Thin multi-aperture imaging system with auto-focus and methods for using same

What is claimed is: 1. A dual-aperture digital camera with autofocus (AF) for imaging an object or scene, comprising: a) a first sub-camera that includes a first optics bloc and a first, color image sensor with a first number of pixels, the first camera operative to provide a first, color image of the object or scene; b) a second sub-camera that includes a second optics bloc and a second image sensor having a second number of pixels, the second sub-camera operative to provide a second image of the object or scene; c) an AF mechanism coupled mechanically at least to the first optics bloc and used to perform an AF action on at least the first optics bloc; and d) a camera controller coupled to the AF mechanism and to the two image sensors and configured, based on calibration data acquired through a calibration step, to control the AF mechanism, to find corresponding points in the first and second images, to estimate a scale difference between the first and second images, and to process the first and second images into a fused color image using the calculated scale difference. 2. The dual-aperture digital camera of claim 1 , wherein the camera controller is further configured to preprocess the first and second images, to obtain respective rectified first and second images, to register the rectified first and second images to obtain respective registered first and second images, and to fuse the registered first and second images into a fused color image. 3. The dual-aperture digital camera of claim 2 , wherein epipolar lines in the rectified first and second images are more-or-less parallel to horizontal or vertical axes of the rectified first and second images. 4. The dual-aperture digital camera of claim 3 , wherein the camera controller configuration is based on calibration data acquired through a calibration step, wherein the calibration data is saved in a one-time programmable memory or an EEPROM in the dual-aperture digital camera. 5. The dual-aperture digital camera of claim 4 , wherein the first number of pixels and the second numbers of pixels are different. 6. A dual-aperture digital camera with autofocus (AF) for imaging an object or scene, comprising: a) a first sub-camera that includes a first optics bloc and a first, color image sensor with a first number of pixels, the first camera operative to provide a first, color image of the object or scene; b) a second sub-camera that includes a second optics bloc and a second image sensor having a second number of pixels, the second sub-camera operative to provide a second image of the object or scene; c) an AF mechanism coupled mechanically at least to the first optics bloc and used to perform an AF action on at least the first optics bloc; and d) a camera controller coupled to the AF mechanism and to the two image sensors and configured, based on calibration data acquired through a calibration step, to control the AF mechanism, to preprocess the first and second images to obtain respective rectified and scale-adjusted first and second images while considering scaling differences caused by the AF action, to register the rectified and scale-adjusted first and second images to obtain respective registered first and second images, and to fuse the registered first and second images into a fused color image. 7. The dual-aperture digital camera of claim 6 , wherein the color image sensor includes a non-standard color filter array. 8. The dual-aperture digital camera of claim 6 , wherein the camera controller configuration is based on calibration data acquired through a calibration step. 9. The dual-aperture digital camera of claim 8 , wherein the calibration data is saved in a one-time programmable memory or an EEPROM in the dual-aperture digital camera. 10. The dual-aperture digital camera of claim 6 , wherein the first number of pixels and the second numbers of pixels are the same. 11. The dual-aperture digital camera of claim 6 , wherein the first number of pixels and the second numbers of pixels are different. 12. The dual-aperture digital camera of claim 6 , wherein the first, color image sensor and the second image sensor have pixels of the same size. 13. The dual-aperture digital camera of claim 6 , wherein the first sub-camera includes an infra-red (IR) filter that blocks IR wavelengths from entering the first image sensor and wherein the second sub-camera is configured to allow at least some IR wavelengths to enter the second image sensor. 14. The dual-aperture digital camera of claim 6 , wherein the second image sensor is a luminance image sensor and wherein the second image is a luminance image. 15. The dual-aperture digital camera of claim 6 , wherein epipolar lines in the rectified first and second images are more-or-less parallel to horizontal or vertical axes of the rectified first and second images. 16. A method, comprising: in a dual camera: a) obtaining simultaneously a first, color image of an object or scene with a first sub-camera and a second image of the object or scene with a second sub-camera, wherein the first sub-camera includes a first optics bloc, wherein the second sub-camera includes a second optics bloc and wherein the first and second sub-cameras have substantially the same field of view; b) using an AF mechanism coupled mechanically at least to the first optics bloc to perform an AF action on at least the first optics bloc; c) preprocessing the first image and the second image to obtain respective rectified and scale-adjusted first and second images while considering scaling differences caused by the AF action; d) performing registration between the rectified and scale-adjusted first and second images to obtain registered images; and e) fusing the registered images into a focused fused color image. 17. The method of claim 16 , wherein the fusing of the registered images is not performed in non-focused areas. 18. The method of claim 16 , wherein the preprocessing to obtain respective rectified scale-adjusted first and second images includes calculating a set of corresponding points in the first and second images and estimating a scale factor S. 19. The method of claim 18 , further comprising using scaling factor S to scale one of the images to match the other image, thereby obtaining the registered images.