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`United States Patent
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`US 8,462,209 B2
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`(45) Date of Patent:
`Jun. 11, 2013
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`US008462209B2
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`(54) DUAL-SWATH IMAGING SYSTEM
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`Inventor. Xluhong Sun, Windham, NH (US)
`(75)
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`MD
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`73 A .
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`Subject to any disclaimer, the term of this
`( * ) Notice:
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`patent is extended or adjusted under 35
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`U.S.C. 154(b) by 851 days.
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`(21) Appl. No.: 12/492,458
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`Flled:
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`Jun. 26, 2009
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`JP
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`6,735,348 B2 *
`6,778,211 B1
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`6,798,984 B2 *
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`7,009,638 B2
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`7,075,735 B2
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`..................... 382/293
`5/2004 Dial et a1.
`8/2004 Zimmermann et a1.
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`9/2004 Antikidis ........................ 396/13
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`3/2006 Gruber et a1.
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`7/2006 Nozawa et a1.
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`(Continued)
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`FOREIGN PATENT DOCUMENTS
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`8313825
`11/1996
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`6/1998
`10155104
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`OTHER PUBLICATIONS
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`Savopol, F., Chapman, M., Boulianne, M., A Digital Multi CCD
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`Camera System for Near Real-Time Mapping; 2000; International
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`Archives of Potogrammetry and Remote Sensing; v01. XXXIII Part
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`B1 pp. 266-271.*
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`(Continued)
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`Primary Examiner 7 Mehrdad Dastouri
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`Assistant Examiner 7 Jeremaiah C Hallenbeck-Huber
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`(74) Attorney, Agent, or Firm 7 Morrison & Foerster LLP
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`ABSTRACT
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`Aportable, aerial, dual-swathphotogrammetric imaging sys-
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`tem comprismg twm nadir pomtmg CCD cameras for Simul-
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`taneously acquiring twin adjacent digital images for merging
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`into a large panorama. A pair of lens shifters symmetrically
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`shift twin images to the left and right sides of the focal points
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`oftwo parallel lenses to extend imaging swathwidth. The twin
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`adjacent images of the imaging system have a strip of narrow
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`overlap at the center of the whole scene that are reserved for
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`photogrammetric processing and stitching twin images into a
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`seamless panorama. Each camera is connected to an embed-
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`ded computer which controls imaging data acquisition,
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`attaches GPS/IMU measurements, generates KML metadata
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`files for its snapshots, and stores acquired images and meta-
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`data into removable SSDs. Direct geo-referenced panoramic
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`digital stills are immediately registered on to GoogleTM Earth
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`precisely. Its images can be further processed for advanced
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`mapping, change detection and GIS applications.
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`16 Claims, 6 Drawing Sheets
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`SECOND DAS/CPU h
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`(65)
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`(51)
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`(56)
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`Prior Publication Data
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`US 2010/0328499 A1
`Dec. 30, 2010
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`Int. Cl'
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`H041V ”18
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`(52) U'S' Cl'
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`USPC ........................................... 348/144; 348/159
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`(58) Field of Classification Search
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`USPC ................................... 348/36, 42, 144, 218.1
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`pp 1ca ion
`e or comp e e searc
`is ory.
`1 t
`hh' t
`See a
`fil f
`1.
`t'
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`(200601)
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`
`
`
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`
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`
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`___MB§.5_M_EMQB.Y.--
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`
`T
`B
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`US 8,462,209 B2
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`APPL-1031 / Page 2 of 15
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`APPL-1031 / Page 2 of 15
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`BACKGROUND OF THE INVENTION
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`1. Field of the Invention
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`This invention relates to photogrammetric imaging sys-
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`tems and, in particular to a dual-swath electro-optical imag-
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`unmanned aerial vehicles (UAV) to acquire large-format,
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`2. Description of Related Art
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`from natural disaster
`Remote
`sensing applications
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`response to warfighting and peace keeping operations require
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`an advanced airborne imaging system to provide fast and
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`large format geo-referenced and orthorectified image maps.
