KR20090095790A - Optical information recording medium and method of servo control using the same - Google Patents

Abstract

An optical information storage medium and a servo control method using the same capable of position servo control are provided to reflect the servo light and increase the accuracy of reference beam which is income to the dark fringe. An optical information storage medium includes a recording layer(110), a dichroic mirror(130) and a reflective layer(150). The record layer, the reference beam and signal beam are crossed and a dark fringe is formed. The light information is recorded. The reflecting layer comprises the pattern which divides the servo light penetrating the dichroic mirror. The same pattern comprises a plurality of reflectors reflecting the servo light. The reflector is symmetrically arranged on the incidence plane of the servo light. The position servo control is performed by using the luminous intensity of the divided servo light which is reflected in the angle reflection board.

Description

Optical information recording medium and method of servo control using the same}

The present invention relates to an optical information storage medium and a servo control method using the same, and more particularly, to an optical information storage medium for recording and reproducing optical information on a storage medium using holography and a servo control method using the same.

Recently, with the rapid development of the information and computer industry, there is an increasing demand for a storage device capable of satisfying high capacity storage capacity and high speed input / output of data.

Therefore, it is an optical information storage medium capable of high-capacity storage and high-speed input / output of data using optical, and it is a compact disc (CD), a digital versatile disc (DVD), a high-definition DVD (HD-DVD), Blue-ray discs (BDs), holographic digital data storage (HDDS), and the like are in the spotlight.

Among these, an optical information processing apparatus (hereinafter, referred to as an 'optical information processing apparatus') using a holographic digital information storage device separates light emitted from a light source into a reference beam and a signal beam, and the reference beam The optical information is recorded by an interference fringe generated by intersecting the signal light with a storage medium of a photorefractive material such as a photopolymer.

In the optical information processing apparatus, a method of multiplexing light is used to increase the recording density of data. Methods of multiplexing light include angular multiplexing, phase-code multiplexing, wavelength multiplexing, and shift multiplexing. Here, the angular multiplexing method is to multiplex by changing the incident angle of the reference light, the phase code multiplexing is to multiplex by modulating the phase spatially, the wavelength multiplexing is to multiplex according to the wavelength change using a wavelength tunable laser, the shift multiplexing It is a method of multiplexing records while moving a storage medium.

In order to reproduce the optical information multiplexed and recorded on the optical information storage medium, the reference light incident upon optical information recording is restored, the reference light is incident on the interference pattern of the optical information storage medium, and the reproduced light is diffracted and reproduced from the interference pattern. Is detected, and optical information is acquired from this reproduced light.

As described above, in order to reproduce the optical information recorded in one interference fringe, the reference light incident upon the optical information recording must be precisely incident on the interference fringe, thereby requiring more accurate position servo control.

Accordingly, an object of the present invention is to provide an optical information storage medium and a servo control method using the same, which enable position servo control for precisely incidence of reference light incident upon optical information recording into an interference fringe.

An optical information storage medium according to an embodiment of the present invention is a recording layer in which the interference light is formed by crossing the reference light and the signal light, the optical layer is recorded; The optical layer is disposed on the side through which the light is incident, the reference light and the A dichroic mirror that reflects the signal light and transmits the servo light for servo control; and a dichroic mirror disposed at a position incident to the correct position of the interference fringe, and dividing the servo light that has passed through the dichroic mirror. And a reflective layer including a pattern to reflect.

The pattern may include a plurality of reflecting plates disposed at an incidence position of the servo light that has passed through the dichroic mirror to split and reflect the servo light to at least four or more.

The plurality of reflecting plates may be disposed symmetrically up, down, left, and right on the plane of incidence of the servo light.

On the other hand, the reference light and the signal light intersect to form an interference fringe to record the optical information, and is disposed on the side of the light incident through the recording layer, the reference light and the signal light is reflected and transmit the servo light for servo control A servo control method using an optical information storage medium having a dichroic mirror to be formed and a reflecting layer having a pattern for dividing and reflecting the servo light passing through the dichroic mirror. A servo control method using an optical information storage medium according to an example includes a servo light detection step of injecting the servo light into the recording layer and detecting the servo light partially reflected in the pattern through the dichroic mirror; Position servo made to position the interference fringe to the incident position of the servo light by using the light intensity of the servo light And a; step.

