TY - GEN
T1 - Faraday effect based optical fiber current sensor for tokamaks
AU - Aerssens, Matthieu
AU - Gusarov, Andrei
AU - Brichard, Benoît
AU - Massaut, Vincent
AU - Mégret, Patrice
AU - Wuilpart, Marc
N1 - Score = 3
PY - 2011
Y1 - 2011
N2 - Fiber optical current sensor (FOCS) is a technique considered to be compatible with the ITER nuclear environment. FOCS principle is based on the magneto-optic Faraday effect that produces non-reciprocal circular birefringence when a magnetic field is applied in the propagation direction of the light beam. The magnetic field or the electrical current is deduced from the modification of the state of polarization of light. The linear birefringence of the fiber related with non-perfect manufacturing, temperature changes or stress constitute a parasitic effect that reduces the precision and sensitivity of FOCS. A two-pass optical scheme with a Faraday mirror at the end has been proposed to compensate the influence of linear birefringence. In this paper we perform a Stokes analysis of the two-pass optical scheme to highlight the fact that the linear birefringence is not compensated perfectly by the Faraday mirror when non-reciprocal birefringence such as Faraday effect is also present.
AB - Fiber optical current sensor (FOCS) is a technique considered to be compatible with the ITER nuclear environment. FOCS principle is based on the magneto-optic Faraday effect that produces non-reciprocal circular birefringence when a magnetic field is applied in the propagation direction of the light beam. The magnetic field or the electrical current is deduced from the modification of the state of polarization of light. The linear birefringence of the fiber related with non-perfect manufacturing, temperature changes or stress constitute a parasitic effect that reduces the precision and sensitivity of FOCS. A two-pass optical scheme with a Faraday mirror at the end has been proposed to compensate the influence of linear birefringence. In this paper we perform a Stokes analysis of the two-pass optical scheme to highlight the fact that the linear birefringence is not compensated perfectly by the Faraday mirror when non-reciprocal birefringence such as Faraday effect is also present.
KW - Fiber optical current sensor (FOCS)
KW - Faraday effect
KW - Linear birefringence compensation
KW - Plasma current measurements
UR - http://ecm.sckcen.be/OTCS/llisapi.dll/open/ezp_121084
U2 - 10.1109/ANIMMA.2011.6172868
DO - 10.1109/ANIMMA.2011.6172868
M3 - In-proceedings paper
SN - 9781457709265
T3 - ANIMMA 2011 - Proceedings: 2nd International Conference on Advancements in Nuclear Instrumentation, Measurement Methods and their Applications
BT - ANIMMA 2011 - Proceedings
CY - Danvers, United States
T2 - 2011 - ANIMMA - Advancements in Nuclear Instrumentation Measurement Methods and their Applications
Y2 - 6 June 2011 through 9 June 2011
ER -