KR100458727B1 - Optical recording media - Google Patents

Abstract

Disclosed is an optical recording medium having a grooved recording layer. The structure having a plurality of unrecorded tracks should allow the scanning device to derive the radial tracking error signal in accordance with the push-pull method. In addition, the structure having a plurality of recorded tracks should enable the scanning device to derive the radial tracking error signal in accordance with the high frequency phase detection method. To achieve this purpose, the depth of the grooves has a value in the range of 1/24 times to 1/7 times the wavelength for scanning the recording medium, and marks and areas on the track between the plurality of recorded tracks. The phase difference between the reflected radiation beams from these ranges from 0.4 to 2.0 radians.

Description

Optical record carrier

The present invention provides a method of recording and reading information using a radiation beam having a predetermined wavelength, comprising a recording layer, the recording layer changing between first and second states upon irradiation with a radiation beam, The information is represented by a plurality of marks recorded in a second state in an area having a first state, the plurality of marks being disposed in a plurality of tracks having guide grooves having a constant depth, and in the first state. A first optical phase difference exists when reflected from an area on a track and an area on a track in a second state, and the first optical phase difference is located between a plurality of tracks in the first state and the track in the first state. An optical record carrier configured to increase an optical retardation with an area of an image.

The information may be stored inside the recording medium by a scanning device having an optical head. The head focuses the radiation beam on the information layer inside the recording medium and follows the unrecorded track using tracking information derived from the grooves inside the track. When the medium has a disc shape, the groove has a circular or spiral shape, and the tracking information has a form of a radial tracking error signal. When a relatively high output radiation beam is modulated by a signal representing information to be recorded, the information is recorded inside the track in the form of a plurality of optically detectable marks. During the reading process, the radiation beam has a relatively low output and is modulated by a plurality of marks upon reflection from the information layer. In addition, the tracking information can be derived from the home or from the recorded information during the reading process.

An optical recording medium having a form defined at the beginning is known from Japanese Patent Application No. JP-A 5174380. Such a recording medium has a laminate comprising a plurality of optical thin film layers having a recording layer embedded therein. The thickness for the transparent layer of the stack adjacent to the recording layer is such that the track in the first state is the same as the area in which the first optical phase difference between the unrecorded area of the track and the recorded area is between the plurality of tracks in the first state. It is adjusted to increase the optical phase difference between the areas of the image. This relationship between the optical phase differences increases the information signal derived from the plurality of scanned marks. A disadvantage of such a conventional recording medium is that the scanning device cannot properly follow the plurality of tracks by using a so-called phase detection method for deriving a tracking signal from the plurality of marks recorded inside the information layer. A method of deriving tracking information using high frequency phase detection is especially known from US Pat. No. 4,785,441.

After all, it is an object of the present invention to provide an optical recording medium capable of deriving a tracking signal from a plurality of marks recorded by the above-described phase detection method and from a plurality of grooves.

In order to achieve this object, the recording medium according to the present invention has a value in which the depth of the guide groove is in a range of 1/24 times to 1/7 times the wavelength, and the first optical retardation is 0.4 to 2.0. It is characterized by having a value in radians. The phase detection method described above requires a relatively narrow groove. The minimum groove depth is set by the requirement for the injection device to derive tracking information from it. The combination of the groove depth and the first optical phase difference described above defines a parameter range in which the tracking signal can be appropriately derived in accordance with the phase detection method.

It is preferable that said 1st optical phase difference has a range of 0.4-1.1 radians. Medium having a phase difference smaller than this value shows an asymmetric tracking signal when derived by the phase detection method. This asymmetry appears as a tracking signal with different amplitudes when the radiation beam is focused up and down the recording layer. Possible measurements of the asymmetry described above are expressed as (xy) / (2z), where x is the maximum value of the phase detection tracking error signal when the radiation beam is focused on 1 μm above the information plane, and y is the radiation beam. The maximum value of the phase detection tracking error signal when condensed below 1 占 퐉 of the information plane, and z is the maximum value of the phase detection tracking error signal when condensed on the information plane of the radiation beam.

