JP2007164930A - Recording method and recording apparatus for magneto-optical recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a recording method capable of more stably recording a recording magnetic domain having a shorter mark length in a magneto-optical recording medium of a magnetic domain expansion reproducing system.
SOLUTION: Trial writing information, which is binary information composed of two components and includes one component and the other component constituting the binary information in the same ratio, is recorded on a magneto-optical recording medium. Reproducing the recorded test writing information; determining the intensity and application direction of the corrected recording magnetic field based on the reproduced signal waveform of the test writing information; and applying the corrected recording magnetic field to the recording magnetic field to The above-described problem is solved by providing a recording method including recording information on a magnetic recording medium.
[Selection] Figure 9

Description

  The present invention relates to a recording method and a recording apparatus for a magneto-optical recording medium, and more particularly to a recording method and a recording apparatus for a magneto-optical recording medium capable of reproducing information having a size smaller than or equal to the optical resolution.

  With the progress of the information society, the recording density has been remarkably improved in the external storage device for storing a huge amount of information. The same applies to the magneto-optical recording medium, and research on increasing the density by reducing the light spot size using a blue laser and a high NA lens is actively conducted. For example, when a blue laser with a wavelength of 405 nm and an objective lens with NA of 0.6 are used, the light spot diameter is about 0.6 μm. When a blue laser with a wavelength of 405 nm and an objective lens with NA of 0.85 are used, the light spot diameter is Becomes as small as about 0.45 μm. When the light spot becomes small, intersymbol interference is reduced when reproducing a small recording mark, and accurate information reproduction can be performed, so that the recording density can be improved.

  Further, in the magneto-optical recording medium, a large capacity technology using heat and magnetism features has been proposed in order to improve the reproduction resolution. As such a large capacity technology, for example, a magnetic super-resolution technology (see, for example, Patent Document 1), a domain wall movement reproduction technology (for example, see Patent Literature 2), a magnetic domain expansion reproduction technology (for example, see Patent Literature 3), a center An aperture rear enlargement detection technique (see, for example, Patent Document 4) has been proposed.

JP-A-3-93056 Japanese Patent Application Laid-Open No. 6-290496 JP-A-8-182901 JP-A-11-162030

  Although the reproduction resolution can be improved by using the techniques disclosed in Patent Documents 1 to 4, the length of the recording mark is naturally shortened along with the improvement of the reproduction resolution. As the length of the recording mark becomes shorter, it becomes more difficult to stably record the shortest mark. Furthermore, when recording short mark length information, if there is a leakage magnetic field from the actuator coil for driving the objective lens or a disturbance magnetic field (noise magnetic field) due to a magnetic field generated from an external electrical device, the shortest There is a risk that it is difficult to stably record the mark.

  The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to improve the reproduction resolution as described above, in particular, a magnetic domain expanding reproduction system (MAMMOS: Magnetic Amplifying Magneto-Optical). It is an object of the present invention to provide a recording method and a recording apparatus capable of recording information more stably on a magneto-optical recording medium using System).

  According to the first aspect of the present invention, information is recorded on a magneto-optical recording medium comprising a recording layer in which information is recorded as magnetic domains, and a reproducing layer in which the magnetic domains recorded in the recording layer are transferred and enlarged. A method for recording, on the magneto-optical recording medium, trial writing information which is binary information composed of two components and includes one component constituting the binary information and the other component in the same ratio. Reproducing the recorded test writing information, determining the intensity and application direction of the correction recording magnetic field based on the reproduction signal waveform of the test writing information, and converting the correction recording magnetic field into the recording magnetic field. In addition, a recording method including recording information on the magneto-optical recording medium is provided.

  The present inventors investigated the relationship between the disturbance magnetic field and information recording / reproducing characteristics in a magnetic domain expansion reproduction type magneto-optical recording medium (hereinafter also referred to as a MAMMOS medium). Problem) occurred. This phenomenon will be described with reference to the recording / reproducing characteristics shown in FIGS. 1 to 3 show recording / reproducing characteristics when the recording magnetic field strength is ± 250 Oe and a light beam having a spot diameter of 0.4 μm is used as reproducing light. In addition, the upper waveform in FIGS. 1A and 1B of FIGS. 1 to 3 is the waveform of the recording magnetic field, and the middle waveform is the reproduction of a normal MO medium (a magneto-optical recording medium that does not reproduce the magnetic domain in an enlarged manner). It is a signal waveform, and the lower waveform is a reproduced signal waveform of the MAMMOS medium.

  FIG. 1 is a diagram showing recording / reproduction characteristics when no disturbance magnetic field is present during information recording. FIG. 1 (a) shows an information component “0” having a mark length of 1.0 μm (size greater than the optical resolution) and FIG. 1B shows recording / reproduction characteristics when binary information in which “1” is alternately arranged is recorded. FIG. 1B shows information components “0” and “1” having a mark length of 0.07 μm (size less than the optical resolution). Is a recording / reproducing characteristic when binary information in which "" is alternately arranged is recorded.

  In the absence of a disturbing magnetic field, as is apparent from FIGS. 1A and 1B, in the MAMMOS medium, the recording waveform length is not limited regardless of whether the recording mark length is 1.0 μm or 0.07 μm. Similar playback signal waveforms were obtained. On the other hand, in the case of a normal MO medium, when the recording mark length is 1.0 μm, the size is equal to or greater than the optical resolution. Therefore, as shown in FIG. 1A, a sine wave reproduction signal waveform corresponding to the recording waveform is obtained. However, when the recording mark length is 0.07 μm, the size is less than the optical resolution, so information cannot be reproduced with a normal MO medium, and the recording waveform corresponds to the recording waveform as shown in FIG. A sine wave reproduction signal waveform cannot be obtained.

