KR101108680B1 - Method and apparatus for reproducing data from super resolution information storage medium - Google Patents

Abstract

A method and apparatus for reproducing a super resolution information storage medium are disclosed. A method for reproducing data recorded on a super resolution information storage medium according to the present invention includes a first beam having a power to cause a super resolution phenomenon at different positions of the super resolution information storage medium and not causing the super resolution phenomenon. Irradiating a second beam with power, respectively; Detecting a first reproduction signal by the first beam and a second reproduction signal by the second beam; And obtaining a differential signal between the first reproduction signal and the second reproduction signal. According to the present invention, the quality of the reproduction signal can be improved by reducing the influence of inter-signal interference by excluding the reproduction signal from the peripheral region of the super resolution region when irradiating a reproduction beam to the super resolution information storage medium.

Super resolution information storage media, inter-signal interference

Description

Method and apparatus for reproducing data from super resolution information storage medium

1 is a view for explaining a region where a super resolution phenomenon occurs in a spot of a reproduction beam irradiated onto a super resolution information storage medium.

Fig. 2A shows an example of a recording pattern recorded with a mark having a size smaller than the resolution and a mark having a size larger than the resolution.

FIG. 2B shows an RF signal obtained by reproducing information recorded in the recording pattern of FIG. 2A with a beam of super resolution power.

3 is a schematic cross-sectional view of a super resolution information storage medium according to an embodiment of the present invention.

4 is a diagram illustrating a state in which a beam of super resolution power and a beam of non-resolution power are irradiated onto an information storage medium according to a data reproducing method according to an embodiment of the present invention.

FIG. 5A shows an enlarged view of an area irradiated with a beam when a beam of super resolution power is irradiated onto a super resolution information storage medium according to a data reproducing method according to an exemplary embodiment of the present invention.

FIG. 5B shows an enlarged view of the area to which the beam is irradiated when the non-resolution power beam is irradiated onto the super-resolution information storage medium.

Fig. 6A shows a reproduction signal obtained by irradiating a beam of super resolution power to a mark recorded in the pattern shown in Fig. 2A according to the data reproduction method according to the present invention.

Fig. 6B shows a reproduction signal obtained by irradiating a beam of non-resolution power to a mark recorded in the pattern shown in Fig. 2B according to the data reproduction method according to the present invention.

6C shows the differential signal of FIGS. 6A and 6B.

7A shows a reproduction signal obtained by irradiating a beam of super resolution power to a mark recorded in a random pattern according to the data reproduction method according to the present invention.

Fig. 7B shows a reproduction signal obtained by irradiating a beam of non-resolution power to a mark recorded in a random pattern according to the data reproduction method according to the present invention.

FIG. 7C illustrates the differential signal of FIGS. 7A and 7B.

FIG. 8 illustrates an eye pattern obtained from the differential signal shown in FIG. 7C.

9 is a block diagram of a data reproducing apparatus of a super resolution information storage medium according to an embodiment of the present invention.

10 is a view showing a blazer type grating device according to an embodiment of the present invention.

11 is a block diagram of a data reproducing apparatus of a super resolution information storage medium according to another embodiment of the present invention.

The present invention relates to a method and apparatus for reproducing data recorded on a super-resolution information storage medium. More particularly, the present invention relates to a method for improving the quality of a reproduction signal by reducing interference between reproduction signals obtained from the super-resolution information storage medium. A method and apparatus for reproducing data in a marine information storage medium.

Optical recording media are widely used as high density recording media because the required recording area per recording unit is very small compared to conventional magnetic recording media. Such optical recording media have a read only memory (ROM) that only plays recorded information, write once read many (WORM), and erase after recording. And ReWritable (RW) that can be rewritten.

One example of a write once type optical recording medium is CD-R (Compact Disc Recordable). The CD-R irradiates a recording layer made of organic dyes such as cyanine and phthalocyanine by irradiating a recording laser beam of 780 nm to cause decomposition of the dye layer, deformation of the substrate and the reflective film, and reading signals recorded with a low power of 1 mW or less. The internal recording medium has a recording capacity of about 650MB and is widely used for recording and reproducing various types of data such as data, music, and images.

However, an optical recording medium using a recording wavelength of 780 nm, such as a CD-R or a CD-RW, is not only insufficient for storing a moving image but also for use in an increasingly complicated multimedia environment.

In order to overcome this problem, a 630 to 680nm short wavelength laser beam was used to realize a cross-section of 2.7 to 4.7 GB, and DVD was also used for playback only (DVD) and write once ( DVD-R) and rewritable (DVD-RAM, DVD + RW, DVD-RW). The DVD-R causes the recording layer to deform and decompose by irradiating the recording layer with the recording laser beam, and the DVD-RAM, DVD-RW and the like cause the change of the optical characteristics due to the phase change to record the data. In particular, attention has been focused on DVD-Rs using organic dyes because of their relative advantages over other media in terms of compatibility, cost and capacity with DVD-ROMs.

The biggest issue in optical recording media is data capacity. Various studies have been attempted to increase this data capacity. The capacity of the optical recording medium depends on how many small-size marks or pits can be accurately reproduced within a given area, and preferentially depends on the characteristics of the laser beam that can accurately reproduce these marks or pits.

