This book presents the modern technological advancements and revolutions in the biomedical sector. Progress in the contemporary sensing, Internet of Things (IoT) and machine learning algorithms and architectures have introduced new approaches in the mobile healthcare. A continuous observation of patients with critical health situation is required. It allows monitoring of their health status during daily life activities such as during sports, walking and sleeping. It is realizable by intelligently hybridizing the modern IoT framework, wireless biomedical implants and cloud computing. Such…mehr
This book presents the modern technological advancements and revolutions in the biomedical sector. Progress in the contemporary sensing, Internet of Things (IoT) and machine learning algorithms and architectures have introduced new approaches in the mobile healthcare. A continuous observation of patients with critical health situation is required. It allows monitoring of their health status during daily life activities such as during sports, walking and sleeping. It is realizable by intelligently hybridizing the modern IoT framework, wireless biomedical implants and cloud computing. Such solutions are currently under development and in testing phases by healthcare and governmental institutions, research laboratories and biomedical companies. The biomedical signals such as electrocardiogram (ECG), electroencephalogram (EEG), Electromyography (EMG), phonocardiogram (PCG), Chronic Obstructive Pulmonary (COP), Electrooculography (EoG), photoplethysmography (PPG), and image modalitiessuch as positron emission tomography (PET), magnetic resonance imaging (MRI) and computerized tomography (CT) are non-invasively acquired, measured, and processed via the biomedical sensors and gadgets. These signals and images represent the activities and conditions of human cardiovascular, neural, vision and cerebral systems. Multi-channel sensing of these signals and images with an appropriate granularity is required for an effective monitoring and diagnosis. It renders a big volume of data and its analysis is not feasible manually. Therefore, automated healthcare systems are in the process of evolution. These systems are mainly based on biomedical signal and image acquisition and sensing, preconditioning, features extraction and classification stages. The contemporary biomedical signal sensing, preconditioning, features extraction and intelligent machine and deep learning-based classification algorithms are described. Each chapter starts with the importance, problemstatement and motivation. A self-sufficient description is provided. Therefore, each chapter can be read independently. To the best of the editors' knowledge, this book is a comprehensive compilation on advances in non-invasive biomedical signal sensing and processing with machine and deep learning. We believe that theories, algorithms, realizations, applications, approaches, and challenges, which are presented in this book will have their impact and contribution in the design and development of modern and effective healthcare systems.
Saeed Mian Qaisar obtained his M.S and Ph.D. degrees in Electrical and Computer Engineering from the Grenoble Alpes University, France in 2005 and 2009 respectively. Subsequently, he did a postdoctoral stay at the University of Bordeaux, France. Afterward, he worked at different R&D positions in France. Currently, he is working as an Associate Professor & Researcher of the Electrical and Computer Engineering Department, Effat University, Jeddah, Saudi Arabia. He has been awarded with the Queen Effat Award for Excellence in Teaching, May 2016. He has two patents to his credit and has more than 200 published journal articles, book chapters and conference papers. He is serving as an editor of several international journals and is also on the technical and review committees of several international journals and conferences. His current area of research interest includes Signal processing, Event-driven systems, Circuits and systems, Machine learning, Deep Learning, Sampling theory, and Embedded Systems. Humaira Nisar has a B.S (Honours) in Electrical Engineering from the University of Engineering and Technology, Lahore, Pakistan, M.S in Nuclear Engineering from Quaid-i-Azam University, Islamabad, Pakistan, another M.S in Mechatronics, and Ph.D. in Information and Mechatronics from Gwangju Institute of Science and Technology, Gwangju, South Korea. She has more than twenty years of research experience. Currently, she is working as a Full Professor in the Department of Electronic Engineering, Universiti Tunku Abdul Rahman, Kampar, Malaysia. Her research interests include signal and image processing, biomedical imaging, neuro-signal processing and analysis, Brain-Computer Interface, and Neurofeedback. She has published more than 200 international journal and conference papers. She is a senior member of IEEE. Abdulhamit Subasi is specialized in Artificial Intelligence, Machine Learning, Biomedical Signal and Image Analysis. Concerning application of machine learning to different fields, he wrote more than 30 book chapters and more than 200 published journal and conference papers. He is also author of the books, "Practical Guide for Biomedical Signals Analysis Using Machine Learning Techniques" and "Practical Machine Learning for Data Analysis Using Python". Moreover, he is the Editor of the book "Applications of Artificial Intelligence in Medical Imaging". He worked at many institutions as an academician and Georgia Institute of Technology, Georgia, USA, as a researcher. He has been awarded with the Queen Effat Award for Excellence in Research, May 2018. He worked as a professor of computer science at Effat University, Jeddah, Saudi Arabia between 2015 and 2020. Since 2020, he has been working as a Professor at Faculty of Medicine, University of Turku, Turku, Finland.
