Title :
Multigigabit transmission through rain in a dual polarization frequency reuse system: an experimental study
Author :
Hendrix, Charles E. ; Kulon, Gregory ; Anderson, Carin S. ; Heinze, Michael A.
Author_Institution :
Hughes Aircraft Co., El Segundo, CA, USA
fDate :
12/1/1993 12:00:00 AM
Abstract :
An experimental terrestrial link was set up for the purpose of evaluating very-high-data-rate communications in dual-polarization frequency reuse systems. Possible applications are in the field of satellite communications. Two 3.2-Gb/s signals using staggered quadriphase shift keying (SQPSK) were transmitted on opposite senses of circular polarization over a 7-km path located in Crane rain region D3. Performance degradation of the demodulator as a function of cross-polarization discrimination (XPD) was evaluated and found to closely match simulation predictions. However, the relationship between XPD and rain attenuation was found to be more complex than thought previously, displaying a relatively slowly varying hysteresis effect as well as significant interactions with characteristics of the receive antenna. The latter effect suggests that careful control of antenna characteristics may be required if such high-data-rate techniques are to be employed in space-ground links
Keywords :
electromagnetic wave absorption; electromagnetic wave polarisation; electromagnetic wave scattering; frequency allocation; microwave links; phase shift keying; radiowave propagation; rain; satellite links; tropospheric electromagnetic wave propagation; 19.6 GHz; 3.2 Gbit/s; 7 km; Crane rain region D3; SHF; SQPSK; XPD; antenna characteristic; circular polarization; cross-polarization discrimination; demodulator; dual polarization frequency reuse system; experimental terrestrial link; hysteresis effect; multigigabit transmission; performance degradation; rain; rain attenuation; receive antenna; satellite communications; space-ground links; staggered quadriphase shift keying; Attenuation; Cranes; Degradation; Demodulation; Frequency; Hysteresis; Polarization; Predictive models; Rain; Satellite communication;
Journal_Title :
Communications, IEEE Transactions on
