Functional Data Analysis
A number of projects evolving from data in functional space.
Updated on September 08, 2022 by Surajit Ray
Random Functions Curve Clustering Mixture model Spectral Clustering
7 min READ
Functional data analysis is a growing field of research and has been employed in a wide range of applications ranging from genetics in biology to stock markets in economics. A crucial but challenging problem is clustering of functional data. In this thesis, we review the main contributions in this field and discuss the strengthens and weaknesses of the different clustering functional data approaches. We propose a new framework for clustering functional data and a new paradigm for model selection that is specifically designed for functional data, which are designed to address many of the weaknesses of existing techniques.
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Abstract
This paper focuses on the analysis of spatially correlated functional data. We propose a parametric model for spatial correlation and the between-curve correlation is modeled by correlating functional principal component scores of the functional data. Additionally, in the sparse observation framework, we propose a novel approach of spatial principal analysis by conditional expectation to explicitly estimate spatial correlations and reconstruct individual curves. Assuming spatial stationarity, empirical spatial correlations are calculated as the ratio of eigenvalues of the smoothed covariance surface Cov(Xi(s) , Xi(t)) and cross-covariance surface Cov(Xi(s) , Xj(t)) at locations indexed by i and j. Then a anisotropy Matrn spatial correlation model is fitted to empirical correlations. Finally, principal component scores are estimated to reconstruct the sparsely observed curves. This framework can naturally accommodate arbitrary covariance structures, but there is an enormous reduction in computation if one can assume the separability of temporal and spatial components. We demonstrate the consistency of our estimates and propose hypothesis tests to examine the separability as well as the isotropy effect of spatial correlation. Using simulation studies, we show that these methods have some clear advantages over existing methods of curve reconstruction and estimation of model parameters. 2016, The Author(s).
Abstract
We present a new approach to factor rotation for functional data. This is achieved by rotating the functional principal components toward a predefined space of periodic functions designed to decompose the total variation into components that are nearly-periodic and nearly-aperiodic with a predefined period. We show that the factor rotation can be obtained by calculation of canonical correlations between appropriate spaces which make the methodology computationally efficient. Moreover, we demonstrate that our proposed rotations provide stable and interpretable results in the presence of highly complex covariance. This work is motivated by the goal of finding interpretable sources of variability in gridded time series of vegetation index measurements obtained from remote sensing, and we demonstrate our methodology through an application of factor rotation of this data. Institute of Mathematical Statistics, 2012.