KR100652561B1 - Near-field recording and reproducing device - Google Patents

Abstract

The present invention relates to a near field optical recording and reproducing apparatus, comprising: a first objective lens for focusing a part of light generated from a light source onto a solid imaging lens and reflecting a part of light at a reflection part; A second objective lens for focusing the light reflected from the objective lens, a photo detector for detecting the light focused on the second objective lens to generate a position signal of the first objective lens, and a position signal generated by the photo detector A near field optical recording and reproducing apparatus is provided with a gap holding means of an optical head comprising position correction means for correcting a position of said first objective lens by receiving a. According to the present invention, it is possible to maintain an accurate gap between the disk and the optical head in an easier and more accurate way. In particular, it ensures that the correct gap between the disc and the head remains stable against shock caused by disturbance or other unstable conditions in the drive, and it is possible to easily recover the gap between the disc and the head without performing the initial flying operation. And improve the playback quality.

Description

Near-field optical recording and reproducing device {NEAR-FIELD RECORDING AND REPRODUCING DEVICE}

1 is a device diagram showing an embodiment of the present invention.

Fig. 2 is a schematic diagram illustrating the gap retention between the optical head and the disc according to the present invention.

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

1: first objective lens 2: second objective lens

3: solid emulsion lens 5: port detector

9: piezo (PZT) 10: optical head assembly

20: recording and playback head 21: disc

The present invention relates to a near field optical recording and reproducing apparatus, and more particularly to a gap holding means of an optical head.

These days, recording capacity of computer hard disks and auxiliary storage devices of computer peripherals is rapidly developing. This is due to the rapid development of the network and the development of scientific civilization, which is due to the database of recording and retaining a large amount of image information and data information that was not previously thought. In the case of hard disks, the annual growth rate is about 60% compared to the previous year's record capacity, and optical disc drives for computer-assisted storage devices have a capacity of several to tens of gigabytes. However, storage capacity at the same level as hard disks and optical disk drives for computer auxiliary storage has limitations in terms of storage capacity. Based on these technical backgrounds, near-field recording, which is emerging as a next-generation data storage device these days, is not only able to accommodate a large amount of data information as a future information storage device, but also sufficient for a future lifestyle. It is settled as a technology to cope with. For example, it is a technology that can be easily applied to all products that pursue miniaturization, mobility and convenience. In advanced countries such as the United States and Japan, research on this is being actively conducted, whereas in Korea, technical research is not even at the beginning level. However, since a global unified standard for such high density technology, especially near field recording technology, has not yet been prepared, it is very important and urgent to provide a foundation to lead the technology in the specification establishment by preempting important technology. Therefore, it is necessary to secure the fundamental technology such as recording and reproducing the near field recording technology as soon as possible, and to prepare technology for each part such as recording head, media, and operation method so that it can be commercialized as soon as possible.

In the near field optical recording and reproducing optical system, maintaining the gap between the disk and the optical head is very important and keeping the gap constant at about 1/4 wavelength (tens of nanometers) or less. If the gap is not kept constant, in the near field optical recording and reproducing optical system, the intensity of light decreases exponentially and the spot diameter of the beam greatly increases, making it difficult to record and reproduce high density near field light. This gap retention between the disc and the optical head is not only used for recording and playback of near-field light, which is commonly referred to as ultra-high density recording and playback, such as Scanning Probe Micro Scope or Atomic Force Micro Scope. This is a very important part of the next generation of recording methods.

In addition, in an ultra high density optical recording and reproducing system including near field optical recording, a precision tracking method capable of accurately reading tracks of data for high density recording and reproducing is very important and researches have been actively conducted.

Although no near field recording apparatus has been commercialized in the focusing method, a general trend is to maintain the gap between the disc and the head by floating the recording / playing head by air generated by the rotation of the disc, as in the case of a hard disc. This method has the convenience of not having to use a separate gap-holding servo, but it is very difficult to maintain a constant height due to external impact or uneven air flow in the drive. In particular, it is expected that the ultra-high density storage device will be used as a portable device, but in this case, it is difficult to maintain the near field gap in case of disturbance due to an impact. In addition, it is not easy to maintain the gap again when disturbance is removed.

Due to such unstable gap retention, many problems may occur in recording and reproducing the disc at a very high density. Therefore, in the near field optical recording and reproducing system, a more precise and stable gap holding means is required even if a sudden shock such as disturbance occurs.

It is an object of the present invention to provide an optical head gap holding means for maintaining a gap between an optical head and a disk in a simpler, more efficient and accurate manner in an ultra high density optical recording and reproducing system such as near field.

The near field optical recording and reproducing apparatus according to the present invention for achieving the above object is to focus a part of the light generated from the light source to the solid-immersion lens and to reflect the remaining part of the light at the reflection site A first objective lens, a second objective lens for focusing the light reflected from the first objective lens, a photodetector for sensing the light focused on the second objective lens and generating a position signal of the first objective lens; And position correction means for correcting the position of the first objective lens by receiving the position signal generated by the photodetector, wherein the reflecting portion forms a concave shape on an opposite surface of the solid emulsion lens of the first objective lens. It is characterized in that.
The concave portion may be formed within the total reflection angle of the first objective lens and may be reflective coated.
In addition, the position correction means may use a piezo material (PZT), the first objective lens is attached to the optical head may be installed separately from the second objective lens.

delete

delete

By such a configuration, the present invention can further increase the accuracy by providing a simple optical system in the recording / reproducing head without using a gap holding servo and using an objective lens in the optical head assembly. In addition, the use of piezoelectric material (PZT) allows structurally simple yet precise gap retention.

