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Hauptverfasser: Smith, D. Hudson, Nisbet, Noah, Ehrett, Carl, Tica, Cristina I., Atwell, Madeline M., Weisensee, Katherine E.
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2411.09802
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author Smith, D. Hudson
Nisbet, Noah
Ehrett, Carl
Tica, Cristina I.
Atwell, Madeline M.
Weisensee, Katherine E.
author_facet Smith, D. Hudson
Nisbet, Noah
Ehrett, Carl
Tica, Cristina I.
Atwell, Madeline M.
Weisensee, Katherine E.
contents Environmental and individualistic variables affect the rate of human decomposition in complex ways. These effects complicate the estimation of the postmortem interval (PMI) based on observed decomposition characteristics. In this work, we develop a generative probabilistic model for decomposing human remains based on PMI and a wide range of environmental and individualistic variables. This model explicitly represents the effect of each variable, including PMI, on the appearance of each decomposition characteristic, allowing for direct interpretation of model effects and enabling the use of the model for PMI inference and optimal experimental design. In addition, the probabilistic nature of the model allows for the integration of expert knowledge in the form of prior distributions. We fit this model to a diverse set of 2,529 cases from the GeoFOR dataset. We demonstrate that the model accurately predicts 24 decomposition characteristics with an ROC AUC score of 0.85. Using Bayesian inference techniques, we invert the decomposition model to predict PMI as a function of the observed decomposition characteristics and environmental and individualistic variables, producing an R-squared measure of 71%. Finally, we demonstrate how to use the fitted model to design future experiments that maximize the expected amount of new information about the mechanisms of decomposition using the Expected Information Gain formalism.
format Preprint
id arxiv_https___arxiv_org_abs_2411_09802
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Modeling human decomposition: a Bayesian approach
Smith, D. Hudson
Nisbet, Noah
Ehrett, Carl
Tica, Cristina I.
Atwell, Madeline M.
Weisensee, Katherine E.
Machine Learning
Environmental and individualistic variables affect the rate of human decomposition in complex ways. These effects complicate the estimation of the postmortem interval (PMI) based on observed decomposition characteristics. In this work, we develop a generative probabilistic model for decomposing human remains based on PMI and a wide range of environmental and individualistic variables. This model explicitly represents the effect of each variable, including PMI, on the appearance of each decomposition characteristic, allowing for direct interpretation of model effects and enabling the use of the model for PMI inference and optimal experimental design. In addition, the probabilistic nature of the model allows for the integration of expert knowledge in the form of prior distributions. We fit this model to a diverse set of 2,529 cases from the GeoFOR dataset. We demonstrate that the model accurately predicts 24 decomposition characteristics with an ROC AUC score of 0.85. Using Bayesian inference techniques, we invert the decomposition model to predict PMI as a function of the observed decomposition characteristics and environmental and individualistic variables, producing an R-squared measure of 71%. Finally, we demonstrate how to use the fitted model to design future experiments that maximize the expected amount of new information about the mechanisms of decomposition using the Expected Information Gain formalism.
title Modeling human decomposition: a Bayesian approach
topic Machine Learning
url https://arxiv.org/abs/2411.09802