KR100565796B1 - Optical-disk for data recording and optical recording apparatus - Google Patents

Abstract

An optical recording medium for recording data and an optical recording device capable of recording data are disclosed. Pits are formed periodically in the optical recording medium in the unrecorded state. At this time, the pit has the same size and is formed in plural periodically along the track direction, and the interval between two adjacent pit is the same as the length of the track direction of the pit. In addition, the pit preformed on the optical recording medium is modulated according to the power of light input from the optical recording device, thereby recording data on the optical recording medium. Therefore, according to the present invention, the preformed pit prevents the tracking offset generated during data recording in advance, thereby preventing the DC-offset generated during data reproduction.

Feet, grooves, land, record, optical record carrier

Description

Optical recording medium and data recording apparatus capable of recording data

1 is a diagram schematically showing a conventional optical recording medium in which data is not recorded;

2A and 2B are views for explaining an example of a pit formed in the groove of FIG. 1,

3 is a view showing a part of a recording / reproducing layer of an optical recording medium for data recording according to a preferred embodiment of the present invention;

4A and 4B illustrate an example of pits formed in an optical recording medium in which data of FIG. 3 is not recorded;

FIG. 5 is a block diagram schematically showing a part of an optical recording apparatus capable of recording data on the optical recording medium shown in FIG. 4; FIG.

6 is a view for explaining an embodiment in which recording target data is recorded on an optical recording medium in which one pit is formed continuously;

FIG. 7 is a view for explaining an embodiment in which recording target data is recorded on an optical recording medium having a plurality of pits preformed; and

8 is a flowchart for schematically describing a data recording method of FIG. 5.

Description of the main parts of the drawing

300: recording / playback layer 310: land

320 groove 330 feet

500: optical recording device 500a: optical recording medium

510: optical pickup 530: control unit

The present invention relates to an optical recording medium for recording data and an optical recording apparatus capable of recording data, and more particularly, to recording by a phase change after at least one pit is formed in advance in an optical recording medium in an unrecorded state. An optical recording medium for recording data, and an optical recording apparatus capable of recording data.

An optical recording apparatus is a device for recording predetermined data on an optical recording medium and reproducing the recorded data. The recording and reproducing of the data is performed according to the reflectance of light such as a laser beam. An example of an optical recording device may be a compact disk player (CDP) as a representative device, and examples of the optical recording medium may be a compact disk (CD), a video compact disk (VCD), or a digital video disk (DVD).

In this case, a plurality of lands 110 and grooves 120 are formed in a conventional optical recording medium on which data is not recorded, as shown in FIG. 1. The land 110 has a height similar to that of the surface of the optical recording medium, and the groove 120 is formed as a groove having a predetermined depth between the lands 110. When the data is to be recorded on such an optical recording medium, the optical recording apparatus records data by forming a plurality of pit of a predetermined size on the groove 120 or on the lands / grooves 110 and 120. At this time, the pit is preferably formed along the center of the groove 120, that is, the center of the track (shown in dashed lines) as shown in FIG. 2A.

However, when a pit is formed on a conventional optical recording medium by a predetermined recording method, for example, a DPP (Differential Push Pull) method, the pit is formed by a land (shown in dashed lines) from the center of the track as shown in FIG. 2B. It is formed by shifting in the direction (110). That is, when data is recorded on a conventional optical recording medium without pits, a tracking offset occurs on the track. Therefore, when reproducing the data recorded on the conventional optical recording medium, the conventional optical recording apparatus does not perform the tracking servo correctly, thereby degrading the reproduction capability of the optical recording apparatus.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an optical recording medium for recording data and an optical recording apparatus capable of recording data, which can prevent tracking offsets generated when data is recorded on the optical recording medium.

In the optical recording apparatus for recording the data to be recorded on the optical recording medium according to the present invention for solving the above technical problem, the light source is predetermined so that the size of the pre-formed feet on the optical recording medium is modulated by a phase change Irradiate power light. After determining the formation period of the pit, the control unit controls the light source to irradiate light having different power according to the determined period and the recording target data. As a result, the recording target data is recorded on the optical recording medium.

