KR100682137B1 - Reference beam focus servo device of the holographic rom disk - Google Patents

Abstract

The present invention relates to a reference light focus servo device of a holographic ROM disk, and in particular, the apparatus of the present invention transmits a beam splitter that reflects reference light and transmits the light reproduced from the disk as it is, and a reference light transmitted from the beam splitter to the disk. An objective lens for transmitting the reproduced light from the disk to the beam splitter, wherein the objective lens has a thin lens thickness and the reproduced light transmits a thick lens, a light detector for detecting the reproduced light transmitted through the beam splitter, and an objective lens An actuator for adjusting a position and a servo controller for comparing the detected data with the data detected by the light detector and the set data and driving the actuator to perform focus servo control of the objective lens when the two data are not the same. Therefore, according to the present invention, by varying the objective lens thickness of the portion through which the reference light and the reproduction light are transmitted, the reference light can be accurately focused and incident on the surface of the disc or the recording material layer within the disc, thereby accurately reproducing the holographic data and thus holographic. It is easy to perform focus servo control of the ROM disk.

Holographic ROM, Reference Light, Focus Servo, Objective Lens

Description

REFERENCE BEAM FOCUS SERVO DEVICE OF THE HOLOGRAPHIC ROM DISK}

1 is a block diagram showing a reference light focus servo device of a holographic ROM disk according to the prior art;

2 is a view for explaining a focus between an objective lens and a disk in a reference light focus servo device of a holographic ROM disk according to the prior art and incident reference light;

3 is a block diagram showing a reference light focus servo device of a holographic ROM disk according to the present invention;

4 is a view showing an objective lens in a reference light focus servo device of a holographic ROM disk according to the present invention;

5 is a view for explaining the focus and incident reference light between the objective lens and the disk in the reference light focus servo device of the holographic ROM disk according to the present invention;

<Description of the symbols for the main parts of the drawings>

100: light source 102: polarizer

104: beam splitter 106: plate

108: objective lens 112: slit

114: condenser lens 116: light detector (PDIC)

118: servo control unit 120: actuator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a servo device of a holographic ROM (HROM) disk, and more particularly, to a holo capable of performing focus servo control of a reference light incident on a surface of a disk upon reproduction of data recorded on a holographic disk. A reference light focus servo device for a graphics ROM disk.

As the information industry develops, a large capacity of a device for storing information and a high speed of processing are required. As a result, the holographic ROM, which is widely known for recording and reproducing holographic digital data, can store a large amount of information in one bit of an optical disc such as a CD or a DVD, and process the stored data in one bit unit. Speed is fast Because of these advantages, holographic ROMs are in the spotlight as the next generation of mass information storage.

On the other hand, the servo operation in the holographic ROM reproducing apparatus is different from an optical disc reproducing apparatus such as a general CD or DVD. That is, in the optical disk reproducing apparatus, the light is focused to have a track size, and the light reflected from the data pit is detected. In the holographic ROM reproducing apparatus, the reference light is irradiated onto the optical disk and diffracted from the optical disk. Is detected through a pin hole of a slit. At this time, the size of the reference light is much larger than the size of the data track, and since the pinhole size of the slit has a track pitch size, a specific track is caused by run-out in the radial direction or the optical axis direction generated as the optical disk rotates. The light reproduced from the data pit of the slit is difficult to enter correctly into the pinhole of the slit. Therefore, it is the servo operation in the holographic ROM reproducing apparatus that detects the light passing through the pinhole and adjusts the light to pass correctly into the pinhole according to the detected data. Therefore, the tracking servo in the holographic ROM reproducing apparatus adjusts the position of the radial direction of the light so that the focused light is accurately positioned in the data track, and the focus servo is the reflection surface of the disk to focus the light. It is to adjust the focus position of the light in the direction of the optical axis so that it is exactly positioned at.

1 is a block diagram showing a reference light focus servo device of a holographic ROM disk according to the prior art. Referring to FIG. 1, a reference light focus servo apparatus of a conventional holographic ROM disk includes a light source 100, a polarizer 102, a polarization beam splitter (PBS) 104, and a λ / 4 plate. (WP: Wave Plate) 106, objective lens 108, imaging lens 110, slit 112, condenser lens 114, and photodetector (PDIC: Photo Detect IC) 116 And a servo control unit 118 and an actuator 120. Unexplained reference numeral 1 denotes a holographic ROM disk.

