Envisioning the Future of Computational Optical Microscopy

Related lectures (31)

Page 3 of 4

On Biomicroscopy Logistics covers the syllabus, schedule, and logistics of the course.

Explores Fourier optics, diffraction principles, Fourier analysis, and the application of Fourier transform in optics.

Explores microscopy resolution through diffraction patterns of various apertures and the use of spatial filters.

Explores fluorescence microscopy, high contrast imaging, specificity, and quantum nature of light.

Covers microscopic analyses using optical and electron microscopy, as well as electron sources.

Introduces practical metrology experiments, covering topics like quantum metrology, single-photon experiments, and AFM for nanoscale measurements.

Explores spatial resolution in optics, covering angular resolution, diffraction limits, numerical aperture, and microscope resolution.

Covers synchrotrons, x-ray lasers, and atomic resolution techniques like Cryo-EM and scanning tunneling microscopy.

Explores automated analysis of fluorescence kinetics in microscopy data to reveal protein stoichiometry and its applications.

Explores the principles and applications of Scanning Probe Microscopy techniques.