Optical pickup apparatus

US 6,185,176 B1
Filed: 05/20/1998
Issued: 02/06/2001
Est. Priority Date: 05/22/1997
Status: Expired due to Fees

First Claim

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1. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:

a single light intensity detection device having a quarter-split light receiving surface;

two semiconductor lasers for emitting light beams of different wavelengths;

an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and

a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism.

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Abstract

An optical pickup apparatus which can be designed compact while having a plurality of semiconductor lasers. The optical pickup apparatus, which reads recorded information from an optical recording medium, comprises an optical system including light intensity detection element having a quarter-split light receiving surface, two semiconductor lasers for emitting light beams of different wavelengths, an objective lens for directing each of the light beams onto an optical recording medium to form a light spot on a recording surface, and a holographic optical element located between the quarter-split light receiving surface and the objective lens, whereby the holographic optical element eliminates coma aberration and spherical aberration of light beams launched from the two semiconductor lasers and traveled through the recording surface and the objective lens, thereby generating a predetermined amount of astigmatism. The holographic optical element further has a lens performance for converging light beams, launched from the two semiconductor lasers and traveled through the recording surface and the objective lens, onto the quarter-split light receiving surface.

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18 Claims

1. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism.
- View Dependent Claims (2, 3, 4)
- - 2. The optical pickup apparatus according to claim 1, wherein said holographic optical element further has a lens performance for converging a light beam, traveled through said recording surface and said objective lens, onto said quarter-split light receiving surface.
  - 3. The optical pickup apparatus according to claim 2, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface.
  - 4. The optical pickup apparatus according to claim 1, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface.

5. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface, and wherein the other one of said semiconductor lasers is located at such a position that said holographic optical element passes a light beam of a second wavelength launched from said other semiconductor laser, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said second wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface.

6. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface, and wherein the other one of said semiconductor lasers is located at such a position that said holographic optical element passes a light beam of a second wavelength launched from said other semiconductor laser, guides negative first-order diffraction light of said light beam to said objective lens, receives return light from a light spot on said recording surface, produced by said negative first-order diffraction light of said second wavelength, from said objective lens, diffracts said return light, and guides positive first-order diffraction light of said second wavelength, acquired by diffraction, to said quarter-split light receiving surface; and
  
  said optical system further includes an aberration correcting element, located between said holographic optical element and said objective lens, for passing said light beam of said second wavelength launched from said other semiconductor laser without acting on said light beam of said first wavelength, and guiding said light beam of said second wavelength to said objective lens while eliminating aberration from said light beam of said second wavelength.
- View Dependent Claims (7, 8)
- - 7. The optical pickup apparatus according to claim 6, wherein said aberration correcting element is a liquid crystal type aberration correcting element having transparent electrodes formed on inner surfaces of a pair of transparent glass substrates in a pattern corresponding to an aberration correcting wave surface, and a liquid crystal layer provided between said transparent electrodes, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.
  - 8. The optical pickup apparatus according to claim 6, wherein said aberration correcting element is an aberration correcting element of a non-linear optical material type having a transparent substrate of a wavelength-selectable non-linear optical material and an isotropic optical material, filled in recesses formed on said transparent substrate and having a pattern corresponding to an aberration correcting wave surface, and having a refractive index equal to a refractive index of extraordinary ray or a refractive index of ordinary ray of said non-linear optical material, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.

9. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface, and wherein the other one of said semiconductor lasers is located at such a position that said holographic optical element passes a light beam of a second wavelength launched from said other semiconductor laser, guides negative first-order diffraction light of said light beam to said objective lens, receives return light from a light spot on said recording surface, produced by said negative first-order diffraction light of said second wavelength, from said objective lens, diffracts said return light, and guides positive first-order diffraction light of said second wavelength, acquired by diffraction, to said quarter-split light receiving surface; and
  
  said optical system further includes a light-source side aberration correcting element, located between said other semiconductor laser and said holographic optical element, for passing said light beam of said second wavelength launched from said other semiconductor laser, giving said light beam of said second wavelength such aberration as to cancel aberration, which occurs at a time said light beam of said second wavelength passes said holographic optical element, and guiding said light beam of said second wavelength to said holographic optical element, thereby eliminating aberration from said light beam of said second wavelength having passed said holographic optical element.
- View Dependent Claims (10, 11)
- - 10. The optical pickup apparatus according to claim 9, wherein said aberration correcting element is a liquid crystal type aberration correcting element having transparent electrodes formed on inner surfaces of a pair of transparent glass substrates in a pattern corresponding to an aberration correcting wave surface, and a liquid crystal layer provided between said transparent electrodes, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.
  - 11. The optical pickup apparatus according to claim 9, wherein said aberration correcting element is an aberration correcting element of a non-linear optical material type having a transparent substrate of a wavelength-selectable non-linear optical material and an isotropic optical material, filled in recesses formed on said transparent substrate and having a pattern corresponding to an aberration correcting wave surface, and having a refractive index equal to a refractive index of extraordinary ray or a refractive index of ordinary ray of said non-linear optical material, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.

12. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface, and wherein said optical system further includes a second quarter-split light receiving surface; and
  
  the other one of said semiconductor lasers is located at such a position that said holographic optical element passes a light beam of a second wavelength launched from said other semiconductor laser, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said second wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said second quarter-split light receiving surface.

13. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface, and wherein said optical system further includes a second quarter-split light receiving surface; and
  
  the other one of said semiconductor lasers is located at such a position that said holographic optical element passes a light beam of a second wavelength launched from said other semiconductor laser, guides negative first-order diffraction light of said light beam to said objective lens, receives return light from a light spot on said recording surface, produced by said negative first-order diffraction light of said second wavelength, from said objective lens, diffracts said return light, and guides positive first-order diffraction light of said second wavelength, acquired by diffraction, to said second quarter-split light receiving surface; and
  
  said optical system further includes an aberration correcting element, located between said holographic optical element and said objective lens, for passing said light beam of said second wavelength launched from said other semiconductor laser without acting on said light beam of said first wavelength, and guiding said light beam of said second wavelength to said objective lens while eliminating aberration from said light beam of said second wavelength.
- View Dependent Claims (14, 15)
- - 14. The optical pickup apparatus according to claim 13, wherein said aberration correcting element is a liquid crystal type aberration correcting element having transparent electrodes formed on inner surfaces of a pair of transparent glass substrates in a pattern corresponding to an aberration correcting wave surface, and a liquid crystal layer provided between said transparent electrodes, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.
  - 15. The optical pickup apparatus according to claim 13, wherein said aberration correcting element is an aberration correcting element of a non-linear optical material type having a transparent substrate of a wavelength-selectable non-linear optical material and an isotropic optical material, filled in recesses formed on said transparent substrate and having a pattern corresponding to an aberration correcting wave surface, and having a refractive index equal to a refractive index of extraordinary ray or a refractive index of ordinary ray of said non-linear optical material, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.

16. An optical pickup apparatus for reading recorded information from an optical recording medium, said optical pickup apparatus including an optical system which comprises:
- a single light intensity detection device having a quarter-split light receiving surface;
  
  two semiconductor lasers for emitting light beams of different wavelengths;
  
  an objective lens for directing each of said light beams onto an optical recording medium to form a light spot on a recording surface; and
  
  a holographic optical element located between said quarter-split light receiving surface and said objective lens, wherein said holographic optical element is operative to eliminate coma aberration and spherical aberration of a light beam traveled through said recording surface and said objective lens, thereby generating a predetermined amount of astigmatism, wherein said holographic optical element passes a light beam of a first wavelength launched from one of said semiconductor lasers, guides zero-order diffraction light of said light beam to said objective lens, diffracts said zero-order diffraction light of said first wavelength traveled through said recording surface, and guides positive first-order diffraction light, acquired by diffraction, to said quarter-split light receiving surface, and wherein said optical system further includes a second quarter-split light receiving surface;
  
  the other one of said semiconductor lasers is located at such a position that said holographic optical element passes a light beam of a second wavelength launched from said other semiconductor laser, guides negative first-order diffraction light of said light beam to said objective lens, receives return light from a light spot on said recording surface, produced by said negative first-order diffraction light of said second wavelength, from said objective lens, diffracts said return light, and guides positive first-order diffraction light of said second wavelength, acquired by diffraction, to said second quarter-split light receiving surface; and
  
  said optical system further includes a light-source side aberration correcting element, located between said other semiconductor laser and said holographic optical element, for passing said light beam of said second wavelength launched from said other semiconductor laser, giving said light beam of said second wavelength such aberration as to cancel aberration, which occurs at a time said light beam of said second wavelength passes said holographic optical element, and guiding said light beam of said second wavelength to said holographic optical element, thereby eliminating aberration from said light beam of said second wavelength having passed said holographic optical element.
- View Dependent Claims (17, 18)
- - 17. The optical pickup apparatus according to claim 16, wherein said aberration correcting element is a liquid crystal type aberration correcting element having transparent electrodes formed on inner surfaces of a pair of transparent glass substrates in a pattern corresponding to an aberration correcting wave surface, and a liquid crystal layer provided between said transparent electrodes, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.
  - 18. The optical pickup apparatus according to claim 16, wherein said aberration correcting element is an aberration correcting element of a non-linear optical material type having a transparent substrate of a wavelength-selectable non-linear optical material and an isotropic optical material, filled in recesses formed on said transparent substrate and having a pattern corresponding to an aberration correcting wave surface, and having a refractive index equal to a refractive index of extraordinary ray or a refractive index of ordinary ray of said non-linear optical material, and can be enabled or disabled selectively by applying a voltage to said transparent electrodes in association with switching between said semiconductor lasers.

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Current Assignee
Pioneer Electronics (USA) Incorporated (Pioneer Corporation)
Original Assignee
Pioneer Electronics (USA) Incorporated (Pioneer Corporation)
Inventors
Sugiura, Satoshi, Tachibana, Akihiro, Kubota, Yoshihisa
Primary Examiner(s)
EDUN, MUHAMMAD N

Application Number

US09/081,801
Time in Patent Office

993 Days
Field of Search

369/112, 369/103, 369/109, 369/100, 369/44.11, 369/44.12, 369/44.14, 359/562, 359/569, 359/573
US Class Current

369/112.1
CPC Class Codes

G11B 2007/0006   adapted for scanning differ...

G11B 2007/13727   Compound lenses, i.e. two o...

G11B 7/0901   for track following only G1...

G11B 7/0909   by astigmatic methods

G11B 7/123   Integrated head arrangement...

G11B 7/1353   Diffractive elements, e.g. ...

Optical pickup apparatus

First Claim

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Abstract

23 Citations

18 Claims

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Optical pickup apparatus

First Claim

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Abstract

23 Citations

18 Claims

Specification

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