English

A Geometric Approach for Computing Tolerance Bounds for Elastic Functional Data

Computation 2019-07-24 v2

Abstract

We develop a method for constructing tolerance bounds for functional data with random warping variability. In particular, we define a generative, probabilistic model for the amplitude and phase components of such observations, which parsimoniously characterizes variability in the baseline data. Based on the proposed model, we define two different types of tolerance bounds that are able to measure both types of variability, and as a result, identify when the data has gone beyond the bounds of amplitude and/or phase. The first functional tolerance bounds are computed via a bootstrap procedure on the geometric space of amplitude and phase functions. The second functional tolerance bounds utilize functional Principal Component Analysis to construct a tolerance factor. This work is motivated by two main applications: process control and disease monitoring. The problem of statistical analysis and modeling of functional data in process control is important in determining when a production has moved beyond a baseline. Similarly, in biomedical applications, doctors use long, approximately periodic signals (such as the electrocardiogram) to diagnose and monitor diseases. In this context, it is desirable to identify abnormalities in these signals. We additionally consider a simulated example to assess our approach and compare it to two existing methods.

Keywords

Cite

@article{arxiv.1805.11401,
  title  = {A Geometric Approach for Computing Tolerance Bounds for Elastic Functional Data},
  author = {J. Derek Tucker and John R. Lewis and Caleb King and Sebastian Kurtek},
  journal= {arXiv preprint arXiv:1805.11401},
  year   = {2019}
}

Comments

25 pages

R2 v1 2026-06-23T02:11:48.222Z