Optical pickup system, optical head, optical disk apparatus, antireflection coating, optical pickup components, and manufacturing method for antireflection coating
An optical pickup system for reading information of three kinds of optical recording media. The optical pickup system has a wavelength selective filter that includes an outer area for shielding one light beam of light beams having three kinds of wavelengths and an inner area for allowing all the light beams to pass through. The optical pickup system also has an objective lens that focuses each light beam having passed through the wavelength selective filter on each light recording medium. An optical head and an optical disk apparatus have the optical pickup system.
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1. Field of the Invention
The present invention relates to an optical pickup system, an optical head, an optical disk apparatus, an antireflection coating for optical pickup application, optical components for optical pickup application, and a method for manufacturing an antireflection coating.
2. Description of Related Art
Conventionally, a compatible optical disk apparatus capable of reproducing different types of optical disks such as compact disks (CDs) and digital versatile disks (DVDs) has been proposed. The CD and DVD (which is hereinafter collectively called the optical disk) both have a transparent substrate whose one side is an information recording surface. The optical disk is composed of a combination of two transparent substrates adhered together with their information recording surfaces facing each other, or a combination of the information recording surface and a transparent protection substrate adhered together with the information recording surface facing the protection substrate.
To reproduce information signals stored in the optical disk, the optical disk apparatus focuses a laser beam from a light source on the information recording surface of the optical disk through the transparent substrate. As detailed later, the wavelength of the laser beam differs between CD and DVD. The optical disk apparatus normally uses an objective lens for focusing the laser beam. In some cases, the thickness of the transparent substrate having the information recording surface differs according to the type of the optical disk or a difference in laser beam wavelength. For example, while the transparent substrate of a CD may be 1.2 mm in thickness, that of a DVD may be 0.6 mm.
For the optical disk apparatus to reproduce optical disks of different types, it is required to focus the laser beam on the information recording surface despite that the thickness of the transparent substrate varies by the type of the optical disk. Besides, a new optical disk apparatus that uses a blue laser of approximately 400 nm wavelength to reproduce information is recently proposed. Therefore, there is a need for the optical disk apparatus to be compatible with the new optical disk in addition to CD and existing DVD.
To meet this need, an optical disk apparatus may have objective lenses for different types of optical disks in a pickup so that the objective lenses are changed in accordance with the type of the optical disk in use. Alternatively, it may have pickups for different types of optical disks so that the pickups are changed in accordance with the type of the optical disk in use. However, in terms of cost and size reduction, it is preferred to use the same objective lens for any type of optical disk.
An example of the objective lens is disclosed in Japanese Unexamined Patent Publication No. 09-145995. This objective lens has a lens surface that is radially sectioned into three or more loop zones. Every other loop zonal lens surfaces and the other every other loop zonal lens surfaces have a different refractive power. The every other loop zonal lens surfaces focus a laser beam on the information recording surface of the optical disk (DVD) having a thin transparent substrate (0.6 mm). The other every other zonal lens surfaces focus the laser beam having the same wavelength, for example, on the information recording surface of the optical disk (CD) having a thick transparent substrate (1.2 mm).
Another example disclosed in Japanese Unexamined Patent Publication No. 2000-81566 (U.S. Pat. No. 6,118,594). It discloses an optical disk apparatus that uses a laser beam having a short wavelength (635 nm or 650 nm) for a DVD with a thinner transparent substrate and uses a laser beam having a long wavelength (780 nm) for a CD with a thicker transparent substrate.
This optical disk apparatus has an objective lens used in common for these laser beams. The objective lens has a diffractive lens structure with a plurality of minute loop zonal steps thickly formed on one side of a refractive lens having a positive refractive power. The diffractive lens structure is designed so as to focus diffracted light of a laser beam having a short wavelength on the information recording surface of a DVD with a thinner transparent substrate, and focus diffracted light of a laser beam having a long wavelength on the information recording surface of a CD with a thicker transparent substrate. Further, it is designed so as to focus the diffracted light having the same diffractive order on the information recording surface. A laser beam with a short wavelength is used for DVD because the recording density of the DVD is higher than that of the CD, thus requiring a small beam spot. As well known, the diameter of an optical spot is proportional to a wavelength and inversely proportional to a numerical aperture (NA).
The above optical disk apparatus allows use of a common objective lens for both DVD and CD. It eliminates the need for replacing components such as an objective lens for each use of DVD and CD. This is effective in reducing costs and simplifying the structure.
Further, Blu-ray disk and High Definition DVD (HD DVD) are appeared as optical recording media in the next of CD and DVD, and optical pickup apparatus that are compatible with the three optical recording media are under development. The optical pickup apparatus is required to transmit the output of a laser light source to a disk of a recording medium at high efficiency. An important point of development to meet this requirement is an antireflection coating that is formed on an optical component such as an objective lens included in the apparatus.
The wavelength of light used in CD is approximately 790 nm, the wavelength of light used in DVD is approximately 655 nm, and the wavelength of light used in Blu-ray disk and HD DVD is approximately 405 nm. Thus, an objective lens placed in the optical pickup apparatus preferably has an antireflection coating that has the optical property that a reflectance is low in the vicinity of these three wavelengths. As an antireflection coating compatible with a plurality of wavelengths an antireflection coating that is compatible with the wavelengths used in DVD and Blu-ray disk is disclosed in Japanese Unexamined Patent Publication No. 2005-38581.
However, since the technique disclosed in Japanese Unexamined Patent Publication No. 09-145995 uses different loop zonal lens surface of the objective lens for DVD and CD, a large area remains ineffective for an incident laser beam, which extremely lowers light use efficiency.
Further, since the technique disclosed in Japanese Unexamined Patent Publication No. 2000-81566 uses the diffracted light by the diffractive lens structure, it is impossible that the diffractive efficiencies for different wavelengths reach 100% at the same time. This diffractive lens is designed so that the diffractive efficiency reaches 100% at an intermediate wavelength between the laser beam with a short wavelength (635 nm or 650 nm) used in DVD and the laser beam with a long wavelength (780 nm) used in CD, thereby making the diffractive efficiency well balanced for the laser beams in use.
Besides, this technique requires minute steps to be formed on the lens surface to create the diffraction lens structure, which is vulnerable to processing error. If the diffractive structure is not formed as designed, it causes a decrease in diffractive efficiently. When the diffractive efficiency decreases or it does not reach 100%, it means incapability of focusing entire incident light on the information recording surface of the transparent substrate in the optical disk, which results in light loss.
Further, Blu-ray format that uses a blue laser having a still shorter wavelength is proposed recently. Backward compatibility is also required for this case. In this case, a wavelength difference is larger than that between DVD and CD, and a difference in the refractive index of a lens is also large. Therefore, in the conventional techniques described above, it is even more difficult to obtain a suitable wavefront aberration in any medium.
The antireflection coating described in Japanese Unexamined Patent Publication No. 2005-38581 defines light transmittance by focusing on two kinds of wavelengths: the wavelength of light used in DVD and the wavelength of light used in Blu-ray disk. In this case, it is possible to form an antireflection coating with low reflectance in the wavelength region of the light used in DVD and Blu-ray disk. However, since the reflectance in the wavelength region of the light used in CD becomes higher than that before formation of the antireflection coating in this example disclosed therein, defect can occur when a CD is used as a recording medium.
For example, when writing information to CD by raising the magnification of a writing speed, use of an antireflection coating that has high reflectance in the wavelength region of the light used in CD is likely to cause a writing error. The magnification of the writing speed of a CD-R drive is increased to as high as 52, and writing at a high magnification is expected.
Further, the technique of Japanese Unexamined Patent Publication No. 2005-38581 expects the use of three or more layers of antireflection coating as well. Since a time to form an antireflection coating in a manufacturing process is proportional to the number of layers of the antireflection coating, the number of antireflection coating is preferably small. When forming a film with low reflectance in two or more kinds of wavelength regions, two layers of antireflection coating called V-coat having V-shaped spectral reflection characteristics can be used if the two kinds of expected wavelength regions are relatively close to each other. However, since the wavelength region of the light used in Blu-ray disk and the wavelength region of the light used in DVD and CD are not close to each other, it is impossible to achieve a purpose with the V-coat.
The antireflection coating is normally placed in the objective lens surface in the optical pickup apparatus. The objective lens is generally made of plastic material fir its high optical performance and low costs. Though the lens made of plastic material is weak against heat, the antireflection coating is formed by vapor deposition or sputtering, and a temperature on the formation surface thereby increases. Since a film formation time is proportional to the number of layers of the antireflection coating, it is preferred that the number of antireflection coating is smaller also in terms of shortening a formation time to reduce effects such as heat deformation on the formation surface.
SUMMARY OF THE INVENTIONThe present invention has been accomplished to solve the above problems and an object of the present invention is thus to provide an optical pickup system, an optical head, and an optical disk apparatus that can focus an optical beam on an information recording surface of each of a plurality of kinds of optical recording media using different wavelength with possibly lowest wavefront aberration and at high light use efficiency. Particularly, a first object of the invention is to provide an optical pickup system that is most suitable for three kinds of optical information recording media.
A second object of the invention is to provide a two-layer antireflection coating achieving low reflectance in three kinds of wavelength regions and an optical pickup component.
According to one aspect of the invention, there is provided an objective lens receiving light beams with different wavelengths λn (n≧3) for at least three kinds of optical recording media and having a positive power to focus each light beam on an information recording surface of a transparent substrate of each optical recording medium by refraction, wherein, if distances between points Pn (n≧3) where incident light beams or extension lines of incident light beams with wavelengths λn (n≧3) to the objective lens crosses an optical axis and a point Q where a lens surface of the objective lens located farther from each optical recording medium than another lens surface crosses the optical axis is expressed by Sn (n≧3), and a sign of the distance Sn is defined as positive if a position of the point Pn is located in a different side from the optical recording medium with respect to the point Q, and defined as negative if the position of the point Pn is located in the same side as the optical recording medium with respect to the point Q, an incident light beam satisfying following expressions enters the objective lens:
λ1<λ3 and (1/S1)<(1/S3) Expression 1:
λ2<λ3(λ2>λ1) and (1/S2)<(1/S3), and Expression 2:
each light beam is focused on the information recording surface with RMS wavefront aberration of 0.035 λRMS or below.
