Refractive corrector incorporating a continuous central phase zone and peripheral phase discontinuities

The invention claimed is: 1. A refractive corrector comprising: (a) a central zone having a continuous wavefront cross-section phase profile, having a wavefront maximum height of greater than 1 design wavelength λ in the area of the central zone; and (b) a peripheral region comprising multiple segments and having a discontinuous wavefront cross-section phase profile having phase shifts between segments that are equal to the design wavelength or multiples of the design wavelength, and wherein the phase shifts in the peripheral region are less than the wavefront maximum height in the central zone; wherein the refractive corrector comprises an optical, polymeric lens material having an anterior surface and posterior surface and an optical axis intersecting the surfaces, and at least one laser-modified layer disposed between the anterior surface and the posterior surface formed by scanning light pulses from a laser along regions of the optical, polymeric material to cause changes in the refractive index of the polymeric lens material, and wherein the at least one laser-modified layer forms at least part of each of the central zone and the peripheral region formed by varying the refractive index of the materials forming each of the central zone and peripheral region across each of the central zone and peripheral region. 2. The refractive corrector of claim 1 , wherein the peripheral region has a Fresnel structure having a phase shift between segments equal to the design wavelength. 3. The refractive corrector of claim 1 , wherein the peripheral region circumscribes the central zone. 4. The refractive corrector of claim 1 , wherein an outer perimeter of the central zone and an outer perimeter of the peripheral region are circular. 5. The refractive corrector of claim 1 , wherein an optical surface of the central zone is parabolic. 6. The refractive corrector of claim 1 , wherein an optical surface of the central zone is hyperbolic. 7. The refractive corrector of claim 1 , wherein an optical surface of the central zone is a freeform surface. 8. The refractive corrector of claim 1 , wherein an optical surface of the central zone is aspheric. 9. The refractive corrector of claim 1 , wherein a diameter of the central zone is from 20% to 90% of the outer diameter of the peripheral region. 10. The refractive corrector of claim 1 , wherein the central zone and the peripheral region are located in a contact lens. 11. The refractive corrector of claim 1 , wherein the central zone and the peripheral region are located in an intra-ocular lens. 12. The refractive corrector of claim 1 , wherein the phase shifts between segments in the discontinuous wavefront cross-section phase profile in the peripheral region are 2π phase shift discontinuities. 13. The refractive corrector of claim 1 , wherein the at least one laser-modified layer includes a first portion having a continuous variation in index of refraction forming the central zone, and additional portions having discontinuous variations in index of refraction forming the peripheral region. 14. The refractive corrector of claim 1 , wherein the refractive corrector is mono-focal for the design wavelength. 15. The refractive corrector of claim 1 , wherein the design wavelength is a wavelength between 400 and 700 nm. 16. The refractive corrector of claim 1 , wherein the design wavelength is 555 nm. 17. A method of forming a refractive corrector comprising: providing an optical, polymeric lens material having an anterior surface and posterior surface and an optical axis intersecting the surfaces; and forming at least one laser-modified layer disposed between the anterior surface and the posterior surface with light pulses from a laser by scanning the light pulses along regions of the optical, polymeric material to cause changes in the refractive index of the polymeric lens material; wherein the optical, polymeric lens material comprises (a) a central zone having a continuous wavefront cross-section phase profile, having a wavefront maximum height of greater than 1 design wavelength λ in the area of the central zone, and (b) a peripheral region comprising multiple segments and having a discontinuous wavefront cross-section phase profile having phase shifts between segments that are equal to the design wavelength or multiples of the design wavelength, wherein the phase shifts in the peripheral region are less than the wavefront maximum height in the central zone; and wherein the at least one laser-modified layer forms at least part of each of the central zone and the peripheral region by varying the refractive index of the materials forming each of such central zone and peripheral region across each of such central zone and peripheral region. 18. The method of claim 17 , wherein the at least one laser-modified layer includes a first portion having a continuous variation in index of refraction forming the central zone. 19. The method of claim 18 , wherein the at least one laser-modified layer includes additional portions having discontinuous variations in index of refraction forming the peripheral region. 20. A method for modifying a refractive property of ocular tissue in an eye, comprising: forming at least one optically-modified layer in at least one of the corneal stroma and the crystalline lens ocular tissue in an eye by scanning light pulses from a laser focused in the corneal stroma or crystalline lens ocular tissue along regions of the corneal stroma or crystalline lens ocular tissue to cause changes in the refractive index within the ocular tissue to form a modified corneal stroma or crystalline lens; wherein the modified corneal stroma or crystalline lens comprises (a) a central zone having a continuous wavefront cross-section phase profile, having a wavefront maximum height of greater than 1 design wavelength λ in the area of the central zone, and (b) a peripheral region comprising multiple segments and having a discontinuous wavefront cross-section phase profile having phase shifts between segments that are equal to the design wavelength or multiples of the design wavelength, wherein the phase shifts in the peripheral region are less than the wavefront maximum height in the central zone; and wherein the at least one optically-modified layer forms at least part of each of the central zone and the peripheral region by varying the refractive index of the ocular tissue forming each of such central zone and peripheral region across each of such central zone and peripheral region. 21. The method of claim 20 , wherein the at least one optically-modified layer includes a first portion having a continuous variation in index of refraction forming the central zone. 22. The method of claim 21 , wherein the at least one optically-modified layer includes additional portions having discontinuous variations in index of refraction forming the peripheral region. 23. The method of claim 20 , wherein the at least one optically-modified layer is formed in the corneal stroma.