Although the laser beam generated from the laser diode is focused through the objective lens of the pickup, the laser beam does not collect to an infinitely small point due to the diffraction effect and has a finite width. In the case of a general optical recording medium, when the wavelength of the laser beam is λ and the numerical aperture of the objective lens is NA (Numerical Aperture), λ / 4NA becomes a limit of the reproduction resolution. Therefore, the recording capacity increases as the wavelength of the light source becomes shorter or the numerical aperture of the objective lens becomes larger.

However, current laser technology has a limitation in providing a laser beam with a short wavelength, there is a limitation in manufacturing cost in order to manufacture an objective lens having a large numerical aperture, and as the numerical aperture of the objective lens increases, the distance between the pickup and the disk is increased. Since the working distance is very short, the surface of the disk is damaged by the collision between the pickup and the disk, which increases the risk of data loss.

If a mark smaller than this resolution can be reproduced, the recording density of the optical recording apparatus can be further increased. Such a technique of reproducing a mark smaller than the resolution is called a super resolution technique. There are two kinds of such super-resolution techniques. One is a magneto-optical recording technique, and the other is a method of enlarging and reproducing the recorded micro-magnets, and the other is a method using a difference in local optical characteristics in a laser spot.

In the latter case, as shown in Japanese Patent Laid-Open No. 1990-096926, it can be said that the purpose is to reduce the size of the effective spot by a nonlinear material that basically changes depending on the incident light intensity. In order to implement this, a wide variety of methods have been attempted for materials of super-resolution data storage media. For example, a method using partial melting of a phase change material (Japanese Patent Publication No. 1993-089511), a method using a Thermochromic material (Japanese Patent Publication No. 1993-242524), a method using a saturable absorbing dye layer (Japanese Patent) Publication No. 1994-243508), a method using a photochromic material (Japanese Patent Publication No. 1994-169057), a method using a crystal-crystal phase change material (Japanese Patent Publication No. 1996-007333), a semiconductor in a semiconductor material or a dielectric matrix Or a method of dispersing metal particles (Japanese Patent Publication No. 1998-320857), a method of using an oxide (Japanese Patent Publication No. 2001-084643), a method using Surface Plasmon (Japanese Patent Publication No. 2001-229544), and the like.

The above methods exploit the difference in optical properties caused by the difference in light intensity in the laser spot or by the difference in temperature distribution of the super resolution layer of the super resolution information storage medium. It will be described in more detail with reference to FIG. As shown in FIG. 1, a mark having a size exceeding a resolution limit because a change in temperature distribution or an optical characteristic occurs due to a partial light intensity difference in a light spot s formed on the super resolution layer of the super resolution information storage medium. Playback can also be performed for (m). In other words, it is considered that the temperature distribution change or the optical characteristic change occurs in the partial region c of the light spot s and the change does not occur in the peripheral region p of the partial region c. The partial region c (hereinafter referred to as a super resolution region) in which the change occurs may be the center portion or the second half portion of the light spot s as shown in FIG. 1.

On the other hand, in order to commercialize a super-resolution information storage medium, it is necessary to satisfy the recording and reproduction characteristics basically required as the storage medium. In particular, since super resolution data storage media use recording and reproduction beams having a relatively higher power than general information storage media, reproduction signal characteristics such as signal-to-noise ratio (CNR), jitter characteristics, and RF signals are obtained. Implementing stability is a major challenge for super-resolution data storage media.

However, referring to FIG. 1, the signal reflected from the recording mark m includes not only the signal from the super resolution region c of the light spot but also the signal reflected from the peripheral region p. If there is no signal reflected in the peripheral area p, since the size of the substantially effective light spot is reduced, it is possible to reproduce marks having different lengths, and the reproduction signal characteristics must be satisfied. However, the reproduction signal characteristics came out poorly. This is because the beam of the peripheral area p of the light spot is also reflected and detected as a signal, and this signal generates inter-symbol interference (ISI).

FIG. 2A shows a recording pattern of a mark recorded on an information storage medium, and FIG. 2B shows an RF signal reproducing a mark of this pattern. The recording pattern shows a recording pattern according to a combination of a 75 nm long mark smaller than the resolution and a 300 nm long mark and space when the laser beam has a wavelength of 405 nm, an NA of 0.85, and a resolution of approximately 119 nm. Looking at the reproduction signal shown in Fig. 2B, it can be seen that when the 300 nm long mark or space is around the optical spot, the 75 nm long mark is not clearly detected due to the influence of this mark and the space. In addition, it can be seen that the level of the reproduction signal varies depending on the number of 75 nm marks and spaces. Further, when there is a 75 nm long mark and a space, the signal level is not constant but detected with a slope depending on the situation around the mark. The above-mentioned problems are caused by the ISI due to the signal obtained from the peripheral region p in addition to the super resolution region c of the light spot s.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and when the superbeam information storage medium is irradiated with a reproduction beam, the reproduction signal from the peripheral region of the superresolution region is excluded to reduce the influence of inter-signal interference, thereby improving the quality of the reproduction signal. It is an object of the present invention to provide a method and apparatus for reproducing data of a super resolution information storage medium which can be improved.

