Systems and methods for dynamic calibration of array cameras

What is claimed is: 1. A camera array, comprising: at least one array of cameras comprising a plurality of cameras; a projector; a processor; and memory containing an image processing application; wherein the image processing application directs the processor to: project a texture onto a scene using the projector to aid with depth estimation in regions of the scene that lack texture; acquire a set of images of the scene using the plurality of cameras, where the set of images comprises a reference image captured from a reference viewpoint and an alternate view image; detect features in the set of images; identify within the alternate view image features corresponding to features detected within the reference image; rectify the set of images based upon a set of geometric calibration data; perform dynamic calibration using the detected features in the set of images and update the geometric calibration data based upon measurements of the extent to which the detected features correspond following rectification; estimate depths of features within the alternate view image identified as corresponding to features detected within the reference image based upon components of observed shifts in locations of features identified as corresponding in the reference image and the alternate view image along epipolar lines; and generate a depth map from the reference viewpoint using the estimated depths and the updated geometric calibration data. 2. The camera array of claim 1 , wherein the image processing application further directs the processor to: determine residual vectors for geometric calibration data at locations where features are observed within the alternate view image based upon observed shifts in locations of features identified as corresponding in the reference image and the alternate view image; and determine updated geometric calibration data for a camera that captured the alternate view image based upon the residual vectors, wherein determining updated geometric calibration data for the camera that captured the alternate view image comprises: using at least an interpolation process to generate a residual vector calibration field from the residual vectors; mapping the residual vector calibration field to a set of basis vectors; generating a denoised residual vector calibration field using a linear combination of less than the complete set of basis vectors; and rectify an image captured by the camera that captured the alternate view image based upon the updated geometric calibration data. 3. The camera array of claim 2 , wherein determining residual vectors for geometric calibration data at locations where features are observed within the alternate view image comprises: estimating depths of features within the alternate view image identified as corresponding to features detected within the reference image based upon components of the observed shifts in locations of features identified as corresponding in the reference image and the alternate view image along epipolar lines; determining scene dependent geometric corrections to apply to the observed shifts in locations of features identified as corresponding in the reference image and the alternate view image based upon the estimated depths of the corresponding features; and applying the scene dependent geometric corrections to the observed shifts in locations of features identified as corresponding in the reference image and the alternate view image to obtain residual vectors for geometric calibration data at locations where features are observed within the alternate view image. 4. The camera array of claim 2 , wherein determining updated geometric calibration data for a camera that captured the alternate view image based upon the residual vectors further comprises using an extrapolation process in the generation of the residual vector calibration field from the residual vectors. 5. The camera array of claim 2 , wherein the image processing application further directs the processor to apply the residual vector calibration field to the set of geometric calibration data with respect to the camera that captured the alternate view image. 6. The camera array of claim 2 , wherein the set of basis vectors is learned from a training data set of residual vector calibration fields. 7. The camera array of claim 6 , wherein the set of basis vectors is learned from a training data set of residual vector calibration fields using Principal Component Analysis. 8. The camera array of claim 2 , wherein determining updated geometric calibration data for a camera that captured the alternate view image further comprises selecting an updated set of geometric calibration data from amongst a plurality of sets of geometric calibration data based upon at least the residual vectors for geometric calibration data at locations where features are observed within the alternate view image. 9. The camera array of claim 2 , wherein the image processing application further directs the processor to: acquire an additional set of images of a scene using the plurality of cameras; and determine residual vectors for the geometric calibration data using the additional set of images; wherein determining updated geometric calibration data for a camera that captured the alternate view image based upon the residual vectors also comprises utilizing the residual vectors for the geometric calibration data determined using the additional set of images. 10. The camera array of claim 9 , wherein the image processing application further directs the processor to: detect at least one region within a field of view of a camera that does not satisfy a feature density threshold; wherein the additional set of images of a scene is acquired in response to detecting that at least one region within a field of view of a camera does not satisfy the feature density threshold. 11. The camera array of claim 2 , wherein utilizing the residual vectors determined using the additional set of images further comprises utilizing the residual vectors determined using the additional set of images to determine updated geometric calibration data with respect to the at least one region within the field of view of the camera in which the density threshold was not satisfied. 12. A method of dynamically generating geometric calibration data for an array of cameras, comprising: projecting a texture onto a scene using a projector to aid with depth estimation in regions of the scene that lack texture; acquiring a set of images of the scene using a plurality of cameras, where the set of images comprises a reference image captured from a reference viewpoint and an alternate view image; detecting features in the set of images; identifying within the alternate view image features corresponding to features detected within the reference image; rectifying the set of images based upon a set of geometric calibration data; performing dynamic calibration using the detected features in the set of images and updating the geometric calibration data based upon measurements of the extent to which the detected features correspond following rectification; estimating depths of features within the alternate view image identified as corresponding to features detected within the reference image based upon components of observed shifts in locations of features identified as corresponding in the reference image and the alternate view image along epipolar lines; and generating a depth map from the reference viewpoint using the estimated depths and the updated geometric calibration data. 13. The method of claim 12 , further comprising: determining residual vectors for geometric