The pattern is disposed at an incidence position of the servo light passing through the dichroic mirror, and includes a plurality of reflecting plates divided into four. The detecting of the servo light comprises: detecting the servo light reflected by being divided into four by the reflection pattern. can do.

In the position servo control step, the optical information storage medium may be moved so that the servo light is incident to the side where the light intensity of the servo light detected by being divided into four is the same.

In the optical information storage medium and the servo control method using the optical information storage medium according to the present invention, since the servo light is divided and reflected, and the position servo control is performed using the light intensity of the divided servo light, the accuracy of the reference light incident on the interference fringe can be increased. It has an effect.

Hereinafter, an optical information processing apparatus using an optical information storage medium according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a part of an optical information processing apparatus using an optical information storage medium according to the present invention. Referring to FIG. 1, although not shown, the optical information processing apparatus 200 crosses the reference light R and the signal light S on the storage medium 100 to form an interference fringe 111, and the optical information storage medium. And a recording / reproducing optical system (not shown) for detecting the reproduction light P reproduced from the 100 (hereinafter referred to as “storage medium”). At this time, the reference light (R) and the signal light (S) may be used a green light (green beam) in response to the photosensitive medium.

The optical information processing apparatus 200 records the optical information by crossing the reference light R and the signal light S in the recording layer 110 (see FIG. 3) of the storage medium 100 made of the photosensitive medium. In this case, a data page divided into on pixels / off pixels is loaded in the signal light S. FIG.

In addition, the optical information processing apparatus 200 enters the reference light R used in recording the optical information to reproduce the optical information into the interference fringe 111, and detects the reproduction light P from the interference fringe 111. The optical information is reproduced.

Meanwhile, the optical information processing apparatus 200 performs servo control for adjusting the position of the storage medium 100 and the incident positions of the reference light R and the signal light S before recording and reproducing the optical information. Therefore, the optical information processing apparatus 200 transmits or reflects the servo light SV according to the polarization of the servo light source 210 for providing the servo light SV and the servo light SV provided from the servo light source 210. The polarized light splitter 230, the λ / 4 wave plate 250 for changing the polarization of the servo light SV reflected by the polarized light splitter 230 into circularly polarized light, and the servo light SV are provided in the optical information storage medium 100. A condenser lens 270 for condensing the light is provided. In this case, the servo light SV may preferably be a red beam having a wavelength that does not respond to the photosensitive medium.

The optical information processing apparatus 200 includes a servo light detector 290 so as to detect the servo light SV in a path of the servo light SV that is incident and reflected by the servo light SV to the storage medium 100. The servo light detector 290 may be configured as a photodiode capable of detecting the light intensity of the detected servo light (SV). The detection area of the servo light detector 290 is divided into at least four or more, and the detection area to be divided is preferably made up, down, left and right symmetrically.

The optical information processing apparatus 200 provides the servo light SV of P polarization from the servo light source 210. Servo light SV of P-polarized light is reflected by the polarized light splitter 230 and is changed into circularly polarized light while passing through the λ / 4 wave plate 250. The servo light SV, which is changed into circularly polarized light, is incident on the storage medium 100 by the condenser lens 270. Of the servo light incident on the storage medium 100, the servo light SV incident on each pattern included in the servo area 130 is reflected, and the servo light SV incident on the data area 110 is stored in the storage medium 100. Penetrates.

Servo light (SV) reflected in each pattern of the servo region 130 is changed from circular flat light to S polarized light while passing through the condenser lens 270 and the λ / 4 wave plate 250 and transmitted through the polarized light splitter 230. do. The servo light (SV) transmitted through the polarized light splitter 230 is detected by the servo light detector 290.

Hereinafter, an optical information storage medium according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a schematic view showing an optical information storage medium according to an embodiment of the present invention, and FIG. 3 is a partial cross-sectional view cut along the line II ′ of FIG. 2. 2 to 3, the storage medium 100 includes a recording layer 110, a dichroic mirror 130, and a reflective layer 150.