More specifically, the optical recording medium includes a plurality of grooves periodically formed along the track direction of the pit, and a plurality of lands formed between the plurality of grooves to distinguish tracks, and the control unit is configured to control the power of light. Accordingly, the size of the pit is modulated to process the data to be recorded on the groove.

Further, the pit is formed in the center of the groove along the track direction, and the controller controls light having power to erase a predetermined area within the pit and a predetermined area within the pit according to the recording target data. The light source is controlled to adaptively irradiate light having a power for maintaining the initial state.

Preferably, the pit has the same size and is periodically formed in the center of the groove, the interval between two adjacent pit is formed to be equal to the length of the track direction of the pit.

When recording the recording target data on the optical recording medium, the control unit compares and analyzes the period and the recording target data to light the power having a power for erasing a predetermined area within the corresponding pit among the plurality of pits. The light source is controlled to adaptively irradiate any one of light having power for maintaining an initial size of the pit, and light having power for forming a new pit in the groove area where the pit is not formed.

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

3 is a diagram showing a part of a recording / reproducing layer of an optical recording medium for data recording according to a preferred embodiment of the present invention.

First, the optical recording medium according to the present invention is a medium on which data is recorded, and has at least one recording / reproducing layer, for example, DVD-R, DVD-RW, DVD + RW, DVD-RAM, DVD-ROM, CD. -R, CD-RW, CD-ROM, and the like, but are not limited thereto. Here, R means data can be written only once, and ± RW and RAM means data can be written many times.

Referring to FIG. 3, a plurality of lands 310, a plurality of grooves 320, and at least one pit 330 are formed in the recording / reproducing layer 300 of the optical recording medium according to the present invention.

The plurality of lands have a height similar to the surface height of the optical recording medium, and are formed between the grooves 310 to be described later. This is to distinguish between tracks and tracks or grooves 310.

Pits 330 are periodically formed in the plurality of grooves 320 along the track direction. Pits 330 are arranged in grooves of a predetermined size along the centerline of the groove 320 (shown in dashed lines).

In detail, the pit 330 may be continuously formed along the center of the plurality of grooves 320 as shown in FIG. 4A. That is, one pit 330 is formed in one recording / reproducing layer 300. This is because a plurality of tracks are interconnected in a spiral structure in the optical recording medium 500a and are formed from the inner circumference to the outer circumference.

On the other hand, when there are at least two pit 330, each pit 330 is formed at the center of the groove 320 with the same size as shown in FIG. 4B. At this time, the distance between two adjacent pits 330 is preferably equal to the length d of the track direction of the pits 330. In addition, the size of the pit 330 formed in advance may have any one of 3T to 12T, but is not limited thereto.

Meanwhile, the pits 330 may be periodically formed along the track direction not only in the groove 320 but also in the plurality of lands 310 according to the recording / reproducing characteristic of the optical recording medium. The format of the pit 330 formed in the land 310 is the same as that of the groove 320 described above.

Here, examples of the optical recording medium having at least one pit 330 formed only in the groove 320 include DVD-R, DVD-RW, and DVD + RW, and at least in the groove 320 and the land 310. An example of an optical recording medium on which one pit 330 is formed is a DVD-RAM.

The optical recording medium according to the present invention has the advantage that the tracking offset does not occur by forming the pit 330 along the centerline of the groove 320.

FIG. 5 is a block diagram schematically illustrating a part of an optical recording apparatus capable of recording data on the optical recording medium of FIG. 4.

4 and 5, the optical recording apparatus 500 according to the present invention includes an optical pickup 510, a signal processor 520, and a controller 530.

