Radar Cross Section Handbook, Volume 2George T. Ruck |
From inside the book
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Page 566
... spheroid can be used by choosing an equivalent spheroid with the same volume and an axial ratio equal to the average axial ratio of the cone . Thus , the equivalent spheroid will have an axial ratio of a / b , cot a or ( cot a ) / 4 ...
... spheroid can be used by choosing an equivalent spheroid with the same volume and an axial ratio equal to the average axial ratio of the cone . Thus , the equivalent spheroid will have an axial ratio of a / b , cot a or ( cot a ) / 4 ...
Page 571
... Spheroid . All the shapes previously considered had surface discontinuities ( edges ) which were large , often dominant , contributors to the cross section . It is instructive to now consider a perfectly conducting shape which has no ...
... Spheroid . All the shapes previously considered had surface discontinuities ( edges ) which were large , often dominant , contributors to the cross section . It is instructive to now consider a perfectly conducting shape which has no ...
Page 939
... spheroid 367-368 ogive 371-373 parabolic antenna 666-667 plasma sheaths 874-875 prolate - oblate spheroid 578 prolate spheroid 352 , 355-356 , 361-363 rectangular plate 524-527 rough surfaces 753-770 lunar surface 761-763 sea 765-761 ...
... spheroid 367-368 ogive 371-373 parabolic antenna 666-667 plasma sheaths 874-875 prolate - oblate spheroid 578 prolate spheroid 352 , 355-356 , 361-363 rectangular plate 524-527 rough surfaces 753-770 lunar surface 761-763 sea 765-761 ...
Other editions - View all
Radar Cross Section Handbook, Volume 1 George T. Ruck,Donald E. Barrick,William D. Stuart No preview available - 2002 |
Common terms and phrases
90 Angle absorber amplitude Angle From Vertical angle of incidence antenna approximation Aspect Angle aurora average backscattering cross backscatter cross section body circular polarization contribution corner reflector cosĀ² curves cylinder degrees Fig dielectric dielectric constant diffraction effects electron density equations Exponential frequency Fresnel reflection function Gaussian geometrical given height high-frequency horizontal polarization impedance incident field ionized ionosphere JPDF Ka-band layer linear polarization load LR or RL Mcps measured normal incidence obtained parallel polarization parameters Perfectly conducting surface permittivity perpendicular polarization phase physical-optics plane plasma radar cross section radius reflection coefficient region rough surface Salisbury screen scattered field scattered power scattering cross section section per unit shown in Figure sinĀ² slightly rough specular sphere surface-height correlation coefficient tan's target technique theory unit area values velocity versus incidence angle versus the angle Vertical polarization wave wavelength X-band zero