Gradient index (grin) backplane routing

1 . A gradient index (GRIN) backplane, comprising: a planarly formed GRIN material, wherein the GRIN material includes at least one refractive index that varies along at least one of orthogonal x, y, and z axes of the GRIN material; and a plurality of nanoparticles in at least a portion of the GRIN material, wherein a section of at least one optical pathway is formed in the at least the portion of the GRIN material based on variation of the at least one refractive index, wherein the plurality of nanoparticles enable the at least one refractive index in the at least the portion of the GRIN material to be changed in response to an electric field, wherein the change in the at least one refractive index in response to the electric field results in a change in the section of the at least one optical pathway in the at least the portion of the GRIN material, so as to provide a routing capability, including switching capability, in the GRIN material for an optical signal that propagates along the at least one optical path. 2 . The GRIN backplane of claim 1 , wherein the at least the portion of the GRIN material includes a column along one of the x, y, and z axes. 3 . The GRIN backplane of claim 1 , wherein the at least the portion of the GRIN material comprises a non-centrosymmetric ferroelectric polymer. 4 . The GRIN backplane of claim 1 , wherein the GRIN material comprises two or more parallel layers of distinct refractive indices in a uniform progression. 5 . The GRIN backplane of claim 4 , wherein the parallel layers are in a diagonal orientation to the x, y, and z axes of the GRIN material. 6 . The GRIN backplane of claim 4 , wherein the parallel layers include a uniform dipole orientation. 7 . The GRIN backplane of claim 4 , wherein the uniform progression of refractive indices within the GRIN material is from a relatively higher refractive index to a relatively lower refractive index. 8 . The GRIN backplane of claim 1 , wherein the GRIN material is formed with the variation of the at least one refractive index along the z-axis and a substantially constant refractive index along the x- and y-axes. 9 . The GRIN backplane of claim 1 , further comprising a layer of conductive traces on at least one surface of the GRIN material. 10 . The GRIN backplane of claim 1 , wherein a concentration of the nanoparticles is based on refractive indices of the nanoparticles. 11 . The GRIN backplane of claim 1 , wherein the nanoparticles include one or more of: non-electro-optic nanoparticles and electro-optic nanoparticles. 12 . The GRIN backplane of claim 11 , wherein the electro-optic nanoparticles include non-centrosymmetric ceramic nanoparticles. 13 . The GRIN backplane of claim 1 , wherein the at least the portion of the GRIN material comprises an entirety of the GRIN material. 14 . The GRIN backplane of claim 1 , wherein an orientation of the nanoparticles is changed in response to the electric field, wherein the changed orientation of the nanoparticles results in the change in the at least one refractive index. 15 . (canceled) 16 . An apparatus, comprising: a gradient index (GRIN) backplane that includes nanoparticles that determine at least in part a direction of one or more optical pathways within the GRIN backplane based on a variation of at least one refractive index of the GRIN backplane; a plurality of components on one or more surfaces of the GRIN backplane, wherein two or more of the components are communicatively coupled through the one or more optical pathways within the GRIN backplane; two or more electrodes on at least one surface of the GRIN backplane, wherein the two or more electrodes are configured to create an electric field between the two or more electrodes in response to application of one or more of: a voltage and a current; and an optical interface coupled to an edge of the GRIN backplane, wherein the optical interface is configured to receive an optical communication signal and provide the optical communication signal to at least one of the components through the one or more of the optical pathways within the GRIN backplane, wherein the nanoparticles are responsive to the electric field to change the at least one refractive index of the GRIN backplane to cause a change in the direction of the one or more optical pathways. 17 . The apparatus of claim 16 , wherein the at least one surface of the GRIN backplane includes different surfaces of the GRIN backplane, and wherein the two or more electrodes are positioned at a location on the different surfaces of the GRIN backplane based on one or more of: dimensions of the backplane and a location of the two or more communicatively coupled components. 18 . The apparatus of claim 16 , wherein the two or more electrodes include shapes and/or sizes that are based on the direction of the one or more optical pathways between the two or more communicatively coupled components. 19 . The apparatus of claim 18 , wherein the shapes of the two or more electrodes include one or more of squares, rectangles, circles, and triangles. 20 . The apparatus of claim 18 , wherein the two or more communicatively coupled components are configured to communicate over the one or more optical pathways by use of optical communication signals that include one or more of: a laser beam, an infrared beam, and a visible light beam. 21 . The apparatus of claim 16 , wherein a portion of the components includes at least one of an emitter and/or a detector configured to facilitate transmission and/or reception of optical communication signals. 22 . The apparatus of claim 16 , wherein variation of the at least one refractive index includes non-linear variation, and wherein the GRIN backplane includes one or more non-linear refractive indices such that optical communication signals directed to different components cross each other without interference. 23 . The apparatus of claim 16 , wherein variation of the at least one refractive index includes non-linear variation, and wherein the GRIN backplane includes one or more non-linear refractive indices such that two or more optical communication signals are directed to different components from a single emanation point at the optical interface. 24 . The apparatus of claim 16 , wherein the at least one surface of the GRIN backplane includes different surfaces of the GRIN backplane, and wherein the different surfaces of the GRIN backplane include opposite surfaces of the GRIN backplane. 25 . A method to fabricate a gradient index (GRIN) backplane, the method comprising: forming at least one sheet of GRIN material, wherein the at least one sheet of GRIN material includes at least one refractive index that varies alone, at least one of orthogonal x, y, and z axes of the GRIN material; placing a plurality of nanoparticles into at least a portion of the GRIN material, wherein a section of at least one optical pathway is formed in the at least the portion of the GRIN material based on the variation of the at least one refractive index, wherein the plurality of nanoparticles enable the at least one refractive index in the at least the portion of the GRIN material to be changed in response to an electric field; and mounting two or more electrodes on different surfaces of the sheet of GRIN material, wherein the two or more electrodes are configured to create the electric field between the different surfaces of the at least one sheet of