Pupil dependent diffractive lens for near, intermediate, and far vision
Abstract
A multifocal diffractive lens comprises a multifocal diffractive structure coupled to a refractive component. The refractive component comprises at least one curved surface. The multifocal diffractive structure comprises a first plurality of substantially monofocal echellettes having a first optical power for near vision correction and a second plurality of substantially monofocal echellettes for far vision correction. The first plurality of substantially monofocal echellettes combined with the second plurality of substantially monofocal echellettes can provide a multifocal diffractive profile having decreased light scatter, chromatic aberration, and diffraction to non-viewing orders such that dysphotopsia is substantially inhibited. A third plurality of substantially monofocal echellettes having an intermediate optical power can be combined with the first plurality of substantially monofocal echellettes and the second plurality of substantially monofocal echellettes.
Claims
exact text as granted — not AI-modified1 . A lens to correct vision of an eye, the lens comprising,
a refractive component comprising at least one curved surface; and a multifocal diffractive structure optically coupled to the at least one curved surface, the multifocal diffractive structure comprising a first plurality of substantially monofocal echellettes having a first optical power corresponding to a near vision correction of the eye and a second plurality of substantially monofocal echellettes having a second optical power corresponding to a far vision correction of the eye.
2 . The lens of claim 1 , wherein the diffractive structure is imposed on the at least one curved surface.
3 . The lens of claim 1 , wherein the diffractive structure is imposed on a second component optically coupled to the refractive component.
4 . The lens of claim 1 , wherein the first plurality of substantially monofocal of echellettes extends substantially around an inner boundary and an outer boundary of each of substantially monofocal echellettes the second plurality.
5 . The lens of claim 4 , wherein the first plurality of substantially monofocal echellettes comprises a first height corresponding to a non-zero integer multiple of a design wavelength and wherein the second plurality of echellettes comprises a second step height of about zero and wherein the first plurality of substantially monofocal echellettes extends substantially along the inner boundary and the outer boundary so as to define said each of the second plurality of substantially monofocal echellettes.
6 . The lens of claim 1 , wherein the first plurality of substantially monofocal echellettes comprises a first plurality of full period zones and the second plurality of substantially monofocal echellettes comprises a second plurality of full period zones corresponding to the first plurality of full period zones.
7 . The lens of claim 6 , wherein the first plurality of substantially monofocal echellettes and an optical zone size of the diffractive structure determine an integer number of full period zones, the integer number of full period zones comprising the first plurality of full period zones and the second plurality of full period zones.
8 . The lens of claim 7 , wherein the first plurality of substantially monofocal echellettes is determined based on the first diffractive optical power, the optical zone size, the design wavelength and a difference of an index of refraction of the eye and an index of refraction of the diffractive structure.
9 . The lens of claim 7 , wherein the first plurality of substantially monofocal echellettes comprises first substantially monofocal diffractive profiles extending substantially across the first plurality of full wave zones and the second plurality of substantially monofocal echellettes comprises second substantially monofocal diffractive profiles extending substantially across the second plurality of full wave zones and wherein the second plurality of full wave zones have sizes and locations based on the first plurality of full wave zones.
10 . The lens of claim 1 , wherein the first plurality of substantially monofocal echellettes has height profiles so as to diffract at least about 90% light transmitted energy to a first focus corresponding to the first optical power for near vision correction and wherein the second plurality of substantially monofocal echellettes has height profiles so as to diffract at least about 90% light transmitted energy to a second focus corresponding to the second optical power for near vision correction.
11 . The lens of claim 1 , further comprising a third plurality of substantially monofocal echellettes, the third plurality of substantially monofocal echellettes having third heights and third full period zones at third locations corresponding to the first plurality of substantially monofocal echellettes and wherein the third plurality of substantially monofocal echellettes has a third optical power corresponding to an intermediate vision of the patient.
12 . The lens of claim 11 , wherein the third plurality of substantially monofocal echellettes has heights approximating heights of the first plurality of substantially monofocal echellettes and wherein the third plurality of substantially monofocal echellettes has widths corresponding to an integer multiple of two or more widths of the full period zones of the first plurality of substantially monofocal echellettes.
13 . The lens of claim 1 , wherein the diffractive structure comprises an inner portion and an outer portion, the inner portion comprising an inner proportion of the first plurality of substantially monofocal echellettes to the second plurality of substantially monofocal echellettes, the outer portion comprising an outer proportion of the first plurality of substantially monofocal echellettes to the second plurality of substantially monofocal echellettes, the outer proportion less than the inner proportion so as to provide near vision correction with the inner portion and far vision correction with outer portion when the pupil responds to light.
14 . The lens of claim 1 , wherein the diffractive structure has full wave zones comprising pairs of half period zones, wherein each of the pairs comprises an inner half period zone having an inner phase and an outer half period zone having an outer phase opposite the inner phase, and wherein a third plurality of echellettes comprises pairs of echellettes, each pair having an inner echellette extending substantially across the inner half period zone and an outer echellette extending substantially across the outer half period zone.
15 . The lens of claim 14 , wherein said pairs of echellettes of the third plurality correspond to the intermediate vision correction and the far vision correction.
16 . The lens of claim 15 , wherein said inner echellette of said each pair of the third plurality of echellettes corresponds to the far vision correction and said outer echellette of said each pair of the third plurality of echellettes corresponds to the intermediate vision correction.
17 . The lens of claim 15 , wherein said inner echellette of said each pair of the third plurality of echellettes corresponds to the intermediate vision correction and said outer echellette of said each pair of the third plurality of echellettes corresponds to the far vision correction.
18 . A method of correcting vision of an eye, the method comprising:
placing a lens along an optical path of the eye, the lens comprising at least one curved surface coupled to a diffractive structure, the diffractive structure comprising a first plurality of substantially monofocal echellettes having a first optical power for a near vision correction and a second plurality of substantially monofocal echellettes having a second optical power for a far vision correction; wherein the first plurality of substantially monofocal echellettes diffracts transmitted light with a first efficiency of at least about 90% for the near vision correction and the second plurality of substantially monofocal echellettes diffracts transmitted light with an efficiency of at least about 90% for the far vision correction.
19 . The method of claim 18 wherein the first plurality of substantially monofocal echellettes has a corresponding first plurality of full period zones and wherein second plurality of substantially monofocal echellettes has a second plurality of full period zones corresponding to the first plurality of full period zones.
20 . The method of claim 19 wherein the diffractive structure comprises a third plurality of substantially monofocal echellettes having an intermediate optical power for an intermediate vision correction, the third plurality of substantially monofocal echellettes having third heights approximating first heights of the first plurality of substantially monofocal echellettes, the third plurality of substantially monofocal echellettes having a third plurality of full period zones corresponding to the first plurality of full period zones, the first plurality of full period zones having first widths and the third plurality of full period zones having third widths, the third widths corresponding to an integer multiple of two or more of the first widths such that first optical power corresponds to the integer multiple multiplied with the third optical power.Cited by (0)
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