Diffractive optical element
First Claim
1. A diffractive optical element comprising:
- a base; and
at least one phase zone comprising an arbitrary multiplicity M of steps of identical step height wherein said multiplicity is not a power of 2 and wherein said steps are generated using a number of binary masks with said number of masks being equal to the smallest integer greater than log2 M.
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Accused Products
Abstract
There is disclosed a diffractive optical element and a method to produce same wherein the element comprises a base and at least one phase zone comprising an arbitrary multiplicity M of steps of generally identical step height, wherein M is not a power of 2. The method includes the steps of defining a basic depth unit equivalent to a zone height divided by M, defining a depth sequence of N depths wherein N is the smallest integer greater than log2 M such that each of the M steps can be produced by at least one linear combination of the N depths, defining N masks herein each mask enables the optical element to be processed to one of the N depths and wherein for each mask, the steps to be processed are those which have the one of the N depths in its linear combination and serially utilizing each of the N masks for processing of the optical element.
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Citations
14 Claims
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1. A diffractive optical element comprising:
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a base; and at least one phase zone comprising an arbitrary multiplicity M of steps of identical step height wherein said multiplicity is not a power of 2 and wherein said steps are generated using a number of binary masks with said number of masks being equal to the smallest integer greater than log2 M. - View Dependent Claims (2, 3)
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4. A method of producing a diffractive optical element with at least one phase zone having a zone height and comprising an arbitrary multiplicity M of steps, wherein M is not a power of 2, comprising the stages of:
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defining a basic depth unit t equivalent to said zone height divided by M; defining a depth sequence of N depths wherein N is the smallest integer greater than log2 M such that each of said M steps can be produced by at least one linear combination of said N depths; defining N binary masks wherein each mask enables said optical element to be processed to one of said N depths and wherein for each mask, the steps to be processed are those which have said one of said N depths in its linear combination; and serially utilizing each of said N masks for processing of said optical element to create said arbitrary multiplicity of steps wherein each step has a identical step height equivalent to said basic depth unit. - View Dependent Claims (5, 6, 7, 8, 9)
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10. In a method of producing a diffractive optical element with at least one phase zone having a zone height and comprising an arbitrary multiplicity M of steps of identical step height t, wherein M is not a power of 2, the stages of:
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defining a basic depth unit t equivalent to said zone height divided by M; and defining a depth sequence of N depths and wherein N is the smallest integer greater than log2 M such that each of said M steps can be produced by at least one linear combination of said N depths.
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11. A method of producing a diffractive optical element with at least one phase zone having a zone height and comprising an arbitrary multiplicity M of steps, wherein M is not a power of 2, comprising the stages of:
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defining a basic depth unit t equivalent to said zone height divided by M; defining a depth sequence of N depths wherein N is the smallest integer greater than log2 M such that each of said M steps can be produced by at least one linear combination of said N depths; defining N binary masks wherein each mask enables said optical element to be processed to one of said N depths and wherein for each mask, the steps to be processed are those which have said one of said N depths in its linear combination; generating said N masks; coating said diffractive optical element with a layer of photoresist; placing one mask of said N masks on said layer of photoresist; exposing said photoresist through said one mask thereby producing the mask pattern on the photoresist; etching said optical element; coating said diffractive optical element with a layer of phtoresist; aligning another mask of said N masks on said layer of photoresist; and repeating said steps of exposing, etching, aligning and coating until the entirety of said N masks have been utilized and said multiplicity of steps are created each having a identical step height equivalent to said basic depth unit.
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12. A method of producing a diffractive optical element with at least one wide and one narrow phase zone each having a zone height, wherein said at least one wide phase zone comprises an arbitrary multiplicity M of steps and wherein M is not a power of 2, comprising the stages of:
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defining a basic depth unit t equivalent to said zone height divided by M; defining a depth sequence of N depths wherein N is the smallest integer greater than log2 M such that each of said M steps can be produced by at least one linear combination of said N depths; defining N binary masks wherein each mask enables said optical element to be processed to one of said N depths, wherein for each mask, the steps to be processed are those which have said one of said N depths in its linear combination and wherein portions of each mask corresponding to portions of said at least one narrow phase zone can be masked out so that the number of steps in said narrow phase zone will be less than M while the wide phase zone will have M number of steps each of identical height equivalent to said basic depth unit; and serially utilizing each of said N masks for processing of said optical element. - View Dependent Claims (13, 14)
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Specification