JP4212759B2 - Magnetic signal reproducing apparatus, magnetic signal reproducing method, and magnetic recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a magnetic signal reproducing apparatus, a magnetic signal reproducing method, and a magnetic recording medium that realize high density reproduction by performing magnetic reproduction while raising the temperature of the recording medium.
[0002]
[Prior art]
In recent years, multimedia technology has been developed, and the demand for larger capacity memory devices has been increasing in order to handle larger amounts of information. In particular, rewritable optical discs, magnetic discs, and magnetic tapes have a higher density technology. Is being actively studied.
[0003]
Among them, a magnetic recording medium whose magnetic characteristics change with temperature is used, a temperature rising area is locally provided on the medium by means such as light irradiation, and only the temperature rising area is selectively magnetically recorded or reproduced. Thus, a magnetic signal recording / reproducing method that enables high-density recording / reproduction (in this application, this is called a heat-assisted magnetic signal recording / reproducing method, and this reproducing method is called a heat-assisted magnetic signal reproducing method) is proposed. Has been.
[0004]
As an example of a heat-assisted magnetic signal recording / reproducing method, a recording medium that uses a ferrimagnetic material having a temperature at which magnetization becomes zero near room temperature (this is referred to as a magnetic compensation point temperature) is used as a recording medium. The area to be recorded is irradiated with a light beam to raise the temperature to near the Curie temperature, and an external magnetic field is applied by a recording head to record information. At the time of reproduction, the light beam is applied to the area to be reproduced on the recording medium. A method has been proposed in which the temperature is increased by irradiation to increase the magnetization of the reproducing portion, and then the magnetic flux leaking from the reproducing portion is detected by a reproducing head to reproduce information (Japanese Patent Laid-Open No. 4-17634). ).
[0005]
[Problem to be Solved by the Invention]
However, in the above-described conventional heat-assisted magnetic signal reproducing method (Japanese Patent Laid-Open No. 4-176634), magnetization is generated from all the areas where the temperature of the recording medium has been raised, so reproduction in a narrow range beyond this area is possible. When trying to do so, this magnetization is mixed in the reproduction signal. The reproduction area can only be reduced to an allowable range because the mixed signal is negligibly small compared to the signal obtained from the area where reproduction is desired.
[0006]
That is, in the conventional heat-assisted magnetic signal reproduction method, if the signal reproduction area width is made smaller than the temperature rise area width in order to further increase the signal reproduction density, the S / N ratio of the reproduction signal is lowered. There is. This is specifically shown below.
[0007]
Magnetizing information recorded on the magnetic recording medium by making the polarity of magnetization correspond to binary using reproducing means (hereinafter referred to as a reproducing head) having a general rectangular magnetization information detection area, Consider reproduction by the above-described heat-assisted magnetic signal reproduction method. FIG. 20 is formed on the medium by the recording state (bit pattern) of the magnetization information on the magnetic recording medium, the magnetization information detection region 4 of the reproducing head, and the local temperature raising device (here, laser light is used). It is the figure which showed the temperature rising area 9 typically.
[0008]
This figure shows the magnetization information of the three regions 5a, 5b and 5c recorded by being magnetized into three different patterns. Here, the state in which the magnetic recording medium is alternately magnetized with the opposite polarity is represented by the hatching direction. Hereinafter, a bit pattern in which a series of information is recorded according to the polarity of the magnetization is referred to as a track 5. That is, in this example, magnetization information exists in a total of three tracks, one track (5b) at the center and one track (5a, 5c) on both sides.
[0009]
Among the media on which such magnetization information is recorded, the magnetic information of one central track (5b) is converted into a reproducing head having a reproducing head signal detection region 4 having a shape larger than one track width in the track width direction (for example, Consider the case of reproduction using an MR head or the like.
[0010]
However, it is assumed that the magnetic recording medium is a general n-type ferrimagnetic material whose magnetic compensation point temperature substantially coincides with the medium temperature near the reproducing head in a state where the temperature is not increased. FIG. 21 shows the temperature characteristics of the magnetization of this magnetic recording medium.
[0011]
Also, the widths of the tracks 5a, 5b, and 5c are substantially equal, and the distance between adjacent tracks is also approximately equal. The sum of the track width and the distance between tracks is called the track pitch. The recording density of this magnetic recording medium is inversely proportional to the track pitch.
[0012]
The temperature of the magnetic recording medium is substantially constant in the thickness direction. Further, since the length in the track direction of the magnetization information detection region 4 in the reproducing means is smaller than the spread of the temperature distribution, the temperature is substantially constant even in the track direction. It is only the temperature distribution of the reproduction participation region facing the magnetization information detection region 4 of the reproduction head that contributes to the reproduction signal. Thereafter, the temperature distribution related to the magnetization information detection is in the track width direction in the reproduction participation region. Handle distribution only.
[0013]
When only the central track 5b in FIG. 20 is reproduced by the heat-assisted magnetic signal reproducing method, only the central track 5b is heated with a light beam or the like. At this time, the magnetic recording medium has a temperature distribution as shown in FIG. 3 due to the light beam, and magnetization corresponding to the temperature distribution appears. Hereinafter, in the magnetic recording medium, the overlapping portion of the heated region 9 and the reproduction-related region where magnetization is detected by the magnetization information detection region 4 of the reproducing head is referred to as a reproduction site. If only the central track 5b exists at this reproduction site, the magnetization information of only the central track 5b can be reproduced. When the temperature rise area 9 by the light beam and the magnetization information detection area 4 of the reproducing head are moved along the track 5 with their relative positions being substantially fixed, all the magnetization information of the central track 5b is detected. Will be able to.
[0014]
FIG. 22 is a diagram showing changes in the magnetization signal due to the width of the temperature rising region 9 in the track width direction and the size of the track width. (A) shows the case where the width of the temperature rising region 9 is smaller than the track width, and (b) shows the case where the width of the temperature rising region 9 is larger than the track width.
[0015]
When the width of the temperature raising region 9 is smaller than the track width (FIG. 22 (a)), the reproduction signal is almost occupied by the signal from the center track 5b, and there is not much mixed signal from the adjacent tracks 5a and 5c. . On the other hand, when the width of the temperature raising region 9 is larger than the track width (FIG. 22B), the signals from the adjacent tracks 5a and 5c are largely mixed in the reproduction signal. If the mixed signal becomes larger than a certain level, the magnetization information of the central track 5b cannot be correctly reproduced.
[0016]
Therefore, in order to perform magnetization information reproduction at a higher density, it is necessary to reduce the width of the temperature raising region 9 in the magnetic recording medium in order to reduce the track pitch while keeping the mixed signal low. It is difficult, and the conventionally proposed heat-assisted magnetic signal reproduction method cannot reduce the track pitch while keeping the mixed signal from the adjacent track low.
[0017]
In addition, laser light that converges and emits coherent light, which is one of the temperature raising means, suppresses this because the light intensity distribution has a spread equal to or greater than the wavelength and the heat distribution further spreads. There was also a problem that it was difficult to do.
[0018]
In the above-described heat-assisted magnetic recording / reproducing method, the temperature of the magnetic recording medium in the magnetization information detection region 4 of the reproducing head at the time of reproduction needs to substantially match the magnetic compensation point temperature when the temperature is not raised. The environmental temperature of the device itself changes by several tens of degrees Celsius depending on the season and time, and the electronic components inside the device also generate heat. In addition, there is an influence of heat generation in a very small area such as heat generation of the reproducing head. Since all of these thermal changes affect the temperature of the magnetic recording medium, in order to make the temperature of the magnetic recording medium in the reproduction participating area at the time of non-temperature increase substantially coincide with the magnetic compensation point temperature, the magnetic field in the reproduction participating area is It is necessary to measure and control the temperature of a minute area called a recording medium, which is very difficult and cannot be solved at a practical cost.
