IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0511988
(2009-07-29)
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등록번호 |
US-8267925
(2012-09-18)
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발명자
/ 주소 |
- Raksi, Ferenc
- Buck, Jesse
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출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
1 인용 특허 :
30 |
초록
▼
An ophthalmic laser system includes a laser source, to generate a pulsed laser beam, an XY scanner, to receive the pulsed laser beam, and to output an XY-scanning beam, scanned in two directions essentially transverse to an optical axis, and a multi-functional Z scanner, to receive the XY-scanning b
An ophthalmic laser system includes a laser source, to generate a pulsed laser beam, an XY scanner, to receive the pulsed laser beam, and to output an XY-scanning beam, scanned in two directions essentially transverse to an optical axis, and a multi-functional Z scanner, to receive the XY-scanning beam, to output an XYZ-scanning beam, having a numerical aperture NA and a focal spot in a target region, and to modify the numerical aperture NA essentially independently from scanning a Z focal depth of the focal spot along the optical axis.
대표청구항
▼
1. An ophthalmic laser system, comprising: a laser source, to generate a pulsed laser beam;an XY scanner, to receive the pulsed laser beam; andto output an XY-scanning beam, scanned in two directions essentially transverse to an optical axis; anda multi-functional Z scanner, to receive the XY-scanni
1. An ophthalmic laser system, comprising: a laser source, to generate a pulsed laser beam;an XY scanner, to receive the pulsed laser beam; andto output an XY-scanning beam, scanned in two directions essentially transverse to an optical axis; anda multi-functional Z scanner, to receive the XY-scanning beam;to output an XYZ-scanning beam, having a numerical aperture NA and a focal spot in a target region; andto modify the numerical aperture NA essentially independently from scanning a Z focal depth of the focal spot along the optical axis. 2. The ophthalmic laser system of claim 1, wherein the Z scanner comprises: a first beam expander block;a movable beam expander block; anda secondary optical controller. 3. The ophthalmic laser system of claim 1, wherein: the outputted XYZ-scanning beam has a geometric aberration, a diffraction aberration, and a total aberration, equaling a sum of the geometric aberration and the diffraction aberration;the total aberration has an optimum as a function of the numerical aperture NA at an optimal numerical aperture NAopt(z) for a Z focal depth; andthe Z scanner is adjustable to modify the numerical aperture NA to the optimal numerical aperture NAopt(z) at the Z focal depth. 4. The laser system of claim 3, wherein: the optimal total aberration corresponds to an optimal aberration measure, whereinthe optimal aberration measure is a minimum of one of a focal spot radius rf, an RMS wavefront error ω, and a spherical aberration coefficient a40, or a maximum of a Strehl ratio S. 5. The ophthalmic laser system of claim 4, wherein: the optimal aberration measure corresponds to one of five reference points P1=(0,0), P2=(2,6), P3=(5,0), P4=(8,0), P5=(8,3) at locations (z, r), all in millimeters, at any azimuth angle φ, whereinz denotes a distance along the optical axis and r denotes the corresponding radial cylindrical coordinate, andthe (0,0) of the cylindrical coordinate system denotes a front and center point of the target region. 6. The ophthalmic laser system of claim 1, wherein: the outputted XYZ-scanning beam has a geometric aberration, a diffraction aberration, and a total aberration, equaling a sum of the geometric aberration and the diffraction aberration; andthe numerical aperture NA is adjustable to reduce, at a Z focal depth, the total aberration of the laser system by at least a P(MovableExpander) percentage relative to a total aberration of an analogous laser system having a Z scanner with a non-adjustable numerical aperture NA; whereinthe P(MovableExpander) percentage is one of 20%, 30%, 40%, and 50%. 7. The ophthalmic laser system of claim 6, wherein: the total aberration is characterized by an aberration measure, the aberration measure being one of a focal spot radius rf, an RMS wavefront error ω, and a spherical aberration coefficient a40. 