2015
DOI: 10.1117/12.2189821
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Local phase control for a planar array of fiber laser amplifiers

Abstract: Arrays of phase-locked lasers have been developed for numerous directed-energy applications. Phased-array designs are capable of producing higher beam intensity than similar sized multi-beam emitters, and also allow beam steering and beam profile manipulation. In phased-array designs, individual emitter phases must be controllable, based on suitable feedback. Most current control schemes sample individual emitter phases, such as with an array-wide beam splitter, and compare to a master phase reference. Relianc… Show more

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Cited by 1 publication
(3 citation statements)
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“…3, based on a design for an extensible phased array laser system. 28,29 Target acquisition algorithms determine the target centroid x c , y c  in the IRFPA pixel array coordinate system. Using camera calibration information, the target centroid x c , y c  is then converted to a target axis θ T , φ T  as polar (θ) and azimuthal (φ) directions in the infrared camera mount mechanical datum coordinate system, using transformations (a LI (b) (e) deduced from innovative calibration algorithms.…”
Section: Target Acquisition With Multiple Focal Planesmentioning
confidence: 99%
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“…3, based on a design for an extensible phased array laser system. 28,29 Target acquisition algorithms determine the target centroid x c , y c  in the IRFPA pixel array coordinate system. Using camera calibration information, the target centroid x c , y c  is then converted to a target axis θ T , φ T  as polar (θ) and azimuthal (φ) directions in the infrared camera mount mechanical datum coordinate system, using transformations (a LI (b) (e) deduced from innovative calibration algorithms.…”
Section: Target Acquisition With Multiple Focal Planesmentioning
confidence: 99%
“…Using camera calibration information, the target centroid x c , y c  is then converted to a target axis θ T , φ T  as polar (θ) and azimuthal (φ) directions in the infrared camera mount mechanical datum coordinate system, using transformations (a LI (b) (e) deduced from innovative calibration algorithms. [30][31][32][33] Conversion from image coordinates to the target axis is accomplished using a composite inverse transformation: 29 ° ° (25) where F is the transformation from the target axis to ideal pixel coordinates, D is a lens distortion mapping, and A is the ideal affine transformation from scene coordinates to pixel coordinates, all determined during camera calibration. The relationship between pixel coordinates and the mechanical mounting is also characterized during fabrication.…”
Section: Target Acquisition With Multiple Focal Planesmentioning
confidence: 99%
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