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`Many airborne digital frame camera systems have come
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`cations. A major limitation is the size of the CCD and CMOS
`20
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`area arrays currently available for use in such systems. As a
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`result, widespread use of digital aerial photographic systems
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`has occurred featuring multiple arrays, multiple lenses or
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`multiple cameras in order to provide large ground coverage
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`and big image format at a high ground resolution by a single
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`flight.
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`In an article by Gordon Petrie entitled “Systematic Oblique
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`Aerial Photography Using Multiple Digital Frame Cameras”,
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`published February 2009 in Photogrammetric Engineering
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`and Remote Sensing, various twin cameras systems, and mul-
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`tiple camera systems are described. Twin camera systems
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`include “DiMAC” Wide from DiMAC Systems in Belgium, a
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`Dual-DigiCAM system from IGI in Germany and a Rollei
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`Metric (now Trimble) in Germany. All three of these twin
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`camera units have a rather similar specification with each
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`individual camera module having a digital image sensor back
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`that produces images of 7.2K><5.4K:39 megapixels in size.
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`Their camera shutters are synchronized to operate simulta-
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`neously to obtain two oblique photos on either side of the
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`flight line. After the rectification and the stitching together of
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`the two rectified images,
`the final merged (near-vertical
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`image is 10.5K><7.2K:75 megapixels in size. However, the
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`tilted photographs acquired by oblique cameras have fan
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`shaped imaging areas with variable resolutions across the
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`different parts of the images. Those tilted photographs need
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`extra work to be converted into the rectified images for Geo-
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`graphic Information System (GIS) application needs. Extra
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`cesses, including to correct the fan shaped images with vari-
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`able resolution to rectangular images with data interpolation,
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`which wastes the precious image resources, introduces arti-
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`fices, and sacrifices image quality.
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`US. Pat. No. 7,009,638 issued Mar. 2, 2006 to Michael
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`Gruber et al. and assigned to Vexcel Imaging GmbH, dis-
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`closes a large format digital camera system exposing multiple
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`detector arrays with one or more single lens systems to
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`acquire sub-images of overlapping sub-area of large area
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`objects. The sub-images are stitched together to form a large
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`format, digital macroimage which can be colored. However,
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`this camera system typically uses four (4) lenses and fifteen
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`(15) 35 mm format area sensor arrays, and is a fairly compli-
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`cated system. The hardware is massive and heavy. It is com-
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`plicated to build, calibrate, operate, and maintain. With 15
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`critical non-redundant sub-systems, it means a higher failure
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`rate. Its lens set is fixed and unlikely to have an interchange-
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`able option. Its composite image is asymmetrically over-
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`lapped and stitched. The patented processing solutions sug-
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`gested many
`compromised
`options which means
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`US 8,462,209 B2
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`problematical. This system is unlikely to be widely accepted
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`by the aerial photogrammetric and GIS industry even though
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`the system manufacture has been sold to a large software
`manufacturer.
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`SUMMARY OF THE INVENTION
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`Accordingly, it is therefore an object of this invention to
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`provide a portable dual-swath photogrammetric imaging sys-
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`tem for airborne applications to acquire wide swathwidth
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`large-format color photogrammetric images with centimeter-
`level resolution.
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`It is another object of this invention to provide a highly
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`reliable simple two camera imaging system which simulta-
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`neously captures a pair of left and right nadir shooting digital
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`aerial photos having a strip of narrow overlapping field at the
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`center of its composed panoramic frame or the edges of the
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`left and right images from each camera.
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`It is another object of this invention to provide a nadir
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`shooting twin symmetrical lens imaging system that produces
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`simultaneously captured left and right images with a center
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`narrow overlapping strip that comprises radiometrically
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`matched and digitally-registered image layers from the join-
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`ing edges ofthe left and right images to form a seamless aerial
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`panoramic image.
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`It is another object of this invention to provide a nadir
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`shooting dual camera system that has a native uniform pixel
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`resolution across its aerial freeze frame panoramic image
`when terrain is flat.
