ECG Biometrics using Deep Neural Networks

Biometrics is a rapidly growing field, with applications in personal identification and security. The Electrocardiogram (ECG) has the potential to be used as a physiological signature for biometric systems. However, current methods still lack in performance across different recording sessions. In this thesis, it is shown that Deep Learning can be applied successfully in the analysis of physiological signals for biometric purposes. This is accomplished in two different experiments by formulating novel approaches based on Convolutional Neural Networks and Recurrent Neural Networks, which may receive heartbeats, signal segments or spectrograms as input. These methods are compared in tasks implying the recognition of subjects from four public databases: Fantasia, ECG-ID, MIT-BIH and CYBHi. This work obtained state-of-the-art results for across-session authentication tasks on the CYBHi dataset, reaching Equal Error Rates of 10.57% and 10.01% for the best model, with corresponding identification accuracy rates of 55.58% and 58.91%. It also demonstrates that using spectrograms as input to the classifier is a promising approach for biometric identification, achieving accuracy values of 99.79% and 96.88%, respectively for Fantasia and ECG-ID databases. Further, it is shown empirically that for ECG biometric systems, the ability of a model to generalize is crucial, not only its capacity to relate and store information. These contributions represent another step towards real-world application of ECGbased biometric systems, closing the gap between intra and inter-session performance and providing some guidelines that can be applied in future work

Feature Papers in Electronic Materials Section

This book entitled "Feature Papers in Electronic Materials Section" is a collection of selected papers recently published on the journal Materials, focusing on the latest advances in electronic materials and devices in different fields (e.g., power- and high-frequency electronics, optoelectronic devices, detectors, etc.). In the first part of the book, many articles are dedicated to wide band gap semiconductors (e.g., SiC, GaN, Ga2O3, diamond), focusing on the current relevant materials and devices technology issues. The second part of the book is a miscellaneous of other electronics materials for various applications, including two-dimensional materials for optoelectronic and high-frequency devices. Finally, some recent advances in materials and flexible sensors for bioelectronics and medical applications are presented at the end of the book