KR100451146B1 - Light source control device of an optical recording/reproducing device, especially for removing a signal detection error during a reproduction - Google Patents

Abstract

PURPOSE: A light source control device of an optical recording/reproducing device is provided to form a pit having a proper width by reducing latent heat accumulated on a disk by reducing the spot size of a beam in a recording mode, and to make the spot size of a beam normal in a reproduction mode so as to perform a normal reproduction process, thereby improving product performance. CONSTITUTION: A pickup(201) radiates a laser beam on a disk(200). A laser driver(203) drives the pickup(201). A spot size controlling plate(206) partially cuts off a quantity of radiated light of the laser beam radiated from the pickup(201) in a recording mode. A spot size controller(207) controls the spot size controlling plate(206). A system controller(204) controls the spot size controller(207) and the laser driver(203) according to the recording mode and a reproduction mode.

Description

Light source control device of optical recording / reproducing device

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to correction of playback errors of discs, and more particularly, to a light source control apparatus of an optical recording / reproducing apparatus for eliminating signal detection errors during playback.

A typical optical recording apparatus includes a pickup 101 for scanning a laser beam onto a disk 100, a photo detector 102 for detecting reflected light from the disk 100, as shown in the block diagram of FIG. And a laser controller 103 for driving the pickup 101 and a system controller 104 for controlling the laser driver 103 in accordance with input data when a recording mode is set by the key input unit 105.

A conventional optical recording method is a method of forming a pit according to recording data by irradiating a laser beam of a predetermined level for a period corresponding to the length of a pit to be formed on a disk.

Referring to the operation of the conventional method as follows.

When the recording mode is set by the key input unit 105, the system control unit 104 controls the servo system (not shown) to rotate the disk 100, and to move the pickup 101 to the recording position on the disk 100. Will be moved.

Thereafter, the system control unit 104 digitally processes the input data for recording and uses the signal corresponding to the length of the pit to be recorded on the disc 100 as a signal for driving the laser diode 111. Will print to

At this time, the laser driver 103 drives the laser diode 111 embedded in the pickup 101 for a period corresponding to the length of the pit to be recorded on the disk 100 according to the control signal of the system controller 104.

Accordingly, in the pickup 101, the laser beam generated by the laser diode 111 is converted into parallel light in the collimated lens 112, and is collected by the objective lens 114 through the optical separator 113. Scanned by the disk 100 and reflected, the reflected light is converted into the parallel light in the objective lens 114 and reflected in the orthogonal direction in the optical separator 113, thereby scanning the light detector 102 through the cylindrical lens 115. It is done.

Therefore, a groove is formed on the disk 100 to which the laser beam from the pickup 101 is irradiated, and the laser beam is kept high as shown in FIG. 2 for a length of the pit length to be recorded. Pits are formed on the disk 100.

At this time, while performing a recording operation in which the disk 100 is irradiated with a laser beam to form pits, the light detector 102 detects the reflected light from the disk 100 through the pickup 101.

Accordingly, by processing the output signal of the photo detector 102, pits are formed on the disc 100 by adjusting the focusing, tracking, and power of the laser beam.

In general, in the recording operation, the laser beam is irradiated as shown in FIG. 2A to form a pit having the same width as the front end and the rear end as shown in FIG. 2B on the disc 100. Due to the latent heat accumulated in 100), the width of the pit becomes wider toward the rear end of the pit. Therefore, the pit having an appropriate width and length is formed by accurately adjusting the power and irradiation time of the recording laser beam according to the characteristics of the disc according to the manufacturer. By doing so, it is possible to accurately detect data recorded on the disc 100 during playback.

Therefore, when the spot size of the beam scanned on the pit formed on the disc 100 during reproduction is almost the same as the width of the pit as shown in FIG. 2 (C), light is scattered at the portion where the pit is formed so that the reflected light is less. The amount of light is detected as in the waveform of Fig. 3A, and reproduction of normal recording data is performed.

However, even when the disc is a recording medium, the recording characteristics may be different depending on the uniformity and temperature of the medium, even when manufactured by the same company. Can vary.