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`It is a further object of this invention to provide a dual
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`camera system that acquires dual-swathes of two adjacent
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`images with a narrow overlapped vertical strip at center. This
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`narrow center overlap consists of a stereo pair that is acquired
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`by two simultaneously exposed cameras with a fixed length of
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`stereo baseline (distance between two shots) and the same
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`attitude induced by aircraft roll, pitch, and yaw dynamics.
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`This narrow strip of overlapped images can be more easily
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`processed by simplified photogrammetric algorithms to pro-
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`vide a software altimeter or range finder function for this
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`dual-swath imaging system.
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`It is another object of this invention to provide a portable
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`airborne camera system using only two 6 cm by 4.5 cm format
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`frame transfer CCD sensors to provide industrial leading
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`large frame size options of78 megapixels and 120 megapixels
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`today and even higher pixel count options in the future.
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`It is another object of this invention to provide a portable
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`airborne camera system using merely two sensors to provide
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`the leading edge 14,200 pixel swathwidth ground track for 78
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`megapixel option and 18,800 pixel swathwidth for 120 mega-
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`pixel option.
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`It is another obj ect ofthis invention to integrate a GPS/IMU
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`device for this twin camera imaging system that provides
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`GPS time reference, direct image geo-reference, and direct
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`image mosaic capabilities to all of its captured images.
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`It is yet another object of this invention to provide a dual
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`camera system that acquires quickly deliverable precisely
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`geo -referenced nadir shooting panoramic images rather than
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`oblique shooting fan shaped images.
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`These and other objects are further accomplished by a dual
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`swath imaging system comprising a first CCD camera
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`mounted on a remote sensing platform, the first CCD camera
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`comprises a first CCD imager and a nadir pointing first optical
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`lens, a first lens shift mount attached between a body of the
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`first camera and the first optical lens for shifting the first
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`optical lens a predetermined distance left with respect to the
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`first camera body and first CCD imager, a second CCD cam-
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`era mounted on the platform adjacent to the first CCD camera,
`APPL-1031 / Page 9 of 15
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`APPL-1031 / Page 9 of 15
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`US 8,462,209 B2
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`the second CCD camera comprises a second CCD imager and
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`a nadir pointing second optical lens, a second lens shift mount
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`attached between a body of the second CCD camera, and the
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`second optical lens for shifting the second optical lens a
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`predetermined distance right with respect to the body of the
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`second CCD camera and the second CCD imager, the first
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`CCD camera comprises the first CCD imager positioned on a
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`right side of a first focal point of the first optical lens for
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`capturing a left scene image, and the second CCD camera
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`comprises the second CCD imager positioned on a left side of
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`the second focal point ofthe second optical lens for capturing
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`a right scene image. The dual-swath imaging system further
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`comprises means for forming a dual-swath panoramic scene
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`by narrow overlapping of the left scene image and the right
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`scene image at adjacent edges. The first lens shift mount shifts
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`the first optical lens a predetermined distance up to halfwidth
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`ofthe first CCD imager, and the second lens shift mount shifts
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`the second optical lens a predetermined distance up to half-
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`width of the second CCD imager. The system comprises
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`means for generating a trigger pulse for simultaneously acti-
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`vating the first camera and the second camera to acquire the
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`left scene image and the right scene image.
