A. Bilenca

TL;DR: In this article, the authors theoretically and experimentally illustrate a new apertured near-field scanning optical microscopy (NSOM) technique, termed differential NSOM (DNSOM), which involves scanning a relatively large (e.g., 0.3-2 mum wide) rectangular aperture (or a detector) in the near field of an object and recording detected power as a function of the scanning position.

TL;DR: This article proposes two experimental realizations of fluorescence interferometry that detect the interference pattern cast by the fluorescence fields and discusses their measurement capabilities and limitations and compares them with those offered by optical low‐coherence interferometric schemes.

TL;DR: It is shown that, by incoherently averaging OFDI reflectance signals acquired at different backscattering angles, speckle noise is reduced, allowing scattering coefficients to be extracted from a single A-line with much higher accuracy than with measurements from conventional OFDI and optical coherence tomography systems.

TL;DR: The MMC method can be useful in efficiently studying numerous applications of light propagation in complex biological media where the remitted photon yield is low, and the results agree very well with diffusion theory as well as classical Monte-Carlo simulations.