First, the optical recording device 500 shown in FIG. 5 is a device for recording data on the optical recording medium 500a, and includes a compact disk player (CDP), a digital video disk player (DVDP), and a digital video disk recorder (DVDR). Etc. can be mentioned. 5 shows a block related to the recording of data in the optical recording device 500, and the illustration of the other blocks is omitted for convenience of description.

When the optical recording apparatus 500 is set to a recording mode, the optical recording apparatus 500 irradiates a laser beam to the recording / reproducing layer 300 to record data to be recorded by phase change. That is, the recording pit 330 is formed or erased by the phase change. In addition, in the reproducing mode, the optical recording apparatus 500 irradiates a laser beam to the optical recording medium 500a, receives a laser beam reflected from the recording / reproducing layer 300, and then passes the signal through a signal processing process. The reproduction target data recorded on the recording medium 500a is reproduced.

The optical pickup 510 includes a laser diode 511, a laser diode driver 512, a beam splitter 513, a collimating lens 514, and an object lens. 515 and a photo diode 516.

The laser diode 511 applied as the light source is driven by the laser diode driver 512 and irradiates a laser beam having a predetermined optical power.

The beam splitter 513 is a light splitter for changing the optical path of the laser beam irradiated from the laser diode 511.

The collimating lens 514 converts and outputs a laser beam having a predetermined radiation angle into parallel light.

The objective lens 515 causes the laser beam output from the collimating lens 514 to be focused on the track of the optical recording medium 500a. That is, the objective lens 515 performs focusing servo and tracking servo by a servo controller (not shown).

When the optical recording apparatus 500 is set to the reproduction mode, the laser beam reflected from the optical recording medium 500a is deflected by the beam splitter 513 in the direction of the photodiode 516. The photodiode 516 converts the deflected laser beam into a high frequency signal.

The signal processor 520 digitally processes a signal output from the optical pickup 510 as a digital signal processor (DSP) and outputs a digital video / audio signal.

The controller 530 controls the optical pickup 510 and the signal processor 520 to reproduce the reproduction target data recorded on the optical recording medium 500a. In addition, when the optical recording apparatus 500 is set to the recording mode, the controller 530 controls that the recording target data provided from the recording target data source source (not shown) is recorded / playback layer 300 of the optical recording medium 500a. The optical pickup 510 is controlled to be recorded in the control unit.

Hereinafter, when the optical recording apparatus 500 is set to the recording mode, a method of recording data to be recorded on the optical recording medium 500a according to the present invention will be described.

First, the optical recording medium 500a in an unrecorded state has at least one recording / reproducing layer 300 shown in FIG. In the case of the present invention, as shown in FIG. 4A, a case of recording data to be recorded by using an optical recording medium 500a in which one pit 330 is formed in a plurality of grooves 320 in advance. Explain to listen.

When the optical recording apparatus 500 is set to the recording mode, the optical pickup 510 performs the focusing servo under the control of the controller 530 and then uses the laser beam irradiated from the laser diode 511 to record the optical recording medium. The data to be recorded is recorded at 500a. At this time, since one pit 330 is already formed in the optical recording apparatus 500 along the track direction, the optical pickup 510 may omit the tracking servo. This is possible because the tracking offset does not occur even during data recording by the pre-formed pit 330.

To this end, the controller 530 determines the periodic pattern of the pit 330 formed on the optical recording medium 500a. The controller 530 controls the laser diode driver 512 to irradiate a laser beam having different power according to the determined periodic pattern and the recording target data.

In detail, the controller 530 analyzes the periodic pattern and the recording target data. According to the analysis result, the controller 530 includes at least one of a first control signal for maintaining a predetermined region of one pit 330 and a second control signal for erasing a predetermined region of one pit 330. Generate a write control signal.

In other words, the controller 530 determines which area of the pit 330 in which the recording target data is to be recorded corresponds to a pre-formed pit 330 and generates a recording control signal. Such a recording control signal is a pulse signal for controlling the power level of the laser beam, which may change the recording / reproducing layer 300. In addition, the pit 330 corresponding to the recording target data or the recording control signal is formed in various sizes by the power of the laser beam.

