92 research outputs found
Applied Signal Processing
Being an inter-disciplinary subject, Signal Processing has application in almost all scientific fields. Applied Signal Processing tries to link between the analog and digital signal processing domains. Since the digital signal processing techniques have evolved from its analog counterpart, this book begins by explaining the fundamental concepts in analog signal processing and then progresses towards the digital signal processing. This will help the reader to gain a general overview of the whole subject and establish links between the various fundamental concepts. While the focus of this book is on the fundamentals of signal processing, the understanding of these topics greatly enhances the confident use as well as further development of the design and analysis of digital systems for various engineering and medical applications. Applied Signal Processing also prepares readers to further their knowledge in advanced topics within the field of signal processing
DENS-ECG: A Deep Learning Approach for ECG Signal Delineation
Objectives: With the technological advancements in the field of tele-health
monitoring, it is now possible to gather huge amounts of electro-physiological
signals such as electrocardiogram (ECG). It is therefore necessary to develop
models/algorithms that are capable of analysing these massive amounts of data
in real-time. This paper proposes a deep learning model for real-time
segmentation of heartbeats. Methods: The proposed algorithm, named as the
DENS-ECG algorithm, combines convolutional neural network (CNN) and long
short-term memory (LSTM) model to detect onset, peak, and offset of different
heartbeat waveforms such as the P-wave, QRS complex, T-wave, and No wave (NW).
Using ECG as the inputs, the model learns to extract high level features
through the training process, which, unlike other classical machine learning
based methods, eliminates the feature engineering step. Results: The proposed
DENS-ECG model was trained and validated on a dataset with 105 ECGs of length
15 minutes each and achieved an average sensitivity and precision of 97.95% and
95.68%, respectively, using a 5-fold cross validation. Additionally, the model
was evaluated on an unseen dataset to examine its robustness in QRS detection,
which resulted in a sensitivity of 99.61% and precision of 99.52%. Conclusion:
The empirical results show the flexibility and accuracy of the combined
CNN-LSTM model for ECG signal delineation. Significance: This paper proposes an
efficient and easy to use approach using deep learning for heartbeat
segmentation, which could potentially be used in real-time tele-health
monitoring systems
Learning Beyond Similarities: Incorporating Dissimilarities between Positive Pairs in Self-Supervised Time Series Learning
By identifying similarities between successive inputs, Self-Supervised
Learning (SSL) methods for time series analysis have demonstrated their
effectiveness in encoding the inherent static characteristics of temporal data.
However, an exclusive emphasis on similarities might result in representations
that overlook the dynamic attributes critical for modeling cardiovascular
diseases within a confined subject cohort. Introducing Distilled Encoding
Beyond Similarities (DEBS), this paper pioneers an SSL approach that transcends
mere similarities by integrating dissimilarities among positive pairs. The
framework is applied to electrocardiogram (ECG) signals, leading to a notable
enhancement of +10\% in the detection accuracy of Atrial Fibrillation (AFib)
across diverse subjects. DEBS underscores the potential of attaining a more
refined representation by encoding the dynamic characteristics of time series
data, tapping into dissimilarities during the optimization process. Broadly,
the strategy delineated in this study holds the promise of unearthing novel
avenues for advancing SSL methodologies tailored to temporal data
Asynchronous P300 BCI:SSVEP based control state detection
Publication in the conference proceedings of EUSIPCO, Aalborg, Denmark, 201
Optimal pseudorandom sequence selection for online c-VEP based BCI control applications
<div><p>Background</p><p>In a c-VEP BCI setting, test subjects can have highly varying performances when different pseudorandom sequences are applied as stimulus, and ideally, multiple codes should be supported. On the other hand, repeating the experiment with many different pseudorandom sequences is a laborious process.</p><p>Aims</p><p>This study aimed to suggest an efficient method for choosing the optimal stimulus sequence based on a fast test and simple measures to increase the performance and minimize the time consumption for research trials.</p><p>Methods</p><p>A total of 21 healthy subjects were included in an online wheelchair control task and completed the same task using stimuli based on the m-code, the gold-code, and the Barker-code. Correct/incorrect identification and time consumption were obtained for each identification. Subject-specific templates were characterized and used in a forward-step first-order model to predict the chance of completion and accuracy score.</p><p>Results</p><p>No specific pseudorandom sequence showed superior accuracy on the group basis. When isolating the individual performances with the highest accuracy, time consumption per identification was not significantly increased. The Accuracy Score aids in predicting what pseudorandom sequence will lead to the best performance using only the templates. The Accuracy Score was higher when the template resembled a delta function the most and when repeated templates were consistent. For completion prediction, only the shape of the template was a significant predictor.</p><p>Conclusions</p><p>The simple and fast method presented in this study as the Accuracy Score, allows c-VEP based BCI systems to support multiple pseudorandom sequences without increase in trial length. This allows for more personalized BCI systems with better performance to be tested without increased costs.</p></div
Adaptation in P300 braincomputer interfaces: A two-classifier cotraining approach
10.1109/TBME.2010.2058804IEEE Transactions on Biomedical Engineering57122927-2935IEBE
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