Flexible haptic actuator

The invention claimed is: 1. A flexible haptic actuator comprising: a core, the core being formed with a flexible material, the core defining a volume, the core being bendable; an electromagnetic coil coiled around the core, the electromagnetic coil being bendable; a casing surrounding the electromagnetic coil and at least a part of the core, the casing including a plurality of flexible sections and a plurality of stiff sections, the casing being bendable; and a haptic mass suspended in the volume, the haptic mass at least partially formed with a ferromagnetic material, the haptic mass movable in the volume in response to the electromagnetic coil generating a magnetic field. 2. The flexible haptic actuator of claim 1 wherein the core has an inner surface and the inner surface has a circular cross section. 3. The flexible haptic actuator of claim 2 wherein: the core comprises particles of a ferrous material. 4. The flexible haptic actuator of claim 3 wherein: the flexible material in the core is elastic. 5. The flexible haptic actuator of claim 3 wherein: the flexible material is selected from the group consisting of a gel, a ferromagnetic gel-like suspension, rubber, polyacrylic, silicon, fluorosilicon, fluoroelastomer, polyurethane rubbers, and combinations thereof. 6. The flexible haptic actuator of claim 3 wherein: the core comprises an annular wall and the electromagnetic coil is embedded in annular wall. 7. The flexible haptic actuator of claim 1 wherein: the haptic mass has a path of travel in the volume; and the electromagnetic coil has a body length at least as long as the path of travel. 8. The flexible haptic actuator of claim 7 wherein: the haptic mass has a path of travel in the volume; and the electromagnetic coil has a body length about the same length as the path of travel. 9. The flexible haptic actuator of claim 1 wherein: the electromagnetic coil comprises a wire. 10. The flexible haptic actuator of claim 1 wherein: the casing has a length and the flexible sections and the stiff sections alternate along the length of the casing. 11. The flexible haptic actuator of claim 10 where: the flexible sections are formed at least in part by an elastic material. 12. The flexible haptic actuator of claim 11 wherein: the casing comprises a plurality of annular ridges and troughs, the ridges and troughs extending around a circumference of the casing; each trough comprising a bottom portion, a cross-section of the bottom portion being arcuate, the bottom portion of each trough forming one of the plurality of flexible sections; and each ridge comprising a peak, a cross section of the peak being arcuate, each ridge forming one of the plurality of stiff sections. 13. The flexible haptic actuator of claim 11 wherein: the casing comprises a plurality of annular pleats, each pleat extending around a circumference of the casing. 14. The flexible haptic actuator of claim 11 wherein: the casing has an outer surface, the outer surface being substantially flat. 15. The flexible haptic actuator of claim 11 wherein: the flexible portions have an axial length and the stiff portions have an axial length; and the axial length of at least one flexible portion being different than the axial length of at least one stiff portion. 16. The flexible haptic actuator of claim 11 wherein: the casing has an outer wall, the outer wall having a cross section; and the cross section is circular. 17. The flexible haptic actuator of claim 11 wherein: the casing has an outer wall, the outer wall having a cross section; and the cross section is quadrilateral. 18. The flexible haptic actuator of claim 1 wherein: the haptic mass is spherical. 19. The flexible haptic actuator of claim 1 wherein: the haptic mass is a polyhedron. 20. The flexible haptic actuator of claim 1 wherein: the haptic mass further comprises a material selected from the group consisting of silicone, polyacrylic, fluorosilicon, fluoroelastomer, polyurethane rubbers, including carbon iron, iron oxide, nickel, is or cobalt, and combinations thereof. 21. The flexible haptic actuator of claim 1 wherein: the core has an inner surface and a centerline; and the flexible apparatus further comprises a diamagnetic material proximal the inner surface, the diamagnetic material being evenly distributed around at least a portion of the centerline. 22. The flexible haptic actuator of claim 21 wherein: the diamagnetic material is applied to the inner surface of the core. 23. The flexible haptic actuator of claim 21 wherein: the diamagnetic material is selected from the group consisting of graphite, pyrolytic carbon, bismuth, mercury, silver, diamond, lead, copper, and combinations thereof. 24. The flexible haptic actuator of claim 1 wherein: the volume contains a vacuum. 25. The flexible haptic actuator of claim 1 wherein: the volume contains non-solid medium. 26. The flexible haptic actuator of claim 1 further comprising: a first and second endcaps enclosing first and second end portions of the volume; and a spring operably connected between the first end cap and the haptic mass, the spring being axially aligned along the centerline. 27. The flexible haptic actuator of claim 26 further comprising: an articulating joint operably connected between the spring and the first end cap. 28. The flexible haptic actuator of claim 27 further wherein: the articulating joint comprises a folded sheet. 29. The flexible haptic actuator of claim 26 further comprising: another spring operably connected between the second end cap and the haptic mass, the spring being axially aligned along the centerline. 30. A method of generating a haptic effect using a haptic actuator having an electromagnetic coil wrapped around a volume, and a haptic mass suspended in the volume, the method comprising: deforming, the haptic actuator; conducting an alternating electric current through the electromagnetic coil; in response to conducting the alternating electric current, generating a magnetic field extending through the volume; in response to the generating the magnetic field, moving the haptic mass within the volume while the haptic actuator is deformed, the moving haptic mass having an oscillating path of travel. 31. The method of claim 30 wherein: deforming the haptic actuator comprises bending the haptic actuator. 32. The method of claim 31 wherein: bending the haptic actuator comprises bending intermittently spaced sections of a casing enclosing the electromagnetic coil and the volume. 33. The method of claim 31 wherein: bending the haptic actuator comprises bending the haptic actuator lout substantially changing the cross-sectional dimensions of the volume. 34. The method of claim 33 wherein: bending the haptic actuator comprises bending the haptic actuator without substantially changing a damping on movement of the haptic mass. 35. The method of claim 30 wherein: deforming the haptic actuator comprises stretching the haptic actuator along a length of the haptic actuator. 36. The method of claim 35 wherein: stretching the haptic actuator comprises stretc