[0019]
The object of the present invention is to solve the above-mentioned problems in the conventional heat-assisted magnetic signal reproduction method, to reduce the mixed signal in signal reproduction at a track pitch narrower than the diameter of the laser spot, and to achieve the conventional heat-assisted magnetic signal. Magnetic signal reproducing apparatus and magnetic signal reproducing method capable of reproducing a high-density magnetic signal exceeding a reproducing method with a high S / N ratio and capable of dealing with a temperature transition of a magnetic recording medium due to a change in environmental temperature or the like, and It is to provide a magnetic recording medium.
[0020]
[Means for Solving the Problems]
The magnetic signal reproducing apparatus of the present invention reproduces information from a magnetic recording medium having a magnetic film having a magnetic compensation point temperature as a first temperature and whose magnetization polarity is reversed at the first temperature when the temperature rises. In the magnetic signal reproducing apparatus, a local temperature raising means for locally raising the temperature of the magnetic recording medium, and a reproducing means having a magnetization information detection region for magnetically detecting magnetization information recorded on the magnetic recording medium, The local temperature raising means is provided in the magnetic recording medium during a reproducing operation. Outside the regeneration target area A temperature region lower than the first temperature and a temperature region higher than the first temperature are formed in a region facing the magnetization information detection region.
[0021]
In the magnetic signal reproducing apparatus, the local temperature raising means forms a temperature region lower than the first temperature and a temperature region higher than the first temperature outside the reproduction target region in the magnetic recording medium. Is preferred .
[0022]
The magnetic signal reproducing apparatus of the present invention has a magnetic film having a magnetic compensation point temperature, and is formed so that the polarity of magnetization information is reversed at the magnetic compensation point temperature when the temperature changes. In the magnetic signal reproducing apparatus for reproducing information from the recording medium, the magnetic signal reproducing apparatus has a local temperature raising means for locally raising the temperature of the magnetic recording medium, and a magnetization information detection region for magnetically detecting magnetization information recorded on the magnetic recording medium. The local temperature raising means, during the reproduction operation, the magnetic compensation point temperature in a region facing the magnetization information detection region in the magnetic recording medium and outside the reproduction target region. A temperature region having a lower temperature and a temperature region having a temperature higher than the magnetic compensation point temperature are formed.
[0023]
In the magnetic signal reproducing apparatus, a plurality of tracks for recording information is formed on the magnetic recording medium, and the local temperature raising means is arranged in an area facing the magnetization information detecting area during a reproducing operation. In each of the tracks other than the reproduction target track, a temperature region lower than the magnetic compensation point temperature and a temperature region higher than the magnetic compensation point temperature are formed.
[0024]
Further, in the magnetic signal reproducing apparatus, the local temperature raising means raises the temperature so that an average temperature of the low temperature region and the high temperature region is substantially the same as the magnetic compensation point temperature. To do.
[0025]
Also, the magnetic signal reproducing apparatus of the present invention has a plurality of tracks for recording information, and has a magnetic film having a magnetic compensation point temperature. In a magnetic signal reproducing apparatus for reproducing information from a magnetic recording medium whose polarity is reversed, a local temperature raising means for locally raising the temperature of the magnetic recording medium by irradiating the magnetic recording medium with laser light, and the magnetic recording Reproducing means having a magnetization information detection region for magnetically detecting magnetization information recorded on the medium, and arranged so that the center of the laser beam and the center of the magnetization information detection region substantially coincide with each other in the track width direction. The magnetization information detection region has a width that at least partially opposes each of the three tracks of the magnetic recording medium in the track width direction. The temperature raising means raises the temperature of the central track facing the magnetization information detection region to a temperature higher than the magnetic compensation point temperature, and the magnetization information detection region in the two tracks adjacent to the central track. The temperature is raised so that the average temperature of each of the opposed regions substantially matches the magnetic compensation point temperature.
[0026]
Further, in the magnetic signal reproducing apparatus, the local temperature raising means forms a temperature distribution having at least two maximum values exceeding the magnetic compensation point temperature on the magnetic recording medium. .
[0027]
Further, the magnetic signal reproducing apparatus is characterized by comprising control means for controlling the operation of the local temperature raising means to change the temperature rise state of the magnetic recording medium.
[0028]
In the magnetic signal reproducing apparatus, a temperature rise state control region in which known data for controlling a temperature rise state by the local temperature raising means is recorded on the magnetic recording medium, and the control means Is characterized by controlling the operation of the local temperature raising means based on a reproduction signal reproduced from the temperature rise state control region.
[0029]
In the magnetic signal reproducing apparatus, the temperature rise state control region is formed in at least one place in a region where the linear velocities in the magnetic recording medium are substantially the same.
[0030]
Further, in the above magnetic signal reproducing apparatus, the temperature rise state control region constitutes a temperature rise state control block having a width at least equal to or larger than the width of the magnetization information detection region in a direction perpendicular to the scanning direction of the reproducing means. It is characterized by becoming.
[0031]
The magnetic signal reproducing apparatus further includes a detecting unit that measures a use environment temperature of the magnetic recording medium, and the control unit controls an operation of the local temperature raising unit based on a detection result of the detecting unit. It is characterized by.
[0032]
The magnetic signal reproduction method of the present invention comprises: A magnetic film having a magnetic compensation point temperature as the first temperature; A magnetic recording medium in which the polarity of magnetization information is reversed at the first temperature at the time of temperature rise is used to locally raise the temperature of the magnetic recording medium by a local temperature raising means, and at least one of the heated portions. A magnetic signal reproducing method for magnetically detecting magnetization information recorded on the magnetic recording medium by a reproducing means having a magnetization information detecting area facing the unit, wherein the magnetic information is recorded outside the reproduction target area in the magnetic recording medium during a reproducing operation. The temperature of the magnetic recording medium is increased so that a temperature region lower than the first temperature and a temperature region higher than the first temperature are formed in a region facing the magnetization information detection region. And
[0033]
In the magnetic signal reproducing method, the temperature is raised so that the overall magnetization in the low temperature region and the overall magnetization in the high temperature region are substantially the same.
[0034]
In the magnetic signal reproduction method, the temperature is raised so that the absolute value of the average magnetization in the low temperature region and the absolute value of the average magnetization in the high temperature region are substantially the same.
[0035]
In addition, the magnetic signal reproducing method of the present invention includes a magnetic film having a magnetic compensation point temperature, and a magnetic recording medium formed so that the polarity of magnetization information is reversed at the magnetic compensation point temperature when temperature changes The magnetic recording medium is locally heated by the local temperature raising means and recorded on the magnetic recording medium by the reproducing means having a magnetization information detection region facing at least a part of the heated portion. A magnetic signal reproducing method for magnetically detecting the magnetization information, wherein the magnetic compensation point is located in a region facing the magnetization information detection region in the magnetic recording medium and outside the reproduction target region during a reproducing operation. The temperature of the magnetic recording medium is raised so as to form a temperature region lower than the temperature and a temperature region higher than the magnetic compensation point temperature.
