KR100657726B1 - Servo device of the holographic rom reading system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a servo device of a holographic ROM reproducing system, comprising: a reference light providing unit for injecting a reference light into a disc at the same incidence angle as the reference light incidence angle used in recording; A portion of the signal light passes through the pinhole, and the rest is arranged to reflect by the reflective mirror layer, a first light detector for detecting signal light passing through the pinhole of the slit, and a light detection data of the first light detector according to the light detection data. A tracking servo control for performing tracking servo control by adjusting the radial regeneration position, a second light detector for detecting signal light reflected by the reflective mirror layer of the slit, and a signal light according to the light detection data of the second light detector. A focusing servo control section for performing focusing servo control by adjusting the focus position in the optical axis direction, and By splitting the signal light by using a slit provided with a mirror layer on the basis of each signal light detection value for performing the tracking servo and focusing servo, there is an advantage that, while using only a single light source ensures a high detection efficiency of the data signal.

Description

SERVO DEVICE OF THE HOLOGRAPHIC ROM READING SYSTEM}

1 is a configuration diagram showing an example of a servo device of a holographic ROM reproducing system according to the prior art;

FIG. 2 is an exemplary view illustrating a track image formed in a slit of the holographic ROM playback system of FIG. 1;

3 is a cross-sectional view showing the structure of a slit employed in the servo device of the holographic ROM reproducing system according to the present invention;

4 is a block diagram showing a servo device of the holographic ROM reproducing system according to the first embodiment of the present invention;

5 is an exemplary view showing a track image formed in a slit of the holographic ROM playback system shown in FIG. 4;

6A to 6C are diagrams illustrating examples of normal focus and abnormal focus detection in the servo device of the holographic ROM reproducing system shown in FIG. 4;

7 is a block diagram showing a servo device of a holographic ROM reproducing system according to a second embodiment of the present invention;

8 is a configuration diagram of an optical device on a focusing light detection path in a servo device of a holographic ROM reproducing system according to a third embodiment of the present invention;

9A to 9C are diagrams showing examples of normal focus and abnormal focus detection in the servo device of the holographic ROM reproducing system shown in FIG.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a servo device of a holographic ROM (HROM) reproducing system, and more particularly to tracking and focusing servo control when reproducing data recorded on a holographic disc. A servo device in a holographic ROM playback system.

As the information industry develops, a large capacity of a device for storing information and a high speed of processing are required. Accordingly, the holographic ROM, which is widely known among devices 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 system is different from the optical disc reproducing apparatus such as general CD or DVD. In other words, the optical disk reproducing apparatus focuses light to have a track size and detects the light reflected from the data pit, whereas in the holographic ROM reproducing system, the reference light is irradiated onto the optical disk and diffracted from the optical disk. Light is detected through a pin hole in a slit. At this time, the size of the reference light is much larger than the size of the data track, and the pinhole size of the slit has a track pitch size, so that the run-out in the radial direction or the optical axis generated as the optical disk is rotated is performed. This makes it difficult for the light reproduced from the data pit of a particular track to enter the pinhole of the slit correctly. Therefore, it is the servo operation in the holographic ROM regeneration system that detects 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 reproduction system adjusts the position of the radial direction of the light so that the focused light is accurately positioned in the data track, and the focusing servo is the focus position of the light so that the reflective surface of the disc is exactly at the focus of the light. To adjust in the optical axis direction.

1 is a configuration diagram illustrating an example of a servo device of a holographic ROM reproducing system according to the related art, and illustrates a three-hole method which is a representative method of tracking servo.

Referring to this, the conventional tracking servo device includes a reference light providing unit 10 for injecting the reference light B1 into the disk 1 at the same incident angle as the reference light incident angle used in recording, and the reference light in the recording material layer of the disk 1. A slit 40 disposed so that the signal light B2 reproduced by the diffraction of (B1) passes through three pinholes, a light detector 70 for detecting the signal light B2 passing through the slit 40, and light And a tracking servo control unit 80 that performs tracking servo control by adjusting the radial direction regeneration position of the disc 1 in accordance with the light detection data of the detection unit 70. In the drawings, reference numerals 20, 30, 50, and 60 are objective lenses.

Referring to the servo control process by the tracking servo device configured as described above, first, when the reference light B1 is incident on the disk 1 by the reference light providing unit 10, the recording material layer of the disk 1 is diffracted by the data layer. The signal light B2 is then provided to the slit 40 through the objective lenses 20 and 30.

Then, as shown in FIG. 2, the track T is formed in the slit 40, and the signal light B2 passing through the pinhole 41 is provided to the light detector 70 through the objective lenses 50 and 60. do.

For example, the light detector 70 is implemented as a three-segment light receiving device, and each light receiving device has one-to-one correspondence with three pinholes 41 provided in the slit 40 and passes through each pinhole 41. ). Of the three pinholes 41, the light receiving element corresponding to the center hole is used for detecting the data signal, and the light receiving element corresponding to the remaining outer holes is used for tracking servo control.