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`The objects are further accomplished by a photogrammet-
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`ric imaging system comprising a first CCD camera mounted
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`on a platform having a nadir pointing first optical lens, and a
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`second CCD camera mounted on the platform adjacent to the
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`first CCD camera and having a nadir pointing second optical
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`lens, the first CCD camera comprises a first CCD imager
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`positioned on a right side of a first focal point of the first
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`optical lens for capturing a left scene image, the second CCD
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`camera comprises a second CCD imager positioned on a left
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`side of a second focal point of a second optical lens for
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`capturing a right scene image, means for geo -referencing the
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`left scene image, means for storing the geo-referenced left
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`scene image, means for geo-referencing the right scene
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`image, means for storing the geo-referenced right scene
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`image, and means for merging the geo-referenced left scene
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`image and the geo-referenced right scene image to form a
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`dual-swath panorama. The system comprises means for form-
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`ing a panoramic scene by narrow overlapping ofthe left scene
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`image and the right scene image at adjacent edges. The first
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`optical lens attaches to a first lens shift mount and the second
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`optical lens attaches to a second lens shift mount, the first lens
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`shift mount being attached to the first CCD camera and the
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`second lens shift mount being attached to the second CCD
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`the first optical lens and the second optical lens whereby the
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`first CCD imager and the second CCD imager are shifted on
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`right and left focal points of the first optical lens and the
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`second optical lens. The system comprises means for gener-
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`ating a trigger pulse for simultaneously activating the first
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`camera and the second camera to acquire the left scene image
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`and the right scene image. The left scene geo-referencing
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`means comprises means for attaching real time GPS/IMU
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`metadata measurements
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`recorded. The right scene geo-referencing means comprises
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`means for attaching real time GPS/IMU metadata measure-
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`ments to each image captured and recorded, the imaging
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`system wherein the means for forming a panoramic scene by
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`narrow overlapping ofthe left scene image and the right scene
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`image comprises means for generating digital elevation mod-
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`els wherein a measured width of the overlapping field pro-
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`vides a real time above ground level height and the imaging
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`system wherein the system comprises minimal size and
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`weight for portability and use in light manned and unmanned
`aerial vehicles.
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`The objects are further accomplished by a method for
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`providing a dual-swath imaging system comprising the steps
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`of mounting a first CCD camera on a remote sensing plat-
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`form, the first CCD camera comprises a first CCD imager and
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`a nadir pointing first optical lens, attaching a first lens shift
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`mount between a body of the first camera and the first optical
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`lens for shifting the first optical lens a predetermined distance
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`with respect to the first camera body and first CCD imager,
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`mounting a second CCD camera on the platform adjacent to
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`the first CCD camera, the second CCD camera comprises a
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`second CCD imager and a nadir pointing second optical lens,
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`attaching a second lens shift mount between a body of the
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`second CCD camera and the second optical lens for shifting
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`the second optical lens a predetermined distance with respect
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`to the second CCD camera and the second CCD imager,
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`capturing a left scene image by the first CCD camera having
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`the first CCD imager positioned on a right side of the first
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`focal point ofthe first optical lens, and capturing a right scene
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`image by the second CCD camera having the second CCD
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`imager positioned on a left side of the second focal point of
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`the second optical lens. The method wherein the method
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`comprises the step of forming a dual-swath panoramic scene
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`by narrow overlapping of the left scene image and the right
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`scene image at adjacent edges, the step of attaching the first
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`lens shift mount and, shifting the first optical lens a predeter-
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`mined distance includes providing the predetermined dis-
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`tance to be up to a halfwidth of the first CCD imager, and the
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`step of attaching the second lens shift mount and shifting the
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`second optical lens a predetermined distance includes provid-
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`ing the predetermined distance to be up to a halfwidth of the
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`second CCD imager.
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`Additional objects, features and advantages of the inven-
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`tion will become apparent to those skilled in the art upon
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`consideration of the following detailed description of the
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`preferred embodiments exemplifying the best mode of carry-
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`ing out the invention as presently perceived.
`BRIEF DESCRIPTION OF THE DRAWINGS
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`The appended claims particularly point out and distinctly
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`claim the subject matter ofthis invention. The various objects,
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`advantages and novel features of this invention will be more
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`fully apparent from a reading of the following detailed
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`description in conjunction with the accompanying drawings
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`in which like reference numerals refer to like parts, and in
`which:
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`FIG. 1 is a block diagram of a dual-swath imaging system
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`according to the present invention.
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`FIGS. 2A, 2B and 2C illustrate the imaging principle ofthe
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`present invention.
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`FIG. 3 illustrates left and right images provided by the two
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`cameras ofthe imaging system with overlapping field accord-
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`ing to the present invention.
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`FIG. 4 is a block diagram of the data acquisition software
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`program for operation of the dual-swath imaging system of
`FIG. 1.
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`FIG. 5 is a block diagram of an automatic image batch
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`processing method for geo-referencing, and stitching the
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`overlapped dual-swath aerial images of FIG. 3.
