Force determination based on capacitive sensing

We claim: 1. An electronic device comprising: a cover glass; a touch sensor comprising one or more arrays of conductive lines integrated with the cover glass and configured to detect a location of a touch on the cover glass; a force-sensing structure disposed at a periphery of the touch sensor, wherein the force-sensing structure comprises: a first layer of polyimide flex material; a first capacitive plate on the first layer of polyimide flex material; a second layer of polyimide flex material; a second capacitive plate disposed on the second layer of polyimide flex material; and a compressible dielectric element disposed between the first capacitive plate and the second capacitive plate; and force-sensing circuitry configured to detect changes in capacitive coupling between the first capacitive plate and the second capacitive plate due to compression of the compressible dielectric element, and to produce a signal that corresponds to a magnitude of a touch force on the touch sensor, wherein: the compressible dielectric element of the force-sensing structure is configured to compress in response to the touch force on the touch sensor; the force-sensing structure encircles an interior cavity of the electronic device; the first capacitive plate is positioned closer to the compressible dielectric element than the first layer of polyimide flex material, the second capacitive plate is positioned closer to the compressible dielectric element than the second layer of polyimide flex material, and the first layer of polyimide flex material is positioned between the cover glass and the first capacitive plate; a portion of the first capacitive plate extends outward from the first layer of polyimide flex material, towards the interior cavity, and a portion of the second capacitive plate extends outward from the second layer of polyimide flex material, towards the interior cavity; and the portions of the first capacitive plate and the second capacitive plate are operatively coupled to the force-sensing circuitry. 2. The electronic device of claim 1 , wherein the force-sensing structure is a first force-sensing structure disposed along a first edge of the touch sensor, the electronic device further comprising: a second force-sensing structure disposed along a second edge of the touch sensor, the second force-sensing structure comprising: a third layer of polyimide flex material; a third capacitive plate; a fourth layer of polyimide flex material; a fourth capacitive plate; and a second compressible dielectric element disposed between the third capacitive plate and the fourth capacitive plate; wherein: the third capacitive plate is positioned closer to the second compressible dielectric element than the third layer of polyimide flex material, and the fourth capacitive plate is positioned closer to the second compressible dielectric element than the fourth layer of polyimide flex material; and the force-sensing circuitry operatively coupled to the first force-sensing structure and the second force-sensing structure and configured to detect changes in capacitive coupling due to deflection of the first force-sensing structure and the second force-sensing structure, wherein the force-sensing circuitry is further configured to produce the signal that corresponds to the magnitude of the touch force on the touch sensor. 3. The electronic device of claim 1 , wherein the touch sensor is a capacitive touch sensor. 4. The electronic device of claim 1 , further comprising: an enclosure having an opening and a bezel surrounding the opening; and a display element disposed within the enclosure, below the cover glass, and viewable through the opening of the enclosure. 5. A force-sensing structure, comprising: an upper body comprising a dielectric layer; an upper capacitive plate connected to the upper body; a lower body; a lower capacitive plate connected to the lower body; a deformable middle body connected to one of the upper body and the upper capacitive plate, the deformable middle body further connected to one of the lower body and the lower capacitive plate; and an electrical connector tail configured to electrically connect the force-sensing structure to a force-sensing circuit, wherein: each of the upper body, the upper capacitive plate, the lower body, the lower capacitive plate, and the deformable middle body defines a hole for positioning a display, wherein the force-sensing structure is disposed at a periphery of a cover glass and around the display, and between the cover glass and a ledge of a housing of an electronic device, with the dielectric layer oriented toward the cover glass; the lower body comprises a second dielectric layer; and the electrical connector tail comprises: a first circuit layer comprising a first flexible conductive layer electrically connected with the upper capacitive plate, a second circuit layer comprising a second flexible conductive layer electrically connected with the lower capacitive plate, and an end portion configured to be detachably connected to a circuit component. 6. The force-sensing structure of claim 5 , wherein the deformable middle body is configured to deform in response to a force on the force-sensing structure. 7. The force-sensing structure of claim 5 , further comprising the force-sensing circuit, wherein the upper capacitive plate and the lower capacitive plate are operatively coupled to the force-sensing circuit, and the force-sensing circuit is configured to detect changes in capacitive coupling between the upper capacitive plate and the lower capacitive plate due to deformation of the deformable middle body. 8. The force-sensing structure of claim 7 , wherein the force-sensing circuit is further configured to produce a signal that corresponds to a magnitude of a force on the force-sensing structure. 9. An electronic device comprising: a cover glass; a touch sensor comprising one or more arrays of conductive lines integrated with the cover glass and configured to detect a location of a touch on the cover glass; a display disposed below the cover glass; a force-sensing structure disposed around the display, wherein the force-sensing structure comprises: a first layer of polyimide flex material; a first capacitive plate on the first layer of polyimide flex material; a second layer of polyimide flex material; a second capacitive plate disposed on the second layer of polyimide flex material; a compressible element disposed between the first capacitive plate and the second capacitive plate; and an electrical connector tail for electrically connecting the force-sensing structure to force-sensing circuitry, wherein: each of the first layer, the first capacitive plate, the second layer, the second capacitive plate, and the compressible element defines a hole in which the display is positioned; the first capacitive plate is positioned closer to the compressible element than the first layer of polyimide flex material, the second capacitive plate is positioned closer to the compressible element than the second layer of polyimide flex material, and the first layer of polyimide flex material is positioned between the cover glass and the first capacitive plate; and the electrical connector tail comprises a first circuit layer comprising a first flexible conductive layer electrically connected with the first capacitive plate, a second circuit layer comprising a second flexible conductive layer electrically connected with the second capacitive plate, and an end portion configured to be detachably connected to a circuit component, wherein the end portion includes a void region between the first circuit layer and the second circuit layer. 1