In order to solve the above problems, a method for reproducing data recorded on a super-resolution information storage medium according to an aspect of the present invention,

Irradiating a first beam having a power causing a super resolution phenomenon and a second beam having a power not causing the super resolution phenomenon at different positions of the super resolution information storage medium; Detecting a first reproduction signal by the first beam and a second reproduction signal by the second beam; And obtaining a differential signal between the first reproduction signal and the second reproduction signal.

According to another aspect of the present invention, the obtaining of the differential signal includes compensating a time difference between the first reproduction signal and the second reproduction signal.

According to another aspect of the invention, the step of irradiating the first beam and the second beam, respectively, the beam emitted from one light source by using a spectroscopic element to the beam to the first beam and the second beam Spectroscopy.

According to another aspect of the present invention, in the spectroscopic step, a + k-th diffraction beam is used as the first beam among the plurality of diffraction beams generated from the spectroscopic element, and a -k-th diffraction beam is converted into the second beam. I use it.

According to another aspect of the present invention, in the spectroscopic step, a -k-d diffraction beam is used as the first beam among the plurality of diffraction beams generated from the spectroscopic element, and a + k-th diffraction beam is converted to the second beam. I use it.

According to another aspect of the invention, the spectroscopic element is a blazer type grating element.

According to another aspect of the invention, the first beam and the second beam are irradiated along the same track.

According to another aspect of the invention, the first beam and the second beam is irradiated from the first light source and the second light source provided independently.

In order to solve the above problems, a method for reproducing data recorded on a super-resolution information storage medium according to another aspect of the present invention,

Irradiating, at different positions of the super resolution information storage medium, a super resolution beam having a power causing a super resolution phenomenon and a plurality of non-resolution beams having a power not causing the super resolution phenomenon; Detecting a super resolution reproduction signal by the super resolution beam and a plurality of non-resolution reproduction signals by the plurality of non-resolution beams; And obtaining a differential signal between the super resolution reproduction signal and the plurality of non-resolution reproduction signals.

According to another aspect of the present invention, obtaining the differential signal includes compensating a time difference between the super resolution reproduction signal and the plurality of non-resolution reproduction signals.

According to another aspect of the present invention, the step of irradiating the super-resolution beam and the plurality of non-resolution beams, respectively, the beam emitted from one light source using a spectroscopic element to beam the beam and the plurality of super-resolution beams Spectroscopy with non-resolution beams.

According to another aspect of the invention, the super resolution beam and the plurality of non-resolution beams are irradiated along the same track.

According to another aspect of the invention, the super resolution beam and the plurality of non-resolution beams are irradiated from the first and second light sources provided independently.

In order to solve the above problems, the apparatus for reproducing the recorded data of the super-resolution information storage medium according to an aspect of the present invention,

Irradiating a first beam having a power causing super resolution and a second beam having a power not causing super resolution at different positions of the super resolution information storage medium, and reflecting from the super resolution information storage medium. An optical pickup configured to photoelectrically change the first beam and the second beam to output a first reproduction signal and a second reproduction signal; And a signal processor outputting a differential signal between the first reproduction signal and the second reproduction signal.

According to another aspect of the invention, the signal processing unit, a compensation unit for outputting the first reproduction signal and the second reproduction signal, the time difference is compensated by compensating the time difference between the first reproduction signal and the second reproduction signal; ; And an operation unit configured to perform a differential operation between the first reproduction signal compensated for the time difference and the second reproduction signal to output the differential signal.

According to another aspect of the invention, the optical pickup, the light source; And a spectroscopic element for spectroscopy the beam emitted from the light source into the first beam and the second beam.

According to another aspect of the present invention, the first beam corresponds to a + k-th diffraction beam among a plurality of diffraction beams generated from the spectroscopic element, and the second beam corresponds to a -k-th diffraction beam.

According to another aspect of the present invention, the first beam corresponds to a -k diffraction beam among a plurality of diffraction beams generated from the spectroscopic element, and the second beam corresponds to a + k diffraction beam.

According to another aspect of the invention, the spectroscopic element is a blazer type grating element.

According to another aspect of the invention, the optical pickup irradiates the first beam and the second beam along the same track of the super resolution information storage medium.

According to another aspect of the present invention, the optical pickup includes a first light source for irradiating the first beam and a second light source for irradiating a second beam.

According to another aspect of the invention, the first light source and the second light source is characterized in that composed of a module.

In order to solve the above problems, an apparatus for reproducing super-resolution information storage medium recorded data according to another aspect of the present invention,

Irradiating a super-resolution beam having a power causing a super-resolution phenomenon and a plurality of non-resolution beams having a power not causing the super-resolution phenomenon at different positions of the super-resolution information storage medium, respectively, and performing the super-resolution information storage medium. An optical pickup configured to photoelectrically change the super resolution beam and the plurality of non super resolution beams reflected from the optical output to output a super resolution reproduction signal and a plurality of non super resolution reproduction signals; And a signal processor for outputting a differential signal between the super-resolution playback signal and the plurality of non-resolution playback signals.

According to another aspect of the present invention, the signal processing unit may compensate for the time difference between the super-resolution playback signal and the plurality of non-resolution playback signals to compensate for the time difference, the super-resolution playback signal and the plurality of non-resolution playback signals. Compensation unit for outputting the field; And an operation unit configured to perform a differential operation between the super resolution reproduction signal compensated for the time difference and the plurality of non-resolution reproduction signals to output the differential signal.

