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Main Author: Sandqvist, Oliver Lunding
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.17605
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author Sandqvist, Oliver Lunding
author_facet Sandqvist, Oliver Lunding
contents We propose a nonparametric method for dynamic prediction in event history analysis with high-dimensional, time-dependent covariates. The approach estimates future conditional hazards by combining landmarking supermodels with gradient boosted trees. Unlike joint modeling or Cox landmarking models, the proposed estimator flexibly captures interactions and nonlinear effects without imposing restrictive parametric assumptions or requiring the covariate process to be Markovian. We formulate the approach as a sieve M-estimator and establish weak consistency. Computationally, the problem reduces to a Poisson regression, allowing implementation via standard gradient boosting software. A key theoretical advantage is that the method avoids the temporal inconsistencies that arise in landmark Cox models. Simulation studies demonstrate that the method performs well in a variety of settings, and its practical value is illustrated through an analysis of primary biliary cirrhosis data.
format Preprint
id arxiv_https___arxiv_org_abs_2601_17605
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Event history analysis with time-dependent covariates via landmarking supermodels and boosted trees
Sandqvist, Oliver Lunding
Statistics Theory
Methodology
We propose a nonparametric method for dynamic prediction in event history analysis with high-dimensional, time-dependent covariates. The approach estimates future conditional hazards by combining landmarking supermodels with gradient boosted trees. Unlike joint modeling or Cox landmarking models, the proposed estimator flexibly captures interactions and nonlinear effects without imposing restrictive parametric assumptions or requiring the covariate process to be Markovian. We formulate the approach as a sieve M-estimator and establish weak consistency. Computationally, the problem reduces to a Poisson regression, allowing implementation via standard gradient boosting software. A key theoretical advantage is that the method avoids the temporal inconsistencies that arise in landmark Cox models. Simulation studies demonstrate that the method performs well in a variety of settings, and its practical value is illustrated through an analysis of primary biliary cirrhosis data.
title Event history analysis with time-dependent covariates via landmarking supermodels and boosted trees
topic Statistics Theory
Methodology
url https://arxiv.org/abs/2601.17605