LI, and data is recorded from the first recording layer L0 to the second recording layer LI. A pickup may be located below the first recording layer L0. A drive may use information on whether data has been separately written on an area through which a test beam for OPC passes in performing OPC to record on the second recording layer LI. If the information for OPC has not been written to the area, the drive may perform OPC using its embedded OPC information instead of separately recording OPC data.
[83] The same method may be applied to a multi-layer information storage medium
having three or more recording layers. In this case, when a recording layer being subjected to OPC is irradiated with a test beam, information indicating whether data has been written on an area through which the test beam passes is recorded on a predetermined region of the information storage medium, and OPC is performed on the plurality of recording layers using the same information.

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[84] Here, an OPC test zone may be disposed in an area other than a user data area.
While FIGs. 3 and 4 illustrate that the lead-in area 20 contains the test zone, a test area may be positioned separately from lead-in and lead-out areas.
[85] Meanwhile, when information indicating that data has been written on the area Y is
recorded on a predetermined area of the information storage medium, the drive B performs OPC at recording power that is adjusted considering that data has been written on the area Y.
[86] A drive according to an embodiment of the present invention controls the pickup
50 to read information concerning whether data has been written for OPC and perform OPC in a manner specific to the drive.
[87] An information storage medium according to an embodiment of the present
invention contains information indicating whether data has been recorded on an area through which a beam for OPC passes, thus making recording of separate data for OPC optional according to the type of a drive. A drive possessing OPC information performs OPC without a need to record separate data, thus reducing the recording time and increasing the utilization efficiency of an OPC area.
[88] A method to record/reproduce data on/from the information storage medium
according to an embodiment of the present invention enables determining an optimum reading power to record/reproduce data to/from a recordable information storage medium having a plurality of recording layers. The method requires a test to find the optimum recording power for recording, thus achieving effective recording/reproducing characteristics. The present invention allows data to be recorded/reproduced in an order of recording layers from closest to farthest from a pickup, thus providing a recordable information storage medium capable of achieving consistency with a DVD-ROM.
[89] The present invention also provides an apparatus to record/reproduce data on the
information storage medium to perform a test on a desired recording layer to find the optimum recording power.
[90] The present invention also provides information on recording of data needed for
OPC so as to select recording conditions for OPC according to a type of a drive, thus enabling more efficient OPC.
[91] Although a few embodiments of the present invention have been shown and
described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

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15
Claims
[1] A method to record/reproduce data on/from a recordable information storage
medium having a plurality of recording layers using a pickup, the method
comprising:
recording the data on at least a portion of a recording layer through which a test
beam to find an optimum recording power passes; and
performing optimum power control (OPC) on a predetermined recording layer.
[2] The method of claim 1, wherein the portion of the recording layer corresponds to
tracks contained in the test beam.

wherein SL, TP, NP, and n denote a thickness of a spacer layer between each of
the plurality of recording layers and a next recording layer, a track pitch, a
numerical aperture of an objective lens, and a refractive index of the information
storage medium, respectively.
[3] The method of claim 1, wherein data is recorded in an order of recording layers
from closest to farthest from the pickup.
[4] The method of claim 1, wherein, after recording data on a recording layer located
closest to the pickup, OPC is performed on an overlying recording layer before
recording data on the overlying recording layer.
[5] The method of claim 1, wherein, before recording user data on the information
storage medium, OPC is performed on the plurality of recording layers.
[6] The method of claim 1, wherein, when the plurality of recording layers comprises
first and second recording layers, and the first recording layer is located closer to
the pickup than the second recording layer, the data is recorded on a portion of
the first recording layer through which the test beam passes before performing
OPC on the second recording layer.
[7] The method of claim 1, wherein control information to perform OPC is recorded
on at least one of a lead-in area and a lead-out area In the information storage
medium.
[8] The method of claim 7, wherein the control information includes at least one of
jitter, asymmetry, degree of modulation, or reflectivity.
SUBSTITUTE SHEET (RULE 26)