[0036]
The magnetic signal reproducing method of the present invention has a plurality of tracks for recording information, has a magnetic film having a magnetic compensation point temperature, and has a magnetic film having a magnetic compensation point temperature as a boundary when the temperature changes. Magnetization of reproducing means using a magnetic recording medium having a reversed polarity, locally heating the magnetic recording medium by laser light irradiation, and having a magnetization information detection region facing at least a part of the heated portion A magnetic signal reproducing method for magnetically detecting magnetization information recorded on the magnetic recording medium by an information detection area, wherein the magnetization information detection area includes three tracks of the magnetic recording medium in a track width direction. Each of the reproducing units has a width that is opposed to each other, and the reproducing means is configured such that the center of the laser beam and the center of the magnetization information detection region substantially coincide in the track width direction. In the reproducing operation, the central track facing the magnetization information detection region is heated to a temperature higher than the magnetic compensation point temperature, and the magnetization information detection region in two tracks adjacent to the central track The temperature is raised so that the average temperature of each of the regions facing each other substantially coincides with the magnetic compensation point temperature.
[0037]
The magnetic recording medium of the present invention has a magnetic layer having a magnetic compensation point temperature as a first temperature in a magnetic recording medium in which the temperature is locally increased and the magnetization information at the heated portion is magnetically reproduced. And a local temperature raising means for locally raising the temperature of the magnetic recording medium, and a reproducing means having a magnetization information detection area for magnetically detecting magnetization information recorded on the magnetic recording medium. The local temperature raising means of the signal reproducing device is adapted to reproduce the magnetic recording medium during reproduction operation. Outside the regeneration target area By forming a temperature region lower than the first temperature and a temperature region higher than the first temperature in a region facing the magnetization information detection region, magnetization is performed with the magnetic compensation point temperature as a boundary when the temperature rises. The temperature rising state control region in which known data is recorded for controlling the temperature rising state is provided.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
[Embodiment 1]
In the present embodiment, a magnetic signal that raises the temperature of a recording medium with laser light and reproduces magnetization information by a reproducing head (reproducing means) having a magnetization information detection region arranged to face at least a part of the temperature raising portion. The playback device will be described. Hereinafter, for the magnetic signal reproducing apparatus of the present embodiment,
(1) Principle
(2) Device configuration
(3) Laser power setting
(4) Use conditions of magnetic recording media (design of magnetic recording media)
(5) Tracking control
▲ 6 ▼ Other
Will be described in the order.
[0039]
(1) Principle
First, the principle of the heat-assisted magnetic signal reproduction system of this embodiment will be described.
[0040]
In the magnetic recording medium used in this embodiment, the polarity of magnetization changes at the first temperature when the temperature rises. For example, as shown in FIG. 5, the magnetic layer has a magnetic compensation point temperature (Tcomp; for example, about 100 ° C.) between room temperature (T1) and Curie temperature (Tc).
[0041]
In such a magnetic recording medium, the magnetization is substantially zero at a temperature at which the polarity changes (magnetic compensation point temperature Tcomp in the magnetic recording medium in FIG. 5), and has a reverse magnetization at lower and higher temperatures. Become. In the heat-assisted magnetic signal reproduction system of the present embodiment, during reproduction, a reproduction-related area of the magnetic recording medium facing the magnetization information detection area of the reproduction head (an area in which magnetization information is read immediately below the magnetization information detection area of the reproduction head) The magnetic recording medium is heated so as to form a region at a higher temperature and a region at a lower temperature than the above-mentioned changing temperature, thereby realizing high-density reproduction. Hereinafter, the principle of this embodiment will be described in detail with reference to FIGS.
[0042]
FIG. 1 is a diagram for explaining the principle of the present invention. FIG. 2 shows a bit pattern recorded on a magnetic recording medium, a magnetization information detection area (area for detecting the magnetization of the magnetic recording medium) of a reproducing head, and a laser spot. It is a figure which shows these positional relationships. In these figures, the magnetic recording medium 2 describes only three tracks 5a, 5b, and 5c.
[0043]
1 and 2, the laser spot 9 converges and irradiates a laser beam on the approximate center of the central track 5 b (reproduction target track (reproduction target area)) on the magnetic recording medium 2, so that FIG. The temperature distribution shown in a)) shall be formed. On the other hand, the magnetization information detection sensitivity in the magnetization information detection region 4 of the read head is constant in the magnetization information detection region, and the read signal is the magnetization per unit area of the magnetic recording medium 2 in the read participation region and the read head detection sensitivity. Is proportional to the value obtained by area integration in the magnetization information detection area. However, regarding the magnetization, the polarity of the polarity is the sign of the magnetization.
[0044]
Here, as shown in FIG. 2, the magnetization information detection region 4 of the reproducing head has a width corresponding to three tracks (5a, 5b, 5c) of the magnetic recording medium 2 and is irradiated by the laser spot 9 to be irradiated. An example of reproducing information recorded on the central track 5b by using the reproducing head and a laser beam (laser spot) when a leakage magnetic flux affecting the reproduced signal is generated from an area larger than the width of one track. explain. It is assumed that each track of the magnetic recording medium 2 is demagnetized.
[0045]
As described in the section of the prior art, in the conventional heat-assisted magnetic signal reproduction method, the magnetization information detection region 4 extends over a plurality of tracks as shown in FIG. When the temperature rise region) also extends over a plurality of tracks, the information recorded on the adjacent track (tracks 5a, 5c) as well as the track (center track 5b) that is the reproduction target is also detected in the magnetization information detection region. 4 is mixed as a signal, and the quality of the reproduction signal is deteriorated.
[0046]
On the other hand, in this embodiment, a magnetic recording medium as described above (in the case of FIG. 1, a magnetic recording medium in which Tcomp exists from room temperature to Curie temperature as shown in FIG. 1A) is used for reproduction. Sometimes, the laser beam irradiation centered on the central track 5b raises the temperature of the reproduction-related area 4b of the central track 5b (the portion immediately below the magnetization information detection area 4 of the central track 5b) to a temperature higher than Tcomp. At this time, the regions immediately below the magnetization information detection regions 4 of the adjacent tracks 5a and 5c are regions higher than Tcomp (reproduction participation regions 4ah and 4ch) and regions lower than Tcomp (reproduction participation regions 4al and 4cl). The temperature is raised to form.
[0047]
FIG. 1B is a diagram showing the magnetization in the reproduction participating region (4al, 4ah, 4ch, 4cl) of the magnetic recording medium 2 when the magnetization is performed in the uniform direction when the temperature is raised as described above. FIG. 1D is a diagram showing the positive and negative polarity of magnetization appearing on the magnetic recording medium 2 in the hatching direction when the bit pattern shown in FIG. 2 is reproduced. As can be seen from these figures, the adjacent tracks 5a and 5c have positive and negative magnetizations in their respective reproduction-related regions.
[0048]
This will be described in more detail with reference to FIG. FIG. 4 is a graph showing the magnetization direction during recording at the positions P1, P2, P3, and P4 of the bit pattern shown in FIG. 2 and the magnetization that appears during reproduction at that position. At each position, the polarity of magnetization is reversed in the adjacent tracks 5a and 5c. That is, in each track, the low temperature side has a negative polarity and the high temperature side has a positive polarity in each track. Since the magnetizations having opposite polarities contribute to the reproduction signal with an opposite sign, the magnetization information in this track cancels each other and decreases in the reproduction signal. For example, at the position P1, the magnetization in the positive direction is recorded on the track 5a at the time of recording, and the magnetization in the negative direction is recorded on the tracks 5b and 5c, but when reproducing the track 5b, the track 5b is above the magnetic compensation point temperature. However, the tracks 5a and 5c have both positive and negative magnetization in the tracks 5a and 5c, and the magnetization decreases as a whole (and cancels as described later). become.
