Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC

Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC

The performance of future linear colliders will depend critically on beam-based alignment and feedback systems. In ILC and CLIC it is planned to perform dispersion-free steering in the main linacs. To this end the beams are accelerated with different gradients to evaluate the dispersion. The steerin...

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Main Authors: A. Latina, J. Pfingstner, D. Schulte, E. Adli, F. J. Decker, N. Lipkowitz
Format: Article
Language:English
Published: American Physical Society 2014-04-01
Series:Physical Review Special Topics. Accelerators and Beams
Online Access:http://doi.org/10.1103/PhysRevSTAB.17.042803
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spelling doaj-0931e986e0af41019677699493fe3b342020-11-24T22:11:39ZengAmerican Physical SocietyPhysical Review Special Topics. Accelerators and Beams1098-44022014-04-0117404280310.1103/PhysRevSTAB.17.042803Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLACA. LatinaJ. PfingstnerD. SchulteE. AdliF. J. DeckerN. LipkowitzThe performance of future linear colliders will depend critically on beam-based alignment and feedback systems. In ILC and CLIC it is planned to perform dispersion-free steering in the main linacs. To this end the beams are accelerated with different gradients to evaluate the dispersion. The steering is performed by minimizing the average offset of the different beams in the beam position monitors and, at the same time, the difference between the beam trajectories. The experimental verification of the dispersion-free steering algorithm is essential to prove its effectiveness and to prepare the commissioning of such machines. The algorithm should take an orbit measurement at every cycle (train to train), estimate the correction from this information, and, from the system response matrices, apply the correction. We have successfully tested dispersion-free steering at FACET, including an adaptive system-identification algorithm, where the system response matrix is measured dynamically and automatically.http://doi.org/10.1103/PhysRevSTAB.17.042803
collection DOAJ
language English
format Article
sources DOAJ
author A. Latina
J. Pfingstner
D. Schulte
E. Adli
F. J. Decker
N. Lipkowitz
spellingShingle A. Latina
J. Pfingstner
D. Schulte
E. Adli
F. J. Decker
N. Lipkowitz
Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC
Physical Review Special Topics. Accelerators and Beams
author_facet A. Latina
J. Pfingstner
D. Schulte
E. Adli
F. J. Decker
N. Lipkowitz
author_sort A. Latina
title Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC
title_short Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC
title_full Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC
title_fullStr Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC
title_full_unstemmed Experimental demonstration of a global dispersion-free steering correction at the new linac test facility at SLAC
title_sort experimental demonstration of a global dispersion-free steering correction at the new linac test facility at slac
publisher American Physical Society
series Physical Review Special Topics. Accelerators and Beams
issn 1098-4402
publishDate 2014-04-01
description The performance of future linear colliders will depend critically on beam-based alignment and feedback systems. In ILC and CLIC it is planned to perform dispersion-free steering in the main linacs. To this end the beams are accelerated with different gradients to evaluate the dispersion. The steering is performed by minimizing the average offset of the different beams in the beam position monitors and, at the same time, the difference between the beam trajectories. The experimental verification of the dispersion-free steering algorithm is essential to prove its effectiveness and to prepare the commissioning of such machines. The algorithm should take an orbit measurement at every cycle (train to train), estimate the correction from this information, and, from the system response matrices, apply the correction. We have successfully tested dispersion-free steering at FACET, including an adaptive system-identification algorithm, where the system response matrix is measured dynamically and automatically.
url http://doi.org/10.1103/PhysRevSTAB.17.042803
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