Inhaltsangabe
1. Introduction to non-invasive biomedical signals for healthcare.- 2. Signal Acquisition Preprocessing and Feature Extraction Techniques for Biomedical Signals.- 3. The Role of EEG as Neuro-Markers for Patients with Depression: A systematic Review.- 4. Brain-Computer Interface (BCI) Based on the EEG Signal Decomposition Butterfly Optimization and Machine Learning.- 5. Advances in the analysis of electrocardiogram in context of mass screening: technological trends and application of artificial intelligence anomaly detection.- 6. Application of Wavelet Decomposition and Machine Learning for the sEMG Signal based Gesture Recognition.- 7. Review of EEG Signals Classification using Machine Learning and Deep-learning Techniques.- 8. "Biomedical signal processing and artificial intelligence in EOG signals".- 9. Peak Spectrogram and Convolutional Neural Network-based Segmentation and Classification for Phonocardiogram Signals.- 10. Eczema skin lesions segmentation using deep neural network (U-net).- 11. Biomedical signal processing for automated detection of sleep arousals Based on Multi-Physiological Signals with Ensemble learning methods.- 12. Deep Learning Assisted Biofeedback.- 13. Estimations of Emotional Synchronization Indices for Brain regions using Electroencephalogram Signal Analysis.- 14. Recognition Enhancement of Dementia Patients' Working Memory using Entropy-based Features and Local Tangent Space Alignment Algorithm.
1. Introduction to non-invasive biomedical signals for healthcare.- 2. Signal Acquisition Preprocessing and Feature Extraction Techniques for Biomedical Signals.- 3. The Role of EEG as Neuro-Markers for Patients with Depression: A systematic Review.- 4. Brain-Computer Interface (BCI) Based on the EEG Signal Decomposition Butterfly Optimization and Machine Learning.- 5. Advances in the analysis of electrocardiogram in context of mass screening: technological trends and application of artificial intelligence anomaly detection.- 6. Application of Wavelet Decomposition and Machine Learning for the sEMG Signal based Gesture Recognition.- 7. Review of EEG Signals Classification using Machine Learning and Deep-learning Techniques.- 8. "Biomedical signal processing and artificial intelligence in EOG signals".- 9. Peak Spectrogram and Convolutional Neural Network-based Segmentation and Classification for Phonocardiogram Signals.- 10. Eczema skin lesions segmentation using deep neural network (U-net).- 11. Biomedical signal processing for automated detection of sleep arousals Based on Multi-Physiological Signals with Ensemble learning methods.- 12. Deep Learning Assisted Biofeedback.- 13. Estimations of Emotional Synchronization Indices for Brain regions using Electroencephalogram Signal Analysis.- 14. Recognition Enhancement of Dementia Patients’ Working Memory using Entropy-based Features and Local Tangent Space Alignment Algorithm.
1. Introduction to non-invasive biomedical signals for healthcare.- 2. Signal Acquisition Preprocessing and Feature Extraction Techniques for Biomedical Signals.- 3. The Role of EEG as Neuro-Markers for Patients with Depression: A systematic Review.- 4. Brain-Computer Interface (BCI) Based on the EEG Signal Decomposition Butterfly Optimization and Machine Learning.- 5. Advances in the analysis of electrocardiogram in context of mass screening: technological trends and application of artificial intelligence anomaly detection.- 6. Application of Wavelet Decomposition and Machine Learning for the sEMG Signal based Gesture Recognition.- 7. Review of EEG Signals Classification using Machine Learning and Deep-learning Techniques.- 8. "Biomedical signal processing and artificial intelligence in EOG signals".- 9. Peak Spectrogram and Convolutional Neural Network-based Segmentation and Classification for Phonocardiogram Signals.- 10. Eczema skin lesions segmentation using deep neural network (U-net).- 11. Biomedical signal processing for automated detection of sleep arousals Based on Multi-Physiological Signals with Ensemble learning methods.- 12. Deep Learning Assisted Biofeedback.- 13. Estimations of Emotional Synchronization Indices for Brain regions using Electroencephalogram Signal Analysis.- 14. Recognition Enhancement of Dementia Patients' Working Memory using Entropy-based Features and Local Tangent Space Alignment Algorithm.
1. Introduction to non-invasive biomedical signals for healthcare.- 2. Signal Acquisition Preprocessing and Feature Extraction Techniques for Biomedical Signals.- 3. The Role of EEG as Neuro-Markers for Patients with Depression: A systematic Review.- 4. Brain-Computer Interface (BCI) Based on the EEG Signal Decomposition Butterfly Optimization and Machine Learning.- 5. Advances in the analysis of electrocardiogram in context of mass screening: technological trends and application of artificial intelligence anomaly detection.- 6. Application of Wavelet Decomposition and Machine Learning for the sEMG Signal based Gesture Recognition.- 7. Review of EEG Signals Classification using Machine Learning and Deep-learning Techniques.- 8. "Biomedical signal processing and artificial intelligence in EOG signals".- 9. Peak Spectrogram and Convolutional Neural Network-based Segmentation and Classification for Phonocardiogram Signals.- 10. Eczema skin lesions segmentation using deep neural network (U-net).- 11. Biomedical signal processing for automated detection of sleep arousals Based on Multi-Physiological Signals with Ensemble learning methods.- 12. Deep Learning Assisted Biofeedback.- 13. Estimations of Emotional Synchronization Indices for Brain regions using Electroencephalogram Signal Analysis.- 14. Recognition Enhancement of Dementia Patients’ Working Memory using Entropy-based Features and Local Tangent Space Alignment Algorithm.
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