Thus, the tracking servo control unit 80 performs tracking servo control to adjust the radial regeneration position of the disc 1 by horizontally moving the position of the objective lens 20 based on the light detection data by the light detection unit 70. Perform.

Meanwhile, the servo device of FIG. 1 as described above is a tracking servo device that does not consider focusing servo. For the focusing servo control function, the servo device has to branch the signal light path, and additionally, various optical devices are required.

For example, by separately installing a light source for focusing servo, and adopting a special reflecting film that passes only a specific wavelength and reflects the remaining wavelengths, branching the signal light into a special reflecting film, one signal light path is used for tracking servo, and the other signal light path is Can be used for focusing servos.

As another example, signal light transmitted through the beam splitter using a polarizer beam splitter (PBS) is used for tracking servo and data signal detection, and signal light reflected by the beam splitter is used for focusing servo.

However, the former example has a problem that the cost increases due to the addition of a light source, and the latter example has a problem that the detection efficiency of the data signal is lowered because the signal light is divided.

In order to solve such a conventional problem, a signal is split using a slit having a reflective mirror layer, and tracking and focusing servos are performed based on respective signal light detection values. It is an object of the present invention to provide a servo device having high signal detection efficiency.

The servo device of the holographic ROM reproducing system according to the present invention for achieving the above object comprises a reference light providing unit for injecting the reference light into the disc at the same incidence angle as the reference light incidence angle used in recording, and from the recording material layer of the disc. A portion of the signal light reproduced by the diffraction of the light passes through the pinhole and the rest is reflected by the reflection mirror layer, a first light detector for detecting the signal light passing through the pinhole of the slit, and the light of the first light detector A tracking servo control section for performing tracking servo control by adjusting the radial direction playback position of the disc according to the detection data, a second light detector section for detecting signal light reflected by the reflective mirror layer of the slit, and a second light detector section light Focusing servo which performs focusing servo control by adjusting the focus position of the signal light in the optical axis direction according to the detection data It includes a control unit.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. This embodiment allows for a better understanding of the objects, features and advantages of the present invention. However, the present invention is not limited to this embodiment.

Figure 3 is a cross-sectional view showing the structure of the slit employed in the servo device of the holographic ROM playback system according to the present invention.

Referring to FIG. 3, the slit 140 employed in the present invention includes a light blocking film 142 and a reflective mirror layer 143 below, and includes three pinholes 141 for transmitting a part of incident light. do.

4 is a block diagram showing a servo device of the holographic ROM reproducing system according to the first embodiment of the present invention.

Referring to FIG. 4, the servo device of the present invention includes a reference light providing unit 10 for allowing the reference light B1 to enter the disk 1 at the same incident angle as the reference light incident angle used for recording, and a recording material of the disk 1. A portion of the signal light B2 reproduced by the diffraction of the reference light B1 in the layer passes through the three pinholes 141 and the others are arranged to reflect by the reflective mirror layer 143 and the slit ( The radial regeneration position of the disc 1 is set in accordance with the first light detector 70 for detecting the signal light B2 passing through the pinhole 141 of the 140 and the light detection data of the first light detector 70. Tracking servo control unit 80 for adjusting and performing tracking servo control, second light detection unit 230 for detecting signal light B2 reflected by reflective mirror layer 143 of slit 140, and second light Focusing servo control by adjusting the focus position of the signal light B2 in the optical axis direction according to the light detection data of the detector 230. It is configured to include a focusing servo control unit 240 to perform the. In the drawings, reference numerals 20, 30, 50, 60, 210, and 220 denote objective lenses.

The slit 140 is inclined at about 45 degrees to position the imaging surface of the existing system shown in FIG.

The second light detector 230 is implemented as a two-split light receiving element disposed before the focal position of the signal light B2, and the focusing servo controller 240 is connected to the center light receiving element 231 and the outer light receiving elements 232 and 233. Focusing servo control is performed based on the comparison result of the light detection values.

Referring to the servo control process by the servo device according to the first embodiment of the present invention configured as described above, first, when the reference light B1 is incident on the disk 1 by the reference light providing unit 10, the recording material of the disk 1 is used. Diffracted by a layer, that is, a data layer, the signal light B2 is provided to the slit 140 through the objective lens 20, 30.

Then, as shown in FIG. 5, the track T is formed in the slit 140, and a part of the signal light B2 passes through the pinhole 141 to pass through the objective lenses 50 and 60 to the first light detector ( 70, the remaining signal light B2 reflected by the reflective mirror layer 143 is provided to the second light detector 230 through the objective lenses 210 and 220.

The first light detector 70 is implemented as, for example, a three-split light receiving element, and each light receiving element has a one-to-one correspondence with three pinholes 141 provided in the slit 140 and passes through the respective pinholes 141. (B2) is detected. Of the three pinholes 141, a light receiving element corresponding to the center hole is used to detect a data signal, and the light receiving element corresponding to the remaining outer holes is used for tracking servo control.