According to another aspect of the invention, the optical pickup, the light source; And a spectroscopic element for spectroscopy the beam emitted from the light source into the super resolution beam and the plurality of non-resolution beams.

According to another aspect of the invention, the optical pickup is characterized in that to irradiate the super-resolution beam and the plurality of non-resolution beams along the same track of the super-resolution information storage medium.

According to another aspect of the invention, the optical pickup includes a first light source for irradiating the super-resolution beam and a second light source for irradiating the plurality of non-resolution beams.

According to another aspect of the invention, the first light source and the second light source is characterized in that composed of a module.

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

The data reproducing method according to the present invention is applied to a super resolution information storage medium capable of reproducing information recorded with a recording mark or pit having a size exceeding a resolution limit.

Prior to describing the playback method and apparatus according to the present invention, an example of a super-resolution information storage medium will be described.

Referring to FIG. 3, the super resolution information storage medium 30 includes a substrate 31, a first dielectric layer 33, a recording layer 35, and a second dielectric layer 39 sequentially formed on the substrate 31. And a super resolution reproduction layer 41, a third dielectric layer 43 and a cover layer 45. Here, the beam used for recording / reproducing information is incident on the cover layer 45 while being focused by the objective lens OL.

The substrate 31 is made of any one material selected from polycarbonate, polymethyl methacrylate (PMMA), amorphous polyolefin (APO), and glass material, that is, one surface of the first dielectric layer 33. It is preferable that a reflective film is coated on the surface facing the incident beam.

The first to third dielectric layers 33 and 39 and 43 are layers for controlling optical and / or thermal characteristics. The cover layer 45 is a layer formed to cover the layers formed on the substrate 31 including the recording layer 35 and the super resolution reproduction layer 41. Here, the first to third dielectric layers 33, 39 and 43 and the cover layer 45 are not essential components, and the information can be reproduced even if these layers are not present.

The first to third dielectric layers 33 and 39 and 43 are preferably made of at least one of an oxide, a nitride, a carbide, a sulfide, and a fluoride. That is, the first to third dielectric layers 33 and 39 and 43 are silicon oxide (SiOX), magnesium oxide (MgOx), aluminum oxide (AlOx), titanium oxide (TiOx), vanadium oxide (VOx), and oxide. Chromium (CrOx), Nickel Oxide (NiOx), Cornium Nitride (ZrOx), Germanium Oxide (GeOx), Zinc Oxide (ZnOx), Silicon Nitride (SiNX), Aluminum Nitride (AlNx), Titanium Nitride (TiNx), Nitride Consists of at least one material selected from cornium (ZrNx), germanium nitride (GeNx), silicon carbide (SiC), zinc sulfide (ZnS), zinc sulfide-silicon dioxide compound (ZnS-SiO2), and magnesium fluoride (MgF2) It is preferable.

The recording layer 35 has a structure such that the cross-sectional shape of the recording mark m recorded by the beam incident at a predetermined recording power becomes a rectangular shape or a shape close to the rectangular shape. Here, the recording mark m includes a mark having a size less than or equal to the resolution of the optical pickup used for reproduction.

Here, in order to repeatedly reproduce the data by using the super resolution phenomenon, the chemical reaction temperature Tw in the recording layer 35 is higher than the temperature Tr at which the super resolution phenomenon occurs in the super resolution reproduction layer 41. high.

Therefore, in order to form the recording mark m, the recording layers 35 have at least two materials having different physical properties from each other and chemically reacting with each other at a predetermined temperature (for example, two types A and B shown in FIG. 3). Material) is a layer of a one-layer structure formed by mixing.

As an example, the recording layer 35 in which the materials A and B are mixed is described. Before the recording, that is, before the chemical reaction occurs between the materials A and B, the recording layer 35 is mixed with the materials A and B. It has a membrane shape. On the other hand, when a recording beam having a predetermined power is irradiated onto the recording layer 35, at the site where the light spot is formed by the beam of the recording power, the substances A and B undergo a mutual chemical reaction, and the substances A and B Is a compound A + B of the physical properties different from the mixed form. Compound A + B modified in this way forms a recording mark m, which has a different reflectance when compared with other regions.

Here, an example of the material A may be tungsten (W), and an example of the material B may be silicon (Si). This is determined in consideration of the fact that when a Ge-Sb-Te material is used as the super-resolution reproducing layer to be described later, the temperature at which the super-resolution phenomenon occurs during regeneration is approximately 350 ° C. and should be recorded above this regeneration temperature. That is, since the reaction temperature of the W-Si alloy is approximately 600 ℃, it is not affected by the regeneration power.

In this case, when the W and Si materials are selected, it is preferable to form the recording layer 35 by mixing the atomic ratio between the two materials to be W: Si ≒ 1: 2 in consideration of the atomic weight and density difference between the two materials. . In this case, when a chemical reaction occurs, a predetermined region of the recording layer 35 formed in the beam of the recording power becomes a WSi ₂ compound. Here, the atomic ratio between W and Si is only an example, and is not limited to this.

