Geometrically configurable multi-core inductor and methods for tools having particular space constraints

What is claimed: 1. An apparatus, comprising: a downhole logging tool disposed within a wellbore; a housing located within the downhole logging tool; an instrument configured to take downhole measurements; a printed circuit board positioned within the housing, wherein the printed circuit board is coupled to the instrument; and a multicore inductor coupled to the printed circuit board, the multicore inductor being shaped to fit within the housing, wherein the multicore inductor comprises: a generally toroidal ferromagnetic first core having a first aperture formed therethrough along a first axis; a generally toroidal ferromagnetic second core having a second aperture formed therethrough along a second axis, said second core disposed in proximity to said first core so that said second axis is not coaxial with said first axis; a generally toroidal ferromagnetic third core having a third aperture formed therethrough along a third axis, said third core disposed in proximity to said first core so that said third axis is not coaxial with said first axis; and an electrically conductive wire forming a first coil wound about said first and second cores passing through said first and second apertures and a second coil wound about said first and third cores passing through said first and third apertures, said wire not forming a coil wound about said second and third cores passing through said second and third apertures. 2. The inductor of claim 1 further comprising: a generally toroidal ferromagnetic fourth core having a fourth aperture formed therethrough along a fourth axis, said fourth core disposed in proximity to said third core so that said fourth axis is not coaxial with said third axis; said wire forming a third coil wound about said third and fourth cores passing through said third and fourth apertures. 3. The inductor of claim 2 wherein: said fourth core is disposed in proximity to said second core so that said fourth axis is not coaxial with said second axis; and said wire forms a fourth coil wound about said fourth and second cores passing through said fourth and second apertures. 4. The inductor of claim 2 wherein: said first axis is parallel to said fourth axis; and said second axis is parallel to said third axis. 5. The inductor of claim 4 wherein: said first axis is perpendicular to said second axis. 6. The inductor of claim 4 wherein: said first axis is parallel to said second axis. 7. The inductor of claim 1 further comprising: a generally toroidal ferromagnetic fourth core having a fourth aperture formed therethrough along a fourth axis, said fourth core disposed in proximity to said first core so that said fourth axis is not coaxial with said first axis; and a generally toroidal ferromagnetic fifth core having a fifth aperture formed therethrough along a fifth axis, said fifth core disposed in proximity to said first core so that said fifth axis is not coaxial with said first axis; said wire forming a third coil wound about said first and fourth cores passing through said first and fourth apertures and a fourth coil wound about said first and fifth cores passing through said first and fifth apertures. 8. An apparatus, comprising: a downhole logging tool disposed within a wellbore; a housing located within the downhole logging tool; an instrument configured to take downhole measurements; a printed circuit board positioned within the housing, wherein the printed circuit board is coupled to the instrument; and a multicore inductor coupled to the printed circuit board, the multicore inductor being shaped to fit within the housing, wherein the multicore inductor comprises: a non-coaxial array of at least four generally toroidal ferromagnetic cores; and an electrically conductive wire forming coils wound through pairs of proximate cores within said array to create an arrangement whereby all coils wound about a given core in said array operate to produce magnetic flux flowing in the same direction within said given core upon imposition of an electrical current through said wire. 9. The inductor of claim 8 , wherein: said array is characterized by a polygonal shape. 10. The inductor of claim 8 , wherein: said array is generally planar. 11. A downhole logging tool, comprising: a housing located within the downhole logging tool; an instrument configured to take downhole measurements; a printed circuit board positioned within the housing, wherein the printed circuit board is coupled to the instrument; and a multicore inductor coupled to the printed circuit board, the multicore inductor being shaped to fit within a space within the housing; wherein the multicore inductor comprises: a non-coaxial array of at least four generally toroidal ferromagnetic cores; and an electrically conductive wire disposed in said housing and forming coils wound through pairs of proximate cores within said array to create an arrangement whereby all coils wound about a given core in said array operate to produce magnetic flux flowing in the same direction within said given core upon imposition of an electrical current through said wire. 12. The downhole tool of claim 11 , wherein: a first core of said array has a first aperture formed therethrough along a first axis; a second core of said array has a second aperture formed therethrough along a second axis, said second core disposed in proximity to said first core so that said second axis is not coaxial with said first axis; a third core of said array has a third aperture formed therethrough along a third axis, said third core disposed in proximity to said first core so that said third axis is not coaxial with said first axis; and said wire forms a first coil wound about said first and second cores passing through said first and second apertures and a second coil wound about said first and third cores passing through said first and third apertures. 13. The downhole tool of claim 12 wherein: a fourth core of said array has a fourth aperture formed therethrough along a fourth axis, said fourth core disposed in proximity to said third core so that said fourth axis is not coaxial with said third axis; and said wire forms a third coil wound about said third and fourth cores passing through said third and fourth apertures. 14. The downhole tool of claim 13 wherein: said fourth core is disposed in proximity to said second core so that said fourth axis is not coaxial with said second axis; and said wire forms a fourth coil wound about said fourth and second cores passing through said fourth and second apertures. 15. The downhole tool of claim 13 wherein: said first axis is parallel to said fourth axis; and said second axis is parallel to said third axis. 16. The downhole tool of claim 15 wherein: said first axis is perpendicular to said second axis. 17. The downhole tool of claim 15 wherein: said first axis is parallel to said second axis. 18. A method for forming an inductor, comprising: determining geometric space constraints of a downhole logging tool to be disposed within a wellbore, wherein the downhole logging tool contains a housing; placing an instrument within the housing; designing a printed circuit board to fit within the housing, wherein the printed circuit board is coupled to the instrument; providing a generally toroidal ferromagnetic first core having a first aperture formed therethrough along a first axis; disposing a generally toroidal ferromagnetic second core having a second aperture formed therethrough along a secon