In this objective lens, at least one lens surface is preferably radially sectioned into a plurality of zones. It is also preferred that an optical path length of a light beam passing through each zone of the objective lens is different from an optical path length passing through another zone by substantially 2 mλ (m is an integral number) for a light beam selected from light beams consisting of a first light beam, a second light beam, and a third light beam, and by substantially mλ (m is an integral number) for a rest of the light beams. Particularly, the wavelength with a difference of substantially 2 mλ is preferably λ1. In a preferred embodiment, the wavelength λ1 is approximately 405 nm, the wavelength λ2 is approximately 655 nm, and the wavelength λ3 is approximately 790 nm. Particularly, S1 and S3 preferably respectively satisfy expressions: S1<0, S3>0
According to another aspect of the invention, there is provided an optical pickup system receiving a first light beam with a wavelength λ1 corresponding to a first optical recording medium, a second light beam with a wavelength λ2 corresponding to a second optical recording medium, and a third light beam with a wavelength λ3 corresponding to a third optical recording medium, having an objective lens that focuses the first light beam on the first optical recording medium, the second light beam on the second optical recording medium, and the third light beam on the third optical recording medium, and being capable of reading information recorded in the first optical recording medium, the second optical recording medium, and the third optical recording medium, wherein the objective lens has a positive power to focus each light beam on an information recording surface of a transparent substrate of each optical recording medium by refraction, and if distances between points P1, P2, P3 where incident light beams or extension lines of incident light beams with wavelengths λ1, λ2, λ3 to the objective lens cross an optical axis and a point Q where a lens surface of the objective lens located farther from each optical recording medium than another lens surface crosses the optical axis are expressed as S1, S2, S3, and signs of the distances S1, S2, S3, are defined as positive if positions of the points P1, P2, P3 are located in a different side from the optical recording medium with respect to the point Q, and defined as negative if the positions of the points P1, P2, P3 are located in the same side as the optical recording medium with respect to the point Q, following expressions are satisfied.:
λ1<λ3 and (1/S1)<(1/S3); Expression 1:
λ2<λ3(λ2>λ1l) and (1/S2)<(1/S3). Expression 2:
Each of the first, the second and the third light beams is preferably focused on each information recording surface with RMS wavefront aberration of 0.035 λRMS or below. It is preferred in the objective lens that at least one lens surface of the objective lens is radially sectioned into a plurality of zones, and an optical path length of a light beam passing through each zone is different from an optical path length passing through another zone by substantially mλ (m is an integral number) for a light beam selected from light beams consisting of the first light beam, the second light beam, and the third light beam, and by substantially 2mλ (m is an integral number) for a rest of the light beams. The wavelength with a difference of substantially 2 mλ is preferably λ1. Preferably, the wavelength λ1 is approximately 405 nm, the wavelength λ2 is approximately 655 nm, and the wavelength λ3 is approximately 790 nm.
It is possible to constitute an optical head and an optical disk with the optical pickup system of this structure.
Preferably, each of the first light beam, the second light beam, and the third light beam is focused on each optical recording medium after passing through a wavelength selective filter having an outer area that allows the first light beam and the second light beam to pass through and shields the third light beam, and an inner area that allows the first light beam, the second light beam, and the third light beam to pass through.
Particularly, a numerical aperture of a light beam after passing through the objective lens is preferably largest in the first light beam, second-largest in the second light beam, and smallest in the third light beam.
S1 and S3 preferably respectively satisfy expressions: S1<0, S3>0. Further, magnification m1 of the first light beam and magnification m3 of the third light beam respectively preferably satisfy expressions of 0<m1≦1/10 and −1/10<m3≦0, and more preferably 0<m1≦1/20 and −1/20<m3≦0.
Preferably, the wavelength selective filter is formed in a surface of the objective lens. A refractive index of the wavelength selective filter is within a range of 0.9 to 1.1 with respect to a refractive index of the objective lens. The objective lens is made of material mainly composed of glass with a refractive index of 1.49 to 1.70.
According to another aspect of the invention, there is provided an objective lens receiving light beams with different wavelengths λn (n≧3) for at least three kinds of optical recording media and having a positive power to focus each light beam on an information recording surface of a transparent substrate of each optical recording medium by refraction, wherein, if distances between points Pn (n≧3) where incident light beams or extension lines of incident light beams with wavelengths λn (n≧3) to the objective lens crosses an optical axis and a point Q where a lens surface of the objective lens located farther from each optical recording medium than another lens surface crosses the optical axis is expressed by Sn (n≧3), and a sign of the distance Sn is defined as positive if a position of the point Pn is located in a different side from the optical recording medium with respect to the point Q, and defined as negative if the position of the point Pn is located in the same side as the optical recording medium with respect to the point Q, an incident light beam satisfying following expressions enters the objective lens:
λ1<λ3 and (1/S1)<(1/S3) Expression 1:
λ2<λ3(λ2>λ1) and (1/S2)<(1/S3), Expression 2:
each light beam is focused on the information recording surface with RMS wavefront aberration of 0.050 λRMS or below, and the objective lens is made of material mainly composed of glass with a refractive indexof 1.49 to 1.70 and a thermal deformation temperature of 300° C. or below.
According to an aspect of the invention, there is provided an antireflection coating formed on a light transmitting surface of an optical component with a refractive index of ns used in an optical pickup device using at least two wavelengths of approximately 405 nm and 655 nm, the antireflection coating comprising two layers of a high refractive index layer with a refractive index of nH and an optical coating thickness of nHdH formed on the optical component; and a low refractive index layer with a refractive index of nL, and an optical coating thickness of nLdL formed on the high refractive index layer, wherein a reflectance is lowest only in two regions of approximately 405 nm and 655 nm and highest in one region between the two lowest regions.
According to another aspect of the invention, there is provided an antireflection coating used in an optical pickup device using at least three wavelengths of approximately 405 nm, 655 nm, and 790 nm and formed on a light transmitting surface of an optical component with a refractive index of ns, the antireflection coating comprising two layers of: a high refractive index layer with a refractive index of nH and an optical film thickness of nHdH formed on the optical component; and a low refractive index layer with a refractive index of nL, and an optical film thickness of nLdL formed on the high refractive index layer, wherein a reflectance is lowest only in two regions of approximately 405 nm and 655 nm and highest in one region between the two lowest regions.
The antireflection coating preferably satisfies following conditions: 0.9≦nH/A≦1.1, 0.1≦nH-ns, 225 nm≦nHdH≦275 nm, 100 nm≦nLdL≦150 nm, where A=(1.21*ns+0.84*nL*nL)/2. More preferably, it satisfies nH-ns≦0.4. In a preferred embodiment, material of the low refractive index layer is silicon oxide or fluoride. The antireflection coating may be formed on a surface of the optical component for an optical pickup. Preferably, the optical component is made of material mainly composed of glass with a refractive index ns of 1.49 to 1.70 and a thermal deformation temperature of 300° C. or below.
According to another aspect of the invention, there is provided a method of manufacturing an object lens for an optical pickup, used in an optical pickup device using at least three wavelengths of approximately 405 nm, 655 nm and 790 nm and having a surface where an antireflection coating composed of a high refractive index layer and a low refractive index layer is formed, the method comprising: selecting material for the high refractive index layer and the low refractive index layer that satisfy following conditions of 0.9≦nH/A≦1.1, 0.1≦nH-ns, where A=(1.21*nS+0.84*nL*nL)/2, when ns is a refractive index of the objective lens, nH is a refractive index of the high refractive index layer, and nL is a refractive index of the low refractive index layer; forming the high refractive index layer with a refractive index of nH on the objective lens; and forming the low refractive index layer with a refractive index of nL on the high refractive index layer.
The step of selecting material preferably selects material so as to satisfy a condition of nH-ns≦0.4. Further, the step of selecting material preferably selects material so as to satisfy a condition of: 1.30≦nL≦1.55
According to another aspect of the invention, there is provided an antireflection coating placed in a light transmitting surface of an optical component with a refractive index of ns used in an optical pickup device using at least three wavelengths of approximately 405 nm, 655 nm and 790 nm, comprising two layers of: a high refractive index layer with a refractive index of nH formed on the optical component; and a low refractive index layer with a refractive index of nL formed on the high refractive index layer, wherein the antireflection coating satisfies following conditions of 0.9≦nH/A≦1.1, 0.1≦nH-ns, where A=(1.21*ns+0.84*nL*nL)/2.
According to another aspect of the invention, there is provided an objective lens wherein the objective lens is made of material mainly composed of glass with a refractive index of 1.49 to 1.70 and a thermal deformation temperature of 300° C or below, and the objective lens has an antireflection coating composed of two layers of a high refractive index layer with a refractive index of nH and an optical film thickness of nHdH and a low refractive index layer with a refractive index of nL and an optical film thickness of nLdL, and having lowest reflectance values only in two regions of approximately 405 nm and 655 nm and a highest reflectance value in one region between the two lowest reflectance values.
The present invention can provide an optical pickup system, an optical head, and an optical disk apparatus that can focus an optical beam on an information recording surface for each of a plurality of kinds of optical recording media having different use wavelengths with a passively lowest wavefront aberration and a high light use efficiency.
The present invention can provide an antireflection coating composed of two layers and having low reflectance in three kinds of wavelength regions and an optical pickup component.
The above and other objects, features and advantages of the present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus are not to be considered as limiting the present invention.
BRIEF DESCRIPTION OF THE DRAWINGS
A lens according to this invention is a multiwavelength lens using a plurality of kinds of monochromatic light. It is a general-purpose multiwavelength lens that can be used for a recording and reproducing apparatus compatible with different kinds of optical recording media such as CD including CD-R, DVD, Blu-ray disk, and Advanced Optical Disk (AOD). A multiwavelength optical system, optical head, and optical disk apparatus according to this invention use this multiwavelength optical lens.
The present invention is schematically described hereinafter.
It is assumed that for a first optical disk using a transparent substrate having a thickness t1, the aberration of an objective lens placed in an optical disk apparatus to be used is corrected appropriately, and a laser beam with a wavelength λ1 is appropriately focused an information recording surface of the substrate. In this optical disk apparatus, a laser beam with a wavelength λ2 which is different from the wavelength λ1 is now to be focused on a second optical disk using a transparent substrate having a thickness t2.
In this case, the laser beam wavelength λ1 and λ2 and the transparent substrate thickness t1 and t1 respectively differ from each other, or, even if the thickness t1 and t1 are the same, the wavelength λ1 and λ2 differ from each other. Thus, spherical aberration due to a difference in transparent substrate thickness and chromatic aberration due to a difference in refractive index of the objective lens because of a difference in laser beam wavelength both occur, or only the chromatic aberration occurs, making it unable to focus the laser beam appropriately on the information recording surface.
