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203 results on '"Mauel, M. E."'

1. Low latency optical-based mode tracking with machine learning deployed on FPGAs on a tokamak.

Author

Wei, Y., Forelli, R. F., Hansen, C., Levesque, J. P., Tran, N., Agar, J. C., Di Guglielmo, G., Mauel, M. E., and Navratil, G. A.

Abstract

Active feedback control in magnetic confinement fusion devices is desirable to mitigate plasma instabilities and enable robust operation. Optical high-speed cameras provide a powerful, non-invasive diagnostic and can be suitable for these applications. In this study, we process high-speed camera data, at rates exceeding 100 kfps, on in situ field-programmable gate array (FPGA) hardware to track magnetohydrodynamic (MHD) mode evolution and generate control signals in real time. Our system utilizes a convolutional neural network (CNN) model, which predicts the n = 1 MHD mode amplitude and phase using camera images with better accuracy than other tested non-deep-learning-based methods. By implementing this model directly within the standard FPGA readout hardware of the high-speed camera diagnostic, our mode tracking system achieves a total trigger-to-output latency of 17.6 μs and a throughput of up to 120 kfps. This study at the High Beta Tokamak-Extended Pulse (HBT-EP) experiment demonstrates an FPGA-based high-speed camera data acquisition and processing system, enabling application in real-time machine-learning-based tokamak diagnostic and control as well as potential applications in other scientific domains. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Tangential extreme ultraviolet and soft x-ray diagnostic system for time-resolved temperature measurement on the High Beta Tokamak-Extended Pulse.

Author

Li, Boting, Levesque, J. P., Wei, Y., Saperstein, A., Chandra, R. N., Navratil, G. A., Mauel, M. E., and Hansen, C.

Subjects
SOFT X rays, PYROMETRY, TIME-resolved measurements, ELECTRON temperature, ELECTRON temperature measurement, WORK design, THOMSON scattering
Abstract

The High Beta Tokamak-Extended Pulse has recently incorporated a tangential multi-energy extreme ultraviolet and soft x-ray diagnostic system. This system enables measurements of the electron temperature and the examination of mode dynamics within the tokamak. While other systems have been built for poloidal views over similar temperature ranges, this is the first multi-energy tangential-view system designed to work in a temperature range below 200 eV in a tokamak. To facilitate these measurements, a filter wheel comprising five distinct groups of dual-filters has been developed and implemented. By employing a combination of 0.1 μm aluminum and 0.2 μm titanium filters, the system allows estimation of electron temperature profiles through reconstruction of the emission profile using the standard "double-foil" technique. The influence of impurities and filter oxide layers on measurement outcomes is examined. Results reveal that, while the absolute electron temperature values may exhibit some deviations, key characteristics like the electron temperature profile shape and inversion radius during sawtooth events remain consistent. This consistency confirms the system's suitability for core plasma studies. This system has proven effective in detecting and analyzing internal magnetohydrodynamic phenomena, such as sawteeth. [ABSTRACT FROM AUTHOR]

Published
2023
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17. Preface to the Special Issue: Strategic Opportunities for Fusion Energy

Author

Massachusetts Institute of Technology. Plasma Science and Fusion Center, Greenwald, Martin J, Ryutov, Dmitri, Zarnstorff, Mike, Mauel, M. E., Massachusetts Institute of Technology. Plasma Science and Fusion Center, Greenwald, Martin J, Ryutov, Dmitri, Zarnstorff, Mike, and Mauel, M. E.

Abstract

The Journal of Fusion Energy provides a forum for discussion of broader policy and planning issues that play a crucial role in energy fusion programs. In keeping with this purpose and in response to several recent strategic planning efforts worldwide, this Special Issue on Strategic Opportunities was launched with the goal to invite fusion scientists and engineers to record viewpoints of the scientific opportunities and policy issues that can drive continued advancements in fusion energy research.

Published
2016

20. Pressure profiles of plasmas confined in the field of a magnetic dipole

Author

Massachusetts Institute of Technology. Plasma Science and Fusion Center, Kesner, Jay, Garnier, Darren, Davis, Matthew S., Mauel, M. E., Massachusetts Institute of Technology. Plasma Science and Fusion Center, Kesner, Jay, Garnier, Darren, Davis, Matthew S., and Mauel, M. E.

