Tomographic reconstruction of tokamak plasma light emission from single image using wavelet-vaguelette decomposition

yen, Romain Nguyen van; Fedorczak, N.; Brochard, F.; Bonhomme, G.; Schneider, Kai; Farge, Marie; Monier‐Garbet, P.

doi:10.1088/0029-5515/52/1/013005

Cited by 15 publications

(31 citation statements)

References 32 publications

(51 reference statements)

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“…Taking advantage of the slow variation of the fluctuations along magnetic field lines in tokamaks, this inverse problem can be modelled by a helical Abel transform, which is a Volterra integral operator of the first kind. In [33] we proposed a tomographic inversion technique, based on a wavelet-vaguelette decomposition and coupled with wavelet denoising to extract coherent structures, that allows to detect individual blobs on the projected movie and to analyse their behaviour. The wavelet-vaguelette decomposition (WVD) was introduced by Tchamitchian [43] and used by Donoho [12] to solve inverse problems in the presence of localized structures.…”

Section: Tomographic Reconstruction Using Wavelet-vaguelette Decomposmentioning

confidence: 99%

“…Right: denoised frame obtained by applying the operator K to the reconstructed emissivity map. From [33].…”

Section: Application To Fast Camera Data From Tokamaksmentioning

confidence: 99%

“…The technicalities of WVD are described in detail in Nguyen van yen et al. (2012), in the following we explain only the principle. The helical Abel transform related the plasma light emissivity (a scalar-valued field) to the integral of the volume emissivity received by the camera , where is a compact continuous operator.…”

Section: Extraction Of Coherent Structures Using Waveletsmentioning

confidence: 99%

“…( c ) Noisy image obtained by adding Gaussian white noise with variance 0.5 (from Nguyen van yen et al. 2012). …”

Section: Extraction Of Coherent Structures Using Waveletsmentioning

confidence: 99%

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Wavelet transforms and their applications to MHD and plasma turbulence: a review

Farge

Schneider

2015

J. Plasma Phys.

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International audienceWavelet analysis and compression tools are reviewed and different applications to study MHD and plasma turbulence are presented. We introduce the continuous and the orthogonal wavelet transform and detail several statistical diagnostics based on the wavelet coefficients. We then show how to extract coherent structures out of fully developed turbulent flows using wavelet-based denoising. Finally some multiscale numerical simulation schemes using wavelets are described. Several examples for analyzing, compressing and computing one, two and three dimensional turbulent MHD or plasma flows are presented

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Section: Tomographic Reconstruction Using Wavelet-vaguelette Decomposmentioning

confidence: 99%

“…Right: denoised frame obtained by applying the operator K to the reconstructed emissivity map. From [33].…”

Section: Application To Fast Camera Data From Tokamaksmentioning

confidence: 99%

Section: Extraction Of Coherent Structures Using Waveletsmentioning

confidence: 99%

“…( c ) Noisy image obtained by adding Gaussian white noise with variance 0.5 (from Nguyen van yen et al. 2012). …”

Section: Extraction Of Coherent Structures Using Waveletsmentioning

confidence: 99%

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Wavelet transforms and their applications to MHD and plasma turbulence: a review

Farge

Schneider

2015

J. Plasma Phys.

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“…Wavelet-based density estimation techniques have also been used to improve particle-in-cell numerical schemes [11], and a particle-in-wavelet scheme was developed for solving the Vlasov-Poisson equations directly in wavelet space [12]. Wavelet de-noising has been applied for tomographic reconstruction of tokamak plasma light emission in [13]. Coherent Vorticity and Current sheet Simulation (CVCS), which applies wavelet filtering to the resistive non-ideal MHD equations, was proposed as a new model for turbulent MHD flows.…”

Section: Introductionmentioning

confidence: 99%

Wavelet methods for studying the onset of strong plasma turbulence

et al. 2018

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Recent simulations have demonstrated that coherent current sheets dominate the kinetic-scale energy dissipation in strong turbulence of magnetized plasma. Wavelet basis functions are a natural tool for analyzing turbulent flows containing localized coherent structures of different spatial scales.Here, wavelets are used to study the onset and subsequent transition to fully developed turbulence from a laminar state. Originally applied to neutral fluid turbulence, an iterative wavelet technique decomposes the field into coherent and incoherent contributions. In contrast to Fourier power spectra, finite time Lyapunov exponents (FTLE), and simple measures of intermittency such as non-Gaussian statistics of field increments, the wavelet technique is found to provide a quantitative measure for the onset of turbulence and to track the transition to fully developed turbulence. The wavelet method makes no assumptions about the structure of the coherent current sheets or the underlying plasma model. Temporal evolution of the coherent and incoherent wavelet fluctuations is found to be highly correlated (Pearson correlation coefficient of > 0.9) with the magnetic field energy and plasma thermal energy, respectively. The onset of turbulence is identified with the rapid growth of a background of incoherent fluctuations spreading across a range of scales and a corresponding drop in the coherent components. This is suggestive of the interpretation of the coherent and incoherent wavelet fluctuations as measures of coherent structures (e.g., current sheets) and dissipation, respectively. The ratio of the incoherent to coherent fluctuations R ic is found to be fairly uniform across different plasma models and provides an empirical threshold for turbulence onset. The utility of this technique is illustrated through examples. First, it is applied to the Kelvin-Helmholtz instability from different simulation models including fully kinetic, hybrid (kinetic ion/fluid electron), and Hall MHD simulations. Second, the wavelet diagnostic is applied to the development of turbulence downstream of the bowshock in a global magnetosphere simulation. Finally, the wavelet technique is also shown to be useful as a de-noising method for particle simulations.

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Plasma tomographic reconstruction from tangentially viewing camera with background subtraction

Odstrčil

Mlynář

Weinzettl

et al. 2014

Review of Scientific Instruments

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Light reflections are one of the main and often underestimated issues of plasma emissivity reconstruction in visible light spectral range. Metallic and other specular components of tokamak generate systematic errors in the optical measurements that could lead to wrong interpretation of data. Our analysis is performed at data from the tokamak COMPASS. It is a D-shaped tokamak with specular metallic vessel and possibility of the H-mode plasma. Data from fast visible light camera were used for tomographic reconstruction with background reflections subtraction to study plasma boundary. In this article, we show that despite highly specular tokamak wall, it is possible to obtain a realistic reconstruction. The developed algorithm shows robust results despite of systematic errors in the optical measurements and calibration. The motivation is to obtain an independent estimate of the plasma boundary shape.

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Tomographic reconstruction of tokamak plasma light emission from single image using wavelet-vaguelette decomposition

Cited by 15 publications

References 32 publications

Wavelet transforms and their applications to MHD and plasma turbulence: a review

Wavelet transforms and their applications to MHD and plasma turbulence: a review

Wavelet methods for studying the onset of strong plasma turbulence

Plasma tomographic reconstruction from tangentially viewing camera with background subtraction

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