Low Power Optimisations for IoT Wearable Sensors Based on Evaluation of Nine QRS Detection Algorithms

Li, Jiamin; Ashraf, Adnan; Cardiff, Barry; Panicker, Rajesh C.; Lian, Yong; John, Deepu

doi:10.1109/ojcas.2020.3009822

Cited by 18 publications

(7 citation statements)

References 31 publications

(27 reference statements)

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“…Singleton features 1) Peak locations: The location (in time) of the R peak and the P, QRS, and T waveform onset times are the most elementary features that are the basis of many other elaborate features below. A complete implementation would need to estimate these features using existing algorithms [34], [35], [36]. In this work we assume, that R-peak detection is done on-chip by the data acquisition analog-front-end circuit, as in the case of commercially available solutions [37].…”

Section: Appendix B Feature Definitionsmentioning

confidence: 99%

Interpretable Rule Mining for Real-Time ECG Anomaly Detection in IoT Edge Sensors

Sivapalan

Nundy²,

James³

et al. 2023

IEEE Internet Things J.

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Electrocardiogram (ECG) analysis is widely used in the diagnosis of cardiovascular diseases. This paper proposes an explainable rule-mining strategy for prioritizing abnormal class detection in ECG data. The proposed method utilizes a biasedtrained Artificial Neural Network (ANN) with input features derived from an ECG beat sequence and formulates a set of rules at each node of an on-demand tree-like search algorithm. The rule base at each node is derived from a linear combination of the most impactful features identified using gradient analysis in an ANN. The final derived model is an explainable rule-based system that detects abnormal heartbeats based on statistical and morphological features from ECG. The model achieves the target sensitivity, and accuracy with a low run-time complexity through a comprehensive offline rule mining process and is trained using the MIT-BIH Arrhythmia Database. The system achieves an accuracy of 93% with only nine nodes and a test sensitivity of 90% and 80% respectively for VEB and SVEB beat types, when tested on previously unseen ECG data from the INCART database. The model performance and complexity can be easily adjusted based on the real-time resource constraints of a wearable sensor. The model was deployed on an ARM Cortex M4-based embedded device and is shown to achieve a > 50% reduction in sensor power consumption when only abnormal beats are wirelessly transmitted. i.e RF transmission is gated using the model output and transmission is disabled when the subject's ECG is normal. The proposed technique is highly suited for healthcare applications because of its explainability, lower complexity, and real-time flexibility when deployed in the Internet of Things (IoT) enabled wearable edge sensors.

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Section: Appendix B Feature Definitionsmentioning

confidence: 99%

Interpretable Rule Mining for Real-Time ECG Anomaly Detection in IoT Edge Sensors

Sivapalan

Nundy²,

James³

et al. 2023

IEEE Internet Things J.

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“…Additionally, we chose to use R-peak location annotations from MIT-BIH database [21] directly instead of implementing our own R-peak detector. Since there are several existing works that achieve good accuracy for R-peak detection [23], [24], [25], we narrowed the scope of this work and focus exclusively on developing the classifier.…”

Section: Data Set and Pre-processingmentioning

confidence: 99%

ANNet: A Lightweight Neural Network for ECG Anomaly Detection in IoT Edge Sensors

Sivapalan

Nundy²,

Dev

et al. 2022

IEEE Trans. Biomed. Circuits Syst.

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In this paper, we propose a lightweight neural network for real-time electrocardiogram (ECG) anomaly detection and system level power reduction of wearable Internet of Things (IoT) Edge sensors. The proposed network utilizes a novel hybrid architecture consisting of Long Short Term Memory (LSTM) cells and Multi-Layer Perceptrons (MLP). The LSTM block takes a sequence of coefficients representing the morphology of ECG beats while the MLP input layer is fed with features derived from instantaneous heart rate. Simultaneous training of the blocks pushes the overall network to learn distinct features complementing each other for making decisions. The network was evaluated in terms of accuracy, computational complexity, and power consumption using data from the MIT-BIH arrhythmia database. To address the class imbalance in the dataset, we augmented the dataset using SMOTE algorithm for network training. The network achieved an average classification accuracy of 97% across several records in the database. Further, the network was mapped to a fixed point model, retrained in a bit accurate fixed-point environment to compensate for the quantization error, and ported to an ARM Cortex M4 based embedded platform. In laboratory testing, the overall system was successfully demonstrated, and a significant saving of ≃50% power was achieved by gating the wireless transmission using the classifier. Wireless transmission was enabled only to transmit the beats deemed anomalous by the classifier. The proposed technique compares favourably with current methods in terms of computational complexity and has the advantage of standalone operation in the edge node, without the need for always-on wireless connectivity making it ideal for IoT wearable devices.

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“…Esta conexión se conoce como Internet de las Cosas (IoT), con la cual es posible realizar el monitoreo de variables y automatización de procesos de forma rápida y segura, permitiendo conectar una variedad de dispositivos a Internet, logrando una comunicación con las personas y objetos (Luna et al, 2019). Una aplicación de la IoT es en el campo de la salud, con el desarrollo de dispositivos de monitoreo cardíaco, el cual ha crecido en los últimos años, estos dispositivos tienen la ventaja de permitir una mayor movilidad, además de ser útiles en la detección temprana de enfermedades cardiovasculares en comparación con los monitores Holter tradicionales (Li et al, 2020). Es aquí donde se destaca el Internet de las cosas (IoT), el cual tiene el potencial de mejorar las aplicaciones médicas en los dispositivos de electrocardiografía.…”

Section: Introductionunclassified

Prototipo de un monitor cardiaco implementando IOT

Viloria

Bracho

2022

revTECHNO

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El objetivo del estudio consiste en desarrollar un prototipo de monitoreo cardiaco ambulatorio implementando IoT. En el presente trabajo se muestra el desarrollo de un dispositivo capaz de estudiar la frecuencia cardiaca utilizando tecnología IoT.El dispositivo desarrollado cuenta con características como amplificar, filtrar y acondicionar la señal cardiaca gracias a su arquitectura y los tres electrodos conectados en puntos específicos del cuerpo humano. Al adquirir estos datos, se realiza el envío a través de un módulo de desarrollo programable el cual se conecta a internet vía WiFi y envía la información obtenida a un servidor web en la nube.

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Low Power Optimisations for IoT Wearable Sensors Based on Evaluation of Nine QRS Detection Algorithms

Cited by 18 publications

References 31 publications

Interpretable Rule Mining for Real-Time ECG Anomaly Detection in IoT Edge Sensors

Interpretable Rule Mining for Real-Time ECG Anomaly Detection in IoT Edge Sensors

ANNet: A Lightweight Neural Network for ECG Anomaly Detection in IoT Edge Sensors

Prototipo de un monitor cardiaco implementando IOT

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