For fMRI time-series analysis to be statistically valid, it is important to deal correctly with temporal autocorrelation in the noise. Most of the approaches in the literature adopt a two-stage approach in which the autocorrelation structure is estimated using the residuals of an initial model fit. This estimate is then used to "prewhiten" the data and the model before the model is refit to obtain final activation parameter estimates. An assumption implicit in this scheme is that the residuals from the initial model fit represent a realization of the "true" noise process. In general this assumption will not be correct as certain components of the noise will be removed by the model fit. In this paper we examine (i) the form of the bias induc...
The voxel-wise general linear model (GLM) approach has arguably become the dominant way to analyze f...
The voxel-wise general linear model (GLM) approach has arguably become the dominant way to analyze f...
We present a new method to detect and adjust for noise and artifacts in functional MRI time series d...
In functional magnetic resonance imaging statistical analysis there are problems with accounting for...
Analysis of fMRI time-series data is usually performed within the general linear model (GLM), and co...
Given the recent controversies in some neuroimaging statistical methods, we compare the most frequen...
When performing statistical analysis of single-subject fMRI data, serial correlations need to be tak...
One of the major issues in GLM-based fMRI analysis techniques is the presence of temporal autocorrel...
Abstract A typical time series in functional magnetic resonance imaging (fMRI) exhibits autocorrelat...
Functional magnetic resonance imaging (fMRI) is one of the most widely used tools to study the neura...
The general linear model provides the most widely applied statistical framework for analyzing functi...
Functional magnetic resonance imaging (fMRI) is a relatively new non-invasive technique that is used...
000), we describe an implementation of a general linear model for autocorrelated observations in whi...
As a consequence of misspecification of the hemodynamic response and noise variance models, tests on...
The validity of inference based on the General Linear Model (GLM) for the analysis of functional mag...
The voxel-wise general linear model (GLM) approach has arguably become the dominant way to analyze f...
The voxel-wise general linear model (GLM) approach has arguably become the dominant way to analyze f...
We present a new method to detect and adjust for noise and artifacts in functional MRI time series d...
In functional magnetic resonance imaging statistical analysis there are problems with accounting for...
Analysis of fMRI time-series data is usually performed within the general linear model (GLM), and co...
Given the recent controversies in some neuroimaging statistical methods, we compare the most frequen...
When performing statistical analysis of single-subject fMRI data, serial correlations need to be tak...
One of the major issues in GLM-based fMRI analysis techniques is the presence of temporal autocorrel...
Abstract A typical time series in functional magnetic resonance imaging (fMRI) exhibits autocorrelat...
Functional magnetic resonance imaging (fMRI) is one of the most widely used tools to study the neura...
The general linear model provides the most widely applied statistical framework for analyzing functi...
Functional magnetic resonance imaging (fMRI) is a relatively new non-invasive technique that is used...
000), we describe an implementation of a general linear model for autocorrelated observations in whi...
As a consequence of misspecification of the hemodynamic response and noise variance models, tests on...
The validity of inference based on the General Linear Model (GLM) for the analysis of functional mag...
The voxel-wise general linear model (GLM) approach has arguably become the dominant way to analyze f...
The voxel-wise general linear model (GLM) approach has arguably become the dominant way to analyze f...
We present a new method to detect and adjust for noise and artifacts in functional MRI time series d...