JP2001229543A - Method and device for reproducing optical recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve problems of small light quantity from recording marks and decrease in the S/N of the reproduced signal by conventional methods because the light scattered by the interaction between near-field light and a recording layer and containing the information of recording marks in the recording layer is cut by a mask layer except for the aperture and the signal is read out through the minute aperture. SOLUTION: An optical disk 2 having the recording layer 15 and the mask layer 13 in which the refractive index reversibly changes by irradiation of light or heating is used. A laser beam 1 is made to enter the optical disk 2 to produce an aperture 4 in the mask layer 13. In the light scattered by the interaction between the recording layer and the near-field light produced by the aperture 4, the scattered light f transmitting the area other than the aperture is used to reproduce the information.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reproducing method and a reproducing apparatus for an optical recording medium which exceeds the diffraction limit of light by using near-field light.

[0002]

2. Description of the Related Art Hitherto, various methods have been developed to increase the density of optical recording. For example, the magazine "Electronics" (published by Ohmsha), October 1998 issue of 100
~ 102 pages, or Applied Physics Letter
s, Vol. 73, No. 15, 12 October 1998, pp. 2078-2080, discloses a recording / reproducing method using near-field light.
The near-field light is such that an electromagnetic field generated by light in a medium has slightly leaked out to the surface of the medium, and is localized so as to be close to the surface of the medium.

[0005] A conventional reproducing method using this near-field light will be described with reference to FIG. The optical disk 102 used in this method has a structure in which a protective layer 112, a mask layer 113, a protective layer 114, a recording layer 115, and a protective layer 116 are sequentially formed on a substrate 111, as shown in FIG. Here, the recording film 115 is made of Ge which is a phase change material.
₂ Sb ₂ Te ₅ is used and the information is recorded mark m
Recorded in. Further, the mask layer 113 has a material having a property that only the high temperature portion at the center of the irradiated laser spot 101a changes from opaque to transparent and reversibly.
An antimony film is used.

When such an optical disk 102 is irradiated with a laser beam 101 through an objective lens 105, the refractive index changes at a high temperature portion at the center of the laser spot 101a of the antimony film constituting the mask layer 113, and the optical disk 102 changes from opaque to transparent. The aperture 103 changes to form the aperture 103 smaller than the spot diameter in the mask layer 113. Aperture 103
Is a fine opening of several nm to several hundred nm.

[0005] Near-field light 104 is generated in the aperture 103 (including the periphery of the aperture), and the generated near-field light 104 reaches the recording layer 115 from the aperture 103.
The light is scattered by interaction with the recording layer 115 and becomes scattered light including information of the recording mark m recorded on the recording layer 115. Then, the scattered light is received through the aperture 103, and the information of the recording mark m of the recording layer 115 is reproduced. Thereby, it is possible to reproduce the recording mark m of 100 nm or less smaller than the laser wavelength.

In order to enable such reproduction, the thickness of the protective layer 114 between the recording layer 115 and the mask layer 113 on the optical disk 102 is determined by the near-field light 104 generated by the aperture 103. 115
Is set to reach the distance.

[0007]

However, in the above-described reproducing method, the aperture 10 in the mask layer 113 is not used.
In regions other than 3, light is blocked, and scattered light is received through the aperture 103, which is a fine opening. Therefore, the amount of scattered light including information on the recording mark m is small. Therefore, there is a problem that the SN ratio of the reproduced signal is reduced, and it becomes difficult to reproduce information.

[0008] By increasing the aperture 103, the amount of scattered light transmitted through the aperture 103 can be increased. However, when the aperture 103 is increased, the resolution is reduced.
Therefore, it is not preferable to increase the aperture 103 to increase the SN ratio of the reproduced signal.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and has been made in consideration of the above-described problems. The light used for reproducing information can be reproduced with a high SN ratio by increasing the amount of scattered light containing information of a recording mark. It is an object of the present invention to provide a method and apparatus for reproducing a recording medium.

[0010]

In order to solve the above-mentioned problems, the reproducing method of the optical recording medium of the present invention has a recording layer for recording optical information and a refractive index which is changed by light irradiation or heating. Using an optical recording medium having a functional layer in which a change occurs reversibly, a light flux is incident on the optical recording medium to cause a local refractive index change region in the functional layer, and the change occurs in the refractive index change region. The optical information of the recording layer is read out from the scattered light scattered by the interaction between the near-field light and the recording layer and transmitted through a region other than the refractive index change region.

