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Autori principali: Price, Michael, Pati, Debdeep, Ning, Ning
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.08735
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author Price, Michael
Pati, Debdeep
Ning, Ning
author_facet Price, Michael
Pati, Debdeep
Ning, Ning
contents Stationary points or derivative zero crossings of a regression function correspond to points where a trend reverses, making their estimation scientifically important. Existing approaches to uncertainty quantification for stationary points cannot deliver valid joint inference when multiple extrema are present, an essential capability in applications where the relative locations of peaks and troughs carry scientific significance. We develop a principled framework for functions with multiple regions of monotonicity by constraining the number of stationary points. We represent each function in the diffeomorphic formulation as the composition of a simple template and a smooth bijective transformation, and show that this parameterization enables coherent joint inference on the extrema. This construction guarantees a prespecified number of stationary points and provides a direct, interpretable parameterization of their locations. We derive non-asymptotic confidence bounds and establish approximate normality for the maximum likelihood estimators, with parallel results in the Bayesian setting. Simulations and an application to brain signal estimation demonstrate the method's accuracy and interpretability.
format Preprint
id arxiv_https___arxiv_org_abs_2512_08735
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stationary Point Constrained Inference via Diffeomorphisms
Price, Michael
Pati, Debdeep
Ning, Ning
Methodology
Stationary points or derivative zero crossings of a regression function correspond to points where a trend reverses, making their estimation scientifically important. Existing approaches to uncertainty quantification for stationary points cannot deliver valid joint inference when multiple extrema are present, an essential capability in applications where the relative locations of peaks and troughs carry scientific significance. We develop a principled framework for functions with multiple regions of monotonicity by constraining the number of stationary points. We represent each function in the diffeomorphic formulation as the composition of a simple template and a smooth bijective transformation, and show that this parameterization enables coherent joint inference on the extrema. This construction guarantees a prespecified number of stationary points and provides a direct, interpretable parameterization of their locations. We derive non-asymptotic confidence bounds and establish approximate normality for the maximum likelihood estimators, with parallel results in the Bayesian setting. Simulations and an application to brain signal estimation demonstrate the method's accuracy and interpretability.
title Stationary Point Constrained Inference via Diffeomorphisms
topic Methodology
url https://arxiv.org/abs/2512.08735