KR20030058752A - Optical recorer - Google Patents

Abstract

PURPOSE: An optical recording player is provided to accurately form a focus of a beam focused by a focusing lens of a slider at a recording layer of a disk, and record and play clear signals. CONSTITUTION: A light receiving and transmitting unit writes and reads information. A swing arm(10) is installed to be rotated to a surface of a rotating disk(D). An actuator(20) provides rotative driving force to the swing arm. A slider(30) is installed at an end of the swing arm toward the disk. A focusing lens is mounted on the slider for focusing the beam and projecting the beam to a recording layer of the disk. A focus measuring unit is installed on the slider for applying a test signal to the recording layer of the disk and recognizing the test signal reflected from the recording layer, so that the focus measuring unit measures whether depth of focus is coincided with the recording layer of the disk. A height adjusting unit(50) is installed on the swing arm for adjusting an interval between the slider and the surface of the disk.

Description

Optical recorder {OPTICAL RECORER}

The present invention relates to an optical recording and reproducing apparatus, and more particularly, to an optical recording and reproducing apparatus having a swing arm height adjusting means for precisely focusing light focused by a focusing lens of a slider onto a recording layer of a disc. It is about.

In light of the trend of large-capacity information, new optical recording and reproducing methods are required to overcome the limitations of existing optical recording and reproducing methods.

An optical recording medium or a magneto-optical recording medium must have a small bit (or recording mark) size and a narrow track width to have a high density recording capacity. However, the limitation due to the difference in the layer structure of the recording medium including the protective layer, the recording layer, and the reflective layer and the condensing method, the diffraction of the spot size of the light condensed on the recording medium to form bits in the recording film of the recording medium. Due to limitations such as limitations, studies on optical recording and reproducing methods are actively being conducted to overcome such limitations.

The structure of a conventional far field optical recording and reproducing method is as shown in FIG. That is, the light irradiated from the transmitting / receiving part is focused using a focusing lens 1 having a numerical aperture (NA: Numerical Aperture) of about 0.5 to 0.6, and the focused light first passes through the substrate 2 and then the recording layer It takes the way to reach (3).

The reason why the light is transmitted through the thick substrate 2 and reaches the recording layer 3 is that a protective layer made of a thick substrate is formed on the outer layer of the recording layer, whereby fingerprints, dust and other contaminants This is to prevent the recording layer from being damaged.

The recording density of the disc is determined by the size of the focused light, and the size of the light is determined by the wavelength? Of the light source and the numerical aperture NA of the lens used, in consideration of diffraction.

However, when the optical recording and reproducing of the signal using the disk of the above structure is taken, as shown in FIG. 1, the light reaches the recording layer 3 through the thick substrate 2. However, there is a limitation that a lens having a high refractive index, that is, a numerical value having a high numerical aperture cannot be used.

In addition, in order for the focus of the light focused through the focusing lens 1 to be formed in the recording layer 3, it is required to keep the focusing lens 1 and the recording layer 3 at a constant distance. ) Is difficult to take a smooth structure, so the focusing lens 1 cannot take a method of recording and reproducing a signal in contact with the surface of the substrate 2, that is, the surface of the disk. There is a need for a certain interval between them, which is another limitation in that a lens having a high numerical aperture cannot be used.

In addition, when a lens having a high numerical aperture is used in this structure, the coma aberration becomes large as shown in the following equation, so that the problem of blurring of focus when the disk is tilted, that is, tilt The problem is further raised that the correction is difficult.

Where t is the distance that the laser light must pass to reach the recording layer, NA is the numerical aperture of the focusing lens, α is the tilt angle of the disk, and n is the refractive index of the substrate.

Therefore, in order to increase the recording density of the disc, it is necessary to deviate from the conventional method as described above, in which the recording layer is formed at a position as close as possible to the light irradiation surface of the disc, so-called reverse stacking structure of the disc. Research has been actively conducted.

2 is a schematic diagram showing the configuration of an optical recording and reproducing method having a reversed structure.

As shown, in the optical recording and reproducing method of the inverted structure, the light penetrates the protective layer (not shown) of the disk having a thin structure instead of the thick substrate 2 and approaches the recording layer 3. This method solves the problems of the conventional method as described above, and enables recording and reproducing of information on a disk having a higher recording density.

On the other hand, an optical recording / reproducing method using a near field has been proposed as a method for increasing the recording density in a region where light diffraction does not occur.

