Holographic mode conversion for transmission lines

What is claimed is: 1. An electromagnetic mode converting transmission line (TL) junction for a finite frequency range, comprising: a dielectric structure divided into a plurality of sub-wavelength voxels, wherein each voxel has a maximum dimension that is less than half of a wavelength of a frequency within the finite frequency range, and wherein each voxel is assigned one of a plurality of dielectric constants to approximate an identified distribution of dielectric constants, such that the mode converting TL junction converts electromagnetic energy from a first mode to a second mode for at least a first waveguide operational in the finite frequency range, wherein the mode converting TL junction comprises a metamaterial with an effective dielectric constant less than 1 for at least a portion of the finite frequency range. 2. The TL junction of claim 1 , wherein the volumetric distribution of dielectric constants is selected using an optimization algorithm in which the dielectric constants are treated as optimizable variables. 3. The TL junction of claim 2 , wherein the optimization algorithm comprises a constrained optimization algorithm in which the dielectric constants are treated as optimization variables constrained to have real parts greater than or equal to approximately one and imaginary parts equal to or approximately zero. 4. The TL junction of claim 1 , wherein the volumetric distribution of dielectric constants is selected based on an equation for a holographic solution. 5. The TL junction of claim 4 , wherein the volumetric distribution of dielectric constants is selected using the equation: ∈ hol ( x, y, z )−1 =βE goal ·E* in /|E in | 2 , wherein ∈ hol (x, y, z) is the volumetric distribution of dielectric constants in an x, y, z coordinate system, wherein β is a selectable constant, wherein E in is the input field distribution of electromagnetic radiation from a TL on the surface of the mode converting TL junction relative to the x, y, z coordinate system, and wherein E goal is a dominant component of the output field distribution of electromagnetic radiation from the mode converting TL junction relative to the x, y, z coordinate system that approximates the target functionality. 6. The TL junction of claim 1 , wherein one of the first and second modes is a TE 01 mode and the other of the first and second modes is a TE 10 mode, such that the mode converting TI junction is effectively configured to rotate polarization by 90 degrees. 7. The TL junction of claim 1 , wherein one of the first and second modes is a TE m,n where m and n are integers, and wherein the other of the first and second modes is a TE n,m mode. 8. The TL junction of claim 1 , wherein one of the first and second modes is a TE m,n where m and n are integers, and wherein the other of the first and second modes is a TM m′,n′ mode, where m′ is different from m and n′ is different from n. 9. The TL junction of claim 1 , wherein one of the first and second modes is a TE 01 mode and the other of the first and second modes is a TE 02 mode, such that the mode converting TL junction is effectively configured to upconvert the mode number. 10. The TL junction of claim 1 , wherein the identified distribution of dielectric constants is selected to cause the mode converting TL junction to serve as one of: an E-type T junction, an H-type T junction, a magic T hybrid junction, and a hybrid ring junction. 11. The TL junction of claim 1 , wherein the TL comprises an optical TL. 12. The TL junction of claim 1 , wherein each voxel is assigned a dielectric constant selected from a set of N discrete dielectric constants, where N is an integer greater than 1. 13. The TL junction of claim 1 , wherein the volumetric distribution is approximately homogeneous in one spatial dimension in a coordinate system, such that the volumetric distribution of the mode converting TL junction is effectively two-dimensional. 14. The TL junction of claim 1 , wherein the mode converting TL junction is printed using a three-dimensional printer to print each of the sub-wavelength voxels with a material having the assigned dielectric constant. 15. The TL junction of claim 1 , wherein each voxel is assigned a dielectric constant selected from a set of N discrete dielectric constants, where N is an integer greater than 1. 16. The TL junction of claim 1 , wherein each voxel is assigned a dielectric constant selected from one of two discrete dielectric constants. 17. The TL junction of claim 16 , wherein the mode converting TL junction is printed using a three-dimensional printer configured to print each of the sub-wavelength voxels with one of two materials, where each material corresponds to one of the two discrete dielectric constants. 18. The TL junction of claim 1 , wherein the mode converting TL junction includes a metamaterial. 19. The TL junction of claim 1 , wherein the mode converting TL junction comprises at least two metamaterials, wherein each of the metamaterials has a different dielectric constant. 20. The TL junction of claim 19 , wherein at least one of the metamaterials has a complex permittivity value. 21. The TL junction of claim 20 , wherein the effective dielectric constant of the at least one metamaterial with the complex permittivity value has a negative imaginary part of the effective dielectric constant for the finite frequency range. 22. The TL junction of claim 1 , wherein the mode converting TL junction comprises at least one non-superluminal low-loss dielectric medium at the finite frequency range, wherein the non-superluminal characteristic of the dielectric medium relates to the dielectric medium having a phase velocity for electromagnetic waves within the finite frequency range that is less than c, the speed of light in a vacuum. 23. A method comprising: identifying a target functionality for a TL junction for use with at least a first TL, wherein the target functionality comprises at least converting electromagnetic energy from a first mode to a second mode; identifying volumetric boundaries to enclose a mode converting TL junction; identifying an input field distribution of electromagnetic radiation on a surface of the mode converting TL junction from the first TL for a finite frequency range; identifying a volumetric distribution of dielectric constants within the mode converting TL junction that will transform the input field distribution of electromagnetic radiation to an output field distribution of electromagnetic radiation that approximates the target functionality for the TL junction; and generating the mode converting TL junction with voxels having the determined volumetric distribution of dielectric constants, wherein the volume of the mode converting TL junction is divided into a plurality of sub-wavelength voxels, wherein each voxel has a maximum dimension that is less than one half-wavelength in diameter for the finite frequency range, and wherein each voxel is assigned a dielectric constant based on the determined distribution of dielectric constants for approximating the target functionality for the TL junction, wherein each voxel is assigned a dielectric constant selected from one of two discrete dielectric constants, and wherein the mode converting TL junction is generated by depositing each of the sub-wavelength voxels with a material having a first dielectric constant and depositing no material for each of the sub-wavelength voxels assign