Computation of Potential Attenuation Process for Charged Human Body Using Numerical Inverse Laplace Transform
Summary :
The potential attenuation process of charged human body (HB) is analyzed. A two-dimensional circuit model is presented for predicting the potential attenuation characteristics of the HB charged on the floor. The theoretical equation for the HB potential is derived in the closed form in the Laplacian transformation domain, and the numerical inverse Laplace transform is used to compute it. The half-life or relaxation time of the HB potential for decay is numerically examined with respect to the electrical parameters of shoes. The experiment is also conducted for verifying the validity of the computed result.
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- IEICE TRANSACTIONS on Communications Vol.E78-B No.2 pp.188-192
- Publication Date
- 1995/02/25
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- Special Section PAPER (Special Issue on Electromagnetic Compatibility)
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Osamu FUJIWARA, Hironori ENDOH, "Computation of Potential Attenuation Process for Charged Human Body Using Numerical Inverse Laplace Transform" in IEICE TRANSACTIONS on Communications,
vol. E78-B, no. 2, pp. 188-192, February 1995, doi: .
Abstract: The potential attenuation process of charged human body (HB) is analyzed. A two-dimensional circuit model is presented for predicting the potential attenuation characteristics of the HB charged on the floor. The theoretical equation for the HB potential is derived in the closed form in the Laplacian transformation domain, and the numerical inverse Laplace transform is used to compute it. The half-life or relaxation time of the HB potential for decay is numerically examined with respect to the electrical parameters of shoes. The experiment is also conducted for verifying the validity of the computed result.
URL: https://global.ieice.org/en_transactions/communications/10.1587/e78-b_2_188/_p
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@ARTICLE{e78-b_2_188,
author={Osamu FUJIWARA, Hironori ENDOH, },
journal={IEICE TRANSACTIONS on Communications},
title={Computation of Potential Attenuation Process for Charged Human Body Using Numerical Inverse Laplace Transform},
year={1995},
volume={E78-B},
number={2},
pages={188-192},
abstract={The potential attenuation process of charged human body (HB) is analyzed. A two-dimensional circuit model is presented for predicting the potential attenuation characteristics of the HB charged on the floor. The theoretical equation for the HB potential is derived in the closed form in the Laplacian transformation domain, and the numerical inverse Laplace transform is used to compute it. The half-life or relaxation time of the HB potential for decay is numerically examined with respect to the electrical parameters of shoes. The experiment is also conducted for verifying the validity of the computed result.},
keywords={},
doi={},
ISSN={},
month={February},}
Copy
TY - JOUR
TI - Computation of Potential Attenuation Process for Charged Human Body Using Numerical Inverse Laplace Transform
T2 - IEICE TRANSACTIONS on Communications
SP - 188
EP - 192
AU - Osamu FUJIWARA
AU - Hironori ENDOH
PY - 1995
DO -
JO - IEICE TRANSACTIONS on Communications
SN -
VL - E78-B
IS - 2
JA - IEICE TRANSACTIONS on Communications
Y1 - February 1995
AB - The potential attenuation process of charged human body (HB) is analyzed. A two-dimensional circuit model is presented for predicting the potential attenuation characteristics of the HB charged on the floor. The theoretical equation for the HB potential is derived in the closed form in the Laplacian transformation domain, and the numerical inverse Laplace transform is used to compute it. The half-life or relaxation time of the HB potential for decay is numerically examined with respect to the electrical parameters of shoes. The experiment is also conducted for verifying the validity of the computed result.
ER -
English