Therefore, in the related art, a normal reproduction operation can be performed in the case of a recording medium having a different characteristic in the error range by allowing a certain error, but there is a problem in that an error occurs when the error is out of the tolerance range.

That is, conventionally, the width of the second half of the pit is wide due to the characteristics of the recording medium. When the width of the pit is larger than the spot size of the beam as shown in FIG. Since it is recognized that it does not exist, the amount of reflected light is detected as shown in the waveform of FIG.

The present invention provides a light source control apparatus of an optical recording / reproducing apparatus, which can be used to correct an error at the time of reproduction by performing different reproduction of the spot diameter of a light beam in a recording mode and a reproduction mode in order to solve the conventional problems. The purpose is to provide.

In order to achieve the above object, the present invention reduces the spot size of the beam by partially blocking the recording laser beam when the recording mode is set, and transmits the entire laser beam for reproduction when the playback mode is set, thereby increasing the general spot size. Characterized in that the process to perform.

The present invention also provides a pickup for scanning a laser beam onto a disc, a laser driver for driving the pickup, a spot size adjusting plate for adjusting the spot size of the laser beam scanned from the pickup, and And a spot size control unit for controlling the aperture ratio of the spot size control plate, and a system control unit for controlling the spot size control unit according to a recording or reproducing mode and controlling the laser drive unit according to recording input data.

The spot size adjusting plate is an LCD and is mounted between the optical separator in the pickup and the objective lens, and adjusts the amount of parallel light in the pickup depending on whether or not a voltage is applied. By blocking the transmission, the size of the light spot scanned on the disc is reduced, and in the reproduction mode, all the light transmission is allowed to make the size of the light spot scanned on the disc larger than in the recording mode.

The reason for adjusting the size of the light spot scanned on the disk is that the characteristics of the disks are different for each manufacturer.

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

A block diagram of an embodiment according to the present invention is shown in Figure 4, the pickup 201 for scanning a laser beam on the disk 200, and the photo detector 202 for detecting the reflected light from the disk 200 And a laser driver 203 for driving the laser diode 211 mounted on the pickup 201, and a spot size adjusting plate 206 for adjusting the spot size of the laser beam scanned by the pickup 201 in the recording mode. And a spot size control unit 207 for controlling the amount of transmitted light of the spot size control plate 206, the spot size control unit 207 in the recording mode, and the laser driver 203 in accordance with the input data for recording. It consists of the system control part 204 to perform.

The pickup 201 is a beam of the laser diode 211 is converted into parallel light in the collimated lens 212 is condensed in the objective lens 214 through the light separator 213, the spot size control plate 206 in sequence Scanned to the disk 200 and reflected light from the disk 200 becomes parallel light at the objective lens 214 and reflected at the optical separator 213 to the photo detector 202 through the cylindrical lens 215. Configured to be injected.

The spot size adjusting plate 206 is an LCD having a structure as shown in FIG. 5A mounted between the optical separator 213 of the pickup 201 and the objective lens 214. In the recording mode, voltage is applied. As shown in Fig. 5 (b), the light transmission is blocked, and in the regeneration mode, the voltage is cut off so as to have a light transmission state as usual.

Referring to the operation and effect of the present invention configured as described above are as follows.

The recording / reproducing apparatus of the present invention operates by being divided into a recording mode or a reproducing mode according to the mode discrimination as shown in the signal flow diagram shown in FIG.

First, when the recording mode is set by the key input unit 205, the system control unit 204 controls the servo system (not shown) to rotate the disk 200 and to record the pickup 201 on the disk 200. Will be moved to the location.

Thereafter, the system control unit 204 controls the spot size control unit 207 to reduce the aperture ratio of the spot size control plate 206, and digitally processes the input data for recording to the length of the pit to be recorded on the disc 200. The signal is output to the laser driver 203 as a signal for driving the laser diode 211.

Here, the spot size control plate 206 is applied to a voltage to block the light transmission as shown in FIG. 5A.

At this time, the laser driver 203 drives the laser diode 211 embedded in the pickup 201 for a period corresponding to the length of the pit to be formed on the disk 200 according to the control signal of the system controller 204.