In addition, the material of the recording layer has been described as an example of two materials, W and Si, but this is only an example, and a substance capable of chemical reaction at a temperature higher than the above regeneration temperature within a recordable temperature range by a laser beam. It is possible to select two or more materials arbitrarily within these ranges. For example, vanadium (V), chromium (Cr), cobalt (Co), nickel (Ni), copper (Cu), germanium (Ge), selenium (Se), niobium (Nb), molybdenum (Mo), silver (Ag) ), Tin (Sn), antimony (Sb), tellurium (Te), titanium (Ti), zirconium (Zr) and may include at least two or more materials selected from lanthanum-based elements.

The super-resolution reproduction layer 41 is a layer made of a phase change material having a property of changing temperature distribution or optical characteristics of a part of the incident beam spot. That is, the super-resolution phase regeneration layer 41 is composed of a chalcogenide phase change material that is a material containing at least one of sulfur (S), selenium (Se), and tellurium (Te). desirable.

For example, the super-resolution regeneration layer 41 is selenium-sulfur (Se-S), selenium-tellurium (Se-Te), sulfur-tellurium (S-Te), phosphorus-sulfur (PS), in-tel Rulium (P-Te), phosphorus-selenium (P-Se), arsenic-sulfur (As-S), arsenic-selenium (As-Se), arsenic-tellurium (As-Te), antimony-sulfur (Sb- S), antimony-selenium (Sb-Se), antimony-tellurium (Sb-Te), silicon-sulfur (Si-S), silicon-selenium (Si-Se), silicon-tellurium (Si-Te), Germanium-sulfur (Ge-S), germanium-selenium (Ge-Se), germanium-tellurium (Ge-Te), tin-sulfur (Sn-S), tin-selenium (Sn-Se), tin-tellurium (Sn-Te), silver-sulfur (Ag-S), silver-selenium (Ag-Se), silver-tellurium (Ag-Te), aluminum-sulfur (Al-S), aluminum-selenium (Al-Se ), Aluminum-tellurium (Al-Te), gallium-sulfur (Ga-S), gallium-selenium (Ga-Se), gallium-tellurium (Ga-Te), indium-sulfur (In-S), indium -A compound of selenium (In-Se), indium tellurium (In-Te), or a compound containing at least one element thereof.

Preferably, the super-resolution regeneration layer 41 is made of germanium-antimony-tellurium (Ge-Sb-Te) or silver-indium-antimony-tellurium (Ag-In-Sb-Te) phase change material. do.

Accordingly, the super-resolution reproducing layer 41 changes from one crystal phase to another at a predetermined temperature, thereby forming a super resolution region in which a temperature distribution change or an optical characteristic change occurs in a portion of the beam spot, and has a recording mark having a size smaller than the resolution. Information (m) can be reproduced.

As described above, the super resolution region in which the temperature distribution change or the optical characteristic change occurs by the reproduction beam becomes a partial region of the reproduction beam spot, and this partial region may be formed in the center or the second half of the spot.

The above-described super resolution information storage medium 30 is merely an example for explaining a super resolution phenomenon, and the reproducing method according to the present invention can be applied to any information storage medium in which a super resolution phenomenon occurs.

Next, a method of reproducing data recorded on a super resolution information storage medium according to an embodiment of the present invention will be described.

As shown in FIG. 4, the data reproducing method according to the present invention irradiates the super-resolution information storage medium 30 with the first beam B1 having a relatively high power and the second beam B2 having a relatively low power. . Marks m are recorded along the track T of the super resolution information storage medium 30, and the first beam B1 and the second beam B2 are irradiated adjacent to different positions of the same track.

The first beam B1 and the second beam B2 may be generated by spectroscopy of a beam irradiated from one light source using a spectroscopic element or by using two light sources that irradiate beams of different power. As a spectroscopic element, a grating element or a diffraction element such as a hologram may be used.

The first beam B1 has a reproduction power (super resolution power) at which a super resolution phenomenon occurs, and the second beam B2 has a reproduction power (non-resolution power) at which a super resolution phenomenon does not occur, and the first beam (B1). B1) and the second beam B2 are irradiated at the same time. As shown in FIG. 5, in the region irradiated with the first beam B1, a temperature resolution change or an optical characteristic change occurs in a portion c of the entire light spot s, whereby a super resolution phenomenon occurs. In the peripheral region p of (c), no super resolution phenomenon occurs. In the area irradiated with the second beam B2, no super resolution occurs in the entire light spot s.

When the wavelength of the first beam B1 is λ and the numerical aperture is NA1, the resolution of the first beam B1 is λ / (4 * NA1). When one light source is used, the wavelength of the second beam B2 becomes λ equal to the wavelength of the first beam B1, and the second when the numerical aperture of the second beam B2 is NA2. The resolution of the beam B2 is λ / (4 * NA2). The numerical aperture of the beam is defined as the radius of the beam divided by the focal length of the objective lens.

The first beam B1 and the second beam B2 are irradiated to the super resolution information storage medium 30 as described above, and then a reproduction signal is obtained from each beam reflected from the super resolution information storage medium 30. FIG. 6A is a reproduction of the marks recorded in the mark pattern shown in FIG. 2A, and is a first reproduction signal in which a super resolution phenomenon occurs, and FIG. 6B is a second reproduction signal in which a super resolution phenomenon does not occur. The first reproduction signal of the first beam B1 is mixed with the component of the signal ISI of the super resolution region c of the light spot, and the second reproduction signal of the second beam B2 is generated by the ISI. This signal contains a component as a main component.

