LARES Satellite Thermal Forces and a Test of General Relativity
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2016-09-22
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R. Matzner et al., "LARES satellite thermal forces and a test of general relativity," 2016 IEEE Metrology for Aerospace (MetroAeroSpace), Florence, 2016, pp. 516-521, doi: 10.1109/MetroAeroSpace.2016.7573269.
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©2016 IEEE
©2016 IEEE
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Abstract
We summarize a laser-ranged satellite test of frame dragging, a prediction of General Relativity, and then concentrate on the estimate of thermal thrust, an important perturbation affecting the accuracy of the test. The frame dragging study analysed 3.5 years of data from the LARES satellite and a longer period of time for the two LAGEOS satellites. Using the gravity field GGM05S obtained via the Grace mission, which measures the Earth's gravitational field, the prediction of General Relativity is confirmed with a 1-σ formal error of 0.002, and a systematic error of 0.05. The result for the value of the frame dragging around the Earth is μ = 0.994, compared to μ = 1 predicted by General Relativity. The thermal force model assumes heat flow from the sun (visual) and from Earth (IR) to the satellite core and to the fused silica reflectors on the satellite, and reradiation into space. For a roughly current epoch (days 1460 - 1580 after launch) we calculate an average along track drag of -0.50pm/sec 2