[0049]
As described above, according to the heat-assisted magnetic signal reproduction method of the present embodiment, the adjacent tracks 5a and 5c have magnetization in the positive direction and the negative direction during reproduction, and the magnetization becomes weak as a whole. Therefore, the signals from the adjacent tracks 5a and 5c are weak, and the reproduction signal from the central track 5b can be reproduced with high quality.
[0050]
In the example of FIGS. 1 and 4, if the positive and negative magnetizations appearing on the adjacent tracks 5a and 5c are set to cancel each other, the mixed signal from the adjacent tracks 5a and 5c is set to substantially zero. be able to. Specifically, in the temperature range corresponding to the adjacent tracks 5a and 5c, the magnetization of the magnetic recording medium 2 can be approximated by a linear function of the temperature (see FIG. 5), so that the average temperature in each track is determined as the magnetic recording medium. If the temperature is raised so as to substantially coincide with the compensation point temperature Tcomp of 2 (for example, about 100 ° C.), the contribution of the magnetization information in this track to the reproduction signal becomes almost zero. In this case, the magnetization information mixed from the adjacent tracks (in this case, both end tracks) 5a and 5c due to the spread of the temperature distribution can be canceled, so that only the central track 5b can be obtained as a reproduction signal. As a result, it is possible to detect the magnetization information with a narrower track width than the temperature rising region width formed on the magnetic recording medium 2 with high accuracy.
[0051]
Here, the magnetization information detection sensitivity of the reproducing head 3 is constant in the magnetization information detection region 4, and the magnetization of the magnetic recording medium 2 is expressed as a linear function of temperature near the magnetic compensation point temperature. However, even if this is not the case, there is a laser power in which the contribution in the reproduction signal cancels out in the region where the magnetization polarities in either of the adjacent tracks 5a and 5c are opposite to each other. For example, when the read head magnetization information detection sensitivity is not constant in the magnetization information detection region 4, an average temperature weighted according to the read head magnetization information detection sensitivity may be used as the average temperature. In this case, in the adjacent tracks 5a and 5c, the absolute values of the average magnetization (weighted according to the read head magnetization information detection sensitivity) in the temperature region higher and lower than the magnetic compensation point temperature are substantially the same. .
[0052]
If the reproducing head magnetization information detection sensitivity and the temperature of the magnetic recording medium 2 have a substantially symmetrical distribution in the magnetization information detection region 4 as in the present embodiment, the adjacent tracks 5a, The magnetization information of 5c can be canceled with the same laser light power. In this case, if the center of the irradiation position of the laser spot coincides with the center of the track 5b, the area for canceling the magnetization information can be maximized. For this reason, in the above-mentioned example (FIG. 1 etc.), it has set so. However, this is not the case depending on the distribution of the read head magnetization detection sensitivity. FIG. 6 shows an example in which the reproducing head magnetization information detection sensitivity has an asymmetric distribution in the magnetization information detection region 4 (see FIG. 6A). In this case, by moving the position of the temperature distribution (center of the laser spot) of the magnetic recording medium 2 (see FIG. 6B), the magnetization information of the track at both ends in FIG. 2 can be canceled with the same laser light power. it can. Such movement of the center of the laser spot can be performed by a method similar to tracking control described later.
[0053]
(2) Device configuration
The magnetic recording medium 2 used in the present embodiment is made of an n-type ferrimagnetic material having a configuration as described above (see FIG. 5) and a magnetic compensation point temperature Tcomp of about 100 ° C. As this ferrimagnetic material, for example, TbFeCo, GdFeCo, or the like can be used. Here, a magnetic body made of TbFeCo with Tb 25%, Fe 10%, and Co 65% was used.
[0054]
As shown in FIG. 2, the magnetic recording medium 2 has a track width of 0.5 μm, a track interval of 0.1 μm, a track pitch of 0.6 μm, and is recorded corresponding to the polarity of the magnetization. The tracks are demagnetized. The recording state in each track is substantially uniform in the width direction.
[0055]
Next, the configuration of the apparatus will be described with reference to FIGS. FIG. 7 is an enlarged view of a laser beam irradiation portion and a magnetic signal reproduction portion in the magnetic signal reproduction device, and FIG. 8 is a schematic diagram showing an overall configuration of the magnetic signal reproduction device.
[0056]
As shown in these drawings, a local temperature raising device 1 and a reproducing head 3 are arranged with a magnetic recording medium 2 (a magnetic recording medium having the characteristics shown in FIG. 5 described above) interposed therebetween. The local temperature raising device 1 converges and irradiates laser light onto the magnetic recording medium 2 in accordance with a laser control signal from the control device 8. The reproducing head 3 is fixed to the reproducing head moving device 16 via a slider 15 and is arranged so that the magnetization information of the magnetic recording medium 2 can be detected. Further, the reproducing head 3 can be moved to an arbitrary magnetization information recording area in the magnetic recording medium 2 by the magnetic recording medium rotating device 13 and the reproducing head moving device 16. The reproducing head moving device 16 is driven by a reproducing head position control signal from the control device 8.
[0057]
The reproducing head 3 has a magnetization information detection region 4 having a width of 1.8 μm (for 3 tracks), and the local temperature raising device 1 is one that locally raises the temperature with a convergent laser beam having a beam diameter of 1 μm. Become.
[0058]
The signal processing device 7 converts the magnetization information detected by the reproducing head 3 into a signal that can be processed by the control device 8 and outputs the signal to the control device 8. The control device 8 has a function of outputting a laser control signal to the local temperature raising device 1 and a reproducing head position control signal to the reproducing head moving device 16 from the signal input from the signal processing device 7.
[0059]
The reproduction operation is performed as follows. First, the magnetic recording medium rotating device 13 rotates the magnetic recording medium 2. Then, the temperature of the magnetic recording medium is raised by the local temperature raising device 1, and the magnetic flux from the temperature raising portion is read from the magnetization information detection area of the reproducing head 3. The read signal is processed by the signal processing device 7 to reproduce information. At this time, the control device 8 controls the laser light power (described later) and also executes tracking control (described later).
[0060]
(3) Laser power setting
As described in the above-mentioned principle section, in the heat-assisted magnetic signal reproduction method of the present embodiment, the magnetization direction of the magnetic recording medium 2 rises at a predetermined temperature (Tcomp in the present embodiment) when the temperature rises. A region that is higher than the predetermined temperature and a region that is lower than the predetermined temperature in the reproduction-related region of the magnetic recording medium 2 (the region immediately below the magnetization information detection region 4 of the reproducing head 3). The temperature of the magnetic recording medium 2 is raised so as to form. More preferably, the magnetic recording medium 2 is set so that the magnetic flux from the other tracks of the reproduction target track is substantially 0, specifically, the average temperature of the adjacent tracks 5a and 5c is close to Tcomp. Raise the temperature.
[0061]
In such a heat-assisted magnetic signal reproduction system of this embodiment, control of the temperature rise state by the local temperature raising device 1 is very important, and even if the temperature rise is too strong or weak, the reproduction target track Magnetic flux (magnetization information) from other tracks is also read by the reproducing head 3, and the reproduction signal quality is deteriorated.
[0062]
If the heat-assisted magnetic signal reproducing apparatus to be used can always maintain the magnetic recording medium 2 at a constant temperature, the laser beam power (standard power) for realizing the above-described temperature rise state is obtained in advance. It is possible to adjust the laser light power of the local temperature raising device 1 to the standard power by the control device 8 during reproduction. For example, (a) the above-mentioned standard power is stored in the internal memory in the heat-assisted magnetic signal reproducing device, the control device 8 reads the standard power during reproduction, and performs laser light power control based on the standard power. (B) The standard power is recorded in a predetermined area of the magnetic recording medium 2 (for example, a part of the inner circumference or the outer circumference of the information recording area), and based on the standard power reproduced from the magnetic recording medium 2 during reproduction. The laser light power is controlled.
