Methods and apparatus for downhole probes

What is claimed is: 1. A drilling apparatus comprising: a probe located within a bore of a drill collar coupled into a drill string comprising a plurality of sections above the drill collar in the drill string, the bore of the drill collar having a first diameter and the drill string sections having bores of a second diameter smaller than the first diameter with the bores of the drill collar and drill string sections in fluid communication permitting drilling fluid to flow through the drill string to a drill bit; and a centralizer; wherein: the probe comprises an electronics unit and a housing, wherein at least a portion of the electronics unit forms a size-on-size fit with the housing; the probe is inside the centralizer and the centralizer is in the bore of the drill collar; and the centralizer comprises: an elongated tubular member having a wall formed to provide a cross-section that provides first outwardly-convex and inwardly-concave lobes, the first lobes arranged to contact an internal wall of the drill collar at a plurality of spots spaced apart around an internal circumference of the drill collar; and a plurality of inwardly-projecting portions, each of the plurality of inwardly-projecting portions arranged between two adjacent ones of the plurality of first lobes. 2. A drilling apparatus according to claim 1 comprising a drilling fluid pump operable to pump drilling fluid through the drill string to the drill bit wherein the drilling apparatus is operable to drill a wellbore while the drilling fluid in the drill collar maintains a flow velocity of less than 41 feet per second (about 12.5 m/s). 3. A drilling apparatus according to claim 2 wherein the drill collar comprises a wall that is thinner than walls of the drill string sections. 4. A drilling apparatus according to claim 3 wherein an outer diameter of the drill collar is the same as the outer diameter of the drill string sections. 5. A drilling apparatus according to claim 3 wherein the drill collar comprises a yield strength exceeding 130,000 psi (9,140 kgf/cm 2 ). 6. A drilling apparatus according to claim 5 wherein the wall of the drill collar comprises a non-magnetic stainless steel alloy. 7. A drilling apparatus according to claim 1 wherein at least one cross-section of the probe has an area of at least pi inches squared (about 20 cm 2 ). 8. A drilling apparatus according to claim 1 wherein the probe has a diameter of at least 2.54 inches (about 6.5 cm). 9. A drilling apparatus according to claim 1 wherein the electronics unit is shaped like a cylinder and the housing is shaped like a hollow cylinder. 10. A drilling apparatus according to claim 1 wherein an entire longitudinal surface of the electronics unit is dimensioned to form a size-on-size fit with the housing. 11. A drilling apparatus according to claim 1 wherein the housing has a length to outer diameter ratio of less than 70:1. 12. A drilling apparatus according to claim 1 wherein the housing is less than 20 feet (about 6.1 m) long. 13. A drilling apparatus according to claim 1 wherein outside diameter and bore diameter of the sections of the drill string are according to an API standard the outside diameter of the drill collar corresponds to the API standard and the diameter of the bore of the drill collar is larger than specified by the API standard. 14. A drilling apparatus according to claim 1 wherein: the drill string sections have outer diameters of 4¾ inches and a cross sectional area of the fluid flow path in the bore of the drill collar around the probe is at least 2¾ in 2 (17.7 cm 2 ); or the drill string sections have outer diameters of 6½ inches and a cross sectional area of the fluid flow path in the bore of the drill collar around the probe is at least 5.3 in 2 (34.1 cm 2 ); or the drill string sections have outer diameters of 8 inches and a cross sectional area of the fluid flow path in the bore of the drill collar around the probe is at least 10.6 in 2 (68.2 cm 2 ). 15. A drilling apparatus according to claim 1 wherein the probe has no resonant modes having frequencies of less than 15 Hertz. 16. A method for subsurface drilling, the method comprising: providing a drill collar having a bore of a first diameter; inserting a probe into the bore of the drill collar and connecting the drill collar to a drill string comprising a plurality of sections above the drill collar, the sections having bores of a second diameter less than the first diameter; and while drilling, passing a drilling fluid through the bores of the sections and the bore of the drill collar while maintaining a flow velocity of the drilling fluid less than 41 feet per second (about 12.5 m/s) in the bore of the drill collar; inserting the probe into a centralizer; and inserting the centralizer into the bore of the drill collar; wherein the centralizer comprises: an elongated tubular member having a wall formed to provide a cross-section that provides first outwardly-convex and inwardly-concave lobes, the first lobes arranged to contact an internal wall of the drill collar at a plurality of spots spaced apart around an internal circumference of the drill collar; and a plurality of inwardly-projecting portions, each of the plurality of inwardly-projecting portions arranged between two adjacent ones of the plurality of first lobes. 17. A method according to claim 16 wherein the drill collar comprises a wall that is thinner than walls of the drill string sections. 18. A method according to claim 17 wherein the outer diameter of the drill collar is the same as the outer diameter of the drill string sections. 19. A method according to claim 16 wherein the drill collar comprises a yield strength of at least 130,000 psi (9,140 kgf/cm 2 ). 20. A method according to claim 19 wherein the drill collar comprises a non-magnetic stainless steel alloy. 21. A method according to claim 16 wherein at least one cross-section of the probe has an area of at least pi inches squared (about 20 cm 2 ). 22. A method according to claim 16 wherein at least one cross-section of the probe has an area of at least 3.5 inches squared (about 23 cm 2 ). 23. A method according to claim 16 wherein providing the probe comprises: providing an electronics unit and a housing; and inserting the electronics unit into the housing; wherein at least a portion of the electronics unit forms a size-on-size fit with the housing. 24. A method according to claim 23 wherein the electronics unit is shaped like a cylinder and the housing is shaped like a hollow cylinder. 25. A method according to claim 23 wherein an entire longitudinal surface of the electronics unit is dimensioned to form a size-on-size fit with the housing that prevents the electronics unit from moving laterally relative to the housing. 26. A method according to claim 23 comprising providing a thin material between an exterior lateral wall of the electronics unit and an interior lateral wall of the housing. 27. A method according to claim 23 wherein the housing has a length to outer diameter ratio of less than 70:1. 28. A method according to claim 23 wherein the housing is less than 20 feet long (about 6.1 m). 29. A method according to claim 23 comprising mechanically coupling the housing to the drill collar.