Retroreflective multi-axis force torque sensor

What is claimed is: 1. A device comprising: a first rigid structure; a second rigid structure elastically coupled to the first rigid structure by a spring element such that the first rigid structure is moveable in six degrees of freedom relative to the second rigid structure; a curved reflector fixed to a surface of the first rigid structure; three or more photodetectors each operable to measure an illuminance of light incident on the photodetector, wherein each of the three or more photodetectors is fixed to a surface of the second rigid structure; a light emitter operable to project light toward the curved reflector, wherein the curved reflector reflects respective portions of the projected light onto the three or more photodetectors, wherein the light emitter and the three or more photodetectors are fixed with respect to each other, and wherein the first rigid structure is movable in six degrees of freedom with respect to the light emitter and the three or more photodetectors; and at least one processor configured to perform operations comprising: measuring, by each photodetector of the three or more photodetectors, an illuminance of the respective portion of projected light incident on the photodetector; after a force is applied against at least one of the first rigid structure or the second rigid structure, determining, based on the measured illuminances, a displacement of the first rigid structure or the second rigid structure in one or more degrees of freedom with respect to a reference position of either the first rigid structure or the second rigid structure respectively; determining, based on the determined displacement and a relationship between displacement and force, a force vector of the applied force, wherein the force vector comprises a magnitude and a direction of the applied force; and providing an output signal indicative of the force vector. 2. The device of claim 1 , wherein the relationship is based on a known characteristic of the spring element. 3. The device of claim 1 , wherein the operations further comprise: providing instructions to control a robotic device based on the determined force vector. 4. The device of claim 1 , wherein determining the force vector comprises: obtaining a transformation matrix configured to convert between displacements and force vectors, wherein the transformation matrix is determined using linear regression based on calibration data including a plurality of displacements and a plurality of force vectors. 5. The device of claim 1 , further comprising: three or more curved reflectors fixed to the surface of the first rigid structure, wherein the operations further comprise: determining, based on the measured illuminances, the displacement of the first rigid structure in six degrees of freedom with respect to the reference position of the first rigid structure; and providing an output signal indicative of the displacement of the first rigid structure in six degrees of freedom. 6. The device of claim 5 , wherein the first rigid structure is displaced from the reference position after the force is applied, wherein the operations further comprise: determining, based on the displacement of the first rigid structure in six degrees of freedom, a force vector indicative of a magnitude of the force and a direction of the force in six degrees of freedom; and providing an output signal indicative of the force vector in six degrees of freedom. 7. The device of claim 1 , wherein the first rigid structure is composed of substantially nonreflective material. 8. The device of claim 1 , wherein the second rigid structure is a printed circuit board. 9. The device of claim 1 , wherein the three or more photodetectors and the light emitter are substantially coplanar. 10. The device of claim 1 , further comprising: a fourth photodetector operable to measure a calibration illuminance indicative of a luminance of the light emitter, wherein the calibration illuminance is not affected by a position of the first rigid structure relative to the second rigid structure, and wherein measuring the calibration illuminance of the respective portion of projected light incident on the fourth photodetector comprises: measuring, by the fourth photodetector, the calibration illuminance; comparing the measured calibration illuminance to a reference illuminance indicative of a past illuminance; and adjusting the determination of the displacement of the first rigid structure or the second rigid structure based on the comparison of the measured calibration illuminance to the reference illuminance and the illuminances measured by the three or more photodetectors. 11. The device of claim 1 , wherein the operations further comprise: adjusting operation of a robotic device based on the output signal. 12. A method comprising: causing a light emitter to project light toward a curved reflector, wherein the curved reflector is fixed to a surface of a first rigid structure and the light emitter is fixed to a surface of a second rigid structure, and further wherein the first rigid structure is elastically coupled to the second rigid structure by a flexure element such that the first rigid structure is movable in six degrees of freedom relative to the second rigid structure; measuring, by three or more photodetectors fixed to the surface of the second rigid structure, three or more illuminances of light incident on the respective three or more photodetectors, wherein each illuminance represents an intensity of a portion of the projected light that reflects off the curved reflector and is incident on a respective photodetector; determining, based on the three or more measured illuminances, a displacement of the first rigid structure or the second rigid structure in one or more degrees of freedom with respect to a reference position of either the first rigid structure or the second rigid structure respectively, wherein the reference position is based on a spatial location of the curved reflector when the flexure is at equilibrium; determining, based on the determined displacement and a relationship between displacement and force, a force vector of a force applied against at least one of the first rigid structure or the second rigid structure, wherein the force vector comprises a magnitude and a direction of the applied force; and providing an output signal indicative of the force vector. 13. The method of claim 12 , wherein determining the displacement comprises: obtaining calibration data that correlates (i) sets of illuminances and (ii) displacement, wherein the sets of illuminances represent measurements captured when the curved reflector is moved to known displacements relative to the reference position; and determining the displacement based on the three or more illuminances and the calibration data. 14. The method of claim 12 , wherein determining the force vector comprises: obtaining calibration data that correlates (i) displacements and (ii) force vectors, wherein the displacements represent measured displacements when known forces are applied against at least one of the first rigid structure or the second rigid structure; determining, using linear regression, a transformation matrix based on the calibration data; and determining the force vector based on the displacement vector and the transformation matrix. 15. The method of claim 12 , further comprising: providing instructions to control a robotic device based on the determined force vector. 16. The method of claim 12 , further comprising: measuring, by a fourth photodetector, a calibrat