Local phase control for a planar array of fiber laser amplifiers

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. Reliance on a global beam splitter limits scalability to larger array sizes due to lack of design modularity. This paper describes a conceptual design and control scheme that relies only on feedback from the array structure itself. A modular and scalable geometry is based on individual hexagonal frames for each emitter; each frame cell consists of a conventional lens mounted in front of the fiber tip. A rigid phase tap structure physically connects two adjacent emitter frame cells. A target sensor is mounted on top of the phase tap, representing the local alignment datum. Optical sensors measure the relative position of the phase tap and target sensor. The tap senses the exit phase of both emitters relative to the target normal plane, providing information to the phase controller for each emitter. As elements are added to the array, relative local position data between adjacent phase taps allows accurate prediction of the relative global position of emitters across the array, providing additional constraints to the phase controllers. The approach is scalable for target distance and number of emitters without loss of control.

[1]  Gary B. Hughes,et al.  Toward directed energy planetary defense , 2014 .

[2]  G. Hughes,et al.  The Transient Optical Sky Survey Data Pipeline , 2012, 1210.1529.

[3]  Michael G. Wickham,et al.  Coherently coupled high power fiber arrays , 2006 .

[4]  Gary B. Hughes,et al.  Relativistic propulsion using directed energy , 2013, Optics & Photonics - Optical Engineering + Applications.

[5]  M A Vorontsov,et al.  Adaptive phase-distortion correction based on parallel gradient-descent optimization. , 1997, Optics letters.

[6]  Gary B. Hughes,et al.  DE-STAR: Phased-array laser technology for planetary defense and other scientific purposes , 2013, Optics & Photonics - Optical Engineering + Applications.

[7]  Gary B. Hughes,et al.  DE-STARLITE: A directed energy planetary defense mission , 2014, Optics & Photonics - Optical Engineering + Applications.

[8]  Mikhail A. Vorontsov,et al.  Adaptive phase-locked fiber array with wavefront phase tip-tilt compensation using piezoelectric fiber positioners , 2007, SPIE Optical Engineering + Applications.

[9]  Juho Kannala,et al.  A generic camera model and calibration method for conventional, wide-angle, and fish-eye lenses , 2006, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[10]  Federico Capasso,et al.  Flat Optics: Controlling Wavefronts With Optical Antenna Metasurfaces , 2013, IEEE Journal of Selected Topics in Quantum Electronics.

[11]  P. Epp,et al.  Coherently coupled high power fiber arrays , 2006, 2006 Digest of the LEOS Summer Topical Meetings.

[12]  T. J. Wagner,et al.  Fiber laser beam combining and power scaling progress: Air Force Research Laboratory Laser Division , 2012, Other Conferences.

[13]  Pu Zhou,et al.  Coherent beam combination of two-dimensional high power fiber amplifier array using stochastic parallel gradient descent algorithm , 2009 .

[14]  Pu Zhou,et al.  Coherent beam combining of two fiber amplifiers using stochastic parallel gradient descent algorithm , 2009 .

[15]  Gary B. Hughes,et al.  Optical modeling for a laser phased-array directed energy system , 2014, Optics & Photonics - Optical Engineering + Applications.

[16]  Gary B. Hughes,et al.  A fast high-precision six-degree-of-freedom relative position sensor , 2016, SPIE OPTO.

[17]  Mark E. Weber,et al.  Diffractive-optics-based beam combination of a phase-locked fiber laser array. , 2008, Optics letters.

[18]  Joshua E. Rothenberg,et al.  Active phase and polarization locking of a 1.4 kW fiber amplifier. , 2010, Optics letters.

[19]  Bing He,et al.  Coherent beam combination of two nanosecond fiber amplifiers by an all-optical feedback loop. , 2012, Optics letters.

[20]  M. Zervas,et al.  High Power Fiber Lasers: A Review , 2014, IEEE Journal of Selected Topics in Quantum Electronics.

[21]  Zhengyou Zhang,et al.  A Flexible New Technique for Camera Calibration , 2000, IEEE Trans. Pattern Anal. Mach. Intell..

[22]  Qingchang Tan,et al.  A Flexible Calibration Method Using the Planar Target with a Square Pattern for Line Structured Light Vision System , 2014, PloS one.

[23]  Mikhail A. Vorontsov,et al.  Phase-locking of tiled fiber array using SPGD feedback controller , 2005, SPIE Optics + Photonics.

[24]  T. Weyrauch,et al.  Adaptive Array of Phase-Locked Fiber Collimators: Analysis and Experimental Demonstration , 2009, IEEE Journal of Selected Topics in Quantum Electronics.

[25]  D. V. Murphy,et al.  Coherent combining of a 4 kW, eight-element fiber amplifier array. , 2011, Optics letters.

[26]  Gary B. Hughes,et al.  Stand-off molecular composition analysis , 2015, SPIE Optical Engineering + Applications.

[27]  Gary B. Hughes,et al.  Directed energy planetary defense , 2013, 2015 IEEE Aerospace Conference.

[28]  Gary B. Hughes,et al.  Directed energy active illumination for near-Earth object detection , 2014, Optics & Photonics - Optical Engineering + Applications.

[29]  Mikhail A Vorontsov,et al.  Laser beam projection with adaptive array of fiber collimators. II. Analysis of atmospheric compensation efficiency. , 2008, Journal of the Optical Society of America. A, Optics, image science, and vision.

[30]  Gary B. Hughes Algorithms for sensor chip alignment to blind datums , 2006, J. Electronic Imaging.

[31]  Roger Y. Tsai,et al.  A versatile camera calibration technique for high-accuracy 3D machine vision metrology using off-the-shelf TV cameras and lenses , 1987, IEEE J. Robotics Autom..

[32]  Rongtao Su,et al.  Active coherent beam combining of a five-element, 800 W nanosecond fiber amplifier array. , 2012, Optics letters.