Abstract
The regression problem involving functional predictors has many important applications and a number of functional regression methods have been developed. However, a common complication in functional data analysis is one of sparsely observed curves, that is predictors that are observed, with error, on a small subset of the possible time points. Such sparsely observed data induce an errors-in-variables model, where one must account for measurement error in the functional predictors. Faced with sparsely observed data, most current functional regression methods simply estimate the unobserved predictors and treat them as fully observed; thus failing to account for the extra uncertainty from the measurement error. We propose a new functional errors-in-variables approach, sparse index model functional estimation (SIMFE), which uses a functional index model formulation to deal with sparsely observed predictors. SIMFE has several advantages over more traditional methods. First, the index model implements a nonlinear regression and uses an accurate supervised method to estimate the lower dimensional space into which the predictors should be projected. Second, SIMFE can be applied to both scalar and functional responses and multiple predictors. Finally, SIMFE uses a mixed effects model to effectively deal with very sparsely observed functional predictors and to correctly model the measurement error. Supplementary materials for this article are available online.
Highlights
In a Functional Data Analysis (FDA) setting the regression problem involving one or more functional predictors, X1(t), . . . , Xp(t), and either a functional or scalar response, has re-cently received a great deal of attention
Given a scalar response Yi and a functional predictor Xi(t), the standard classical functional regression model is of the form
We propose a new errors-in-variables approach (Carroll et al, 2006), named Sparse Index Model Functional Estimation (SIMFE), which implements an index model, but offers advantages over the previously discussed approaches
Summary
In a Functional Data Analysis (FDA) setting the regression problem involving one or more functional predictors, X1(t), . . . , Xp(t), and either a functional or scalar response, has re-cently received a great deal of attention. In a Functional Data Analysis (FDA) setting the regression problem involving one or more functional predictors, X1(t), . Xp(t), and either a functional or scalar response, has re-. For examples of recent research on multivariate functional data see Hall et al (2006), Li and Hsing (2010), Li and Chiou (2011), Chiou and Muller (2014) and the references therein. Given a scalar response Yi and a functional predictor Xi(t), the standard classical functional regression model is of the form. Most approaches use an unsupervised method, such as functional principal components analysis, to represent the predictors and regress Y against the lower dimensional representation of X(t)
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