Further, when the ratio of the reflection intensity of the region on the track in the second state and the reflection intensity of the region on the track in the first state is greater than 0.15, the phase detection tracking signal can be further improved. Such a medium is called a dark-writing medium. The so-called white-writing medium is Preferably, the ratio between the reflection intensity of the region on the track in the first state and the reflection intensity of the region on the track in the second state has a value greater than 0.15. The symmetry of the tracking signal as derived by the phase detection method is improved when the above ratio is in the range of 0.3 to 0.5 for both the dark recording medium and the white recording medium.

In order to be able to derive an excellent information signal from the radiation beam reflected from the information layer, it is preferable that the reflection intensity of the region on the track in the first state with respect to the dark recording medium is larger than 0.15. In addition, for the white recording medium, it is preferable that the reflection intensity of the region in the second state is larger than 0.15.

A groove formed inside the information layer can be used to store information such as an address used to access the information. Such information may be stored in the form of wobble for the depth direction of the groove or in the form of the location of the groove. In this case, the depth of the groove preferably has a range of 1/12 to 1/7 times the wavelength of the radiation beam.

The optical phase difference of the medium can be realized by embedding a recording layer inside a laminate composed of a plurality of optical thin film layers and adjusting the thicknesses of the plurality of layers. At this time, when the material of the recording layer in the first state has an imaginary part with a refractive index larger than 3.4, the design of the laminate can be easily achieved.

In addition, the recording layer material is preferably made of a phase change form. In addition, the recording speed can be relatively increased when a plurality of amorphous marks are recorded inside the crystalline layer. In this case, the first state is a crystal state, and the second state is an amorphous state.

Hereinafter, this and other inventions of the present invention will become more apparent and more apparent from the examples given with reference to the following drawings.

In the drawing,

1 is a cross-sectional view of a recording medium according to the present invention;

2 is a plan view of a recording layer of the recording medium;

3 shows an injection apparatus for scanning a recording medium according to the present invention,

4A shows a circuit for an apparatus for forming a radial push-pull tracking error signal,

4B shows a circuit for an apparatus for forming a radial DTD tracking error signal.

1 shows an information recording medium 1 according to the invention, which is formed to record and read information using a focused radiation beam having a constant design wavelength. The recording medium 1 has a transparent substrate 2 and a recording layer 3. The recording layer can be scanned by the radiation beam through the substrate 2. The recording layer 3 is embedded in the stack 4 composed of a plurality of optical thin film layers disposed on the substrate. The laminate includes a transparent interference layer 5, a recording layer 3, another interference layer 6, and a reflective layer 7 in order from the substrate side. The laminate 4 is shielded from external influences by the protective layer 8.

The board | substrate 2 is provided with the groove pattern in the side in which the laminated body 4 is arrange | positioned. For disc shaped media, the groove pattern has a plurality of grooves formed in a circular or spiral shape. When viewed from the laminate side, the groove pattern portion constituting the depression inside the substrate is called a groove 9. In addition, the pattern part which comprises a raise part from the same viewpoint is called the land 10. FIG. Since the thicknesses of the plurality of layers in the stack 4 are too small, the pattern on the substrate 2 also exists in the recording layer 3 as well.

Example I

A substrate of a recording medium is manufactured using polycarbonate (PC) having a refractive index of 1.58 at a design wavelength of 670 nm. Interference layer 5 is a layer with a thickness of 90 nm consisting of 80% ZnS with a refractive index of 2.13 and 20% SiO ₂ . The recording layer 3 is a layer having a thickness of 30 nm made of a phase change material of GeSb ₂ Te ₄ having a refractive index of 4.26-1.69 in an amorphous state and a refractive index of 4.44-i 3.08 in a crystalline state. In addition, the interference layer 6 is a layer having a thickness of 30 nm made of the same material as the interference layer 5. The reflective layer 7 is a layer having a thickness of 100 nm made of an aluminum alloy having a refractive index of 1.98-7.81. The groove 9 has a depth of 40 nm, the groove width is 500 nm, and the groove pitch corresponding to the track pitch is 900 nm.