Light entering the lens at an angle greater than or equal to the critical angle is totally reflected inside the light instead of traveling to the next path as it progresses from a dense refractive index to a small area. At this time, due to total reflection of light, very small intensity of light exists on the surface of the lens. This is called an evanescent wave. Using this evernet wave, it is possible to achieve high resolution, which is impossible because of the diffraction limit, the absolute limit of resolution due to light diffraction in the far-field. Basically, near-field light is confined to an area much smaller than the wavelength of light, so the uncertainty principle makes its physical properties completely different from the remote 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 to a disk.

In the near field optical system for recording and reproducing in such a manner, the gap holding means according to the present invention will be described with reference to the accompanying drawings.

1 is a block diagram showing the technical configuration of the present invention. There is an optical head assembly 10 in the recording / reproducing head 20. The optical head assembly 10 is a laser diode 8, a collimation lens 7, a beam splitter, which is a light source 8, as a basic optical system. (4) and a solid emulsion lens (3) which totally reflects the focused light in a region at or above a critical angle of the first objective lens (1) and the first objective lens (1) to generate everbernant waves on the surface. . A concave portion is formed in the center of the image opposite to the solid emulsion lens of the first objective lens 1. This configuration prevents light from spreading and effectively focuses the reflected beam on the second objective lens 2 described later. In particular, the concave portion is preferably formed within the total reflection angle of the first objective lens 1. In addition, a concave portion is subjected to a reflective coating. This prevents the light generated from the light source 8 from entering the solid emulsion lens 3 through the region within the total reflection angle, and is used to maintain the gap of the present invention as described later by using the reflected light. In the near field optical recording and reproducing apparatus using the solid emulsion lens 3, the totally reflected light is used. Since light within the total reflection angle acts as a noise, it is necessary to block the incident to the solid emulsion lens 3. The recording and playback head 20 is fixed to maintain a physically constant distance from the disk 21.

The optical head assembly 10 is fixed in the recording / reproducing head 20 by a piezo material (PZT) 9 and is fixed by the piezo 9 in a x, y, z direction, i.e., in the horizontal and vertical directions. It is possible to move. In order to accurately maintain the gap between the disc 21 and the solid emulsion lens 3, the recording / reproducing head 20 includes a simple optical system in addition to the optical head assembly 10. The optical system may have various configurations, but in the present invention, the second objective lens 2 and the photo detector 5 are basically components. This optical system has a focus position on the coating layer of the first objective lens 1. Although not shown in the drawing, the optical signal sensed by the photodetector 5 is converted into an electrical signal to calculate a difference from a reference value, and the result is transmitted to a piezoelectric element (PZT) 9 which is a piezoelectric element in the optical head assembly. Control means for transmitting is included.

Referring to the specific gap holding method according to the present invention having such a configuration as follows.

The optical system, that is, the second objective lens 2 and the photodetector 5, which are separately provided, has the first objective lens 1 when the gap between the disk 21 and the solid emulsion lens 3 is accurately maintained at a predetermined interval. The beam reflected from the concave portion (reflective coating process) of the lens surface formed within the critical angle of the lateral plane accurately passes on the photodetector 5 past the second objective lens 2 on the opposite side to maintain a stable state. The part shown with the solid line in FIG. 2 shows this.

However, when the optical head assembly 10 is unstable due to an unstable state inside or outside the drive such as a disturbance, that is, when the concave portion formed on the surface of the lens moves by a distance h1 as shown in FIG. 2, the photodetector 5 ), Defocus occurs by the distance h2. This is indicated by the dashed-dotted line. This defocusing amount is fed back to the piezo 9 by the control means to correct the distance, thereby maintaining a constant gap.

In the operation of the optical head assembly, when a flying head is used like a conventional hard disk, pitching or rolling due to flying of the head cannot be avoided, so it is disadvantageous for ultra high density recording and reproduction. The recording / playback head located at a certain distance from the top of the disc and the optical head assembly installed inside the head move only vertically or horizontally by the piezo in the recording / playback head to prevent pitching or rolling of the head, so that more accurate data recording and playback Can be done.

According to the present invention, it is possible to maintain an accurate gap between the disc and the optical head in a near field optical recording and reproducing system that performs recording and reproduction of ultra high density, so that recording and reproducing can be performed more easily and accurately. Accurate gap between disc and head is maintained stably against shock caused by disturbance or other unstable conditions in the drive, and the gap between disc and head can be easily restored without performing the initial flying operation. To improve.

Claims (6)

delete A first objective lens for focusing a part of the light generated from the light source to a solid imaging lens and reflecting a part of the light at the reflection part; A second objective lens for focusing light reflected from the first objective lens; A photo detector for detecting a light focused on the second objective lens and generating a position signal of the first objective lens; And position correction means for correcting the position of the first objective lens by receiving the position signal generated by the photo detector. And the reflecting portion is formed in a concave shape on the opposite surface of the solid emulsion lens of the first objective lens. The method of claim 2, And the concave portion is formed within the total reflection angle of the first objective lens. The method of claim 2, The near field optical recording and reproducing apparatus, wherein the concave portion is formed by reflecting coating. The method of claim 2, And said position correction means uses piezo material (PZT). The method of claim 2, And the first objective lens is attached to the optical head and installed separately from the second objective lens.

Images