WO 2005/083686 16 PCT/KR2005/000587
[ 10] The method of claim 1 or 2, wherein information indicating that the data has
been written on the portion of the recording layer through which the test beam passes is recorded.
[11] An information storage medium on which the data is recorded by the method of
claim 1 or 2.
[12] An information storage medium on which the data is recorded by the method of
claim 4.
[13] An apparatus to record/reproduce data on/from a recordable information storage
medium that includes a plurality of recording layers, the apparatus comprising: a pickup irradiating a beam onto the information storage medium; a recording/reproducing signal processor receiving a beam reflected from the information storage medium through the pickup for signal processing; and a controller detecting whether data has been recorded on a portion of a recording layer through which a test beam to determine am optimum recording power passes and performs optimum power control (OPC) on a desired recording layer to record through the pickup.
[14] An information storage medium comprising first and second recording layers,
either of the first and second recording layers containing a lead-in area, a user data area, and a lead-out area, wherein data is recorded from the first recording layer to the second recording layer,
wherein the first and second recording layers respectively comprise OPC areas, and
wherein the data is recorded on the inner or outer circumference of the OPC area in the first recording layer and OPC is performed on a region of the OPC area in the second recording layer disposed opposite the region on which data is recorded to determine an optimum recording power.
[15] The information storage medium of claim 13, wherein the OPC area is positioned
separately from me lead-in area and the lead-out area.
[16] A recordable information storage medium comprising a plurality of recording
layers, having stored thereon OPC information indicating whether data has been written on a portion of a recording layer through which a test beam passes to determine an optimum recording power to record on a desired recording layer.
[17] The information storage medium of claim 16, wherein the recording layers have
an OPC area, and the OPC information includes information indicating whether the data has been written on an inner or an outer circumference of the OPC area through which the test beam passes.
[ 18] The information storage medium of claim 16 or 17, wherein each of the plurality
of recording layers comprises a lead-in area, a user data area, and a lead-out area,

WO 2005/083686 17 PCT/KR2005/000587
and the OPC information is recorded on at least one of the lead-in area and the lead-out area.
[19] The information storage medium of claim 18, wherein the lead-in area comprises
a read-only region and a recordable region, and the OPC information is recorded on the recordable region.
[20] An apparatus to record/reproduce data on/from a recordable information storage
medium that includes a plurality of recording layers, the apparatus comprising: a pickup irradiating a beam onto the information storage medium; a recording/reproducing signal processor receiving a beam reflected from the information storage medium through the pickup for signal processing; and a controller reading information indicating whether data has been recorded on a portion of a recording layer through which a test beam to determine an optimum recording power passes and performing optimum power control (OPC) on a desired recording layer to record through the pickup using the information.
[21] The apparatus of claim 20, wherein, when the data has not been recorded on the
portion of the recording layer, a pickup is controlled to record the data on the portion of the recording layer through which the test beam passes to determine the optimum recording power for recording on the desired recording layer.
[22] The apparatus of claim 20 or 21, wherein information indicating that the data has
been recorded on the portion of the recording layer through which the test beam passes is recorded on the information storage medium.
[23] The apparatus of claim 20 or 21, wherein the information storage medium
includes information on optimum recording power conditions to be applied when the data is recorded on the portion of the recording layer through which the test beam passes and when data is not recorded on the portion of the recording layer through which the test beam passes.
[24] The apparatus of claim 23, wherein, when the data is not recorded on the portion
of (he recording layer, OPC is performed using the optimum recording power conditions instead of separately recording the data to find the optimum recording power.
[25] A method to perform optimum power control (OPC) for each recording layer in
an information storage medium having a plurality of recording layers, the method comprising: reading control information;
performing OPC on a first recording layer of the plurality of recording layers; recording user data on the first recording layer,
performing, while the user data is input, OPC on a second recording layer disposed on the first recording layer, wherein the user data input while

