Related papers: Energy-Efficient Tree-Based EEG Artifact Detection

Energy-Efficient Tree-Based EEG Artifact Detection

URL: http://arxiv.org/abs/2204.09577v1
Date: Tue, 19 Apr 2022 12:57:26 GMT
Title: Energy-Efficient Tree-Based EEG Artifact Detection
Authors: Thorir Mar Ingolfsson, Andrea Cossettini, Simone Benatti, Luca Benini
Abstract summary: In epilepsy monitoring, EEG artifacts are often mistaken for seizures due to their morphological similarity in both amplitude and frequency. In this work we present the implementation of an artifact detection algorithm based on a minimal number of EEG channels on a parallel ultra-low-power (PULP) embedded platform.
Score: 17.085570466000906
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In the context of epilepsy monitoring, EEG artifacts are often mistaken for seizures due to their morphological similarity in both amplitude and frequency, making seizure detection systems susceptible to higher false alarm rates. In this work we present the implementation of an artifact detection algorithm based on a minimal number of EEG channels on a parallel ultra-low-power (PULP) embedded platform. The analyses are based on the TUH EEG Artifact Corpus dataset and focus on the temporal electrodes. First, we extract optimal feature models in the frequency domain using an automated machine learning framework, achieving a 93.95% accuracy, with a 0.838 F1 score for a 4 temporal EEG channel setup. The achieved accuracy levels surpass state-of-the-art by nearly 20%. Then, these algorithms are parallelized and optimized for a PULP platform, achieving a 5.21 times improvement of energy-efficient compared to state-of-the-art low-power implementations of artifact detection frameworks. Combining this model with a low-power seizure detection algorithm would allow for 300h of continuous monitoring on a 300 mAh battery in a wearable form factor and power budget. These results pave the way for implementing affordable, wearable, long-term epilepsy monitoring solutions with low false-positive rates and high sensitivity, meeting both patients' and caregivers' requirements.

Related papers

AI-Powered Dynamic Fault Detection and Performance Assessment in Photovoltaic Systems [44.99833362998488]
intermittent nature of photovoltaic (PV) solar energy leads to power losses of 10-70% and an average energy production decrease of 25%. Current fault detection strategies are costly and often yield unreliable results due to complex data signal profiles. This research presents a computational model using the PVlib library in Python, incorporating a dynamic loss quantification algorithm.
arXiv Detail & Related papers (2024-08-19T23:52:06Z)
Energy-Efficient Seizure Detection Suitable for low-power Applications [0.5326090003728084]
Epilepsy is the most common, chronic, neurological disease worldwide. Neuro implants can be used for effective treatment by suppressing an upcoming seizure upon detection. We present an energy-efficient seizure detection approach involving a TC-ResNet and time-series analysis.
arXiv Detail & Related papers (2024-06-19T11:36:29Z)
REST: Efficient and Accelerated EEG Seizure Analysis through Residual State Updates [54.96885726053036]
This paper introduces a novel graph-based residual state update mechanism (REST) for real-time EEG signal analysis. By leveraging a combination of graph neural networks and recurrent structures, REST efficiently captures both non-Euclidean geometry and temporal dependencies within EEG data. Our model demonstrates high accuracy in both seizure detection and classification tasks.
arXiv Detail & Related papers (2024-06-03T16:30:19Z)
A Tiny Transformer for Low-Power Arrhythmia Classification on Microcontrollers [10.203375838335935]
A promising approach for real-time analysis of the electrocardiographic (ECG) signal and the detection of heart conditions, such as arrhythmia, is represented by the transformer machine learning model. We present a tiny transformer model for the analysis of the ECG signal, requiring only 6k parameters and reaching 98.97% accuracy in the recognition of the 5 most common arrhythmia classes from the MIT-BIH Arrhythmia database.
arXiv Detail & Related papers (2024-02-16T15:14:16Z)
EKGNet: A 10.96{\mu}W Fully Analog Neural Network for Intra-Patient Arrhythmia Classification [79.7946379395238]
We present an integrated approach by combining analog computing and deep learning for electrocardiogram (ECG) arrhythmia classification. We propose EKGNet, a hardware-efficient and fully analog arrhythmia classification architecture that archives high accuracy with low power consumption.
arXiv Detail & Related papers (2023-10-24T02:37:49Z)
EpiDeNet: An Energy-Efficient Approach to Seizure Detection for Embedded Systems [9.525786920713763]
This paper introduces EpiDeNet, a new lightweight seizure detection network. Sensitivity-Specificity Weighted Cross-Entropy (SSWCE) is a new loss function that incorporates sensitivity and specificity. A three-window majority voting-based smoothing scheme combined with the SSWCE loss achieves 3x reduction of false positives to 1.18 FP/h.
arXiv Detail & Related papers (2023-08-28T11:29:51Z)
Multiple Time Series Fusion Based on LSTM An Application to CAP A Phase Classification Using EEG [56.155331323304]
Deep learning based electroencephalogram channels' feature level fusion is carried out in this work. Channel selection, fusion, and classification procedures were optimized by two optimization algorithms.
arXiv Detail & Related papers (2021-12-18T14:17:49Z)
Energy-Efficient Real-Time Heart Monitoring on Edge-Fog-Cloud Internet-of-Medical-Things [4.927511651631258]
We present a novel and energy-efficient methodology for continuously monitoring the heart for low-power wearable devices. The proposed methodology is composed of three different layers: 1) a Noise/Artifact detection layer to grade the quality of the ECG signals; 2) a Normal/Abnormal beat classification layer to detect anomalies in the ECG signals; and 3) an Abnormal beat classification layer to detect diseases from ECG signals. Our methodology reaches an accuracy of 99.2% on the well-known MIT-BIH Arrhythmia dataset.
arXiv Detail & Related papers (2021-12-15T05:42:20Z)
Lung Cancer Lesion Detection in Histopathology Images Using Graph-Based Sparse PCA Network [93.22587316229954]
We propose a graph-based sparse principal component analysis (GS-PCA) network, for automated detection of cancerous lesions on histological lung slides stained by hematoxylin and eosin (H&E) We evaluate the performance of the proposed algorithm on H&E slides obtained from an SVM K-rasG12D lung cancer mouse model using precision/recall rates, F-score, Tanimoto coefficient, and area under the curve (AUC) of the receiver operator characteristic (ROC)
arXiv Detail & Related papers (2021-10-27T19:28:36Z)
SOUL: An Energy-Efficient Unsupervised Online Learning Seizure Detection Classifier [68.8204255655161]
Implantable devices that record neural activity and detect seizures have been adopted to issue warnings or trigger neurostimulation to suppress seizures. For an implantable seizure detection system, a low power, at-the-edge, online learning algorithm can be employed to dynamically adapt to neural signal drifts. SOUL was fabricated in TSMC's 28 nm process occupying 0.1 mm2 and achieves 1.5 nJ/classification energy efficiency, which is at least 24x more efficient than state-of-the-art.
arXiv Detail & Related papers (2021-10-01T23:01:20Z)
Towards Long-term Non-invasive Monitoring for Epilepsy via Wearable EEG Devices [11.622034020961912]
We present the implementation of seizure detection algorithms based on a minimal number of EEG channels on a parallel ultra-low-power embedded platform. We analyze global and subject-specific approaches, considering all 23-electrodes or only 4 temporal channels. For 8s window size and subject-specific approach, we report zero false positives and 100% sensitivity.
arXiv Detail & Related papers (2021-06-15T09:37:09Z)

This list is automatically generated from the titles and abstracts of the papers in this site.