Proceedings of LFNM ...Institution of Electrical and Electronics Engineers, 2005 - Fiber optics |
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Page 123
... beam concerning the lattice wave vector . The optical power ranges from 5 up to 50 μW in experiments with linear and nonlinear propagation of light beams within the lattices . EXPERIMENTAL RESULTS First , we study the features of ...
... beam concerning the lattice wave vector . The optical power ranges from 5 up to 50 μW in experiments with linear and nonlinear propagation of light beams within the lattices . EXPERIMENTAL RESULTS First , we study the features of ...
Page 137
... beam is marked as 1 . Arcs 2 , 4 and 8 are due to beam diffraction on the many of S. - like gratings . Scattering 3 and arcs 5 , 11 are because of diffraction of waveguide modes on gratings . Spots 6 , 9 and 7 , 10 appear due to ...
... beam is marked as 1 . Arcs 2 , 4 and 8 are due to beam diffraction on the many of S. - like gratings . Scattering 3 and arcs 5 , 11 are because of diffraction of waveguide modes on gratings . Spots 6 , 9 and 7 , 10 appear due to ...
Page 241
... beam traveling inside corner reflector undergoes total internal reflection on each face of the prism . It is clear that the edge of the prism is a strong inhomogeneity on beam's trajectory thus light beam diffracts on the edge and ...
... beam traveling inside corner reflector undergoes total internal reflection on each face of the prism . It is clear that the edge of the prism is a strong inhomogeneity on beam's trajectory thus light beam diffracts on the edge and ...
Contents
LFNM Plenary | 1 |
BatteryLess Spatial Optical Communication Terminals for LocationBased Indoor | 14 |
Resonant Photoproduction of the ElectronPositron Pair with Photon Emission | 27 |
Copyright | |
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active allows amplitude analysis application approximation band beam boundary calculated carrier cavity characteristics circuit coefficient considered corresponding coupled crystal curves dependence described determined device diffraction direction distribution e-mail effect efficiency electric Electronics elements energy equation error excitation experimental fiber field filter frequency function gain given grating IEEE increasing input intensity interval laser lattice layer length light limited losses maximum measurement medium method mirror mode modulation noise nonlinear observed obtained operation optical oscillator output parameters periodic phase photonic polarization possible presented problem propagation pulse pumping quantum radiation range REFERENCES reflection refractive index region resonator sample scattering semiconductor sensor shift shown shows signal simulation solitons solution spatial spectral spectrum structure surface temperature thickness transmission Ukraine University University of Guanajuato wave waveguide wavelength width