This research investigated injury risk functions (IRF) for the THOR-AV 50th
percentile male dummy in accordance with ISO TS18506, focusing on areas with
design changes. The IRF development utilized a combination of physical tests and
finite element (FE) model simulations. For certain postmortem human subject test
cases lacking physical dummy tests, the validated Humanetics THOR-AV FE model
(v0.7.2) was used to quickly generate data, with the understanding that final
IRFs based on full physical test data might offer greater accuracy.
Log-logistic, log-normal, and Weibull survival functions were fitted with 95%
confidence intervals. The Akaike Information Criterion, Goodman-Kruskal-Gamma,
Area under the Curve of Receiver Operating Characteristic, and Quantile-Quantile
plot were employed to assess the prediction strength and relative quality of the
final IRF selections. Among the three survival distributions, the Weibull
distribution provided the best fit. The lumbar Fz was identified as the best
indicator for lumbar spine injury, followed by Lij. The Fz injury risk values at
5%, 25%, and 50% probabilities are 2170N, 3560N, and 4856N for MAIS2+,
respectively. The Lij injury risk values at 5%, 25%, and 50% probabilities are
0.44, 0.65, and 0.79 for MAIS2+, respectively. Abdomen pressure from APTS
sensors was found to be a weak indicator for abdomen injury prediction, with
injury risk values at 5%, 25%, and 50% probabilities being 128, 209, and 268 kPa
for MAIS2+, respectively. The total ASIS force from the left and right ASIS load
cells was a better injury predictor than the maximum ASIS load from the
individual load cells, with injury risk values at 5%, 25%, and 50% probabilities
being 542, 1872, and 3522 Newtons for MAIS2+, respectively.