Gradient-based Explanations for Deep Learning Survival Models
Abstract
Deep learning survival models often outperform classical methods in time-to-event predictions, particularly in personalized medicine, but their "black box" nature hinders broader adoption. We propose a framework for gradient-based explanation methods tailored to survival neural networks, extending their use beyond regression and classification. We analyze the implications of their theoretical assumptions for time-dependent explanations in the survival setting and propose effective visualizations incorporating the temporal dimension. Experiments on synthetic data show that gradient-based methods capture the magnitude and direction of local and global feature effects, including time dependencies. We introduce GradSHAP(t), a gradient-based counterpart to SurvSHAP(t), which outperforms SurvSHAP(t) and SurvLIME in a computational speed vs. accuracy trade-off. Finally, we apply these methods to medical data with multi-modal inputs, revealing relevant tabular features and visual patterns, as well as their temporal dynamics.
Cite
@article{arxiv.2502.04970,
title = {Gradient-based Explanations for Deep Learning Survival Models},
author = {Sophie Hanna Langbein and Niklas Koenen and Marvin N. Wright},
journal= {arXiv preprint arXiv:2502.04970},
year = {2025}
}