Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques

Continued human exploration of the solar system requires the mitigating of radiation effects from the Sun. Doses from Solar Particle Events (SPE) pose a serious threat to the health of astronauts. A method for forecasting the rate and total severity of such events would give time for the astronauts...

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Main Author: Nichols, Theodore Franklin
Format: Others
Published: Trace: Tennessee Research and Creative Exchange 2009
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Online Access:http://trace.tennessee.edu/utk_graddiss/77
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spelling ndltd-UTENN-oai-trace.tennessee.edu-utk_graddiss-11072011-12-13T16:00:23Z Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques Nichols, Theodore Franklin Continued human exploration of the solar system requires the mitigating of radiation effects from the Sun. Doses from Solar Particle Events (SPE) pose a serious threat to the health of astronauts. A method for forecasting the rate and total severity of such events would give time for the astronauts to take actions to mitigate the effects from an SPE. The danger posed from an SPE depends on dose received and the temporal profile of the event. The temporal profile describes how quickly the dose will arrive (dose rate). Previously deployed methods used neural networks to predict the total dose from the event. Later work added the ability to predict the temporal profiles using the neural network approach. Locally weighted regression (LWR) techniques were then investigated for use in forecasting the total dose from an SPE. That work showed that LWR methods could forecast the total dose from an event. This previous research did not calculate the uncertainty in a forecast. The present research expands the LWR model to forecast dose and temporal profile from an SPE along with the uncertainty in these forecasts. Forecasts made with LWR method are able to make forecasts at a time early in an event with results that can be beneficial to operators and crews. The forecasts in this work are all made at or before five hours after the start of the SPE. For 58 percent of the events tested, the dose-rate profile is within the uncertainty bounds. Restricting the data set to only events less than 145 cGy, 86 percent of the events are within the uncertainty bounds. The uncertainty in the forecasts are large, however the forecasts are being made early enough into an SPE that very little of the dose will have reached the crew. Increasing the number of SPEs in the data set increases the accuracy of the forecasts and reduces the uncertainty in the forecasts. 2009-08-01 text application/pdf http://trace.tennessee.edu/utk_graddiss/77 Doctoral Dissertations Trace: Tennessee Research and Creative Exchange Nuclear Engineering
collection NDLTD
format Others
sources NDLTD
topic Nuclear Engineering
spellingShingle Nuclear Engineering
Nichols, Theodore Franklin
Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques
description Continued human exploration of the solar system requires the mitigating of radiation effects from the Sun. Doses from Solar Particle Events (SPE) pose a serious threat to the health of astronauts. A method for forecasting the rate and total severity of such events would give time for the astronauts to take actions to mitigate the effects from an SPE. The danger posed from an SPE depends on dose received and the temporal profile of the event. The temporal profile describes how quickly the dose will arrive (dose rate). Previously deployed methods used neural networks to predict the total dose from the event. Later work added the ability to predict the temporal profiles using the neural network approach. Locally weighted regression (LWR) techniques were then investigated for use in forecasting the total dose from an SPE. That work showed that LWR methods could forecast the total dose from an event. This previous research did not calculate the uncertainty in a forecast. The present research expands the LWR model to forecast dose and temporal profile from an SPE along with the uncertainty in these forecasts. Forecasts made with LWR method are able to make forecasts at a time early in an event with results that can be beneficial to operators and crews. The forecasts in this work are all made at or before five hours after the start of the SPE. For 58 percent of the events tested, the dose-rate profile is within the uncertainty bounds. Restricting the data set to only events less than 145 cGy, 86 percent of the events are within the uncertainty bounds. The uncertainty in the forecasts are large, however the forecasts are being made early enough into an SPE that very little of the dose will have reached the crew. Increasing the number of SPEs in the data set increases the accuracy of the forecasts and reduces the uncertainty in the forecasts.
author Nichols, Theodore Franklin
author_facet Nichols, Theodore Franklin
author_sort Nichols, Theodore Franklin
title Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques
title_short Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques
title_full Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques
title_fullStr Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques
title_full_unstemmed Forcasting Dose and Dose Rate from Solar Particle Ecents Using Locally Weighted Regression Techniques
title_sort forcasting dose and dose rate from solar particle ecents using locally weighted regression techniques
publisher Trace: Tennessee Research and Creative Exchange
publishDate 2009
url http://trace.tennessee.edu/utk_graddiss/77
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