Claims
- 1. A method for using a photosensitive element that is photosensitive to light within a predetermined range of exposures to capture images including exposures that are outside the predetermined range of exposures; the method comprising the steps of:
exposing the photosensitive element to light from a scene; fracturing the light from the scene into concentrated and residual portions with the concentrated portions directed at concentrated image areas of the photosensitive element to form a pattern of concentrated image elements providing a concentrated image when light from the scene is within a first exposure range; and with the residual portions of the light directed at residual image area of the photosensitive element and forming an image in the residual image area of the photosensitive element when light from the scene is within a second exposure range;
wherein the combination of the first exposure range the and second exposure range has a greater range than the predetermined range of exposures.
- 2. The method of claim 1 wherein the step of fracturing the light from the scene comprises passing the light through an array of micro-lenses.
- 3. The method of claim 2 wherein light from the scene is concentrated into a plurality of differently concentrated portions with each differently concentrated portion being directed at the photosensitive element to form separate patterns of concentrated image elements on the photosensitive element.
- 4. The method of claim 3 wherein the light from the scene is concentrated into a plurality of differently concentrated portion by passing the light through an array of micro-lenses having two sets of micro-lenses with each set having different light concentrating characteristics.
- 5. The method of claim 1 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image of the scene by using imaging information from the concentrated image elements and removing artifacts of the residual image area from the output image.
- 6. The method of claim 1 wherein the first range is, at least in part, lower than a lower end of the predetermined exposure range of the photosensitive element.
- 7. The method of claim 1 wherein the second range is, at least in part, higher than an upper end of the predetermined exposure range of the photosensitive element.
- 8. The method of claim 1 wherein the first exposure range and second exposure range overlap at least in part.
- 9. The method of claim 1 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image of the scene using imaging information from the concentrated image area and the residual image area.
- 10. The method of claim 1 wherein the first exposure range and second exposure range do not overlap.
- 11. The method of claim 2 wherein said micro-lenses have a fill-factor of less than 95 percent.
- 12. The method of claim 2 wherein said micro-lenses have a fill-factor of greater than 30 percent.
- 13. The method of claim 1 wherein said first exposure range and said second exposure range provide a range that is greater than the latitude of the photosensitive element by a factor of more than 0.3 log E.
- 14. The method of claim 1 further comprising the steps of detecting the range of exposures in a scene and recording a signal on the photosensitive element indicating the range of exposures in the scene.
- 15. A photography method comprising the steps of:
exposing a photosensitive element that records a contrast image in response to exposure to light within a predetermined range of exposures; directing at least one portion of the light at first areas of the photosensitive element so that the photosensitive element can record imaging information from an exposure that is within a first exposure range; and permitting a remaining portion of the light to strike a second area of the photosensitive element so that the photosensitive element can record imaging information from an exposure that is within a second range wherein the combined first exposure range and second exposure range have a greater range than the predetermined range of exposures within which the photosensitive element is photosensitive.
- 16. The photography method of claim 15 further comprising the steps of:
photoprocessing the photosensitive element; scanning the processed photosensitive element to obtain imaging data; separating imaging data scanned from the first areas from imaging data scanned from the second areas; rendering an output image using imaging data from the second areas where the second image areas contain a contrast image; and rendering an output image using imaging data from the first areas where the second areas do not contain a contrast image.
- 17. The photography method of claim 16 wherein the first range is, at least in part, lower than a lower end of the predetermined range of exposures of the photosensitive element.
- 18. The photography method of claim 16 wherein the second range is, at least in part, higher than an upper end of the predetermined exposure range of the photosensitive element.
- 19. The photography method of claim 16 wherein the first range and second range overlap at least in part.
- 20. The photography method of claim 16 wherein the first range and second range do not overlap.
- 21. The photography method of claim 16 wherein the step of fracturing the light comprises passing the light through an array of micro-lenses.
- 22. The photography method of claim 21 wherein said micro-lenses have a fill-factor of less than 95 percent.
