Controller with sensor-rich controls

What is claimed is: 1. A controller system comprising: one or more processors; and a controller comprising: a housing having an opening defined therein; and a trackpad disposed within the opening defined in the housing, the trackpad comprising: a cover; a touch sensor disposed underneath, and coupled to, the cover, wherein the touch sensor is configured to provide, to the one or more processors, touch data indicative of an object touching the cover; a carrier disposed underneath the touch sensor and coupled to the cover; at least one biasing member coupled to the carrier and to the housing, wherein a center portion of the at least one biasing member comprises one or more holes configured to receive corresponding projections extending from a rear side of the carrier, wherein the at least one biasing member biases a portion of the cover against an inner surface of the housing and is configured to deflect in response to the object pressing on the cover; a metal layer disposed underneath, and coupled to, the carrier; and a pressure sensor coupled to the housing and disposed underneath, and spaced a distance from, the metal layer, wherein the pressure sensor is configured to provide, to the one or more processors, force data indicative of an amount of force of a press on the cover based at least in part on a proximity of the metal layer to the pressure sensor. 2. The controller system of claim 1 , wherein the metal layer comprises copper foil. 3. The controller system of claim 1 , wherein the metal layer is attached to a bottom surface of the carrier. 4. The controller system of claim 1 , wherein the trackpad further comprises a haptic actuator disposed underneath the touch sensor and configured to provide haptic feedback in response to the amount of the force of the press satisfying a threshold. 5. The controller system of claim 4 , wherein the at least one biasing member is a first anisotropic spring coupled to a first side of the carrier, and wherein the trackpad further comprises: a second anisotropic spring coupled to the housing and to a second side of the carrier opposite the first side, wherein the second anisotropic spring is configured to deflect in response to the object pressing on the cover, and wherein the first anisotropic spring and the second anisotropic spring are configured to deflect in response to the haptic feedback provided by the haptic actuator. 6. The controller system of claim 1 , wherein the force data comprises capacitance values that vary in response to variable proximity of the metal layer relative to the pressure sensor. 7. The controller system of claim 1 , wherein the pressure sensor comprises a substrate including an electrode configured to measure a change in capacitance based on movement of the metal layer relative to the pressure sensor. 8. A controller system comprising: one or more processors; and a controller comprising: a housing; and a control configured to be operated by a finger, the control comprising: a cover; a touch sensor disposed underneath, and coupled to, the cover, wherein the touch sensor is configured to provide, to the one or more processors, touch data indicative of the finger touching the cover; a carrier disposed underneath the touch sensor and coupled to the cover; at least one biasing member coupled to the carrier and to the housing, wherein a center portion of the at least one biasing member comprises one or more holes configured to receive corresponding projections extending from a rear side of the carrier, wherein the at least one biasing member is configured to apply a biasing force on the carrier in an opposite direction to that of a force of a press of the finger on the cover; a metal layer disposed underneath, and coupled to, the carrier; and a pressure sensor coupled to the housing and disposed underneath, and spaced a distance from, the metal layer, wherein the pressure sensor is configured to provide, to the one or more processors, force data indicative of an amount of the force of the press of the finger on the cover based at least in part on a proximity of the metal layer to the pressure sensor. 9. The controller system of claim 8 , wherein the carrier is configured to deflect towards the pressure sensor in response to the finger pressing on the cover, and wherein the metal layer is configured to deflect towards the pressure sensor in response to the carrier deflecting towards the pressure sensor. 10. The controller system of claim 8 , wherein the metal layer comprises copper foil. 11. The controller system of claim 8 , wherein the control further comprises a haptic actuator disposed underneath the touch sensor and configured to provide haptic feedback in response to the amount of the force of the press satisfying a threshold. 12. The controller system of claim 8 , wherein the control comprises a trackpad. 13. The controller system of claim 8 , wherein the at least one biasing member biases a portion of the cover against an inner surface of the housing. 14. The controller system of claim 8 , wherein the distance the pressure sensor is spaced from the metal layer is at least about 0.5 millimeters (mm). 15. The controller system of claim 8 , wherein the controller further comprises a thumbstick comprising: a potentiometer configured to sense a deflection of the thumbstick; and capacitive sensors disposed in or on a top of the thumbstick, the capacitive sensors configured to sense movement of a thumb on the top of the thumbstick prior to the potentiometer sensing the deflection of the thumbstick. 16. A trackpad of a controller, the trackpad comprising: a cover; a touch sensor disposed underneath, and coupled to, the cover, wherein the touch sensor is configured to output touch data indicative of a touch on the cover; a carrier disposed underneath the touch sensor and coupled to the cover; at least one biasing member coupled to the carrier and to a housing of the controller, wherein a center portion of the at least one biasing member comprises one or more holes configured to receive corresponding projections extending from a rear side of the carrier, wherein the at least one biasing member is configured to apply a biasing force on the carrier in an opposite direction to that of a force of a press on the cover; a metal layer disposed underneath, and coupled to, the carrier; and a pressure sensor coupled to the housing and disposed underneath, and spaced a distance from, the metal layer, wherein the pressure sensor is configured to output force data indicative of an amount of force of the press on the cover based at least in part on a proximity of the metal layer relative to the pressure sensor. 17. The trackpad of claim 16 , wherein the force data comprises capacitance values that vary in response to variable force of the press on the cover. 18. The trackpad of claim 16 , wherein the metal layer is attached to a bottom surface of the carrier. 19. The trackpad of claim 16 , wherein the trackpad further comprises a haptic actuator disposed underneath the touch sensor and configured to vibrate in response to the amount of the force of the press satisfying a threshold. 20. The trackpad of claim 16 , wherein the at least one biasing member is a first spring coupled to a first side of the carrier, and wherein the trackpad further comprises: a second spring coupled to the housing and to a second side of the carrier opposite the first side, wherein the second spring is configured to apply a second biasing force on the