Subsequently, the first reproduction signal and the second reproduction signal are arithmetic so as to exclude components caused by the ISI. The time delay between the first reproduction signal and the second reproduction signal is compensated for and then computed into a differential signal. 6C illustrates a differential signal between the first reproduction signal and the second reproduction signal.

Referring to FIG. 6C, 75 nm marks and spaces smaller than the resolution are accurately reproduced, and signal levels are constantly detected regardless of the number of marks and spaces. It can also be seen that the 300 nm mark and the space have a constant signal level even when the 75 nm mark and the space are adjacent to each other. In addition, since the flat region at the high level and the low level for the 300 nm mark smaller than the total size of the light spot is shown, it can be confirmed that the effective beam size used for reproduction is smaller than the actual spot size.

Meanwhile, in the above example, the difference signal between the first reproduction signal and the second reproduction signal is simply used, but various operations can be performed.

Next, the results of reproducing the data recorded in the random recording pattern according to the reproducing method of the present invention are shown in Figs. 7A to 7C. FIG. 7A illustrates a first reproduction signal reproduced with a first beam having super resolution power, FIG. 7B illustrates a second reproduction signal reproduced with a second beam having non-super resolution power smaller than that of the super resolution power, and FIG. The differential signal between the first reproduction signal and the second reproduction signal is shown.

FIG. 8 illustrates an eye-pattern obtained from the differential signal of FIG. 7C, and it can be seen that the jitter characteristic of the reproduction signal is very good. In other words, it can be seen that the data reproducing method according to the present invention can be effectively applied to data recorded in the super resolution information storage medium 30 in a random pattern.

9 is a block diagram of a data reproducing apparatus according to an embodiment of the present invention. Referring to FIG. 9, an apparatus for reproducing data according to an exemplary embodiment of the present invention includes an optical pickup 50, a recording / reproducing signal processor 60, and a controller 70. More specifically, the optical pickup 50 includes a light source 51 for irradiating a beam, a spectroscopic element 53 for spectroscopy the beam irradiated from the light source 51, and a beam passing through the spectroscopic element 53 in parallel. Collimating lens 52, a beam splitter 54 for converting a propagation path of an incident beam, and an objective lens 56 for focusing the beam passing through the beam splitter 54 on the super resolution information storage medium 30. do.

The beam emitted from the light source 51 is split into the first beam and the second beam through the spectroscopic element 53. The first beam is a beam having super resolution power, and the second beam is a beam having non-resolution power. The power of the first beam and the second beam can be adjusted by changing the diffraction pattern of the spectroscopic element 53. As the spectroscopic element 53, a grating element or a diffraction element such as a hologram may be used.

The first beam and the second beam reflected from the super resolution information storage medium 30 are reflected by the beam splitter 54 and received by the photodetector 57. The first and second beams received by the photodetector 57 are converted into electrical signals and output as reproduction signals through the signal processor 60.

The signal processor 60 amplifies the first beam signal photoelectrically changed by the photodetector 57 by the amplifier 61, and compensates the time delay through the compensator 62. The reproduction signal of the first beam and the reproduction signal of the second beam are differentially computed by the calculation unit 63. The final RF signal is output through channel 1 (Ch1) and the push-pull signal is output through channel 2 (Ch2).

In the control unit 70, the beam of super resolution power and non-resolution power required to be irradiated according to the material characteristics of the super resolution information storage medium 30 in order to reproduce the recording mark having a size of less than the resolution is the optical pickup Control 50. In addition, the controller 70 implements a focusing servo and a tracking servo using the RF signal and the push-pull signal.

The spectroscopic element 53 is explained in more detail. As described above, the first beam having super resolution power and the second beam having non-resolution power should satisfy the aberration amount condition in addition to the power condition. That is, the aberration amount of the first beam and the second beam amount are required to be substantially the same. Meaning that the aberration amount of the first beam and the second beam is different from each other means that the shape of the spot formed on the super-resolution data storage medium 30 by the first beam and the shape of the spot formed by the second beam Means there is a difference. If there is a difference in the shape of the spot caused by the first beam and the shape of the spot caused by the second beam, as a result, it becomes difficult to achieve the object of the present invention.

In order to satisfy the power condition and the aberration amount condition of the first beam and the second beam, a blaze type grating element is used as the spectroscopic element 53.

10 is a view showing a blazer type grating device 70 according to an embodiment of the present invention. When the beam 71 emitted from the light source 51 is incident on the blazer type grating element 70 shown in FIG. 10, the zeroth order diffraction beam 72, the + 1st order diffraction beam 73, and the -first order diffraction beam ( 74) and a plurality of diffraction beams of ± 2nd order diffraction beam (not shown) to ± Nth order diffraction beam (not shown) are emitted. N is theoretically an integer of infinity.