2 shows a part of the recording layer 3 having a plurality of grooves 9 and a plurality of lands 10. At this time, the information is recorded inside the home. The recording layer 3 initially has a crystal state. During the recording process, an amorphous region 11 called a mark is formed inside the recording layer. The lengths and positions of these plural marks represent information recorded in the medium. The reflection intensity of the laminate 4 in the region of the recording layer in the amorphous state has a value of 0.07. In addition, the reflection intensity of the laminate 4 in the region in the crystal state has a value of 0.18. Thus, the ratio of amorphous reflection to crystalline reflection is 0.39. Both reflection intensities are measured by using a reflected beam focused in a grooveless region.

The radiation beam reflected from the region with the crystalline state inside the track indicated by 'a' in FIG. 2 is delayed in phase by 1.2 radians compared to the radiation beam reflected from the region 'b' with the same crystalline state between the tracks. do. Further, the radiation beam reflected from the region having an amorphous state inside the track indicated by 'c' in FIG. 2 is delayed in phase by 0.6 radians compared to the radiation beam reflected from the region having the crystalline state inside the track. Thus, the phase difference between the land and the groove is increased by the phase difference between the plurality of marks and the area between these marks. In other words, the effective depth of the groove is increased at the position where the mark is placed.

The push-pull tracking error signal has a maximum measurement value corresponding to 90% of the value obtained for a medium having a groove depth optimized for the maximum push-pull signal. In addition, the phase detection tracking error signal measured by the scanning device described later has a maximum value of 0.24. The value of this tracking error signal corresponds to a time difference normalized to the channel clock period used to record the information on the recording medium.

Example II

The substrate of the recording medium is again manufactured using polycarbonate (PC) having a refractive index of 1.58 at a design wavelength of 670 nm. The laminate has layers in the same order as shown in FIG. 1. Interference layer 5 is a layer having a thickness of 95 nm consisting of 80% ZnS having a refractive index of 2.13 and 20% SiO ₂ . The recording layer 3 is a layer having a thickness of 25 nm made of a phase change material of GeSb ₂ Te ₄ having a refractive index of 4.26-1.69 in an amorphous state and a refractive index of 4.44-i 3.08 in a crystalline state. In addition, the interference layer 6 is a layer having a thickness of 35 nm made of the same material as the interference layer 5. The reflective layer 7 is a layer having a thickness of 100 nm made of an aluminum alloy having a refractive index of 1.98-7.81. The depth of the groove 9 is 55 nm, the width of the groove is 400 nm, and the groove pitch is 900 nm.

The information is recorded inside a plurality of grooves in the form of a plurality of amorphous marks inside the crystalline periphery. In the amorphous state, the reflection intensity of the laminate 4 in the region of the recording layer has a value of 0.05. In addition, the reflection intensity of the laminate 4 in the region in the crystal state has a value of 0.16. Thus, the ratio of amorphous reflection to crystalline reflection is 0.31. At this time, both of these regions are regions without grooves.

The radiation beam reflected from the region having the crystalline state inside the track indicated by 'a' in FIG. 2 is delayed in phase by 1.6 radians compared to the radiation beam reflected from the region having the same crystalline state between the tracks. Further, the radiation beam reflected from the region having an amorphous state inside the track indicated by 'c' in FIG. 2 is 0.7 radii compared to the radiation beam reflected from the region having a crystalline state inside the track indicated by 'b' in FIG. 2. The phase is delayed by some amount.

The push-pull tracking error signal has a maximum measurement value corresponding to 95% of the value obtained for a medium having a groove depth optimized for the maximum push-pull signal. In addition, the phase detection tracking error signal has a maximum value of 0.24.

