Sura heating facility transmissions to the CASSIOPE/e‐POP satellite

Sura heating facility transmissions to the CASSIOPE/e‐POP satellite

Throughout a nighttime pass of the CASSIOPE satellite at an altitude of about 1300 km above the Sura heating facility, transmission of O‐mode radiation from Sura to the enhanced Polar Outflow Probe (e‐POP) Radio Receiver Instrument on CASSIOPE was maintained. Also, during this pass, continuous VHF/U...

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Bibliographic Details
Published in:Radio science Vol. 52; no. 2; pp. 259 - 270
Main Authors: James, H. G., Frolov, V. L., Andreeva, E. S., Padokhin, A. M., Siefring, C. L.
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-02-2017
Subjects:
CASSIOPE/e‐POP
Heating
Ionosphere
Ionospherics
O‐mode ducted propagation
Radio
radio receiver
Radio receivers
Receivers & amplifiers
Satellites
Sura heating
Tomography
transionospheric
UHF
VHF
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Summary:Throughout a nighttime pass of the CASSIOPE satellite at an altitude of about 1300 km above the Sura heating facility, transmission of O‐mode radiation from Sura to the enhanced Polar Outflow Probe (e‐POP) Radio Receiver Instrument on CASSIOPE was maintained. Also, during this pass, continuous VHF/UHF transmission from the e‐POP Coherent Electromagnetic Radio Tomography radio beacon to three coordinated ground receivers in the Sura vicinity was achieved. Tomography of the VHF/UHF received wave data based on total electron content permitted the two‐dimensional distribution of ionospheric ambient electron plasma frequency fpe to be determined in the latitude‐altitude space between Sura and CASSIOPE. The foF2 values about 0.1 MHz above the Sura pump frequency of 4.3 MHz were measured by the tomography. We examine the question of whether the observations can be explained on the basis of classic propagation in a smooth ionosphere. Tracing of rays from Sura toward CASSIOPE orbital locations finds most rays reflected away from the topside by the patchy ionospheric structure in bottomside fpe. It is concluded that O‐mode ducting in underdense field‐aligned irregularities is responsible for maintaining the transionospheric transmission across the 2 min pass. O‐ to Z‐mode “radio‐window” conversion in the F region bottomside is not required to explain these data. Key Points Strong O‐mode transmission from Sura was received by e‐POP Radio Receiver Instrument Ionospheric tomography provided the ionospheric density distribution Ray tracing indicates that the observed transionospheric transmission requires O‐mode ducting
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ISSN:0048-6604
1944-799X
DOI:10.1002/2016RS006190