Reinforced key assembly

What is claimed is: 1. A dome switch, comprising: a base; a dome disposed over the base and having a substantially circular perimeter; a collar surrounding the dome and connected along the substantially circular perimeter and having a raised portion extending from the base; a key cap positioned above the dome; and a sensing structure configured to detect a collapse of the dome caused by a depression of the key cap, wherein the raised portion limits a downward motion of the key cap when the dome is collapsed. 2. The dome switch of claim 1 , wherein the sensing structure comprises: a first sensing element disposed on the base and configured to detect contact of an interior surface of the upper portion of the dome with the base; and a second sensing element disposed on the collar and configured to detect at least one of: motion of the dome; or contact between the raised portion and the key cap. 3. The dome switch of claim 2 , wherein: the first sensing element is configured to generate a first output in response to detecting the contact of the interior surface with the base; and the second sensing element is configured to generate a second output in response to at least one of: detecting the motion of the dome; and detecting the contact between the raised portion and the key cap. 4. The dome switch of claim 1 , wherein the raised portion of the collar is configured to impede deformation of the dome after the upper portion contacts the base. 5. The dome switch of claim 1 , wherein the collar is configured such that a force-displacement curve characteristic of the dome has at least two peaks. 6. The dome switch of claim 1 , wherein: the dome and the collar define a gap therebetween; and the gap is configured to shrink as the dome deforms. 7. A method of operating a dome switch, comprising: receiving a first displacement at a key cap positioned above a dome, thereby buckling the dome; detecting a contact between an inner portion of the dome and a base portion disposed below the dome caused by the first displacement of the key cap; generating a first user input signal in response to detecting the contact; receiving a second displacement at the key cap that is greater than the first displacement; detecting the second displacement of the key cap; resisting the second displacement using a raised portion of a collar that is connected to a substantially circular perimeter of the dome; and generating a second user input signal in response to detecting the second displacement. 8. The method of claim 7 , wherein detecting the second displacement occurs while the contact between the inner portion and the base portion is maintained. 9. The method of claim 7 , wherein the dome buckles so that the contact between the inner portion and the base portion occurs. 10. The method of claim 7 , further comprising: identifying an orientation of at least one of the first displacement or the second displacement of the key cap relative to the collar. 11. The method of claim 7 , further comprising: in response to detecting the second displacement, generating a first haptic effect; and in response to the contact, generating a second haptic effect. 12. A dome switch, comprising: a base; a key cap positioned above the base; a dome having: an upper portion positioned below the key cap; and a lower portion positioned on the base and defining a substantially circular perimeter; a collar positioned about the substantially circular perimeter and having a raised portion that extends toward an underside of the key cap; and a sensing element disposed on the base and configured to detect contact of the upper portion with the base, wherein the raised portion limits a downward motion of the key cap. 13. The dome switch of claim 12 , wherein: the dome comprises a dome wall extending between the upper and lower portions; the dome is configured to buckle in response to a buckling force; and a portion of the dome wall contacts the raised portion when the dome buckles, thereby causing the collar to resist deformation of the dome in response to an input force exceeding the buckling force. 14. The dome switch of claim 13 , wherein: the sensing element is a first sensing element; and the dome switch further comprises: a second sensing element positioned on the collar and configured to produce an electrical response in response to deformation of the dome. 15. The dome switch of claim 14 , wherein the second sensing element comprises an array of capacitive-sensing elements disposed on a top surface of the collar. 16. The dome switch of claim 15 , wherein: a portion of the key cap relative to each element of the array of capacitive-sensing elements defines an orientation of the key cap; and the array of capacitive-sensing elements is configured to generate an output based on the orientation. 17. The dome switch of claim 13 , wherein the collar relieves stress within the dome when the input force exceeds the buckling force. 18. The dome switch of claim 13 , wherein the dome wall and the collar cooperate to control the input force required to deform the upper portion. 19. The dome switch of claim 13 , wherein the raised portion has a thickness greater than a thickness of the dome wall. 20. The dome switch of claim 13 , wherein a thickness of the lower portion is greater than a thickness of the upper portion. 21. The dome switch of claim 12 , wherein the collar defines a chamfer opposite the dome. 22. The dome switch of claim 21 , wherein the chamfer includes a sensing structure configured to detect at least one of a first deformation or a second deformation of the dome. 23. The dome switch of claim 12 , wherein: the dome comprises a first material having a first stiffness; and the collar comprises a second material having a second stiffness that differs from the first stiffness. 24. The dome switch of claim 12 , wherein the collar is molded to the dome about the substantially circular perimeter.