Accordingly, the laser beam generated by the laser diode 211 is converted into parallel light in the collimated lens 212 and passes through the optical separator 213 as it is, and through the spot size adjusting plate 206 as shown in FIG. By partially blocking the light transmission, the size of the spot which is collected by the objective lens 214 and scanned by the disk 200 is reduced.

Therefore, a groove is formed at a position on the disk 200 to which the laser beam from the pickup 201 is irradiated, and the pit is held on the disk 200 by keeping the laser beam high for the length of the pit length to be recorded. Will form.

At this time, the light scanned on the disk 200 is reflected and converted into parallel light on the objective lens 214, and the parallel light is reflected in the orthogonal direction by the optical separator 213, so that the light detector 202 is provided through the cylindrical lens 215. ) Is detected.

Accordingly, by processing the output signal of the photo detector 202, the focusing, tracking, and power of the laser beam are adjusted to form a pit having an appropriate width and length on the disc 200.

On the other hand, when the disk 200 having the pit formed according to the recording data is mounted and the playback mode is set by the key input unit 205, the system controller 204 rotates the disk 200 by controlling the servo system (not shown). In addition, the pickup 201 is moved to the initial playing position on the disc 200.

At this time, the system control unit 204 controls the spot size control unit 207 to cut off the voltage applied to the spot size control plate 206 so as to be in a total light transmission state, and the laser diode 211 mounted on the pickup 201 is controlled. The laser driver 203 is controlled to drive the laser beam to the disk 200.

Accordingly, the laser beam in the laser diode 211 is converted into parallel light in the collimated lens 212 to be collected in the objective lens 214 through the light separator 213 and the spot size adjusting plate 206 and collected therein. The beam is irradiated onto the disk 200.

Here, the spot size of the laser beam irradiated onto the disk 200 becomes larger than the spot size during the recording operation because the spot size adjusting plate 206 is in a completely light transmitting state.

At this time, the reflected light from the disk 200 is converted into parallel light in the objective lens 214 and incident to the optical separator 213 through the spot size adjusting plate 206 and the light changed in the perpendicular direction at the optical separator 213 is Incident on the photodetector 202 through the cylindrical lens 215.

Therefore, when the photodetector 202 converts the electric signal according to the amount of incident light, the data recorded on the disc 200 is reproduced by performing arithmetic processing to reproduce the high frequency signal.

Here, the reproduction of the disc 200 is performed to process the electrical signal converted by the photodetector 202 to correct the tracking and focusing of the pickup 201 so as to perform a normal reproduction operation.

As described in detail above, the present invention forms a pit of an appropriate width by reducing the spot size of the beam in recording mode to reduce the latent heat accumulated on the disc, and makes the normal playback by making the spot size of the beam normal in the playback mode. By doing so, the performance of the product can be improved and the user can be satisfied.

1 is a block diagram of a general optical recording apparatus.

2 is an exemplary view showing a conventional pit state.

3 is a waveform diagram showing the amount of reflected light according to the formation of pits in FIG.

4 is a block diagram of a light source control apparatus according to the present invention.

5 is an exemplary view showing the structure of the spot size control plate in FIG.

6 is a signal flow diagram for controlling a light source according to the present invention.

*** Explanation of symbols for main parts of drawing ***

200: disc 201: pickup

202: photo detector 203: laser driver

204: system control unit 205: key input unit

206: spot size control plate 207: spot size control unit

Claims (3)

Pickup means for scanning a laser beam onto the disc, Laser drive means for driving the pickup means, Spot size adjusting means mounted between the optical separator and the objective lens to adjust the amount of scanning light of the laser beam scanned by the pickup means in the recording mode; Spot size controlling means for controlling the spot size adjusting means; And a system control means for controlling the spot size control means and the laser drive means in accordance with a recording / reproducing mode. The light source control apparatus of the optical recording / reproducing apparatus according to claim 1, wherein the spot size adjusting means comprises an LCD. The pickup means according to claim 1 or 2, wherein the spot size adjusting means partially blocks the light in the pickup means so that the size of the beam spot becomes small in the recording mode and the beam spot becomes the normal size in the reproduction mode. A light source control apparatus for an optical recording / reproducing apparatus, characterized in that it transmits all the light.