The present invention sets the aspherical surface shape of an objective lens and the divergence of an incident light beam to an objective lens so that no or little aberration occurs in an optical path length at a given optical height for all different kinds of disks with difference wavelengths. It is thereby possible to reduce the aberration for all the optical disks. Further, since this invention achieves it only with refracted light, not using diffraction, no light loss of diffraction efficiency occurs.
As detailed later, a lens of an embodiment of the invention has a lens surface that is sectioned into a plurality of aspherical surfaces.
Referring first to
An incident point to the objective lens 1 on the optical path is represented by P2, an exit point from the objective lens 1 is by P3, and an incident point to the transparent substrate 2 is by P4. A spatial distance and the refractive index between the points are represented as follows:
Point P1 to Incident point P2: Distance=S1h, Refractive index=n1
Incident point P2 to Exit point P3: Distance=S2h, Refractive index=n2
Exit point P3 to Incident point P4: Distance=S3h, Refractive index=n3
Incident point P4 to Focal point P5: Distance=S4h, Refractive index=n4.
The optical path length Lh from the point P1 to the focal point P5 is expressed by the following expression:
Lh=n1*S1h+n2*S2h+n3*S3h+n4*S4h Expression 3:
The optical path length Lh on the optical axis OA is when h=0 in Expression 3.
Expression 3 is applicable to any optical height h. When aberration is corrected, the focal point P5 for each optical height h is on the information recording surface 2a within allowable ranges. Specifically, the present invention uses a laser beam having a different wavelength for each of a plurality of substrates having different thickness and therefore spherical aberration and chromatic aberration cancel each other out so that the focal point P5 for a given optical height h is on the information recording surface 2a within each of the allowable ranges.
Though the case where the incident light to the objective lens 1 is parallel light, which is an infinite system, is described above, the incident light may be divergent light, which is a finite system. It is also possible to select the infinite or finite systems for use for different optical recording media and different wavelengths. Further, it is also possible to use the same finite system for different optical recording media while changing the divergence of an incident light beam. The incident light to the objective lens may be convergent light.
For example, a monochromatic light λ1 of 405 nm wavelength for HDDVD (AOD) and a monochromatic light λ2 of 655 nm wavelength for DVD are used. In this case, an area of a lens surface commonly used for the both wavelengths can be sectioned into a plurality of aspherical surface sections. In this technique, the optical path length of one aspherical section is different from that of another aspherical section by integral multiple of the wavelength λ1 of each monochromatic light. Further, a difference between a maximum value and a minimum value of wavefront aberration of each monochromatic light in each aspherical section is ΔVd(λ1) and ΔVd(λ2) where d is an integral number of 1, 2 . . . , meaning each aspherical section.
In these conditions, if the ratio of the difference between the maximum value and the minimum value of the wavefront aberration of each monochromatic light is between 0.4 and 2.5, preferably between 0.5 and 2.0, in any aspherical section, Root Mean Square (RMS) wavefront aberration of the whole lens can fall within an allowable range for all the wavelengths. Further, the RMS wavefront aberration value in CD can be improved if the incident light beam is divergent light or incident light with higher divergence than in HDDVD and DVD. The spherical aberration due to a thick substrate and the chromatic aberration due to highly divergent incident light thereby cancel out each other, thereby correcting the spherical aberration that occurs in CD.
If the optical length when the optical height h=0 is L0, and the optical path length at each optical height is Lh, the wavefront aberration Vh is expressed by the following expression:
Vh=(Lh-L0)/λi Expression 4:
For example, a difference between the maximum and minimum values of the wavefront aberration in a first aspherical section is defined as ΔVd(λ1) and ΔVd(λ2). As in the embodiments described later, the ratio of a difference between the maximum and minimum values of the wavefront aberration for each wavelength falls within the range of 0.4 to 2.5 in any aspherical section in this invention. Thus, each aspherical section has a uniform distribution of wavefront aberration for any wavelength. This is different from conventional techniques that design a lens surface based on one wavelength and corrects wavefront aberration in the other wavelength using phase lag.
In the multiwavelength lens of the present invention, a difference between the maximum and minimum values of the wavefront aberration of each wavelength can be 0.14 λi or lower, preferably 0.12 λi or lower, and more preferably 0.10 λi or lower. For example, when a difference between the maximum and minimum values is 0.14 λi or lower, if the wavelength is 790 nm, it is 110.6 nm or lower, if the wavelength is 655 nm, it is 91.7 nm or lower, and if the wavelength is 405 nm, it is 56.7 nm. The multiwavelength lens of this invention can thereby have suitable optical characteristics in each wavelength.
Further, if this invention is applied to a dual wavelength optical system, use of a multiwavelength lens in which the wavefront aberration for each wavelength is substantially symmetrical produces a suitable balance between the two wavelengths, thereby further reducing the RMS wavefront aberration.
As a result, the RMS wavefront aberration is 0.03152λ1RMS in HDDVD, 0.023237λ2RMS in DVD, and thus the RMS wavefront aberration is substantially equal in HDDVD and DVD. The RMS wavefront aberration in CD is 0.01764λ3RMS, which is smaller than that of HDDVD and DVD.
For the recording and reproducing the CD (790 nm), it is possible to change the divergence of the incident light to the objective lens or a so-called object distance for the objective lens in a geometrical-optical sense. This is effective for correcting spherical aberration since the degree of spherical aberration changes by the divergence of the incident light. This is described in the embodiments below.
Further, in the embodiments of the invention described later, the incident light having the wavelengths of 405 nm and 655 nm are infinite and the incident light having the wavelength of 790 nm is finite. Specifically, the divergence of the incident light with 405 nm and 655 nm wavelengths are the same and the divergence of the incident light with 790 nm wavelength is different. Selection of a wavelength whose divergence is to be changed may be made each time according to use wavelength and substrate thickness so as to reduce aberration. Further, all the wavelengths may be incident as divergent light or as convergent light.
The embodiments of the invention described later allow formation of a suitable optical spot on an information recording surface for any optical disk having a substrate of a different thickness. This is applicable also when the thickness of a disk substrate is not different, that is, when the thickness is the same and the wavelength is different, by setting focal point P5 shown in
Preferred embodiment of the present invention is described hereinafter in detail.
First EmbodimentA first embodiment of the present invention is described below with reference to the drawings. It takes the case of using three kinds of optical disks, HDDVD (λ1=405 nm), DVD(λ2=655 nm), and CD(λ3=790 nm), as an example. Though the lens used in the first embodiment has a refractive index that is equivalent to plastic resin, it may have a refractive index of a glass if it is desired to use a glass as a lens material.
In
The wavelength selective filter 6 shown in
Specifically, a dichroic coating having the spectral transmittance characteristics as shown in
Ideal spectral transmittance characteristics are that transmittance is 100% for a wavelength of 750 nm or lower and it is 0% for a wavelength of 750 nm or higher. The spectral transmittance characteristics shown in
The first embodiment designs the lens surface shape of the objective lens 1 in such a way that the optical path length Lh expressed by Expression 3 for a given optical height h falls is a value that reduces aberration to fall within an allowable range in all the case of HDD, DVD, and CD. It is thereby possible to reduce aberration in HDDVD, DVD, and CD and produce an appropriate optical spot on the information recording surface of each medium.
In the first embodiment, the light incident surface A is radially sectioned from the optical axis into a plurality of zones, and the surface shape of each zone is designed so as to reduce aberration to an allowable range for HDDVD, DVD and CD.
The surface shape of the light incident surface A in the first embodiment is described hereinafter with reference to
The optical height h in Expression 5 is that in the j-th zone.
In
Then, for each case of HDD, DVD, and CD, the range of h and constants B, C, K, A4, A6, A8, A10, A12, A14, A16 are calculated for each zone in Expression 5 to reduce aberration to an allowable range.
A distance between surface apexes f and e on the optical axis of the objective lens 1, which is a center thickness t0, is 1.94 mm. A refractive index n for a wavelength λ1=405 nm (Blu-ray disk) is 1.54972, a refractive index n for a wavelength λ2=655 nm (DVD) is 1.53, and a refractive index n for a wavelength λ3=790 nm (CD) is 1.5263653.
The transparent substrate of Blu-ray disk (wavelength λ1=405 nm) has a thickness of 0.6 mm and a refractive index of 1.6235. The transparent substrate of DVD (wavelength λ2=655 nm) has a thickness of 0.6 mm and a refractive index of 1.58. The transparent substrate of CD (wavelength λ3=790 nm) has a thickness of 1.2 mm and a refractive index of 1.57163.
In HDDVD with a wavelength of 405 nm, NA is 0.650 and a focal length is 3.1015 mm. In DVD with a wavelength of 655 nm, NA is 0.628 and a focal length is 3.2116 mm. The effective diameter of incident parallel light is φ4.032 in both HDDVD and DVD. Further, the entire lens surface in the side A is a HDDVD/DVD common use area. In CD with a wavelength of 790 nm, NA is 0.470 and a focal length is 3.2327 mm.
The tables of
In CD, a distance from the object surface to the objective lens is 49.4 mm, and divergent light is input to the objective lens. In the case of CD as well, a distance from an emission point of a CD laser to a surface apex of the objective lens in the light source side may be 49.4 mm in an actual optical system. In this case, however, an optical pickup becomes large.
It is preferred in this case to place the collimator lens between the CD laser light source and the objective lens, and places the emission point of the CD laser in the position closer to the collimator lens than the focal position of the collimator lens. In this arrangement, the light emitted from the CD laser and having passed through the collimator lens becomes divergent light and enters the objective lens. The collimator lens and the CD laser are preferably arranged so that the incident light to the objective lens becomes the same as the light emitted from a distance of 49.4 mm without collimator lens.
The thickness of the wavelength selective filter is determined so that the incident light enters at 0 degree. The incident light can enters obliquely due to positions of components such as a laser and mirrors, accuracy variation, displacement of an emission point of a two-wavelength laser or a three-wavelength laser in the direction perpendicular to the optical axis, and so on. For this reason, the thickness of the wavelength selective filter is preferably small, and it is 0.5 mm in the first embodiment.
In the first embodiment shown in
Therefore,
405 nm(λ1)<790 nm(λ3).
Further,
(1/S1)=(1/∞)=0,
(1/S3)=(1/49.4)=0.0202429
Therefore,
0<0.0202429; (1/S1)<(1/S3)
Hence, in HDDVD and CD, λ1<λ3 and (1/S1)<(1/S3) are both satisfied.
Further, since
655 nm(λ2)<790 nm(λ3).
and
(1/S2)=(1/∞)=0,
(1/S3)=(1/49.4)=0.0202429.