  FIG. 2 is a diagram showing recording / reproduction characteristics in the presence of a disturbing magnetic field in which the intensity of the recording magnetic field shifts in the minus direction (downward in FIG. 2). FIG. FIG. 2B shows recording / reproduction characteristics when binary information in which information components “0” and “1” of 1.0 μm are alternately arranged is recorded. FIG. 2B shows an information component “0.07 μm in information component“ This is a recording / reproduction characteristic when binary information in which “0” and “1” are alternately arranged is recorded. The disturbance magnetic field strength was 50 Oe.

  When there is a disturbing magnetic field in which the intensity of the recording magnetic field shifts in the negative direction, as shown in FIG. 2A, if the recording mark length is sufficiently long as 1.0 μm, the case of FIG. As in the case of (when not), a reproduction signal waveform similar to the recording waveform was obtained. However, when the recording mark length was shortened to 0.07 μm, the signal waveform at the position where the amplitude of the reproduction signal should be maximized was lost in the reproduction signal waveform of the MAMMOS medium as shown in FIG. That is, it has been found that when a disturbance magnetic field exists in which the intensity of the recording magnetic field shifts in the negative direction, a part of the reproduced signal waveform of the MAMMOS medium is lost when the recording mark length is shortened. As is clear from FIGS. 2A and 2B, the reproduction results of the conventional MO medium were the same as those in FIG.

  FIG. 3 is a diagram showing recording / reproduction characteristics in the presence of a disturbance magnetic field in which the intensity of the recording magnetic field shifts in the positive direction (upward in FIG. 3). FIG. 3B shows recording / reproduction characteristics when binary information in which information components “0” and “1” having a mark length of 1.0 μm are alternately arranged is recorded. FIG. 3B shows information having a mark length of 0.07 μm. This is a recording / reproduction characteristic when binary information in which components “0” and “1” are alternately arranged is recorded. The disturbance magnetic field strength was 50 Oe.

  When there is a disturbing magnetic field in which the intensity of the recording magnetic field shifts in the plus direction, as shown in FIG. 3A, if the recording mark length is sufficiently long as 1.0 μm, the case of FIG. As in the case of (when not), a reproduction signal waveform similar to the recording waveform was obtained. However, when the recording mark length was shortened to 0.07 μm, the signal waveform at the position where the amplitude of the reproduction signal should be minimized was lost in the reproduction signal waveform of the MAMMOS medium as shown in FIG. That is, even in the presence of a disturbance magnetic field in which the intensity of the recording magnetic field shifts in the positive direction (upward in FIG. 3), if the recording mark length is shortened, a part of the reproduced signal waveform of the MAMMOS medium becomes a waveform. I found it missing. As is clear from FIGS. 3 (a) and 3 (b), the same results as in FIG. 1 were obtained for the reproduction characteristics of the conventional MO medium (middle waveform in FIG. 3).

  From the results shown in FIGS. 1 to 3, it was found that when a disturbance magnetic field is present when information is recorded on the MAMMOS medium, a waveform portion corresponding to information of a short mark length is lost in the reproduced signal waveform. If there is a missing portion in the reproduced signal waveform in this way, accurate information cannot be reproduced from that portion.

  Further, the present inventors further examined the relationship between the disturbance magnetic field and the recording / reproducing characteristics by changing the recording mark length. As the recording mark length becomes shorter, the reproduction signal waveform omission rate (frequency of omission) increases. I found out that The figure is shown in FIG. The characteristics of FIG. 4 are similar to the case of FIG. 3 in that the mark length and the missing rate of the reproduced signal waveform when a disturbance magnetic field exists such that the recording magnetic field shifts in the positive direction (upward in FIG. 3). It is the figure which showed the relationship. In this evaluation experiment, reproduction light having a spot diameter of 0.4 μm was used. As is apparent from the characteristics of FIG. 4, when the recording mark length is less than 0.1 μm, the missing rate suddenly increases.

  As described above, in the MAMMOS medium, when information recording is performed in the presence of a disturbance magnetic field, there is a possibility that the reproduction signal waveform may be lost in a region where the recording mark length is short. The following can be considered as the cause.

  In the MAMMOS medium, the domain wall position of the recording mark is determined by the distribution of heat generated by laser light irradiation and the timing at which the recording magnetic field is switched. Therefore, when the recording mark length is sufficiently long, the recording magnetic field for forming the next recording mark in a state where the domain wall of the recording mark preceding in the traveling direction of the medium is sufficiently cooled (the coercive force is sufficiently large). Is applied. At this time, since the coercive force in the vicinity of the domain wall of the preceding recording mark is sufficiently large, even if some disturbance magnetic field is present at the time of information recording (even if the recording magnetic field fluctuates slightly due to the disturbance magnetic field), the recording in which the disturbance magnetic field precedes The position and shape of the magnetic domain wall of the mark are not greatly affected. However, when the mark length is shortened, the ratio of the recording mark length to the width of the heat distribution generated by laser light irradiation is shortened. In this case, the recording magnetic field for forming the next recording mark is applied before the temperature of the domain wall of the preceding recording mark is sufficiently lowered, that is, in the state where the coercive force near the domain wall of the preceding recording mark is low. Therefore, the influence of the disturbance magnetic field (recording magnetic field fluctuation) on the domain wall position and shape of the preceding recording mark is increased. As a result, if a disturbing magnetic field exists during information recording, the shape of the recording mark and the shape of the domain wall may be disturbed with a short recording mark. In the MAMMOS medium, when the recording mark shape or the domain wall shape is disturbed due to the above-mentioned causes, the recording magnetic domain in that portion cannot be enlarged and reproduced at all. Therefore, in the MAMMOS medium, as shown in FIGS. 2 and 3, it is considered that the reproduction signal waveform is missing.