Example III

The substrate of the recording medium is again manufactured using polycarbonate (PC) having a refractive index of 1.58 at a design wavelength of 670 nm. The laminate has layers in the same order as shown in FIG. 1. Interference layer 5 is a layer having a thickness of 70 nm consisting of 80% ZnS having a refractive index of 2.13 and 20% SiO ₂ . The recording layer 3 is a layer having a thickness of 25 nm made of a phase change material of GeSb ₂ Te ₄ having a refractive index of 4.40-i 1.96 when in an amorphous state and a refractive index of 4.65-i 3.81 when in a crystalline state. In addition, the interference layer 6 is a layer having a thickness of 25 nm made of the same material as the interference layer 5. The reflective layer 7 is a layer having a thickness of 100 nm made of aluminum having a refractive index of 1.98-7.81. The groove 9 has a depth of 51 nm, a groove width of 500 nm, and a groove pitch of 870 nm.

The information is recorded inside a plurality of grooves in the form of a plurality of amorphous marks inside the crystalline periphery. The reflection intensity of the laminate 4 in the region of the recording layer in an amorphous state has a value of 0.043. In addition, the reflection intensity of the laminate 4 in the region in the crystal state has a value of 0.17. Thus, the ratio of amorphous reflection to crystalline reflection is 0.25. At this time, both of these regions are regions without grooves.

The radiation beam reflected from the region having the crystalline state inside the track indicated by 'a' in FIG. 2 is delayed in phase by 1.5 radians compared to the radiation beam reflected from the region having the same crystalline state between the tracks. Also, the radiation beam reflected from the region having an amorphous state inside the track indicated by 'c' in FIG. 2 is delayed in phase by 0.8 radians compared to the radiation beam reflected from the region having the same crystalline state between the tracks. .

The push-pull tracking error signal has a maximum measurement value corresponding to 95% of the value obtained for a medium having a groove depth optimized for the maximum push-pull signal. In addition, the phase detection tracking error signal has a maximum value of 0.3.

Although the above three examples of the recording medium according to the present invention relate to a recording medium in which an amorphous mark is recorded in the crystalline periphery, the present invention is equally applicable to a recording medium in which a plurality of crystalline marks are recorded inside the amorphous mark. Can be applied. In addition, the present invention is not limited to a recording medium in which information is recorded in a plurality of grooves, and the same can be applied to a recording medium in which information is recorded on lands between the plurality of grooves. In addition, the laminate 4 may have various forms. That is, another reflective layer can be disposed between the substrate 2 and the interference layer 5 of the laminate 4 as shown in FIG. 1. Alternatively, another interference layer and a reflective layer can be inserted between the stack and the substrate. In addition, the stack may have only layers 3, 4 and 5, which stack is well suited for write-once media. In addition, as the material for the recording layer, a phase change material, dye or other material suitable for optically recording information therein may be used.

Injection device

3 shows an optical scanning device suitable for recording information on and reading information from the medium in accordance with the present invention. This figure shows a part of the recording medium 1 with information embossed in the form of a plurality of pits and bumps. The information layer is scanned through the substrate 2. In this case, the recording medium may include one or more information layers stacked on each other.

The device comprises a radiation source 12, for example a semiconductor laser, which emits a radiation beam 13. The radiation beam is condensed on the information layer 3 by the objective system 4, for the sake of simplicity, the objective system is represented by one lens. In addition, the radiation beam reflected by the information layer is directed to the detection device 15 via the beam splitter. In this case, the beam splitter may be a translucent plate, a diffraction grating may be used and may have a polarization dependency. The detection device converts the incident light into one or more electrical signals and supplies it to the electronic circuit 16 to derive an information signal S _i representing the information read from the recording medium and a plurality of control signals. One of the plurality of control signals is a radial tracking error signal S _r representing the distance between the center of the spot formed on the information plane by the radiation beam and the center line of the track being scanned. Another control signal is a focus error signal S _f representing the distance between the focus of the radiation beam and the information plane. These two error signals are supplied to the servo circuit 17 to control the focal position of the radiation beam. In the figure, focus control is realized by moving the objective system 14 in its optical axis direction in response to the focus error signal, while the objective system is moved in a direction crossing the track in response to the radial tracking signal. By moving, radial tracking is realized. In addition, during the recording process, the intensity of the radiation source is modulated by the information to be recorded.

