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Controlling the spatial structure of vector beams synthesized by a fiber laser array

•This paper presents a mathematical model and experimental implementation of a new method for controlling the spatial intensity distribution of a synthesized beam with nonuniformly distributed polarization.•The method is based on phase control of elements of an array of coherent emitters with the gi...

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Published in:	Optics and laser technology 2022-10, Vol.154, p.108351, Article 108351
Main Authors:	Adamov, E.V., Aksenov, V.P., Dudorov, V.V., Kolosov, V.V., Levitskii, M.E.
Format:	Article
Language:	English
Subjects:	Coherent beam combining Cylindrical vector beam Fiber laser Spatial light modulator Spatial structure of beams Vector beam Vortex beam
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container_title	Optics and laser technology
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creator	Adamov, E.V. Aksenov, V.P. Dudorov, V.V. Kolosov, V.V. Levitskii, M.E.
description	•This paper presents a mathematical model and experimental implementation of a new method for controlling the spatial intensity distribution of a synthesized beam with nonuniformly distributed polarization.•The method is based on phase control of elements of an array of coherent emitters with the given distribution of directions of linear polarization.•The phase control is based on the well-known SPGD optimization algorithm in combination with the use of a phase corrector in the feedback loop.•The results of controlling the spatial structure of the beam are presented for phase correctors of two types. This paper presents the mathematical model and experimental implementation of a new method for dynamic control of the spatial intensity distribution of a synthesized beam with nonuniformly distributed polarization. The beam is formed by an array of fiber lasers with the controllable phase and multidirectional linear polarization. The phase control is based on the well-known SPGD optimization algorithm combined with the phase corrector in the feedback loop. The numerical model demonstrates establishment of phase relations between array elements in the dynamic process of SPGD optimization and is actually a “digital twin” of the experiment. It is found that for the experiments with the adaptive mirror (AM) and with the spatial light modulator (SLM) as a phase corrector, identical target spatial structures in the target plane are achieved at different phase distributions in the initial plane.
doi_str_mv	10.1016/j.optlastec.2022.108351
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This paper presents the mathematical model and experimental implementation of a new method for dynamic control of the spatial intensity distribution of a synthesized beam with nonuniformly distributed polarization. The beam is formed by an array of fiber lasers with the controllable phase and multidirectional linear polarization. The phase control is based on the well-known SPGD optimization algorithm combined with the phase corrector in the feedback loop. The numerical model demonstrates establishment of phase relations between array elements in the dynamic process of SPGD optimization and is actually a “digital twin” of the experiment. 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This paper presents the mathematical model and experimental implementation of a new method for dynamic control of the spatial intensity distribution of a synthesized beam with nonuniformly distributed polarization. The beam is formed by an array of fiber lasers with the controllable phase and multidirectional linear polarization. The phase control is based on the well-known SPGD optimization algorithm combined with the phase corrector in the feedback loop. The numerical model demonstrates establishment of phase relations between array elements in the dynamic process of SPGD optimization and is actually a “digital twin” of the experiment. 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This paper presents the mathematical model and experimental implementation of a new method for dynamic control of the spatial intensity distribution of a synthesized beam with nonuniformly distributed polarization. The beam is formed by an array of fiber lasers with the controllable phase and multidirectional linear polarization. The phase control is based on the well-known SPGD optimization algorithm combined with the phase corrector in the feedback loop. The numerical model demonstrates establishment of phase relations between array elements in the dynamic process of SPGD optimization and is actually a “digital twin” of the experiment. It is found that for the experiments with the adaptive mirror (AM) and with the spatial light modulator (SLM) as a phase corrector, identical target spatial structures in the target plane are achieved at different phase distributions in the initial plane.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.optlastec.2022.108351</doi></addata></record>
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subjects	Coherent beam combining Cylindrical vector beam Fiber laser Spatial light modulator Spatial structure of beams Vector beam Vortex beam
title	Controlling the spatial structure of vector beams synthesized by a fiber laser array
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