KR20010034277A - System, method and information carrier for laser-stimulated magnetic recording - Google Patents

Abstract

The magnetic disk has a layer structure having a recordable layer 110 and a reflective layer 112. Laser induced recording is generated by the magnetic head 102 which blocks the laser beam by a small portion. The converging laser beam passes through the recording layer and is reflected by the reflective layer, thereby reaching its focus inside the recording layer. The head receives only a portion of the radiation. Such a configuration makes it possible to maintain the head temperature well.

Description

SYSTEM, METHOD AND INFORMATION CARRIER FOR LASER-STIMULATED MAGNETIC RECORDING}

The present invention relates to laser induced magnetic recording of an information carrier.

Laser induced magnetic recording enables high density magnetic recording. The small spot inside the magnetic recording layer is heated by the laser beam in such a way that the amount of energy provided by the magnetic head and required to record information in this spot is significantly reduced for the recording process at room temperature. Numerous configurations are known for magnetic heads and optical heads for implementing such laser induced recordings, which will be briefly described below.

U.S. Incorporated herein for reference. Patent 5,565,385 discloses a structure having a magnetic head disposed on one side of the cross media and an optical head for local heating disposed on the other side of the medium. Such a structure requires two very precise interacting subsystems to position the magnetic head and the optical head.

U.S. Incorporated herein for reference. Patent 5,307, 328 discloses another structure in which a laser head and a magnetic head are arranged on the same side of the recording medium. This document describes an apparatus for recording, reading or erasing on a recording medium. The apparatus has a coil disposed between the objective lens and the recording medium. Optical radiation is focused on the spot and the converging beam passes through the coil opening. The core of the transparent material is disposed inside the winding opening, which has a refractive index that significantly reduces the verbosity of the focused beam. As a result, the diameter of the coil can be reduced, allowing for an increase in the generated magnetic field. This known structure works well within certain parameter ranges, but has some problems when the device for recording and reading is made smaller to obtain higher data density on the record carrier. For example, the laser power per unit area squeezed through the transparent core increases as the size of the device decreases, thereby heating the core, eventually the magnetic head, and as its temperature increases, its performance deteriorates. .

U.S. Incorporated herein for reference. 5,193,082 relates to another structure. In this document, a system in which a magnetic head and an optical head are integrated into one unit is disclosed. This unit has one ferrite block. The optical system is integrated inside the surface of the block with the actual optical head at one end. The optical system has a laser diode, a waveguide and a diffractometer. The optics and the actual magnetic head are placed next to each other. The diffractometer and the magnetic head face the recording medium. The diffractizer focuses the laser beam inside the waveguide at a point on the record carrier where the magnetic head exhibits a magnetic field. Such a structure likewise has some problems. Units in such a structure require a relatively large ferrite block as a substrate. As a result, the maximum speed at which the unit can move is overly determined by the inertia of the block. Moreover, a laser beam is incident on the recording medium under a substantial angle. Since the cross section of the beam perpendicular to its axis is much smaller than the cross section of the irradiated spot on the medium, a more powerful diode is needed to achieve the same energy density as in vertical irradiation. In addition, the skew of the laser beam incident on the surface of the recording medium causes undesirable interference that can quench light at one spot and amplify the light at another spot. This provides uneven heating that cannot be well controlled and can even adversely affect the material of the recording medium.

(Purpose of invention)

Finally, it is an object of the present invention to provide an alternative to the conventional write approach. Still another object of the present invention is to provide a structure for solving the problems of the prior art.

(Summary of invention)

For this purpose, the present invention provides an information processing system for reading and / or recording the information content of a recordable medium by applying a magnetic field and electromagnetic radiation to the recordable medium. The system includes a magnetic head for generating a magnetic field and a radiation source for generating radiation. During use of the system, the magnetic head is placed almost inside the beam, causing the recordable medium to be subjected to electromagnetic radiation passing out of the magnetic field. For example, the unblocked beam has a disc shaped cross section. When the magnetic head is placed inside the beam, the cross section of the beam is partially blocked by the head, so that it has a substantially annular or nearly u-shaped cross section, for example in the plane of the head. Preferably, the optical path of the beam has a path such that the magnetic head does not absorb some of the electromagnetic radiation, but the radiation is guided along the magnetic head. Since the magnetic head is small compared to the size of the beam cross section, the focal point formed by the beam has sufficient quality for scanning the recording medium.

Preferably, a reflective recording medium is provided in operation of the system. The recordable medium is disposed between the magnetic head and the radiation source on one side and the reflective medium on the other side. The reflective medium reflects the radiation toward the magnetic head side and condenses the radiation near the magnetic head when reflected and coming from the other side. The recordable medium and the reflective medium are arranged such that the length of the optical path of the radiation reflected from the reflective medium to the condensing area of the radiation in the recordable medium is much larger than the wavelength of the radiation.

