Nonparametric operator-regularized covariance function estimation for functional data

Wong, Raymond K. W.; Zhang, Xiaoke

doi:10.1016/j.csda.2018.05.013

Cited by 12 publications

(22 citation statements)

References 31 publications

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“…The rate of convergence of the kernel smoother of Yao et al [37] was later strengthened by Hall et al [11] and Li and Hsing [22]. Other methods to deal with sparsely observed functional data make use of minimizing a specific convex criterion function and expressing the estimator within a reproducing kernel Hilbert space, see Cai and Yuan [6], and Wong and Zhang [35]).…”

Section: Introductionmentioning

confidence: 99%

Sparsely observed functional time series: estimation and prediction

Rubín¹,

Panaretos²

2020

Electron. J. Statist.

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Functional time series analysis, whether based on time of frequency domain methodology, has traditionally been carried out under the assumption of complete observation of the constituent series of curves, assumed stationary. Nevertheless, as is often the case with independent functional data, it may well happen that the data available to the analyst are not the actual sequence of curves, but relatively few and noisy measurements per curve, potentially at different locations in each curve's domain. Under this sparse sampling regime, neither the established estimators of the time series' dynamics, nor their corresponding theoretical analysis will apply. The subject of this paper is to tackle the problem of estimating the dynamics and of recovering the latent process of smooth curves in the sparse regime. Assuming smoothness of the latent curves, we construct a consistent nonparametric estimator of the series' spectral density operator and use it develop a frequency-domain recovery approach, that predicts the latent curve at a given time by borrowing strength from the (estimated) dynamic correlations in the series across time. Further to predicting the latent curves from their noisy point samples, the method fills in gaps in the sequence (curves nowhere sampled), denoises the data, and serves as a basis for forecasting. Means of providing corresponding confidence bands are also investigated. A simulation study interestingly suggests that sparse observation for a longer time period, may be provide better performance than dense observation for a shorter period, in the presence of smoothness. The methodology is further illustrated by application to an environmental data set on fair-weather atmospheric electricity, which naturally leads to a sparse functional time-series.

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Section: Introductionmentioning

confidence: 99%

Sparsely observed functional time series: estimation and prediction

Rubín¹,

Panaretos²

2020

Electron. J. Statist.

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“…Various nonparametric methods have now been proposed to estimate the smooth covariance function, for example, Peng and Paul (), Cai and Yuan (), Goldsmith et al. (), Xiao, Li, Checkley, and Crainiceanu (), and Wong and Zhang ().…”

Section: Introductionmentioning

confidence: 99%

Fast covariance estimation for multivariate sparse functional data

Xiao

Luo

2020

Stat

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Covariance estimation is essential yet underdeveloped for analysing multivariate functional data. We propose a fast covariance estimation method for multivariate sparse functional data using bivariate penalized splines. The tensor‐product B‐spline formulation of the proposed method enables a simple spectral decomposition of the associated covariance operator and explicit expressions of the resulting eigenfunctions as linear combinations of B‐spline bases, thereby dramatically facilitating subsequent principal component analysis. We derive a fast algorithm for selecting the smoothing parameters in covariance smoothing using leave‐one‐subject‐out cross‐validation. The method is evaluated with extensive numerical studies and applied to an Alzheimer's disease study with multiple longitudinal outcomes.

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“…Probabilistic features of and estimators for lag-h-covariance operators C X;h of stationary processes X = (X k ) k∈Z with values in L 2 [0, 1], the space of measurable, square-Lebesgue integrable real valued functions with domain [0, 1], are widely studied for fixed lag h, see, e. g., [5], [19], [22], [34], [27]. Further, [39] developed covariance estimators in the space of continuous functions C[0, 1], [48] in tensor product Sobolev-Hilbert spaces, [33] for continuous surfaces, and [18], [1] for arbitrary separable Hilbert spaces. [34], [39], [18], [1] constrained their assertions to autoregressive (AR) processes, where [1] deduced the results for a random AR(1) operator.…”

Section: State Of the Artmentioning

confidence: 99%

“…[34], [39], [18], [1] constrained their assertions to autoregressive (AR) processes, where [1] deduced the results for a random AR(1) operator. Thereby, [5], [19], [22], [1] utilized classical moment estimators, [27] estimated the integral kernels, in [18], [34] truncated spectral decompositions occured having estimated principle components, and [48] used operator regularized covariance estimators. Also, the limit distribution of the estimation errors of the lag-0-covariance operators was discussed in [26], [28].…”

Section: State Of the Artmentioning

confidence: 99%

Lagged Covariance and Cross-Covariance Operators of Processes in Cartesian Products of Abstract Hilbert Spaces

Kühnert¹

2021

Preprint

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A major task in Functional Time Series Analysis is measuring the dependence within and between processes, for which lagged covariance and cross-covariance operators have proven to be a practical tool in well-established spaces. This article deduces estimators and asymptotic upper bounds of the estimation errors for lagged covariance and cross-covariance operators of processes in Cartesian products of abstract Hilbert spaces for fixed and increasing lag and Cartesian powers. We allow the processes to be non-centered, and to have values in different spaces when investigating the dependence between processes. Also, we discuss features of estimators for the principle components of our covariance operators.

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Nonparametric operator-regularized covariance function estimation for functional data

Cited by 12 publications

References 31 publications

Sparsely observed functional time series: estimation and prediction

Sparsely observed functional time series: estimation and prediction

Fast covariance estimation for multivariate sparse functional data

Lagged Covariance and Cross-Covariance Operators of Processes in Cartesian Products of Abstract Hilbert Spaces

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