RU98102710A - OPTICAL SENSOR (OPTIONS), LENS (OPTIONS) AND OPTICAL ADAPTER DEVICE (OPTIONS) - Google Patents

Claims (63)

1. An optical sensor in an optical device compatible with a plurality of optical recording media of various thicknesses, comprising: a light source for emitting a light beam; a lens for focusing the light beam emitted from the light source into a single light spot on the surface of the information recording of one of the many optical recording media; and a photocell for detecting a light beam transmitted through the lens after reflection from the surface of the information recording of one of the plurality of recording media on which the light spot is focused, characterized in that the lens has an inner zone, an annular lens area and an outer zone centered at the apex, and the lens area has an annular shape and separates the inner zone from the outer zone; and the inner zone, the annular lens zone and the outer zone have aspherical surface shapes to focus the light beam passing through the inner zone and the outer zone into a single light spot by which information is read from the information recording surface of one optical recording medium, and to scatter light passing through the annular lens area formed between the inner zone and the outer zone, so that this scattered light does not focus on the surface of the information record, if this one optical recording medium is the first optical recording medium with a first thickness, and in order to focus the light transmitted through the inner zone and the annular lens area into a single light spot by which information is read from the surface of the information recording of one optical recording medium, and to scatter light, passed through the outer zone so that this scattered light does not focus on the surface of the information record of one optical recording medium, if this one optical recording medium si is a second optical recording medium with a second thickness greater than the first thickness.  2. The optical sensor according to claim 1, characterized in that the lens has such a working distance that the light transmitted through the inner zone is focused into a single light spot with minimal optical distortion on the surface of the information record of the second optical recording medium during playback of the second optical medium .  3. The optical sensor according to claim 2, characterized in that the aspherical shape of the surface of the inner zone with said working distance is such that the light transmitted through the inner zone is focused into a single light spot on the surface of the information record of the first optical recording medium during playback of the first optical media, and the same light is focused into the optical spot with minimal optical distortion on the surface of the information recording of the second optical recording medium during playback of an optical carrier.  4. The optical sensor according to claim 2, characterized in that the aspherical surface shape of the annular lens area is such that the light transmitted through the annular lens area is focused into a single light spot without spherical distortion on the surface of the information recording of the second optical recording medium in playback time of the second optical medium with a thick substrate. 5. The optical sensor according to claim 2, characterized in that the difference ΔZ between the focal length of the annular lens area and the focal length of the inner zone becomes the defocus value determined by the following relation:
ΔZ = - (2W ₄₀ ) / (NA) ² ,
where NA is the numerical aperture in the inner zone, and W ₄₀ is the spherical distortion coefficient that the inner zone has during the reproduction of the second optical recording medium.  6. The optical sensor according to claim 1, characterized in that the numerical aperture of the inner zone stores a value of at least 0.3 as a minimum.  7. The optical sensor according to claim 1, characterized in that the annular lens area of the lens has such a numerical aperture that the inner zone and the annular lens area form a single light spot on the surface of the information record of the second optical recording medium during playback of information from the second optical medium.  8. The optical sensor according to claim 1, characterized in that the inner zone, the annular lens area and the outer zone are formed on the lens surface of the lens from the side of the lens facing the light source.  9. The optical sensor according to claim 8, characterized in that the imaginary surface continuing the aspherical surface of the annular lens area is allocated from the top of the aspherical surface of the inner zone.  10. The optical sensor according to claim 8, characterized in that the width of the annular lens area lies between about 100 and about 300 microns.  11. The optical sensor according to claim 10, characterized in that the surface area of the annular lens area is at least 10% of the surface of the lens onto which the light beam from the light source is incident.  12. The optical sensor according to claim 1, characterized in that it further comprises at least one additional light source, each of the light source and at least one additional light source emitting light beams with different wavelengths.  13. The optical sensor according to claim 12, characterized in that it further comprises a beam splitter with a beam splitting characteristic with respect to each of the plurality of beams respectively emitted from the light source and at least one additional light source.  14. The optical sensor according to claim 1, characterized in that the first optical recording medium is a digital multilateral disk (DMSC), and the second optical recording medium is one of a compact disk (CD) and a laser disk (LD), when said the light source emits a light beam with a wavelength that is used for digital multilateral disk (DMSC).  15. The optical sensor according to claim 1, characterized in that it further comprises at least one additional light source, wherein the first optical recording medium is a digital multilateral disk (DMSC), and the second optical recording medium is one of a compact -drive (CD), recordable compact disc (CD), rewritable compact disc (PCD) and laser disc (LD), when the first of the light sources emitting light beams has a wavelength that is used for digital multilateral disc (CM D) and the second light source has a wavelength which is used for recordable compact discs (ZKD).  16. The optical sensor according to claim 1, characterized in that the photocell is the only detector used to detect the light beam as optical information from the first and second optical recording media when at least two of the plurality of light sources and the first and second optical recording media are reproduced compatible.  