Thus, the tracking servo controller 80 horizontally shifts the position of the objective lens 20 based on the light detection data by the first light detector 70 to adjust the radial regeneration position of the disc 1. Perform control.

Meanwhile, the center light receiving element 231 and the outer light receiving elements 232 and 233 of the second light detector 230 provide the signal light detection values to the focusing servo controller 240, and the focusing servo controller 240 is the center. Focusing servo control is performed based on a comparison result of the light detection values of the light receiving element 231 and the outer light receiving elements 232 and 233.

As shown in FIG. 6A, when the light detection values of the center light receiving element 231 and the outer light receiving elements 232 and 233 are the same (or the difference value does not exceed the threshold range), it is determined as a normal focusing state. 6B and 6C, when the light detection values of the center light receiving element 231 and the outer light receiving elements 232 and 233 are not equal to each other (or when the difference exceeds the threshold range), the focusing state is abnormal. Determine. FIG. 6B illustrates a case where the light detection values of the outer light receiving elements 232 and 233 are larger than the light detection value of the center light receiving element 231, and is in an under focus state. FIG. 6C shows the light detection of the outer light receiving elements 232 and 233. The photodetection value of the central light receiving element 231 is larger than the value, and is in the overfocus state.

In this way, the focusing servo controller 240 determines the focusing error state according to the light detection data of the second light detector 230, and in the case of the focusing error, the focusing servo controller 240 vertically shifts the position of the objective lens 20 to determine the signal light B2. Focusing servo control is performed to adjust the focus position in the optical axis direction.

7 is a block diagram showing a servo device of the holographic ROM reproducing system according to the second embodiment of the present invention. As compared with the first embodiment illustrated in FIG. 4, it can be seen that the objective lenses 210 and 220 are removed on the optical path between the slit 140 and the second light detector 230. As such, when the signal light B2 reflected by the reflective mirror layer 143 of the slit 140 is designed to be directly incident on the second light detector 230, the objective lenses 210 and 220 are removed to reduce costs. It works.

FIG. 8 is a configuration diagram of the arrangement of the optical devices on the focusing light detection path in the servo device of the holographic ROM reproducing system according to the third embodiment of the present invention, and shows an optical path between the objective lens 220 and the second light detecting unit 230. It can be seen that an astigmatism lens 310 has been added to the image. When the astigmatism lens 310 is added as described above, the focus beam is detected as an ellipse, as shown in FIGS. 9A to 9C, and the central light receiving element 231 and the outer light receiving elements 232 and 233 as shown in FIG. 9A. If the detected light values are equal to each other (or the difference value does not exceed the threshold range), it is determined as a normal focusing state. As shown in FIGS. 9B and 9C, the center light receiving element 231 and the outer light receiving element 232, If the light detection values by 233 are not equal to each other (or the difference value exceeds the threshold range), it is determined to be an abnormal focusing state. FIG. 9B is a case where the light detection values of the outer light receiving elements 232 and 233 are larger than the light detection value of the center light receiving element 231 and are in an under focus state. FIG. 9C shows light detection of the outer light receiving elements 232 and 233. The photodetection value of the central light receiving element 231 is larger than the value, and is in the overfocus state.

In the detailed description thus far, only the embodiments of the present invention have been described, but it is apparent that the technology of the present invention can be easily modified by those skilled in the art within the scope of the technical idea described in the claims below.

As described above, the present invention uses a slit having a reflective mirror layer to branch the signal light to perform tracking servo and focusing servo based on the respective signal light detection values, thereby providing high detection efficiency of the data signal while using only a single light source. It is effective to ensure.

Claims (4)

An apparatus for controlling servo by detecting light reproduced from a disc on which data is recorded in a holographic ROM reproducing system, A reference light providing unit for injecting the reference light into the disk at the same incident angle as the reference light incident angle used during recording; A portion of the signal light reproduced by the diffraction of the reference light in the recording material layer of the disc passes through the pinhole and the rest is arranged to reflect by the reflective mirror layer; A first light detector for detecting the signal light passing through the pinhole of the slit; A tracking servo controller which performs tracking servo control by adjusting a radial direction reproducing position of the disk according to the light detection data of the first light detector; A second light detector for detecting the signal light reflected by the reflective mirror layer of the slit; A focusing servo controller which performs focusing servo control by adjusting a focus position of the signal light in the optical axis direction according to the light detection data of the second light detector. Servo device of the holographic ROM playback system comprising a. The method of claim 1, The second light detector is implemented as a two-split light receiving element including a center light receiving element and an outer light receiving element disposed before a focus position of the signal light. Wherein the focusing servo controller performs the focusing servo control based on a comparison result of light detection values of the central light receiving element and the outer light receiving element. Servo device of holographic ROM playback system characterized in that. The method according to claim 1 or 2, Wherein a plurality of objective lenses are disposed on an optical path between the slit and the second light detector Servo device of holographic ROM playback system characterized in that. The method of claim 3, wherein An astigmatism lens disposed on an optical path between the objective lens and the second light detector Servo device of holographic ROM playback system characterized in that.

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