Full-field Fourier ptychography (FFP): spatially varying pupil modeling and its application for rapid field-dependent aberration metrology
Pengming Song, Shaowei Jiang, He Zhang, Xizhi Huang, Yongbing Zhang,, and Guoan Zheng

TL;DR
This paper introduces a full-field Fourier ptychography method that efficiently models and measures spatially varying aberrations across an entire field of view, enabling rapid and robust aberration metrology without moving parts.
Contribution
The paper presents a novel FFP scheme that recovers full-field aberration coefficients with significantly fewer parameters and faster computation, improving upon previous Fourier ptychography methods.
Findings
Aberration coefficients can be recovered in approximately 35 seconds using a CPU.
The method reduces optimization degrees of freedom by over two orders of magnitude.
No moving parts or calibration targets are required for aberration measurement.
Abstract
Digital aberration measurement and removal play a prominent role in computational imaging platforms aimed at achieving simple and compact optical arrangements. A recent important class of such platforms is Fourier ptychography, which is geared towards efficiently creating gigapixel images with high resolution and large field of view (FOV). In current FP implementations, pupil aberration is often recovered at each small segment of the entire FOV. This reconstruction strategy fails to consider the field-dependent nature of the optical pupil. Given the power series expansion of the wavefront aberration, the spatially varying pupil can be fully characterized by tens of coefficients over the entire FOV. With this observation, we report a Full-field Fourier Ptychography (FFP) scheme for rapid and robust aberration metrology. The meaning of 'full-field' in FFP is referred to the recovering of…
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