17. The optical sensor according to claim 1, characterized in that the lens has a difference, which is formed in the area where the annular lens area and the inner zone are in contact with each other, and this difference leads to the fact that the difference in light paths between the light beam transmitted through the inner zone of the said lens, and the light beam passing through the annular lens zone has an integer multiple of the wavelengths of light emitted from the light source during the reproduction of information from the second optical recording medium.  18. The optical sensor according to claim 17, characterized in that the differential height is approximately 1.0-1.5 microns.  19. The optical sensor according to claim 1, characterized in that the lens has a difference, which is formed in the region where the annular lens area and the outer zone are in contact with each other, and this difference leads to the fact that the difference in light paths between the light beam transmitted through the inner zone of the lens, and the light beam passing through the annular lens zone has an integer multiple of the wavelengths of light emitted from the light source during the reproduction of information from the second optical recording medium.  20. A lens compatible with at least two substrates with correspondingly different thicknesses and surfaces of the information record that store information comprising: an inner zone, an annular lens area and an outer zone centered at the apex, the annular lens area has an annular shape and separates the inner zone from the outer zone, characterized in that the inner zone, the annular lens area and the outer zone have aspherical surface shapes to focus light transmitted through the inner zone and the outer y into a single light spot by which information is read from the surface of the information record of the first of at least two substrates, which has a first thickness, and in order to scatter light transmitted through the annular lens area formed between the inner zone and the outer zone, so that this scattered light does not focus on the surface of the information record of the first substrate, when this first substrate should be used, and in order to focus the light transmitted through the inner zone and the annular lens zone into units another light spot whereby information is read from the surface of the information record of the second of at least two substrates, which has a second thickness greater than the first thickness, and to scatter light transmitted through the outer zone so that this scattered light does not focus on the surface of the information record of the second substrate when this second substrate is to be used. 21. The lens according to claim 20, characterized in that the difference ΔZ between the focal length of the annular lens area and the focal length of the inner zone is the same as the defocus value, determined by the following ratio:
ΔZ = - (2W ₄₀ ) / (NA) ² ,
where NA is the numerical aperture in the inner zone, and W ₄₀ is the spherical distortion coefficient when the second substrate is to be used.  22. The lens according to p. 20, characterized in that it has a difference that forms in the area where the annular lens area and the inner zone are in contact with each other, and this difference leads to the fact that the difference in light paths between the light transmitted through the inner the area of the lens, and the light passing through the annular lens region, has an integer multiple of the wavelengths of the light beam emitted from the light source when the second substrate is to be used.  23. The lens according to claim 20, characterized in that it has a difference that forms in the area where the annular lens area and the outer zone are in contact with each other, and this difference leads to the fact that the difference in light paths between the light transmitted through the inner the area of the lens, and the light passing through the annular lens region, has an integer multiple of the wavelengths of the light beam emitted from the light source when the second substrate is to be used.  24. An optical sensor in an optical device that is compatible with disks of various thicknesses, containing a light source for emitting a light beam, a lens facing one of these disks, which is placed in an optical device, the lens having a light transmission area divided accordingly into an internal, annular lens and outer zones corresponding to the near axial zone, the intermediate axial zone and the far axial zone of the incident light, characterized in that the curvatures of the central and peripheral zones are optimized for one disk if the one disk has a first thickness and curvature of the annular region is optimized for the one disk if the one disk has a second thickness greater than the first thickness; a photo detector for detecting a light beam reflected from this single disk; a separation unit for separating the incident light beam transmitted from the light source from the reflected light beam reflected by one disk. 25. The optical sensor according to p. 24, characterized in that the inner zone has a value of NA numerical aperture, according to the following equation:
0.8λ ≈ spot size,
where λ is the wavelength of the light beam emitted from the light source, and the spot size is the size of the spot that forms on the same disk a light beam passing through the lens.  26. The optical sensor of claim 25, wherein the wavelength is 650 nm, and NA is at least 0.37.  27. The optical sensor according to claim 24, characterized in that the annular lens area has an aspherical surface shape by which this annular lens area corrects optical distortions of the light beam from the light source passing through the sensor in the focal position of the inner zone. 28. The optical sensor according to p. 27, characterized in that the lens has a defocus coefficient W ₂₀ that minimizes optical distortion, according to the following equation:
W ₂₀ = -W ₄₀ ,
where W ₄₀ is the coefficient of spherical distortion resulting from the difference between the first and second thicknesses. 29. The optical sensor according to p. 28, characterized in that the ΔZ value of the defocus of the lens follows the equation
ΔZ = - (2W ₄₀ ) / (NA) ² = -8.3 μm,