[0063]
However, under normal conditions of use, even if the temperature is locally increased with the same laser beam power, the magnetic recording medium 2 is always at a desired temperature due to changes in the environmental temperature, changes in the linear velocity of the magnetic recording medium 2, and the like. Not exclusively. Therefore, in order to cope with these changes, it is desirable to adjust by changing the laser beam power.
[0064]
For example, when the temperature at the time of non-heating in the magnetization information detection region of the magnetic recording medium 2 increases (hereinafter referred to as the reference temperature) due to the increase in the environmental temperature, as shown in FIG. Reduce optical power (lower maximum temperature). In this way, it is possible to make the average temperature of the track (adjacent track) not desired to be reproduced close to the magnetic compensation point temperature (about 100 ° C.) and cancel the magnetization information there. On the contrary, when the temperature of the magnetic recording medium 2 is lowered, as shown in FIG. 9 (a), the laser beam power is increased to a certain value (lowering the maximum temperature), and the average temperature of the tracks that are not desired to be reproduced. Can be about 100 ° C.
[0065]
The adjustment of the laser light power accompanying the change in the environmental temperature is a laser in which the temperature at a certain position in the heat-assisted magnetic signal reproducing apparatus and the average temperature of the adjacent tracks 5a and 5c are set to a substantially magnetic compensation point temperature (Tcomp = about 100 ° C.). When the relationship between the optical powers is obtained, the temperature (or environmental temperature) of the magnetic recording medium 2 is detected by a thermistor or the like, and the laser light power is adjusted based on the detected temperature.
[0066]
Further, the adjustment of the laser beam power accompanying the change in the linear velocity of the magnetic recording medium 2 can be performed by changing the laser beam power in accordance with the reproduction target track. For example, the thermomagnetic recording device stores each track and the laser beam power required for each track as a table in an internal memory, and refers to the internal memory at the time of reproduction, so that the control device 8 causes the local heating device This can be realized by operating 1.
[0067]
As a more effective method, there is a method in which a magnetic control medium 2 is provided with a power control region (temperature increase state control region) for controlling the laser beam power. This will be described with reference to FIG.
[0068]
FIG. 10 is a diagram for explaining the laser light power control region 50. For simplicity, only a part of three tracks (tracks 5a, 5b, 5c in FIG. 1) is shown. The laser light power control area 50 is arranged at a known position in the information recording area 51 for recording information data. The laser light power control region 50 is a laser light power control block (here, the track 5a) having a width at least equal to or larger than the width of the magnetization information detection region 4 in the track width direction (direction perpendicular to the reproduction scanning direction). , 5b, 5c, the laser light power control region 50) 54 is formed. Magnetization information is recorded in the laser light power control areas 50 of the tracks 5a, 5b, and 5c in bit patterns having different periods (track 5a: 1T period, track 5b: 2T period, track 5c: 4T period). ing.
[0069]
When the center track 5b is reproduced, if the laser beam power is an appropriate value, only a 2T period signal should be reproduced from the laser beam power control area 50, but the laser beam power deviates from the appropriate value. 1T period and 4T period signals are superimposed (example of the signal is shown in FIG. 10B).
[0070]
For this reason, it is detected by using a filter or the like what period signal the signal shown in FIG. 10B includes, and signals of 1T period and 4T period are not detected (or very low level). If the laser beam power is adjusted so that the laser beam power is appropriate, an appropriate laser beam power can be obtained.
[0071]
Further, the laser light power can be detected also by detecting the phase of the reproduction signal from the laser control area 50.
[0072]
In FIG. 10, a different bit pattern is recorded on each of the three tracks (5a, 5b, 5c), but it is sufficient if a bit pattern different from the adjacent track is recorded in the laser control area 50. The bit patterns recorded in 5a and 5c may be the same.
[0073]
FIG. 11 shows another example of the laser light power control region. The laser light power control region 50 'includes a region (Q1, Q3,...) Where the track b and the tracks a, c are magnetized in the same direction and a region (Q2, Q4,...) Magnetized in the opposite direction. A bit pattern is formed so as to have In the magnetic recording medium 2 having such a laser beam power control area 50 ′, the laser beam power control area 50 ′ is reproduced, and the reproduction signal from Q1 (or Q3) and the signal from Q2 (or Q4) are reproduced. The laser light power can be controlled by taking a difference from the reproduction signal and determining whether the signal is positive or negative.
[0074]
Note that the laser light power control as described above does not function effectively if a tracking error occurs. For this reason, it is desirable to perform tracking control, which will be described later, simultaneously in the laser light power control region 50 or immediately before the laser light power control region 50.
[0075]
The laser beam power control area 50 (50 ′) may be recorded at a predetermined position (for example, a part of the inner and outer circumferences of the disk) of the magnetic recording medium, but the linear velocity of the magnetic recording medium 2 is reproduced. When changing according to the position, it is desirable to provide at least for each part where the linear velocity changes (for example, for each block, each track, and each sector) in terms of precise control of laser light power. Even if the laser light power control region 50 is not provided every time the linear velocity changes, if the laser light power is adjusted using a table or calculation according to the linear velocity (according to the reproduction position), the Appropriate laser beam power can be obtained.
[0076]
Further, the laser light power control area 50 (50 ′) is a case where the laser light power is controlled based on whether or not the reproduction signal is mixed from the adjacent tracks 5a and 5c, as in the examples of FIGS. It is necessary to provide the laser light power control block 54 unit having a width equal to or greater than that of the magnetization information detection region 4 in at least the track width direction (direction perpendicular to the scanning direction). In this way, precise control can be realized rather than controlling the laser beam power based on the reproduction signal amplitude from the laser beam power control area 50 in the track 5b, for example.
[0077]
According to the adjustment control of the laser beam power using the laser beam power control area 50 described above, it is possible to cope with the environmental temperature change and the linear velocity change of the magnetic recording medium 2, and the magnetization of the reproducing head 3. Even when the information detection sensitivity changes in the magnetization information detection region due to heat, it can be corrected.
[0078]
(4) Use conditions of magnetic recording medium 2 (design of magnetic recording medium 2)
In the present embodiment, in the region where the temperature (reference temperature) of the magnetic recording medium 2 immediately below the magnetization information detection region 4 of the reproducing head 3 at the time of no temperature rise is higher than the magnetic compensation point temperature of the magnetic recording medium 2, In principle, it is impossible to cancel information. In addition to this, from the viewpoint of signal quality, the temperature in the track (5b) that is desired to be reproduced cannot be reproduced unless it is in a temperature range that produces magnetization larger than the extent that the reproducing head 3 can detect. Further, when the temperature in the magnetic recording medium 2 reaches the vicinity of the Curie temperature, the magnetization information becomes unstable and may disappear, so the maximum temperature reached in the local temperature rise must not reach the vicinity of the Curie temperature. . Therefore, in the present embodiment, the reference temperature needs to be within a certain range.
[0079]
Conversely, the temperature characteristics of the magnetic recording medium 2 can be designed from the assumed reference temperature and the magnitude of magnetization that can be detected by the reproducing head. This is specifically shown below.