The amount of aberration of the + 1st diffraction beam 73 and the amount of the aberration of the -1st diffraction beam 74 are substantially the same. Also, if one of ordinary skill in the art the + 1st order diffraction beam 73 has a high power and the -1st order diffraction beam 74 has a relatively low power or + 1st order The diffraction beam 73 has low power and the -first-order diffraction beam 74 can easily implement the blazer type grating element 70 according to an embodiment of the present invention. On the other hand, the power of the 0th order diffraction beam 72 is very weak and can be ignored.

11 is a block diagram of a data reproducing apparatus according to another embodiment of the present invention.

The data reproducing apparatus shown in FIG. 9 has a spectroscopic element 53 for generating a first beam having super resolution power and a second beam having non-resolution power, but the data reproducing apparatus shown in FIG. A first light source 58a irradiating a beam of power and a second light source 58b irradiating a beam of non-resolution power are independently provided to generate a first beam and a second beam. Here, an example in which the first light source 58a and the second light source 58b are packaged as an optical module is shown.

However, it is also possible to independently configure the first light source and the second light source without disposing the optical module, and to arrange the first light source and the second light source at different positions. When the first light source 58a and the second light source 58b are respectively provided as in the data reproducing apparatus shown in FIG. 11, the spectroscopic element 53 does not need to be provided.

In the apparatus shown in FIG. 11, the members using the same reference numerals as those of FIG. 9 are the same functions and functions as those described above, and a detailed description thereof will be omitted herein.

On the other hand, the photodetector 57 includes a first light detector 57a and a second light source for receiving a beam reflected from the information storage medium D by the first beam emitted from the first light source 58a. And a second light detector 57b for receiving the beam reflected from the super resolution information storage medium 30 by the second beam emitted from 58b). The time delay of the first reproduction signal by the first beam and the second reproduction signal by the second beam is compensated by the compensator 62, and then arithmetic processed to obtain an RF signal having excellent signal characteristics in which the ISI is eliminated. have.

As described above, when the first light source 58a and the second light source 58b are provided, any one of the first light source 58a and the second light source 58b can be used as a light source for recording data. There is this.

In the above, embodiments of the present invention have been described taking an example in which two beams of the first beam having super resolution power and the second beam having non-resolution power are irradiated to the super resolution information storage medium 30 as an example. However, according to another embodiment of the present invention, a plurality of beams having non-resolution power may be generated using the spectroscopic element 53 or a plurality of light sources to perform data reproduction according to the present invention. That is, after irradiating a plurality of beams having non-resolution power to the super-resolution information storage medium 30, a final reproduction signal is obtained according to Equation 1 using all reproduction signals obtained from the respective beams having non-resolution power. It may be.

In Equation 1, RF ₁ is a reproduction signal obtained from a beam having super resolution power, and RF ₂ to RF _N are reproduction signals obtained from (N-1) beams having non-resolution power. RF ₂ to RF _N are signals whose time difference from RF ₁ is compensated for. g ₁ to g _N-1 are predetermined coefficients. Those skilled in the art will be able to obtain a final RF signal according to Equation 1 above.

On the other hand, the method for reproducing the data recorded on the super-resolution information storage medium according to an embodiment of the present invention can be implemented as computer-readable code on a computer-readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, optical data storage devices, and the like, and may also be implemented in the form of a carrier wave (for example, transmission over the Internet). It includes being. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

 As described above, according to the present invention, the quality of the reproduction signal can be improved by reducing the influence of inter-signal interference by excluding the reproduction signal from the peripheral region of the super resolution region when irradiating a reproduction beam to the super resolution information storage medium. Further, the data reproducing apparatus of the super resolution information storage medium according to the present invention can improve the reproduction signal characteristics of the super resolution information storage medium by simple signal processing without greatly changing the existing reproducing apparatus.

By using the data reproducing method and apparatus according to the present invention, the data reproducing performance of the super-resolution information storage medium can be improved, thereby making it possible to realize a high quality, high density, and high capacity information storage medium. In addition, the super-resolution information storage medium to which the reproducing method of the present invention is applied is shown in the above example by limiting the 5-layer or 7-layer multilayer film structure and the super-resolution layer to specific materials. It can be applied to various information storage media in which phenomena occur.

Claims (30)

