With reference to FIG. 1, camera 12 mounted on airframe 10 captures an image of first field of view 20 along first optical axis 21 aimed at first object of interest 23. During the time of exposure, airframe 10 flies first flight path arc 22 centered on first object of interest 23 with a radius subst
With reference to FIG. 1, camera 12 mounted on airframe 10 captures an image of first field of view 20 along first optical axis 21 aimed at first object of interest 23. During the time of exposure, airframe 10 flies first flight path arc 22 centered on first object of interest 23 with a radius substantially equal to the distance between camera 12 and first object of interest 23. Airframe 10 pivots camera 12 around first object of interest 23 while the shutter in camera 12 is open. This is repeated around each subsequent object of interest to produce a scalloped or slalom path, namely Forward Motion Compensated (FMC) flight path 33.
대표청구항▼
1. An aerial photography system to take an image of an object, comprising: an airframe,a camera mounted on said airframe,a shutter for said camera,distance estimating means to estimate an object distance between said camera and said object,an autopilot to direct said airframe to fly an arc centered
1. An aerial photography system to take an image of an object, comprising: an airframe,a camera mounted on said airframe,a shutter for said camera,distance estimating means to estimate an object distance between said camera and said object,an autopilot to direct said airframe to fly an arc centered on said object with a radius substantially equal to said object distance while said shutter is open,whereby blur in said image from motion of said airframe is substantially reduced. 2. The aerial photography system of claim 1, further comprising a propulsion system for said airframe that is turned off while said shutter is open and that is turned on while said shutter is closed, whereby blur in said image from vibration of said propulsion system is avoided. 3. The aerial photography system of claim 1, further comprising a planned flight path designed to capture a plurality of images of a corresponding number of objects of interest,where for each image and corresponding object of interest in turn, a corresponding object of interest distance between said camera and the corresponding object of interest is estimated with said distance estimating means and said autopilot directs said airframe to fly a corresponding arc centered on said corresponding object of interest with a corresponding radius substantially equal to said corresponding object of interest distance while said shutter is open to record said each image,whereby forward motion is compensated for each image with a flight path slightly modified from said planned flight path. 4. The aerial photography system of claim 1 to take an other image containing a plurality of objects of interest at different distances from said camera, further comprising a virtual object location calculated with a weighted average based on importance and location of each object of interest in said other image,said autopilot flies an arc centered on said virtual object location with a radius substantially equal to the distance between said camera and said virtual object location while said shutter is open to capture said other image,whereby forward motion blur is reduced for said plurality of objects of interest in said other image. 5. The aerial photography system of claim 4, further comprising a planned flight path designed to capture a plurality of images with a corresponding number of virtual object locations,where for each image and corresponding virtual object location in turn, said autopilot directs said airframe to fly a corresponding arc centered on said corresponding virtual object location with a corresponding radius substantially equal to a corresponding distance between said camera and said corresponding virtual object location while said shutter is open to record said each image,whereby forward motion is compensated for each object of interest in each image with a flight path slightly modified from said planned flight path. 6. The aerial photography system of claim 1, wherein said camera is mounted on said airframe for a forward oblique principal axis in a direction of travel of said airframe,said shutter is a focal plane rolling shutter such that a slit of a light sensitive surface in said camera records light at one time,said slit is scanned across said light sensitive surface in an opposite direction to said motion of said airframe,said autopilot directs said airframe to fly an other arc with increasing pitch while radius decreasing as said slit exposes said light sensitive surface corresponding to objects closer to said camera in said image,whereby forward motion compensation is greater for nearby objects than objects far forward of said airframe. 7. The aerial photography system of claim 6, further comprising a planned flight path designed to capture a plurality of sequential images where said autopilot directs said airframe to fly said other arc for each of said sequential images. 8. The aerial photography system of claim 1, wherein said camera is mounted on said airframe for a side oblique principal image axis compared to a direction of travel,said shutter is a focal plane rolling shutter such that a slit of a light sensitive surface in said camera records light at one time,said slit is scanned across said light sensitive surface from a far side to a near side of said side oblique principal image axis,said autopilot directs said airframe to fly an other arc in a plane formed by said side oblique principal axis and a forward direction of said airframe with a radius towards said side oblique principal axis decreasing as said slit exposes said light sensitive surface corresponding to objects closer to said camera in said image,whereby forward motion compensation is greater for nearby objects than objects far to the side of said airframe. 