Therefore,
0<0.0202429; (1/S2)<(1/S3)
Hence, in DVD and CD, λ2<λ3 and (1/S2)<(1/S3) are both satisfied.
The refractive index of this objective lens is close to the refractive index of a plastic resin. Thus, when using polyolefin resin or acrylic resin, the objective lens is designed by using the refractive index of the resin to determine each aspherical surface shape and a lens center thickness. Particularly, since the polyolefin resin does not substantially absorb water under the high-humidity environment as well, it is advantageous in that the refractive index does not change. On the other hand, the acrylic resin is advantageous in that a transmittance of Blu-ray is high and a transmittance in the vicinity of Blu-ray (405 nm) does not substantially change over time.
The objective lens is preferably made of material with low birefringence since it produces a suitable value of wavefront aberration when forming a lens by injection molding, cast molding, or the like. Further, use of acrylic material has a problem that water absorption changes under the high-humidity environment. Therefore, when using the acrylic material, it is preferred to perform humidity conditioning beforehand so as to make it absorb some water since it is effective when the objective lens is used under the environment of almost absolute dry or high-humidity. In this case, the lens is designed by using the refractive index of the resin after absorbing some water by the humidity conditioning.
Substitution of values into the coefficients C, K, A4, A6, A8, and A10 in Expression 6 gives a value of the distance ZB for a given optical height h (≠0) as negative. This means that the point d on the light exit side B is located closer to the light incident surface side (in the left side of
(i) An allowable value for the aberration to evaluate the aberration is an RMS wavefront aberration of 0.035λ and preferably 0.033λ for HDDVD (wavelength λ1=405 nm), DVD (wavelength λ2=655 nm) and CD (wavelength λ3=790 nm) when an incident laser beam to the objective lens 1 has an incident angle of 0°, that is, when it is parallel light parallel with the optical axis OA. In the first embodiment, the light exit surface B and the light incident surface A are designed to have the above surface shapes in order that the wavefront aberrations for HDDVD, DVD, and CD do not exceed this allowable value.
Though the first embodiment describes the case of using three kinds of different wavelengths λ1, λ2, and λ3, this is the same when using the n (n is an integral number of 2 and above) number of kinds of different wavelengths λi (i=1, 2, . . . , n).
(ii) In the case of using the n number of kinds of wavelengths λi, if the RMS wavefront aberrations when the incident laser beams with the wavelengths λi have the incident angle of 0° is Wi·λi, the aberration satisfies the following expression:
The allowable value W0 is 0.035 or below and preferably 0.033 or below.
In Expression 7, the wavelength of the i-th light beam is λi (i=1, 2, . . . ), a sum of square of the RMS wavefront aberration for all the wavelengths is ΣWi2, and the RMS wavefront aberration of a light beam having wavelength λi is Wi·λi.
(iii) In a case of using laser beams having the n number of kinds of different wavelengths λi, of the maximum RMS wavefront aberration is Wmax and the minimum RMS wavefront aberration is Wmin, the following expression are satisfied:
1≦Wmax/Wmin<Wth
The allowable value Wth in this case is 1.8, preferably 1.6, and more preferably 1.4. In the case of the first embodiment, one of the RMS wavefront aberrations W1 for DVD and the RMS wavefront aberration W2 for CD is the maximum RMS wavefront aberration Wmax, and the other is the minimum RMS wavefront aberration Wmin.
The value of Expression 7 is:
It is 0.0 035 λRMS or below, and also 0.033 λRMS or below.
The optical spot diameter is approximately 0.82*wavelength/NA in an ideal optical system having no aberration. In an actual lens, the optical spot diameter is generally preferably smaller. Since other adverse effects can occur if the optical spot diameter is too small, it is preferred that the optical spot is 0.9 to 1.03 times the value of 0.82*wavelength/NA. Further, if the optical spot diameter is too small, it causes an adverse effect such as Super-resolution. If the optical spot diameter is too large, it causes deteriorated focusing characteristics of the optical spot, affecting jitter characteristics or the like.
Evaluation of the first embodiment is as follows.
In HDDVD (wavelength 405 nm; NA 0.650), 0.82*wavelength/NA=0.5109 μm. Since an actual optical spot diameter is 0.5149 μm, it is 1.0078 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
In DVD (wavelength 655 nm; NA 0.628), 0.82*wavelength/NA=0.8553 μm. Since an actual optical spot diameter is 0.8606 μm, it is 1.0062 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
In CD (wavelength 790 nm; NA 0.470), 0.82*wavelength/NA=1.3783μm. Since an actual optical spot diameter is 1.3979 μm, it is 1.0142 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
Further, this lens is designed so that the wavefront aberration appears on the positive (+) side in the wavelength of 655 nm (DVD), and on the negative (−) side in the wavelength of 405 nm (HDDVD). The wavefront aberration is thus substantially symmetrical.
As described in the foregoing, the first embodiment allows the aberration to fall within the above allowable range. This is achieved by designing the lens surface shape and setting the divergence of incident light to the objective lens that make the aberration within the allowable range, considering each wavelength and each substrate thickness.
The effect of the first embodiment to reduce the overall aberration is obvious from the graphs of the optical spot shown in
Though the first embodiment describes the case of using three kinds of optical disks, HDDVD, DVD, and CD, this invention is not limited thereto but is also applicable to the case of using other kinds of optical disks. Further, the first embodiment is applicable to the optical disk having the same or different substrate thickness. In this case, it changes the wavelength of the laser beam to be used for each disk and designs the lens surface shape so as to reduce the overall aberration according to it.
Second EmbodimentA second embodiment of the invention describes a case where the substrate thickness is different and the wavelength is also different (405 nm, 655 nm, and 790nm). Specifically, the second embodiment relates to the case of using Blu-ray or Blue laser with the wavelength of 405 nm and the substrate thickness of 0.1 mm, the case of using DVD with the wavelength of 655 nm and the substrate thickness of 0.6 mm, and the case of using CD with the wavelength of 790 nm and the substrate thickness of 1.2 mm.
In the second embodiment, the basic lens structure is the same as in the first embodiment shown in
On the side A in the light source side, the relationship between ZA and h is expressed by Expression 5. The specific values are shown in the tables of FIGS. 12 to 15 for each zone 1 to 22. On the other hand, on the side B in the disk side which is opposite to the light source, the relationship between ZB and h is expressed by Expression 6. The specific values are shown in the table of
The refractive index of the objective lens in the second embodiment is close to the refractive index of a glass with a high refractive index, which is the refractive index of VD89, for example.
A distance between the surface apexes f and e on the optical axis of the objective lens 1, which is the center thickness t0, is 2.076 mm. The refractive index n for a wavelength λ1=405 nm (Blu-ray disk) is 1.83164, the refractive index n for a wavelength λ2=655 nm (DVD) is 1.7911, and the refractive index n for a wavelength λ3=790 nm (CD) is 1.783555.
The transparent substrate of Blu-ray disk (wavelength λ1=405 nm) has a thickness of 0.6 mm and a refractive index of 1.6235. The transparent substrate of DVD (wavelength λ2=655 nm) has a thickness of 0.6 mm and a refractive index of 1.58. The transparent substrate of CD (wavelength λ3=790 nm) has a thickness of 1.2 mm and a refractive index of 1.573. Therefore, a difference in refractive index between Blu-ray disk (wavelength λ1=405 nm) and DVD (wavelength λ2=655 nm) is 0.03 or higher, and a difference in refractive index between Blu-ray disk (wavelength λ1=405 nm) and CD (wavelength λ3=790 nm) is also 0.03 or higher.
In Blu-ray disk with a wavelength of 405nm, NA is 0.850 and a focal length is 1.765 mm. In DVD with a wavelength of 655 nm, NA is 0.600 and a focal length is 1.8564 mm. In CD with a wavelength of 790 nm, NA is 0.469 and a focal length is 1.8745 mm. The aperture diameters are as shown in
In CD, a distance from the object surface to the objective lens is 15.5 mm, and divergent light is input to the objective lens. In the case of CD as well, a distance from an emission point of a CD laser to a surface apex of the objective lens in the light source side may be 15.5 mm in an actual optical system. In this case, however, an optical pickup becomes large.
It is preferred in this case to place the collimator lens between the CD laser light source and the objective lens, and places the emission point of the CD laser in the position closer to the collimator lens than the focal position of the collimator lens. In this arrangement, the light emitted from the CD laser and having passed through the collimator lens becomes divergent light and enters the objective lens. The collimator lens and the CD laser are preferably arranged so that the incident light to the objective lens becomes the same as the light emitted from a distance of 15.5 mm without collimator lens.
In the second embodiment shown in
Therefore,
405 nm(λ1)<790 nm(λ3).
Further,
(1/S1)=(1/∞)=0,
(1/S3)=(1/15.5)=0.064516129
Therefore,
0<0.064516129; (1/S1)<(1/S3)
Hence, in Blu-ray and CD, λ1<λ3 and (1/S1)<(1/S3) are both satisfied.
Further, since
655 nm(λ2)<790 nm(λ3).
and
(1/S2)=(1/∞)=0,
(1/S3)=(1/15.5)=0.064516129.
Therefore,
0<0.064516129; (1/S2)<(1/S3)
Hence, in DVD and CD, λ2<λ3 and (1/S2)<(1/S3) are both satisfied.
As shown in
However, the light with the wavelength of 655 nm (DVD) passes though the Blu-ray exclusive use area with the wavelength selective filter. Therefore, the incident laser beam enters DVD and it becomes flare light having extremely high aberration on the information recording surface of DVD, which does not have any harmful effect.
This is obvious also from the optical spot graphs of
The value of Expression 7 is:
It is 0.0 035 λRMS or below, and also 0.033 λRMS or below.
Further, since the refractive index of the lens is the value described above, it is likely to obtain an appropriate difference in substantial optical path length and suitable wavelength aberration. Specifically, a different in refractive index between wavelengths 405 nm and 655 nm is 0.04054, and a difference in refractive index between wavelengths 405 nm and 790 nm is 0.048085. Since the both values are larger than 0.03, it is likely to produce an appropriate difference in substantial optical path length and suitable wavelength aberration.
As shown in
Evaluation of the optical spot diameter in comparison with 0.82*wavelength/NA which is described in the first embodiment is as follows.
In Blu-ray (wavelength 405 nm; NA 0.850), 0.82*wavelength/NA=0.3907 μm. Since an actual optical spot diameter is 0.3836 μm, it is 0.9818 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
In DVD (wavelength 655 nm; NA 0.600), 0.82*wavelength/NA=0. 8952 μm. Since an actual optical spot diameter is 0.8570 μm, it is 0.9574 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02. In DVD, the optical spot diameter is smaller than in the ideal lens by about as much as 4% (0.04 times). This is because the DVD light passes through the Blu-ray exclusive use area also, and the optical spot diameter becomes smaller due to this effect.
