Phase recovery (PR) refers to calculating the phase of the light field from its intensity
measurements. As exemplified from quantitative phase imaging and coherent diffraction …

When it comes to “phase measurement” or “quantitative phase imaging”, many people will
automatically connect them with “laser” and “interferometry”. Indeed, conventional …

Quantitative phase imaging (QPI) has emerged as a valuable tool for biomedical research
thanks to its unique capabilities for quantifying optical thickness variation of living cells and …

We report a computational 3D microscopy technique, termed Fourier ptychographic
diffraction tomography (FPDT), that iteratively stitches together numerous variably …

Computational microscopy, as a subfield of computational imaging, combines optical
manipulation and image algorithmic reconstruction to recover multi-dimensional microscopic …

Emerging deep-learning (DL)-based techniques have significant potential to revolutionize
biomedical imaging. However, one outstanding challenge is the lack of reliability …

Fourier ptychographic microscopy (FPM) is a computational high‐throughput technique for
high‐resolution and wide field‐of‐view (FOV) imaging applications such as cell biology …

Lens-free on-chip microscopy (LFOCM) has been widely utilized in digital pathology, drug
screening, point-of-care testing (POCT), and quantitative phase imaging (QPI) due to its high …

Intensity diffraction tomography (IDT) provides quantitative, volumetric refractive index
reconstructions of unlabeled biological samples from intensity-only measurements. IDT is …

Quantitative phase imaging (QPI) by differential phase contrast (DPC) with partially coherent
illumination provides speckle-free imaging and lateral resolution beyond the coherent …