Optical soft aperture and use thereof
First Claim
1. An optical element comprising a soft aperture providing varying degrees of power attenuation to an input beam having a slow axis and a fast axis, with a first power attenuation being at an edge of the element and a second power attenuation being at the center of the element, the second power attenuation being less than the first power attenuation, wherein at least a full width at half maximum portion of the beam along the slow axis encounters the second power attenuation, none of the beam along the slow axis encounters the first power attenuation and a portion of the beam along the fast axis encounters the first power attenuation, said soft aperture comprising diffractive portions randomly dispersed in different radial regions of the element, a density of said diffractive portions increasing as radial regions in which said diffractive portions are located are further removed from a center of the element, thereby providing said varying degrees of power attenuation.
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Accused Products
Abstract
A soft aperture allows gradual attenuation of a light beam dependent upon its location away from the center of a diffractive optical element. Such an optical element may be provided by decreasing a number of phase levels, increasing a number of phase levels, increasing a density of metal patches or diffractive gratings, or decreasing a blaze height and/or duty cycle, all radially from the center. Alternatively, the soft aperture may be defined by a photolithographic process. Such a soft aperture is particularly useful in aiding circularizing of an elliptical light beam. The soft aperture may be used alone or integrated with other optical elements.
37 Citations
8 Claims
- 1. An optical element comprising a soft aperture providing varying degrees of power attenuation to an input beam having a slow axis and a fast axis, with a first power attenuation being at an edge of the element and a second power attenuation being at the center of the element, the second power attenuation being less than the first power attenuation, wherein at least a full width at half maximum portion of the beam along the slow axis encounters the second power attenuation, none of the beam along the slow axis encounters the first power attenuation and a portion of the beam along the fast axis encounters the first power attenuation, said soft aperture comprising diffractive portions randomly dispersed in different radial regions of the element, a density of said diffractive portions increasing as radial regions in which said diffractive portions are located are further removed from a center of the element, thereby providing said varying degrees of power attenuation.
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3. A method for circularizing a light beam having a slow axis and a fast axis comprising:
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providing a first power attenuation to the light beam at an outer edge of a diffractive optical element, including providing metal patches of a first density on said outer edge; providing a second power attenuation to the light beam at a center of the diffractive optical element including providing metal patches of a second density on said center, said second density being lower than said first density, the second power attenuation being less than the first power attenuation; and passing the light beam through the diffractive optical element such that at least a full width at half maximum portion of the beam along the slow axis encounters the second power attenuation, none of the beam along the slow axis encounters the first power attenuation and a portion of the beam along the fast axis encounters the first attenuation. - View Dependent Claims (4)
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5. A method for circularizing a light beam having a slow axis and a fast axis comprising:
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providing a first power attenuation to the light beam at an outer edge of a diffractive optical element, including providing diffractive scattering portions of a first density on said outer edge; providing a second power attenuation to the light beam at a center of the diffractive optical element including providing diffractive scattering portions of a second density on said center, said second density being lower than said first density, the second power attenuation being less than the first power attenuation; and passing the light beam though the diffractive optical element such that at least a full width at half maximum portion of the beam along the slow axis encounters the second power attenuation, none of the beam along the slow axis encounters the first power attenuation and a portion of the beam along the fast axis encounters the first attenuation.
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- 6. An apparatus for reducing ellipticity of an elliptical light beam having an input beam profile made up of elliptical regions of particular power, the apparatus comprising a diffractive optical element having corresponding regions of transmission efficiency, the corresponding regions having varying degrees of power attenuation, metal patches being randomly dispersed in different radial regions of the diffractive optical element, a density of said metal patches increasing as radial regions in which said metal patches are located are further removed from a center of the diffractive optical element, thereby providing said varying degrees of power attenuation, wherein a product of a transmission efficiency of each region of the diffractive optical element and a particular power of corresponding regions of the input beam profile form an output beam profile, the output beam profile being more circular than the input beam profile.
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8. An apparatus for reducing ellipticity of an elliptical light beam having an input beam profile made up of elliptical regions of particular power, the apparatus comprising a diffractive optical element having corresponding regions of transmission efficiency, the corresponding regions having varying degrees of power attenuation, diffractive portions being randomly dispersed in different radial regions of the diffractive optical element, a density of said diffractive portions increasing as radial regions in which said diffractive portions are located are further removed from a center of the diffractive optical element, thereby providing said varying degrees of power attenuation, wherein a product of a transmission efficiency of each region of the diffractive optical element and a particular power of corresponding regions of the input beam profile form an output beam profile, the output beam profile being more circular than the input beam profile.
Specification