Preferably, both recordable and reflective media are integrated inside a physical device, for example a magnetic disk, to interact with the system in operation.

The system may have a lens that adjusts the main direction of radiation, and the magnetic head is mounted inside the lens.

The invention also relates to a physical device, for example a magnetic disk. The apparatus has a recordable medium that deforms the information content of the recordable medium by splitting the magnetic field generated on the first side of the recordable medium and the electromagnetic radiation generated on the first side of the recordable medium. The apparatus has a reflective medium on a second side of the recordable medium and not on the first side to reflect the radiation towards the recordable medium. The recordable medium and the reflective medium are arranged such that the length of the optical path of the radiation reflected from the reflective medium to the condensing area of the radiation in the recordable medium is much larger than the wavelength of the radiation. The recordable medium may comprise, for example, pre-recorded information that may be added or overwritten.

The invention also relates to a method of processing information. The method includes generating a magnetic field through the magnetic head and generating electromagnetic radiation through the radiation source. The recordable medium is subjected to the combination of magnetic field and radiation to modify the information content of the recordable medium. Such a process to be subjected to the magnetic field and radiation includes a process of operating the magnetic head between the radiation source and the recordable medium to partially block the cross section through which the radiation passes. Reflective media are used to reflect the radiation, and the recordable media is disposed between the reflective media and the magnetic head. The recordable medium and the reflective medium are arranged such that the length of the optical path of the radiation reflected from the reflective medium to the condensing area of the radiation in the recordable medium is much larger than the wavelength of the radiation.

The present invention proposes to use a structure having a laser and a magnetic head on the same side of a recordable medium. A mirror is used on the opposite side of the recording medium so that the mirror receives and reflects a laser beam through the recordable medium so that the reflected beam is focused on or within the recording medium near the magnetic head. The mirror and the magnetic recording medium are preferably present at functionally constant distances from each other such that the length of the optical path is substantially constant. The optical path is larger than the wavelength of the radiation used.

The mirror is preferably physically integrated with a substrate contained within the mechanical support. The recording layer is for example placed on a thin sheet (e.g., thickness of 0.1 mm-0.2 mm) having a precisely adjusted thickness. This sheet is attached to the substrate. This disk has a mirror on one side of the thin substrate and a magnetic recording layer on the other side of the substrate. Thereafter, such a substrate is attached to a thicker and stronger support. As a result of the above arrangement, after passing through the recordable layer and reflecting off the mirror, it is possible to focus the laser beam on the spot of the recording layer on the opposite side of the magnetic head. As a result, the magnetic head blocks much less laser beam cross-section, which in turn results in a very large amount of radiation, as in some prior art configurations, resulting in a temperature high enough to render the system inoperable. You won't get it.

The invention is explained in more detail with reference to the following accompanying drawings:

1, 2 and 3 show the structure of a system and a recordable device according to the present invention.

Throughout the drawings, the same reference numerals indicate corresponding or similar features.

1 is a view showing the components inside the magnetic recording apparatus 100 of the present invention. System 100 includes a sub-optic system 104 having a magnetic head 102, a radiation source 106 for generating a radiation beam 108, and under combined control of the magnetic head 102 and the radiation source 106. And a recordable medium 110 suitable for recording or erasing information therein. The radiation source 106 is equipped with a laser for using the principle of laser induced magnetic recording as described above, for example. The head 102 and the radiation source 106 lie on the same side, i.e., the bottom side, of the recordable medium 110. The system 100 includes a radial medium 112 that reflects radiation incident thereon from the radiation source 106 onto the recordable medium 110. The magnetic head 102 is disposed inside the optical path between the radiation source 106 and the recordable medium 110, blocking the beam 108 only part of it. The recordable medium 110 itself is disposed between the magnetic head 102 and the reflective medium 112. Reflective medium 112 serves to create the focal point 114 of the optical system at a location within the recordable medium 112 directly above (in the drawing) of the head 120. The light path between the radiation source 106 and the focal point 114 includes a portion from the radiation source 106 toward the reflective medium 112 and a portion from the reflective medium 112 toward the focal point 114. This optical path is longer than the length from the radiation source 106 to the underside (in the figure) of the recordable medium 110. Thus, the width of the beam 108 in the plane of the head 102 is much larger than the characteristic size of the head 120, and the head receives only a small portion of the radiation.

Reflective medium 112 may be a stationary component with respect to head 102 such that recordable medium 110 may move relative to head 102 and reflective medium 112. In contrast, the reflective medium 112 and the recordable medium 110 are both integral parts inside a layer structure such as a magnetic disk or tape. This is further explained with reference to FIG.

