Interference of light and material particles is described with a unified model which does not
need to assume the wave-particle duality. A moving particle is associated with a region of …

To describe wave interference, a wave function with a direct physical meaning is used. On
the contrary the distribution of material particles in an interference pattern is calculated with …

The interaction between real and virtual point emitters is presented as the propagation
principle of light under arbitrary spatial coherence. It is supported on a geometrical …

Classical resolution criteria such as Rayleigh's and Sparrow's are based on the fringe
structure produced by Fresnel diffraction or Fraunhofer diffraction. However, these two …

Nonparaxial modeling of optical field propagation at distances comparable to the
wavelength and under arbitrary spatial coherence is crucial for micro-and nano-optics …

Optical point sources are considered theoretical idealizations. However, it is pertinent to
characterize feasible physical point sources for the current micro-and nano-optics. It is …

Interference of light and material particles is described in this chapter with a unified model,
which does not need to assume the superposition principle. A moving particle is associated …

This work presents a linear algebraic theory of partial coherence for optical fields of
continuous variables. This approach facilitates use of linear algebraic techniques and …

The theoretical description of the spatially correlated polarization of electromagnetic wave
fields and its non-paraxial propagation is discussed in terms of pure spatially correlated …

Interference and diffraction with classical waves and quantum particles is discussed in the
framework of a geometric model based on its own physical principle and general law. The …