초록 ▼

Methods and apparatus for light-field capture with large depth of field. A design methodology is described in which the relationships among various plenoptic camera parameters, including inverse magnification, F-number, focal length, wavelength, and pixel size, may be analyzed to design plenoptic ca

Methods and apparatus for light-field capture with large depth of field. A design methodology is described in which the relationships among various plenoptic camera parameters, including inverse magnification, F-number, focal length, wavelength, and pixel size, may be analyzed to design plenoptic cameras that provide increased depth-of-field when compared to conventional plenoptic cameras. Plenoptic cameras are described, which may be implemented according to the design methodology, and in which both Keplerian telescopic and Galilean telescopic imaging can be realized at the same time while providing a larger depth of field than is realized in conventional plenoptic cameras, thus capturing light-field images that capture “both sides” in which all but a small region of the scene is in focus. In some embodiments, apertures may be added to the microlenses so that depth of field is increased.

대표청구항 ▼

1. An imaging device, comprising: a photosensor that captures light projected onto the photosensor;an objective lens, wherein the objective lens that refracts light from a scene located in front of the imaging device to form a three-dimensional (3D) image of the scene in the imaging device;an optica

1. An imaging device, comprising: a photosensor that captures light projected onto the photosensor;an objective lens, wherein the objective lens that refracts light from a scene located in front of the imaging device to form a three-dimensional (3D) image of the scene in the imaging device;an optical element array positioned between the objective lens and the photosensor, wherein the optical element array comprises a plurality of optical elements, and wherein each optical element in the optical element array comprises: a microlens; andan aperture that increases depth of field of the microlens;wherein the 3D image of the scene extends in front of and behind the optical element array, wherein each optical element of the optical element array projects a separate portion of the 3D image of the scene onto a separate location on the photosensor, and wherein the separate portions of the 3D image projected onto the photosensor by the optical elements are in focus except for portions projected onto the photosensor from within a range extending in front of and behind the microlenses in the optical element array. 2. The imaging device as recited in claim 1, where the range is determined according to inverse magnification M and focal length f of the microlenses. 3. The imaging device as recited in claim 1, where the microlenses are at distance f from the photosensor, where f is focal length of the microlenses. 4. The imaging device as recited in claim 1, where pixel size p of pixels in the photosensor is determined according to number of pixels N in each microimage captured by the imaging device and wavelength of light λ. 5. The imaging device as recited in claim 1, where the optical elements are configured to obtain an inverse magnification M, where M is determined according to pixel size p of pixels in the photosensor, focal length f of the microlenses, and wavelength of light λ. 6. The imaging device as recited in claim 1, where the optical elements are configured to obtain an F-number F for the microlenses according to pixel size p of pixels in the photosensor and wavelength of light λ. 7. The imaging device as recited in claim 1, wherein the photosensor comprises a plurality of pixels of size p, where p is determined according to wavelength of light λ and F-number F of the microlenses. 8. The imaging device as recited in claim 1, wherein the photosensor is configured to capture a light-field image comprising the separate portions of the image of the scene projected onto the photosensor by the microlenses, wherein each of the separate portions is in a separate region of the light-field image. 9. A method for capturing light-field images, comprising: receiving light from a scene at an objective lens of an imaging device;refracting light from the objective lens of the imaging device to form a 3D image of the scene within the imaging device;receiving light from the 3D image at an array positioned between the objective lens and a photosensor of the imaging device, wherein the array comprises a plurality of microlenses, and wherein the array further comprises a plurality of apertures, wherein each aperture corresponds to a particular one of the microlenses in the array, and wherein each aperture increases depth of field of a respective microlens;receiving light from the array at the photosensor, wherein the photosensor receives a separate portion of the 3D image of the scene from each microlens at a separate location on the photosensor; andwherein the 3D image of the scene extends in front of and behind the optical element array, and wherein the separate portions of the 3D image projected onto the photosensor are in focus except for portions projected onto the photosensor from within a range extending in front of and behind the microlenses in the array. 10. The method as recited in claim 9, where the range is determined according to inverse magnification M and focal length f of the microlenses. 11. The method as recited in claim 9, where the microlenses are at distance f from the photosensor, where f is focal length of the microlenses. 12. The method as recited in claim 9, where pixel size p of pixels in the photosensor is determined according to number of pixels N in each microimage captured by the imaging device and wavelength of light λ. 13. The method as recited in claim 9, where the imaging device is configured to obtain an inverse magnification M for the microlenses, where M is determined according to pixel size p of pixels in the photosensor, focal length f of the microlenses, and wavelength of light λ. 14. The method as recited in claim 9, where the imaging device is configured to obtain an F-number F for the microlenses according to pixel size p of pixels in the photosensor and wavelength of light λ. 15. The method as recited in claim 9, wherein the photosensor comprises a plurality of pixels of size p, where p is determined according to wavelength of light λ and F-number F of the microlenses. 16. An optical imaging system, comprising: an objective lens, wherein the objective lens is configured to refract light from a scene located in front of the optical imaging system to form a three-dimensional (3D) image of the scene behind the objective lens; andan optical element array, wherein the 3D image of the scene extends in front of and behind the optical element array;wherein the optical element array comprises a plurality of optical elements, wherein each optical element of the optical element array is configured to project a respective portion of the 3D image of the scene onto a respective location on a photosensor, wherein the respective portions of the 3D image of the scene projected onto the photosensor include portions of the 3D image from in front of the optical element array and portions of the 3D image from behind the optical element array; andwherein the optical elements are configured to obtain an inverse magnification M between 2 and 3 to produce a depth of field for the optical imaging system such that respective portions of the 3D image projected onto the photosensor by the optical elements are in focus except for portions projected onto the photosensor from within a range extending in front of and behind the optical element array, wherein the range is determined according to the inverse magnification M. 17. The optical imaging system as recited in claim 16, wherein each optical element in the optical element array comprises a microlens and an aperture, wherein the aperture affects optical characteristics of the respective microlens to obtain the inverse magnification M of between 2 and 3 for the optical element. 18. The optical imaging system as recited in claim 16, where the range is determined according to the inverse magnification M and focal length f of the optical elements. 19. The imaging device as recited in claim 16, where the inverse magnification M is determined according to pixel size p of pixels in the photosensor, focal length f of the microlenses, and wavelength of light λ. 20. The imaging device as recited in claim 16, where the optical imaging system is configured to obtain an F-number F for the optical elements according to pixel size p of pixels in the photosensor and wavelength of light λ. 21. The imaging device as recited in claim 20, wherein the obtained F-number F for the optical elements is between 10 and 18 .