  Here, the influence of the disturbance magnetic field on the domain wall of the recording mark will be described more specifically with reference to FIGS. 5 and 6 are diagrams showing the relationship between the heat distribution (temperature profile) generated in the recording layer by laser light irradiation and the recording mark length.

  In FIG. 5, after forming the white recording mark 41, a recording mark 42 having a magnetization direction opposite to the magnetization direction of the recording mark 41 (recording mark having the same magnetization direction as the black recording mark 40) is formed. It shows the state just before. A broken line 43 in FIG. 5 is a critical temperature position at which the magnetization direction of the recording layer is reversed by the recording magnetic field, and when the recording magnetic field is reversed, the magnetization of the recording layer region heated above this temperature is reversed. . When the recording magnetic field is reversed in the state of FIG. 5, the magnetization of the region of the recording mark 42 is reversed because it is heated and the coercive force is sufficiently lowered. That is, a magnetic domain having the same magnetization direction as that of the black recording mark 40 is formed, and a domain wall is formed at a position corresponding to the broken line 43. At this time, the domain wall (arrow 44) region at the boundary between the recording mark 41 and the recording mark 40 preceding in the disk traveling direction is sufficiently cooled and has a sufficiently large coercive force, so that a disturbance magnetic field exists. However, the effect is small, and the position of the domain wall does not change or the shape of the domain wall does not change.

  On the other hand, in FIG. 6, similarly to FIG. 5, after forming the white recording mark 51, the recording mark 52 having the magnetization direction opposite to the magnetization direction of the recording mark 51 (the same magnetization as the black recording mark 50). It is a figure showing a state immediately before forming a recording mark having a direction). FIG. 6 is a diagram showing a state in which the ratio of the mark length to the temperature profile width is smaller than that in FIG. 5 (when the mark length is short). A broken line 53 in FIG. 6 is a critical temperature position at which the magnetization direction of the recording layer is reversed by the recording magnetic field. When the recording magnetic field is reversed, the magnetization of the recording layer region heated above this temperature is reversed. . When the recording magnetic field is reversed in the state of FIG. 6, in the area of the recording mark 52, since the coercive force is sufficiently lowered by heating, the magnetization is reversed. That is, a magnetic domain having the same magnetization direction as that of the black recording mark 50 is formed, and a domain wall is formed at a position corresponding to the broken line 53. However, at this time, the domain wall (arrow 54) region at the boundary between the recording mark 51 and the recording mark 50 preceding in the disk traveling direction is not sufficiently cooled, and the coercive force is low. Therefore, when the recording magnetic field fluctuates due to the disturbance magnetic field, the position of the domain wall between the recording marks 50 and 51 may change, the shape of the domain wall may be deformed, or the recording mark itself may be deformed.

  The present invention has been made to solve the above-described problems. In the MAMMOS medium recording method of the present invention, before recording user data or the like, two components (for example, “0”) are used as test writing information. (1)) and one component (for example, “0”) and the other component (for example, “1”) are included in the same ratio, and test writing is performed, and the test writing information Based on the reproduced signal waveform, the strength of the corrected recording magnetic field and the application direction are determined so that the reproduced signal waveform is not lost (disturbing the disturbance magnetic field). Information is recorded on the MAMMOS medium using a magnetic field obtained by adding the corrected recording magnetic field to the recording magnetic field. Therefore, if the recording method of the MAMMOS medium of the present invention is used, there is no loss in the reproduced signal waveform, so that information can be reliably recorded and reproduced even with a shorter recording mark. Since the disturbance magnetic field changes depending on the use environment and the like, it is preferable to correct the recording magnetic field in the recording method of the present invention for each recording.

  According to the second aspect of the present invention, information is recorded on a magneto-optical recording medium comprising a recording layer in which information is recorded as magnetic domains, and a reproducing layer in which the magnetic domains recorded in the recording layer are transferred and enlarged. A binary information composed of two components, wherein one component and the other component constituting the binary information are included in the same ratio, and the mark length of one component and the other component Are recorded on the magneto-optical recording medium with test writing information shorter than the shortest mark length of the user data recorded on the magneto-optical recording medium, reproducing the recorded test writing information, and the test writing. A recording method comprising: determining the intensity and application direction of a corrected recording magnetic field based on a reproduced signal waveform of information; and adding the corrected recording magnetic field to the recording magnetic field to record information on the magneto-optical recording medium. Provided.

  As shown in FIG. 4, a recording mark with a short mark length is more sensitive (susceptible to) a disturbance magnetic field. Therefore, in the recording method of the MAMMOS medium of the present invention, when a corrected recording magnetic field for canceling the disturbance magnetic field is obtained, a test writing with a short mark length that is highly sensitive to the disturbance magnetic field (is easily affected). It is preferable to use information. Thereby, the disturbance magnetic field can be compensated more accurately. Further, when user data is actually recorded on the MAMMOS medium, it is desirable to ensure that the reproduction signal waveform is not lost within the range of the mark length included in the user data. It is desirable to use test writing information having a mark length shorter than the shortest mark length. By obtaining the corrected recording magnetic field using test writing information having a mark length shorter than the shortest mark length of the user data, it is possible to more reliably prevent the signal waveform of the shortest mark used for the user data from being lost. In other words, the disturbance magnetic field can be corrected with high sensitivity and the shortest mark of the user data can be obtained by obtaining the corrected recording magnetic field using test writing information having a mark length that is more easily affected by the disturbance magnetic field than the shortest mark length of the user data. Recording and reproduction can be performed stably.

