JP2000504465A - Optical recording medium - Google Patents

Abstract

(57) Abstract An optical recording medium having a grooved layer is described. The structure of the unwritten track must allow the scanning device to derive a radial tracking error signal according to the push-pull method. The structure of the written track must allow the scanning device to derive a radial tracking error signal according to a high frequency phase detection method. For this purpose, the optical depth of the groove is in the range of 1/24 to 1/7 times the wavelength scanning the recording medium and is reflected from the area on the track between the written marks and from the marks. The phase difference between the radiation beams is in the range of 0.4 to 2.0 radians.

Description

DETAILED DESCRIPTION OF THE INVENTION                         Optical recording medium   The present invention writes information with a radiation beam having a predetermined wavelength And an optical recording medium for reading, comprising a recording layer, The layer changes between the first and second states upon emission by the radiation beam and is recorded. The information that has been written by the mark written in the second state in the area in the first state The mark is located in a track comprising a guide groove having a depth. And the first optical phase difference is shifted from the area on the track in the first state and into the second state. And the first optical phase difference is in the first state. Optical position between the area between the tracks in the track and the area on the track in the first state Increase the phase difference.   Information can be stored in the recording medium by a scanning device having an optical head. That f A beam focuses the radiation beam onto the information layer in the medium, and a groove in the track. Follows tracks that are not written with tracking information derived from I do. If the medium is disc-shaped, the grooves may be round or spiral. Yes, and the tracking information is in the form of radial tracking errors. Relatively high The output radiation beam is modulated by a signal representing the information to be written In some cases, that information is written in the track in the form of optically detectable marks. You. During reading, the radiation beam has a relatively low power, which reflects from the information layer At this time, the signal is modulated by the mark. The tracking information during reading is the groove Or from written information.   An optical recording medium according to the preamble is known from JP-A-5-174380. This medium Comprises a stack of optical thin layers with a recording layer embedded therein. Product adjacent to recording layer The thickness of the transparent layer is determined by the difference between the unwritten area of the track and the written area. The first optical phase difference between the track in the first state and the first state Is adjusted to increase the optical phase difference between the region on the track in the state. This relationship between the phase differences increases the information signal derived from the scanned mark. The drawback of this known recording medium is that the tracks are tracked from marks written in the information layer. The scanning device uses a so-called phase detection method to extract the racking signal. Cannot be tracked accurately. By using high-frequency phase detection, A method for deriving King information is known, inter alia, from U.S. Pat. Have been.   This allows tracking information to be obtained from marks written according to the phase detection method. SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical recording medium, which can be pulled out of a groove, and also It is.   The purpose of this is to make sure that the recording medium according to the preamble has an optical depth of the guide groove of 1/24 of the wavelength Within a range of 1/7 and the first optical phase difference is within a range of 0.4 to 2.0 radians. Achieved when characterized by the following. Phase detection requires relatively shallow grooves . The minimum groove depth should allow the scanning device to derive tracking information from it Set by the request that it must. Combination of groove depth and first optical phase difference Parameters that allow the tracking information to be accurately derived according to the phase detection method Define the area.   The first optical phase difference is preferably in the range of 0.4 to 1.1 radians. Less than this value A medium having a small phase difference may be an asymmetrical track as derived by the phase detection method. Will show a locking signal. When the radiation beam is focused below and above the recording layer In addition, the asymmetric is noticeable as a different amplitude of the tracking signal. Asymmetric possible The measure is (xy) / (2z), where x is the radiation beam The maximum value of the phase detection tracking error signal when focused on μm, and y is Phase detection tracking error when the radiation beam is focused 1 μm below the information plane -The maximum value of the signal and z is the value when the radiation beam is focused on the information plane This is the maximum value of the phase detection tracking error signal.   