Wavefront measurements of eyes are often taken when the pupil is in a first configuration in an evaluation context. The results can be represented by a set of basis function coefficients. Prescriptive treatments are often applied in a treatment context, which is different from the evaluation context
Wavefront measurements of eyes are often taken when the pupil is in a first configuration in an evaluation context. The results can be represented by a set of basis function coefficients. Prescriptive treatments are often applied in a treatment context, which is different from the evaluation context. Hence, the patient pupil can be in a different, second configuration, during treatment. Systems and methods are provided for determining a transformed set of basis function coefficients, based on a difference between the first and second configurations, which can be used to establish the vision treatment.
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1. A method of calculating effective powers of an optical system of a patient, through the use of a computer processor, the method comprising: calculating a first effective power using a first Zernike expansion coefficient for the optical system, the first Zernike expansion coefficient associated wi
1. A method of calculating effective powers of an optical system of a patient, through the use of a computer processor, the method comprising: calculating a first effective power using a first Zernike expansion coefficient for the optical system, the first Zernike expansion coefficient associated with a first aperture dimension; andcalculating a second effective power using a second Zernike expansion coefficient for the optical system, the second Zernike expansion coefficient associated with a second aperture dimension, the second aperture dimension greater than the first aperture dimension, the second Zernike expansion coefficient scaled relative to the first Zernike expansion coefficient using a scaling factor comprising a ratio of the second aperture dimension to the first aperture dimension raised to a power of a factor comprising a radial degree of the coefficient; anddetermining a treatment for the optical system of the patient based on the calculated first effective power and the calculated second effective power,wherein the optical system comprises an optical tissue of the patient, the first aperture dimension comprises a first pupil dimension, and the second aperture dimension comprises a second pupil dimension, andwherein the treatment comprises a member selected from the group consisting of an intraocular lens treatment, a contact lens treatment, and a refractive laser treatment. 2. The method of claim 1, wherein the first pupil dimension comprises a first pupil radius and the second pupil dimension comprises a second pupil radius. 3. The method of claim 1, further comprising modifying the optical tissue of the patient according to the treatment. 4. The method of claim 1, wherein the patient has presbyopia. 5. A system for calculating effective power for an optical system of a patient, the system comprising a data processing module comprising a processor and a tangible non-transitory computer readable medium, the computer readable medium programmed with a computer application that, when executed by the processor, causes the processor to: calculate a first effective power using a first Zernike expansion coefficient for the optical system, the first Zernike expansion coefficient associated with a first aperture dimension, andcalculate a second effective power using a second Zernike expansion coefficient for the optical system, the second Zernike expansion coefficient associated with a second aperture dimension, anddetermine a treatment for the optical system of the patient based on the calculated first effective power and the calculated second effective power,wherein the second aperture dimension is greater than the first aperture dimension, and the second Zernike expansion coefficient is scaled relative to the first Zernike expansion coefficient using a scaling factor comprising a ratio of the second aperture dimension to the first aperture dimension raised to a power of a factor comprising a radial degree of the coefficient,wherein the optical system comprises an optical tissue of the patient, the first aperture dimension comprises a first pupil dimension, and the second aperture dimension comprises a second pupil dimension, andwherein the treatment comprises a member selected from the group consisting of an intraocular lens treatment, a contact lens treatment, and a refractive laser treatment. 6. The system of claim 5, wherein the first pupil dimension comprises a first pupil radius and the second pupil dimension comprises a second pupil radius. 7. The system of claim 5, wherein the system is configured to modify the optical tissue of the patient according to the treatment. 8. The system of claim 5, wherein the patient has presbyopia. 9. A computer program product for calculating effective powers of an optical system of a patient, the computer program product comprising: code for calculating a first effective power using a first Zernike expansion coefficient for the optical system, the first Zernike expansion coefficient associated with a first aperture dimension; andcode for calculating a second effective power using a second Zernike expansion coefficient for the optical system, the second Zernike expansion coefficient associated with a second aperture dimension, the second aperture dimension greater than the first aperture dimension, the second Zernike expansion coefficient scaled relative to the first Zernike expansion coefficient using a scaling factor comprising a ratio of the second aperture dimension to the first aperture dimension raised to a power of a factor comprising a radial degree of the coefficient; andcode for determining a treatment for the optical system of the patient based on the calculated first effective power and the calculated second effective power; anda computer-readable medium for storing the codes,wherein the optical system comprises an optical tissue of the patient, the first aperture dimension comprises a first pupil dimension, and the second aperture dimension comprises a second pupil dimension, andwherein the treatment comprises a member selected from the group consisting of an intraocular lens treatment, a contact lens treatment, and a refractive laser treatment. 10. The computer program product of claim 9, wherein the patient has presbyopia. 11. The computer program product of claim 9, wherein the first pupil dimension comprises a first pupil radius and the second pupil dimension comprises a second pupil radius.
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