  In the recording method of the magneto-optical recording medium of the present invention, it is preferable that determining the intensity and application direction of the correction recording magnetic field includes detecting the lack of the reproduction signal waveform. Specifically, it is preferable that the lack of the reproduction signal waveform is detected by obtaining an average value or an integral value of the amplitude of the reproduction signal waveform.

  When the reproduced signal waveform of the trial writing information is not missing, the average value of the reproduced signal waveform is a predetermined value (for example, 0), but when the reproduced signal waveform is missing, the average value is predetermined. The value deviates from the value of. For example, as shown in FIG. 2, when there is a disturbance magnetic field that causes the recording magnetic field to shift in the negative direction (downward in FIG. 2), the position where the amplitude of the reproduction signal should be maximized Therefore, the average value becomes smaller than a predetermined value. On the other hand, as shown in FIG. 3, when there is a disturbance magnetic field that causes the recording magnetic field to shift in the positive direction (upward in FIG. 3), the position where the amplitude of the reproduction signal should be minimized Therefore, the average value becomes larger than a predetermined value. Therefore, by determining the correction recording magnetic field so that the average value of the reproduction signal waveform of the trial writing information becomes a predetermined value, a reproduction signal waveform having no omission is obtained. Further, even if an integral value is used instead of the average value of the reproduction signal waveform, the magnitude and application direction of the correction recording magnetic field can be determined in the same manner as in the case of the average value.

  Further, the lack of the reproduced signal waveform may be detected by counting the number of missing signal waveforms. In this method, the number of missing reproduction signal waveforms in the trial writing information is directly counted, and the intensity of the correction recording magnetic field and the application direction are determined so that the number of omissions becomes zero. It is possible to eliminate it.

  In the magneto-optical recording medium recording method of the present invention, it is preferable that the test writing information is information in which the one component and the other component are alternately arranged.

  According to the third aspect of the present invention, information is recorded on a magneto-optical recording medium comprising a recording layer in which information is recorded as magnetic domains and a reproducing layer in which the magnetic domains recorded in the recording layer are transferred and enlarged. Recording apparatus, binary information composed of two components, wherein one component and the other component constituting the binary information are included in the same ratio, and one component and the other component A magnetic field generator for recording test writing information whose mark length is shorter than the shortest mark length of user data recorded on the magneto-optical recording medium, and a detection unit for detecting a lack of a reproduction signal waveform of the test writing information And a correction recording magnetic field generation unit that generates a correction recording magnetic field based on the detection result of the detector.

  According to the magneto-optical recording medium recording method of the present invention, before recording user data or the like, binary information composed of two components and one component constituting the binary information and the other component are composed. Is recorded on the magneto-optical recording medium, and based on the reproduction signal waveform of the trial writing information, the strength of the correction recording magnetic field that does not cause a loss in the reproduction signal waveform of the magneto-optical recording medium, and Determine the direction of application. Therefore, even with a short recording mark, the reproduction signal waveform is not lost, and information can be recorded and reproduced reliably.

  Embodiments of a magneto-optical recording medium recording method and recording / reproducing apparatus according to the present invention will be specifically described below with reference to the drawings, but the present invention is not limited thereto.

[Magnetic recording medium]
A schematic configuration of the magneto-optical recording medium of Example 1 is shown in FIG. The magneto-optical recording medium 8 in this example is a MAMMOS medium. As shown in FIG. 7, a dielectric layer 2, a recording layer 3, an intermediate layer 4, a magnetic domain expansion reproducing layer 5, and a dielectric layer 6 are formed on a substrate 1. And the protective layer 7 has the structure formed in this order. The MAMMOS medium 8 of this example was manufactured as follows using a high frequency sputtering apparatus (not shown).

First, the substrate 1 was a polycarbonate substrate having a thickness of 0.6 mm having a land width of 0.3 μm, a groove width of 0.3 μm, and a groove depth of 40 nm. The substrate 1 was mounted in a film forming chamber of a sputtering apparatus, and the film forming chamber was evacuated to an ultimate vacuum of 8 × 10 ⁻⁵ Pa. Next, the substrate 1 was vacuum baked at 80 ° C. for 5 hours.

Next, SiN was formed as a dielectric layer 2 on the substrate 1 in a thickness of 60 nm in an Ar / N ₂ atmosphere. Next, a rare earth transition metal alloy TbFeCo having a Curie temperature of 280 ° C. and a compensation temperature near room temperature was formed as a recording layer 3 with a film thickness of 90 nm on the dielectric layer 2 in an Ar gas atmosphere. Next, a rare earth transition metal alloy TbGdFe having a compensation temperature below room temperature was formed as an intermediate layer 4 on the recording layer 3 to a thickness of 10 nm in an Ar gas atmosphere. Next, a rare earth transition metal alloy GdFe was formed as a magnetic domain expansion reproduction layer 5 on the intermediate layer 4 with a film thickness of 20 nm in an Ar gas atmosphere. At this time, the ratio of Gd and Fe was adjusted so that the Curie temperature was about 240 ° C. and the compensation temperature was equal to or higher than the Curie temperature. The recording layer 3, the intermediate layer 4, and the magnetic domain expansion reproducing layer 5 were all perpendicular magnetization films from room temperature to the Curie temperature. Next, SiN was formed as a dielectric layer 6 on the magnetic domain expansion reproducing layer 5 in a thickness of 60 nm in an Ar / N ₂ mixed gas atmosphere. Finally, a protective layer 7 was formed on the dielectric layer 6 by applying a UV curable resin with a spin coater and applying UV irradiation to solidify the UV resin. As described above, the MAMMOS medium 8 having the laminated structure shown in FIG. 7 was produced.

