1) quantum correlated diffraction imaging
量子关联衍射成像
2) intensity correlated quantum imaging
强度关联量子成像
1.
The intensity correlated quantum imaging experiment and application with thermal light restricted by the high bright thermal light to some extent.
高亮度的辐照热光源一定程度上限制了基于经典热光场的强度关联量子成像技术的实验研究和广泛应用。
3) Diffraction Imaging
衍射成像
1.
The Fresnel diffraction imaging technique is used to eliminate the effect of the lateral displacement and data calculating is used to calibrate the fbrication error of the angles.
从五角棱镜的原理和特性出发,叙述了利用五角棱镜扫描建立大平面基准过程中,由于加工角差和当五角棱镜相对入射光束有相对运动时其出射光束的横移对平面基准的影响,提出了用衍射成像技术消除光束横移,数据计算修正棱镜的角度差的影响。
4) three-photon correlated imaging
三光子关联成像
5) non-diffracting imaging
无衍射成像
1.
Based on the theories of non-diffracting imaging system in coherent light,the measurement system of point spread function(PSF) of non-diffracting imaging system has been presented.
在分析相干光照明下无衍射成像系统理论的基础上,设计了无衍射光成像系统的点扩散函数的测量系统。
6) diffraction self_imaging
衍射自成像
1.
The diffraction self_imaging phenomenon of the grating_Talbot effect is explained by using plane wave interference theory.
用平面波干涉理论解释了光栅的衍射自成像现象 (Talbot效应 ) ,并分别对Ronchi光栅和正弦光栅的衍射像给出了理论结
补充资料:单量子阱(见量子阱)
单量子阱(见量子阱)
single quantum well
单且子阱sillgle quantum well见量子阱。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条