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`FIG. 6A, FIG. 6B, and FIG. 6C show the front, top and side
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`views of a lens shift mount (LSM) for attaching a lens to a
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`camera body and shifting the lens a predetermined distance
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`perpendicularly to its optical axis.
`DESCRIPTION OF ILLUSTRATIVE
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`EMBODIMENT
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`Referring to FIG. 1 a block diagram of a dual-swath elec-
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`tro-optical (EO) aerial imaging system 10 according to the
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`APPL-1031 / Page 10 of 15
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`APPL-1031 / Page 10 of 15
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`US 8,462,209 B2
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`6
`TABLE 1
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`5
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`present invention is shown comprising two cameras 12, 14
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`having two identical parallel mounted nadir pointing optical
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`lenses 16, 18 with two identical CCD imagers 11, 13 mounted
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`on a pair of specially configured camera bodies 17, 19. The
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`camera bodies 17, 19 are attached to optical lenses 16, 18 with
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`a pair of mechanical lens shift mounts (LSM) 34-1 and 34-2
`which are mounted between camera 12 elements 16 and 17
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`and between camera 14 elements 18 and 19 with appropriate
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`orientations to have the lens optical axes symmetrically
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`shifted to left and right a predetermined distance to take dual
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`images simultaneously (see FIGS. 2A and 2C).
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`Referring to FIG. 1, FIG. 6A, FIG. 6B and FIG. 6C, FIGS.
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`6A, 6B and 6C show the front, top and side views of a lens
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`shift mount 34 which are used to symmetrically shift the twin
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`lenses 16, 18 a predetermined offset to their original optical
`axis locations. The lens shift mount 34-1 as shown in FIG. 1
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`has a first end 38 (FIG. 6B) that attaches to the camera body
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`17 and a second end 36 for attaching to the optical lens 16.
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`This lens shift mount 34 shifts the lens a predetermined dis-
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`tance 39 (FIG. 6B) up to a half width of the CCD imagers 11,
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`13, which is determined by the width of the center overlap
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`strip (for example, a 200 pixel width of the overlap when
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`focused at infinity in the present embodiment) and results in
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`the CCD imagers 11, 13 being symmetrically shifted on the
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`left and right focal points of the lenses 16, 18 by approxi-
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`mately 23.17 mm each in the present embodiment. FIG. 6A
`and FIG. 6B show the orientation of the lens shift mount 34-2
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`for attaching to camera body 19. For attaching to camera body
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`17, the lens shift mount 34-1 is rotated 180 degrees from the
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`position shown in FIG. 6B.
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`The two cameras 12 and 14 are triggered simultaneously by
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`a common open/close trigger pulse 23 from a precision ana-
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`log switch wired inside instrument module 26 when receiving
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`a programmed CMOS-logic level pulse input from the main
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`DAS/CPU unit 20. When triggered, camera 12 acquires digi-
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`tal images and sends image data 27 to a first DAS/CPU
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`module 20 which includes a first data acquisition system
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`(DAS) for interfacing with a first central processing unit
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`(CPU) wherein both the DAS and CPU are integrated in the
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`stackable module 20. Camera 14 acquires digital images
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`simultaneously with Camera 12 and sends image data 29 to a
`second DAS/CPU module 22 which includes a second DAS
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`45
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`for interfacing with a second CPU inside a second DAS/CPU
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`module 22. The DAS/CPU module 20 processes and sends
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`imaging data 27 of camera 12 to a removable solid state disk
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`(SSD) 24 inside an IMU/GPS and mass memory multi-func-
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`tion instrument module 26 via a computer Serial ATA (SATA)
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`data cable, which is a part of inter-module connection buses
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`28. The DAS/CPU module 22 processes and sends imaging
`data 29 of camera 14 to another removable solid state disk
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`(SSD) 25 inside the multi-function instrument module 26 via
`another SATA cable in bus 28. Meanwhile the CPUs of DAS/
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`CPU module 20 and DAS/CPU module 22 attach real time
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`GPS/IMU metada