[Magnetic recording / reproducing apparatus]
Next, the magneto-optical recording / reproducing apparatus used in this example will be described. A schematic configuration of the magneto-optical recording / reproducing apparatus of this example is shown in FIG. As shown in FIG. 8, the magneto-optical recording / reproducing apparatus 100 in this example mainly includes a spindle 11 for rotating the MAMMOS medium 8 and an optical for recording / reproducing information (user data, etc.) on the MAMMOS medium 8. A head 12 including a head and a magnetic head (magnetic field generating unit), a laser driver 13 for driving the optical head, a magnetic head driver 14 for driving the magnetic head, and an offset magnetic field generating coil 15 (corrected recording magnetic field generation) Part), a coil driver 16 for driving the offset magnetic field generating coil 15, an optical signal processing system 17 for processing the detected optical signal, a recording magnetic field processing system 18 for correcting the recording magnetic field, and the spindle 11 And a host CPU 20 for controlling the entire magneto-optical recording / reproducing apparatus 100.

  As shown in FIG. 8, the optical signal processing system 17 mainly includes an IV conversion unit 21 that converts an optical signal detected by the head 12 into an electric signal, surface shake of the MAMMOS medium 8, and the MAMMOS medium 8. A servo circuit 22 for causing the laser beam to follow the track, and a PLL circuit 23 for generating a clock for recording and reproduction by using clock pits arranged on the MAMMOS medium 8 are configured.

  Further, as shown in FIG. 8, the recording magnetic field processing unit 18 mainly performs an I-V conversion unit 31 that converts an optical signal detected by the head 12 into an electric signal, and digitally processes the MO reproduction signal by performing signal processing. It comprises a signal processing device for converting data, and a feedback control unit 35 (detection unit) for determining an offset magnetic field (corrected recording magnetic field) from a reproduction signal of trial writing information. As shown in FIG. 8, the feedback control unit 35 includes an arithmetic processing unit 33 for obtaining the strength and application direction of the offset magnetic field, and a memory 34.

  In this example, an optical head provided with a laser having a wavelength of 405 nm and an objective lens having a numerical aperture NA of 0.9 was used. The linear velocity at the time of recording / reproducing information on the MAMMOS medium 8 in this example was 4 m / sec, and the laser light was incident from the protective layer 7 side. The coil (not shown) of the magnetic head that generates the recording magnetic field is disposed on the objective lens, and the recording magnetic field is applied from the protective layer 7 side. Information recording on the MAMMOS medium 8 was performed using the optical pulse magnetic field modulation recording method, and the recording power of the laser light was 10 mW and the recording magnetic field ± 200 Oe. At the time of information reproduction, the reproduction power of the laser beam was set to 1.5 mW laser power necessary for the recording magnetic domain in the recording mark portion and the non-recording mark portion to be transferred to the reproduction layer and expanded.

  In this example, when the leakage magnetic field (disturbance magnetic field) from the actuator for moving the objective lens is measured, there is a leakage magnetic field in the same direction as the direction of the recording magnetic field applied when recording the information “1”. The strength was about 50 Oe. Note that the voltage of the MO reproduction signal in the MAMMOS medium 8 in this example is 0 V in the AS-DEPO state (the state immediately after film formation), and the recording mark to which the recording magnetic field is applied in the direction corresponding to the information “1”. A positive voltage signal is obtained in the portion (recording magnetic domain), and a negative voltage is obtained from the recording mark portion (recording magnetic domain) to which the recording magnetic field is applied in the direction corresponding to the information “0”.

[Recording magnetic field correction method and information recording method]
A procedure from the recording magnetic field correction method to the user data information recording in this example will be described with reference to FIGS. First, in order to determine an offset magnetic field for correcting the recording magnetic field, the test writing information includes two information components (hereinafter simply referred to as components) “0” and “1”, and the component “0 ”And“ 1 ”are included in the same ratio, and the trial writing information is recorded on the MAMMOS medium 8 of this example (step S1 in FIG. 9). Specifically, as a recording pattern of the test writing information, a pattern in which recording magnetic domains corresponding to the component “1” having the same magnetic domain length (recording mark length) and recording magnetic domains corresponding to the component “0” are alternately arranged. The MAMMOS medium 8 was formed. In this example, the magnetic domain length of the recording magnetic domain is 100 nm.

  Next, the MAMMOS medium 8 is irradiated with laser light having a laser power of 1.5 mW, which is transferred to the reproducing layer 5 and the recording magnetic domain is enlarged, and the reflected light from the enlarged magnetic domain of the reproducing layer 5 is detected by the head 12 (FIG. Step S2). Next, the detected optical signal is converted by the IV conversion unit 31 in the recording magnetic field processing unit 18, and then input to the arithmetic processing unit 33 to obtain the average value M of the reproduction signal (step S3 in FIG. 9). ). In this step S3, when the average value M of the reproduction signal of the test writing information obtained by the arithmetic processing unit 33 is 0, information such as user data is recorded without generating an offset magnetic field (FIG. 9). Middle step S4).