When the recording control signal is generated, the laser diode 511 irradiates a laser beam having a power corresponding to a predetermined section of the recording control signal. For example, if the input recording control signal is the second control signal, the laser diode 511 irradiates a ray point beam of approximately 40 power for a predetermined time. Here, it is preferable that the numerical value of power is not limited to this as an Example.

The beam splitter 513 deflects the irradiated laser beam of a predetermined power toward the objective lens 515. The objective lens 515 concentrates the laser beam on the center of the groove 320 of the optical recording medium 500a, that is, the track. In this way, recording of the data to be recorded is performed. At this time, as described above, no tracking offset is generated during data recording, so that the shift of the objective lens 515 for tracking servo does not occur. This allows the DC-offset to be prevented from occurring due to the light amount change caused by the shift of the objective lens 515 when the data recorded on the optical recording medium 500a according to the present invention is reproduced. .

At this time, the recording target data is recorded by the phase change. That is, one pit 330 formed in the groove 320 is erased according to the power of the laser beam, so that the optical recording medium 500a causes a phase change.

FIG. 6 is a diagram for explaining an embodiment in which recording target data is recorded on an optical recording medium in which one pit is formed continuously.

For example, as shown in Fig. 6A, when one pit 602 is formed continuously in the groove 610, and the data to be recorded should be recorded at 3T intervals, Same as

First, the controller 530 maintains the initial 3T pit area 604 to record the 3T recording target data, and the next 3T pit area (shown in dashed lines) a 'is erased by phase change. Next, the 3T pit area 606 is maintained, and the 3T pit area b 'is then generated to generate a write control signal. That is, when data is to be recorded at intervals of 3T on the pit 602 formed in advance, the recording control signal is composed of 'first control signal-> second control signal-> first control signal-> second control signal.

Then, the optical pickup 510 irradiates the optical recording medium 500a with a laser beam having a predetermined power according to the recording control signal. That is, the laser diode 511 is driven by the driving control of the laser diode driver 512 in the second power → 3T section corresponding to the second control signal during the first power → 3T section during the 3T section. During the first power → 3T period corresponding to the first control signal, the laser beam having the second power corresponding to the second control signal is sequentially irradiated. As a result, a plurality of pits 604 and 606 as shown in FIG. 6B are formed in the groove 610 of the optical recording medium 500a to record the data to be recorded.

Meanwhile, the optical recording apparatus 500 capable of recording data according to the present invention described above may also record data on the optical recording medium 500a in which a plurality of pits 330 are periodically formed, as shown in FIG. 4B.

When recording data to be recorded on the optical recording medium 500a as shown in FIG. 4B, the controller 530 may be configured to irradiate a laser beam having different power according to the periodic patterns of the plurality of pits 330 and the data to be recorded. The laser diode driver 512 is controlled.

In detail, the controller 530 analyzes the periodic pattern and the recording target data. The controller 530 may erase the third control signal and the predetermined area of the plurality of pits 330 to maintain a predetermined area among the plurality of pits 330 formed in the recording / reproducing layer 300 based on the analysis. A fourth control signal, a fifth control signal for maintaining the unformed area of the plurality of pit 330 of the groove 320, and a sixth control signal for generating a new pit in the unformed area of the pit 330. Generates a recording control signal including at least one of the following.

That is, the controller 530 determines whether the position where the recording target data is to be recorded corresponds to a predetermined area among the plurality of pre-formed pits 330 or whether the pits correspond to an unformed area of the groove 320. Then, the controller 530 generates a recording control signal for recording the data to be recorded on the optical recording medium 500a according to the determination result. This recording control signal is a pulse signal for adjusting the power level of the laser beam.

The optical pickup 510 irradiates the optical recording medium 500a with a laser beam having a predetermined power according to the recording control signal. At this time, the recording target data is recorded on the optical recording medium 500a by phase change. That is, a predetermined area of the plurality of pits 330 formed in the groove 320 is erased according to the power of the laser beam, or new pits are formed in the groove 320 so that the optical recording medium 500a causes a phase change.