- 23. The photography method of claim 21 wherein said micro-lenses have a fill-factor of greater than 30 percent.
- 24. The photography method of claim 16 wherein the first range and the second range provide a range that is greater than the latitude of the photosensitive element by a factor of more than 0.3 log E.
- 25. A method for forming an output image from a photoprocessed photosensitive element having a first image area with a concentrated light image recorded therein and a second image area for receiving a residual light image; the method comprising the steps of:
scanning the photosensitive element to obtain image data from the first and second image areas; determining whether the second image area contains an image; forming an output image based upon image data from the first image area where the second image area does not contain an image; and forming an output image based at least in part upon image data from the second image area where the second image area contains an image.
- 26. The method of claim 25 wherein a signal is recorded on the photosensitive element indicating that the photosensitive element contains imaging information in the first image area or the second image area and wherein the step of detecting whether imaging information is encoded in the second image comprises detecting the signal.
- 27. The method of claim 25 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image by using imaging information from the first image area and removing artifacts of the second image area from the output image.
- 28. The method of claim 27 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an undersampling scanning border and the step of assembling an image comprises removing artifacts of the second image area from the undersampled imaging information by color correction.
- 29. The method of claim 27 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using a matching sampling border and the step of assembling an output image based upon the recovered image data comprises forming the output using samples that contain areas of the photosensitive element associated with the first image area.
- 30. The method of claim 27 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an oversampling border and the step of assembling an output image based upon the recovered image data, the step comprises assembling the output image using samples associated with the first image area.
- 31. The method of claim 25 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image of the scene using imaging information from the first image area and second image area.
- 32. The method of claim 31 wherein the step of removing artifacts of the first image from the second image comprises deriving imaging information from the first and second image to form substitute imaging information and substituting the substitute information in place of the imaging information associated with the first image area.
- 33. The method of claim 25 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image of the scene by using imaging information from the second image area and removing artifacts of the first image area from the second image area.
- 34. The method of claim 33 wherein the step of removing artifacts of the first image from the second image comprises deriving imaging information from second image to form substitute imaging information and substituting the substitute information in place of the imaging information associated with the first image area.
- 35. The method of claim 25 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an under sampling scanning border and the step of assembling an image comprises removing artifacts of the first image area from the under sampled imaging information by color correction.
- 36. The method of claim 25 wherein the step of recovering image data from the photosensitive element comprises using a matching sampling border and the step of assembling an output image based upon the recovered image data comprises forming the output image using imaging information associated with the second image area.
- 37. The method of claim 25 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an oversampling border and the step of assembling an output image based upon the recovered image data comprises assembling the output image using samples associated with the second image area.
- 38. The method of claim 29 wherein said scanning is performed at a pitch finer than the pitch of the concentrated image elements.
- 39. A method for capturing and rendering an output image using a photosensitive element that records images when exposed to predetermined range of exposure intensities, the method comprising the steps of:
exposing the photosensitive element to light from a scene; fracturing the light from the scene into a first fraction and a second fraction; concentrating the first fraction of the light from the scene to form a first image on a first portion of the photosensitive element when the exposure is within a first exposure range; passing the second fraction of the light from the scene onto the photosensitive element to form a second image on a second portion of the photosensitive element when the light from the scene is within a second range wherein the combination of the first range and second range is greater than the predetermined range of exposure intensities of the photosensitive element; photoprocessing the photosensitive element; recovering image data from at least one of the images formed on the photosensitive element; and assembling an output image based upon the recovered image data.
- 40. The method of claim 39 wherein light from the scene is fractured by being passed through an array of micro-lenses.
- 41. The method of claim 40 wherein the light from the scene is concentrated into a plurality of differently concentrated portions each differently concentrated portion directed at the photosensitive element to create separate concentrated images on the photosensitive element.
- 42. The method of claim 39 wherein the step of exposing the photosensitive element to light from a scene comprises exposing the photosensitive element for a period of time sufficient to cause an exposure to form in the residual image area.