[0080]
In order to simplify the calculation, the temperature rise distribution is approximated by a combination of linear functions as shown in FIG. The distribution range of the rising temperature is constant, and only the rising temperature is proportional to the laser power. Further, in the magnetic recording medium 2, the point at which the temperature is highest is located in the approximate center of the magnetization information detection region in the reproducing head 3, and this temperature is referred to as the highest temperature reached.
[0081]
When the reference temperature is about 50 ° C. and the magnetic compensation point temperature in the magnetic recording medium 2 is about 100 ° C., the maximum temperature reached for the average temperature of the both end tracks 5a and 5c in FIG. Consider an example at 200 ° C.
[0082]
Here, when the reference temperature becomes about 25 ° C. due to the decrease in the environmental temperature, the maximum temperature for setting the average temperature of the tracks at both ends to about 100 ° C. is about 250 ° C., and the average temperature of the central track 5b is 212.degree. 5 ° C. On the other hand, when the reference temperature is about 75 ° C. due to the increase in the environmental temperature, the maximum temperature for setting the average temperature of the tracks at both ends to about 100 ° C. is also about 150 ° C. Is 137.5 ° C. FIG. 13 is a diagram showing the relationship between the reference temperature, the maximum temperature reached, and the average temperature of the central track.
[0083]
From this figure, the use conditions of the magnetic recording medium 2 can be determined. For example, if the Curie temperature of the magnetic recording medium 2 is 250 ° C. and the lower limit of the average temperature of the central track 5b at which the reproducing head can detect the magnetization information is about 137.5 ° C., the magnetization information in the magnetic recording medium 2 is not obtained. It can be seen that the reference temperature range in which magnetization information can be detected without stabilization is about 25 ° C. or more and about 75 ° C. or less.
[0084]
Conversely, when it is desired to use the magnetic recording medium 2 within a certain range of reference temperatures, the magnetic compensation point temperature, the Curie temperature, and the reproducing head of the magnetic recording medium 2 can detect the magnetization information by the reverse operation. What is necessary is just to obtain | require the lower limit of the average temperature of the center track | truck 5b, and to select what satisfies it.
[0085]
Further, when the laser power is changed, the temperature distribution of all of the above three tracks (5a, 5b, 5c) changes, but the temperature of the track 5b desired to be reproduced changes depending on the magnetization temperature of the magnetic recording medium 2. If the temperature characteristics of the magnetization of the magnetic recording medium 2 are designed to be near a low temperature (near Tpeak in FIG. 5), the magnetization of the track desired to be reproduced does not change greatly. In particular, in the case of a general n-type ferrimagnetic material, this is near the maximum of magnetization, and it is advantageous because the absolute value of magnetization in the track 5b desired to be reproduced can be made large.
[0086]
(5) Tracking control
Next, tracking control in the heat-assisted magnetic signal reproduction system of this embodiment will be described.
[0087]
FIG. 14 is a diagram for explaining tracking control. FIG. 14A shows the case where there is no tracking deviation, and FIGS. 14B and 14C show the case where tracking deviation occurs. 14 shows the case where the magnetization in the same direction is recorded on each of the tracks 5a, 5b and 5c. The reproduction signal intensity in FIG. 14 is shown by separating the reproduction signals obtained from the tracks 5a, 5b and 5c for each track (ignoring the magnetization direction).
[0088]
In the case of FIG. 14A, the temperature of the magnetic recording medium is distributed around the central track 5b, and the magnetization of the magnetic recording medium cancels out as a whole in the tracks 5a and 5c and becomes substantially zero. Therefore, a reproduction signal cannot be obtained from the tracks 5a and 5c.
[0089]
On the other hand, in the case of FIGS. 14B and 14C, the magnetic recording medium temperature is distributed out of the center of the central track 5b. For this reason, both the tracks 5a and 5c have a large magnetization, and a reproduction signal is generated. In this case, the reproduction signal from the adjacent tracks 5a and 5c becomes noise. Therefore, when tracking deviation occurs as shown in FIGS. 14B and 14C, the reproduction signal quality deteriorates.
[0090]
For this reason, tracking control is very important in this embodiment. Although there are various tracking control methods, here, a method of performing tracking control using the characteristics of the heat-assisted magnetic signal reproduction method of the present embodiment will be described.
[0091]
FIG. 15 is a diagram for explaining this tracking control method. For simplicity, only a part of three tracks (tracks 5a, 5b, 5c in FIG. 1) is shown. A tracking control area 52 is provided in the information recording area 51 for recording information data. This tracking control area 52 is arranged at a known position, and has a known magnetization with a bit pattern of different periods (track 5a: 1T period, track 5b: 2T period, track 5c: 4T period) on tracks 5a, 5b, 5c. Information is recorded.
[0092]
When the central track 5b is reproduced, if there is no tracking deviation, only the 2T period signal should be reproduced from the tracking control area 52. However, if the tracking deviation occurs, the 1T period and 4T period signals are reproduced. Are superimposed. Therefore, if it is detected by using a filter or the like what period the reproduction signal from the tracking control area 52 contains, tracking control can be performed based on the detection result.
[0093]
Specifically, the intensities of the 1T period signal (track 5a) and the 4T period signal (track 5c) are compared. If the intensity is the same, it is determined that there is no tracking deviation. Conversely, if either intensity is higher, the center of the laser spot (and the center of the reproducing head 3) is shifted to the larger one. Therefore, the center of the laser spot (and the center of the reproducing head 3) is moved to the lower intensity side to eliminate the tracking deviation.
[0094]
▲ 6 ▼ Other
The heat-assisted magnetic signal reproduction method (magnetic signal reproduction device, magnetic signal reproduction method, magnetic recording medium) of the present embodiment described above is an example, and various modifications can be made within the scope of the present embodiment. Is possible.
[0095]
For example, the track pitch, laser spot diameter, track interval, and the like in the present embodiment are not limited to this.
[0096]
Further, the magnetic recording medium is not limited to the present embodiment as long as the polarity of magnetization is reversed with temperature. Unlike the above example, if TbFeCo near the composition of Tb21%, Fe68%, and Co13% is used, it is suitable for high-density recording.
[0097]
Further, the moving mechanism of the relative position of the reproducing head 3 with respect to the magnetic recording medium is not limited to the present embodiment as long as it can detect the magnetization information recorded on the magnetic recording medium with the reproducing head. In the above-described embodiment, the reproducing head 3 and the local temperature raising device 1 are arranged with the magnetic recording medium 2 interposed therebetween. However, both the reproducing head 3 and the local temperature raising device 1 are disposed on one side with respect to the magnetic recording medium 2. It goes without saying that may be arranged.
[0098]
Here, the width in the track width direction of the magnetization information detection region 4 of the reproducing head 3 is set to the width of three tracks. However, the width is not limited to this, and is larger than about one track and about three tracks. If it is a thing, the heat-assisted magnetic signal reproduction | regeneration system of this Embodiment is applicable. However, if the width in the track width direction of the magnetization information detection region 4 is about three tracks, the highest density reproduction can be realized in the method of the present embodiment.
[0099]
Further, the laser light power control recording area 50 and the tracking control recording area 52 described above may be the same area. That is, laser light power control and tracking control may be performed using the same known bit pattern. Further, at least one of the bit patterns recorded in the laser light power control recording area 50 and the tracking control recording area 52 may be address information. In these cases, the known data recording area can be reduced, and the information data recording area can be increased. Needless to say, the bit pattern is not limited to those shown in FIGS.