  On the other hand, if the average value M of the reproduction signal of the trial writing information obtained by the arithmetic processing unit 33 is not 0 in step S3, at least a part of the reproduction signal waveform is missing as shown in FIGS. Therefore, the intensity and direction of the offset magnetic field are set based on the average value M so that the reproduction signal waveform is not lost (step S5 in FIG. 9). Specifically, in step S9, the coil driver 16 was controlled as follows to set the strength and direction of the offset magnetic field. When the average value M of the reproduction signal of the trial writing information obtained by the arithmetic processing unit 33 becomes a positive voltage (for example, the state of FIG. 3B), the component “0” of the trial writing information is recorded. The coil driver 16 is controlled by the host CPU 20 so that an offset magnetic field having a predetermined intensity is generated from the offset magnetic field generating coil 15 in a direction in which the recording magnetic field applied in the process is increased. On the other hand, when the average value M of the reproduction signal of the trial writing information becomes a negative voltage (for example, the state of FIG. 2B), it is applied when recording the component “1” of the trial writing information. The coil driver 16 was controlled so that an offset magnetic field having a predetermined intensity was generated from the offset magnetic field generating coil 15 in the direction of increasing the recording magnetic field.

  The intensity and direction of the offset magnetic field applied to the recording magnetic field every step S5 were set as follows based on the average value M of the reproduction signal. When the average value M of the reproduction signal of the trial writing information is a positive voltage, an offset magnetic field of 5 Oe is applied in the same direction as the recording magnetic field applied when the component “0” of the trial writing information is recorded. did. On the other hand, when the average value M of the reproduction signal of the test writing information is a negative voltage, an offset magnetic field of 5 Oe is applied in the same direction as the recording magnetic field applied when recording the component “1” of the test writing information. I did it.

  Next, when the average value M of the reproduction signal of the test writing information is not 0 V in step S3 in FIG. 9, the offset magnetic field having the predetermined intensity and direction set in step S5 is added to the recording magnetic field, and the test writing is performed again. Information was recorded (step S1 in FIG. 9). Next, the trial writing information was reproduced and the average value M was obtained. When the procedure for recording, reproducing, calculating the average value, and setting the offset magnetic field as described above is repeated, the offset magnetic field generated from the offset magnetic field generating coil 15 has a magnitude that cancels the disturbance magnetic field. The average value M of the reproduction signal becomes 0V. At this time, the control signal of the coil driver 16 that controls the offset magnetic field generating coil 15 when the polarity of the average value M of the reproduction signal of the trial writing information is changed is stored in the memory 34. Thereafter, the coil driver 16 is driven based on the control signal recorded in the memory 34 to record user data while generating the offset magnetic field from the offset magnetic field generating coil 15 (step S4 in FIG. 9). In this example, the user field is recorded by correcting the recording magnetic field by the above procedure.

[Evaluation of playback characteristics]
In this example, after correcting the recording magnetic field as described above, evaluation information to be described later is recorded on the MAMMOS medium, and its reproduction characteristics are evaluated. For comparison, the reproduction characteristics were also measured when evaluation information was recorded without correcting the recording magnetic field with an offset magnetic field.

  First, recording magnetic domains corresponding to the component “1” and recording magnetic domains corresponding to the component “0” constituting the evaluation information are alternately formed, and the magnetic domain length (recording mark length) of each recording magnetic domain is 100 nm. A pattern was formed on the MAMMOS medium. That is, information having the same recording mark pattern as the trial writing information was recorded on the MAMMOS medium as evaluation information. Then, the missing rate of the reproduced signal waveform detected from the evaluation information was obtained. Note that the missing rate was obtained by counting the number of marks longer than the recorded mark in the detected reproduction signal waveform using a time interval analyzer.

  In this example, random pattern data with a shortest mark length of 100 nm was recorded on the MAMMOS medium as evaluation information, and the error rate in that case was measured. The above evaluation results are shown in Table 1.

  As can be seen from Table 1, when the recording magnetic field was not corrected with the offset magnetic field, the reproduction signal waveform loss rate increased and the error rate also deteriorated, compared with the case where the recording magnetic field was corrected with the offset magnetic field. This is because, as described above, in the recording / reproducing apparatus 100 of this example, there is a leakage magnetic field of about 50 Oe in the direction of the recording magnetic field applied when recording the evaluation information component “1” from the actuator. It is considered that the recording magnetic domain corresponding to the evaluation information component “0” was not stably formed, the waveform corresponding to the reproduction signal waveform component “0” was missing, and the error rate was deteriorated.

  On the other hand, when information was recorded using the recording magnetic field correction method of this example, the missing rate of the waveform of the shortest mark became a very small value, and the error rate was improved. From this result, recording of a short mark length is performed by generating an offset magnetic field so that the leakage magnetic field (disturbance magnetic field) from the actuator is canceled as in the recording magnetic field correction method of this example. It was found that information could be recorded stably and reliably on the magnetic domain, and the reproduction characteristics were improved.

  In the second embodiment, the mark lengths (recording domain lengths) of the components “0” and “1” constituting the test writing information are both made shorter than the shortest mark length of information (user data etc.) recorded after the recording magnetic field correction. The offset magnetic field was obtained.