Another improvement in the phase detection tracking signal is that the area on the track in the second state is The ratio of the intensity reflection of the area on the track in the first state to the intensity reflection of the first state is less than 0.15. This can be achieved when large. Such a medium is called a dark writing medium. So-called The lightly written medium preferably has an intensity reflection of the area on the track in the first state and a second state. Has a ratio greater than 0.15 with the intensity reflection of the area on the track at. Phase detection The symmetry of the tracking signal as derived by It is improved when it is within the range of 0.3 to 0.5 for both the light-write medium and the light-write medium.   The intensity reflection of the area on the track in the first state is preferably reflected from the information layer. To extract good information signals from the applied radiation, On the other hand, it is larger than 0.15. For lightly written media, on the track in the second state Is preferably greater than 0.15.   Grooves in the information layer, such as addresses used in accessing information Can be used to store information. Such information is available at the depth or position of the groove. It can be stored in the form of shaking. The optical depth of the groove is then preferably adjusted to the wavelength of the radiation beam. It is in the range of 1/12 to 1/7 times.   The optical retardation of this medium embeds the recording layer within the stack of optical thin layers and It can be realized by adjusting the thickness. The design of the stack is in the first state This is facilitated if the material of the recording layer has an imaginary part with a refractive index greater than 3.4.   The material of the recording layer is preferably of the phase-change type. The amorphous mark When written in a crystal layer, the writing speed can be relatively high. Then the first state The state is a crystalline state and the second state is an amorphous state.   These aspects of the present invention will become apparent from the examples described below, and Other aspects of the disclosure will be elucidated with reference to the embodiments described hereinafter.   In the figure,   FIG. 1 shows a sectional view of a recording medium according to the present invention,   FIG. 2 shows a plan view of the recording layer of the medium,   FIG. 3 shows a scanning device for scanning a medium according to the invention,   FIG. 4A shows a circuit diagram for generating a push-pull radial tracking error signal. Showing the road and   FIG. 4B shows an apparatus for forming a DTD (diagonal time difference) radial tracking error signal. FIG.   FIG. 1 writes and writes information with a focused radiation beam having a design wavelength. 1 shows an information recording medium 1 according to the invention designed for reading. Medium 1 It has a transparent substrate 2 and a recording layer 3. The recording layer is a radiation beam passing through the substrate 2. Can be scanned. The recording layer 3 is embedded in a laminate 4 of optical thin layers disposed on the substrate 2. It is embedded. The lamination includes a transparent interference layer 5, a recording layer 3, and another interference layer 6 from the substrate side. , And a reflective layer 7. The laminate 4 is shielded from environmental influences by the protective layer 8 ing.   The substrate 2 has a groove pattern on the surface on which the stack 4 is arranged. Disk shape For media, the groove pattern has circular or spiral grooves. On the side of the stack The portion of the groove pattern that forms the concave portion in the substrate when viewed from above is called a groove 9. You. The part of the pattern that forms the raised part from the same point of view is called land 10. Have been broken. The thickness of the layer in the laminate 4 is such that the pattern on the substrate 2 exists in the recording layer 3 as well. Small enough. Example I   The substrate of the recording medium is a polycarbonate with a refractive index of 1.58 at the design wavelength of 670 nm. Made of Nate (PC). The interference layer 5 is made of 80% ZnS having a refractive index of 2.13 and 20% Si0_TwoAnd a 90 nm thick layer. The recording layer 3 is 4.26 in the amorphous state. GeSb with a refractive index of i1.69 and 4.44-i3.08 when in the crystalline state_TwoTe_Four 30 nm thick layer of phase change material. The interference layer 6 is made of the same material as the interference layer 5 at 30 nm. It is a layer of thickness. The reflection layer 7 is made of an aluminum alloy having a refractive index of 1.98-i7.81. It is a 100 nm thick layer. The mechanical depth of the groove 9 is 40 nm, the width of the groove is 500 nm, and The pitch of the groove, which is one track pitch, is 900 nm.   