The polarizer 102 polarizes the reference light S1 generated from the light source 100 to S polarized light, and the beam splitter PBS 104 reflects the S polarized light and transmits P polarized light as it is. The λ / 4 plate 106 transforms the S-polarized light incident from the beam splitter (PBS) 104 into circularly polarized light and transforms the circularly polarized light transmitted from the disk 1 through the objective lens 108 into P-polarized light. . The objective lens 108 enters the circularly polarized light of the reference light transformed by the λ / 4 plate 106 into the disk 1, and transmits the circularly polarized light of the light S2 reproduced from the disk 1 into the λ / 4 plate ( To 106). The slit 112 passes only through the pinhole the regenerated light having a diameter of 1 bit from the P-polarized light transmitted through the beam splitter (PBS) 104 through the imaging lens 110 through the condenser lens 114 through the light detection unit (PDIC) Forward to 116. The photodetector (PDIC) 116 is composed of at least two divided optical sensors to detect P polarized light incident through the pinhole of the slit 112, and the servo controller 118 is configured by the photodetector (PDIC) 116. The actuator 120 is driven according to the detected data to perform focus servo control. The actuator 120 adjusts the focus distance between the disc 1 and the objective lens 108 under the control of the servo controller 118.

The reference light focus servo device of the conventional holographic ROM disk configured as described above operates as follows.

The laser light generated by the light source 100 is polarized as S-polarized light in the polarizer 102 as the reference light S1, and the polarized S-polarized light is incident on the beam splitter (PBS) 104. S-polarized light of the reference light S1 incident on the beam splitter PBS 104 is reflected and incident on the λ / 4 plate 106. At this time, the S-polarized light is not incident on the mirror center of the beam splitter (PBS) 104 but is incident on the mirror outer portion. The S-polarized light of the reference light S1 incident on the λ / 4 plate 106 is deformed into circularly polarized light and is incident on the disk 1 through the objective lens 108. At this time, the reference light S1 incident on the disk 1 has the same incident angle lambda as at the time of recording.

Data recorded on the recording material layer of the disc 1 by circularly polarized light of the reference light S1 is reproduced and transferred to the λ / 4 plate 106 through the objective lens 108. The circularly polarized light of the reproduction light S2 incident on the λ / 4 plate 106 is converted into P-polarized light and transmitted to the beam splitter (PBS) 104. The P-polarized light of the regenerated light S2 incident on the beam splitter PBS 104 is transmitted as it is and transmitted to the imaging lens 110. At this time, the P-polarized light of the reproduction light S2 is transmitted through the mirror center of the beam splitter PBS 104. P-polarized light of the regenerated light S2 passing through the imaging lens 110 passes only light of 1 bit diameter through the pinhole of the slit 112 and is transmitted to the photodetector (PDIC) 116 through the condenser lens 114. .

The photodetector (PDIC) 116 transmits light quantity data detected by each of the at least two divided optical sensors to the servo controller 118, and the servo controller 118 is detected by the photodetector (PDIC) 116. When the amount of light data is compared with the set data and the detected data is the same as the set data, the focus servo is determined to be normal and the focus servo control of the actuator 120 of the objective lens 108 is not performed.

However, if the data detected by the photodetector (PDIC) 116 is not the same as the set data and there is a difference, the servo controller 118 determines the focus servo to be abnormal and focuses the actuator 120 of the objective lens 108. Perform servo control. Accordingly, the focal length between the objective lens 108 and the disk 1 is adjusted by driving the actuator 120. In this case, the reference light is also incident on the disk 1 through the objective lens 108. It is adjusted automatically.

FIG. 2 is a view for explaining a focus between an objective lens and a disk in a reference light focus servo device of a holographic ROM disk according to the related art and incident reference light.

As shown in FIG. 2, the reference light focus servo apparatus of a conventional holographic ROM disk has a focal point f1 of the light S2 reproduced by the reference light S1 incident on the disk 1 formed on the disk 1. Rather, it is formed at a position slightly away from the disk 1 between the disk 1 and the objective lens 108. The reason is that when recording the holographic data on the disc 1, the hol flies to record the holographic data by causing interference of the light at a certain distance between the disc and the mask, so that the focal point f1 of the reproduction light S1 is set to the disc 1 and the mask. It is formed at a position separated by the interval between.

However, since the reference light S1 is also incident on the disk 1 through the objective lens 108, its focus also coincides with the focus f1 of the reproduction light S2. Thus, the reference light S1 is the disk 1 The holographic data cannot be reproduced accurately unless it is accurately incident on the recording material layer, and it is difficult to control the focus servo of the holographic ROM disk.

In order to solve the problems of the prior art as described above, the center portion of the lens through which the reproduction light is transmitted is thick, and the outer portion of the lens through which the reference light is transmitted is provided with a thin objective lens so that the reference light is accurately focused on the disk. To provide a reference light focus servo device of a holographic ROM disk capable of accurately reproducing holographic data.

