Haptic enabled user interface device incorporating electropermanent magnet

What is claimed is: 1. A haptic enabled user interface device, comprising: a housing; and a haptic actuator mounted within the housing and configured to generate a haptic effect at an exterior surface of the haptic enabled user interface device, wherein the haptic actuator comprises a casing, and an electropermanent magnet disposed in the casing, the electropermanent magnet having a deactivated state and an activated state for a net magnetic field thereof, wherein the electropermanent magnet comprises, a first magnet having magnetic poles that are selectively switchable between a first polarity and a second polarity opposite the first polarity, a second magnet adjacent to the first magnet and having magnetic poles of the second magnet fixed at the first polarity, wherein a material forming the first magnet has a lower magnetic coercivity than a material forming the second magnet, and a conductive coil adjacent to the first magnet and configured to switch a polarity of the magnetic poles of the first magnet between the first polarity and the second polarity, and wherein the casing comprises a layer of ferromagnetic material located opposite an end of the electropermanent magnet, and wherein when the net magnetic field of the electropermanent magnet is in the activated state, the electropermanent magnet is configured to generate the haptic effect by actuating the layer of ferromagnetic material. 2. The haptic enabled user interface device of claim 1 , further comprising a power source configured to apply an electrical current to activate or deactivate the net magnetic field of the electropermanent magnet. 3. The haptic enabled user interface device of claim 2 , wherein the electrical current is an alternating current having a frequency that is between 1 Hz and 10 Hz, and wherein the haptic effect is a deformation-based haptic effect. 4. The haptic enabled user interface device of claim 2 , wherein the electrical current is an alternating current, wherein the haptic enabled user interface device further comprises a haptic controller, connected to the power source, that is configured to control a frequency of the alternating current based on whether the haptic actuator is to generate a vibration-based haptic effect or whether the haptic actuator is to generate a non-vibration-based haptic effect. 5. The haptic enabled user interface device of claim 1 , wherein the material forming the second magnet includes neodymium. 6. The haptic enabled user interface device of claim 5 , wherein the material forming the first magnet includes an aluminum nickel cobalt alloy. 7. The haptic enabled user interface device of claim 5 , wherein the material forming the first magnet has a magnetic field strength that is in a range of 0.1 Tesla to 1 Tesla. 8. The haptic enabled user interface device of claim 1 , wherein the housing comprises a surface layer that forms the exterior surface of the haptic enabled user interface device, wherein the layer of ferromagnetic material is adhered to the surface layer, and wherein the haptic effect is a deformation haptic effect that deforms a portion of the surface layer in an inward direction toward the electropermanent magnet. 9. The haptic enabled user interface device of claim 1 , wherein the housing comprises a surface layer that forms the exterior surface of the haptic enabled user interface device, wherein the layer of ferromagnetic material is a first layer of the casing and is not parallel with the surface layer, wherein the casing has a second layer that is parallel with the surface layer, and wherein actuation of the first layer towards the electropermanent magnet causes deformation of the second layer away from the electropermanent magnet, and wherein the haptic effect is a deformation haptic effect that deforms a portion of the surface layer in an outward direction away from the electropermanent magnet. 10. The haptic enabled user interface device of claim 1 , wherein the haptic enabled user interface device is a mobile phone. 11. The haptic enabled user interface device of claim 1 , wherein the haptic enabled user interface device is a game controller. 12. The haptic enabled user interface device of claim 1 , wherein the ferromagnetic material comprises at least one of iron, cobalt, and nickel, and not comprising any of steel, aluminum, copper, lead, or zinc. 13. The haptic enabled user interface device of claim 1 , wherein the electropermanent magnet has a thickness along an axis of the net magnetic field thereof that is in a range of 100 μm to 1 mm. 14. The haptic enabled user interface device of claim 1 , wherein a distance between the end of the electropermanent magnet and the layer of ferromagnetic material is in a range of between 20 μm and 50 μm, and wherein a thickness of the layer of ferromagnetic material is in a range of between 0.2 mm and 5 mm. 15. The haptic enabled user interface device of claim 1 , wherein the conductive coil is wrapped around only the first magnet. 16. A haptic enabled user interface device, comprising: a housing; and a haptic actuator mounted within the housing and configured to generate a haptic effect at an exterior surface of the haptic enabled user interface device, wherein the haptic actuator comprises a casing, and an electropermanent magnet disposed in the casing, the electropermanent magnet having a deactivated state and an activated state for a net magnetic field thereof, wherein the electropermanent magnet comprises a first magnet having magnetic poles that are selectively switchable between a first polarity and a second polarity opposite the first polarity, a second magnet adjacent to the first magnet and having magnetic poles of the second magnet fixed at the first polarity, wherein a material forming the first magnet has a lower magnetic coercivity than a material forming the second magnet, and a conductive coil adjacent to the first magnet and configured to switch a polarity of the magnetic poles of the first magnet between the first polarity and the second polarity, and wherein the casing comprises a layer of magneto-active polymer located opposite an end of the electropermanent magnet, wherein the magneto-active polymer comprises a polymer matrix and ferromagnetic material, and wherein when the net magnetic field of the electropermanent magnet is in the activated state, the electropermanent magnet is configured to generate the haptic effect by actuating the layer of magneto-active polymer. 17. A haptic enabled user interface device, comprising: a housing having a support surface; a display device attached to the housing and having a front surface that forms part of an exterior surface of the haptic enabled user interface device, and a back surface that forms part of an interior surface of the haptic enabled user interface device; and an array of electropermanent magnets disposed on the support surface of the housing; an array of corresponding portions of magneto-active polymer disposed on the back surface of the display device, wherein each portion of the array of corresponding portions of magneto-active polymer is located opposite an end of a corresponding electropermanent magnet of the array of electropermanent magnets, wherein each electropermanent magnet of the array of electropermanent magnets has a deactivated state and an activated state for a net magnetic field thereof, and comprises a corresponding first magnet, a corresponding second magnet, and a corresponding conductive coil, wherein the corresponding first magnet has magnetic poles that are selective