Citations (14)
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Mikhail V. Tinin. (2023) Wave field in a layer with a linear background profile and multiscale random irregularities. Waves in Random and Complex Media 33:5-6, pages 1295-1306.
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Andrey V. Kulizhsky. (2017) Uniform integral representation for the fluctuating field propagating through the multi-scale media. Waves in Random and Complex Media 27:2, pages 289-307.
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Mikhail
V Tinin. (2004) Wave scattering in a multiscale random inhomogeneous medium. Waves in Random Media 14:2, pages 97-108.
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N
T Afanasiev, S
N Kolesnik & M
V Tinin. (2001) A comparison of the results of a numerical simulation and an approximate calculation of the statistical characteristics of radio waves in a layer with random inhomogeneities of dielectric permittivity. Waves in Random Media 11:4, pages 363-376.
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Articles from other publishers (10)
Mikhail Tinin & Sergei Knizhin. (2020) Some Possibilities of Spatial Signal Processing in an Inhomogeneous Medium Based on DWFT. Radio Science 55:4.
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M.V. Tinin. (2018) Two-Frequency Coherence Function for the Field of a Wave Propagating Through a Multiscale Randomly Inhomogeneous Medium. Radiophysics and Quantum Electronics 61:4, pages 259-271.
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M. V. Tinin. (2018) Higher Approximations to Study Statistical Characteristics of Waves in Multiscale Inhomogeneous Media. Advances in Mathematical Physics 2018, pages 1-13.
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M. V. Tinin & S. I. Knizhin. (2017) On radio wave propagation in multiscale randomly inhomogeneous ionosphere. On radio wave propagation in multiscale randomly inhomogeneous ionosphere.
Mikhail V. Tinin & Sergei I. Knizhin. (2016) Wide-angle generalization of integral representation as double weighted Fourier transform in the problem of wave reflection from a randomly inhomogeneous ionospheric layer. Wide-angle generalization of integral representation as double weighted Fourier transform in the problem of wave reflection from a randomly inhomogeneous ionospheric layer.
Mikhail Tinin. (2016) Wave reflection from randomly inhomogeneous ionospheric layer: 1. The method of describing the wavefield in a reflecting layer with random irregularities. Radio Science 51:8, pages 1350-1362.
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Nikolay N. Zernov & Vadim E. Gherm. (2015) Strong scintillation of GNSS signals in the inhomogeneous ionosphere: 1. Theoretical background. Radio Science 50:2, pages 153-167.
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A. V. Kulizhsky & M. V. Tinin. (2013) About the method of integral field representation as the double weighted Fourier transform in the problems of wave propagation in inhomogeneous media. Radiophysics and Quantum Electronics 55:8, pages 483-492.
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Yuri A. Kravtsov & Mikhail V. Tinin. (2000) Representation of a wave field in a randomly inhomogeneous medium in the form of the double‐weighted Fourier transform. Radio Science 35:6, pages 1315-1322.
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M. V. Tinin, N. T. Afanasiev & A. V. Kulizhsky. (2000) Fluctuations of VHF field in the vicinity of the maximum frequency of operation (shadow-zone boundary). Radiophysics and Quantum Electronics 43:1, pages 14-23.
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