The principle of near field optical recording and reproducing is as follows. Light entering the lens at an angle greater than or equal to the critical angle is totally reflected when traveling from a dense refractive index to a small one. At this time, due to total reflection of light, light of very small intensity exists on the surface of the lens, which is called an evanescent wave or dissipation wave. Using this evernet wave, it is possible to achieve high resolution, which is impossible because of the diffraction limit, which is an absolute limit of resolution due to diffraction of light in the far-field. The near field optical recording and reproducing optical system totally reflects the light in the lens to generate an Evernet wave on the surface of the lens, and records and plays back by coupling the Evernet wave and the recording medium.

3 is a configuration diagram briefly showing the configuration of the near field optical recording and reproducing method.

As shown, the near-field optical recording and reproducing method injects the light irradiated from the transmitting / receiving part into the focusing lens 5 having a very high numerical aperture through the objective lens 4, thereby generating By the coupling of the recording layer 3 formed on the surface, a signal is recorded or reproduced.

However, the above-described various types of optical recording and reproducing methods all have a condition that signals can be accurately reproduced or recorded only when the depth of focus of the light focused through the focusing lens falls within the recording layer thickness of the disc.

Here, the depth of focus refers to the depth of an area where light is focused, and has a very small value, but is one of the factors to be considered in an optical recording / reproducing apparatus having a high precision structure for reproducing or recording a signal on a high recording density disk. .

Therefore, some discrepancies in the depth of the recording layer cannot be avoided for each disc due to various manufacturing reasons. Therefore, there is an urgent demand for the development of a device capable of focusing the focused light within the thickness of the recording layer. come.

It is an object of the present invention to provide an optical recording / reproducing apparatus having a structure which enables the focusing of light focused by a focusing lens of a slider to be accurately formed on a recording layer of a disk.

1 to 3 schematically show a configuration of a conventional optical recording and reproducing method,

1 is a schematic diagram showing the configuration of a far field method.

Fig. 2 is a schematic diagram showing a recording / playback method for a disc of reversal structure.

3 is a schematic diagram showing the configuration of a near-field method;

4 and 5 show the structure of an embodiment of the present invention,

4 is a perspective view

5 is a cross-sectional view of main parts

** Description of the symbols for the main parts of the drawings **

D: Disc 3: Recording Layer

10: swing arm 20: actuator

30: slider 40: focus measuring means

50: altitude adjustment means

In order to achieve the above object, the present invention provides a transmitter and receiver for recording or reproducing information by irradiating and injecting light, a swing arm mounted to the main body so as to be reciprocally rotated, An actuator for providing a rotational driving force to the swing arm, a slider provided at an end of the disk side of the swing arm, and a focusing lens attached to the slider to focus light irradiated from the light-receiving unit to enter the recording layer of the disk. An optical recording and reproducing apparatus, provided in the slider, applies a test signal to a recording layer of the disc, recognizes a test signal reflected from the recording layer of the disc, and detects the depth of focus of the focusing lens and the disc. Focus measuring means for measuring whether the recording layer is matched; An altitude adjusting means installed on the swing arm to adjust a distance between the slider and the surface of the disk by a signal transmitted from the measuring means; An additional optical recording and reproducing apparatus is provided.

Further, the slider is provided so that the track of the disk can be scanned while floating against the disk by pneumatic pressure, and the disk has a contact surface in which a recording layer is formed on the contact surface side with the slider about the center of the thickness thereof. The present invention can also be applied to a recordable disc.

In addition, the altitude adjustment means is preferably installed in the actuator.

In addition, the altitude adjustment means is preferably a bimetal or shape memory alloy.

And a magnetic coil mounted on the disk side facing surface of the slider; Reproducing or recording means for transmitting and receiving an electrical signal with the magnetic coil; The present invention can be applied even when configured to include.

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

4 and 5 show the structure of an embodiment of the present invention, Figure 4 is a perspective view, Figure 5 is a cross-sectional view of the main portion.

As shown, the optical recording and reproducing apparatus according to the present invention reciprocates with respect to the surface of a transmitting / receiving unit (not shown) for recording or reproducing information by irradiating and incident light, and the surface of the rotating disk D mounted on the main body. The swing arm 10 provided as possible, the actuator 20 which provides rotational driving force to the swing arm 10, the slider 30 provided in the disk D side end of the swing arm 10, and the slider 30 And a condenser lens 31 for condensing the light irradiated from the transmitting / receiving part to be incident on the recording layer 3 of the disk D.

