Impedance matching in very high dielectric constant isolator/circulator junctions

What is claimed is: 1. A circulator/isolator junction comprising: a pair of ferrite discs, each of the pair having an outer rim; a composite dielectric material surrounding the outer rim of each of the pair of ferrite discs; and a center conductor located between the pair of ferrite discs, the center conductor including a plurality of transmission lines extending away from the center of the center conductor, the composite dielectric material including segments having a first dielectric constant and segments having a second dielectric constant, the first dielectric constant segments being aligned over each of the plurality of transmission lines and having a dielectric constant lower than a dielectric constant of the second dielectric constant segments. 2. The circulator/isolator junction of claim 1 wherein the composite dielectric material is generally annular. 3. The circulator/isolator junction of claim 1 wherein the first dielectric constant material is sufficient to allow for a width of the transmission lines that is within production tolerances of the transmission lines. 4. The circulator/isolator junction of claim 1 wherein the center conductor includes three transmission lines spaced approximately 120 degrees apart and the composite dielectric material includes three first dielectric constant segments positioned directly above and directly below the transmission lines. 5. The circulator/isolator junction of claim 1 further including a pair of ground plates located on an outer surface of the pair of ferrite discs. 6. The circulator/isolator junction of claim 1 wherein the second dielectric constant material has a dielectric constant of at least 30. 7. The circulator/isolator junction of claim 1 wherein the first dielectric constant material has a dielectric constant of less than 30. 8. The circulator/isolator junction of claim 1 wherein the composite dielectric material has a diameter of 25 mm or less for the frequency range 1.8 to 2.7 GHz. 9. The circulator/isolator junction of claim 1 wherein the junction has 4 ports and 4 transmission lines. 10. The circulator/isolator junction of claim 1 wherein the junction has 6 ports and 6 transmission lines. 11. The circulator/isolator junction of claim 1 wherein the center conductor and transmission lines are configured in a micro-strip configuration. 12. A segmented circulator/isolator comprising: a ferrite disc having an outer rim; a plurality of first dielectric constant material segments surrounding the outer rim of the ferrite disc and having gaps between adjacent first dielectric constant material segments; and a plurality of second dielectric constant material segments surrounding the outer rim of the ferrite disc and located in the gaps, the plurality of second dielectric constant material segments having a higher dielectric constant than the plurality of first dielectric constant material segments, the combination of the plurality of first dielectric constant material segments and the plurality of second dielectric constant material segments forming a ring around the outer rim of the ferrite disc. 13. The segmented circulator/isolator of claim 12 wherein the ferrite disc includes two materials having different dielectric constants. 14. The segmented circulator/isolator of claim 12 wherein a width of each of the plurality of first dielectric constant material is sufficient to allow for a width of a transmission line that is above production tolerances of the transmission line. 15. The segmented circulator/isolator of claim 12 further comprising a second segmented circulator/isolator including a center conductor including three transmission lines spaced approximately 120 degrees apart, the plurality of first dielectric constant segments positioned directly above and directly below the transmission lines. 16. The segmented circulator/isolator of claim 12 further comprising a pair of ground plates located on an outer surface of the disc. 17. A method of forming a circulator/isolator junction comprising: inserting a ferrite rod into a single piece first dielectric constant tube; cutting grooves in the dielectric constant tube having a first dielectric constant to form first dielectric constant segments; inserting and attaching segments having a second dielectric constant into the grooves to form an alternating first and second dielectric constant assembly, the first and second dielectric constants being different; and slicing the alternating first and second dielectric constant assembly to form discs having the ferrite rod alternatingly surrounded by the first dielectric constant segments and the second dielectric constant segments. 18. The method of claim 17 wherein the grooves extend completely through the diameter of the tube. 19. The method of claim 17 wherein the grooves are spaced approximately 120 degrees apart. 20. The method of claim 17 wherein the first dielectric constant tube has a diameter of 25 mm or less.