4 shows the layout of the detector 15 and a portion of the associated electronic circuit 16 which derives the radial tracking error signal from the detector signal. 4A shows a circuit for deriving a radial tracking signal according to the push pull method. The detection device 15 has a quadrant detector having four radiation sensitive detection elements A, B, C, and D. The detection signals generated by the detection elements A and B are added and amplified by the amplifier 18. Similarly, the detection signals generated by the detection elements C and D are added and amplified by the amplifier 19. The outputs of the amplifiers 18 and 19 are connected to the differential amplifier 20 to produce the difference between the two input signals. Accordingly, the output signal of the differential amplifier 20 corresponds to the radial pull pull tracking error signal S _r (PP). This error signal is well suited for controlling the radial tracking servo in the portion of the recording medium having a plurality of tracks without a plurality of recorded marks.

4b shows a circuit for deriving a radial tracking signal according to a high frequency phase detection method. The detection signals generated by the elements A and C of the detection device 15 are added and amplified by the amplifier 21. The output of amplifier 21 is then fed to a slicer. The slicer detects the level intersection of the input signal and the detection level, and digitalizes the input signal. In addition, the detection signals of the elements B and D of the detection device 15 are added and amplified inside the amplifier 23, the output of which is connected to the input of the slicer 24. At this time, in order to compensate for the response effect of the optical system of the scanning device to the detection signal, the output signals of the amplifiers 21 and 23 may be shaped by an equalizer before being supplied to the slicers 22 and 24, respectively. The digital output signals of the slicers 22, 24 are fed to a phase comparator 25, which generates an output signal depending on the phase between a plurality of pulses present at the two inputs of the comparator. The output signal of this comparator 25 is low pass filtered by the filter 26. The output signal S _r of this filter 26 corresponds to a radial tracking error signal derived by a diagonal time-difference (DTD) method, which is one specific embodiment of the above-described phase detection method. This error signal is well suited for controlling the radial tracking servo in the portion of the recording medium having a plurality of recorded marks.

In addition, the plurality of recorded tracks on the recording medium according to the present invention is a method in which the method shown in FIG. 4B is modified in an analog manner, but in particular, a phase detection method known in US Pat. It can also be followed using a radial tracking error signal derived by other high frequency phase detection methods such as one method.

Claims (9)

Record and read information using a radiation beam having a predetermined wavelength, comprising a recording layer, the recording layer changing between first and second states upon irradiation with a radiation beam, the recorded information being first A plurality of marks recorded in a second state in an area having a state, wherein the plurality of marks are disposed in a plurality of tracks having guide grooves having a constant depth, the plurality of marks being located on the track in the first state; There is a first optical phase difference when reflected from an area on a track in a second state, the first optical phase difference being between an area located between a plurality of tracks in the first state and an area on the track in a first state. An optical record carrier configured to increase an optical retardation, And the depth of the guide groove is in a range of 1/24 times to 1/7 times the wavelength, and the first optical retardation has a value in the range of 0.4 to 2.0 radians. The method of claim 1, And the ratio of the reflection intensity of the region on the track in the second state to the reflection intensity of the region on the track in the first state is greater than 0.15. The method of claim 1, And the ratio of the reflection intensity of the area on the track in the first state to the reflection intensity of the area on the track in the second state is greater than 0.15. The method of claim 2, And the reflection intensity of the area on the track in the first state is greater than 0.15. The method of claim 3, wherein And the reflection intensity of the area on the track in the second state is greater than 0.15. The method of claim 1, And the depth of the guide groove has a range of 1/12 to 1/7 times the wavelength. The method of claim 1, And the recording layer comprises a material having an imaginary part having a refractive index of greater than 3.4 in the first state. The method of claim 1, And the recording layer comprises a phase change material. The method of claim 8, And the second state is an amorphous state.