Approximate Recovery in Changepoint Problems, from $\ell_2$ Estimation Error Rates
Abstract
In the 1-dimensional multiple changepoint detection problem, we prove that any procedure with a fast enough error rate, in terms of its estimation of the underlying piecewise constant mean vector, automatically has an (approximate) changepoint screening property---specifically, each true jump in the underlying mean vector has an estimated jump nearby. We also show, again assuming only knowledge of the error rate, that a simple post-processing step can be used to eliminate spurious estimated changepoints, and thus delivers an (approximate) changepoint recovery property---specifically, in addition to the screening property described above, we are assured that each estimated jump has a true jump nearby. As a special case, we focus on the application of these results to the 1-dimensional fused lasso, i.e., 1-dimensional total variation denoising, and compare the implications with existing results from the literature. We also study extensions to related problems, such as changepoint detection over graphs.
Keywords
Cite
@article{arxiv.1606.06746,
title = {Approximate Recovery in Changepoint Problems, from $\ell_2$ Estimation Error Rates},
author = {Kevin Lin and James Sharpnack and Alessandro Rinaldo and Ryan J. Tibshirani},
journal= {arXiv preprint arXiv:1606.06746},
year = {2016}
}
Comments
43 pages, 8 figures