Introduction to Radio EngineeringCRC Press, 14 oct. 2016 - 294 pages The book introduces the basic foundations of high mathematics and vector algebra. Then, it explains the basic aspects of classical electrodynamics and electromagnetism. Based on such knowledge readers investigate various radio propagation problems related to guiding structures connecting electronic devices with antenna terminals placed at the different radar systems. It explains the role of antennas in process of transmission of radio signals between the terminals. Finally, it shows the relation between the main operational charactistics of each kind of radar and the corresponding knowledge obtained from the previous chapters. |
Table des matières
Differential Operators in Classical Electrodynamics | |
NTRODUCTION TO CLASSICAL ELECTRODYNAMICS | |
References | |
Electromagnetic Waves Propagation in Various Media | |
Reflection and Refraction of Electromagnetic Waves | |
GUIDING STRUCTURES AND GUIDING WAVES | |
References | |
References | |
RADAR FUNDAMENTALS | |
MillimeterWave Radars | |
Guiding GPRs Based on Leaky Coaxial Cables | |
Physical Fundamentals of GroundPenetrating Radars and Remote | |
ESPUWB Radar Systems Applications | |
Structures | |
Autres éditions - Tout afficher
Introduction to Radio Engineering Nathan Blaunstein,Christos G. Christodoulou,Mikhail Sergeev Aucun aperçu disponible - 2016 |
Introduction to Radio Engineering Nathan Blaunstein,Christos G. Christodoulou,Mikhail Sergeev Aucun aperçu disponible - 2020 |
Expressions et termes fréquents
amplitude angle Applications arbitrary attenuation Blaunstein boundary conditions buried object Cartesian coordinate system Chapter characteristics clutter coaxial cable coefficient conductivity conductor corresponding cylindrical defined density depth described detection dielectric differential E₁ E₂ electric and magnetic electric field electromagnetic wave Engineering Example FDTD field component follows from Equation formulas free space frequency function ground-penetrating radar guiding structures H₁ H₂ IEEE Trans imaging incident inhomogeneous integral intrinsic impedance introduced ionosphere layer leaky coaxial cable magnetic field Maxwell's equations Microwave MMW radars mode normalized obtain operator permittivity phase velocity phasor plane wave presented in Figure propagation constant propagation parameter pulse radar systems radiation radio radiometer range scalar scattered shown in Figure signal solution spherical coordinate system subsoil medium subsurface surface target transmission line transmitted transverse vector voltage wave propagation waveguide wavelength Wiley York