F-ratio test and hypothesis weighting: a methodology to optimize feature vector size.

Journal of biophysics (Hindawi Publishing Corporation : Online) Pub Date : 2011-01-01 Epub Date: 2011-08-17 DOI:10.1155/2011/290617

R M Dünki, M Dressel

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引用次数: 1

Abstract

Reducing a feature vector to an optimized dimensionality is a common problem in biomedical signal analysis. This analysis retrieves the characteristics of the time series and its associated measures with an adequate methodology followed by an appropriate statistical assessment of these measures (e.g., spectral power or fractal dimension). As a step towards such a statistical assessment, we present a data resampling approach. The techniques allow estimating σ(2)(F), that is, the variance of an F-value from variance analysis. Three test statistics are derived from the so-called F-ratio σ(2)(F)/F(2). A Bayesian formalism assigns weights to hypotheses and their corresponding measures considered (hypothesis weighting). This leads to complete, partial, or noninclusion of these measures into an optimized feature vector. We thus distinguished the EEG of healthy probands from the EEG of patients diagnosed as schizophrenic. A reliable discriminance performance of 81% based on Taken's χ, α-, and δ-power was found.

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f比检验和假设加权:一种优化特征向量大小的方法。

将特征向量降维是生物医学信号分析中的一个常见问题。该分析通过适当的方法检索时间序列及其相关措施的特征，然后对这些措施(例如，谱功率或分形维数)进行适当的统计评估。作为迈向这种统计评估的一步，我们提出了一种数据重采样方法。该技术允许估计σ(2)(F)，即方差分析中F值的方差。三个检验统计量由所谓的F比σ(2)(F)/F(2)导出。贝叶斯形式为假设和考虑的相应度量分配权重(假设加权)。这将导致这些度量完全、部分或不包含到优化的特征向量中。因此，我们将健康先证者的脑电图与精神分裂症患者的脑电图区分开来。基于take’s χ、α-和δ-power的可靠判别性能为81%。

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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Journal of biophysics (Hindawi Publishing Corporation : Online)

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