A Two-Sample Distribution-Free Test for Functional Data with Application to a Diffusion Tensor Imaging Study of Multiple Sclerosis

Pomann, Gina‐Maria; Staicu, Ana‐Maria; Ghosh, Sujit K.

doi:10.1111/rssc.12130

Cited by 49 publications

(70 citation statements)

References 50 publications

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“…Finally, we investigated whether the way the activity varies (the population distributions) is the same in Normal cats and DJD cats; for this we used the functional Anderson-Darling testing procedure of Pomann et al [55]. We found significant evidence against this null hypothesis for both weekends (p = 0.013) and weekdays (p = 0.010).…”

Section: Resultsmentioning

confidence: 90%

“…Null distributions were based on N = 10,000 simulations. Further, we formally assessed whether the population distributions of activity and intensity profiles for the two groups of DJD cats were the same using the Anderson-Darling testing procedure proposed by Pomann et al [55]. Results are discussed in the results section; they were supportive of separating weekend and weekday activity and pooling data from the two groups of cats with DJD into one DJD group.…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

The Use of Functional Data Analysis to Evaluate Activity in a Spontaneous Model of Degenerative Joint Disease Associated Pain in Cats

et al. 2017

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Introduction and objectivesAccelerometry is used as an objective measure of physical activity in humans and veterinary species. In cats, one important use of accelerometry is in the study of therapeutics designed to treat degenerative joint disease (DJD) associated pain, where it serves as the most widely applied objective outcome measure. These analyses have commonly used summary measures, calculating the mean activity per-minute over days and comparing between treatment periods. While this technique has been effective, information about the pattern of activity in cats is lost. In this study, functional data analysis was applied to activity data from client-owned cats with (n = 83) and without (n = 15) DJD. Functional data analysis retains information about the pattern of activity over the 24-hour day, providing insight into activity over time. We hypothesized that 1) cats without DJD would have higher activity counts and intensity of activity than cats with DJD; 2) that activity counts and intensity of activity in cats with DJD would be inversely correlated with total radiographic DJD burden and total orthopedic pain score; and 3) that activity counts and intensity would have a different pattern on weekends versus weekdays.Results and conclusionsResults showed marked inter-cat variability in activity. Cats exhibited a bimodal pattern of activity with a sharp peak in the morning and broader peak in the evening. Results further showed that this pattern was different on weekends than weekdays, with the morning peak being shifted to the right (later). Cats with DJD showed different patterns of activity from cats without DJD, though activity and intensity were not always lower; instead both the peaks and troughs of activity were less extreme than those of the cats without DJD. Functional data analysis provides insight into the pattern of activity in cats, and an alternative method for analyzing accelerometry data that incorporates fluctuations in activity across the day.

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Section: Resultsmentioning

confidence: 90%

Section: Methodsmentioning

confidence: 99%

The Use of Functional Data Analysis to Evaluate Activity in a Spontaneous Model of Degenerative Joint Disease Associated Pain in Cats

et al. 2017

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“…This choice of orthogonal basis also allows us to formulate the mean model for the conditional response profile, given scalar/vector covariates, based on mean models for the conditional FPC scores given the covariates:

normalE false[Y_{i} false(t false) false| X_{i} false(\cdot false) false] = true \sum_{k = 1}^{K} ϕ_{k} false(t false) normalE false[ξ_{i k} false| X_{i} false(\cdot false) false]

, where

normalE false[ξ_{i k} false| X_{i} false(\cdot false) false] = \int_{{scriptT}_{X}} G_{k} false{X_{i} false(s false), s false} d s

, G k (·, ·) are unknown bivariate functions and ξ ik are the FPC scores of response. The representation is novel and extends ideas of Aston et al (2010) and Pomann et al (2015) to the case of a functional covariate. Also, it is related to Müller and Yao (2008) for

normalE false[ξ_{i k} false| X_{i} false(\cdot false) false] = true \sum_{m = 1}^{M} f_{k m} false(ξ_{i m}^{X} false)

, where f km (·) are unknown smooth functions for m = 1, …, M and

k = 1, \dots, K, false{ξ_{i 1}^{X}, \dots, ξ_{i M}^{X} false}

are the FPC scores of the functional covariate X i (·), and M is a finite truncation.…”

Section: Methodsmentioning

confidence: 99%

Additive Function-on-Function Regression

Kim

Staicu

Maity

et al. 2018

Journal of Computational and Graphical Statistics

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We study additive function-on-function regression where the mean response at a particular time point depends on the time point itself, as well as the entire covariate trajectory. We develop a computationally efficient estimation methodology based on a novel combination of spline bases with an eigenbasis to represent the trivariate kernel function. We discuss prediction of a new response trajectory, propose an inference procedure that accounts for total variability in the predicted response curves, and construct pointwise prediction intervals. The estimation/inferential procedure accommodates realistic scenarios, such as correlated error structure as well as sparse and/or irregular designs. We investigate our methodology in finite sample size through simulations and two real data applications. Supplementary Material for this article is available online.

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“…From this viewpoint, the model representation is optimal. The idea of using the eigenbasis of the pooled covariance can be related to Jiang and Wang () and Pomann et al (), who considered independent functional data.…”

Section: Introductionmentioning

confidence: 99%

Longitudinal functional data analysis

Park

Staicu

2015

Stat

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We consider dependent functional data that are correlated because of a longitudinal-based design: each subject is observed at repeated times and at each time a functional observation (curve) is recorded. We propose a novel parsimonious modeling framework for repeatedly observed functional observations that allows to extract low dimensional features. The proposed methodology accounts for the longitudinal design, is designed to study the dynamic behavior of the underlying process, allows prediction of full future trajectory, and is computationally fast. Theoretical properties of this framework are studied and numerical investigations confirm excellent behavior in finite samples. The proposed method is motivated by and applied to a diffusion tensor imaging study of multiple sclerosis.

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A Two-Sample Distribution-Free Test for Functional Data with Application to a Diffusion Tensor Imaging Study of Multiple Sclerosis

Cited by 49 publications

References 50 publications

The Use of Functional Data Analysis to Evaluate Activity in a Spontaneous Model of Degenerative Joint Disease Associated Pain in Cats

The Use of Functional Data Analysis to Evaluate Activity in a Spontaneous Model of Degenerative Joint Disease Associated Pain in Cats

Additive Function-on-Function Regression

Longitudinal functional data analysis

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