2 is a diagram of a system 220 in accordance with the present invention. System 200 includes a magnetic disk 202 that houses a recordable medium 110 and a reflective medium 112. This disc 202 has a layer structure in which a recordable medium 110 is disposed between the protective layer 204 and the transparent layer 206. The reflective medium 112 is disposed between the transparent layer 206 and the support substrate 208. The optical path length of the radiation between the recordable medium 110 and the reflective medium 112 is longer than the conventional wavelength of radiation such that the geometric optics provide a proper description of the path. Preferably, the length of the optical path between the recordable medium 11 and the reflective medium 112 is nearly constant. This can be achieved, for example, by placing the media 110 and 112 at approximately the same effective distance and having a transparent layer 206 having a functionally uniform refractive index interposed therebetween and having a functionally constant thickness. Reflective medium 112 may be stacked over substrate 208 using, for example, chemical vapor deposition or other techniques suitable for the purpose as is known in the art. As a result of the above configuration, the laser beam 108 reflected by the mirror 112 can be focused on the recording layer 110 on the magnetic head 102 (on the drawing). Accordingly, the magnetic head 102 blocks much less laser beam than in the conventional structure described above. As a result, the magnetic head does not get a very large amount of radiation, and as a result, does not obtain a temperature high enough to render the system 100 or 200 inoperable.

In a preferred embodiment, the radiation source 106 has a blue laser having a wavelength in the range of, for example, 400 to 500 nm. Reflective medium 112 may be much thinner than layer 206 having a thickness of, for example, 0.1-0.2 mm. To read or write data in a functionally small area, the sub-optical system 104 uses a high-NA lens, i.e., an NA of 0.8. For tracking, an NA of 0.4 is already available. Layer 206 may be a thin sheet with a well controlled thickness such that the optical path through layer 206 (2 times its thickness multiplied by its refractive index) is approximately constant. The layer 206 may be provided with a spare groove in the magnetic recording layer for servo purposes (for example, a circular or spiral groove such as present in a CD or a land / groove such as in a DVD-RW / RAM).

The system 100 or 200 described above is an automated device that allows a customer to create a compilation of their own content (eg, audio or video) by recording information selected by the customer on a recordable medium 110. It may be a vending machine.

3 shows an implementation 300 of systems 100 and 200. In implementation 300, the magnetic head 102 is physically coupled, eg merged, or mounted over the lens within the lens to focus the radiation beam 108. The position of the lens 304 and the magnetic head 102 may be controlled via one actuator (not shown). The radiation beam 108 incident on the lens 304 is an annular beam, ie radiation is focused inside the annular area while almost no radiation passes through the area 305 inside the annular area.

Claims (9)

An information processing system (100) for modifying information content of a recordable medium by splitting a magnetic field and a beam of electromagnetic radiation (108) onto the recordable medium (110), The system, A magnetic head 102 for generating a magnetic field, A radiation source 106 for generating radiation, During use of the system, the magnetic head is placed inside the beam such that the recordable medium is subjected to electromagnetic radiation passing out of the magnetic field. The method of claim 1, A reflective record carrier 112 is provided in operation of the system, The recordable medium is arranged between the magnetic head and the radiation source on one side and the reflective medium on the other side, The reflective medium is operative to reflect the radiation towards the magnetic head side to focus radiation 114 near the magnetic head when reflected and coming from the other side, The recordable medium and the reflective medium are arranged such that the length of the optical path of the radiation reflected from the reflective medium to the condensing area of the radiation in the recordable medium is much larger than the wavelength of the radiation. . The method of claim 2, Both recordable and reflective media are integrated within a physical device (202) to interact with the system in operation. The method of claim 3, wherein And the physical device comprises a magnetic disk. The method of claim 1, The system comprises a lens 304 for adjusting the main direction of radiation, An information processing system wherein the magnetic head and the lens comprise one component. A magnetic field generated on the first side of the recordable medium and the radiation 108 generated on the first side of the recordable medium are split, thereby transforming the information content of the recordable medium, A reflective medium 112 on the second side of the recordable medium and not on the first side, for reflecting radiation towards the recordable medium, A recordable medium and a reflective medium are physical devices characterized in that the length of the optical path of the radiation reflected from the reflective medium to the condensing region of the radiation in the recordable medium is much greater than the wavelength of the radiation ( 202). The method of claim 6, A physical device comprising a magnetic disk. The method of claim 6, The recordable medium has physically recorded information. Generating a magnetic field through the magnetic head 102, Generating electromagnetic radiation via the radiation source 106, Subjecting the recordable medium 110 to a combination of magnetic field and radiation, in order to modify the information content of the recordable medium, wherein the step of subjecting to the magnetic field and radiation, Operating the magnetic head between the radiation source and the recordable medium to partially block radiation; Using the reflective medium 112 to reflect the radiation such that the recordable medium is disposed between the reflective medium and the magnetic head, The recordable medium and the reflective medium are arranged such that the length of the optical path of the radiation reflected from the reflective medium to the condensing region of the radiation in the recordable medium is much larger than the wavelength of the radiation. .