FIG. 7 is a view for explaining an embodiment in which recording target data is recorded on an optical recording medium having a plurality of pits preformed.

For example, as shown in FIG. 7A, a plurality of pits 702, 704, and 706 having a size of 3T are formed in the groove 710 at intervals of 3T, and the input recording target data is 12T. Considering the case where it should be formed in the pit of, That is, the controller 530 keeps the first and second feet 702 and 704 in the pit area so as to record the 12T recording target data, and the first and second pit unformed areas (shown in dashed lines). (a, b) generates a pit by the phase change, and generates a write control signal that allows a part or all of the third feet 706 to also be erased by the phase change. That is, the recording control signal corresponding to 12T includes 'first control signal → fourth control signal → first control signal → fourth control signal → second control signal'.

Then, the laser diode 511 is driven by the driving control of the laser diode driver 512, and the fourth power → 3T section corresponding to the fourth control signal during the first power → 3T section during the 3T section. During the first power → 3T period corresponding to the first control signal, the laser beam having the second power corresponding to the second control signal during the fourth power → 3T period corresponding to the fourth control signal is sequentially irradiated. As a result, a pit 708 as shown in FIG. 7B is formed in the groove 710 of the optical recording medium 500a to record 12T recording target data.

8 is a flowchart for schematically describing a data recording method of FIG. 5.

3 to 8, at least one pit 330 in which recording target data is to be recorded is periodically formed in the groove 320 (S810). At this time, at least one pit 330 is formed along the track direction. When the optical recording apparatus 500 is set to the recording mode, the optical recording apparatus 500 irradiates a laser beam having a predetermined power to the pit 330 of the recording / reproducing layer 300 (S820).

When one pit 330 is formed in the groove 320 in step S810 as shown in FIG. 4A, the step S820 includes a laser beam having a first power for maintaining a predetermined area in the pit 330 in an initial state, and a pit ( A laser beam having a second power for erasing a predetermined area in 330 is adaptively irradiated according to the data to be recorded.

On the other hand, if a plurality of pit 330 is formed in the groove 320 in step S810 as shown in Figure 4b, step S820 is a first to maintain a predetermined area of the plurality of pit 330 formed in the recording / playback layer 300 A laser beam having three powers, a laser beam having a fourth power for erasing a predetermined area of the plurality of pits 330, and a fifth power for maintaining an area in which the plurality of pits 330 of the grooves 320 are not formed. And a laser beam having a sixth power for generating a new pit in an area where the pit 330 is unformed.

Therefore, the size of the pit 330 formed in step S810 is modulated by the laser beam irradiated in step S820 (S830). That is, the pit 330 is phase-changed by the irradiated laser beam, and a part of the pit 330 is erased, thereby recording data to be recorded (S840).

Meanwhile, when the optical recording medium 500a on which data is recorded is to be formatted and changed to an unrecorded state, the controller 530 may allow at least one pit 330 to be formed as illustrated in FIGS. 4A and 4B. Generate a write control signal. The laser diode driver 512 drives the laser diode 511 to irradiate the laser beam with power corresponding to the write control signal.

As a result, the optical recording medium 500a in which data is recorded is formatted into an initial state in which data is not recorded. That is, the pit 330 corresponding to the recording target data formed on the optical recording medium 500a is formed and / or erased by phase change so that the optical recording medium 500a is formatted in an initial state.

In addition, the optical recording apparatus 500 capable of recording data according to the present invention may record data on the optical recording medium 500a having at least one pit 330 formed not only in the groove 320 but also in the land 310. Of course it can.

As described so far, according to the optical recording medium for data recording and the optical recording apparatus capable of data recording according to the present invention, the optical recording medium having a predetermined period is formed in advance in the data recording by forming a pit having a predetermined period in the optical recording medium which is not in the data recording state. Tracking offset can be prevented in advance. In addition, when reproducing the recorded data, it is possible to prevent the DC-offset caused by the tracking offset from occurring.

