Ionospheric Constraints on VHF/UHF Communications Links during Solar Maximum and Minimum Periods

An extensive VHF/UHF scintillation data base covering the frequency range of VHF to a few gigahertz has been utilized to determine the magnitudes of phase and intensity scintillations and their temporal/spatial structures during the sunspot maximum and minimum periods. The equatorial portion of the...

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Bibliographic Details
Main Authors: Basu, Santimay, MacKenzie, E., Basa, Sunanda
Other Authors: EMMANUEL COLL BOSTON MA
Format: Text
Language:English
Published: 1988
Subjects:
Astrophysics
Atmospheric Physics
Plasma Physics and Magnetohydrodynamics
Radiofrequency Wave Propagation
*IONIZATION
*COMMUNICATIONS NETWORKS
*SCINTILLATION
*SUNSPOTS
*F REGION
*AURORAE
REPRINTS
DENSITY
MEASUREMENT
POSITION(LOCATION)
INTENSITY
ARTIFICIAL SATELLITES
POLAR CAP
SOLAR CYCLE
ULTRAHIGH FREQUENCY
VERY HIGH FREQUENCY
SYNCHRONOUS SATELLITES
GREENLAND
GEOMAGNETISM
EQUATORIAL REGIONS
ANOMALIES
STATIONS
ASCENSION ISLAND
FREQUENCY
CONTROL
PE62101F
WUAFGL46430903
Greenland
Tromso
Thule
Online Access:http://www.dtic.mil/docs/citations/ADA201770
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA201770
Description
Summary:An extensive VHF/UHF scintillation data base covering the frequency range of VHF to a few gigahertz has been utilized to determine the magnitudes of phase and intensity scintillations and their temporal/spatial structures during the sunspot maximum and minimum periods. The equatorial portion of the study has been based on geostationary satellite observations at Huancayo, a station on the magnetic equator, and at Ascension Island, which is an equatorial anomaly station having an extremely disturbed irregularity environment. The high- latitude part of the study is based on quasi-stationary satellite measurements at a polar cap location (Thule) and two auroral locations (Goose Bay and Tromso) . The Tromso observations are augmented with the Defense Nuclear Agency HiLatsatellite beacon measurements during the solar minimum period. The data indicate a strong solar cycle control of scintillation activity at all locations, resulting in a drastic reduction of the magnitudes and occurrence of scintillations during the current solar minimum period. This pattern is consistent with both a reduction of F region ionization density and a reduction of irregularity generation in the solar minimum period. At the magnetic equator the magnitude of scintillations at 1.5 GHz seldom exceeds 3 dB with the percentage occurrence > 2 dB varying from 70% during high sunspot conditions to 30% during low sunspot conditions. At the crest of the equatorial anomaly, on the other hand, during the solar maximum in 1979, fades of 20 dB at 1.5 GHz are observed 30% of the time. Reprints. Pub. in Radio Science, v23 n3 p363-378 May-Jun 1988.

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