In CD (wavelength 790 nm; NA 0.469), 0.82*wavelength/NA=1.3812 μm. Since an actual optical spot diameter is 1.4084 μm, it is 1.0197 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
Though the wavelength of one monochromatic light is 405 nm and the wavelengths of the other monochromatic light are 655 nm and 790 nm in the second embodiment, the one may be 380 to 430 nm and the other may be 630 to 680 nm and 770 to 820 nm. While the refractive index differs in this case, it is designed in accordance with the value.
Third Embodiment The configuration of a third embodiment of the invention (convergent light incidence in HDDVD) describes the case where an object length to CD is longer than in the first embodiment (parallel light incidence in HDDVD). In the first embodiment, the incident light to the objective lens is parallel light in HDDVD and DVD, and it is divergent light in CD. In the third embodiment, the incident light to the objective lens is convergent light in HDDVD, parallel light in DVD, and divergent light in CD. The configuration of the third embodiment (convergent light incidence in HDDVD) can increase the object distance to CD compared to the first embodiment the first embodiment (parallel light incidence in HDDVD). The coma aberration occurring off-axis is higher when divergent light is incident to the objective lens compared to when parallel light is incident to the objective lens. Therefore, when the objective lens is horizontally shifted (objective lens shift) in the plane substantially perpendicular to the optical axis for tracking, high comma aberration can occur. The degree of comma aberration is largely affected by the divergence of light. Smaller divergence or longer object distance can reduce comma aberration in the objective lens shift. Therefore, the configuration of the optical system of the third embodiment is advantageous in CD objective lens shift compared to the configuration of the first embodiment. However, since convergent light is incident to HDDVD, comma aberration occurs in HDDVD also during the objective lens shift. Thus, it is preferred to consider the balance of object distance (magnification) in HDDVD and CD. If the magnification in HDDVD is m1 and magnification in CD is m3, it is preferable to satisfy:
0<m1≦1/10, −1/10≦m3<0
If m1 and m3 are out of the above range, comma aberration in the objective lens shift increases. The following range is more preferable:
0<m1≦1/20, −1/20≦m3<0
Though the lens in the third embodiment has a refractive index equivalent to plastic resin, it may be designed to have a refractive index of glass if a lens material is glass.
The basic lens structure of the third embodiment is described with reference to
On the side A in the light source side, the relationship between ZA and h is expressed by Expression 5. The specific values are shown by the table of
A distance between the surface apexes f and e on the optical axis of the objective lens 1, which is the center thickness t0, is 1.92 mm. The refractive index n for a wavelength λ1=408 nm (HDDVD) is 1.5229, the refractive index n for a wavelength λ2=658 nm (DVD) is 1.5048, and the refractive index n for a wavelength λ3=785 nm (CD) is 1.5018.
The transparent substrate of HDDVD (wavelength λ1=408 nm) has a thickness of 0.6 mm and a refractive index of 1.622. The transparent substrate of DVD (wavelength λ2=658 nm) has a thickness of 0.6 mm and a refractive index of 1.577. The transparent substrate of CD (wavelength λ3=785 nm) has a thickness of 1.2 mm and a refractive index of 1.5720.
In HDDVD with a wavelength of 408 nm, NA is 0.650 and a focal length is 3.101 mm. In DVD with a wavelength of 658 nm, NA is 0.650 and a focal length is 3.2059 mm. In CD with a wavelength of 785 nm, NA is 0.470 and a focal length is 3.2246 mm. The aperture diameters are as shown in
The tables of
In CD, a distance from the object surface to the objective lens is 98.9113.0 mm, and divergent light is input to the objective lens. In an actual optical system, a distance from an emission point of a CD laser to a surface apex of the objective lens in the light source side may be 98.9113 mm. In this case, however, an optical pickup becomes large. It is thus preferred to place the collimator lens between the CD laser light source and the objective lens, and places the emission point of the CD laser in the position closer to the collimator lens than the focal position of the collimator lens. In this arrangement, the light emitted from the CD laser and having passed through the collimator lens becomes divergent light and enters the objective lens. The collimator lens and the CD laser are preferably arranged so that the incident light to the objective lens becomes the same as the light emitted from a distance of 98.9113 mm without collimator lens.
In the third embodiment shown in
Therefore,
408 nm(λ1)<785 nm(λ3).
Further,
(1/S1)=(1/−93.9)=−0.010649627,
(1/S3)=(1/113.0)=0.008849557
Therefore,
−0.010649627<0.008849557; (1/S1)<(1/S3)
Hence, in HDDVD and CD, λ1<λ3 and (1/S1)<(1/S3) are both satisfied.
Further, since magnification ml of HDDVD is 1/31.2, and magnification m3 of CD is −1/34.1, 0<m1≦1/20 and −1/20≦m3<0 are both satisfied.
Further,
658 nm(λ2)<785 nm(λ3)
and
(1/S2)=(1/∞)=0,
(1/S3)=(1/113.0)=0.008849557.
Therefore,
0<0.008849557; (1/S2)<(1/S3)
Hence, in DVD and CD, λ2<λ3 and (1/S2)<(1/S3) are both satisfied.
As shown in
However, the light with the wavelength of 408 nm (HDDVD) also passes though the DVD exclusive use area with the wavelength selective filter. Therefore, the laser beam emitted from the laser enters HDDVD after passing through the objective lens. Since the incident light becomes flare light having extremely high aberration on the information recording surface of HDDVD, it does not have any harmful effect.
The wavelength selective filter as shown in
The RMS wavefront aberration in HDDVD is 0.03253 λRMS, the RMS wavefront aberration in DVD is 0.03178 λRMS, and the RMS wavefront aberration in CD is 0.02091 λRMS. Thus, the RMS wavefront aberration of 0.035 λRMS or below, and further 0.033 λRMS or below are achieved in HDDVD, DVD, and CD.
The value of Expression 7 is:
It is 0.0 035 λRMS or below, and also 0.033 λRMS or below.
Evaluation of the optical spot diameter in comparison with 0.82*wavelength/NA which is described in the first embodiment is as follows.
In HDDVD (wavelength 408 nm; NA 0.650), 0.82*wavelength/NA=0.5147 μm. Since an actual optical spot diameter is 0.5029 μm, it is 0.9771 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02. In HDDVD, the optical spot diameter is smaller than that of the ideal lens by about as much as 2.3% (0.023 times). This is because the HDDVD light passes through the DVD exclusive use area also, and the optical spot diameter becomes smaller due to this effect.
In DVD (wavelength 658 nm; NA 0.65), 0.82*wavelength/NA=0.8301 μm. Since an actual optical spot diameter is 0.8236 μm, it is 0.9922 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
In CD (wavelength 785 nm; NA 0.470), 0.82*wavelength/NA=1.3696 μm. Since an actual optical spot diameter is 1.3811 μm, it is 1.0084 times the value of 0.82*wavelength/NA, thus being within a preferable range of 0.9 to 1.02.
Though the wavelengths of monochromatic light are 408 nm, 658 nm, and 785 nm in the third embodiment, they may be 380 to 430 nm, 630 to 680 nm, and 770 to 820 nm, respectively. While the refractive index differs in this case, it may be designed in accordance with these values. Further, the incident light to the objective lens is parallel light in HDDVD and DVD, and it is divergent light in CD in the first embodiment, and the incident light to the objective lens is convergent light in HDDVD, parallel light in DVD, and divergent light in CD in the third embodiment. However, it is not limited to these combinations. For example, it is possible to use convergent light in HDDVD and DVD and divergent light in CD. If the object distance is the same in HDDVD and DVD, it is possible to use the same optical detector for both HDDVD and DVD.
Fourth EmbodimentA fourth embodiment of the invention describes the case where the substrate thickness is different and the wavelength is also different (408 nm, 655 nm, and 790 nm), which is similar to the second embodiment. In this embodiment, the objective lens is made of different material from the objective lens in the second embodiment.
In the second embodiment, it is expected that an objective lens is made of glass having a high melting point and a high thermal deformation temperature (Tg=528° C.), such as VC89, for example. On the other hand, in the fourth embodiment, it is expected that an objective lens is made of glass having a low melting point and a low thermal deformation temperature (Tg=228° C.), such as K-PG325 manufactured by SUMITA optical glass, inc., for example. A difference in objective lens material between the second and fourth embodiments is comparatively described below.
Since the glass with a high refractive index such as VC89 has a high melting point of 600° C. or above, it requires a carbide die in which it is difficult to provide a microstructure on its surface as a lens molding die that is endurable for the temperature. Further, since it takes a long time to reduce the temperature to a normal temperature after lens molding, it causes low productivity per hour. On the other hand, the glass with a low refractive index such as K-PG325 has a low melting point of about 300° C., it is possible to use an equivalent lens molding die to the one used for plastic material, in which it is easy to provide a microstructure such as orbicular zones. Further, since it takes only a short time to reduce the temperature to a normal temperature, it achieves high productivity per hour. In the following, the material that is mainly composed of glass with a refractive index of 1.49 to 1.70 and a thermal deformation temperature of 300° C. or below is called “low-melting glass”.
The refractive index of the low-melting glass is 1.49 to 1.70 for light of 408 nm, for example, which is lower than normal glass such as VC89. Therefore, optical design of a high NA lens is difficult to make since the low-melting glass has a low refractive index. This embodiment secures the characteristics when using the low-melting glass as material of the objective lens by increasing the center thickness of the lens to 2.642 mm. Though the low-melting glass has substantially the same refractive index as plastic material, it is more advantageous as objective lens material in having higher temperature/humidity characteristics than the plastic material.
Specifically, the fourth embodiment relates to the case of using Blu-ray or light emitted from Blue laser with the wavelength of 408 nm and the substrate thickness of 0.0875 mm, the case of using DVD with the wavelength of 655 nm and the substrate thickness of 0.6 mm, and the case of using CD with the wavelength of 790 nm and the substrate thickness of 1.2 mm. It uses the low-melting glass as lens material.
In the fourth embodiment, the basic lens structure is the same as in the first embodiment shown in
On the side A in the light source side, the relationship between ZA and h is expressed by Expression 5. The specific values are shown in the tables of FIGS. 29 to 34 for each zone. On the other hand, on the side B in the disk side which is opposite to the light source, the relationship between ZB and h is expressed by Expression 6. The specific values are shown in the table of
A distance between the surface apexes f and e on the optical axis of the objective lens 1, which is the center thickness t0, is 2.642 mm. The refractive index n for a wavelength λ1=408 nm (Blu-ray disk) is 1.5126, the refractive index n for a wavelength λ2=655 nm (DVD) is 1.4987, and the refractive index n for a wavelength λ3=790 nm (CD) is 1.4958.