An apparatus of the present invention for achieving the above object is a device for controlling the focus to the disk by the light reproduced from the holographic ROM disk to the reference light, reflecting the reference light and transmits the light reproduced from the disk as it is And a beam splitter for transmitting the reference light transmitted from the beam splitter to the disk and transmitting the light reproduced from the disk to the beam splitter, wherein the lens outer thickness through which the reference light is transmitted is thin and the reproduction light is transmitted. A thick objective lens, a light detector for detecting reproduction light transmitted through the beam splitter, an actuator to adjust the position of the objective lens, and light quantity data detected by the light detector and data set by comparing the two data If is not the same by driving the actuator And a servo control unit for performing a focus servo control of the objective lens.

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

3 is a block diagram illustrating a reference light focus servo device of a holographic ROM disk according to the present invention.

Referring to FIG. 3, a reference light focus servo apparatus of a holographic ROM disk according to the present invention includes a light source 200, a polarizer 202, a beam splitter (PBS) 204, and a λ / 4 plate (WP) ( 206, the objective lens 208 having a thin lens thickness through which the reference light S1 is transmitted and the lens thickness through which the reproduction light S2 is transmitted, the imaging lens 210, the slit 212, and the condenser lens ( 214, a photodetector (PDIC) 216, a servo controller 218, and an actuator 220. Unexplained reference numeral 1 denotes a holographic ROM disk.

The polarizer 202 polarizes the reference light S1 generated from the light source 200 to the S polarized light, and the beam splitter PBS 204 reflects the S polarized light and transmits the P polarized light as it is. Polarization is reflected through the outer portion of the beam splitter mirror, and circularly polarized light of the reproduction light S2 is transmitted through the central portion of the beam splitter mirror.

The λ / 4 plate 206 transforms the S-polarized light incident from the beam splitter (PBS) 204 into circularly polarized light and transforms the circularly polarized light transmitted from the disk 1 through the objective lens 208 into P-polarized light. .

3 and 4, the objective lens 208 has a thick thickness at the center of the lens 208a through which the reproduction light S2 is transmitted and a thin thickness around the lens outer 208b through which the reference light S1 is transmitted. Is done. Accordingly, the circularly polarized light of the reference light S1 deformed in the λ / 4 plate 206 is transmitted through the thin lens outer portion 208b of the objective lens 208 to be incident on the disk 1, whereby the lens center 208a By the lens thickness thinner than), the focus of the reference light S1 is formed on the disk 1. The circularly polarized light of the light S2 reproduced from the disk 1 is transmitted through the thick lens center 208a portion of the objective lens 208 and transmitted to the λ / 4 plate 206. At this time, since the thickness of the center portion of the lens 208a is made of the same lens thickness as before, the focus of the reproduction light S2 is formed on the disk 1 between the objective lens 208 and the disk 1.

The slit 212 passes only the regenerated light having a diameter of 1 bit from the P-polarized light transmitted through the image splitting lens 210 through the beam splitter (PBS) 204 through the pinhole, and passes through the condensing lens 214 through the light detecting unit PDIC. Forward to 216.

The photo detector (PDIC) 216 is configured by at least two or more divided optical sensors to detect P-polarized light incident through the pinhole of the slit 212.

The servo controller 218 drives the actuator 220 according to the data detected by the photodetector (PDIC) 216 to perform focus servo control. The actuator 220 adjusts the focus distance between the disk 1 and the objective lens 208 under the control of the servo controller 218.

The reference light focus servo device of the holographic ROM disk according to the present invention configured as described above operates as follows.

The laser light generated by the light source 200 is polarized to S-polarized light in the polarizer 202 as the reference light S1, and the polarized S-polarized light is incident on the beam splitter (PBS) 204. S-polarized light of the reference light S1 incident on the beam splitter (PBS) 204 is reflected and incident on the λ / 4 plate 206. At this time, the S-polarized light is not incident on the mirror center of the beam splitter (PBS) 204 but is incident on the mirror outer portion.

The S-polarized light of the reference light S1 incident on the λ / 4 plate 206 is transformed into circularly polarized light and is incident on the disk 1 through the thin lens outer portion 208b of the objective lens 208. At this time, the reference light S1 incident on the disk 1 has the same angle of incidence λ as recorded, and the focus of the reference light S1 is formed on the surface or inside of the disk 1 by the thin lens thickness of the outer portion 208b. do.

The data recorded in the recording material layer of the disk 1 is reproduced by the circularly polarized light of the reference light S1 focused on the disk 1 and transmitted through the objective lens 208, where the objective lens 208 The circularly polarized light of the light S2 reproduced from the disk 1 is transmitted to the λ / 4 plate 206 through the thick lens center 208a portion. At this time, since the thickness of the center portion of the lens 208a is the same as the conventional lens thickness, the focus of the reproduction light S2 is between the objective lens 208 and the disk 1 according to the distance between the mask and the disk during recording. It forms on the disk 1.

