TY - GEN
T1 - THE BROWNIAN BASED APPROACH APPLIED TO A LIMITED SAMPLE SIZE FOR BALLISTIC RESISTANCE EVALUATION
T2 - 32nd International Symposium on Ballistics, BALLISTICS 2022
AU - Tahenti, Beya
AU - Coghe, Frederik
AU - Nasri, Rachid
AU - Lauwens, Ben
AU - Pirlot, Marc
N1 - Publisher Copyright:
© Proceedings - 32nd International Symposium on Ballistics, BALLISTICS 2022. All rights reserved.
PY - 2022
Y1 - 2022
N2 - The field of penetration mechanics covers studies related to materials behavior under impact loading. Usually, the assessment of the ballistic resistance makes use of the V50, the bullet impact velocity with 50 percent probability of perforation of the tested target. However, the estimation of the entire curve of the perforation probability is frequently solicited. Recently, a stochastic model based on the Brownian motion concept has been proposed for that goal. The bullet motion within the target was represented as a stochastic differential equation using the bullet deceleration and a diffusion coefficient. In this paper, the maximum likelihood inference is developed for the estimation of the model parameters. This inference is applied to the complete database (581 observations) and a sample of 20 observations. In both cases, the perforation probability curve is consistent with the confidence intervals on the experimental estimations. The obtained results show that the likelihood inference extends the application of this approach to experimental samples with limited size. In addition, the proposed inference technic is applied to a second experimental database of ballistic impacts to validate the applicability of the proposed modelling methodology using the likelihood inference to various impact cases.
AB - The field of penetration mechanics covers studies related to materials behavior under impact loading. Usually, the assessment of the ballistic resistance makes use of the V50, the bullet impact velocity with 50 percent probability of perforation of the tested target. However, the estimation of the entire curve of the perforation probability is frequently solicited. Recently, a stochastic model based on the Brownian motion concept has been proposed for that goal. The bullet motion within the target was represented as a stochastic differential equation using the bullet deceleration and a diffusion coefficient. In this paper, the maximum likelihood inference is developed for the estimation of the model parameters. This inference is applied to the complete database (581 observations) and a sample of 20 observations. In both cases, the perforation probability curve is consistent with the confidence intervals on the experimental estimations. The obtained results show that the likelihood inference extends the application of this approach to experimental samples with limited size. In addition, the proposed inference technic is applied to a second experimental database of ballistic impacts to validate the applicability of the proposed modelling methodology using the likelihood inference to various impact cases.
UR - http://www.scopus.com/inward/record.url?scp=85179001040&partnerID=8YFLogxK
M3 - Conference contribution
T3 - Proceedings - 32nd International Symposium on Ballistics, BALLISTICS 2022
SP - 1596
EP - 1604
BT - Exterior Ballistics, Terminal Ballistics
A2 - Manning, Thelma G.
A2 - Rickert, Frederick C.
PB - DEStech Publications
Y2 - 9 May 2022 through 13 May 2022
ER -