A method of reproducing data recorded on a super resolution information storage medium, Irradiating a first beam having a power causing a super resolution phenomenon and a second beam having a power not causing the super resolution phenomenon at different positions of the super resolution information storage medium; Detecting a first reproduction signal by the first beam and a second reproduction signal by the second beam; And Acquiring a differential signal between the first reproduction signal and the second reproduction signal. delete The method of claim 1, Irradiating the first beam and the second beam, respectively, Spectroscopy the beam emitted from one light source into the first beam and the second beam by using a spectroscopic element. The method of claim 1, And the first beam and the second beam are irradiated along the same track. The method of claim 1, And the first and second beams are irradiated from independently provided first and second beams, respectively. The method of claim 3, In the spectroscopic step, a + k-th diffraction beam is used as the first beam and a -k-th diffraction beam is used as the second beam among a plurality of diffraction beams generated from the spectroscopic element. . The method of claim 3, In the spectroscopic step, a k-th diffraction beam is used as the first beam and a + k-th diffraction beam is used as the second beam among a plurality of diffraction beams generated from the spectroscopic element. . The method according to claim 6 or 7, The spectroscopic element is a blazer type grating element. A method of reproducing data recorded on a super resolution information storage medium, Irradiating, at different positions of the super resolution information storage medium, a super resolution beam having a power causing a super resolution phenomenon and a plurality of non-resolution beams having a power not causing the super resolution phenomenon; Detecting a super resolution reproduction signal by the super resolution beam and a plurality of non-resolution reproduction signals by the plurality of non-resolution beams; And  And obtaining a differential signal between the super resolution reproduction signal and the plurality of non-resolution reproduction signals. The method of claim 9, Obtaining the differential signal, Compensating for a time difference between the super resolution playback signal and the plurality of non-resolution playback signals. The method of claim 9, Irradiating the super resolution beam and the plurality of non-resolution beams, respectively, Spectroscopy the beam emitted from one light source into the super-resolution beam and the plurality of non-resolution beams by using a spectroscopic element. The method of claim 9, And said non-resolution beams are irradiated along the same track. The method of claim 9, And the non-resolution beams are irradiated from the first light source and the second light source independently provided. An apparatus for reproducing data recorded on a super resolution information storage medium, Irradiating a first beam having a power causing super resolution and a second beam having a power not causing super resolution at different positions of the super resolution information storage medium, and reflecting from the super resolution information storage medium. An optical pickup configured to photoelectrically change the first beam and the second beam to output a first reproduction signal and a second reproduction signal; And And a signal processor for outputting a differential signal between the first reproduction signal and the second reproduction signal. 15. The method of claim 14, The signal processing unit, A compensator for compensating a time difference between the first reproduction signal and the second reproduction signal to output the first reproduction signal and the second reproduction signal whose time difference is compensated for; And And a calculation unit configured to perform a differential operation between the first reproduction signal compensated for the time difference and the second reproduction signal to output the differential signal. 15. The method of claim 14, The optical pickup, Light source; And And a spectroscopic element for spectroscopy the beam emitted from the light source into the first beam and the second beam. 15. The method of claim 14, And the optical pickup irradiates the first beam and the second beam along the same track of the super resolution information storage medium. 15. The method of claim 14, And the optical pickup includes a first light source for irradiating the first beam and a second light source for irradiating a second beam. The method of claim 18, And the first light source and the second light source are modules. The method of claim 16, And the first beam corresponds to a + k-th diffraction beam among a plurality of diffraction beams generated from the spectroscopic element, and the second beam corresponds to a -k-th diffraction beam. The method of claim 16, And the first beam corresponds to a -k-th diffraction beam among a plurality of diffraction beams generated from the spectroscopic element, and the second beam corresponds to a + k-th diffraction beam. The method of claim 20 or 21, And the spectroscopic element is a blazer type grating element. An apparatus for reproducing data recorded on a super resolution information storage medium, Irradiating a super-resolution beam having a power causing a super-resolution phenomenon and a plurality of non-resolution beams having a power not causing the super-resolution phenomenon at different positions of the super-resolution information storage medium, respectively, and performing the super-resolution information storage medium. An optical pickup configured to photoelectrically change the super resolution beam and the plurality of non super resolution beams reflected from the optical output to output a super resolution reproduction signal and a plurality of non super resolution reproduction signals; And And a signal processor for outputting a differential signal between the super resolution reproduction signal and the plurality of non-resolution reproduction signals. 24. The method of claim 23, The signal processing unit, A compensating unit for compensating a time difference between the super resolution reproduction signal and the plurality of non-resolution reproduction signals and outputting the super resolution reproduction signal and the plurality of non-resolution reproduction signals with a time difference compensated; And And an operation unit configured to perform a differential operation between the super resolution reproduction signal compensated for the time difference and the plurality of non-resolution reproduction signals to output the differential signal. 24. The method of claim 23, The optical pickup, Light source; And And a spectroscopic element for spectroscopy the beam emitted from the light source into the super resolution beam and the plurality of non-resolution beams. 24. The method of claim 23, And the optical pickup irradiates the super resolution beam and the plurality of non-resolution beams along the same track of the super resolution information storage medium. 24. The method of claim 23, And the optical pickup includes a first light source for irradiating the super resolution beam and a second light source for irradiating the plurality of non-resolution beams. 28. The method of claim 27, And the first light source and the second light source are modules. A computer-readable recording medium having recorded thereon a program for realizing a method of reproducing data recorded on a super-resolution information storage medium, Method for reproducing the data recorded on the super-resolution information storage medium, Irradiating a first beam having a power causing a super resolution phenomenon and a second beam having a power not causing the super resolution phenomenon at different positions of the super resolution information storage medium; Detecting a first reproduction signal by the first beam and a second reproduction signal by the second beam; And And obtaining a differential signal between the first reproduction signal and the second reproduction signal. A computer-readable recording medium having recorded thereon a program for realizing a method of reproducing data recorded on a super-resolution information storage medium, Method for reproducing the data recorded on the super-resolution information storage medium, Irradiating, at different positions of the super resolution information storage medium, a super resolution beam having a power causing a super resolution phenomenon and a plurality of non-resolution beams having a power not causing the super resolution phenomenon; Detecting a super resolution reproduction signal by the super resolution beam and a plurality of non-resolution reproduction signals by the plurality of non-resolution beams; And  And obtaining a differential signal between the super resolution reproduced signal and the plurality of non-resolution reproduced signals.

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