Developments in electromagnetic scattering in high frequency and resonance regions
Read Online

Developments in electromagnetic scattering in high frequency and resonance regions proceedings of the Middle East Technical University International Symposium held in Ankara, 16-19 June, 1980. by Middle East Technical University International Symposium (1980 Ankara)

  • 663 Want to read
  • ·
  • 58 Currently reading

Published by [Middle East Technical University] in [Ankara] .
Written in English

Book details:

Edition Notes

ContributionsOrta Dog u Teknik U niversitesi.
ID Numbers
Open LibraryOL14177926M

Download Developments in electromagnetic scattering in high frequency and resonance regions


  The treatment, initiated in Paper I [J. Math. Phys. 10, 82 ()], of the high‐frequency scattering of a scalar plane wave by a transparent sphere is continued. The main results here are an improved theory of the rainbow and a theory of the glory. The modified Watson transformation is applied to the third term of the Debye expansion of the scattering amplitude in terms of multiple ://   Light scattering by small particles has a long and interesting history in physics. Nonetheless, it continues to surprise with new insights and applications. This includes new discoveries, such as We know that the radar target's characteristic dimension is 1 m if we use the high frequency band of 30 MHz MHz, and m if using the high frequency band of MHz-3 GHz, and about m High Frequency Asymptotics vs. Numerical Techniques regions. In Region I, incident, reflected, and diffracted electromagnetic scattering around a 60 -wedge

Rajat Acharya, in Satellite Signal Propagation, Impairments and Mitigation, Mie scattering. Mie scattering theory is the generalized solution that describes the scattering of an electromagnetic wave by a homogeneous spherical medium having RI different from that of the medium through which the wave is traversing. It is worth reiterating that Mie scattering is not any independent physical However, in the visible and IR regions of the spectrum, due to the fact that the theory ignores all other contributions to optical absorption, the simulation did not match with the measurement. Thus, Mie theory is useful around the resonance frequency, but the broad spectrum of the lamp needs to be considered in an accurate model of the :// Perform 3D analyses on resonance, propagating, radiation and scattering problems. Perform 2D modal analyses on waveguides and transmission lines. Understand how to set up boundary conditions and excitation sources. Analyze full-wave high-frequency electromagnetic field problems. Postprocess results to obtain electromagnetic Request PDF | On Feb 1, , V.V. Koledov and others published The interaction of electromagnetic waves with VO2 nanosized spheres and films in optical and extremely high frequency range. | Find

Electromagnetic, seismic and acoustic equations are considered. Recent developments in methods and analysis ranging from finite differences to hp-adaptive finite elements, including high-accuracy and fast methods are described with extensive :// Coherent anti-Stokes Raman spectroscopy (CARS) This technique involves the phenomenon of wave mixing, takes advantage of the high intensity of stimulated Raman scattering, and has the applicability of conventional Raman the CARS method two strong collinear laser beams at frequencies ν 1 and ν 2 (ν 1 > ν 2) irradiate a the frequency difference, ν 1 − ν 2, is   more intense than the dipole) in scattering by small particles with negative dielectric susceptibility and weak dissipation23, and anomalous scattering with the complicated near-field structures, such as the vortices, unusual frequency dependence, etc, In addition, the Fano resonances, which We see this in the electromagnetic context as well – extremely high-frequency, high-energy electromagnetic waves can give rise. Waves Appl. Characteristics of Electromagnetic Wave. X-rays are electromagnetic waves having the same nature as visible light, ultra violet, infrared, radio waves and microwaves,