The transparent substrate of Blu-ray disk (wavelength λ1=408 nm) has a thickness of 0.0875 mm and a refractive index of 1.6205. The transparent substrate of DVD (wavelength λ2=655 nm) has a thickness of 0.6 mm and a refractive index of 1.5794. The transparent substrate of CD (wavelength λ3=790 nm) has a thickness of 1.2 mm and a refractive index of 1.5725. Therefore, a difference in refractive index between Blu-ray disk (wavelength λ1=408 nm) and DVD (wavelength λ2=655 nm) is 0.03 or higher, and a difference in refractive index between Blu-ray disk (wavelength λ1=408 nm) and CD (wavelength λ3=790 nm) is also 0.03 or higher.
In Blu-ray disk with a wavelength of 408 nm, NA is 0.850 and a focal length is 2.3721 mm. In DVD with a wavelength of 655 nm, NA is 0.650 and a focal length is 2.4262 mm. In CD with a wavelength of 790 nm, NA is 0.510 and a focal length is 2.4378 mm. The aperture diameters are as shown in
In CD, a distance from the object surface to the objective lens is 19.35 mm, and divergent light is input to the objective lens. In the case of CD as well, a distance from an emission point of a CD laser to a surface apex of the objective lens in the light source side may be 19.35 mm in an actual optical system. In this case, however, an optical pickup becomes large.
It is preferred in this case to place the collimator lens between the CD laser light source and the objective lens, and places the emission point of the CD laser in the position closer to the collimator lens than the focal position of the collimator lens. In this arrangement, the light emitted from the CD laser and having passed through the collimator lens becomes divergent light and enters the objective lens. The collimator lens and the CD laser are preferably arranged so that the incident light to the objective lens becomes the same as the light emitted from a distance of 19.35 mm without collimator lens.
In the fourth embodiment shown in
Therefore,
408 nm(λ1)<790 nm(λ3).
Further,
(1/S1)=(1/∞)=0,
(1/S3)=(1/19.35)=0.05168
Therefore,
0<0.05168; (1/S1)<(1/S3)
Hence, in Blu-ray and CD, λ1<λ3 and (1/S1)<(1/S3) are both satisfied.
Further, since
655 nm(λ2)<790 nm(λ3)
and
(1/S2)=(1/∞)=0,
(1/S3)=(1/19.35)=0.05168.
Therefore,
0<0.05168; (1/S2)<(1/S3).
Hence, in DVD and CD, λ2<λ3 and (1/S2)<(1/S3) are both satisfied.
As shown in
However, the light with the wavelength of 655 nm (DVD) passes though the Blu-ray exclusive use area with the wavelength selective filter. Therefore, the incident laser beam enters DVD and it becomes flare light having extremely high aberration on the information recording surface of DVD, which does not have any harmful effect.
Though the wavelengths of one monochromatic light are 408 nm, 655 nm and 790 nm in the fourth embodiment, they may be 380 to 430 nm, 630 to 680 nm and 770 to 820 nm, respectively. While the refractive index differs in this case, it may be designed in accordance with the value.
As described in the foregoing, the fourth embodiment forms the objective lens of NA=0.85 with the material mainly composed of glass with the refractive index of 1.49 to 1.70 for the light of 408 nm. Since material with a low melting point of about 300° C., for example, can be used as the low-refractive index material, it is possible to produce the lens with a normal die and thereby increase productivity.
Fifth Embodiment
On the other hand, the 16-layer coating causes high costs due to a large number of coats.
The wavelength selective filter preferably has a transmittance of 10% or lower for a CD wavelength (770 to 800 nm). A more preferable transmittance is 5% or lower, and the most preferable transmittance is 2% or lower.
Further, the wavelength selective filter preferably has a transmittance of 85% or higher for Blu-ray and DVD wavelength (380 to 700 nm). A more preferable transmittance is 90% or higher, and the most preferable transmittance is 95% or lower.
Though the wavelength selective filter shown in FIGS. 39 to 42 is formed on a glass substrate, separated from an objective lens, it may be coated on one side of the objective lens. In this case, it is preferably coated on an almost flat surface of the objective lens facing to the disk. This allows easy formation of a uniform film. Further, if the refractive index of the wavelength selective filter and the refractive index of the objective lens are substantially equal, it is possible to achieve the similar design to the coating design in the embodiment shown in FIGS. 39 to 42, which facilitates manufacturing. In this embodiment, the refractive index of the objective lens such as plastic is 1.54 to 1.55, and the refractive index of BK7 is 1.51; therefore, the both refractive indexes are substantially the same. The refractive index of the wavelength selective filter is preferably within the range of 0.9 to 1.1 with respect to the refractive index of the objective lens.
Sixth EmbodimentA sixth embodiment of the invention is described hereinafter with reference to the drawings. This embodiment describes an objective lens that focuses laser light on an optical recording medium as an optical component included in an optical pickup device. The optical pickup device is compatible with CD, DVD, and Blu-ray disk. The optical component is not limited to the objective lens, and it is possible to achieve an effect of the invention if it is an optical member through which light with three kinds of wavelength regions pass.
An antireflection coating used in this invention is composed of layers with a high refractive index and layers with a low refractive index laminated on one another on an optical component. Material of the layer with a high refractive index is at least one selected from oxides such as aluminum oxide, zirconium oxide, titanium oxide, tantalum oxide, niobium oxide, antimonyoxide, cerium oxide, yttrium oxide, hafnium oxide and magnesium oxide, nitrides such as silicon nitride and germanium nitride, carbides such as silicon carbide, sulfides such as zinc sulfide, and mixed material of these. Material of the layer with a low refractive index is at least one selected from silicon oxide, fluorides such as magnesium fluoride, aluminum fluoride, barium fluoride, calcium fluoride, lithium fluoride, sodium fluoride, strontium fluoride, yttrium fluoride, chiolite and cryorite, and mixed material of these. It is preferred to use oxide, nitride, carbide and fluoride to obtain high retention characteristics under a high temperature and high humidity environment.
The antireflection coating of this invention is formed by vacuum deposition, for example. In the vacuum deposition process, various deposition techniques such as vacuum evaporation, sputtering, chemical vapor deposition, reservation, and so on. When performing the vacuum evaporation, it is effective to ionize part of vapor flow in order to improve the film property and use ion plating that applies bias to a substrate, cluster ion beam, and ion assisted deposition that applies ion to a substrate with ion gun. The sputtering involves DC reactive sputtering, RF sputtering, ion beam sputtering, and so on. The chemical vapor deposition involves plasma polymerization, light assisted deposition, thermal decomposition, organic metal chemical vapor deposition, and so on. It is possible to create a desired film thickness by adjusting a deposition time during film formation and so on.
The optical component may be composed of any optical material that is transparent in a use band, including plastic such as polyolefin resin, cycloolefin resin, methacrylic resin and polycarbonate resin, optical glass such as quartz glass and borosilicate glass, oxide single crystal or polycrystal substrate such as Al2O3 and MgO, fluoride single crystal or polycrystal substrate such as CaF2, MgF2, BaF2 and LiF, chlorides such as NaCl, KBr and KCl, and bromide single crystal or polycrystal substrate. The principle of the effect of the antireflection coating is described hereinafter with reference to
Reflected light R when light O is incident on the objective lens 1 is described below. Though
Though some light enters the objective lens 1 without becoming the reflected light R3 at the boundary between the high refractive index layer 8 and the objective lens 1, the description is omitted since it is not necessary to describe the reflected light R. Further, though the reflected light R2 includes component that is multiply reflected at a reflectance of about 5% on the upper and lower boundaries of the low refractive index layer 7, and the reflected light R3 includes component that is multiply reflected at a reflectance of about 5% on the upper and lower boundaries of the high refractive index layer. However, the intensity of the light of these components becomes as low as 0.25% or below after being reflected twice or more, and the description is also omitted here.
The reflected light R is synthesized light of the reflected light R1 to R3 shown in
The basic principal is as follows. For example, the optical film thickness of the low refractive index layer 7 is one-fourth of the wavelength of the light O. In this case, the phase difference between the reflected light R1 and R2 corresponds to one-half the wavelength of the light O, and therefore the reflected light R1 and R2 cancel out each other. As a result, only the reflected light R3 becomes reflected light R. Thus, the light intensity ratio of the reflected light R3 with respect to the light O is reflectance in this wavelength region. On the other hand, if the wavelength of the light O is changed while keeping the conditions of the objective lens 1, the high refractive index layer 8 and the low refractive index layer 7, the reflected light R1 to R3 cancel out each other in some cases. The reflectance is low in this wavelength region.
Using this principle, if an antireflection coating that minimizes a reflectance in the vicinity of the wavelength region corresponding to the wavelength used for Blu-ray disk (about 405 nm) and in the vicinity of the wavelength region corresponding to the wavelength used for DVD (about 655 nm) while reducing a reflectance in the wavelength region corresponding to the wavelength used for CD (790 nm) is formed on the surface of the objective lens 1, it is possible to produce a high performance optical pickup apparatus compatible with the three kinds of optical media.
An example of simulation by setting the conditions for the objective lens 1, the high refractive index layer 8 and the low refractive index layer 7 based on the above principle is as follows. In the simulation and example described below, the film thickness dH of the high refractive index layer 8 and the film thickness dL of the low refractive index layer 7 are determined on the basis of one-fourth of a given wavelength (QW) . The given wavelength corresponds to the wavelength of the light O shown in
The table of
In
The inventers of the present invention have found the relationship between the values of ns, nH, and nL by analyzing nH where a gray cell appears in the tables of
Therefore, a minimum condition of optimal value of nH is: ns<nH≦nL*nL. The value of optimal nH existing in this range can be given by (a*ns+b*nL*nL)/2, where a and b are given constants. As a result of the simulations as shown in
Further, as shown in the table of
Specific examples are shown in consideration of these conditions. By depositing one of the three kinds of AR coats shown in the following examples 1, 2 and 3, it is possible to obtain relatively high transmittance characteristics in the three wavelengths described above. In addition, since the number of layers is as small as two, it is possible to provide the AR coating with relatively low costs.
