Famin Wang
Chinese Academy of Sciences
11 Papers
24 Citations
Famin Wang is an academic researcher from Chinese Academy of Sciences. The author has contributed to research in topics: Point spread function & Resolution (electron density). The author has an hindex of 3, co-authored 7 publications. Previous affiliations of Famin Wang include Shanghai University & University of Science and Technology of China.
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Papers
3D resolution improvement in confocal microscopy by mirror refection interference and fluorescence emission difference
TL;DR: In this paper, a method based on mirror refection interference and fluorescence emission difference is provided to improve the three-dimensional resolution and SNR in confocal microscopy, and numerical simulations have been performed to verify the effectiveness of the method.
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Three-dimensional resolution enhancement in confocal microscopy with radially polarized illumination using subtractive imaging
TL;DR: In this paper, a method based on the subtraction of images taken under radially polarized illumination is provided to improve the three-dimensional resolution in confocal microscopy, and numerical simulations predict that lateral resolutions close to 0.218 λ is possible for practical confocal laser scanning microscopy with visible light.
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Improving confocal microscopy resolution by tangentially polarized illumination and image subtraction
TL;DR: Tangentially polarized light or vortex phase modulated tangentially polarised light are used as confocal microscopy illumination light and image subtraction is studied in this article to improve the resolution.
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Fourier ptychographic rapid superresolution imaging via line-scanning microscopy with virtual structural- modulated
Famin Wang,Famin Wang,Yun Xiao,Jiawang Zhao,Jiawang Zhao,Yunhai Zhang,Hangfeng Li,Hangfeng Li +7 more
TL;DR: The combination of VSM, LSM, and FP algorithm to improve the image acquisition speed, resolution and SNR is reported here to provide a turnkey solution for imaging biological samples with 2 times lateral resolution of wide-field and improved SNR and imaging speed.
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