The scattered light, which is generated by the interaction between the near-field light generated in the refractive index change region of the functional layer and the recording layer and contains the optical information recorded on the recording layer, is refracted by the functional layer. It is divided into those that transmit through the index change region and those that transmit through a wide area other than the refractive index change region.

Among them, the scattered light transmitted through the refractive index change region has high intensity because of high transmittance, but when the area of the refractive index change region cannot be increased because the area of the refractive index change region is small, the scattered light Looking at the total amount of light,
It becomes smaller than scattered light transmitted through areas other than the refractive index change region. On the other hand, the scattered light transmitted through the area other than the refractive index change region has a low transmittance and thus the intensity is small, but the smaller the area of the refractive index change region is, the larger the area is. growing.

Therefore, in the present invention, as described above, the optical information of the recording layer is read from the scattered light transmitted through a region other than the refractive index change region, which is conventionally blocked. This makes it possible to increase the amount of scattered light including the optical information of the recording layer without increasing the refractive index change region, so that the SN ratio of the reproduction signal can be increased and the reproduction of the recorded information becomes easy.

In the above-described method for reproducing an optical recording medium according to the present invention, the light amount of a light beam applied to the optical recording medium or the relative linear velocity between the optical recording medium and the applied light beam is controlled to change the refractive index. It is desirable that the intensity of the scattered light transmitted through the region other than the region be greater than the intensity of the scattered light transmitted through the refractive index change region.

[0015] The size of the refractive index change region formed in the functional layer is determined by the temperature distribution in the functional layer. Therefore,
By controlling the relative light velocity of the light beam irradiated on the optical recording medium or the light beam irradiated on the optical recording medium, and as described above, the intensity of the scattered light transmitted through the area other than the refractive index change area, By making the intensity of the scattered light transmitted through the refractive index change region larger than the intensity of the scattered light transmitted through the region other than the refractive index change region contributing to reproduction, the size of the refractive index change region is appropriately controlled. By increasing the number, the SN ratio of the reproduced signal can be increased more efficiently, and the reproduction of the recorded information can be facilitated.

In order to solve the above-mentioned problems, in the method of reproducing an optical recording medium according to the present invention, a recording layer for recording optical information and a refractive index are changed by light irradiation or heating. By using an optical recording medium having a functional layer and a light flux incident on the optical recording medium, a local refractive index change region is generated in the functional layer, and recording is performed with near-field light generated in the refractive index change region. The optical information of the recording layer is read from the scattered light scattered by the interaction with the layer, and when reading the optical information, the optical recording medium is irradiated so that the signal amount of the reproduced signal obtained from the scattered light becomes a maximum value. It is characterized by controlling the amount of light flux to be emitted or the relative linear velocity between the optical recording medium and the light flux.

From the relationship between the light amount (intensity) of the light beam and the signal amount of the reproduced signal, as described above, the light amount of the light beam or the optical recording is adjusted so that the signal amount of the reproduced signal obtained from the scattered light becomes a maximum value. By controlling the relative linear velocity between the medium and the luminous flux,
It is possible to appropriately control the size of the refractive index change region in the functional layer so that the intensity of scattered light passing through the region other than the refractive index change region is larger than the intensity of scattered light passing through the refractive index change region. It becomes possible. Therefore, also in this case, it is possible to easily reproduce the recorded information by increasing the SN ratio of the reproduced signal.

[0018] In order to solve the above-mentioned problems, a reproducing apparatus for an optical recording medium according to the present invention comprises: a recording layer for recording optical information;
Using an optical recording medium having a functional layer in which the refractive index changes due to light irradiation or heating, and this change occurs reversibly, irradiates the optical recording medium with a light beam while receiving the reflected light. Means, rotation control means for controlling rotation of the optical recording medium, reproduction means for reproducing optical information of the recording layer based on a reproduction signal obtained from the reflected light read by the light beam irradiation means, and a maximum of the reproduction signal. A maximum value detecting means for detecting a value,
Control means for controlling at least one of the light beam irradiation means and the rotation control means so that the reproduction signal has a maximum value based on the detection result by the maximum value detection means.