8. The ophthalmic laser system of claim 6, wherein: the aberration measure corresponding to one of five reference points P1=(0,0), P2=(2,6), P3=(5,0), P4=(8,0), P5=(8,3), at locations (z, r), all in millimeters, at any azimuth angle φ, wherein z denotes a distance along the optical axis and r denotes the corresponding cylindrical coordinate; andthe (0,0) of the cylindrical coordinate system denotes a front and center point of the target region. 9. The ophthalmic laser system of claim 1, wherein: the outputted XYZ-scanning beam has a geometric aberration, a diffraction aberration, and a total aberration, equaling a sum of the geometric aberration and the diffraction aberration; andthe numerical aperture NA can be adjusted to increase, at a Z focal depth, a Strehl ratio S corresponding to the total aberration of the laser system by at least a P(MovableExpander) percentage higher than the Strehl ratio S of a laser system where the Z scanner does not have an adjustable numerical aperture NA; wherein the P(MovableExpander) percentage is one of 20%, 30%, 40%, and 50%. 10. The ophthalmic laser system of claim 1, wherein: the outputted XYZ-scanning beam has a geometric aberration, a diffraction aberration, and a total aberration, equaling a sum of the geometric aberration and the diffraction aberration; andthe numerical aperture NA can be adjusted to increase, at a Z focal depth, a Strehl ratio S corresponding to the total aberration to a value above 0.8, whereinthe Strehl ratio S of an analogous laser system, only differing in having the Z scanner without an adjustable numerical aperture NA, is below 0.8. 11. The ophthalmic laser system of claim 10, wherein: the Strehl ratio S corresponds to one of five reference points P1=(0,0), P2=(2,6), P3=(5,0), P4=(8,0), P5=(8,3), at locations (z, r), all in millimeters, at any azimuth angle φ, wherein z denotes a distance along the optical axis and r denotes the corresponding cylindrical coordinate, andthe (0,0) of the cylindrical coordinate system denotes a front and center point of the target region. 12. The ophthalmic laser system of claim 1, wherein: the Z scanner is configured to scan a Z focal depth of the laser system within a Z scanning range, wherein the Z scanning range is one of 5 millimeters to 10 millimeters and 0 millimeters to 15 millimeters. 13. The ophthalmic laser system of claim 1, wherein: the outputted XYZ-scanning beam has a geometric aberration and a diffraction aberration; anda total aberration, equaling a sum of the geometric aberration and the diffraction aberration;the total aberration having a sequence of optimal total aberration values at a sequence of optimal numerical apertures NAopt(z) corresponding to a sequence of Z focal depths;wherein the Z scanner can be adjusted to modify the numerical aperture NA to the sequence of the optimal numerical apertures NAopt(z) at the sequence of Z focal depths. 14. The ophthalmic laser system of claim 13, wherein: the aberration is characterized by an aberration measure, the aberration measure being one of a focal spot radius rf, a Strehl ratio S, an RMS wavefront ω, and a spherical aberration coefficient a40, corresponding to the sequence of Z focal depths. 15. The ophthalmic laser system of claim 13, wherein: a radial coordinate of the focal spot along the sequence of Z focal depths is less than 3 mm. 16. The ophthalmic laser system of claim 1, wherein: the outputted XYZ-scanning beam has a geometric aberration and a diffraction aberration, and a total aberration, equaling a sum of the geometric aberration and the diffraction aberration;wherein the numerical aperture NA can be adjusted to a sequence of numerical apertures NA(z) at a sequence of Z focal depths to reduce a representative total aberration by at least a P(scan) percentage relative to analogous laser systems where the Z scanner does not have an adjustable numerical aperture NA. 17. The ophthalmic laser system of claim 16, wherein: the representative total aberration is one of an average, a minimum, or a maximum of the total aberration over a Z scanning range. 18. The ophthalmic laser system of claim 16, wherein: the total aberration is characterized by one of a focal spot radius rf, a Strehl ratio S, an RMS wavefront ω, and a spherical aberration coefficient a40, corresponding to the sequence of Z focal depths. 19. The ophthalmic laser system of claim 16, wherein: the P(scan) percentage is one of 20%, 30%, 40%, and 50%. 20. The ophthalmic laser system of claim 1, wherein: the numerical aperture NA can be adjusted from a first value when a corneal procedure is performed to a second value when a lens procedure is performed. 