Simultaneous inference for functional data in sports biomechanics

IF 1.4 4区数学 Q2 STATISTICS & PROBABILITY

Asta-Advances in Statistical Analysis Pub Date : 2021-10-01 DOI:10.1007/s10182-021-00418-4

Todd Colin Pataky, Konrad Abramowicz, Dominik Liebl, Alessia Pini, Sara Sjöstedt de Luna, Lina Schelin

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引用次数: 5

Abstract

The recent sports science literature conveys a growing interest in robust statistical methods to analyze smooth, regularly-sampled functional data. This paper focuses on the inferential problem of identifying the parts of a functional domain where two population means differ. We considered four approaches recently used in sports science: interval-wise testing (IWT), statistical parametric mapping (SPM), statistical nonparametric mapping (SnPM) and the Benjamini-Hochberg (BH) procedure for false discovery control. We applied these procedures to both six representative sports science datasets, and also to systematically varied simulated datasets which replicated ten signal- and/or noise-relevant parameters that were identified in the experimental datasets. We observed generally higher IWT and BH sensitivity for five of the six experimental datasets. BH was the most sensitive procedure in simulation, but also had relatively high false positive rates (generally > 0.1) which increased sharply (> 0.3) in certain extreme simulation scenarios including highly rough data. SPM and SnPM were more sensitive than IWT in simulation except for (1) high roughness, (2) high nonstationarity, and (3) highly nonuniform smoothness. These results suggest that the optimum procedure is both signal and noise-dependent. We conclude that: (1) BH is most sensitive but also susceptible to high false positive rates, (2) IWT, SPM and SnPM appear to have relatively inconsequential differences in terms of domain identification sensitivity, except in cases of extreme signal/noise characteristics, where IWT appears to be superior at identifying a greater portion of the true signal.

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运动生物力学中功能数据的同时推理

最近的体育科学文献表达了对稳健统计方法的兴趣，以分析光滑的，有规律采样的功能数据。本文重点讨论了识别功能域中两个总体均值不同的部分的推理问题。我们考虑了最近在体育科学中使用的四种方法:区间测试(IWT)、统计参数映射(SPM)、统计非参数映射(SnPM)和用于错误发现控制的Benjamini-Hochberg (BH)程序。我们将这些程序应用于六个具有代表性的运动科学数据集，以及系统地改变模拟数据集，这些数据集复制了在实验数据集中识别的十个信号和/或噪声相关参数。我们观察到六个实验数据集中的五个普遍较高的IWT和BH灵敏度。BH是模拟中最敏感的程序，但也有相对较高的假阳性率(一般为>0.1)，急剧上升(>0.3)在某些极端的模拟场景，包括高度粗糙的数据。SPM和SnPM在模拟中除了(1)高粗糙度、(2)高非平稳性和(3)高非均匀光滑性外，均比IWT更敏感。这些结果表明，最佳程序是信号和噪声都依赖。我们得出结论:(1)BH是最敏感的，但也容易受到高假阳性率的影响;(2)IWT、SPM和SnPM在域识别灵敏度方面似乎有相对无关的差异，除了极端信号/噪声特征的情况下，IWT在识别大部分真实信号方面似乎更胜一筹。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Asta-Advances in Statistical Analysis 数学-统计学与概率论

CiteScore

2.20

自引率

14.30%

发文量

审稿时长

>12 weeks

期刊介绍： AStA - Advances in Statistical Analysis, a journal of the German Statistical Society, is published quarterly and presents original contributions on statistical methods and applications and review articles.