Your search keyword '"Tang, Gongguo"' showing total 2 results

1. Experimental robustness of Fourier ptychography phase retrieval algorithms

Author

Yeh, Li-Hao, Dong, Jonathan, Zhong, Jingshan, Tian, Lei, Chen, Michael, Tang, Gongguo, Soltanolkotabi, and Waller, Laura

Subjects

Atomic, Molecular and Optical Physics, Physical Sciences, Bioengineering, Networking and Information Technology R&D (NITRD), Optical Physics, Electrical and Electronic Engineering, Communications Technologies, Optics, Communications engineering, Electronics, sensors and digital hardware, Atomic, molecular and optical physics

Abstract

Fourier ptychography is a new computational microscopy technique that provides gigapixel-scale intensity and phase images with both wide field-of-view and high resolution. By capturing a stack of low-resolution images under different illumination angles, an inverse algorithm can be used to computationally reconstruct the high-resolution complex field. Here, we compare and classify multiple proposed inverse algorithms in terms of experimental robustness. We find that the main sources of error are noise, aberrations and mis-calibration (i.e. model mis-match). Using simulations and experiments, we demonstrate that the choice of cost function plays a critical role, with amplitude-based cost functions performing better than intensity-based ones. The reason for this is that Fourier ptychography datasets consist of images from both brightfield and darkfield illumination, representing a large range of measured intensities. Both noise (e.g. Poisson noise) and model mis-match errors are shown to scale with intensity. Hence, algorithms that use an appropriate cost function will be more tolerant to both noise and model mis-match. Given these insights, we propose a global Newton's method algorithm which is robust and accurate. Finally, we discuss the impact of procedures for algorithmic correction of aberrations and mis-calibration.

Published

2015

2. Experimental robustness of Fourier ptychography phase retrieval algorithms.

Author

Yeh, Li-Hao, Dong, Jonathan, Zhong, Jingshan, Tian, Lei, Chen, Michael, Tang, Gongguo, Soltanolkotabi, Mahdi, and Waller, Laura

Subjects

Optics, Optical Physics, Communications Technologies, Electrical and Electronic Engineering

Abstract

Fourier ptychography is a new computational microscopy technique that provides gigapixel-scale intensity and phase images with both wide field-of-view and high resolution. By capturing a stack of low-resolution images under different illumination angles, an inverse algorithm can be used to computationally reconstruct the high-resolution complex field. Here, we compare and classify multiple proposed inverse algorithms in terms of experimental robustness. We find that the main sources of error are noise, aberrations and mis-calibration (i.e. model mis-match). Using simulations and experiments, we demonstrate that the choice of cost function plays a critical role, with amplitude-based cost functions performing better than intensity-based ones. The reason for this is that Fourier ptychography datasets consist of images from both brightfield and darkfield illumination, representing a large range of measured intensities. Both noise (e.g. Poisson noise) and model mis-match errors are shown to scale with intensity. Hence, algorithms that use an appropriate cost function will be more tolerant to both noise and model mis-match. Given these insights, we propose a global Newton's method algorithm which is robust and accurate. Finally, we discuss the impact of procedures for algorithmic correction of aberrations and mis-calibration.

Published

2015