21. The ophthalmic laser system of claim 20, wherein: the first value is in the range of 0.2-0.5; andthe second value is in the range of 0.1-0.3. 22. The ophthalmic laser system of claim 20, wherein: the first value is in the range of 0.25-0.35; andthe second value is in the range of 0.15-0.25. 23. The ophthalmic laser system of claim 1, wherein: the first beam expander block is one of a fixed block and a movable block. 24. A laser system for performing cataract surgery, comprising: a laser source, to generate a pulsed laser beam;an XY scanner, to XY scan the pulsed beam in directions essentially transverse to an optical axis; anda Z scanner, to Z scan a focal spot of the XY scanned beam in a target region along the optical axis Z; andto adjust a numerical aperture NA to track an optimal numerical aperture NAopt(z) as the focal spot is Z scanned. 25. The laser system of claim 24, wherein: the Z scanned beam has a total aberration, the total aberration having an optimum as a function of the numerical aperture NA at an optimal numerical aperture NAopt(z) for a series of Z focal depths; andthe Z scanner is adjustable to modify the numerical aperture NA to track the optimal numerical aperture NAopt(z) as the focal spot is scanned through the series of Z focal depths. 26. The laser system of claim 25, wherein: the Z scanned beam has a geometric aberration, a diffraction aberration; andthe total aberration equals a sum of the geometric aberration and the diffraction aberration. 27. The laser system of claim 24, wherein the numerical aperture NA tracking the optimal numerical aperture NAopt(z) comprises one of: the numerical aperture NA being essentially equal to NAopt(z); andthe numerical aperture NA being within a P(track) percentage proximity of NAopt(z), wherein P(track) is one of 10%, 20% and 30%. 28. The laser system of claim 24, wherein the Z scanner comprises: an integrated controller, configured to scan the focal spot through a series of Z focal depths; andto adjust the numerical aperture NA to track the optimal numerical aperture NAopt(z) corresponding to the series of Z focal depths in a correlated manner. 29. The laser system of claim 28, wherein: the integrated controller is configured to scan the focal spot and to adjust the numerical aperture NA in the course of one adjustment action. 30. The laser system of claim 28, wherein the integrated controller comprises one of: an adjuster of a distance between a first beam expander block and a movable beam expander block; andan adjuster of a position of a controller lens. 31. The laser system of claim 28, wherein the integrated controller comprises: two adjusters, configured to adjust two parameters of the Z scanner in a correlated manner. 32. The laser system of claim 24, wherein: the Z scanner is configured to scan a focal spot in a target region within a Z scanning range extending from 0 mm to 10 mm; andto adjust the numerical aperture NA in a range within one of 0.40 to 0.10 and 0.35 to 0.15 during the scanning of the focal spot. 33. The laser system of claim 24, wherein the Z scanner is configured: to scan the focal spot and to adjust the numerical aperture NAin combination with the XY scanner. 34. The laser system of claim 24, wherein the Z scanner is configured: to scan the focal spot and to adjust the numerical aperture NAin combination with an auxiliary Z scanner, disposed between the laser source and the XY scanner. 35. An ophthalmic laser system, comprising: a laser source, to generate a pulsed laser beam;an XY scanner, to receive the pulsed laser beam; andto output an XY-scanning beam, scanned in two directions essentially transverse to an optical axis; anda multi-functional Z scanner, to receive the XY-scanning beam;to output an XYZ-scanning beam, scanned additionally in a Z direction along the optical axis; andto reduce a numerical aperture NA in a target region from a corneal range of 0.25 to 0.35 when a Z focal depth of the laser system is representative of a corneal procedure to a lens range of 0.15 to 0.25 when the Z focal depth is representative of a lens procedure. 36. The ophthalmic laser system of claim 35, wherein: the Z scanner has two adjustable control parameters, a first control parameter associated with a distance between a first beam expander block and a movable beam expander block; anda second control parameter associated with a position of a movable lens of the Z scanner.
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