Information bounds for inverse problems with application to deconvolution and L\'evy models
Abstract
If a functional in an inverse problem can be estimated with parametric rate, then the minimax rate gives no information about the ill-posedness of the problem. To have a more precise lower bound, we study semiparametric efficiency in the sense of H\'ajek-Le Cam for functional estimation in regular indirect models. These are characterized as models that can be locally approximated by a linear white noise model that is described by the generalized score operator. A convolution theorem for regular indirect models is proved. This applies to a large class of statistical inverse problems, which is illustrated for the prototypical white noise and deconvolution model. It is especially useful for nonlinear models. We discuss in detail a nonlinear model of deconvolution type where a L\'evy process is observed at low frequency, concluding an information bound for the estimation of linear functionals of the jump measure.
Cite
@article{arxiv.1307.6610,
title = {Information bounds for inverse problems with application to deconvolution and L\'evy models},
author = {Mathias Trabs},
journal= {arXiv preprint arXiv:1307.6610},
year = {2014}
}
Comments
To appear in Annales de l'Institut Henri Poincar\'e