According to this, the local maximum value detecting means detects the local maximum value of the reproduction signal, and the control means based on the detection result,
At least one of the light beam irradiation means and the rotation control means is controlled so that the signal amount of the reproduction signal obtained from the scattered light has a maximum value. Thereby, the size of the refractive index change region in the functional layer is appropriately controlled such that the intensity of the scattered light passing through the region other than the refractive index change region becomes larger than the intensity of the scattered light passing through the refractive index change region. In addition, it is possible to easily reproduce recorded information by increasing the SN ratio of a reproduced signal.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to FIGS. The optical disk as an optical recording medium used here is of a phase change type,
It has a structure shown in FIG. In FIG.
A protective layer 12, a mask layer (functional layer) 1
3, a protective layer 14, a recording layer 15, and a protective layer 16 are laminated in this order.

The substrate 11 is made of glass or polycarbonate, and the protective layers 12, 14, 16 are made of SiN or Zn.
It is formed of a dielectric material such as S-SiO _2. Also,
Recording film 15 is formed of a phase change material such as Ge ₂ Sb ₂ Te _5. The recording layer 15 is crystallized in advance, and the recording mark M is formed by amorphization. Therefore, the recording layer 15 is composed of the recording marks M in the amorphous state and the other crystalline regions N.

The mask layer 13 is formed from an antimony film. As the mask layer 13, a material having a property that a portion corresponding to the center portion of the laser spot 1a changes from opaque to transparent when the optical disk 2 is irradiated with the laser beam (light flux) 1, As a result of experiments, it has been found that the above-mentioned antimony film is optimal.

When an antimony film is used to irradiate the laser spot 1a, an aperture (a refractive index change region) 4 having a diameter smaller than the spot diameter is formed on the mask layer 13.
Is formed. By appropriately adjusting the laser power, the size of the aperture 4 becomes sufficiently shorter than the laser wavelength, and near-field light (not shown) is generated in the aperture 4 (including the periphery of the aperture).

The thickness of each layer in the optical disk 2 is as follows.
3, the thicknesses of the protective layer 14 and the recording layer 15 are several tens of nm.
Protective layer 14 located between mask layer 13 and recording layer 15
Is set to be shorter than the distance (reach distance) at which the near-field light generated in the aperture 4 formed on the mask layer 13 reaches the recording layer 115, and is several tens nm or less.

Next, a description will be given of a recording / reproducing apparatus as the reproducing apparatus of the present invention, which performs the information recording / reproducing operation on the optical disc 2 and which uses the optical recording medium reproducing method of the present invention.

The recording / reproducing apparatus has the configuration shown in FIG. That is, this recording / reproducing apparatus includes an optical pickup (light beam irradiation means) 21, a laser driving circuit (light beam irradiation means / control means) 22, a recording circuit 23, a reproduction circuit (reproduction means) 24, and a differentiation circuit (maximum value detection means). 25, and a rotation control circuit (rotation control means / control means) 26.

In this recording / reproducing apparatus, at the time of recording information, a recording signal output from the recording circuit 23 is sent to a semiconductor laser provided in the optical pickup 21 via a laser driving circuit 22, and a high-intensity laser for recording is recorded. Beam 1
Is output as The optical pickup 21 includes the objective lens 5 shown in FIG. 1, and focuses the laser beam 1 on the rotating optical disk 2 as a laser spot 1a by the objective lens 5. Thereby, the optical disk 2
Is recorded as a recording mark M on the recording layer 15.

In this recording / reproducing apparatus, the adjustment of the light quantity of the emitted light of the semiconductor laser provided in the optical pickup 21 is performed by a laser drive circuit 22, and the rotation of the optical disk 2 is adjusted by a rotation control circuit 26.

On the other hand, at the time of reproduction, the optical pickup 21 emits a reproduction laser beam 1 having a lower intensity than the semiconductor laser, and the laser beam 1 is rotated by the objective lens 5 as shown in FIG. The light is focused on the optical disk 2 as a laser spot 1a. Laser spot 1
is condensed, the mask layer 13 has an aperture 4
Is formed, and the near-field light generated by the aperture 4 is
The light is scattered by the interaction with the recording mark M on the recording layer 15 and becomes scattered light containing information on the recording mark M. The scattered light is composed of e transmitted through the aperture 4 and f transmitted through a transmission region other than the aperture 4. These scattered lights e · f
Is converted into an electric signal by a photodetector included in the optical pickup 21 to generate a reproduction signal a. The reproduction signal a is sent to the reproduction circuit 24 and the differentiation circuit 25, respectively, and the reproduction circuit 24 reproduces information recorded from the reproduction signal a.