Abstract

Equilibrium pressure profiles of plasmas confined in the field of a dipole magnet are reconstructed using magnetic and x-ray measurements on the levitated dipole experiment (LDX). LDX operates in two distinct modes: with the dipole mechanically supported and with the dipole magnetically levitated. When the dipole is mechanically supported, thermal particles are lost along the field to the supports, and the plasma pressure is highly peaked and consists of energetic, mirror-trapped electrons that are created by electron cyclotron resonance heating. By contrast, when the dipole is magnetically levitated losses to the supports are eliminated and particles are lost via slower cross-field transport that results in broader, but still peaked, plasma pressure profiles., United States. Dept. of Energy (National Science Foundation (U.S.). Partnership in Plasma Science. Grant DE-FG02-00ER54585), United States. Dept. of Energy (National Science Foundation (U.S.). Partnership in Plasma Science. Award PHY-1201896)

Published
2015

27. 137 and 165 GHZ radiometer measurements of hot electrons in LDX

Author

Massachusetts Institute of Technology. Plasma Science and Fusion Center, Kesner, Jay, Woskov, Paul P., Garnier, Darren, Mauel, M. E., Massachusetts Institute of Technology. Plasma Science and Fusion Center, Kesner, Jay, Woskov, Paul P., Garnier, Darren, and Mauel, M. E.

Abstract

Summary form only given. The levitated dipole experiment (LDX) is investigating a levitated dipole magnetic configuration as an alterative confinement concept for fusion plasmas. A 1.1 MA, 68 cm mean diameter, 560 kg superconducting coil (F-coil) is floated for up to 3 hours between cryogenic recoolings by a 280 kA levitating coil during which time plasmas are pulsed by electron cyclotron breakdown and heating (ECH). Up to a total of 15 kW ECH power from three sources at 2.45 (2.5 kW), 6.4 (2.5 kW), and 10.5 GHz (10 kW) are pulsed to sustain plasmas for up to 14 s with a slowly decaying afterglow detectable for over 20 s. Electron densities in the range of 10[superscript 11] cm[superscript -3] with highly peaked profiles (~1/r[superscript 4]) are diagnosed with a 4-channel 60 GHz interferometer. Significant hot electron synchrotron emission has been observed with two heterodyne radiometers, at 137 and 165 GHz, 3 GHz double sideband (DBS) each and noise temp, of 3000 and 2000 K DBS, respectively. The receivers' field of view (FOV) where combined by a 4-port corrugated Al waveguide beamsplitter (quartz) block and transmitted in HE[subscript 11] mode by a 35 mm dia., 1.1 m long ceramic waveguide to a quartz vacuum widow (>95% trans, at 137 & 165 GHz) located below the F-coil. About 9 dB attenuation was necessary in the waveguide to avoid receiver saturation. The radiometer views were directed vertically upward 28 cm from the dipole axis in X-mode orientation. A 2.3 m distance from window to plasma peak resulted in 1/e[superscript 2] plasma FOV diameters of 29 and 24 cm at 137/165 GHz, respectively. Equivalent blackbody temperatures at 137/165 GHz as high as 620/410 eV were observed at the vacuum window during sustained plasma operation, dropping to about 110/60 eV within 1 s at the start of the afterglow and then deceasing exponentially to 0.2/0.1 eV about 24 s later. These are lower limits for the actual peak plasma emission because the receiver FOVs aren't uniformly, United States. Dept. of Energy

Published
2012

42. Constance mirror program: Progress and plans

Author

Klinkowstein, R. E, Mauel, M. E, Irby, J. H, Smullin, L. D, and Voldman, S. H

Subjects
Plasma Physics
Abstract

The current state of the mechanics of the Constance II experiment, the physics results gathered, the motivation background, and future plans for the Constance II experiment are reviewed. Several improvements have been made and several experimental investigations have been completed. These include the construction/installation/testing of: (1) liquid-nitrogen cooled, Ioffe bars installed, (2) a diverter coil (3) the 100 kW ICRF generator, (4) the data acquisition system, and (5) the optimum hot-iron operation of the machine with Titanium and pulsed-gas plasma guns. Measurements were made of the density, temperature, and radius of the plasma. Ion-cyclotron fluctuations were observed, their bandwidth measured, and data collected demonstrating resonance heating. New X-ray diagnostics were designed and purchased, and progress on the Thomson scattering was made. Finally, a new hot cathode gun was designed and constructed.

Published
1981

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