- 43. The method of claim 40 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises detecting whether imaging information is encoded in a second image.
- 44. The method of claim 43 further comprising the step of recording a signal on the photosensitive element indicating that the photosensitive element contains imaging information in the first image or the second image and the step of detecting whether imaging information is encoded in the second image comprises detecting the signal.
- 45. The method of claim 39 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image of the scene by using imaging information from the first image and removing artifacts of the second image from the output image.
- 46. The method of claim 39 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an undersampling scanning border and the step of assembling an image comprises removing the artifacts of the second image from the under sampled imaging information by color correction.
- 47. The method of claim 39 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using a matching sampling border and the step of assembling an output image based upon the recovered image data comprises forming the output using samples that contain areas of the photosensitive element associated with the first image.
- 48. The method of claim 39 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an oversampling border and the step of assembling an output image based upon the recovered image data, comprises assembling the output image using samples associated with the first image.
- 49. The method of claim 39 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image of the scene using imaging information from the first and second image.
- 50. The method of claim 39 wherein the step of removing artifacts of the first image from the second image comprises deriving imaging information from the first and second image to form substitute imaging information and substituting the substitute information in lace of the imaging information.
- 51. The method of claim 39 wherein the step of recovering image data from at least one of the images formed on the photosensitive element comprises forming an output image by using imaging information from the second image and removing artifacts of the first image from the second image.
- 52. The method of claim 51 wherein the step of removing artifacts of the first image from the second image comprises deriving imaging information from the second image to form substitute imaging information and substituting the substitute information in place of the imaging information associated with the first image.
- 53. The method of claim 39 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive elements using an under sampling scanning border and the step of assembling an image comprises removing artifacts of the first image from the under sampled imaging information by color correction.
- 54. The method of claim 39 wherein the step of recovering image data from the photosensitive element comprises using a matching sampling border and the step of assembling an output image based upon the recovered image data comprises forming the output using samples that contain areas of the photosensitive element associated with the second image.
- 55. The method of claim 39 wherein the step of recovering image data from the photosensitive element comprises scanning the photosensitive element using an oversampling border and the step of assembling an output image based upon the recovered image data comprises assembling the output image using samples associated with the second image area.
- 56. A camera for recording images on a photosensitive element strip having an emulsion for recording an image when the photosensitive element is exposed to light within a predefined range of exposures, the camera comprising:
a camera body having an aperture; a camera photosensitive element gate positioning the photosensitive element to confront the aperture; an array of micro-lenses disposed between said aperture and said photosensitive element, said array of micro-lenses being adapted to fracture light from a scene into a first fraction and a second fraction wherein the first fraction of light from the scene is concentrated to form a first image on a first portion of the photosensitive element when exposure intensity is within a first range, with said array passing a second fraction of light from the scene onto the photosensitive element to form a second image on a second portion of the photosensitive element when light from the scene is within a second range; and a shutter disposed between said aperture and said micro-lens array controllably permitting a light from the scene to expose the photosensitive element for a predefined period of time, said predefined period of time being defined as sufficient to form an image on said second portion of the photosensitive element when light from the scene is within a second range.
- 57. The camera of claim 56 wherein the combination of the first range and the second range is greater than the predetermined range of exposure intensity of the photosensitive element.
- 58. The camera of claim 56 wherein said array of micro-lenses comprises an array of uniformly distributed micro-lenses.
- 59. The camera of claim 56 wherein said array of micro-lenses comprises an array of aspherical micro-lenses.
- 60. The camera of claim 56 wherein said array of micro-lenses comprises an array of acylindrical micro-lenses.
- 61. The camera of claim 56 further comprising a lens system that focuses light from the scene to form an image at the array of micro-lenses.
- 62. The camera of claim 56 wherein said array of micro-lenses comprises an array of different micro-lenses, said array of micro-lenses having a set of focal distances, each one of the set of focal distances being associated with an individual one of the micro-lenses.