On a lens having a refractive index of 1.53, a mixed material of Al2O3 (n=1.68) and ZrO2 (n=2.07) having a refractive index of 1.85 with the thickness of 135.1 nm (optical film thickness λ/2) and SiO2 having a refractive index of 1.46 with the thickness of 85.5 nm (optical film thickness λ/4) are coated. A reference wavelength of an AR coat optical film thickness is 500 nm.
EXAMPLE 2On a lens having a refractive index of 1.53, Y2O3 having a refractive index of 1.80 with the thickness of 139 nm (optical film thickness λ/2) and SiO2 having a refractive index of 1.46 with the thickness of 85.5 nm (optical film thickness λ/4) are coated. A reference wavelength of an AR coat optical film thickness is 500 nm.
EXAMPLE 3On a lens having a refractive index of 1.53, SiN having a refractive index of 2.04 with the thickness of 122.5 nm (optical film thickness λ/2) and SiO2 having a refractive index of 1.46 with the thickness of 85.5 nm (optical film thickness λ/4) are coated. A reference wavelength of an AR coat optical film thickness is 500 nm.
Examples shown in
As a comparative example, a case that is to be eliminated if nH is defined by a parameter A of this embodiment within a range defined as a two-layer antireflection coating.
As shown in
The optical characteristics of Examples and Comparative Examples are analyzed in further detail below.
The reflectance in λ3 mainly affects the standard deviation. As shown in the graphs of the reflectance corresponding to each wavelength in Examples 4 to 8 and Comparative Examples 1 to 3, the reflectance in λ1, and λ2 is relatively low in Comparative Example 1 and 2 as well. Thus, no problem occurs if it is used as an antireflection coating for two wavelengths. However, a change in reflectance is steep in the wavelength region of λ2 and λ3 in Comparative Examples 1 to 3, a reflectance in λ3 is high. Thus, analysis of standard deviation of reflectance in λ1 to λ3 allows verification of suitability. Further, use of a square sum as a determination value enables to reflect the effect of λ3 accurately.
The analytical result shown in
As described in the foregoing, the present invention can provide an antireflection coating which is composed of two layers and which makes reflectance low in three kinds of wavelength regions, and an optical pickup component.
Since the antireflection coating of this invention has a two-layer structure, it is possible to reduce a film coating deposition time compared to a film coating having a three of more layer structure, thereby reducing harmful effects such as thermal deformation of a deposition surface.
Particularly, it is effective to use a low malting glass with a low melting point and thermal deformation temperature (Tg=288° C. such as K-PG325 manufactured by SUMITA optical glass for the antireflection coating of this invention in order to prevent deformation of a lens surface when depositing a filmcoating. Further, the antireflection coating exerts its maximum effect when it is coated on both surfaces or one surface of a lens compatible with three wavelengths used in the first and the second embodiments of the invention.
By using the parameter A described in the above embodiments, it is possible to form a selection system of each member in a three wavelength antireflection coating compose of two layers. This system at least includes a condition input section, a calculation section, a result display section, a material storage section, and a control section. If the condition input section inputs one or two of ns, nH, nL, the calculation section calculates a suitable value for the rest of values based on the parameter A and the condition of nH-ns, and selects a suitable material from the materials stored in the material storage section. The control section executes these processing.
It is normally difficult to calculate suitable values for the rest of variables by specifying only one of three variables. However, with addition of the condition of selecting one from the material stored in the material storage section, it is possible to select suitable values for the remaining two variables by specifying one of thee variables.
As described above, the present invention can focus all light beams on a desired position with possibly lowest aberration, with NA necessary for recording or reproducing by refraction without using a diffraction lens structure, for three or more kinds of optical disks that record or reproduce data with different wavelengths.
Further, the lens of this invention is applicable to a multiwavelength optical system using a plurality of monochromatic light and an optical system using different wavelengths in optical communication or the like.
Optical Head Structure 1
In
The parallel light becomes convergent light in the collimator lens 16 and then reaches a light detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. After that, a system control circuit (not shown) controls an actuator drive circuit (not shown) to drive the actuators 181 and 182 so as to place the objective lens 1 in an appropriate focus position and tracking position based on the obtained focus error signal and tracking error signal.
When recording or reproducing the HDDVD disk 1, the Blue laser 11 is driven. A laser beam of the 405 nm wavelength generated in the Blue laser 11 transmits through the half prism 15. The transmitted laser beam enters the collimator lens 16 and becomes parallel light after transmitting through the collimator lens 16. The parallel light is then focused on an information recording surface of the HDDVD disk 1 at NA 0.65 to form an optical spot as is the case with the DVD described above.
The focused light reaches a light detector (not shown) A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. After that, a system control circuit (not shown) controls an actuator drive circuit (not shown) to drive the actuators 181 and 182 so as to place the objective lens 1 in an appropriate focus position and tracking position based on the obtained focus error signal and tracking error signal.
When recording or reproducing the CD disk 4, the CD laser 13 is driven. A laser beam of the 795 nm wavelength generated in the CD laser 13 transmits through the linear diffraction grating 14, is reflected by the half prism 17 and enters the wavelength selective filter 6. The inner side of the wavelength selective filter 6 is the entire light transmitting area 61, and the outer side lets the light passing through the inner side of the light shielding area 62 transmit through as shown in
The light reflected by the CD disk 4 becomes convergent light by the objective lens 1 and reaches a light detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. To obtain the tracking error signal for the CD disk 3, the laser beam from the CD laser 12 is separated into 0th order light and ±1st order light by the diffraction grating 18, thus obtaining the tracking error signal from the ±1st order light
Then, based on the focus error signal and tracking error signal thus obtained, the actuators 181 and 182 are driven so as to place the objective lens 1 in an appropriate focus position and tracking position.
Though the optical detector is not shown in
Further, since the CD light is finite, it is difficult to use the same detector as HDDVD and DVD in a normal optical arrangement and an optical detector for CD is required. Therefore, it is possible to place a diffraction grating that functions as a diffraction grating only for the wavelength of about 790 nm and allows the reflected light from the CD disk to enter the same optical detector as HDDVD and DVD, for example.
The collimator lens 16 is not always necessary, and the present invention is also applicable to an optical system of a so-called finite system. Further, it is possible to place a laser in a position farther away from a focal position of parallel light of the collimator lens 16 so as to makes incident light to the objective lens convergent light.
Optical Head Structure 2
In
The parallel light entering the objective lens 1 is the light with NA0.8 or higher. As shown in the second embodiment, the Blu-ray exclusive area exists in the outer area of the objective lens 1 in the light source side. Therefore, if DVD light of 655 nm is incident, the light transmitting through the Blu-ray exclusive use area becomes DVD flare, which does not contribute to image formation nor optical spot formation on the DVD disk. Therefore, the optical spot substantially equal to NA 0.60 is formed on the DVD disk 3.
The light reflected by the DVD disk 3 becomes parallel light by the objective lens 1 and enters the collimator lens 16. The collimator lens 16 changes the parallel light into convergent light and the light reaches an optical detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. After that, a system control circuit (not shown) controls an actuator drive circuit (not shown) to drive the actuators 181 and 182 so as to place the objective lens 1 in an appropriate focus position and tracking position based on the obtained focus error signal and tracking error signal.
When recording or reproducing the Blu-ray disk 1, the Blue laser 11 is driven. A laser beam of the 405 nm wavelength generated in the Blue laser 11 transmits through the half prism 15. The transmitted laser beam enters the collimator lens 16 and becomes parallel light after transmitting through the collimator lens 16. The parallel light is then focused on an information recording surface of the Blu-ray disk 1 at NA 0.65 to form an optical spot as is the case with the DVD described above.
The focused light reaches a light detector (not shown) A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. After that, a system control circuit (not shown) controls an actuator drive circuit (not shown) to drive the actuators 181 and 182 so as to place the objective lens 1 in an appropriate focus position and tracking position based on the obtained focus error signal and tracking error signal.
When recording or reproducing the CD disk 4, the CD laser 13 is driven. A laser beam of the 790 nm wavelength generated in the CD laser 13 transmits through the linear diffraction grating 14, is reflected by the half prism 17 and enters the wavelength selective filter 6. The inner side of the wavelength selective filter 6 is the entire light transmitting area 61, and the outer side lets the light passing through the inner side of the light shielding area 62 transmit through as shown in
The light reflected by the CD disk 4 becomes convergent light by the objective lens 1 and reaches a light detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. To obtain the tracking error signal for the CD disk 3, the laser beam from the CD laser 12 is separated into 0th order light and ±1st order light by the diffraction grating 18, thus obtaining the tracking error signal from the ±1st order light
Then, based on the focus error signal and tracking error signal thus obtained, the actuators 181 and 182 are driven so as to place the objective lens 1 in an appropriate focus position and tracking position.
Though the optical detector is not shown in
Further, since the CD light is finite, it is difficult to use the same detector as HDDVD and DVD in a normal optical arrangement, and thus an optical detector for CD is required. It is possible to place a diffraction grating that functions as a diffraction grating only for the wavelength of about 790 nm and allows the reflected light from the CD disk to enter the same optical detector as HDDVD and DVD, for example.
The collimator lens 16 is not always necessary, and the present invention is also applicable to an optical system of a so-called finite system. Further, it is possible to place a laser in a position farther away from a focal position of parallel light of the collimator lens 16 so as to makes incident light to the objective lens convergent light.
Optical Head Structure 3
In
The light with NA=0.65 or higher is incident on the objective lens 1. As shown in the third embodiment, the DVD exclusive area exists in the outer area of the objective lens 1 in the light source side. Therefore, if HDDVD light of 408 nm is incident, the light transmitting through the DVD exclusive use area becomes flare, which does not contribute to image formation nor optical spot formation on the HDDVD disk. Therefore, the optical spot substantially equal to NA 0.65 is formed on the HDDVD disk 2.
The light reflected by the HDDVD disk 2 becomes divergent light by the objective lens 1 and enters the collimator lens 16. The collimator lens 16 changes the divergent light into convergent light and output it to an optical detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. After that, a system control circuit (not shown) controls an actuator drive circuit (not shown) to drive the actuators 181 and 182 so as to place the objective lens 1 in an appropriate focus position and tracking position based on the obtained focus error signal and tracking error signal.
When recording or reproducing the DVD disk 3, the DVD laser 12 is driven. A laser beam of the 658 nm wavelength generated in the DVD laser 12 transmits through the half prism 15. The transmitted laser beam then enters the collimator lens 16. The laser beam becomes parallel light after passing through the collimator lens 16. After that, the light is focused at NA 0.65 on the information recording surface of the DVD disk 3 to form an optical spot as is the case with HDDVD.
