Polarization diversity grating couplers with low loss and zero PDW/PDL

What is claimed is: 1. An optical grating coupler defining an axis and configured to couple light between a planar waveguide and an optical fiber, comprising: first and second entry surfaces; and a plurality of scattering regions symmetric to the axis and arranged along beam paths orthogonal to the entry surfaces, the scattering regions comprising: a pair of first scattering regions, the first scattering regions occupying respective entry edge regions of the grating coupler, the pair of first scattering regions comprising a first plurality of scatterer structures dimensioned to provide a first scattering strength and a negative polarization dependent wavelength (PDW); a second scattering region adjacent respective edges of the pair of first scattering regions, comprising a second plurality of scatterer structures dimensioned to provide a second scattering strength stronger than the first scattering strength and a negative PDW; a third scattering region adjacent the second scattering region, comprising a third plurality of scatterer structures dimensioned to provide a third scattering strength stronger than the second scattering strength and a positive PDW; and a fourth scattering region adjacent the third scattering region, comprising a fourth plurality of scatterer structures dimensioned to provide a fourth scattering strength stronger than the third scattering strength and a positive PDW; wherein placement of the scattering regions is arranged such that light entering the grating coupler from the planar waveguide experiences an increasing scattering strength as it traverses the grating coupler and is coupled into the optical fiber. 2. The optical grating coupler of claim 1 , wherein a scattering region of the plurality of scattering regions comprises a plurality of scatterer structures that vary in aspect ratio continuously from a proximal edge to a distal edge of the scattering region. 3. The optical grating coupler of claim 1 , further comprising a pair of fifth scattering regions occupying respective distal edge regions of the grating coupler, the pair of fifth scattering regions comprising a fifth plurality of scatterer structures dimensioned to provide a fifth scattering strength stronger than the third scattering strength and a positive PDW. 4. The optical grating coupler of claim 1 , wherein scattering strength presented to incoming light by the plurality of scattering regions changes from weak to strong along a beam path of the incoming light to match a Gaussian mode profile of the optical fiber. 5. The optical grating coupler of claim 1 , wherein the PDW of the plurality of scattering regions changes from negative to positive along a beam path of the incoming light. 6. The optical grating coupler of claim 5 , wherein the overall PDW of the optical grating coupler is zero. 7. The optical grating coupler of claim 1 , wherein shapes and aspect ratios of the scatterer structures are selected to modulate scattering along the beam path to match a gaussian mode of the fiber and reduce loss. 8. The optical grating coupler of claim 1 , wherein the first plurality of scatterer structures in the pair of first scattering regions are configured as merged scatterer cells presenting an elongate structure parallel to the beam path. 9. The optical grating coupler of claim 1 , wherein the second plurality of scatterer structures comprises dendritic cells. 10. The optical grating coupler of claim 1 , wherein the third plurality of scatterer structures comprises square cells. 11. The optical grating coupler of claim 1 , wherein the fourth plurality of scatterer structures comprises triangular cells. 12. The optical grating coupler of claim 1 , wherein scatterer structures in a scattering region of the plurality of scattering regions vary in shape continuously from a proximal edge to a distal edge of the scattering region. 13. The optical grating coupler of claim 1 , wherein an aspect ratio of the scatterer structures in a scattering region of the plurality of scattering regions varies continuously from a proximal edge to a distal edge of the scattering region. 14. The optical grating coupler of claim 1 , wherein the PDW of the scattering regions of the grating coupler are configured such that the PDW of the grating coupler is zero. 15. A method of fabricating an optical grating coupler to couple light between a planar waveguide and an optical fiber, the method comprising: forming a pair of first scattering regions, the first scattering regions occupying respective entry edge regions of the grating coupler, the pair of first scattering regions comprising a first plurality of scatterer structures dimensioned to provide a first scattering strength and a negative polarization dependent wavelength (PDW); forming a second scattering region adjacent respective edges of the pair of first scattering regions, comprising a second plurality of scatterer structures dimensioned to provide a second scattering strength stronger than the first scattering strength and a negative PDW; forming a third scattering region adjacent the second scattering region, comprising a third plurality of scatterer structures dimensioned to provide a third scattering strength stronger than the second scattering strength and a positive PDW; and forming a fourth scattering region adjacent the third scattering region, comprising a fourth plurality of scatterer structures dimensioned to provide a fourth scattering strength stronger than the third scattering strength and a positive PDW; wherein placement of the scattering regions is arranged such that light entering the grating coupler from the planar waveguide experiences an increasing scattering strength as it traverses the grating coupler and is coupled into the optical fiber. 16. The method of claim 15 , further comprising forming a pair of fifth scattering regions occupying respective distal edge regions of the grating coupler, the pair of fifth scattering regions comprising a fifth plurality of scatterer structures dimensioned to provide a fifth scattering strength stronger than the third scattering strength and a positive PDW. 17. The method of claim 15 , wherein a scattering region of the plurality of scattering regions comprises a plurality of scatterer structures that vary in aspect ratio continuously from a proximal edge to a distal edge of the scattering region. 18. The method of claim 15 , wherein scattering strength presented to incoming light by the plurality of scattering regions changes from weak to strong along a beam path of the incoming light to match a Gaussian mode profile of the optical fiber. 19. The method of claim 15 , wherein shapes and aspect ratios of the scatterer structures are selected to modulate scattering along the beam path to match a gaussian mode of the fiber and reduce loss. 20. The method of claim 15 , wherein the first plurality of scatterer structures in the pair of first scattering regions are configured as merged scatterer cells presenting an elongate structure parallel to the beam path.