- 63. The camera of claim 56 wherein said photosensitive element comprises a plurality of layers and the set of focal distances is defined so that each one of the set of focused distances focuses light from a scene onto a different one of the layers of the photosensitive element.
- 64. The camera of claim 56 wherein the f-number of the micro-lenses is between f-1.5 and f-16.
- 65. The camera of claim 56 wherein the f-number of the micro-lenses is between f-2 and f-7.
- 66. The camera of claim 56 wherein said array of micro-lenses is positioned on a support.
- 67. The camera of claim 56 wherein the ratio of highest to lowest refractive index between the support and the array of micro-lenses is between 0.8 and 1.2.
- 68. The camera of claim 67 wherein the ratio of highest to lowest refractive index between the support that the array of micro-lenses is between 0.95 and 1.05.
- 69. The camera of claim 67 wherein said support comprises said photosensitive element.
- 70. The camera of claim 66 wherein the support is formed from a substrate and said array of micro-lenses are formed from the same substrate.
- 71. The camera of claim 66 wherein the percentage of the unit area of the photosensitive element covered with a distribution of micro-lenses is between 20% to 100%.
- 72. The camera of claim 56 wherein the percentage of unit area of the photosensitive element covered by the array of micro-lenses is greater than 75%.
- 73. The camera of claim 56 wherein the separation between micro-lenses is between 3 and 100 microns.
- 74. The camera of claim 56 further comprising a light detector for detecting the level of scene brightness and said camera further comprises a camera controller and camera write head for writing a signal on the photosensitive element indicative of whether the scene exposure intensity suggests that an image will be recorded in the second portion of the film.
- 75. A camera for recording images on a photosensitive element having an emulsion for recording an image when the photosensitive element is exposed to light within a predefined range of exposures, the camera comprising:
a camera body having an aperture; a camera photosensitive element gate positioning the photosensitive element to confront the aperture; an array of micro-lenses disposed between said lens system and said photosensitive element said array of micro-lenses fracturing light from a scene into a set of more than one differently concentrated fractions with each concentrated fraction forming an image and each one of the set of differently concentrated fractions forming an image on a predefined area of the photosensitive element in response to a different range of light intensities, said array passing another fraction of light from the scene onto the photosensitive element to form a residual image on a predefined portion of the photosensitive element when light from the scene is within a second range; and a shutter disposed between said aperture and said micro-lens array to expose the photosensitive element to light from the scene for a predefined exposure time, said predefined period of time being defined as sufficient to form an image on said second portion of the photosensitive element when light from the scene is within a second range.
- 76. The camera of claim 75 wherein the array of micro lenses comprises a set of different micro-lens types each type concentrating light to a different extent.
- 77. The camera of claim 76 wherein the distribution of different types of micro-lenses in the array is uniform.
- 78. The camera of claim 76, wherein each of said micro-lenses types has a different focal distance.
- 79. The camera of claim 76, wherein said photosensitive element comprises a plurality of layers and the focal distances of the micro-lens types are defined so that each one of the set of different focus distances is defined focuses light from a scene onto a different one of the layers of the photosensitive element.
- 80. The camera of claim 76, wherein said camera further comprises a light sensor detecting the amount of light in an exposure, a processor to determine the amount of light in an exposure and a signal generator to record a signal on the photosensitive element indicating which portions of the photosensitive element contain imaging data associated with that amount of light.
- 81. An image rendering system for forming an output image from a developed photosensitive element having at least one image area having a concentrated exposure recorded thereon and at least one image area for receiving a residual exposure; the system comprising:
an optical scanner to obtain image data from the photosensitive element; and a processor for analyzing the image data and determining whether a residual exposure is recorded on the developed photosensitive element; with said processor forming an output image based upon image data from the at least one of the image area having a concentrated exposure recorded thereon, and forming an output image based at least in part upon image data from the image area for receiving a residual exposure where a residual exposure is recorded on the exposed photosensitive element.