FIG. 2 shows a part of the recording layer 3 having the grooves 9 and the lands 10. Information is in the groove Written. The recording layer 3 is initially in a crystalline state. Called mark during writing An amorphous region 11 is created in the recording layer. The length and position of the mark Expresses information recorded in the medium. Its recording layer in the amorphous state The intensity reflection of the stack 4 in the region of is equal to 0.07. Stack 4 in region in crystalline state Has an intensity reflection equal to 0.18. The ratio of amorphous to crystalline reflection is thus 0.39. Both intensity reflections result in a focused radiation beam in the non-grooved area. Therefore it was measured.   The region in the track and in the crystalline state, indicated by "a" in FIG. Radiation reflected from the region "b" between tracks and also in the crystalline state Is advanced in phase by 1.2 radians compared to the radiation reflected from. Figure In the track and in the amorphous state, indicated by "c" in FIG. Radiation reflected from the region is reflected from the region on the track and in the crystalline state Is advanced in phase by 0.6 radians compared to the applied radiation. Therefore, The phase difference between the mark and the groove is determined by the phase difference between the mark and the area between the marks. Be strengthened. In other words, the effective depth of the groove is enhanced at the location of the mark.   Push-pull tracking error signal is best for maximum push-pull signal Has a measured maximum of 90% of the value obtained for media with a defined groove depth You. The phase detection tracking error signal is measured by the scanning device described below. Has a maximum value of 0.24. The value of this tracking error signal is When normalized on the channel clock period used to write information on It is a difference. Example II   The substrate of this recording medium again has a refractive index of 1.58 at a design wavelength of 670 nm. Made from carbonate (PC). The lamination consists of layers in the same order as shown in FIG. Have. The interference layer 5 is made of 80% ZnS and 20% Si0 having a refractive index of 2.13._Two95nm thick layer with It is. The recording layer 3 is 4.26-i1.69 when in the amorphous state, and is crystalline. GeSb with refractive index of 4.44-i3.08 when in the solid state_TwoTe_Four25 of phase change materials nm thick layer. The interference layer 6 is the same material as the interference layer 5 and has a thickness of 35 nm. Reflection Layer 7 is a 100 nm thick layer of an aluminum alloy having a refractive index of 1.98-i7.81 . The mechanical depth of the groove 9 is 55 nm, the width of the groove is 400 nm, and the pitch of the groove is 9 nm. 00 nm.   Information is written in the grooves in the crystalline environment in the form of amorphous marks. Amo The intensity reflection of the stack 4 in the area of the recording layer in the rufus state is equal to 0.05. crystal The intensity reflection of the stack 4 in the region in the state is equal to 0.16. Amorph to crystal reflection The ratio of the negative reflection is thus 0.31. Both regions are grooveless.   Region in track and in crystalline state, reflected from "a" in FIG. Radiation is reflected by radiation reflected from regions between tracks and also in the crystalline state. By comparison, the phase is advanced by 1.6 radians. In-track and amorphous The radiation reflected from the area in the state, "c" in FIG. Region in one crystalline state, compared to the radiation reflected from "a" in FIG. The phase is advanced by 0.7 radians.   Push-pull tracking error signal is best for maximum push-pull signal With a measured maximum of 95% of the value obtained for media with a reduced groove depth. are doing. The phase detection tracking error signal has a maximum value of 0.24. Example III   The substrate of the recording medium again has a refractive index of 1.58 at a design wavelength of 670 nm. -Made of Carbonate (PC). The stacking has the same order as the layers shown in FIG. I have. The interference layer 5 is made of 80% ZnS and 20% Si0 having a refractive index of 2.13._TwoWith a 70nm thick layer with is there. The recording layer 3 is 4.40-i1.96 when in the amorphous state, and in the crystalline state GeSb with refractive index 4.65-i3.81_TwoTe_Four25nm of phase change material It is a layer of thickness. The interference layer 6 is a layer of the same material as the interference layer 5 having a thickness of 25 nm. Reflective layer 7 is a 100 nm thick layer of an aluminum alloy having a refractive index of 1.98-i7.81. The mechanical depth of the groove 9 is 51 nm, the width of the groove is 500 nm and the pitch of the groove is 870. nm.   