On the other hand, the differentiating circuit 25 detects the maximum value of the signal amount of the reproduced signal a obtained at this time, generates a detection signal b, and outputs the detection signal b to the laser drive circuit 22 and the rotation control. The signal is fed back to the circuit 26. The laser drive circuit 22 and the rotation control circuit 26 control the light amount (intensity) of the semiconductor laser and the rotation speed of the optical disk 2 based on the detection signal b so that the signal amount of the reproduction signal a becomes a maximum value. In addition, any one of the light amount (intensity) of the semiconductor laser and the rotation speed of the optical disk 2 may be controlled based on the detection signal b so that the signal amount of the reproduction signal a becomes a maximum value.

As described above, based on the detection signal b fed back from the differentiating circuit 25, the laser drive circuit 22 and the rotation control circuit 26 adjust the light amount of the semiconductor laser so that the signal amount of the reproduced signal a becomes a maximum value. By controlling the rotation speed of the optical disc 2 and / or the SN ratio of the reproduction signal a is increased, and reproduction with a high SN ratio can be performed.

The reason why the SN ratio of the reproduced signal a can be increased together with the reproducing method used in the above-mentioned recording / reproducing apparatus will be described below with reference to FIGS. FIG.
FIG. 3 is a diagram showing a state when a laser beam 1 for reproduction is irradiated on the optical disc 2 via an objective lens 5 on the optical disc 2 and a temperature distribution of an irradiation area of a mask layer 13 of a laser spot 1a. The temperature distribution 8a is the temperature distribution of the irradiation area of the laser spot 1a on the mask layer 13 when the power of the laser beam 1 is low, and the temperature distribution 8b is the temperature distribution when the power is high. As described above, the temperature of the irradiation area depends on the power of the laser beam 1. In the drawing, a line indicated by 7 is a threshold temperature, and the refractive index of a high temperature portion exceeding the threshold temperature 7 changes to increase the transmittance, thereby forming an aperture. Therefore,
The size of the aperture is small when the power of the laser beam 1 is low, and is large when the power of the laser beam 1 is high.

At the time of reproduction, the aperture 4a of the mask layer 13
Interaction between the near-field light generated in (or 4b) and the recording mark M of the recording layer 15 causes scattering and generates scattered light. The generated scattered light is converted into an electric signal by the photodetector provided in the optical pickup 21 shown in FIG. 2 to generate a reproduction signal a to reproduce the recording mark M. The scattered light is transmitted to the aperture 4a. (Or 4
b) and scattered light f reproduced through other regions.

Usually, since the aperture 4a (or 4b) has a high transmittance, the scattered light e is more easily reproduced. However, the area of the aperture 4a (or 4b) is smaller than the area of the laser spot 1a other than the aperture 4a (or 4b). Therefore, the scattered light e reproduced from the aperture 4a (or 4b)
Needs to consider the product of the area of the aperture 4a (or 4b) and the transmittance of the aperture 4a (or 4b). Similarly, the total intensity of the scattered light f reproduced from the area other than the aperture 4a (or 4b) is also equal to the aperture 4a (or 4b).
It is proportional to the product of the spot area excluding b) and the transmittance of this portion.

In other words, from this, at the time of reproduction, by lowering the power of the laser beam 1 and controlling the area of the aperture as in the aperture 4a, the intensity of the scattered light e transmitted through the aperture and reproduced is reduced. Also, the intensity of the scattered light f transmitted through the area other than the aperture and reproduced is increased (in other words, the ratio of the scattered light f is made higher than the scattered light eNO ratio). By reproducing the recording mark M in this manner, a sufficient amount of scattered light including information on the recording mark M can be secured, and reproduction with a high SN ratio can be performed.

FIG. 4 shows a CNR (Carrier Noi).
FIG. 9 is a diagram illustrating a change in the intensity of scattered light using a measurement result of (se Ratio: proportional to the signal amount of a reproduced signal when the recording mark M is reproduced). (However, in practice, it is difficult to measure CNR with a drive device, so CN
A signal amount (amplitude and effective value of a reproduced signal) that can be actually measured by a drive device proportional to R is used. If the intensity of the laser beam 1 is higher than the intensity Pt (region d), the aperture increases, and the intensity of the scattered light e from inside the aperture becomes higher than the intensity of the other scattered light f. On the other hand, if the intensity of the laser beam 1 is lower than the intensity P (region c), the aperture becomes smaller, and conversely, the intensity of the other scattered light f becomes larger than the intensity of the scattered light e from inside the aperture. .

