Orbit tomography in constants-of-motion phase-space

M. Rud; D. Moseev; F. Jaulmes; K. Bogar; Y. Dong; P. C. Hansen; J. Eriksson; H. Järleblad; M. Nocente; G. Prechel; B. C.G. Reman; B. Schmidt; Antti Snicker; L. Stagner; A. Valentini; M. Salewski

doi:10.1088/1741-4326/ad4bf4

Orbit tomography in constants-of-motion phase-space

M. Rud^*, D. Moseev, F. Jaulmes, K. Bogar, Y. Dong, P. C. Hansen, J. Eriksson, H. Järleblad, M. Nocente, G. Prechel, B. C.G. Reman, B. Schmidt, Antti Snicker, L. Stagner, A. Valentini, M. Salewski

^*Corresponding author for this work

BA4511 Fusion energy

Research output: Contribution to journal › Article › Scientific › peer-review

8 Citations (Scopus)

Abstract

Tomographic reconstructions of a 3D fast-ion constants-of-motion phase-space distribution function are computed by inverting synthetic signals based on projected velocities of the fast ions along the diagnostic lines of sight. A spectrum of projected velocities is a key element of the spectrum formation in fast-ion D-alpha spectroscopy, collective Thomson scattering, and gamma-ray and neutron emission spectroscopy, and it can hence serve as a proxy for any of these. The fast-ion distribution functions are parameterised by three constants of motion, the kinetic energy, the magnetic moment and the toroidal canonical angular momentum. The reconstructions are computed using both zeroth-order and first-order Tikhonov regularisation expressed in terms of Bayesian inference to allow uncertainty quantification. In addition to this, a discontinuity appears to be present in the solution across the trapped-passing boundary surface in the three-dimensional phase space due to a singularity in the Jacobian of the transformation from position and velocity space to phase space. A method to allow for this apparent discontinuity while simultaneously penalising large gradients in the solution is demonstrated. Finally, we use our new methods to optimise the diagnostic performance of a set of six fans of sightlines by finding where the detectors contribute most complementary diagnostic information for the future COMPASS-Upgrade tokamak.

Original language	English
Article number	076018
Number of pages	20
Journal	Nuclear Fusion
Volume	64
Issue number	7
DOIs	https://doi.org/10.1088/1741-4326/ad4bf4
Publication status	Published - Jul 2024
MoE publication type	A1 Journal article-refereed

Funding

This work has received support from the Niels Bohr Foundation which is a merger of The Niels Bohr Grant, The Emil Herborg Grant, The Grant of Mag.art. Marcus Lorenzen, The Ole R\u00F8mer Foundation and The Julie Marie Vinter Hansen Travel Grant. The views and opinions expressed herein do not necessarily reflect those of The Royal Danish Academy of Sciences and Letters. This work has been carried out within the framework of the EUROfusion Consortium, funded by the European Union via the Euratom Research and Training Programme (Grant Agreement No. 101052200-EUROfusion). Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Commission. Neither the European Union nor the European Commission can be held responsible for them.

Keywords

constants of motion
diagnostics
fast ions
orbits
tomography

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1088/1741-4326/ad4bf4Licence: CC BY

Cite this

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title = "Orbit tomography in constants-of-motion phase-space",

abstract = "Tomographic reconstructions of a 3D fast-ion constants-of-motion phase-space distribution function are computed by inverting synthetic signals based on projected velocities of the fast ions along the diagnostic lines of sight. A spectrum of projected velocities is a key element of the spectrum formation in fast-ion D-alpha spectroscopy, collective Thomson scattering, and gamma-ray and neutron emission spectroscopy, and it can hence serve as a proxy for any of these. The fast-ion distribution functions are parameterised by three constants of motion, the kinetic energy, the magnetic moment and the toroidal canonical angular momentum. The reconstructions are computed using both zeroth-order and first-order Tikhonov regularisation expressed in terms of Bayesian inference to allow uncertainty quantification. In addition to this, a discontinuity appears to be present in the solution across the trapped-passing boundary surface in the three-dimensional phase space due to a singularity in the Jacobian of the transformation from position and velocity space to phase space. A method to allow for this apparent discontinuity while simultaneously penalising large gradients in the solution is demonstrated. Finally, we use our new methods to optimise the diagnostic performance of a set of six fans of sightlines by finding where the detectors contribute most complementary diagnostic information for the future COMPASS-Upgrade tokamak.",

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AU - Rud, M.

AU - Moseev, D.

AU - Jaulmes, F.

AU - Bogar, K.

AU - Dong, Y.

AU - Hansen, P. C.

AU - Eriksson, J.

AU - Järleblad, H.

AU - Nocente, M.

AU - Prechel, G.

AU - Reman, B. C.G.

AU - Schmidt, B.

AU - Snicker, Antti

AU - Stagner, L.

AU - Valentini, A.

AU - Salewski, M.

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N2 - Tomographic reconstructions of a 3D fast-ion constants-of-motion phase-space distribution function are computed by inverting synthetic signals based on projected velocities of the fast ions along the diagnostic lines of sight. A spectrum of projected velocities is a key element of the spectrum formation in fast-ion D-alpha spectroscopy, collective Thomson scattering, and gamma-ray and neutron emission spectroscopy, and it can hence serve as a proxy for any of these. The fast-ion distribution functions are parameterised by three constants of motion, the kinetic energy, the magnetic moment and the toroidal canonical angular momentum. The reconstructions are computed using both zeroth-order and first-order Tikhonov regularisation expressed in terms of Bayesian inference to allow uncertainty quantification. In addition to this, a discontinuity appears to be present in the solution across the trapped-passing boundary surface in the three-dimensional phase space due to a singularity in the Jacobian of the transformation from position and velocity space to phase space. A method to allow for this apparent discontinuity while simultaneously penalising large gradients in the solution is demonstrated. Finally, we use our new methods to optimise the diagnostic performance of a set of six fans of sightlines by finding where the detectors contribute most complementary diagnostic information for the future COMPASS-Upgrade tokamak.

AB - Tomographic reconstructions of a 3D fast-ion constants-of-motion phase-space distribution function are computed by inverting synthetic signals based on projected velocities of the fast ions along the diagnostic lines of sight. A spectrum of projected velocities is a key element of the spectrum formation in fast-ion D-alpha spectroscopy, collective Thomson scattering, and gamma-ray and neutron emission spectroscopy, and it can hence serve as a proxy for any of these. The fast-ion distribution functions are parameterised by three constants of motion, the kinetic energy, the magnetic moment and the toroidal canonical angular momentum. The reconstructions are computed using both zeroth-order and first-order Tikhonov regularisation expressed in terms of Bayesian inference to allow uncertainty quantification. In addition to this, a discontinuity appears to be present in the solution across the trapped-passing boundary surface in the three-dimensional phase space due to a singularity in the Jacobian of the transformation from position and velocity space to phase space. A method to allow for this apparent discontinuity while simultaneously penalising large gradients in the solution is demonstrated. Finally, we use our new methods to optimise the diagnostic performance of a set of six fans of sightlines by finding where the detectors contribute most complementary diagnostic information for the future COMPASS-Upgrade tokamak.

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Orbit tomography in constants-of-motion phase-space

Abstract

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Keywords

UN SDGs

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