Biosignal Processing Principles and Practices
Coordonnateurs : Liang Hualou, Bronzino Joseph D., Peterson Donald R.
With the rise of advanced computerized data collection systems, monitoring devices, and instrumentation technologies, large and complex datasets accrue as an inevitable part of biomedical enterprise. The availability of these massive amounts of data offers unprecedented opportunities to advance our understanding of underlying biological and physiological functions, structures, and dynamics.
Biosignal Processing: Principles and Practices provides state-of-the-art coverage of contemporary methods in biosignal processing with an emphasis on brain signal analysis. After introducing the fundamentals, it presents emerging methods for brain signal processing, focusing on specific non-invasive imaging techniques such as electroencephalography (EEG), magnetoencephalography (MEG), magnetic resonance imaging (MRI), and functional near-infrared spectroscopy (fNIR). In addition, the book presents recent advances, reflecting the evolution of biosignal processing.
As biomedical datasets grow larger and more complicated, the development and use of signal processing methods to analyze and interpret these data has become a matter of course. This book is one step in the development of biosignal analysis and is designed to stimulate new ideas and opportunities in the development of cutting-edge computational methods for biosignal processing.
Digital Biomedical Signal Acquisition and Processing. Time–Frequency Signal Representations for Biomedical Signals. Multivariate Spectral Analysis of Electroencephalogram: Power, Coherence, and Second-Order Blind Identification. General Linear Modeling of Magnetoencephalography Data. Emergence of Groupwise Registration in MR Brain Study. Functional Optical Brain Imaging. Causality Analysis of Multivariate Neural Data.
Date de parution : 10-2012
Ouvrage de 216 p.
17.8x25.4 cm
Thèmes de Biosignal Processing :
Mots-clés :
EEG Power Spectrum; EEG Signal; Digital Biomedical Signal Acquisition and Processing; EEG Coherence; Time–Frequency Signal Representations for Biomedical Signals; Scalp EEG; General Linear Modeling of Magnetoencephalography Data; ECG Signal; Functional Optical Brain Imaging; fNIR Data; Causality Analysis of Multivariate Neural Data; fNIR Measurements; biosignal processing principles; fNIR Studies; brain waves physiology; EEG Electrode; brain mapping; Tissue Probability Maps; EEG Dynamic; Concentric Spheres Model; FWER Control; Cross-spectral Density Function; Multivariate Spectral Analysis; Meg Data; Occipital Channel; EEG Channel; Granger Causality; Volume Conduction; Scalp Potential; Dipole Layer; GLM Framework; Alpha Band; ADNI Data