  The MAMMOS medium in this example has the same configuration as in Example 1 and was manufactured in the same manner as in Example 1. The recording / reproducing apparatus of this example has almost the same configuration as the recording / reproducing apparatus used in Example 1 (recording / reproducing apparatus in FIG. 8). However, in this example, as described above, the mark length of the test writing information is shorter than the shortest mark length of information (user data, etc.) recorded after the correction of the recording magnetic field. The PLL circuit 23 for generating a clock for recording / reproducing information in the signal processing system 17 has a configuration different from that of the recording / reproducing apparatus used in the first embodiment. Otherwise, the configuration was the same as in Example 1.

  A schematic configuration of the PLL circuit 23 of this example is shown in FIG. As shown in FIG. 10, the PLL circuit 23 includes a phase comparator, a filter, a VCO, and a frequency dividing circuit. In the PLL circuit 23 of this example, as shown in FIG. 10, in addition to the frequency dividing circuit 23a for clock generation at the time of recording / reproducing information (user data, etc.) recorded after the recording magnetic field correction, the recording magnetic field correction (trial A frequency dividing circuit 23b for generating a clock for recording writing information is separately provided. In the PLL circuit 23 of this example, the frequency of the VCO is set to 10 times the PLL output frequency (clock frequency when recording / reproducing user data or the like). Therefore, the clock frequency for recording magnetic field correction can be selected between 1 and 10 times the PLL output frequency by changing the VCO frequency dividing ratio. That is, by changing the VCO frequency division ratio, the recording magnetic field correction clock cycle can be selected between 1/10 and 1 times the recording / reproduction clock cycle of user data or the like. By using the PLL circuit 23 having such a structure, it is possible to record test writing information having a mark length shorter than the shortest mark length of information (user data or the like) recorded after correcting the recording magnetic field on the MAMMOS medium.

  In this example, the recording magnetic field was corrected by the same method as in Example 1 (procedure of FIG. 9) using the recording / reproducing apparatus. However, in this example, as the recording pattern of the trial writing information, the recording magnetic domain corresponding to the component “1” and the recording magnetic domain corresponding to the component “0” of the trial writing information are alternately formed, and each magnetic domain length is formed. (Record mark length) was 80 nm.

  Next, also in this example, as in Example 1, a comparative evaluation of the reproduction characteristics when the recording magnetic field was corrected by the offset magnetic field and when it was not corrected was performed. First, as a recording pattern of evaluation information, a recording magnetic domain corresponding to the component “1” and a recording magnetic domain corresponding to the component “0” of the test writing information are alternately formed, and the magnetic domain length (recording mark length) of each recording magnetic domain is formed. A recording mark pattern having a thickness of 80 nm was formed on the MAMMOS medium. That is, information having the same recording mark pattern as the trial writing information was recorded on the MAMMOS medium as evaluation information. Then, the missing rate of the reproduced signal waveform detected from the evaluation information was obtained. Similarly to Example 1, random pattern data having a shortest mark length of 100 nm was recorded on the MAMMOS medium as evaluation information, and the error rate was measured. The evaluation results are shown in Table 2.

  As apparent from Table 2, when the recording magnetic field was not corrected with the offset magnetic field, the reproduction signal waveform missing rate increased and the error rate also deteriorated, compared with the case where the recording magnetic field was corrected with the offset magnetic field. This is because, like the first embodiment, in the recording / reproducing apparatus of this example, there is a leakage magnetic field of about 50 Oe in the direction of the recording magnetic field applied when recording the evaluation information component “1” from the actuator. It is considered that the recording magnetic domain corresponding to the evaluation information component “0” was not stably formed, the waveform corresponding to the reproduction signal waveform component “0” was missing, and the error rate was deteriorated. On the other hand, when information was recorded using the recording magnetic field correction method of this example, the missing rate of the shortest mark waveform decreased and the error rate improved. From this result, even in the recording magnetic field correction method of this example, by recording information by generating an offset magnetic field so that the leakage magnetic field (disturbance magnetic field) from the actuator is canceled, a recording magnetic domain with a short mark length is obtained. It was found that information recording can be performed stably and reliably, and the reproduction characteristics are improved.

  Further, from the results of Tables 1 and 2, it was found that when the error rate of Example 1 and the error rate of Example 2 were compared, Example 2 gave better results. This is considered to be due to the following reasons.

  Comparing the missing rate of Example 1 in Table 1 with the missing rate of Example 2 in Table 2, it can be seen that the missing rate is higher in Example 2. This is because the mark length of the test writing information is shorter in the second embodiment, and thus the sensitivity to the disturbance magnetic field is higher than that in the first embodiment (the reproduced signal waveform is easily lost). In the first embodiment, the offset magnetic field is obtained using the test writing information having the same mark length as the shortest mark length of the evaluation information, whereas in the second embodiment, the mark length shorter than the shortest mark length of the evaluation information. The offset magnetic field is obtained using the trial writing information. That is, in Example 2, the offset magnetic field is obtained under conditions that are more easily affected by the disturbance magnetic field than the evaluation information. Therefore, the correction method of the second embodiment can compensate the disturbance magnetic field with higher accuracy. As a result, it can be considered that the information recording in the second embodiment is more stable and reliable than the first embodiment, and the error rate is improved.

  In the first and second embodiments, the average value of the reproduction signal of the test writing information is obtained and the offset magnetic field is determined based on the average value. However, the present invention is not limited to this. An integrated value of the reproduction signal may be used. When the reproduced signal waveform is not missing, the integrated value of the reproduced signal is also a predetermined value, and when the reproduced signal waveform is missing, the integrated value of the reproduced signal is deviated from the predetermined integrated value. Therefore, the magnitude and application direction of the offset magnetic field can be determined by using the integrated value of the reproduction signal instead of the average value of the reproduction signal of the test writing information. In that case, what is necessary is just to change step S3 which calculates | requires the average value M in FIG. 9 to the step which calculates | requires an integral value.

