Melissa:
[quote="mgmeyer"]
Actually, the passive radar I have been working on is not over-the-horizon. It's a line-of-sight VHF system -- which is currently implemented as a bistatic device, with the receivers separated by a few hundred km. The illumination is commercial FM radio stations, with one receiver dedicated to obtaining the reference illumination, and the other for collecting scattered signals. TDOA-type measurements are possible; I have used multiple FM transmitters to detect point targets (airplanes, and also a meteor once) and used that to estimate the target location. The scatter can be received in a single location so long as the transmitters are spaced enough apart (sort of the opposite of what you described with listening to the scatter from a single station in several different locations).
I've also done a good amount of work with interferometry and imaging. I think that would be the way to go for finding angles of arrival for meteor scatter. It would require multiple antennas (3 or 5) (or else we have to work hard at deconvolving the mutual coupling of the antennas to put them close together).
[b]I guess that I agree with you. We would need interferometry and keeping track of the phases to find exactly where a metaor happened.[/b]
The HF frequencies that the hams use for OTH DXing *are* more useful for detecting meteors. The radar meteor folks (and radio amateurs interested in meteor bounces) split meteor events into two categories -- those with underdense and those with overdense trails. The threshold here is I believe about 10^14 free electrons generated per meter of trail (I suppose the overdense trails come from bigger meteors). At HF you can see the underdense trails, but as the frequency climbs, of course the lower density trails become invisible. (The HF "SuperDARN" radar chain at the north and south poles sees tons of meteors, and has to work pretty hard to see through the clutter they cause! While my system, at VHF, only sees an occasional blip.)
[b]I think that the line density is two orders of magnitude lower, if I remember correctly.[/b]
All of this is in reference to "specular-like" reflections from the plasma of meteor trails, but there is another scattering mechanism that can allow radars to detect meteor ablation, and that is Bragg scatter from density irregularities in the trail plasma. These density waves/turbulence result from instabilities like the Kelvin-Helmholtz and density gradients on the edges of the plasma tube. At VHF frequencies, I suspect the majority of our meteor detections are due to this effect. But we'll see specular reflections from overdense meteor trails that are oriented so that their long dimension is perpendicular to the radar line of sight. (Only the really powerful radars, like arecibo, altair, etc can detect "head echoes" - scatter from the meteor itself.)
[b]One thing we found with a large L-band phased array was that during meteor showers we detect echoes from 200km+ altitudes. This has been partly confirmed by unpublished EISCAT observations. Our interpretation is that there we see plasma produced by sputtering, since the atmospheric density is too low to support classical ablation.[/b]
A complication is that while HF is better for detecting meteors (any system serious about monitoring meteor traffic should probably be HF), there is a lack of good "free" illumination at HF to use in a passive radar system. Plus, atmospheric refraction effects come into play and will have to be dealt with.
The analog TV channels are around 60-70 MHz... still VHF, but lower at least. I'm not sure how useful they'd be for meteor trails. But they don't make great radar waveforms, because of a horizontal scan sync pulse, which introduces a range ambiguity of (I believe) 8 km.
[b]There are, in principle, two research avenues one could follow. The first is to concentrate on "classical" meteors, those between 80 and 130 km, and measure them both with optical means (modified CONCAMs) and with a passive radar that would provide accurate plasma parameters such as density and time development. The science would come from correlating the optical with the plasma diagnostics and these would then be input into an ablation model that would have to have shock wave heating, different materials, rotation of an irregular body, etc. The second would be to concentrate on the high altitude exotic meteor component, detect and measure the plasma parameters, and make a serious attempt to increase the number and quality of the optical detections at these altitudes.[/b]
Satellites are a possible illumination source, although their signal strength tends to be low and their frequencies high.
I'm not familiar with the GLONASS/Galileo satellites, but GPS is at an even higher frequency, which will sail right through the vast majority of meteor trails, and the Bragg scattering cross section for the plasma density irregularities also decreases with frequency.
There are many people who use differential GPS measurements to do ionospheric tomography, determining integrated electron density (from GPS altitude (20000km) to ground). I'm not sure if the GPS signals would be useful for meteor trail detection, but I suspect not.
Given that we could find some useful illumination: I had not been thinking of a TDOA-like approach, but that could be useful, either as a primary detection scheme or as validation. Currently my passive radar setup is bistatic - requiring two spatially-separated receivers to implement the full radar system - so adding a third and doing TDOA for point targets would be feasible. I have been experimenting with distributed multistatic passive radar as a tool for studying space weather-related effects, and I'm very interested in additional uses for sprinkling these receivers around the globe. The more science we can get out of these instruments, the better.
Not sure if you've seen this stuff, but here are a couple references on deducing orbits of meteors ((what is the difference between a meteor and a meteoroid?)) from radar AOA information:
Baggaley et al., 1993 ([url]
http://adsabs.harvard.edu/abs/1993mtpb.conf..245B[/url])
Morton and Jones, 1982 ([url]
http://adsabs.harvard.edu/abs/1982MNRAS.198..737M[/url])
[b]I have met Jack Baggaley and I know Peter Brown and Margaret Campbell-Brown, so I am familiar with their papers. Thanks for the refs, though.
Noah[/b]