The recording layer 110 is formed of a photosensitive medium, and forms the interference pattern 111 as the reference light R and the signal light S cross each other. As described above, the recording layer 110 reacts to the reference light R and the signal light S, but does not respond to the servo light SV. Accordingly, the servo light SV may be incident to the dichroic mirror 130 without affecting the recording layer 110.

The dichroic mirror 130 transmits or reflects the incident light according to the wavelength of the light. At this time, the dichroic mirror 130 reflects the reference light R and the signal light S, and transmits the servo light SV.

The reflective layer 150 has a pattern for reflecting the servo light SV transmitted through the dichroic mirror 130. The pattern is disposed at an incidence position of the servo light SV transmitted through the dichroic mirror 130, and includes a plurality of reflecting plates 151 for dividing and reflecting the servo light SV into at least four or more.

The reflection plate 151 is provided on the incidence plane of the servo light SV symmetrically up, down, left and right, and is disposed at a position where the servo light SV is incident to the correct position of the interference fringe 111. Do. This causes the servo light SV to be incident to the correct position and the servo light SV reflected by the reflector 151 to be detected at the same light intensity in each detection area. Therefore, the position servo control can be performed by using the light intensity of the divided servo light SV reflected by each reflecting plate 151.

Here, the remaining portion of the reflective layer 150 except for the reflective plate 151 may be made of a material through which the servo light SV may pass. This is to prevent the servo light SV from entering the remaining portions except for the reflecting plate 151 and affecting optical information recording and reproduction.

The optical information storage medium 100 may further include a substrate 170 for protecting the recording layer 110 on the side where light is incident.

Hereinafter, a servo control method using an optical information storage medium according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

4 is a flowchart illustrating a servo control method using an optical information storage medium according to an embodiment of the present invention. Referring to FIG. 4, for position servo control, the servo light SV is incident to the storage medium 100. Servo light (SV) incident on the storage medium 100 passes through the recording layer 110 and enters the dichroic mirror 130. Servo light SV incident on the dichroic mirror 130 passes through the dichroic mirror 130 and is incident on the reflective layer 150.

Servo light SV incident to the reflective layer 150 is reflected by the plurality of reflecting plates 151. Servo light SVs reflected by the plurality of reflecting plates 151 are respectively detected in a detection area divided into at least four or more (step S11).

Here, in the above description, at least four reflector plates 151 are provided, and the plurality of reflector plates 151 are symmetrically formed up, down, left, and right. Hereinafter, for convenience of explanation and understanding, Four reflective plates 151 are provided, respectively, and will be described with an example of symmetry of up, down, left, and right.

5A to 5C are conceptual views illustrating the light intensity of servo light detected in a plurality of detection areas according to positions of servo light incident on a plurality of reflecting plates in the optical information storage medium according to an embodiment of the present invention.

Here, A is a detection area for detecting the servo light (SV) reflected by the reflecting plate 151 in the upper left, B is a detection area for detecting the servo light (SV) reflected by the reflecting plate 151 in the upper right, C is A detection area for detecting servo light (SV) reflected by the reflecting plate 151 at the lower left, and D represents a detection area for detecting servo light (SV) reflected by the reflecting plate 151 at the lower right.

Referring to FIG. 5A, when the servo light SV is incident to the correct position of the interference fringe 111, the servo light SV is incident to the center of the four reflecting plates 151 to detect the detection areas A, B, C, and D. It can be seen that each detected with the same light intensity.

Referring to FIG. 5B, when the servo light SV is incident to the right side of the interference fringe 111, the servo light SV is incident to the right of the four reflecting plates 151 and is detected in the detection areas A and B. It can be seen that the light intensity of the servo light SV is greater than the light intensity of the servo light SV detected in the detection areas C and D.

At this time, the position error signal for position servo control of the incident position of the servo light SV may be calculated by Equation 1 below.

Equation 1)

PE1 = (Ya + Yc)-(Yb + Yd)

Where PE1 is a position error signal in the horizontal direction, Ya is the light intensity of the servo light SV detected in the detection area A, Yb is the light intensity of the servo light SV detected in the detection area B, and Yc is the detection It is the light intensity of the servo light SV detected in the area C, and Yd is the light intensity of the servo light SV detected in the detection area d.

