Auto-focus in low-profile folded optics multi-camera system

What is claimed is: 1. An image capture system comprising: a plurality of cameras configured to capture a corresponding plurality of portions of a target image scene, a camera of the plurality of cameras comprising: an image sensor; a primary light folding surface configured to redirect light representing one portion of the corresponding plurality of portions of the target image scene in a first direction toward the image sensor; an optical element having an input surface configured to receive the light from the primary light folding surface, a secondary light folding surface configured to redirect the light in a second direction toward the image sensor, and an output surface through which light redirected by the secondary light folding surface propagates in the second direction toward the image sensor; a lens assembly comprising: a stationary portion having a first surface connected to the output surface of the optical element and a second surface connected to the image sensor, wherein the stationary portion of the lens assembly comprises a field corrector lens, and a movable portion positioned between the primary light folding surface and the optical element; an actuator configured to move the movable portion of the lens assembly along the first direction; at least one guide rail coupled to the actuator and the movable portion of the lens assembly, the at least one guide rail positioned to slidably engage another surface within the camera to constrain motion of the movable portion of the lens assembly away from an optical axis or rotating around the optical axis, the optical axis substantially parallel to the first direction; and a processor configured to generate a final image of the target image scene based at least partly on the corresponding plurality of portions. 2. The system of claim 1 , further comprising: a cover glass coupled between the image sensor and the stationary portion of the lens assembly, wherein the cover glass comprises a first cover glass surface coupled to the second surface of the stationary portion of the lens assembly and a second cover glass surface coupled to the image sensor; wherein the first direction, output surface of the optical element, first surface of the stationary portion of the lens assembly, first cover glass surface, second cover glass surface are generally parallel to a plane formed by the image sensor; wherein the optical element further comprises a guide surface extending generally parallel to the plane formed by the image sensor, the guide surface comprising the another surface within the camera which the at least one guide rail is positioned to slidably engage; wherein the input surface of the optical element is generally perpendicular to the plane formed by the image sensor; and wherein the secondary light folding surface extends at an angle between the guide surface of the optical element and the output surface of the optical element. 3. The system of claim 2 , wherein the optical element, stationary portion of the lens assembly, cover glass, and image sensor are adhered into a stack. 4. The system of claim 1 , further comprising a substrate, wherein the image sensor of each of the plurality of cameras is inserted into a slot in the substrate. 5. The system of claim 1 , further comprising one or more of glides, interlocking grooves, a magnetic field, oil, ball bearings, air, gas, or water positioned in contact with one or both of the movable portion of the lens assembly and the at least one guide rail in order to reduce friction. 6. The system of claim 1 , wherein the actuator is configured to move the movable portion of the lens assembly in the first direction within a space formed between an output surface of a prism comprising the primary light folding surface and the input surface of the optical element comprising the secondary light folding surface. 7. The system of claim 6 , wherein motion of the movable portion of the lens assembly in the first direction within the space between a near focus position and a far focus position is approximately 180 micrometers or less. 8. The system of claim 6 , wherein the near focus position corresponds to a focal distance of approximately 200 mm and the far focus position corresponds to a focal length of approximately 6767 mm. 9. The system of claim 1 , wherein the movable portion of the lens assembly comprises a plurality of lenses affixed to one another. 10. The system of claim 1 , wherein the primary light folding surface comprises one of a mirror and a refractive prism. 11. The system of claim 1 , wherein the optical element comprises one of a mirror and a refractive prism. 12. The system of claim 1 , further comprising an autofocus module storing instructions for focusing the movable portion of the lens assembly. 13. The system of claim 1 , wherein the optical element is positioned between the movable portion of the lens assembly and the actuator. 14. The system of claim 13 , wherein the at least one guide rail is coupled to a lower surface of the actuator at a first end and is coupled to a lower surface of the movable portion of the lens assembly at a second end. 15. The system of claim 1 , wherein a pixel pitch of a pixel of the image sensor is 1.1 μm. 16. An image capture system comprising: a plurality of cameras configured to capture a corresponding plurality of portions of a target image scene, a camera of the plurality of cameras comprising: an image sensor; a primary light folding surface configured to redirect light representing one portion of the corresponding plurality of portions of the target image scene in a first direction toward the image sensor; an optical element having an input surface configured to receive the light from the primary light folding surface, a secondary light folding surface configured to redirect the light in a second direction toward the image sensor, and an output surface through which light redirected by the secondary light folding surface propagates in the second direction toward the image sensor; a lens assembly comprising: a stationary portion having a first surface coupled to the output surface of the optical element and a second surface coupled to the image sensor, and a movable portion positioned between the primary light folding surface and the optical element; an actuator configured to move the movable portion of the lens assembly along the first direction; at least one guide rail coupled to the actuator and the movable portion of the lens assembly, the at least one guide rail positioned to slidably engage another surface within the camera to constrain motion of the movable portion of the lens assembly away from an optical axis or rotating around the optical axis, the optical axis substantially parallel to the first direction; and a processor configured to generate a final image of the target image scene based at least partly on the corresponding plurality of portions, wherein the actuator is configured to move the movable portion of the lens assembly in the first direction within a space formed between an output surface of a prism comprising the primary light folding surface and the input surface of the optical element comprising the secondary light folding surface, and wherein the optical element comprises a refractive prism and further comprises a support block affixed to the refractive prism at the secondary light folding surface, a lower prism surface of the prism and a lower block surface of the support block comprising the another surface within the camera which the at least one guide rail is positioned to slidably