In addition, the present invention further comprises a focus measuring means 40 and a swing arm altitude adjusting means 50, the focus measuring means 40 being provided on the slider 30, the recording layer 3 of the disc D. ) Is applied to the test signal and the test signal reflected from the recording layer 3 of the disk D is recognized. The depth of focus of the focusing lens 31 and the recording layer 3 of the disk D are measured. do.

The altitude adjusting means 50 is installed on the swing arm 10 to adjust the distance between the slider 30 and the surface of the disk D by the signal transmitted from the measuring means 40.

That is, the focusing means 40 is provided separately from the light converging part including the focusing lens 31 on the slider 30, applies a test signal to each disk D mounted on the main body, and reflects the test signal. By recognizing this, it is possible to measure the depth and thickness of the recording layer 3 of the disc D.

The altitude adjusting means 50 changes the altitude of the swing arm 10 by the value measured as described above, so that the distance between the slider 30 formed at the end of the swing arm 10 and the surface of the disc D is adjusted. Therefore, the depth of focus of the light focused through the focusing lens 31 can be within the thickness of the recording layer 3 of the disk D.

Therefore, each time the disc is mounted in the optical recording and reproducing apparatus, the interval between the appropriate slider of each disc and the disc is determined, thereby making it possible to reproduce and record a clearer signal.

This structure can be applied not only to the conventional far field method, but also to a contact surface recording type disc, i.e., so-called reversal, in which the recording layer 3 of the disc D is formed on the contact surface side with the slider 30 with respect to the center of the thickness thereof. The same applies to the method of using the disk of the structure, and also to the case of the near field method in which the slider 30 is installed to scan the track of the disk D while being floated against the disk D by pneumatic pressure. Can be.

Here, the altitude adjusting means 50 may be formed anywhere as long as the altitude of the swing arm 10 can be adjusted. However, the altitude adjusting means 50 is installed in the actuator 20 provided for the reciprocating rotation of the swing arm 10. It is preferable in that the present invention can be easily implemented without greatly modifying the structure of the present invention.

In addition, since the altitude adjustment of the swing arm 10 by the altitude adjustment means 50 of the present invention is performed at very fine intervals, by a simple method of converting the electrical signal transmitted from the focus measuring means 40 into thermal energy. In order to implement the altitude adjustment of the swing arm 10, it is preferable to apply a bimetal or shape memory alloy to the altitude adjustment means.

In addition, the present invention can be applied not only to the optical recording and reproducing method, but also to the recording and reproducing method of the magneto optic method, which uses an optical method and an electromagnetic method as a method of recording or reproducing a signal of a disc. Of course, it can be applied.

The present invention provides an optical recording / reproducing apparatus having a structure that enables the focusing of light focused by a focusing lens of a slider to be accurately formed on a recording layer of a disk.

Claims (6)

A transmitter / receiver for recording or reproducing information by irradiating and entering light, a swing arm mounted on the main body so as to be reciprocally rotated, an actuator providing rotational driving force to the swing arm, and the swing 10. An optical recording and reproducing apparatus, comprising: a slider provided at an end of a disk side of an arm; and a focusing lens attached to the slider to focus light irradiated from the light transmitting and receiving section to enter a recording layer of the disk. A focus installed on the slider to apply a test signal to the recording layer of the disc and to recognize the test signal reflected from the recording layer of the disc, and to measure whether the focus depth of the focusing lens matches the recording layer of the disc. Measuring means; An altitude adjusting means installed on the swing arm to adjust a distance between the slider and the surface of the disk by a signal transmitted from the measuring means; An additional optical recording and reproducing apparatus. The method of claim 1, The slider is installed to scan the track of the disk while floating against the disk by pneumatic pressure, And the disc is a contact surface recording type disc in which a recording layer is formed on the contact surface side with the slider with respect to the center of the thickness thereof. The method of claim 1, And the altitude adjusting means is installed in the actuator. The method of claim 3, And the altitude adjusting means is a bimetal. The method of claim 3, And the altitude adjusting means is a shape memory alloy. The method according to any one of claims 1 to 5, A magnetic coil mounted to the disk side facing surface of the slider; Reproducing or recording means for transmitting and receiving an electrical signal with the magnetic coil; High density optical recording and reproducing apparatus configured to include.