- 82. The image rendering system of claim 81 wherein said photosensitive element has a recorded signal indicating that the photosensitive element contains a residual exposure and said scanner detects the signal and directs the processor to form an output image using at least some of the image data from the residual exposure.
- 83. The image rendering system of claim 81, wherein said photosensitive element has signal that is not optically detectable indicating that an residual exposure is recorded and said system further comprises a detector having a sensor to detect the signal with said detector providing a signal from which the processor can determine that a residual exposure is recorded on the developed photosensitive element.
- 84. The image rendering system of claim 81, wherein, said optical scanner obtains imaging information for the image area for receiving a residual exposure and the processor determines whether a residual image is recorded on the photosensitive element at least in part by examining the imaging information from the image area for receiving a residual exposure.
- 85. The image rendering system of claim 81 wherein the processor forms an output image of the scene by using imaging information from the concentrated exposure and removing artifacts of the second image from the output image.
- 86. The image rendering system of claim 81 wherein the scanner scans the photosensitive element using an undersampling scanning border and the processor assembles an output image by removing artifacts of the residual exposure from the under sampled imaging information using color correction.
- 87. The image rendering system of claim 81 wherein the scanner scans the photosensitive element using a matching sampling border and the processor assembles an output image based upon the recovered image data comprises forming the output using samples that contain areas of the photosensitive element associated with the concentrated exposure.
- 88. The image rendering system of claim 81 wherein the scanner scans the photosensitive element using an oversampling border and the processor assembles an output image based upon the recovered image data, and the processor assembles the output image using samples associated with the concentrated exposure area.
- 89. The image rendering system of claim 81 wherein the processor forms an output image of the scene using imaging information from the concentrated and the residual exposure.
- 90. The image rendering system of claim 81 wherein the processor removes artifacts of the concentrated exposure from the residual exposure by deriving substitute imaging information from the concentrated exposure and the residual exposure and substituting the substitute information in place of the imaging information associated with the concentrated exposure.
- 91. The image rendering system of claim 81 wherein the processor forms an output image of the scene by using imaging information from the residual exposure and removing artifacts of the concentrated exposure from the residual exposure.
- 92. The image rendering system of claim 81 wherein the processor forms an output image of the scene by deriving imaging information from the residual exposure to form substitute imaging information and substituting the substitute information in place of the imaging information associated with the concentrated exposure.
- 93. The image rendering system of claim 81 wherein the scanner scans the photosensitive element using an under sampling scanning border and the processor assembles an image by removing artifacts of the concentrated exposure from the under sampled imaging information using color correction.
- 94. The image rendering system of claim 81 wherein the scanner scans the photosensitive element using a matching sampling border and the processor assembles an output image based upon the recovered image data by forming the output image using samples that contain areas of the photosensitive element associated with the residual exposure.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is being filed as one of a group of five co-filed and commonly assigned U.S. patent application Ser. No. ______ [Attorney Docket No. 83316AEK], entitled CAMERA SPEED COLOR FILM WITH BASE SIDE MICRO-LENSES; in the names of Lyn Irving and Richard Szajewski; U.S. patent application Ser. No. ______ [Attorney Docket No. 8331 8AEK], entitled LENTIDULAR IMAGING WITH INCORPORATED BEADS, in the names of Krishnan Chari, Lyn Irving and Richard Szajewski; U.S. patent application Ser. No. ______ [Attorney Docket No. 84200AEK], entitled CAMERA SPEED COLOR FILM WITH EMULSION SIDE MICRO-LENSES, in the names of Richard Szajewski and Lyn Irving; and U.S. patent application Serial No. ______ [Attorney Docket No. 83212RRS], entitled IMAGING USING SILVER HALIDE FILMS WITH MICRO-LENS CAPTURE, AND OPTICAL RECONSTRUCTION in the names of Richard Szajewski and Lyn Irving, the contents of which are incorporated herein by reference.