On the other hand, when the recording mark M is recorded, the area of the recording mark M occupying in the aperture becomes smaller as the intensity of the laser beam 1 increases, due to the relative relationship between the size of the recording mark M and the size of the aperture. Resolution decreases.

Since the above-mentioned CNR is proportional to the product of the intensity of the scattered light and the resolution, the CNR is maximized in the region c in FIG. 4 and gradually decreases as it moves to the region d. Therefore, by adjusting the power of the laser beam 1 so that the CNR is maximized (maximum value), that is, the amplitude and the effective value (proportional to CNR) of the reproduced signal are maximized, the size of the aperture can be reduced. Control can be performed such that the intensity of f is greater than the intensity of scattered light e. However, since the size of the aperture is determined by the temperature distribution as described above, not only the power of the laser beam 1 but also the rotation speed of the optical disk 2 is adjusted to adjust the relative linear velocity between the laser beam 1 and the optical disk 2. It can also be controlled by

[0039]

As described above, the method for reproducing an optical recording medium according to the present invention comprises a recording layer for recording optical information and a functional layer whose refractive index changes by light irradiation or heating and in which this change is reversible. By using an optical recording medium having: a light flux incident on the optical recording medium, a local refractive index change region is generated in the functional layer, and the near-field light generated in the refractive index change region and the recording layer The optical information of the recording layer is read from the scattered light scattered by the interaction and transmitted through a region other than the refractive index change region.

Thus, the amount of scattered light containing optical information of the recording layer can be increased without increasing the refractive index change area, so that the SN ratio of the reproduced signal can be increased,
This has the effect of making it easier to reproduce the recorded information.

Further, the reproducing method of the optical recording medium of the present invention comprises:
As described above, in the method for reproducing an optical recording medium according to the present invention, the refractive index is further controlled by controlling the light amount of the light beam irradiated on the optical recording medium or the relative linear velocity of the light beam irradiated on the optical recording medium. The intensity of the scattered light transmitted through the region other than the change region is set to be greater than the intensity of the scattered light transmitted through the refractive index change region.

As a result, the size of the refractive index change region is appropriately controlled, and the amount of scattered light transmitted through the region other than the refractive index change region contributing to reproduction is increased.
There is an effect that the SN ratio of the reproduction signal is increased to facilitate the reproduction of the recorded information.

Further, the reproducing method of the optical recording medium of the present invention comprises:
As described above, using an optical recording medium including a recording layer for recording optical information and a functional layer whose refractive index is changed by light irradiation or heating and in which this change is reversible, Injecting a light beam creates a local refractive index change region in the functional layer, and reads the optical information of the recording layer from the scattered light scattered by the interaction between the near-field light generated in the refractive index change region and the recording layer. In addition, when reading optical information, the light amount of the light beam irradiated on the optical recording medium or the relative linear velocity between the light recording medium and the light beam is controlled so that the signal amount of the reproduced signal obtained from the scattered light becomes a maximum value. Is what you do.

Thus, the size of the refractive index change region in the functional layer is adjusted so that the intensity of scattered light passing through the region other than the refractive index change region is greater than the intensity of scattered light passing through the refractive index change region. Since it is possible to perform appropriate control, the SN ratio of the reproduced signal is also increased in this case,
This has the effect that recorded information can be easily reproduced.

As described above, the reproducing apparatus for an optical recording medium according to the present invention comprises a recording layer for recording optical information and a functional layer whose refractive index changes upon irradiation or heating with light and in which this change is reversible. A light beam irradiating means for irradiating the light beam to the optical recording medium while receiving the reflected light, a rotation control means for controlling the rotation of the optical recording medium, and reading by the light beam irradiating means. A reproducing unit that reproduces optical information of the recording layer based on a reproduced signal obtained from the reflected light, a maximum value detecting unit that detects a maximum value of the reproduced signal, and a reproducing unit that reproduces the optical information based on a detection result obtained by the maximum value detecting unit. And a control unit that controls at least one of the light beam irradiation unit and the rotation control unit so that the signal has a maximum value.

As a result, at least one of the light beam irradiation means and the rotation control means is controlled so that the signal amount of the reproduction signal obtained from the scattered light becomes a maximum value.
The size of the refractive index change region in the functional layer is appropriately controlled so that the intensity of the scattered light passing through the region other than the refractive index change region is larger than the intensity of the scattered light passing through the refractive index change region. , By increasing the SN ratio of the reproduced signal,
This has the effect that recorded information can be easily reproduced.