where NA is the numerical aperture of the inner zone.  30. The optical sensor according to claim 24, characterized in that the width of the annular lens area forms at least 10% of the incidence surface of the lens through which light from the light source passes.  31. The optical sensor according to claim 24, characterized in that the width of the annular lens area lies between about 100 and about 300 microns.  32. The optical sensor according to p. 24, characterized in that the surface of the annular lens area protrudes from the surface of the inner and outer zones.  33. The optical sensor according to p. 24, characterized in that the surface of the annular lens area is a recess in the surface of the inner and outer zones.  34. The optical sensor according to p. 24, characterized in that the surface of the annular lens area forms a difference with the surface of one of the inner and outer zones.  35. The optical sensor according to p. 34, characterized in that the surface of the annular lens area forms a difference with the surface of the inner zone, and this difference has such a value that the difference in light paths between the light passing through the inner zone and the light passing through the annular lens zone, is an integer multiple of the wavelengths of light emitted from the light source.  36. The optical sensor according to p. 34, characterized in that the surface of the annular lens zone forms a difference with the surface of the outer zone, and this difference has such a value that the difference in light paths between the light passing through the inner zone and the light passing through the annular lens zone, is an integer multiple of the wavelengths of light emitted from the light source.  37. The optical sensor according to claim 34, characterized in that it further comprises a collimating lens located in the linear path between the lens and the photocell, for collimating the incident light beam separated by the separation unit, and for transmitting the light beam reflected from one disk to the separation unit and a photocell lens for focusing the reflected light beam passing through the separation unit to the photodetector, wherein the separation unit is a beam splitter.  38. The optical sensor according to claim 24, characterized in that it further comprises a unit on which a light source and a photo detector are located next to each other, a separation unit, which is a holographic beam splitter, and a collimating lens for collimating the light beam passing through the holographic splitter beam from the light source, and for transmitting the reflected light beam from one disk to the holographic beam splitter, while the holographic beam splitter directs the reflected light beam to the photodetector Héctor.  39. The optical sensor according to claim 38, characterized in that it further comprises a quarter-wave plate located between the holographic beam splitter and the collimating lens.  40. The optical sensor according to claim 38, wherein the holographic beam splitter is a polarization hologram.  41. The optical sensor according to claim 34, characterized in that it further comprises a unit on which a light source and a photo detector are located next to each other, a separation unit that is a holographic beam splitter, and a collimating lens for collimating the light beam passing through the holographic splitter beam from the light source, and for transmitting the light beam reflected from one disk to the holographic beam splitter, while the holographic beam splitter directs the reflected light beam to the photode Héctor.  42. An optical adapter device in an optical device for reading information from an optical recording medium containing a first light source for emitting a first light beam, characterized in that a second light source for emitting a second light beam is provided, and at this time only one of the first and second light sources emit respectively the first or second light beams, and a lens for receiving one of the first and second light beams emitted from the corresponding first or second source in light, and for focusing one of the first and second light beams emitted to the optical recording medium, and transmitting the light beam reflected from the optical recording medium, as well as a photo detector for receiving a light beam reflected from the optical recording medium and passing through the lens, for reproduction of information.  43. The optical adapter device according to claim 42, wherein the first light source emits a first light beam if the optical recording medium has a first thickness and the second light source emits a second light beam if the optical recording medium has a second thickness greater than the first thickness.  44. The optical adapter device according to claim 42, wherein the first light beam has a first frequency, and the second light beam has a second frequency different from the first frequency.  45. The optical adapter device according to claim 43, wherein the first light beam has a first frequency, and the second light beam has a second frequency different from the first frequency.  46. The optical adapter device according to claim 42, wherein the lens is a single lens.  47. The optical adapter device according to claim 42, wherein the lens includes a light-transmitting region divided into inner, annular lens and outer zones, the curvatures of the central and peripheral zones being optimized for the optical recording medium if this optical recording medium has the first thickness, and the curvature of the annular zone is optimized for the optical recording medium if this optical recording medium has a second thickness greater than the first thickness.  48. The optical adapter device according to p. 42, characterized in that the lens includes a light transmitting region divided into inner, annular lens and outer zones, the curvatures of the central and peripheral zones being optimized for the optical recording medium if this optical recording medium has the first thickness, and the curvature of the annular zone is optimized for the optical recording medium if this optical recording medium has a second thickness.  49. The optical adapter device according to claim 47, characterized in that the surface of the annular lens area forms a difference with the surface of one of the inner and outer zones.  50. The optical adapter device according to p. 47, characterized in that the surface of the annular lens area forms a difference with the surface of one of the inner and outer zones.  51. The optical adapter device according to claim 42, characterized in that it further comprises a first beam splitter for transmitting the first light beam from the first light source and for reflecting the second light beam from the second light source, a second beam splitter for transmitting the first light beam transmitted through the first beam splitter, and the second light beam reflected by the first beam splitter, and a collimating lens for collimating the first light beam and the reflected second light beam passing through Ora beam splitter, and transmit the collimated light beam to the lens, said second beam splitter reflects the first and second light beams reflected from the optical recording medium.  