Microwave polarimetry system in the CDX-U tokamak

Y. S. Hwang; Å Fredriksen; H. Qin; C. B. Forest; M. Ono

doi:10.1063/1.1146418

Microwave polarimetry system in the CDX-U tokamak

Y. S. Hwang
, Å Fredriksen
, H. Qin
, C. B. Forest
, M. Ono

PPPL Computational Science

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

Abstract

An existing microwave interferometer system is modified to add the capability of polarimetry in the CDX-U tokamak. Though this interferometer system can scan vertically and radially, only the vertical view channel is modified to accomodate Faraday rotation measurements, with its radial scanning capability preserved. For our relatively long microwave wavelength, the signal amplitude variation due to refraction is more important than effects due to vibration. An amplitude independent design of Faraday rotation diagnostics has been developed. By using a linearly polarized beam as input and putting a rotating polarizer in the beam after the plasma, birefringency effects are minimized. A digital phase detection technique has been developed for better resolution of the Faraday rotation angle.

Original language	English (US)
Pages (from-to)	379-381
Number of pages	3
Journal	Review of Scientific Instruments
Volume	66
Issue number	1
DOIs	https://doi.org/10.1063/1.1146418
State	Published - 1995

All Science Journal Classification (ASJC) codes

Instrumentation

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10.1063/1.1146418

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title = "Microwave polarimetry system in the CDX-U tokamak",

abstract = "An existing microwave interferometer system is modified to add the capability of polarimetry in the CDX-U tokamak. Though this interferometer system can scan vertically and radially, only the vertical view channel is modified to accomodate Faraday rotation measurements, with its radial scanning capability preserved. For our relatively long microwave wavelength, the signal amplitude variation due to refraction is more important than effects due to vibration. An amplitude independent design of Faraday rotation diagnostics has been developed. By using a linearly polarized beam as input and putting a rotating polarizer in the beam after the plasma, birefringency effects are minimized. A digital phase detection technique has been developed for better resolution of the Faraday rotation angle.",

author = "Hwang, \{Y. S.\} and {\AA} Fredriksen and H. Qin and Forest, \{C. B.\} and M. Ono",

year = "1995",

doi = "10.1063/1.1146418",

language = "English (US)",

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pages = "379--381",

journal = "Review of Scientific Instruments",

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AU - Hwang, Y. S.

AU - Fredriksen, Å

AU - Qin, H.

AU - Forest, C. B.

AU - Ono, M.

PY - 1995

Y1 - 1995

N2 - An existing microwave interferometer system is modified to add the capability of polarimetry in the CDX-U tokamak. Though this interferometer system can scan vertically and radially, only the vertical view channel is modified to accomodate Faraday rotation measurements, with its radial scanning capability preserved. For our relatively long microwave wavelength, the signal amplitude variation due to refraction is more important than effects due to vibration. An amplitude independent design of Faraday rotation diagnostics has been developed. By using a linearly polarized beam as input and putting a rotating polarizer in the beam after the plasma, birefringency effects are minimized. A digital phase detection technique has been developed for better resolution of the Faraday rotation angle.

AB - An existing microwave interferometer system is modified to add the capability of polarimetry in the CDX-U tokamak. Though this interferometer system can scan vertically and radially, only the vertical view channel is modified to accomodate Faraday rotation measurements, with its radial scanning capability preserved. For our relatively long microwave wavelength, the signal amplitude variation due to refraction is more important than effects due to vibration. An amplitude independent design of Faraday rotation diagnostics has been developed. By using a linearly polarized beam as input and putting a rotating polarizer in the beam after the plasma, birefringency effects are minimized. A digital phase detection technique has been developed for better resolution of the Faraday rotation angle.

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JO - Review of Scientific Instruments

JF - Review of Scientific Instruments

IS - 1

ER -

Microwave polarimetry system in the CDX-U tokamak

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