  Alternatively, the offset magnetic field may be determined so that the number of missing reproduction signal waveforms of the trial writing information is directly counted by visual observation or the like. In this case, step S3 for obtaining the average value M in FIG. 9 may be changed to a step for counting the number of missing reproduction signal waveforms. In this method, the strength of the offset magnetic field and the application direction are determined so that the number of missing reproduced signal waveforms in the test writing information is zero, so that it is possible to more reliably eliminate missing reproduced signal waveforms.

  In the magneto-optical recording medium recording method of the present invention, even when information recording is performed under the presence of a disturbance magnetic field, the recording magnetic field can be corrected with high accuracy, so that more stable information recording is possible. Therefore, the recording method of the magneto-optical recording medium of the present invention is a magneto-optical recording medium that needs to form a finer recording magnetic domain, in particular, a magnetic super-resolution technique, a domain wall moving reproduction technique, a magnetic domain expansion reproduction technique, etc. It is optimal as a method for recording information on the magneto-optical recording medium used.

FIG. 1 is a diagram showing waveforms of a recording magnetic field and a reproduction signal of a magneto-optical recording medium when there is no disturbance magnetic field. FIG. 1A shows a waveform when the mark length is 1.0 μm. b) is a waveform when the mark length is 0.07 μm. FIG. 2 is a diagram showing waveforms of the recording magnetic field and the reproduction signal of the magneto-optical recording medium when there is a disturbance magnetic field (minus direction), and FIG. 2A is a waveform when the mark length is 1.0 μm. FIG. 2B shows a waveform when the mark length is 0.07 μm. FIG. 3 is a diagram showing waveforms of the recording magnetic field and the reproduction signal of the magneto-optical recording medium when there is a disturbance magnetic field (plus direction), and FIG. 3A is a waveform when the mark length is 1.0 μm. FIG. 3B shows a waveform when the mark length is 0.07 μm. FIG. 4 is a diagram showing the relationship between the mark length and the reproduction signal waveform missing rate. FIG. 5 is a diagram for explaining the reason why the reproduction signal waveform is missing. FIG. 6 is a diagram for explaining the reason why the reproduction signal waveform is missing. FIG. 7 is a schematic configuration diagram of the MAMMOS medium manufactured in Example 1. FIG. 8 is a schematic configuration diagram of the recording / reproducing apparatus used in the first embodiment. FIG. 9 is a flowchart for explaining the procedure of the information recording method according to the first embodiment. FIG. 10 is a schematic configuration diagram of the PLL circuit used in the second embodiment.

Explanation of symbols

8 MAMMOS medium 12 Head 15 Offset magnetic field generating coil 16 Coil driver 17 Optical signal processing system 18 Recording magnetic field processing system 33 Arithmetic processing unit 34 Memory 35 Feedback control unit

Claims (7)

A method for recording information on a magneto-optical recording medium comprising a recording layer in which information is recorded as magnetic domains, and a reproducing layer in which the magnetic domains recorded in the recording layer are transferred and enlarged,
Recording, on the magneto-optical recording medium, trial writing information which is binary information composed of two components and includes one component and the other component constituting the binary information in the same ratio;
Playing back the recorded trial writing information,
Determining the intensity and application direction of the correction recording magnetic field based on the reproduction signal waveform of the test writing information;
Recording the information on the magneto-optical recording medium by applying the correction recording magnetic field to the recording magnetic field. A method for recording information on a magneto-optical recording medium comprising a recording layer in which information is recorded as magnetic domains, and a reproducing layer in which the magnetic domains recorded in the recording layer are transferred and enlarged,
Binary information composed of two components, one component and the other component constituting the binary information are included at the same ratio, and the mark lengths of one component and the other component are both Recording test writing information shorter than the shortest mark length of user data recorded on the recording medium on the magneto-optical recording medium;
Playing back the recorded trial writing information,
Determining the intensity and application direction of the correction recording magnetic field based on the reproduction signal waveform of the test writing information;
Recording the information on the magneto-optical recording medium by applying the correction recording magnetic field to the recording magnetic field. 3. The recording method according to claim 1, wherein determining the intensity and the application direction of the correction recording magnetic field includes detecting a loss of the reproduction signal waveform. 4. The recording method according to claim 3, wherein the lack of the reproduction signal waveform is detected by obtaining an average value or an integral value of the amplitude of the reproduction signal waveform. 4. The magneto-optical recording medium according to claim 3, wherein missing of the reproduced signal waveform is detected by counting the number of missing signal waveforms. The recording method according to claim 1, wherein the trial writing information is information in which the one component and the other component are alternately arranged. A recording apparatus for recording information on a magneto-optical recording medium comprising a recording layer in which information is recorded as magnetic domains, and a reproducing layer in which the magnetic domains recorded in the recording layer are transferred and enlarged,
Binary information composed of two components, one component and the other component constituting the binary information are included at the same ratio, and the mark lengths of one component and the other component are both A magnetic field generator for recording test writing information shorter than the shortest mark length of user data recorded on a recording medium;
A detection unit for detecting a lack of a reproduction signal waveform of the test writing information;
A recording apparatus comprising: a corrected recording magnetic field generation unit that generates a corrected recording magnetic field based on a detection result of the detector.

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