Information is written in the grooves in the crystalline environment in the form of amorphous marks. Amo The intensity reflection of the laminate 4 in the area of the recording layer in the rufus state is equal to 0.43. Conclusion The intensity reflection of the stack 4 in the region in the crystalline state is equal to 0.17. Amole for crystal reflection The ratio of the fass reflection is thus 0.25. Both regions are grooveless.   Region in track and in crystalline state, reflected from "a" in FIG. Radiation is reflected by radiation reflected from regions between tracks and also in the crystalline state. In comparison, the phase is advanced by 1.5 radians. In-track and amorphous The radiation reflected from the area in the state, "c" in FIG. 0.8 radians phase compared to radiation reflected from a region in one crystalline state Proceed with.   Push-pull tracking error signal is best for maximum push-pull signal With a measured maximum of 95% of the value obtained for media with a reduced groove depth. I do. The phase detection tracking error signal has a maximum value of 0.3.   The above three examples of the recording medium according to the present invention show that the amorphous mark is in a crystalline environment. Although the present invention is related to the medium to be written, It can be applied equally well to media written in the environment. The present invention The present invention is not limited to a recording medium written in a groove, and the present invention writes information on a land in a groove. It can also be applied to media to be imported. The laminate 4 can have various shapes. Another anti The radiation layer may be arranged between the substrate 2 and the interference layer 5 of the laminate 4 as shown in FIG. No. Alternatively, another interference layer and a reflective layer may be interposed between the stack and the substrate. No. The stack may comprise only layers 5, 3 and 6, the stack being write-once. Very suitable for media. The material of the recording layer may be a phase change material, a dye or It may be a material suitable for optically writing any other information. Scanning device   FIG. 3 shows an optical scan suitable for writing and reading information from a medium according to the invention. The device is shown. This figure has information embossed in the form of depressions and protrusions. 1 shows a part of a record carrier 1. The information layer is scanned through the substrate 2. That The record carrier may comprise more than one information layer arranged one above the other.   The device comprises a radiation source 12 for emitting a radiation beam 13, for example a semiconductor laser. I have it. The radiation beam is shown in the figure as a single lens for simplicity. Is focused on the information layer (recording layer) 3 by the objective mirror system 14. That information The radiation reflected by the report layer is directed to the detector 15 via the beam splitter. It is. The beam splitter may be a translucent plate, a diffraction grating and is polarization dependent. You may. A detector converts the incident radiation into one or more electrical signals, An information signal S whose signal represents the information to be read from the record carrier_i And control signals The signal is supplied to an electronic circuit 16 for extracting the signal. One of its control signals is radiation Tracking error signal S_r Is formed by a radiation beam on the information surface. It represents the distance between the center of a point and the center line of the track being scanned. Also Another control signal is a focus error signal S_f Between the focal point of the radiation beam and the information surface. Expresses the distance between them. These two error signals are supplied to the servo circuit 17 , The circuit controls the position of the focal point of the radiation beam. In the figure, the focus control is This is achieved by moving the objective system 14 in the direction of the optical axis in response to the focus error signal. Present Whereas radial tracking responds to radial tracking errors This is achieved by moving the objective system across the track. Writing The intensity of the radiation source is modulated by the information to be recorded.   FIG. 4 shows the layout of the detection device 15 and the radial tracking error signal from the detection signal. And a part of an associated electronic circuit 16 for extracting the signal. Figure 4A is push Shows a circuit for deriving a radial tracking error signal according to the pull method You. The detector 15 is a quadrant detector having four radiation sensitive detection elements A, B, C and D. It has a dispatcher. The detection signals from detection elements A and B are applied and applied to amplifier 18. Is amplified. Similarly, detection signals from detection elements C and D are added and increased. It is amplified by the width unit 19. The output terminals of amplifiers 18 and 19 provide the difference between the two input signals. Connected to the differential amplifier 20 to be formed. The output signal of the differential amplifier 20 is Radial tracking error signal S_r(PP). This error signal is written Tracking servo within a portion of a recording medium with unmarked tracks Very suitable for controlling.   