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Quantifying the average and the likelihood of increases in space weather indices and in situ measurements during Solar Cycles 20-23

Lohmeyer W. Q., A. Pang, K. Cahoy, Y. Shprits., (2013), Quantifying the average and the likelihood of increases in space weather indices and in situ measurements during Solar Cycles 20-23, Int. J. Of Space Science And Engineering, 1, 230-252, doi:10.1504/IJSPACESE.2013.058856

Abstract

It is known that space weather harshly affects spacecraft performance, yet spacecraft operations and understanding the cause of anomalies can be challenging due to the complexity of environmental metrics. In this work, we analyse five metrics and in-situ measurements (Kp, Dst, and AE index, and high-energy proton and electron flux) throughout Solar Cycles 20-23 (1964 to 2008), and provide a baseline for the environment during the phases of the solar cycles (maximum, minimum, declining or ascending). We define increased activity as activity greater than two median absolute deviations (MADs) above the average activity for each phase. MAD is used, rather than standard deviation, because it is more resilient to outliers. The average and MAD values are tabulated in Table 3 to Table 6. We determine the probability that increased activity occurs 3, 14 or 30 days before a random day to distinguish between increased/quiet activities and to aid in correlating intensifications of the environment and anomalous satellite performance.

Authors (sorted by name)

Shprits

Journal / Conference

Int. J. Of Space Science And Engineering

Bibtex

@article{article,
author = {Whitney Q. Lohmeyer and Anthony Pang and Kerri Cahoy and Yuri Shprits.},
title = {Quantifying the average and the likelihood of increases in space weather indices and in situ measurements during Solar Cycles 20-23},
journal = { Int. J. of Space Science and Engineering},
year ={2013},
volume = {1},
number = {3},
pages = {230-252},
doi = {10.1504/IJSPACESE.2013.058856},
abstract = { It is known that space weather harshly affects spacecraft performance, yet spacecraft operations and understanding the cause of anomalies can be challenging due to the complexity of environmental metrics. In this work, we analyse five metrics and in-situ measurements (Kp, Dst, and AE index, and high-energy proton and electron flux) throughout Solar Cycles 20-23 (1964 to 2008), and provide a baseline for the environment during the phases of the solar cycles (maximum, minimum, declining or ascending). We define increased activity as activity greater than two median absolute deviations (MADs) above the average activity for each phase. MAD is used, rather than standard deviation, because it is more resilient to outliers. The average and MAD values are tabulated in Table 3 to Table 6. We determine the probability that increased activity occurs 3, 14 or 30 days before a random day to distinguish between increased/quiet activities and to aid in correlating intensifications of the environment and anomalous satellite performance.}
}