Dependence of radar signal strength on frequency and aspect angle of nonspecular meteor trails

Details Dependence of radar signal strength on frequency and aspect angle of nonspecular meteor trails Dependence of radar signal strength on frequency and aspect angle of nonspecular meteor trails

Jun 2008

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2008jgra..11306203c&link_type=abstract

Journal of Geophysical Research, Volume 113, Issue A6, CiteID A06203

Physics

7

Ionosphere: Meteor-Trail Physics, Ionosphere: Plasma Waves And Instabilities (2772), Ionosphere: Ionospheric Irregularities, Radio Science: Ionospheric Physics (1240, 2400), Radio Science: Radar Atmospheric Physics (1220)

Scientific paper

When a meteoroid penetrates Earth's atmosphere, it forms a high-density ionized plasma column immersed in the ionosphere between approximately 70 and 140 km altitude. High-power, large-aperture (HPLA) radars detect nonspecular trails when VHF or UHF radio waves reflect off structures in a turbulent meteor trail. These trails persist from a few milliseconds to many minutes and the return from these trails is referred to as nonspecular trails or range-spread trail echoes. In this paper, we present analysis of nonspecular trails detected with ALTAIR, which is an HPLA radar operating simultaneously at 160 MHz and 422 MHz on the Kwajalein Atoll. First, we investigate the aspect sensitivity of nonspecular trails and show that as the angle between the radar beam and the background magnetic field increases, the signal strength falls off 3 to 4 dB per degree at 160 MHz. For ALTAIR, this means that the aspect angle must be within approximately 12 degrees in order to detect nonspecular trails using the chosen waveforms. Second, we compare and contrast the meteoroids that form nonspecular trails and find that the meteoroid energy causes much of the variability in the nonspecular trail's signal-to-noise ratio (SNR) for a given aspect angle. In addition, we show two range-resolved fragmentation events that also affect the SNR. Finally, we determine the dependence of SNR on wavelength using two wavelengths and show that the maximum nonspecular trail SNR scales as approximately λ 6, with a variation that depends upon altitude.

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