Deep learning for the change-point Cox model with current status data.
This study develops estimation methods for a deep partially linear Cox proportional hazards model with a change point under current status data, aiming to accommodate complex change-point effects.
APA
Huang Q, Feng A, et al. (2026). Deep learning for the change-point Cox model with current status data.. Lifetime data analysis, 32(1), 14. https://doi.org/10.1007/s10985-026-09689-y
MLA
Huang Q, et al.. "Deep learning for the change-point Cox model with current status data.." Lifetime data analysis, vol. 32, no. 1, 2026, pp. 14.
PMID
41661381
Abstract
This study develops estimation methods for a deep partially linear Cox proportional hazards model with a change point under current status data, aiming to accommodate complex change-point effects. Prior work has largely relied on linear models, which may inadequately capture relationships among multivariate covariates and thus hinder accurate change-point detection. To address this, we use a deep neural network to model covariate effects within the Cox framework and propose a maximum likelihood estimation procedure for the model. We establish asymptotic properties of the resulting estimators, including consistency, asymptotic independence, and semiparametric efficiency. Simulation studies indicate that the proposed inference procedure performs well in finite samples. An analysis of a breast cancer dataset is provided to illustrate the methodology.
MeSH Terms
Deep Learning; Proportional Hazards Models; Humans; Breast Neoplasms; Likelihood Functions; Female; Computer Simulation
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