Buch, Englisch, 280 Seiten, Format (B × H): 156 mm x 234 mm
Contemporary Methods and Applications
Buch, Englisch, 280 Seiten, Format (B × H): 156 mm x 234 mm
ISBN: 978-1-041-00745-6
Verlag: Taylor & Francis Ltd
Time-frequency analysis is critical in biomedical signal analysis, which helps diagnose and monitor physiological conditions such as heart rate variability, seizure detection, and brain-computer interfacing. This edited book includes original theoretical, practical, and review chapters aimed at proposing advancements in time-frequency signal processing methods for biomedical healthcare applications. Exemplary themes of interest include biomedical signal processing challenges in complex physiological data, signals from remote sensors, wearables, and nearables such as ballistography-based sensors.
Features:
- Discusses detailed time-frequency signal processing applications for simple to complex biomedical research
- Reports novel time-frequency techniques used for biomedical signals
- Presents the theoretical basis of time-frequency analysis and state-of-the-art applications tailored for various biomedical problems
- Provides a forum for presenting new and improved techniques and theories related to time-frequency analysis
- Combines the primary knowledge of time-frequency signal analysis and processing, from theory and applications
This book is aimed at graduate students and researchers in bioengineering and signal processing.
Zielgruppe
Academic and Postgraduate
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
I. Introduction to Time-Frequency Analysis for Biomedical Engineering. Chapter 1: Wavelet-Based Biomedical Signal Analysis: A Tutorial Approach for Pathological Assessment. II. Time-Frequency Analysis of Specific Biomedical Signals. Chapter 2: Time-Frequency Analysis of ECG Signal. Chapter 3: Application of decomposition techniques to physiological time series with variable spectral content. III. Applications in Neurological Signal Processing. Chapter 4: Denoising of Single-Channel EEG Signals Using Wavelet Transform with Krawtchouk Functions. Chapter 5: Optimized Feature Selection and Neural Network-Based Classification of Motor Imagery Using EEG Signals: A Time-Frequency Approach. Chapter 6: Electroencephalogram Based Driver Drowsiness Detection Using Entropy Features with Light Weight Deep Learning Model. IV. Seizure Detection and Classification using Time-Frequency Features. Chapter 7: From Signals to Automated System: Seizure Detection Using Time-Frequency EEG Features – An Experimental Investigation. Chapter 8: Deep Learning based Epileptic Seizure Classification in Neonates using STFT-Transformed EEG Signals. Chapter 9: E-PRESTO: Epileptic PREictal State detection using Time-series mOdelling. Chapter 10: Sliding Window-Based Epileptic Seizure Detection using Classifier Fusion and TQWT with Statistical Features. V. Advanced Techniques and Machine Learning Applications. Chapter 11: Arrhythmia detection using WPD with Bagging and Boosting Ensemble Machine Learning Methods. Chapter 12: EEG based biometric authentication using Wavelet Packet Decomposition and Ensemble Classifiers
