TH22909C3 - Objective lens for optical pickups - Google Patents

Abstract

DC60 (06/07/60) objective lens, including refractive lens. Which has positive refracting power and a diffraction lens structure with a number of concentric ring-shaped segments. Which will be formed on at least one lens surface Of refracted lenses The objective lens is a double-sided convex plastic lens. Which has a somewhat deviated surface The first sphere and the two diffraction lens structures. Will be formed on the first surface of the objective lens The diffraction lens structure is similar to that of a Fresnel lens. It will be formed by the retrospective section. There are many cohorts, each of which has a wedge-shaped section. The edges between the loops that are closer to each other will It has been formed as a step in which the path difference is pre-determined. Lens structure Diffraction has a wavelength, which is the same as that At least two beams, which are Different wave lengths with exactly the same diffraction rank will produce a wavefront that They are suitable for at least two types of log plates. In which each record plate has a layer Cover with different thickness Lenses close to the object, including refractive lenses, have positive refractive power. And a diffraction lens structure with a number of concentric ring-shaped segments This has been formed on at least one surface of the refracted lens. An objective lens is a double-sided convex plastic lens with a first and second spherical distortion surface.A diffraction lens structure is formed on the first surface of the objective lens. The top turning lens structure is similar to that of a fresnel lens. It is formed by numerous co-axial rings, each having a wedge-shaped section. The edges between the adjacent rings are step-formed, where the optical path difference is pre-determined. The diffraction lens structure has a wavelength. They are dependent in such a way that at least two light beams of different wavelengths with exactly the same diffraction rank. Will produce a wave face suitable for at least two optical recording discs. Each optical log plate has a covering layer of different thickness.

Claims (9)

1. Objective lens for optical heads Which includes: a refractive lens having positive refractive power; and A diffraction structure, which contains a number of co-axial annular segments. It has been formed on the surface of at least one such refracted lens surface. Here, the diffraction lens structure is wavelength dependent in the way that at least two light beams of different wavelengths are With the same order of diffraction This will produce a wave face suitable for at least two optical recording discs, respectively. Which provides a cover layer of different thickness 2. Objective lenses according to claim 1, herein the diffraction lens structure has wavelengths which are independent in such a way that The light diffuses over the first wave lengths to produce the optimum waveform for the thinner shield optical plates. And the second diffraction produces a suitable wave face for the optical disc with a thicker layer. The first wavelength is shorter than the second wavelength. 3. Objective lens according to claim 1, herein the diffraction lens structure is condition dependent on the said wavelength in such a way that Spherical aberration will vary in the direction that is corrected less than normal. While the incident light wavelength increases 4. Objective lens according to claim 1, where condition (1) is hereby met; (Formula) where h45 is the height from the optical axis of the point where the light rays, where NA is 0.45 intersects with the diffraction lens structure, is the wavelength of that light and P2 is the second coefficient When the optical path length is added by the lens structure, diffraction is represented by the following optical path difference function (h): (formula) where P4 and P6 are the coefficients of the sequence. The fourth and sixth and h are the heights from the optical axis 5. Objective lens according to claim 1, wherein the aforementioned refractive lens and the aforementioned diffraction lens structure Will have all the longitudinal aberrations in such a way that The rear focus increases while the wavelength of the incident light increases. And the following (2) conditions have been fulfilled; (Formula) where CA is the almost parallel motion of the focal point. With wavelength displacement and SA is the spherical aberration variation for lateral rays. With the displacement of that wavelength 6. Objective lens according to claim 1, wherein the diffraction lens structure is almost parallel. And the following (3) conditions shall be fulfilled; (Formula) where f is the total focal length of that objective lens at the aforementioned shorter wavelength and fD is the focal length of the diffraction lens structure at the aforementioned shorter wavelength, which is to be equated with The following (formula) where P2 is the second order coefficient. When the complementary path length added by the diffraction lens structure is represented by the following optical path difference function (h): (formula) where P4 and P6 are the coefficients of The fourth and sixth division and h are the height from the optical axis and the incident light wavelength. 7. Objective lenses according to claim 1, herein the diffraction lens structure is designed to comply with the following condition (4); (Formula) where 1 is the wavelength of light for that optical log plate. Whose cover layer is 0.6 mm and 2 is the wavelength of the light for the disk. Which has a covered layer of 1.2 mm. 8. Close-object lens according to claim 7, wherein the radiating wavelength B of the diffraction lens structure The central region around the optical axis corresponds to the condition that 1 <B <2 p 1 1. Objective lens according to claim 1, wherein the surrounding area of the lens surface under which the lens structure is formed. Turn on this, such It is a continuous surface without a step.The periphery is defined as a region where the height from the optical axis is in the range of 85% to 100% of the radius of the refracted lens <1 0. Objective lens according to claim 8, wherein the radiating wavelength of the aforementioned diffraction lens structure In the periphery is shorter than the radiating wavelength B of the aforementioned diffraction lens structure in that central region (formula). 9. Lens near object according to claim 8, wherein the radiating wavelength B of such diffraction lens structure In the central region around the optical axis Will satisfy the following conditions (5) and (6);>