FIG.4B shows a circuit for extracting a radial error signal according to the high-frequency phase detection method. are doing. Detection signals from elements A and C of detection device 15 are applied and Is amplified. The output of the amplifier 21 is supplied to the slicer 22. That slicer Detects the level crossing of the input signal with the detection level, and counts the input signal accordingly. Become The detection signals of the elements B and D of the detection device 15 are added, and the output terminal is It is amplified in the amplifier 23 connected to the input terminal of the Ether 24. Amplifier 21 Before the output signals of the first and second slicers are fed to slicers 22 and 24, respectively. By an equalizer to compensate for the consequences of the response of the optical system of the scanning device to the It may be shaped. Digital output signal of slicers 22 and 24 goes to phase comparator 25 Supplied, the phase comparator determines the phase between the pulses at the two input terminals of the comparator. To produce an output signal. The output signal of the comparator 25 is low-passed by the filter 26. It is over-filtered. Output signal S of filter 26_r Is the diagonal time-d radial tracking error signal derived according to the This is a specific embodiment of the phase detection method. This error signal indicates the written mark To control the radial tracking servo in the part of the recording medium Always suitable.   Tracks written on a recording medium according to the invention are also shown in FIG. Analog variant of, or, inter alia, known from U.S. Pat. Comply with other high frequency phase detection methods, such as analog or digital variants of the phase detection method. It can be tracked using the radial tracking error signal derived as described above.

Claims (1)

[Claims] 1. Write and read information with a radiation beam having a predetermined wavelength   Optical recording medium for recording, comprising a recording layer, wherein the recording layer is   Changes between the first and second states upon radiation by the   Represented by the mark written in the second state in the area in the first state   The mark is located in a track with a guide groove having a depth,   1 optical phase difference from the area on the track in the first state and in the second state   Exists on the reflection from the area on the track, and the first optical phase difference is in the first state.   Optical position between the area within the track and the area on the track in the first state   In an optical recording medium that enhances the phase difference,     The optical depth of the guide groove is in the range of 1/24 to 1/7 times the wavelength, and the first light   Optical recording medium characterized in that the chemical phase difference is in the range of 0.4 to 2.0 radians . 2. 2. The optical recording medium according to claim 1, wherein the area on the track in the second state.   Ratio of the intensity reflection of the area on the track in the first state to the intensity reflection of 0.15   An optical recording medium characterized in that it is also large. 3. 2. The optical recording medium according to claim 1, wherein the area on the track in the first state.   Ratio of the intensity reflection of the area on the track in the second state to the intensity reflection of 0.12 is greater than 0.15   An optical recording medium characterized in that it is also large. 4. The optical recording medium according to claim 2, wherein the area on the track in the first state.   An optical recording medium characterized by having an intensity reflection of greater than 0.15. 5. 4. The optical recording medium according to claim 3, wherein the area on the track in the second state.   An optical recording medium characterized by having an intensity reflection of greater than 0.15. 6. 2. The optical recording medium according to claim 1, wherein the optical depth of the guide groove is 1/12 of the wavelength.   An optical recording medium characterized by being within a range of up to 1/7 times. 7. 2. The optical recording medium according to claim 1, wherein the recording layer is in a first state.   Optics comprising a material having an imaginary part with a refractive index greater than   recoding media. 8. 2. The optical recording medium according to claim 1, wherein said recording layer comprises a phase change material.   An optical recording medium, comprising: 9. 9. The optical recording medium according to claim 8, wherein the second state is amorphous.   An optical recording medium characterized by the above-mentioned.