Regression with genuinely functional errors-in-covariates

TL;DR

This paper introduces a new estimator for functional linear regression models that accounts for complex stochastic process measurement errors, improving inference accuracy over traditional methods.

Contribution

It proposes a novel estimator based on matrix completion techniques that handles general stochastic process errors in functional covariates, extending existing models.

Findings

Estimator outperforms spectral truncation methods in simulations

Significantly reduces bias caused by measurement errors

Demonstrated effectiveness on gait cycle data

Abstract

Contamination of covariates by measurement error is a classical problem in multivariate regression, where it is well known that failing to account for this contamination can result in substantial bias in the parameter estimators. The nature and degree of this effect on statistical inference is also understood to crucially depend on the specific distributional properties of the measurement error in question. When dealing with functional covariates, measurement error has thus far been modelled as additive white noise over the observation grid. Such a setting implicitly assumes that the error arises purely at the discrete sampling stage, otherwise the model can only be viewed in a weak (stochastic differential equation) sense, white noise not being a second-order process. Departing from this simple distributional setting can have serious consequences for inference, similar to the multivariate case, and current methodology will break down. In this paper, we consider the case when the additive measurement error is allowed to be a valid stochastic process. We propose a novel estimator of the slope parameter in a functional linear model, for scalar as well as functional responses, in the presence of this general measurement error specification. The proposed estimator is inspired by the multivariate regression calibration approach, but hinges on recent advances on matrix completion methods for functional data in order to handle the nontrivial (and unknown) error covariance structure. The asymptotic properties of the proposed estimators are derived. We probe the performance of the proposed estimator of slope using simulations and observe that it substantially improves upon the spectral truncation estimator based on the erroneous observations, i.e., ignoring measurement error. We also investigate the behaviour of the estimators on a real dataset on hip and knee angle curves during a gait cycle.