9. The aerial photography system of claim 8, further comprising a planned flight path designed to capture a plurality of sequential images where said autopilot directs said airframe to fly said other arc for each of said sequential images. 10. A method for forward motion compensation while acquiring an image of an object with a camera mounted on an airframe comprising: determining an object distance between said camera and said object,flying said airframe in an arc centered on said object with a radius substantially equal to said object distance while a shutter of said camera is open,whereby blur in said image from motion of said airframe is substantially reduced. 11. The method of claim 10 further comprising: turning off a propulsion system for said airframe while said shutter of said camera is open,turning on the propulsion system for said airframe while said shutter of said camera is closed,whereby blur in said image from vibration of said propulsion system is reduced. 12. The method of claim 10 further comprising: taking a plurality of sequential images of corresponding objects along a flight path,modifying said flight path for each sequential image in turn so as to fly an arc centered on the corresponding object with a corresponding radius substantially equal to the corresponding distance between said camera and said corresponding object while said shutter of said camera is open to take said each sequential image,whereby blur from forward motion of said airframe is reduced in said plurality of sequential images. 13. The method of claim 10 for acquiring an other image with a plurality of objects of interest at different distances in said other image, further comprising: calculating a virtual object location as a weighted average of locations of said objects of interest,flying said airframe in an arc centered on said virtual object location with a radius substantially equal to the distance between said camera and said virtual object location while shutter of said camera is open,whereby blur from forward motion of said airframe is reduced for said plurality of objects of interest in said other image. 14. The method of claim 13 further comprising: taking a plurality of sequential images of corresponding virtual object locations along a flight path,modifying said flight path for each sequential image in turn so as to fly a corresponding arc centered on the corresponding virtual object location with a corresponding radius substantially equal to the corresponding distance between said camera and said corresponding virtual object location while shutter of said camera is open to take said each sequential image,whereby blur from forward motion of said airframe is reduced in said plurality of sequential images for said plurality of objects of interest in each sequential image. 15. The method of claim 10 further comprising: mounting said camera on said airframe for a forward oblique principal axis in a direction of travel of said airframe,scanning a slit across a light sensitive surface of said camera from back to front compared to the direction of travel of said airframe,flying said airframe in an other arc with increasing pitch where a radius of the other arc initially equals a furthest distance at front of forward oblique field of view corresponding to said forward oblique principal axis and decreases to a closest distance at back of said forward oblique field of view as said slit is scanned across said light sensitive surface of said camera,whereby the forward motion compensation more closely matches different distances in said forward oblique field of view. 16. The method of claim 15 further comprising: taking a plurality of sequential images along a planned flight path where for each sequential image in turn, an autopilot directs said airframe to fly said other arc. 17. The method of claim 10 further comprising: mounting said camera on said airframe for a side oblique principal axis compared to a direction of travel of said airframe,scanning a slit across a light sensitive surface of said camera from a far to a near side of said side oblique principal axis,flying said airframe in an other arc in a plane formed by said side oblique principal axis and a forward direction of motion of said airframe with an other radius towards said side oblique principal axis where the other radius of said other arc initially equals a furthest distance at a far side of side oblique field of view corresponding to said side oblique principal axis and decreases to a closest distance at a near side of said side oblique field of view as said slit is scanned across said light sensitive surface of said camera,whereby forward motion compensation more closely matches different distances in said side oblique field of view. 18. The method of claim 17 further comprising: taking a plurality of sequential images along a planned flight path where for each sequential image in turn, an autopilot directs said airframe to fly said other arc. 19. The aerial photography system of claim 1, wherein said shutter is closed at an end of the flight of said arc. 20. The method of claim 10 further comprising, after flying said airframe in said arc, closing said shutter at an end of the flight of said arc.
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이 특허에 인용된 특허 (2)
Lareau Andre G. ; Beran Stephen R. ; James Brian ; Quinn James P. ; Lund John, Autonomous electro-optical framing camera system with constant ground resolution, unmanned airborne vehicle therefor, and methods of use.
Lareau Andre G. (Bloomingdale IL) Beran Stephen R. (Mount Prospect IL) Lund John A. (McHenry IL) Pfister William R. (Schaumburg IL), Electro-optical imaging array with motion compensation.
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