Claims
- 1. A refractive index distribution lens comprising:
- a first surface defined by a convex-spherical surface with a vertex, said first surface lying on the object side when said lens is used to provide negative magnification;
- a second surface defined by a flat surface, said second surface lying on the image side when said lens is used to provide negative magnification; and
- a refractive index distribution formed in the interior of said lens, said refractive index distribution having a sphere-symmetrical distribution about a point in the vicinity of the vertex of said first surface.
- 2. An image-forming lens according to claim 1, wherein, when said refractive index distribution is designated by N (.rho.); the distance from said point is designated by .rho.; and the focal length and the thickness of said lens designated by f and d, respectively, the following formulae are satisfied: ##EQU1## where N.sub.0, N.sub.1, N.sub.2. . . are refractive index distribution coefficients N.sub.0 being a refractive index in the vicinity of said point.
- 3. A refractive index distribution lens comprising:
- a first surface defined by a convex-spherical surface with a vertex;
- a second surface defined by a flat surface; and
- a refractive index distribution formed in the interior of said lens, said refractive index distribution having a sphere-symmetrical about a point in the vicinity of the vertex of said first surface, wherein said first surface is disposed on the light source side when said lens is used as an objective lens, and said second surface is disposed on the light source side when said lens is used as a collimator lens.
- 4. A refractive index distribution lens according to claim 3, wherein said refractive index distribution N(.rho.), the distance .rho. from said point, and the refractive index N.sub.0 of the portion of said lens in the vicinity of said point meet the following conditions: ##EQU2## and
- 1. 56<N.sub.0 <1.63.
- 5. A refractive index distribution lens according to claim 4, wherein the focal distance f of said lens and the thickness d of said lens as measured on the optical axis meet the following conditions:
- 0.35<d/f<0.60
- 6. A refractive index distribution lens according to claim 5, wherein the following condition is further met:
- -0.25<N.sub.1 f.sup.2 <-0.20
- 7. A refractive index distribution lens according to claim 3, wherein the focal distance f of said lens and the thickness d of said lens as measured on the optical axis meet the following condition:
- 0.35<d/f<0.60
- 8. A refractive index distribution lens according to claim 3, wherein said refractive index distribution N(.rho.); the distance .rho. from said point, the refractive index N.sub.0 of the portion of said lens in the vicinity of said point and the focal distance f of said lens meet the following conditions: ##EQU3## and
- 0. 25<N.sub.1 f .sup.2 <-0.20.
- 9. A refractive index distribution lens according to claim 8, wherein the following condition is further met:
- 1.56<N.sub.o .ltoreq.1.63
- 10. A refractive index distribution lens according to claim 8, wherein the following condition is further met:
- 0.35<d/f<0.60
- where d represents the thickness of said lens as measured on the optical axis of said lens.
- 11. A refractive index distribution lens for focusing a laser beam on a recording surface through a transparent layer formed thereon, comprising:
- a first surface defined by a convex-spherical surface with a vertex;
- a second surface defined by a flat surface, said second surface lying on the side of said recording surface; and
- a refractive index distribution formed in the interior of said lens, said refractive index distribution having a sphere-symmetrical distribution about a point in the vicinity of the vertex of said first surface, wherein when said refractive index distribution is designated by N(.rho.); the distance from said point designated by .rho.; and the focal length and the thickness of said lens designated by f and d, respectively, the following formulae are satisfied: ##EQU4## where N.sub.0 N.sub.1 N.sub.2 . . . are refractive index distribution coefficients, N.sub.0 being a refractive index in the vicinity of said point.
- 12. A refractive index distribution lens according to claim 11, wherein the following inequality is also satisfied:
- 0.03<t/f<0.50
- where t is the thickness of said transparent layer.
- 13. A refractive index distribution lens for collimating a laser beam from a semiconductor laser having a cover glass, comprising:
- a first surface defined by a convex-spherical surface with a vertex;
- a second surface defined by a flat surface, said second surface lying on the side of said semiconductor laser; and
- a refractive index distribution formed in the interior of said lens, said refractive index distribution having a sphere-symmetrical distribution about a point in the vicinity of the vertex of said first surface, wherein when said refractive index distribution is designated by N(.rho.); the distance from said point designated by .rho.; and the focal length and the thickness of said lens designated by f and d, respectively, the following formulae are satisfied: ##EQU5## where N.sub.0, N.sub.1, N.sub.2 . . . are refractive index distribution coefficients, N.sub.0 being a refractive index in the vicinity of said point.
- 14. A refractive index distribution lens according to claim 13, wherein the following inequality is also satisfied:
- 0.03<t/f<0.50
- where t is the thickness of said cover glass.
Priority Claims (1)
Number |
Date |
Country |
Kind |
60-263078 |
Nov 1985 |
JPX |
|
Parent Case Info
This application is a continuation of application Ser. No. 07/129,368 filed Nov. 30, 1987, now abandoned; which is a continuation of application Ser. No. 06/927,869 filed Nov. 7, 1986, now abandoned.
US Referenced Citations (16)
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Non-Patent Literature Citations (1)
Entry |
Yamamoto, et al., Selfoc Microlens with a Spherical Surface, vol. 1, No. 6, Applied Optics (Mar. 15, 1982). |
Continuations (2)
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Number |
Date |
Country |
Parent |
129368 |
Nov 1987 |
|
Parent |
927869 |
Nov 1986 |
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