Isolated probe tip

The invention claimed is: 1. A probe tip for an isolated probe having a triaxial cable, comprising: a conductive probe tip interface at one end of the cable; a signal conductor, the signal conductor traversing a length of the cable and electrically connected to the conductive probe tip interface; a reference conductor surrounding the signal conductor along the length of the cable; a shield conductor surrounding the reference conductor at least along the length of the cable, the shield conductor and the reference conductor electrically connected at ends of the probe tip; a first insulator between the signal conductor and the reference conductor along the length of the cable; a second insulator between the reference conductor and the shield conductor along the length of the cable; and high magnetic permeability material inside the shield conductor. 2. The probe tip as claimed in claim 1 , wherein the high magnetic permeability material comprises a common mode choke at one or both ends of the cable, and the shield conductor further comprises a conductive shell housing the common mode choke. 3. The probe tip as claimed in claim 1 , further comprising high magnetic permeability material outside of the shield conductor. 4. The probe tip as claimed in claim 1 , further comprising a printed circuit board connected to an end of the cable opposite the conductive probe tip interface. 5. The probe tip as claimed in claim 4 , wherein the printed circuit board includes a common mode choke. 6. The probe tip as claimed in claim 1 , wherein the high magnetic permeability material comprises a ferrite. 7. The probe tip as claimed in claim 1 , wherein the high magnetic permeability material inside the shield conductor lies between the shield conductor and the reference conductor. 8. The probe tip as claimed in claim 1 , wherein the high magnetic permeability material inside the shield conductor is integrated into material of the second insulator. 9. A method of manufacturing a tip for an isolated probe having a triaxial cable, comprising: accessing a shield conductor of the triaxial cable, wherein the triaxial cable includes a signal conductor, a first insulator surrounding the signal conductor, a reference conductor surrounding the first insulator, a second insulator surrounding the reference conductor, and the shield conductor surrounding the second insulator; inserting a high magnetic permeability material between the shield conductor and the reference conductor in the triaxial cable; and electrically connecting the shield conductor to the reference conductor. 10. The method of manufacturing as claimed in claim 9 , further comprising placing high magnetic permeability material outside the shield conductor. 11. The method of manufacturing as claimed in claim 9 , wherein accessing the shield conductor comprises unbraiding the shield conductor at ends of the cable and wrapping the shield conductor over the high magnetic permeability material before electrically connecting the shield conductor to the reference conductor. 12. The method of manufacturing as claimed in claim 9 , wherein accessing the shield conductor comprises removing a portion of the shield conductor at ends of the cable, and the method further comprises: placing a braid having a larger diameter than the shield conductor at each end of the cable to hold the high magnetic permeability material; and soldering the larger diameter braid to the shield conductor. 13. The method of manufacturing as claimed in claim 9 , wherein: accessing the shield conductor comprises: coating an end of the cable with an anti-fraying material; trimming the anti-fraying material; and creating openings in an end of the cable, the openings exposing the shield conductor; inserting the high magnetic permeability material comprises sliding the high magnetic permeability material into the openings against the shield conductor; and removing the anti-fraying material. 14. The method as claimed in claim 13 , wherein creating openings comprises using wedges of a material other than the high magnetic permeability material to expand the shield conductor. 15. A triaxial cable, comprising: a signal conductor, the signal conductor traversing a length of the cable; a reference conductor surrounding the signal conductor along the length of the cable; a shield conductor surrounding the reference conductor along the length of the cable, the shield conductor and the reference conductor electrically connected at ends of the cable; a first insulator between the signal conductor and the reference conductor along the length of the cable; a second insulator between the reference conductor and the shield conductor along the length of the cable; and high magnetic permeability material inside the shield conductor. 16. The cable as claimed in claim 15 , further comprising high magnetic permeability material outside of the shield conductor. 17. The cable as claimed in claim 15 , wherein the high magnetic permeability material comprises a common mode choke at one or both ends of the cable, the cable further comprising a conductive metal shell electrically connected to the shield conductor. 18. The cable as claimed in claim 15 , wherein the high magnetic permeability material comprises a ferrite. 19. The cable as claimed in claim 15 , wherein the high magnetic permeability material inside the shield conductor lies between the shield conductor and the reference conductor. 20. The cable as claimed in claim 15 , wherein the high magnetic permeability material inside the shield conductor is integrated into material of the second insulator.