52. The optical adapter device according to p. 49, characterized in that it further comprises: a first beam splitter for transmitting the first light beam from the first light source and for reflecting the second light beam from the second light source, a second beam splitter for transmitting the first light beam, passed through the first beam splitter, and the second light beam reflected by the first beam splitter, and a collimating lens for collimating the first light beam and the reflected second light beam transmitted through a second beam splitter, and transmitting the collimated light beam to the lens, the second beam splitter reflecting the first and second light beams reflected from the optical recording medium.  53. The optical adapter device according to claim 42, characterized in that it further comprises a first beam splitter for reflecting the first light beam from the first light source, a second beam splitter for transmitting the first light beam reflected by the first beam splitter and reflecting the second light beam, reflected by the first beam splitter and a collimating lens for collimating the first light beam and the reflected second light beam passing through the second beam splitter and transmitting collimated lights nth beam to the lens, the first and second beam splitters transmit the first and second light beams reflected from the optical recording medium to the photodetector.  54. The optical adapter device according to p. 49, characterized in that it further comprises a first beam splitter for reflecting the first light beam from the first light source, a second beam splitter for transmitting the first light beam reflected by the first beam splitter and reflecting the second light beam, reflected by the first beam splitter and a collimating lens for collimating the first light beam and the reflected second light beam passing through the second beam splitter and transmitting collimated lights nth beam to the lens, the first and second beam splitters transmit the first and second light beams reflected from the optical recording medium.  55. An optical adapter device in an optical device for reading information from an optical recording medium containing a first light source for emitting a first light beam, characterized in that a second light source for emitting a second light beam is provided, and at this time only one of the first and second light sources emit respectively the first or second light beams, and a lens for receiving one of the first and second light beams emitted from the corresponding first or second source in light, and for focusing one of the first and second light beams emitted to the optical recording medium and transmitting the light beam reflected from the optical recording medium, as well as a first photodetector for receiving the first light beam reflected from the optical recording medium and passing through the lens , to reproduce information; and a second photodetector for receiving a second light beam reflected from the optical recording medium and passing through the lens to reproduce information.  56. The optical adapter device according to claim 55, wherein the first light source emits a first light beam if the optical recording medium has a first thickness and the second light source emits a second light beam if the optical recording medium has a second thickness greater than the first thickness.  57. The optical adapter device according to claim 56, wherein the first light beam has a first frequency, and the second light beam has a second frequency different from the first frequency.  58. The optical adapter device according to claim 55, wherein the lens includes a light-transmitting region divided into inner, annular lens and outer zones, the curvatures of the central and peripheral zones being optimized for the optical recording medium if this optical recording medium has the first thickness, and the curvature of the annular zone is optimized for the optical recording medium if this optical recording medium has a second thickness greater than the first thickness.  59. The optical adapter device according to p. 58, characterized in that the surface of the annular lens area forms a difference with the surface of one of the inner and outer zones.  60. The optical adapter device according to claim 49, characterized in that it further comprises a beam splitter for transmitting the first light beam from the first light source and for reflecting the second light beam from the second light source, a collimating lens for collimating the first light beam passing through the beam splitter and a second light beam reflected by the second beam splitter and transmitting the collimated light beam to the lens, the beam splitter transmitting the first light beam reflected from the optical on the recording medium to the first photo detector and reflects the second light beam reflected from the optical recording medium to the second photodetector.  61. A lens for use in an optical device compatible with various types of optical storage media, having many parts with different optical characteristics, moreover, one part of the many parts of the lens focuses the light beam on one of the storage media, regardless of the type of optical storage medium, characterized in that many parts of the lens include a first part for focusing the light beam emitted from the light source on a single optical storage medium, regardless of the thickness th one optical memory medium; the second part for focusing the light beam emitted from the light source on one optical storage medium if the optical storage medium has a first predetermined thickness, and the third part for focusing the light beam emitted from the light source on one optical storage medium if the optical medium the memory has a second predetermined thickness, which is different from the first predetermined thickness, and the surface of the second part forms a difference with the surface of one of the first and third parts.  62. The optical sensor according to p. 61, characterized in that the surface of the second part forms a difference with the surface of the first part, and the difference is such that the difference in light paths between the light passing through the first part and the light passing through the second part, is an integer multiple of the wavelengths of the light beam emitted from the light source.  63. The optical sensor according to p. 61, characterized in that the surface of the second part forms a difference with the surface of the third part, and the difference is such that the difference in light paths between the light passing through the first part and the light passing through the second part, is an integer multiple of the wavelengths of the light beam emitted from the light source.