The light reflected by the DVD disk 3 becomes parallel light by the objective lens 1 and enters the collimator lens 16. The collimator lens 16 changes the parallel light into convergent light and outputs it to an optical detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit. (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. After that, a system control circuit (not shown) controls an actuator drive circuit (not shown) to drive the actuators 181 and 182 so as to place the objective lens 1 in an appropriate focus position and tracking position based on the obtained focus error signal and tracking error signal.
When recording or reproducing the CD disk 4, the CD laser 13 is driven. A laser beam of the 785 nm wavelength generated in the CD laser 13 transmits through the linear diffraction grating 14, is reflected by the half prism 17 and enters the wavelength selective filter 6. The inner side of the wavelength selective filter 6 is the entire light transmitting area 61. Thus, the outer side lets the light passing through the inner side of the light shielding area 62 transmit through as shown in
The light reflected by the CD disk 4 becomes convergent light by the objective lens 1 and reaches a light detector (not shown). A detection output signal from the light detector is supplied to a signal processing circuit (not shown), thereby creating an information recording and reproducing signal, focus error signal, and tracking error signal. To obtain the tracking error signal for the CD disk 3, the laser beam from the CD laser 12 is separated into 0th order light and ±1st order light by the diffraction grating 18, thus obtaining the tracking error signal from the ±1st order light
Then, based on the focus error signal and tracking error signal thus obtained, the actuators 181 and 182 are driven so as to place the objective lens 1 in an appropriate focus position and tracking position, as is the case with the DVD disk 3.
Though the optical detector is not shown in
Further, the present invention is applicable to the lens structure where convergent light for HDDVD, convergent light for DVD, and divergent light for CD, are respectively incident. If the object distance of HDDVD and DVD is the same, it is possible to use the same optical detector for HDDVD and DVD.
Optical Disk Apparatus Structure
First, the disk distinguishing means 24 distinguishes a type of a disk loaded. Among methods for distinguishing the disk are a method detecting the thickness of the disk substrate optically or mechanically and a method detecting a reference mark preciously stored in the disk or a disk cartridge. Or, there is also a method reproducing disk signals with tentative disk thickness and type, and judging that it is a disk of another thickness and type if normal signals are not obtained. The disk distinguishing means 24 then transmits the result to the system control circuit 23.
When the result shows that the disk is a DVD disk, the system control circuit 23 transmits a signal for lighting the DVD laser 11 to the laser drive circuit 22, and the DVD laser 11 lights by the laser drive circuit 22. Thus, in an optical head, the laser beam having the 655 nm wavelength reaches the light detector 17, as is the embodiment shown in
The system control circuit 23 controls the actuator drive circuit 20 based on the focus error signal and tracking error signal. The actuator drive circuit 20 drives the actuator 19 by this control to move the objective lens 1 in the focus direction and tracking direction, which is called a servo circuit operation. By this operation, the focus control and tracking control are regularly processed, and the above circuits and the actuators 181 and 182 operate to arrange the object lens 1 in a right position to the DVD disk 3, thus suitably obtaining the information recording and reproducing signals.
On the other hand, when the result shows that the disk loaded is the CD disk 4, the system control circuit 23 transmits a signal for lighting the CD laser 13 to the laser drive circuit 22. The CD laser 13 thus generates the laser beam having a 790 nm wavelength. The subsequent operations are the same as the case of the optical head shown in
When the result shows that the disk loaded is a Blue-ray or HDDVD disk, the system control circuit 23 transmits a signal for lighting the Blue laser 11 to the laser drive circuit 22. The Blue laser 11 thus generates the laser beam having a 405 nm wavelength. The subsequent operations are the same as the case of the optical head shown in
As shown in
From the invention thus described, it will be obvious that the embodiments of the invention may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended for inclusion within the scope of the following claims.
Claims
1. An antireflection coating formed on a light transmitting surface of an optical component with a refractive index of ns used in an optical pickup device using at least two wavelengths of approximately 405 nm and 655 nm, the antireflection coating comprising two layers of:
- a high refractive index layer with a refractive index of nH and an optical coating thickness of nHdH formed on the optical component; and
- a low refractive index layer with a refractive index of nL, and an optical coating thickness of nLdL formed on the high refractive index layer,
- wherein a reflectance is lowest only in two regions of approximately 405 nm and 655 nm and highest in one region between the two lowest regions.
2. The antireflection coating of claim 1, wherein following conditions are satisfied: 0.9≦nH/A≦1.1, 0.1≦nH-ns, 225 ≦nHdH≦275 nm, 100 nm≦nLdL≦150 nm, where A=(1.21 *ns+0.84*nL*nL)/2.
3. The antireflection coating of claim 2, wherein a following condition is satisfied: nH-ns≦0.4.
4. The antireflection coating of claim 2, wherein a following condition is satisfied: 1.30≦nL≦1.55.
5. An antireflection coating formed on a light transmitting surface of an optical component with a refractive index of ns used in an optical pickup device using at least three wavelengths of approximately 405 nm, 655 nm, and 790 nm, the antireflection coating comprising two layers of:
- a high refractive index layer with a refractive index of nH and an optical coating thickness of nHdH formed on the optical component; and
- a low refractive index layer with a refractive index of nL, and an optical coating thickness of nLdL formed on the high refractive index layer,
- wherein a reflectance is lowest only in two regions of approximately 405 nm and 655 nm and highest in one region between the two lowest regions.
6. The antireflection coating of claim 5, wherein following conditions are satisfied: 0.9≦nH/A≦1.1, 0.1≦nH-ns, 225 nm≦nHdH≦275 nm, 100 nm≦nLdL≦150 nm, where A=(1.21*ns+0.84*nL*nL)/2.
7. The antireflection coating of claim 6, wherein a following condition is satisfied: nH-ns≦0.4.
8. The antireflection coating of claim 6, wherein a following condition is satisfied: 1.30≦nL≦1.55.
9. The antireflection coating of claim 5, wherein material of the low refractive index layer is silicon oxide or fluoride.
10. An optical component for an optical pickup, on which surface the antireflection coating of claim 5 is formed.
11. The optical component for an optical pickup of claim 10, wherein the optical component is made of material mainly composed of glass with a refractive index ns of 1.49 to 1.70 and a thermal deformation temperature of 300° C. or below.
12. An objective lens receiving light beams with wavelengths of approximately 405 nm, 655 nm and 790 nm for at least three kinds of optical recording media and having a positive power to focus each light beam on an information recording surface of a transparent substrate of each optical recording medium by refraction,
- wherein, if distances between points P1, P2, P3 where incident light beams or extension lines of incident light beams with wavelengths of approximately 405 nm, 655 nm and 790 nm to the objective lens cross an optical axis and a point Q where a lens surface of the objective lens located farther from each optical recording medium than another lens surface crosses the optical axis are expressed as S1, S2, S3, and signs of the distances S1, S2, S3, are defined as positive if positions of the points P1, P2, P3 are located in a different side from the optical recording medium with respect to the point Q, and defined as negative if the positions of the points P1, P2, P3 are located in the same side as the optical recording medium with respect to the point Q, an incident light beam satisfying following expressions enters the objective lens:
- (1/S1)<(1/S3), (1/S2)<(1/S3),
- each light beam is focused on the information recording surface with RMS wavefront aberration of 0.050 λRMS or below, and
- an antireflection coating having lowest reflectance values only in two regions of approximately 405 nm and 655 nm and a highest reflectance value in one region between the two lowest reflectance values is formed on at least one surface of two lens surfaces.
13. The objective lens of claim 12, wherein the antireflection coating comprises two layers of:
- a high refractive index layer with a refractive index of nH and an optical coating thickness of nHdH formed on an optical component; and
- a low refractive index layer with a refractive index of nL, and an optical coating thickness of nLdL formed on the high refractive index layer.
14. The objective lens of claim 13, wherein the antireflection coating satisfies following conditions: 0.9≦nH/A≦1.1, 0.1≦nH-ns, 225 nm≦nHdH≦275 nm, 100 nm≦nLdL≦150 nm, where A=(1.21*ns+0.84*nL*nL)/2.
15. An antireflection coating formed on a light transmitting surface of an optical component with a refractive index of ns used in an optical pickup device using at least three wavelengths of approximately 405 nm, 655 nm and 790 nm, comprising two layers of:
- a high refractive index layer with a refractive index of nH formed on the optical component; and
- a low refractive index layer with a refractive index of nL formed on the high refractive index layer,
- wherein following conditions are satisfied:
- 0.9≦nH/A≦1.1, 0.1≦nH-ns, where A=(1.21*ns+0.84*nL*nL)/2.
16. An optical component for an optical pickup, wherein the optical component is made of material mainly composed of glass with a refractive index of 1.49 to 1.70 and a thermal deformation temperature of 300° C. or below, and the optical component has an antireflection coating composed of two layers of a high refractive index layer with a refractive index of nH and an optical coating thickness of nHdH and a low refractive index layer with a refractive index of nL and an optical coating thickness of nLdL, and having lowest reflectance values only in two regions of approximately 405 nm and 655 nm and a highest reflectance value in one region between the two lowest reflectance values.
17. A method of manufacturing an optical component for an optical pickup, used in an optical pickup device using at least three wavelengths of approximately 405 nm, 655 nm and 790 nm and having a surface where an antireflection coating composed of a high refractive index layer and a low refractive index layer is formed, the method comprising:
- selecting material for the high refractive index layer and the low refractive index layer that satisfy following conditions:
- 0.9≦nH/A≦1.1, 0.1≦nH-ns, where A=(1.21*nS+0.84*nL*nL)/2
- when ns is a refractive index of the optical component, nH is a refractive index of the high refractive index layer, and nL is a refractive index of the low refractive index layer;
- forming the high refractive index layer with a refractive index of nH on the optical component; and
- forming the low refractive index layer with a refractive index of nL on the high refractive index layer.
18. The method of manufacturing an optical component for an optical pickup of claim 17, wherein the step of selecting material selects material so as to satisfy a condition of: nH-nS≦0.4.
19. The method of manufacturing an optical component for an optical pickup of claim 17, wherein the step of selecting material selects material so as to satisfy a condition of: 1.30≦nL≦1.55.
Type: Application
Filed: Jul 19, 2005
Publication Date: Jan 26, 2006
Applicant: Hitachi Maxell, Ltd. (Osaka)
Inventors: Yasuyuki Sugi (Ibaraki-shi), Yoshiaki Minakawa (Ibaraki-shi), Mitsuhiro Miyauchi (Ibaraki-shi), Koichiro Wakabayashi (Ibaraki-shi)
Application Number: 11/184,004
International Classification: G11B 7/00 (20060101);