[0100]
[Embodiment 2]
The heat-assisted magnetic signal reproducing apparatus of the present embodiment was recorded at an equal interval and an equal track pitch by the magnetic signal reproducing method using an n-type ferrimagnetic material having a magnetic compensation point temperature higher than that in the non-temperature rising state. The magnetic recording information is reproduced by a reproducing head having a reproducing head magnetization information detection area approximately 5 times the track pitch, and the magnetization information of only the track located at the substantially central portion of the reproducing head magnetization information detection area is reproduced. However, laser light including higher-order diffracted light is irradiated as a local temperature raising means.
[0101]
In the present embodiment, components having the same functions as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.
[0102]
FIG. 16 is a diagram showing the configuration of the heat-assisted magnetic signal reproducing device of the present embodiment. Unlike the heat-assisted magnetic signal reproducing apparatus according to the first embodiment shown in FIG. 7, this heat-assisted magnetic signal reproducing apparatus employs a local temperature raising device 11.
[0103]
The local temperature raising device 11 forms a laser spot having an intensity distribution as shown in FIG. 17 on the magnetic recording medium 2. For comparison, FIG. 17 also shows the intensity distribution of the laser spot by the local heating device 1 of the first embodiment. As shown in this figure, in this embodiment, a laser beam including higher-order diffracted light is irradiated onto the magnetic recording medium 2. That is, laser light having auxiliary light beams on both sides in addition to the central main light beam is irradiated. In this case, even if optical systems having the same wavelength and the same aperture diameter are used, the diameter of the central light beam in the local temperature riser 11 is larger than that in the local temperature riser 1 of the first embodiment due to the diffraction phenomenon. Becomes smaller.
[0104]
The positional relationship between the magnetization information detection region 4 of the reproducing head 3 and the laser spot is as shown in FIG. 17, and the position where the light intensity is highest (center position) and the center of the magnetization information detection region 4 are substantially coincident. Is set to
[0105]
FIG. 18 is a diagram showing a temperature distribution that appears on the magnetic recording medium 2 by irradiation with a laser spot by the local temperature raising device 11. As shown in this figure, on the magnetic recording medium 2, high temperature portions appear at the center portion of the laser spot and at three locations on both sides thereof. The temperature of the high temperature portion of the magnetic recording medium 2 is set higher than the magnetic compensation point temperature Tcomp (about 100 ° C.).
[0106]
FIG. 19 shows the temperature distribution of the magnetic recording medium 2 (FIG. 19A) and the magnetization (FIG. 19B) when the magnetic recording medium 2 is heated in the uniform direction when the magnetization is increased. It is a figure shown with the detection area 4, the temperature rising area 9 (FIG. 19 (d)), and the track 5 (FIG. 19 (d)) formed in the magnetic recording medium 2. In the present embodiment, there are five tracks 5d, 5e, 5f, 5g, and 5h in the magnetization information detection region 4 of the reproducing head 3. As shown in this figure, the local temperature raising device 11 heats the central track (reproduction target track) 5f of the magnetic recording medium 2 to Tcomp or higher, and the average temperature of the tracks 5d, 5e, 5g, and 5h becomes near Tcomp. To heat. For example, in the magnetic recording medium 2 shown in FIG. 19A, the points (X1, X2, X3, X4) at which the temperature is approximately Tcomp are substantially track widths between X1 and X2 and between X3 and X4. Heating is performed so that the space between X2 and X3 is approximately twice the track width.
[0107]
At this time, magnetic flux is generated from the central track 5f and a reproduction signal is obtained. However, since the magnetization of the tracks 5c, 5d, 5g and 5h is canceled out and becomes substantially zero as a whole, no reproduction signal is generated. Therefore, it is possible to reproduce the magnetization information of only the central track 5f.
[0108]
Also in the present embodiment, laser light power control, tracking control, use condition setting, and the like can be performed in the same manner as in the first embodiment.
[0109]
Furthermore, the present embodiment can be variously modified similarly to the first embodiment.
[0110]
【The invention's effect】
According to the present invention, since the contribution of the magnetization information in the temperature rising region to the magnetization information detection region of the reproducing means can be reduced or offset, the magnetization information in a narrower range than the temperature rising region can be offset. When detecting the magnetization information, the mixing information can be reduced and the magnetization information can be detected with a high S / N ratio.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram for explaining a high-density reproduction principle according to Embodiment 1;
FIG. 2 is a diagram showing a positional relationship among a bit pattern, a magnetization information detection region, and a laser spot of the magnetic recording medium according to the first embodiment.
FIG. 3 is a diagram illustrating a temperature distribution formed on a magnetic recording medium by irradiation with a laser spot.
FIG. 4 is a diagram showing a bit pattern of a magnetic recording medium, a magnetization direction at the time of recording, and a magnetization at the time of temperature increase during reproduction.
FIG. 5 is a diagram showing magnetic characteristics of the magnetic recording medium according to the first embodiment.
FIG. 6 is a diagram for explaining a reproducing method when there is a distribution in magnetization information detection sensitivity.
FIG. 7 is a schematic diagram showing the main configuration of the magnetic signal reproducing apparatus according to the first embodiment.
FIG. 8 is a schematic diagram showing an overall configuration of the magnetic signal reproducing apparatus of the first embodiment.
FIG. 9 is a diagram for explaining a regeneration method when the reference temperature changes.
FIG. 10 is a diagram illustrating a laser light power control region.
FIG. 11 is a diagram illustrating another example of a laser light power control region.
FIG. 12 is a diagram for explaining a method for approximating the temperature distribution of a magnetic recording medium.
FIG. 13 is a diagram illustrating a method for setting a usage state of a magnetic recording medium.
FIG. 14 is a diagram illustrating a racking control method.
FIG. 15 is a diagram illustrating a tracking control region.
FIG. 16 is a schematic diagram showing a main configuration of a magnetic signal reproducing device according to a second embodiment.
FIG. 17 is a diagram for explaining the light intensity distribution of a laser beam spot emitted from the local temperature raising apparatus according to the second embodiment.
FIG. 18 is a diagram for explaining a temperature distribution formed on a magnetic recording medium by the local heating device of the second embodiment.
FIG. 19 is a diagram illustrating a magnetic signal reproduction method according to the second embodiment.
FIG. 20 is a diagram showing a positional relationship between a bit pattern of a magnetic recording medium, a magnetization information detection region, and a laser spot.
FIG. 21 is a diagram showing magnetic characteristics of a conventional magnetic recording medium.
FIG. 22 is a diagram illustrating the principle of a conventional heat-assisted magnetic signal reproduction method.
