Coaxial electrical interconnect

What is claimed is: 1. A coaxial electrical interconnect, comprising: an inner conductor including an electrically conductive spring probe; and a plurality of outer conductors including a plurality of electrically conductive spring probes disposed around the inner conductor, each spring probe having a barrel with a spring positioned to bias a plunger out of the barrel, the plunger having a first plunger portion external to the barrel and a second plunger portion disposed partially in the barrel, the first and second plunger portions having different diameters, wherein a barrel of the spring probe of the inner conductor is located proximate a plunger of at least one of the spring probes of the outer conductors; and wherein the spring probe of the inner conductor is inverted relative to the spring probes of the outer conductors. 2. The coaxial electrical interconnect of claim 1 , wherein the spring probes of the inner and outer conductors are substantially identical. 3. The coaxial electrical interconnect of claim 1 , wherein the spring probes of the outer conductor are disposed in a circular configuration about the spring probe of the inner conductor. 4. The coaxial electrical interconnect of claim 1 , further comprising a spring probe support member configured to provide mechanical support for the spring probes of the inner and outer conductors. 5. The coaxial electrical interconnect of claim 4 , wherein the spring probe support member is constructed of a dielectric material. 6. The coaxial electrical interconnect of claim 4 , wherein the spring probe support member is engaged with the first plunger portion of the spring probe of the inner conductor and with the barrels of the spring probes of the outer conductor. 7. The coaxial electrical interconnect of claim 1 , wherein the first plunger portion of the spring probe of the inner conductor and the barrels of the spring probes of the outer conductor are substantially equal in length to facilitate maintaining a characteristic impedance of the electrical interconnect as the plungers move relative to the barrels. 8. The coaxial electrical interconnect of claim 1 , wherein the spring probe of the inner conductor and the plurality of spring probes of the outer conductor are sized and positioned relative to one another to provide a given characteristic impedance. 9. The coaxial electrical interconnect of claim 1 , wherein a first region of the electrical interconnect comprises the first plunger portion of the spring probe of the inner conductor and the barrels of the spring probes of the outer conductor, a second region of the electrical interconnect comprises the second plunger portions of the spring probes of the inner and outer conductors, and a third region of the electrical interconnect comprises the barrel of the spring probe of the inner conductor and the first plunger portions of the spring probes of the outer conductor, and wherein the spring probes of the inner and outer conductors are sized and positioned relative to one another to provide given characteristic impedances for the first, second, and third regions. 10. The coaxial electrical interconnect of claim 9 , wherein the given characteristic impedances of the first, second, and third regions are the same. 11. The coaxial electrical interconnect of claim 9 , wherein the first region further comprises a dielectric support member configured to provide mechanical support for the spring probes of the inner and outer conductors. 12. A method for facilitating a matched impedance electrical connection, comprising: providing a coaxial electrical interconnect, having an inner conductor including an electrically conductive spring probe, and a plurality of outer conductors including a plurality of electrically conductive spring probes disposed around the inner conductor, each spring probe having a barrel with a spring positioned to bias a plunger out of the barrel, the plunger having a first plunger portion external to the barrel and a second plunger portion disposed partially in the barrel, the first and second plunger portions having different diameters, wherein a barrel of the spring probe of the inner conductor is located proximate a plunger of at least one of the spring probes of the outer conductors; wherein the spring probe of the inner conductor is inverted relative to the spring probes of the outer conductors; and facilitating a constant characteristic impedance of the electrical interconnect as the plungers move relative to the barrels. 13. The method of claim 12 , wherein facilitating a constant characteristic impedance comprises sizing the first plunger portion of the spring probe of the inner conductor and the barrels of the spring probes of the outer conductor with substantially equal lengths.