## Proceedings of LFNM'...: International Workshop on Laser and Fiber-optical Networks Modeling, Volume 4Kharkiv State University of Radio Electronics, 2002 - Fiber optics |

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Page 37

Suppose that the complex amplitude of the field distribution on the output mirror

of the WQR and accordingly at the end of the polyharmonic waveguide , versed

to the phase corrector , be described by circular

Suppose that the complex amplitude of the field distribution on the output mirror

of the WQR and accordingly at the end of the polyharmonic waveguide , versed

to the phase corrector , be described by circular

**function**: 1 , P1 S1 , circ ( 21 ) ...Page 118

Fourier method The split - step Fourier method ( SSFM ) [ 3 ] uses a set of N

harmonic basis

- step wavelet collocation method ( SSWCM ) , the

defines ...

Fourier method The split - step Fourier method ( SSFM ) [ 3 ] uses a set of N

harmonic basis

**functions**4. ( T ) = exp ... Wavelet collocation method For our split- step wavelet collocation method ( SSWCM ) , the

**function**$ ( T ) of Fig . 1defines ...

Page 351

1 ( % ) = $ 10 ( 5,9 ) f ( r ) dr , ( 6 ) where f ( r ) is the distribution

sizes and 1. ( r , ® ) is the radiation scattering indicatrix of a particle . The

mathematical problem of finding the

( 6 ) .

1 ( % ) = $ 10 ( 5,9 ) f ( r ) dr , ( 6 ) where f ( r ) is the distribution

**function**of particlesizes and 1. ( r , ® ) is the radiation scattering indicatrix of a particle . The

mathematical problem of finding the

**function**f ( r ) is to solve the integral equation( 6 ) .

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### Contents

INV L1 NEW CONCEPT OF MULTIPASS RESONATORS FOR GAS AND | 1 |

L2 WIDEAPERTURE ELECTRODISCHARGE EXCIMER LASERS | 8 |

L4 POSSIBILITY OF HIGHFREQUENCY PULSE DISCHARGE | 17 |

Copyright | |

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absorption active allows amplitude angle applied axis beam calculated carried characteristics charge coefficient components considered constant corresponds crystals defined density dependence described determined devices diffraction direction discharge distribution effective electric electrons elements energy equal equation experimental expression factor fiber field frequency function gain given gratings IEEE increase intensity interaction Kharkov laser layer length light linear means measured medium method mirror mode modulation necessary nonlinear observed obtained operator optical output parameters particles periodic phase photonic physical plane polarization positive possible presented problem processes propagation properties pulse pumping quantum radiation range received References reflection refractive resonator scattering shown shows signal solution space spatial spectral structure surface temperature tion transformation Ukraine University vector volume vortex wave waveguide wavelength