In addition, since tracking offset does not occur during data recording, tracking servo can be omitted during data reproduction. Simplify. Therefore, the manufacturing cost of the optical pickup is also reduced, and the optical recording apparatus can be downsized.                     

Although the present invention has been described in detail through the representative embodiments, those skilled in the art to which the present invention pertains can make various modifications without departing from the scope of the present invention with respect to the embodiments described above. Will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

Claims (16)

A plurality of grooves in which pits are formed periodically along the track direction; And And a plurality of lands formed between the plurality of grooves for track division. The pit is continuously formed along the track direction in the center of the groove, The size of the pit is modulated according to the optical power input from the outside to record the data to be recorded. The light input from the outside is light having power for erasing a predetermined area within the pit, and light having power for keeping the predetermined area within the pit in an initial state according to the recording target data. Record carrier. delete The method of claim 1, And a plurality of pits having the same size and being periodically formed at the center of the groove, and an interval between two adjacent pits being formed to be equal to the length of the track direction of the pits. The method of claim 1, And the pits are formed on the land periodically along the track direction. An optical recording apparatus for recording data to be recorded on an optical recording medium, A light source for irradiating the optical recording medium with light having a predetermined power so that the size of the pit periodically formed on the optical recording medium is modulated by a phase change; And And a controller configured to control the light source to emit light having different power according to the determined period and the recording target data, and to control the recording data to be recorded after the formation period of the pit is determined. The pits are continuously formed along the track direction at the center of the groove of the optical recording medium, The controller controls the light source to adaptively irradiate light having power for erasing a predetermined area in the pit and light having power for maintaining a predetermined area in the pit in an initial state according to the recording target data. An optical recording device capable of recording data, characterized in that the control. The method of claim 5, The optical recording medium, A plurality of grooves in which the pit is formed periodically along the track direction; And Includes; a plurality of lands formed between a plurality of the grooves for track separation, And the control unit processes the pit size to be modulated according to the power of the light so that the recording target data is recorded on the groove. delete The method of claim 6, And the plurality of pits have the same size and are periodically formed in the center of the groove, and an interval between two adjacent pits is formed to be equal to the length of the track direction of the pits. The method of claim 8, When recording the recording target data on the optical recording medium, the control unit compares and analyzes the period and the recording target data to light the power having a power for erasing a predetermined area within the corresponding pit among the plurality of pits. And control the light source to irradiate at least one of light having power for maintaining an initial size of the pit, and light having power for forming a new pit in the groove area in which the pit is unformed, in a predetermined order. An optical recording device capable of recording data. The method of claim 6, And the pit is formed on a plurality of the lands periodically. An optical recording method for recording data to be recorded on an optical recording medium including a plurality of grooves and a plurality of lands, A step in which pits for recording data to be recorded are periodically formed in a plurality of grooves along the track direction; After determining the formation period of the pit, light having power for erasing a predetermined area within the pit and power for maintaining the predetermined area within the pit in an initial state according to the determined period and the recording target data. Adaptively irradiating light having; And And recording the data to be recorded by changing a predetermined area of the pit by the light to be irradiated. The method of claim 11, And wherein said forming step continuously forms said pit in the center of said groove along said track direction. delete The method of claim 11, In the forming step, a plurality of the pits having the same size are periodically formed at the center of the groove, and the distance between two adjacent pits is formed to be equal to the length of the track direction of the pits. How to record data. The method of claim 14, The irradiating step may include: light having power for erasing a predetermined area within the pit among the plurality of pits by comparing and analyzing the period and the recording target data, and light having power for maintaining the initial size of the plurality of pits. And light having at least one of light having power for forming a new pit in the groove area in which the pit is unformed, in a predetermined order. The method of claim 11, And said pit is further formed periodically in said land along said track direction.

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