The circularly polarized light of the reproduction light S2 incident on the λ / 4 plate 206 is converted into P polarization and transmitted to the beam splitter (PBS) 204, and the reproduction light incident on the beam splitter (PBS) 204 ( The P-polarized light of S2) is transmitted as it is and transmitted to the imaging lens 210. At this time, the P-polarized light of the reproduction light S2 is transmitted through the mirror center of the beam splitter (PBS) 204.

P-polarized light of the regenerated light S2 passing through the imaging lens 210 passes only light of 1 bit diameter through the pinhole of the slit 212 and is transmitted to the photodetector (PDIC) 216 through the condenser lens 214. .

The photodetector (PDIC) 216 transfers the light quantity data detected by the at least two divided optical sensors to the servo controller 218. For example, when the photodetector (PDIC) 216 consists of two optical sensors divided into two, the light quantity data a and b detected by each optical sensor are transmitted to the servo controller 218.

The servo control unit 218 compares the light amount data a and b detected by the light detection unit (PDIC) 216 with the set data. For example, it is compared whether the difference a-b of the light quantity data detected by each of the two divided optical sensors is equal to the set data a-b = 0. If the difference (ab) of the detected light quantity data is equal to the set data (ab = 0), the servo controller 218 determines the focus servo to be normal and performs the focus servo control of the actuator 220 of the objective lens 208. Do not perform.

However, if the data (a, b) detected by the photodetector (PDIC) 216 is not the same as the set data and there is a difference (ab <0, ab> 0), the servo control unit 218 abnormally causes the focus servo. By discriminating, focus servo control of the actuator 220 of the objective lens 208 is performed. Accordingly, the focal length between the objective lens 208 and the disk 1 is adjusted by driving the actuator 220. In this case, since the reference light S1 is incident on the disk 1 through the objective lens 208, The focus of the light is also adjusted automatically.

5 is a view for explaining the focus between the objective lens and the disk in the reference light focus servo device of the holographic ROM disk according to the present invention and incident reference light.

As shown in Fig. 5, in the reference light focus servo device of the holographic ROM disk according to the present invention, the focus f1 of the light S2 reproduced by the reference light S1 is constant between the disk and the mask during recording. Due to the difference in distance, it is not formed on the disk 1 but is formed at a position slightly away from the disk 1 between the disk 1 and the objective lens 108.

However, the reference light S1 incident on the disk 1 through the thin lens outer portion 208b portion of the objective lens 208 does not coincide with the focal point f1 of the reproduction light S2, or on the surface of the disk 1. The focus f2 is focused on the recording material layer in the disc 1.

Accordingly, the present invention can accurately focus the reference light S1 incident on the disk 1 from the holographic ROM disk, thereby accurately reproducing the holographic data, and thereby easily performing focus servo control of the holographic ROM disk. Do.

 As described above, in the present invention, the focus servo device of the holographic ROM disk has a thick central lens of the lens through which reproduction light is transmitted, and a thin objective lens at the lens outer portion through which reference light is transmitted. It can be accurately focused and incident on the recording material layer so that the holographic data can be accurately reproduced, and thus there is an advantage in that it is easy to perform focus servo control of the holographic ROM disk.

On the other hand, the present invention is not limited to the above-described embodiment, various modifications are possible by those skilled in the art within the spirit and scope of the present invention described in the claims to be described later.

Claims (7)

An apparatus for servo-controlling a focus to a disk with reference light incident on it and reproduced from a holographic ROM disk, A beam splitter for reflecting the reference light and transmitting the light reproduced from the disk as it is; An objective lens that transmits the reference light transmitted from the beam splitter to the disk and transmits the light reproduced from the disk to the beam splitter, and has a thin outer thickness of the lens through which the reference light is transmitted and a central thickness of the lens through which the reproduced light is transmitted. Wow, A light detector for detecting reproduction light transmitted through the beam splitter; An actuator for adjusting the objective lens position, A servo control unit which performs focus servo control of the objective lens by driving the actuator by comparing the light amount data detected by the light detection unit with the set data and when the two data are not the same. Reference light focus servo device of the holographic ROM disk comprising a. The method of claim 1, The apparatus includes a polarizer for polarizing the reference light and transmitting it to the beam splitter, and modifying a phase of the reference light transmitted from the beam splitter to enter the disk and modifying a phase of light reproduced from the disk to the beam splitter. The reference light focus servo device of the holographic ROM disk, characterized in that it further comprises a plate for transmitting. 3. The reference light focus servo device of claim 2, wherein the polarizer polarizes the reference light by P polarization or S polarization. The method of claim 2, And said plate deforms the phase of said reference or reproduction light by [lambda] / 4. The method of claim 1, And the beam splitter reflects the reference light through an outer portion of the beam splitter mirror and transmits the reproduced light through a center portion of the beam splitter mirror. delete The method of claim 1, And the light detector is at least two divided sensors.

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