18 PCT/KR2005/000587
WO 2005/083686
performing OPC on the second recording layer is stored in a memory or a buffer
until performing the OPC on the second recording layer is completed; and
recording the user data on the second recording layer.
[26] The method of claim 25, further including, during performing OPC on the first
recording layer and performing OPC on the second recording layer, reading
control information including at least one of reflectivity, jitter, degree of
modulation or asymmetry.
[27] An information storage medium on which the data is recorded by the method of
claim 2$ or 26.
[28] A method to perform optimum power control (OPC) for each recording layer in
an information storage medium having a plurality of recording layers, the
method comprising:
sequentially performing OPC on each recording layer when the information
storage medium is inserted into a drive; and
sequentially recording data on each recording layer.
[29] The method of claim 28, further including, during performing OPC on each
recording layer, reading control information including at least one of reflectivity,
jitter, degree of modulation or asymmetry.
[30] An information storage medium on which the data is recorded by the method of
claim 28.
[31] An apparatus to record/reproduce data on/from a recordable information storage
medium that includes a plurality of recording layers, the apparatus comprising:
a pickup irradiating a beam onto the information storage medium;
an optimum power control (OPC) controller performing OPC on a recording
layer from a lowermost recording layer upward when the beam is irradiated onto
the information storage medium;
a memory or buffer,
a recording/reproducing signal processor recording/reproducing the user data on
the recording layer subjected to OPC in the memory or the buffer,
wherein the OPC controller next performs OPC on an overlying recording layer
and records the user data input during OPC of the overlying recording layer, and
the memory or buffer is used to store the user data until OPC on the overlying
recording layer is completed.
[32] An apparatus to record/reproduce data on/from a recordable information storage
medium that includes a plurality of recording layers, the apparatus comprising:
a pickup irradiating a beam onto the information storage medium;
an optimum power control (OPC) controller sequentially performing OPC on
each recording layer when the beam is irradiated onto the information storage

WO 2005/083686 19 PCT/KR2005/000587
medium; and
a recording/reproducing signal processor sequentially recording/reproducing the
data on each recording layer.
[33] A disk drive having stored thereon predetermined optimum power control (OPC)
information with respect to an information storage medium to eliminate, prior to
performing OPC, prerecording data on an area of the information storage
medium through which a beam passes during OPC.
[34] An information storage medium having stored thereon information indicating
whether data has been recorded on an area through which a beam for optimum
power control (OPC) passes.
35. A method and an apparatus to record/reproduce data on/from a recordable information storage medium, substantially as herein described and illustrated with reference to the accompanying drawings.
36. A method to perform optimum power control (OPC) and a disk drive, having stored thereon predetermined optimum power control (OPC) information, substantially as herein described and illustrated with reference to the accompanying drawings.


Abstract
An information storage medium on which data is recorded after performing optimum power control (OPC) and a method and apparatus to record/reproduce data on/from the information storage medium, wherein the recordable information storage medium has a plurality of recording layers and a pickup irradiates a beam onto the information storage medium, utilize operations of: recording data on at least a portion of a recording layer through which a test beam to find an optimum recording power passes before performing optimum power control (OPC) on a desired recording layer and performing OPC on the desired recording layer. The method and apparatus allow data to be recorded after performing a test to determine an optimum recording power, thus providing effective recording/reproducing quality.
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Documents:

1320-mumnp-2005-abstract(22-09-2008).doc

1320-mumnp-2005-abstract(22-09-2008).pdf

1320-MUMNP-2005-ABSTRACT(GRANTED)-(15-10-2008).pdf

1320-mumnp-2005-abstract.doc

1320-mumnp-2005-abstract.pdf

1320-mumnp-2005-cancelled pages(22-09-2008).pdf

1320-MUMNP-2005-CANCELLED PAGES(22-9-2008).pdf

1320-MUMNP-2005-CLAIMS(GRANTED)-(15-10-2008).pdf

1320-mumnp-2005-claims(granted)-(22-09-2008).doc

1320-mumnp-2005-claims(granted)-(22-09-2008).pdf

1320-mumnp-2005-claims.doc

1320-mumnp-2005-claims.pdf

1320-mumnp-2005-correspondence(21-09-2009).pdf

1320-mumnp-2005-correspondence(ipo)-(06-10-2008).pdf

1320-MUMNP-2005-CORRESPONDENCE(IPO)-(23-1-2009).pdf

1320-mumnp-2005-correspondence-others.pdf

1320-mumnp-2005-correspondence-received-ver-201205.pdf

1320-mumnp-2005-correspondence-received.pdf

1320-mumnp-2005-description (complete).pdf

1320-MUMNP-2005-DESCRIPTION(GRANTED)-(15-10-2008).pdf

1320-mumnp-2005-drawing(22-09-2008).pdf

1320-MUMNP-2005-DRAWING(GRANTED)-(15-10-2008).pdf

1320-mumnp-2005-drawings.pdf

1320-mumnp-2005-form 1(22-09-2008).pdf

1320-mumnp-2005-form 1(24-11-2006).pdf

1320-mumnp-2005-form 18(31-07-2006).pdf

1320-MUMNP-2005-FORM 2(GRANTED)-(15-10-2008).pdf

1320-mumnp-2005-form 2(granted)-(22-09-2008).doc

1320-mumnp-2005-form 2(granted)-(22-09-2008).pdf

1320-MUMNP-2005-FORM 2(TITLE PAGE)-(28-11-2005).pdf

1320-MUMNP-2005-FORM 2(TITLE PAGE)-(GRANTED)-(15-10-2008).pdf

1320-mumnp-2005-form 26(10-04-2006).pdf

1320-mumnp-2005-form 26(31-03-2005).pdf

1320-MUMNP-2005-FORM 26(31-7-2006).pdf

1320-mumnp-2005-form 3(22-09-2008).pdf

1320-MUMNP-2005-FORM 3(22-9-2008).pdf

1320-mumnp-2005-form 3(24-11-2005).pdf

1320-mumnp-2005-form 3(28-04-2006).pdf

1320-MUMNP-2005-FORM 3(28-4-2006).pdf

1320-mumnp-2005-form 5(22-09-2008).pdf

1320-mumnp-2005-form-1.pdf

1320-mumnp-2005-form-2.doc

1320-mumnp-2005-form-2.pdf

1320-mumnp-2005-form-3.pdf

1320-mumnp-2005-form-5.pdf

1320-mumnp-2005-form-pct-ib-301.pdf

1320-mumnp-2005-form-pct-ib-304.pdf

1320-mumnp-2005-form-pct-ib-306.pdf

1320-mumnp-2005-form-pct-ib-307.pdf

1320-mumnp-2005-form-pct-ib-308.pdf

1320-mumnp-2005-form-pct-ib-311.pdf

1320-mumnp-2005-form-pct-isa-210(22-09-2008).pdf

1320-mumnp-2005-form-pct-isa-220.pdf

1320-mumnp-2005-form-pct-isa-237.pdf

1320-mumnp-2005-pct-search report.pdf

1320-mumnp-2005-petition under rule 137(22-09-2008).pdf

1320-MUMNP-2005-REPLY TO FIRST EXAMINATION REPORT(18-9-2008).pdf

1320-MUMNP-2005-REPLY TO FIRST EXAMINATION REPORT(23-9-2008).pdf

1320-MUMNP-2005-SPECIFICATION(AMENDED)-(22-9-2008).pdf

1320-MUMNP-2005-WO INTERNATIONAL PUBLICATION REPORT(28-11-2005).pdf

abstract1.jpg


Patent Number 224465
Indian Patent Application Number 1320/MUMNP/2005
PG Journal Number 02/2009
Publication Date 09-Jan-2009
Grant Date 15-Oct-2008
Date of Filing 28-Nov-2005
Name of Patentee SAMSUNG ELECTRONICS CO., LTD.
Applicant Address 416, Maetan-dong, Yeongtong-gu, Suwon-si, Gyeonggi-do 442-742
Inventors:
# Inventor's Name Inventor's Address
1 LEE KYUNG-GEUN 229-1006 Sibeomdanji Woosung Apt., Seohyun-dong, Bundang-gu, Seongnam-si, Gyeonggi-do 463-773
2 YONG-JINAHN 105-1401 Woosung Apt., 154-2, Yangjae-dong, Seocho-gu, Seoul 137-793 (KR).
3 WOOK-YEON HWANG 115 Daesim 2-ri, Yangseo-myeon, Yangpyeong-gun, Gyeonggi-do 476-822
PCT International Classification Number G11B7/004
PCT International Application Number PCT/KR2005/000587
PCT International Filing date 2005-03-03
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10-2004-0027575 2004-04-21 Republic of Korea
2 10-2004-0043333 2004-06-12 Republic of Korea
3 10-2004-0014378 2004-03-03 Republic of Korea