Magnetic omni-wheel with roller bracket

What is claimed is: 1. A multidirectional wheel for traversing a surface having a contour, comprising: at least one hub, the at least one hub defining a first axial direction of rotation; at least one magnet having an outer face arranged to generally circumscribe the first axial direction, wherein the hub is made of a magnetically inducible material which directs the flux of the at least one magnet toward the surface being traversed; a plurality of magnetically inducible brackets disposed around an entirety of an outer periphery of the at least one hub, each of the brackets being sized and shaped with a profile that is non-symmetric with respect to an axial plane that bisects the bracket to define a wheel profile that complements the contour of the surface such that the size of an air gap is reduced as compared to a wheel profile that does not complement the contour of the surface at each rotational position of the wheel; and a plurality of rollers supported for rotation by the plurality of brackets, the rollers being supported by the brackets for rotation in a second axial direction that is at an angle to the first axial direction, wherein at least one roller contacts the surface in any rotational position of the wheel as the wheel traverses the surface while defining the air gap between the surface and the outer face of the magnet, the hub, and the brackets. 2. The multidirectional wheel as in claim 1 , wherein the brackets are sized and shaped to define a convex wheel profile. 3. The multidirectional wheel as in claim 2 , wherein the brackets include a tapered portion. 4. The multidirectional wheel as in claim 1 , wherein the brackets are sized and shaped to define a flat wheel profile. 5. The multidirectional wheel as in claim 4 , wherein the brackets include a flat portion. 6. The multidirectional wheel as in claim 1 , wherein the brackets are sized and shaped to define a concave wheel profile. 7. The multidirectional wheel as in claim 6 , wherein the brackets include a protrusion portion. 8. The multidirectional wheel as in claim 1 , wherein the wheel profile complements the contour of the surface according to the following combinations: (1) the wheel profile is convex and the surface contour is concave; (2) the wheel profile is flat and the surface contour is flat; and (3) the wheel profile is concave and the surface contour is convex. 9. The multidirectional wheel as in claim 1 , wherein the brackets include a mount that supports the roller and a protrusion. 10. The multidirectional wheel as in claim 9 , wherein the protrusion is lobe shaped. 11. The multidirectional wheel as in claim 9 , wherein the protrusion is flat shaped. 12. The multidirectional wheel as in claim 9 , wherein the protrusion is taper shaped. 13. The multidirectional wheel as in claim 1 , wherein there are two hubs defining the first axial direction of rotation and wherein the at least one magnet comprises a disk disposed between the two hubs. 14. The multidirectional wheel as in claim 13 , wherein the brackets are disposed about each of the two hubs. 15. The multidirectional wheel as in claim 14 , wherein the brackets disposed about each of the two hubs, the hubs, and the magnet collectively define a concave profile. 16. The multidirectional wheel as in claim 14 , wherein the brackets disposed about each of the two hubs, the hubs, and the magnet collectively define a convex profile. 17. The multidirectional wheel as in claim 14 , wherein the brackets disposed about each of the two hubs, the hubs, and the magnet collectively define a flat profile. 18. The multidirectional wheel as in claim 13 , further comprising a motor wherein at least one of the two hubs is operationally coupled to the motor for driven rotation. 19. The multidirectional wheel as in claim 18 , further comprising an axle operationally coupled to the motor and the at least one of the two hubs. 20. A multidirectional wheel for traversing a surface having a contour, comprising: at least one hub, the at least one hub defining a first axial direction of rotation; at least one magnet having an outer face arranged to generally circumscribe the first axial direction, wherein the hub is made of a magnetically inducible material which directs the flux of the at least one magnet toward the surface being traversed; a plurality of magnetically inducible brackets disposed around an entirety of a radial outer periphery of the at least one hub, the brackets being sized and shaped to define a wheel profile that complements the contour of the surface such that the size of an air gap is reduced as compared to a wheel profile that does not complement the contour of the surface at each rotational position of the wheel; a plurality of fasteners adapted to removably couple the each of the plurality of magnetically inducible brackets to the radial outer periphery of the at least one hub; and a plurality of rollers supported for rotation by the plurality of brackets, the rollers being supported by the brackets for rotation in a second axial direction that is at an angle to the first axial direction, wherein at least one roller contacts the surface in any rotational position of the wheel as the wheel traverses the surface while defining the air gap between the surface and the outer face of the magnet, the hub, and the brackets, and wherein the plurality of magnetically inducible brackets includes a first plurality of brackets having a first size and shape adapted for installation on the wheel and complementing the contour of the surface when the contour is convex, and a second plurality of brackets interchangeable with the first plurality of brackets having a second size and shape and adapted for installation on the wheel and complementing the contour of the surface when the contour is concave, the first and second plurality of brackets being removably coupled to the radial outer periphery of at least one hub via the fasteners.