According to the position error signal calculated by Equation (1), the difference between the sum of the light intensities of the servo light SVs reflected and detected on the left side and the sum of the light intensity of the servo light SVs reflected and detected on the right side is “0”. Position servo control may be performed by moving the storage medium 100 to a position calculated as ", or by moving the incident position of the reference light R.

Referring to FIG. 5C, when the servo light SV is incident to the lower side of the interference fringe 111, the servo light SV is incident to the lower side of the four reflecting plates 151 and is detected in the detection areas C and D. It can be seen that the light intensity of the servo light is greater than the light intensity of the servo light detected in the detection areas A and B. FIG.

At this time, the position error signal for position servo control of the incident position of the servo light SV may be calculated by Equation 2 below.

Equation 2)

PE2 = (Ya + Yb)-(Yc + Yd)

Where PE2 is the position error signal in the vertical direction, Ya is the light intensity of the servo light SV detected in the detection area A, Yb is the light intensity of the servo light SV detected in the detection area B, and Yc is the detection It is the light intensity of the servo light SV detected in the area C, and Yd is the light intensity of the servo light SV detected in the detection area D.

According to the position error signal calculated by Equation (2), the difference between the sum of the light intensities of the servo light SVs reflected and detected from the upper side and the sum of the light intensity of the servo light SVs reflected and detected from the lower side is "0." Position servo control may be performed by moving the storage medium 100 to a position calculated as ", or by moving the incident position of the reference light R (step S13).

Here, in the above description, it is described that four reflectors 151 are provided, but this is merely an example for convenience of description and understanding, and does not limit the number of reflectors 151. Therefore, if the reflector plate 151 is provided with four or more numbers at positions where the servo light SV is incident on the interference fringe 111 and is symmetrically up, down, left, and right, its configuration and operation may be similar. will be.

1 is a block diagram showing a part of an optical information processing apparatus using an optical information storage medium according to the present invention.

2 is a simplified diagram showing an optical information storage medium according to an embodiment of the present invention.

FIG. 3 is a partial cross-sectional view taken along the line II ′ of FIG. 2.

4 is a flowchart illustrating a servo control method using an optical information storage medium according to an embodiment of the present invention.

5A to 5C are conceptual views illustrating the light distribution of servo light reflected and detected from an optical information storage medium according to an embodiment of the present invention.

<Description of Signs of Major Parts of Drawings>

100: optical information storage medium 110: recording layer

130: dichroic mirror 150: reflective layer

151: reflector 290: servo light detector

Claims (6)

A recording layer in which an interference fringe is formed by crossing the reference light and the signal light so that optical information is recorded; A dichroic mirror disposed on a side where light enters through the recording layer, and reflects the reference light and the signal light and transmits servo light for servo control; and And a reflecting layer disposed at a position incident to the interference fringe and having a pattern for dividing and reflecting the servo light passing through the dichroic mirror. The method of claim 1, wherein the pattern is, And a plurality of reflecting plates arranged at an incidence position of the servo light passing through the dichroic mirror, for reflecting at least four or more of the servo lights. The method of claim 2, wherein the plurality of the reflecting plate, Optical information storage medium, characterized in that arranged on the plane of incidence of the servo light up, down, left, right symmetry. A dike that intersects the reference light and the signal light to form an interference fringe, and is disposed on the recording layer on which optical information is recorded, and on the side where the light passes through the recording layer, and reflects the reference light and the signal light and transmits the servo light for servo control. A servo control method using a optical information storage medium having a dichroic mirror and a reflective layer having a pattern for dividing and reflecting the servo light passing through the dichroic mirror, the method comprising: A servo light detection step of injecting the servo light into the recording layer and detecting the servo light partially reflected in the pattern through the dichroic mirror; And a position servo control step of positioning the interference fringe at the incident position of the servo light by using the light intensity of the servo light, which is detected by division. 2. The method of claim 4, wherein The pattern is disposed at the incidence position of the servo light transmitted through the dichroic mirror, and has a plurality of reflecting plates divided into four, The servo light detection step, The servo control method using the optical information storage medium, characterized in that for detecting the servo light is divided into four reflection by the reflection pattern. The method of claim 5, wherein the position servo control step, And moving the optical information storage medium such that the servo light is incident on the side where the light intensity of the servo light is detected by being divided into four.

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