Radar Cross Section: Its Prediction, Measurement, and ReductionArtech House, 1985 - 462 Seiten The leading text and reference on radar cross section (RCS) theory and applications, this work presents a comparison of two radar signal strengths. One is the strength of the radar bean sweeping over a target, the other is the strength of the reflected echo senses by the receiver. This book shows how the RCS "gauge" can be predicted for theoretical objects. |
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Seite 22
... bandwidth is typically wide , the IF bandwidth normally sets the noise bandwidth of the radar receiver . If a matched filter receiver is to be employed , it is normally implemented at IF . It is also in the IF section that automatic ...
... bandwidth is typically wide , the IF bandwidth normally sets the noise bandwidth of the radar receiver . If a matched filter receiver is to be employed , it is normally implemented at IF . It is also in the IF section that automatic ...
Seite 37
... bandwidth . The noise bandwidth of the receiver B , is a function of the IF filter response shape , but the three - dB IF bandwidth is normally used without appreciable error [ 1 ] . The ideal receiver would add no noise to the signal ...
... bandwidth . The noise bandwidth of the receiver B , is a function of the IF filter response shape , but the three - dB IF bandwidth is normally used without appreciable error [ 1 ] . The ideal receiver would add no noise to the signal ...
Seite 247
... bandwidth around 20 percent for a material thickness close to λ / 4 , which is somewhat less bandwidth than for the Salisbury screen . For magnetic materials , the bandwidth increases as the material becomes thinner . The values plotted ...
... bandwidth around 20 percent for a material thickness close to λ / 4 , which is somewhat less bandwidth than for the Salisbury screen . For magnetic materials , the bandwidth increases as the material becomes thinner . The values plotted ...
Inhalt
Introduction | 1 |
Radar Fundamentals | 13 |
Physics and Overview of Electromagnetic Scattering | 47 |
Urheberrecht | |
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Andere Ausgaben - Alle anzeigen
Radar Cross Section Eugene F. Knott,John F. Schaeffer,Michael T. Tulley Eingeschränkte Leseprobe - 2004 |
Radar Cross Section Eugene F. Knott,John F. Schaeffer,Michael T. Tulley Keine Leseprobe verfügbar - 2004 |
Radar Cross Section Eugene F. Knott,John F. Schaeffer,Michael T. Tulley Keine Leseprobe verfügbar - 2004 |
Häufige Begriffe und Wortgruppen
absorbing material admittance amplitude anechoic chamber antenna Antennas Propag aspect angle axis bandwidth bistatic body broadside circuit components cone corner reflector creeping wave curved cylinder dBsm degrees density detection dielectric diffraction diffraction coefficients direction echo edge electric field electromagnetic energy equation evaluation Figure foam free space function geometric optics ground plane high frequency illuminated impedance incident field incident wave integral Keller layer lobe magnetic field matrix Maxwell's equations median metal microwave normal nose-on performance phase physical optics polarization pulse radar absorbing radar absorbing material radar cross section radiation RATSCAT RCS measurements RCSR receiver reduce reflection coefficient region rotation Salisbury screen scattered field sheet shown in Fig signal solution specular point support column surface target techniques theory tion transmission line transmitted traveling wave typically values vector waveguide wavelength wire zero