Abstract
Radio frequency transmissions from each satellite in the Constellation Observing System for Meteorology, Ionosphere, and Climate (COSMIC) can be used to study the plasma in the upper atmosphere by (1) providing profiles and two dimensional images of the ionosphere and (2) monitoring phase and amplitude scintillations induced in radio waves propagating through the ionosphere. In addition, the received radio data can be applied to the neutral atmosphere by (a) detecting horizontal fluctuations in tropospheric water vapor and (b) yielding accurate position data for satellite drag and neutral density determination. A three-frequency radio beacon called the Tri-Band Beacon (TBB) is being developed for the COSMIC pro-gram to provide transmissions at VHF, UHF and L-band. Tomographic imaging of the ionosphere is a recently developed technique that uses integrated measurements and computer reconstructions to determine electron densities. The integral of electron density along vertical or oblique paths is obtained by employing radio transmissions from low-earth-orbiting (LEO) COSMIC satellite transmitters to a chain of receivers on the earth’s surface. Analyzing the total electron content (TEC) data using computerized ionospheric tomography (CIT) produces two-dimensional maps of the ionospheric plasma. Difficulties associated with CIT arise from the non-unique ness of the reconstructions owing to limited angle measurements or non optimal receiver. Improvements in both reconstruction algorithms and CIT measurement systems are being implemented for the COSMIC mission by combining the GPS occultation data with the TBB measurements of TEC. once the ionospheric effects on the radio wave propagation have been de termined, the Doppler shifts of the UHF and VHF transmissions can be analyzed to give positioning of the COSMIC satellites to within a few meters. By measuring the effects of the atmospheric drag on the COSMIC satellites, global data for neutral densities in the upper atmosphere can he obtained. There is an additional phase delay of the VHF/UHFIL-bands from the neutral constituents of the troposphere. This phase delay can be used to provide measurements of integrated water vapor. The spatial distribution of water vapor density may be determined with high precision phase measurements from a linear array of ground receivers observing the L-band transmissions of the COSMIC TBB.
Highlights
Can be used to study the plasma in the upper atmosphere by (1) providing profiles and two dimensional images of the ionosphere and (2) monitoring phase and amplitude scintillations induced in radio waves propagating through the ionosphere
The spatial distribution of water vapor density may be determined with high precision phase mea surements from a linear array of ground receivers observing the L-band transmissions of the COSMIC Tri-Band Beacon (TBB)
The earth's upper atmosphere contains a partially ionized plasma that is constantly changing under the influence of solar extreme ultraviolet (EUV) radiation, recombination chemistry, neutral winds, and electric fields (Rishbeth and Garriott, 1969; Kelley, 1989)
Summary
The Constellation Observing System for Meteorology, Ionosphere, and Climate (COS MIC) uses multi-point sensors that employ line-of-sight measurements for studying the Earth's atmosphere. The three sensors on each COSMIC satellite are (1) the Tri-Band Beacon (TBB), (2) Tiny Ionospheric Photometer (TIP), and (3) GPS occultation receiver These instruments are complementary in their observations by using both radio and optical measurements. The primary objective of the Tri-Band Beacon experiment on COSMIC is to study the electron density in the Earth's ionosphere. The second objective of the Tri-Band B eacon is to measure the influence of ionospheric irregularities on VHF (150 MHz), UHF (400 MHz) and L-B and (1067 MHz) transmissions from space to the ground This is accomplished by recording amplitude and phase scintilla tions between the COSMIC beacon and ground receivers. This use of the radio beacon can provide a source of water vapor measurements that are relatively inexpensive compared to measure ments from radiometers.
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