[Explanation of symbols]
1,11 Local temperature riser
2 Magnetic recording media
3 Playback head
4 Magnetization information detection area
5 tracks
5b Center track (reproduction target track)
5a, 5c Adjacent track
9 Laser spot
50, 50 'Laser light power control area
52 Tracking control area
54 Laser light power control block
Tcomp Magnetic compensation point temperature

Claims (17)

In a magnetic signal reproducing apparatus that has a magnetic film having a magnetic compensation point temperature as a first temperature and reproduces information from a magnetic recording medium in which the polarity of magnetization is reversed at the first temperature when the temperature is raised,
Local heating means for locally heating the magnetic recording medium;
A reproducing means having a magnetization information detection region for magnetically detecting magnetization information recorded on the magnetic recording medium,
The local temperature raising means includes a temperature region lower than the first temperature and a temperature higher than the first temperature in a region outside the reproduction target region in the magnetic recording medium and facing the magnetization information detection region during the reproduction operation. The magnetic signal reproducing device is characterized in that the temperature region is formed. In a magnetic signal reproducing apparatus that has a magnetic film having a magnetic compensation point temperature and reproduces information from a magnetic recording medium formed so that the polarity of magnetization information is reversed at the magnetic compensation point temperature when the temperature changes,
A local temperature raising means for locally raising the temperature of the magnetic recording medium, and a reproducing means having a magnetization information detection region for magnetically detecting magnetization information recorded on the magnetic recording medium,
The local temperature raising means includes a temperature region lower than the magnetic compensation point temperature within the region facing the magnetization information detection region in the magnetic recording medium and outside the reproduction target region during the reproducing operation, and the magnetic A magnetic signal reproducing device, wherein a temperature region higher than the compensation point temperature is formed. The magnetic signal reproducing device according to claim 2 ,
The magnetic recording medium is formed with a plurality of tracks for recording information,
The local temperature raising means includes a temperature region lower than the magnetic compensation point temperature and a temperature higher than the magnetic compensation point temperature in each of the tracks other than the reproduction target track in the region facing the magnetization information detection region during the reproduction operation. The magnetic signal reproducing device is characterized in that the temperature region is formed. The magnetic signal reproducing apparatus according to claim 2 or 3 ,
The local signal raising means raises the temperature so that an average temperature of the low temperature region and the high temperature region is substantially the same as the magnetic compensation point temperature. A plurality of tracks for recording information are formed, and a magnetic film having a magnetic compensation point temperature is provided, and information is reproduced from a magnetic recording medium in which the polarity of magnetization information is reversed at the magnetic compensation point temperature when the temperature changes. In the magnetic signal reproducing apparatus to
A local temperature raising means for irradiating the magnetic recording medium with laser light to locally raise the temperature of the magnetic recording medium;
It has a magnetization information detection region for magnetically detecting magnetization information recorded on the magnetic recording medium, and is arranged so that the center of the laser beam and the center of the magnetization information detection region substantially coincide with each other in the track width direction. And a reproducing means,
The magnetization information detection region has a width facing at least a part of each of the three tracks of the magnetic recording medium in the track width direction.
During the reproducing operation, the local temperature raising means raises the temperature of the central track facing the magnetization information detection region to a temperature higher than the magnetic compensation point temperature, and the two tracks adjacent to the central track are in the two tracks. A magnetic signal reproducing apparatus, wherein the temperature is raised so that the average temperature of each of the regions facing the magnetization information detection region substantially coincides with the magnetic compensation point temperature. The magnetic signal reproducing device according to any one of claims 2 to 4 ,
The magnetic signal reproducing apparatus, wherein the local temperature raising means forms a temperature distribution having at least two maximum values exceeding the magnetic compensation point temperature on the magnetic recording medium. The magnetic signal reproducing device according to any one of claims 2 to 6 ,
A magnetic signal reproducing apparatus comprising control means for controlling the operation of the local temperature raising means to change the temperature rise state of the magnetic recording medium. The magnetic signal reproducing apparatus according to claim 7 , wherein
The magnetic recording medium is provided with a temperature rise state control region in which known data for controlling a temperature rise state by the local temperature raising means is recorded,
The magnetic signal reproducing apparatus, wherein the control means controls the operation of the local temperature raising means based on a reproduction signal reproduced from the temperature rise state control region. The magnetic signal reproducing apparatus according to claim 8 , wherein
2. The magnetic signal reproducing apparatus according to claim 1, wherein the temperature rise state control region is formed in at least one place in a region where the linear velocities in the magnetic recording medium are substantially the same. The magnetic signal reproducing apparatus according to any one of claims 7 to 9,
The temperature rise state control region comprises a temperature rise state control block having a width at least equal to or larger than the width of the magnetization information detection region in a direction perpendicular to the scanning direction of the reproducing means. Signal reproduction device. The magnetic signal reproducing apparatus according to claim 7 , wherein
Comprising a detecting means for measuring a use environment temperature of the magnetic recording medium,
The said control means controls the operation | movement of the said local temperature rise means based on the detection result of the said detection means, The magnetic signal reproducing | regenerating apparatus characterized by the above-mentioned. A magnetic recording medium having a magnetic film having a magnetic compensation point temperature as a first temperature, the polarity of magnetization information being reversed at the first temperature at the time of temperature increase is used, and the magnetic recording medium is locally heated. Magnetic signal reproducing method for magnetically detecting magnetization information recorded on the magnetic recording medium by a reproducing means having a magnetization information detection region facing at least a part of the heated portion locally Because
During the reproducing operation, a temperature region lower than the first temperature and a temperature region higher than the first temperature are formed in a region outside the reproduction target region on the magnetic recording medium and facing the magnetization information detection region. And heating the magnetic recording medium. The magnetic signal reproducing method according to claim 12 ,
A magnetic signal reproducing method, wherein the temperature is raised so that the overall magnetization in the low temperature region and the overall magnetization in the high temperature region are substantially the same. The magnetic signal reproducing method according to claim 12 ,
A magnetic signal reproducing method, wherein the temperature is raised so that an absolute value of average magnetization in the low temperature region and an absolute value of average magnetization in the high temperature region are substantially the same. A magnetic recording medium having a magnetic film having a magnetic compensation point temperature and formed so that the polarity of magnetization information is reversed at the boundary of the magnetic compensation point temperature when the temperature changes is used. A magnetic signal for locally detecting the magnetization information recorded on the magnetic recording medium by a reproducing means having a magnetization information detection region facing at least a part of the heated portion while being locally heated by the temperature means A playback method,
During the reproducing operation, a temperature region in the magnetic recording medium facing the magnetization information detection region and outside the reproduction target region, a temperature region lower than the magnetic compensation point temperature, and a temperature higher than the magnetic compensation point temperature. A magnetic signal reproducing method, wherein the temperature of the magnetic recording medium is increased so as to form a region. A plurality of tracks for recording information is formed, a magnetic recording medium having a magnetic film having a magnetic compensation point temperature, and a magnetic recording medium in which the polarity of magnetization information is reversed at the boundary of the magnetic compensation point temperature at the time of temperature change, The magnetic recording medium is locally heated by laser light irradiation and recorded on the magnetic recording medium by a magnetization information detection area of a reproducing means having a magnetization information detection area facing at least a part of the heated portion. A magnetic signal reproducing method for magnetically detecting the magnetization information,
The magnetization information detection region has a width facing at least a part of each of the three tracks of the magnetic recording medium in the track width direction.
The reproducing means is arranged so that the center of the laser beam and the center of the magnetization information detection region substantially coincide with each other in the track width direction,
During the reproducing operation, the central track facing the magnetization information detection region is heated to a temperature higher than the magnetic compensation point temperature, and is opposed to the magnetization information detection region in two tracks adjacent to the central track. A magnetic signal reproducing method, wherein the temperature is raised so that the average temperature of each region substantially coincides with the magnetic compensation point temperature. In the magnetic recording medium in which the magnetization information at the heated portion is magnetically reproduced while being heated locally
A magnetic layer having a magnetic compensation point temperature as the first temperature;
Magnetic signal reproducing apparatus comprising: a local temperature raising means for locally raising the temperature of the magnetic recording medium; and a reproducing means having a magnetization information detection region for magnetically detecting magnetization information recorded on the magnetic recording medium The local temperature raising means includes a temperature region lower than the first temperature and a temperature lower than the first temperature in a region outside the reproduction target region on the magnetic recording medium and facing the magnetization information detection region during the reproduction operation. By forming a high temperature region, the polarity of the magnetization is reversed at the magnetic compensation point temperature at the time of temperature rise,
A magnetic recording medium comprising a temperature rising state control area in which known data is recorded for controlling a temperature rising state.

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