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Bibliographic Details
Main Authors: Wang, Hongyun, Foley, Shannon E., Zhou, Hong
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.11947
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author Wang, Hongyun
Foley, Shannon E.
Zhou, Hong
author_facet Wang, Hongyun
Foley, Shannon E.
Zhou, Hong
contents We assess the skin thermal injury risk in the situation where a test subject is exposed to an electromagnetic beam until the occurrence of flight action. The physical process is modeled as follows. The absorbed electromagnetic power increases the skin temperature. Wherever it is above a temperature threshold, thermal nociceptors are activated and transduce an electrical signal. When the activated skin volume reaches a threshold, the flight signal is initiated. After the delay of human reaction time, the flight action is materialized when the subject moves away or the beam power is turned off. The injury risk is quantified by the thermal damage parameter calculated in the Arrhenius equation. It depends on the beam power density absorbed into the skin, which is not measurable. In addition, the volume threshold for flight initiation is unknown. To circumference these difficulties, we normalize the formulation and write the thermal damage parameter in terms of the occurrence time of flight action, which is reliably observed in exposure tests. This thermal injury formulation provides a viable framework for investigating the effects of model parameters.
format Preprint
id arxiv_https___arxiv_org_abs_2408_11947
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Assessing skin thermal injury risk in exposure tests of heating until flight
Wang, Hongyun
Foley, Shannon E.
Zhou, Hong
Computational Engineering, Finance, and Science
We assess the skin thermal injury risk in the situation where a test subject is exposed to an electromagnetic beam until the occurrence of flight action. The physical process is modeled as follows. The absorbed electromagnetic power increases the skin temperature. Wherever it is above a temperature threshold, thermal nociceptors are activated and transduce an electrical signal. When the activated skin volume reaches a threshold, the flight signal is initiated. After the delay of human reaction time, the flight action is materialized when the subject moves away or the beam power is turned off. The injury risk is quantified by the thermal damage parameter calculated in the Arrhenius equation. It depends on the beam power density absorbed into the skin, which is not measurable. In addition, the volume threshold for flight initiation is unknown. To circumference these difficulties, we normalize the formulation and write the thermal damage parameter in terms of the occurrence time of flight action, which is reliably observed in exposure tests. This thermal injury formulation provides a viable framework for investigating the effects of model parameters.
title Assessing skin thermal injury risk in exposure tests of heating until flight
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2408.11947