|
[1] CARLSTROM T N, GLASS F, DU D, et al. Thomson scattering
measurements on DIII-D using in-vessel laser mirrors and lenses to diagnose a
new divertor location [J]. Review of Scientific Instruments, 2018, 89(10): 10C111.
[2] HUANG Y, ZHANG P, FENG Z, et al. The development of Thomson
scattering system on HL-2A tokamak [J]. Review of Scientific Instruments, 2007,
78(11): 113501.
[3] YAMADA I, NARIHARA K, FUNABA H, et al. Recent progress of the
LHD Thomson scattering system [J]. Fusion Science and Technology, 2010, 58(1): 345-351.
[4] SCANNELL R, WALSH M J, CAROLAN P G, et al. Enhanced edge
Thomson scattering on MAST [J]. Review of Scientific Instruments, 2006, 77(10):
1663.
[5] LEBLANC B P, BELL R E, JOHNSON D W, et al. Operation of the
NSTX Thomson scattering system [J]. Review of Scientific Instruments, 2003,
74(3): 1659-1662.
[6] 王瑜琴,黄渊,刘春华, 等. HL-2M
装置上汤姆逊散射系统中多色光谱仪的优化设计 [J]. 核聚变与等离子体物理, 2016, 36(2): 111-118.
[7] SUN H. Thin lens equation for a real laser beam with weak
lens aperture truncation [J]. Optical Engineering, 1998, 37(11): 2906-2913.
[8] LI H Y, LI S J, XIE Q F, et al. Thomson scattering diagnostic
system for the XuanLong-50 experiment [J]. Review of Scientific Instruments,
2022, 93(5): 053504.
[9] GONG S, SHI Z, ZHOU Y, et
al. Optical design of vertical edge Thomson scattering on HL-3 tokamak [J].
Plasma Science and Technology, 2023, 25(7): 075601.
|
