The Atmosphere Explorer-C satellite (AE-C) is uniquely suited for correlative studies with groundbased stations because its on-board propulsion system enables a desired ground station overflight condition to be maintained for a period of several weeks. It also provides the first low-altitude (below 260 km) comparison of satellite and incoherent scatter electron and ion temperatures. More than 40 comparisons of remote and in situ measurements were made by using data from AE-C and four incoherent scatter stations (Arecibo, Chatanika, Millstone Hill, and St. Santin). The results indicate very good agreement between satellite and ground measurements of the ion temperature, the average satellite retarding potential analyzer temperatures differing from the average incoherent scatter temperatures by -2% at St. Santin, +3% at Millstone Hill, and +2% at Arecibo. The electron temperatures also agree well, the average satellite temperatures exceeding the average incoherent scatter temperatures by 3% at St. Santin, 2% at Arecibo, and 11% at Millstone Hill. Several temperature comparisons were made between AE-C and Chatanika. In spite of the highly variable ionosphere often encountered at this high-latitude location, good agreement was obtained between the in situ and remote measurements of electron and ion temperatures. Longitudinal variations are found to be very important in the comparisons of electron temperature in some locations. The agreement between the electron temperatures is considerably better than that found in some earlier comparisons involving satellites at higher altitudes.In some of these instances the ratio of probe temperature (Te)•, to incoherent scatter temperature (Te)s was as high as 1.7-1.9 [Hanson et al., 1969; Carlson and Sayers, 1970]. Others have found smaller discrepancies ((Te)•,/(Te)s -1.15) [McClure et al., 1973] or no significant discrepancy [Evans, 1965; Taylor and Wrenn, 1970; Wrenn et al., 1973]. The diversity of these findings may have been due to the lack of simultaneity of the observations and/or to the spatial separation of the ionospheric samples being examined in the different experiments. Comparisons involving rocket-borne electrostatic probes flown in the vicinity of an incoherent scatter station have not indicated a large discrepancy; i.e., (Te)p/(Te)s was generally less than 1.2 [Brace et al., 1969; Sagalyn and Wand, 1971], but these comparisons were limited to altitudes below 300 km. An indication of an altitude dependence was obtained in a rocket probe-incoherent scatter comparison that extended to 700 km [Brace and McClure, 1971 ]. Below 350 km, (Te)p/(Te)s -• 1.0, whereas at 700 km the ratio had attained a value of 1.8. The results of this experiment, however, may have been influenced by the large separation (nearly 5000 km) in longRude between the rocket trajectory and the incoherent scatter beam. An altitude dependence was also suggested by a related temperature comparison in which simultaneous in situ measurements were made from the same vehicle [Benson, 1973]. In this case...