[Brief description of the drawings]

FIG. 1 illustrates an embodiment of the present invention, and is an explanatory diagram illustrating a configuration of an optical disc on which recording and reproduction are performed, and a reproduction method.

FIG. 2 is an explanatory diagram showing a configuration of a recording / reproducing apparatus for reproducing the optical disc in FIG.

FIG. 3 is an explanatory diagram for describing a reproducing method used in the recording / reproducing apparatus in FIG. 2;

FIG. 4 is an explanatory diagram showing a relationship between laser light intensity for determining the size of an aperture and signal quality.

FIG. 5 is an explanatory diagram showing a configuration of a conventional optical disc and a reproducing method.

[Explanation of symbols]

 Reference Signs List 1 laser beam (light flux) 2 optical disk (optical recording medium) 4 aperture (refractive index change area) 5 objective lens 11 substrate 12 protective layer 13 mask layer (functional layer) 14 protective layer 15 recording layer 16 protective layer 21 optical pickup (light flux) Irradiation means) 22 Laser drive circuit (light beam irradiation means / control means) 24 Reproduction circuit (reproduction means) 25 Differentiation circuit (maximum value detection means) 26 Rotation control circuit (Rotation control means / control means)

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Takashi Nakano 1-1-4 Higashi, Tsukuba, Ibaraki Pref., National Institute of Advanced Industrial Science and Technology (72) Inventor Nobufumi Attada 1-1, Higashi, Tsukuba, Ibaraki 4 Research Institute of Industrial Science and Technology (72) Inventor Hiroshi Fuji 1-1-4 Higashi Tsukuba, Ibaraki Prefecture Research Institute of Industrial Science and Technology (72) Inventor Hiroyuki Katayama 22 Nagaike-cho, Abeno-ku, Osaka-shi, Osaka No. 22 Inside Sharp Corporation (72) Kenji Ota 22-22 Nagaikecho, Abeno-ku, Osaka-shi, Osaka F-term inside Sharp Corporation (reference) 5D090 AA01 BB04 BB17 CC04 DD05 EE15 FF11 HH03 LL02 LL05

Claims (4)

[Claims] 1. An optical recording medium comprising: a recording layer for recording optical information; and a functional layer whose refractive index changes by light irradiation or heating and in which the change is reversible, is used. When a light beam is incident, a local refractive index change region is generated in the functional layer, and near-field light generated in the refractive index change region is scattered light scattered by interaction with the recording layer. A method for reproducing an optical recording medium, comprising reading out optical information of the recording layer from scattered light transmitted through an area other than the rate change area. 2. The intensity of scattered light transmitted through an area other than the refractive index change area by controlling the amount of a light beam irradiated on the optical recording medium or the relative linear velocity of the light beam irradiated on the optical recording medium. 2. The reproducing method for an optical recording medium according to claim 1, wherein the intensity of the scattered light transmitted through the refractive index change region is made larger than the intensity of the scattered light. 3. An optical recording medium comprising: a recording layer for recording optical information; and a functional layer having a refractive index that changes upon irradiation or heating to change the refractive index, the change being reversible. A local refractive index change region is generated in the functional layer by injecting a light beam into the recording layer, and the near-field light generated in the refractive index change region and the scattered light scattered due to the interaction with the recording layer cause the recording layer to change. When reading the optical information, and when reading the optical information, so that the signal amount of the read signal obtained from the scattered light has a maximum value, the light amount of the light beam irradiating the optical recording medium, or the optical recording medium and A method for reproducing an optical recording medium, comprising controlling a linear velocity relative to a light beam. 4. An optical recording medium comprising: a recording layer for recording optical information; and a functional layer having a refractive index which is changed by irradiation or heating to change the refractive index, the change being reversible. A light beam irradiating means for irradiating the light beam while receiving the reflected light, a rotation control means for controlling the rotation of the optical recording medium, and a reproduction signal obtained from the reflected light read by the light beam irradiating means. A reproducing means for reproducing the optical information of the recording layer, a maximum value detecting means for detecting a maximum value of the reproduction signal, and a reproduction signal having a maximum value based on a detection result by the maximum value detecting means. And a control means for controlling at least one of the light beam irradiation means and the rotation control means.