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1. ECG Classification With Event-Driven Sampling

Author

Maryam Saeed, Olev Martens, Benoit Larras, Antoine Frappe, Deepu John, and Barry Cardiff

Subjects
Level-crossing ADC, electrocardiograms, functional approximation, Chebyshev polynomials, artificial neural networks, arrhythmia, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Electrocardiogram (ECG) data’s high dimensionality challenges real-time arrhythmia classification. Our approach employs functional approximation to condense ECG recordings into a compact feature set for simpler classification using Chebyshev polynomials. These polynomials, with 200 time points and 80 coefficients, accurately represent arrhythmias in an $81 \times 1$ feature vector. We prove Chebyshev polynomials act as implicit low-pass filters on input signals. Using MIT-BIH Arrhythmia and MIT-BIH Supraventricular Arrhythmia datasets, we introduce classifiers that achieve significant accuracy. A three-layered Artificial Neural Network yields high F1-scores (0.99, 0.90, 0.93, and 0.76 for classes N, S, V, and F) with minimal parameters (20,964), surpassing existing models. Furthermore, our proposed ECG classification system exhibits minimal computational demands, requiring only 0.1 MIPS per beat. We also propose efficient signal reconstruction methods, with the iterative approach showcasing accurate reconstruction with negligible error. This approach accommodates various data sampling types and determines optimal Chebyshev coefficients for capturing signal bandwidth.

Published
2024
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2. A predictive analytics approach for stroke prediction using machine learning and neural networks

Author

Soumyabrata Dev, Hewei Wang, Chidozie Shamrock Nwosu, Nishtha Jain, Bharadwaj Veeravalli, and Deepu John

Subjects
predictive analytics, machine learning, neural network, electronic health records, stroke, Computer applications to medicine. Medical informatics, R858-859.7
Abstract

The negative impact of stroke in society has led to concerted efforts to improve the management and diagnosis of stroke. With an increased synergy between technology and medical diagnosis, caregivers create opportunities for better patient management by systematically mining and archiving the patients’ medical records. Therefore, it is vital to study the interdependency of these risk factors in patients’ health records and understand their relative contribution to stroke prediction. This paper systematically analyzes the various factors in electronic health records for effective stroke prediction. Using various statistical techniques and principal component analysis, we identify the most important factors for stroke prediction. We conclude that age, heart disease, average glucose level, and hypertension are the most important factors for detecting stroke in patients. Furthermore, a perceptron neural network using these four attributes provides the highest accuracy rate and lowest miss rate compared to using all available input features and other benchmarking algorithms. As the dataset is highly imbalanced concerning the occurrence of stroke, we report our results on a balanced dataset created via sub-sampling techniques.

Published
2022
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3. Binary Classifiers for Data Integrity Detection in Wearable IoT Edge Devices

Author

Arlene John, Rajesh C. Panicker, Barry Cardiff, Yong Lian, and Deepu John

Subjects
Data integrity detection, IoT sensors, electrocardiography, signal quality index, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4
Abstract

This paper presents a comparison of several artificial intelligence (AI) based binary classifiers for detecting the integrity of data obtained from Internet of Things (IoT) enabled wearable sensors. Detecting the integrity of data at the network edge facilitates the elimination of corrupted or unusable data, which translates to a lower amount of data stored and transmitted. This reduces the storage and power requirements of IoT devices without a reduction in functionality. In this work, we explore several machine learning-based classifiers to check the integrity of electrocardiogram (ECG) data. The feature vectors are derived from low complexity kurtosis and skewness based Signal Quality Indices (SQIs). From the experiments, it is found that a bagged ensemble of 3 neural networks achieves the highest detection accuracy of 99.47%. We also estimated the complexity and power consumed by the various classifier implementations and classifier fusion implementations. The energy consumed by the ensemble classifier was estimated to be around 0.039 nJ.

Published
2020
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4. Low Power Optimisations for IoT Wearable Sensors Based on Evaluation of Nine QRS Detection Algorithms

Author

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

Subjects
Bluetooth low energy, direct memory access, Internet of Things, on-chip processing, QRS detection, wearable sensors, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4
Abstract

This paper aims to reduce the power consumption of electrocardiography based wearable healthcare devices, by introducing power reduction approaches and considerations at system level design, where we have the highest potential to influence power. It focuses, in particular, on algorithm design and implementation, data acquisition, and transmission under constrained resources. A thorough investigation of the suitability of nine existing algorithms for on-sensor QRS feature detection is conducted, with respect to metrics such as sensitivity, positive predictivity, power consumption, parameter choice and time delay. Optimisation of data acquisition on CPU-based IoT systems is performed, and the current consumption is reduced by a factor of 3 using a combination of direct memory access (DMA) list approach and low-level register manipulations for task delegation. The acquisition data rate, sampling rate, buffer and batch size are also optimised. To reduce the power consumption by data transmission, the effect of on-sensor versus off-sensor processing is investigated. While focusing on CPU-based systems with experiments performed on a generic low-power wearable platform, the design optimisation and considerations proposed in this work could be extended to custom designs and allow further investigation into QRS detection algorithm optimisation for wearable devices.

Published
2020
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5. Identifying Stroke Indicators Using Rough Sets

Author

Muhammad Salman Pathan, Zhang Jianbiao, Deepu John, Avishek Nag, and Soumyabrata Dev

Subjects
Stroke, risk prediction, data mining, feature selection, rough set theory, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Stroke is widely considered as the second most common cause of mortality. The adverse consequences of stroke have led to global interest and work for improving the management and diagnosis of stroke. Various techniques for data mining have been used globally for accurate prediction of occurrence of stroke based on the risk factors that are associated with the electronic health care records (EHRs) of the patients. In particular, EHRs routinely contain several thousands of features and most of them are redundant and irrelevant that need to be discarded to enhance the prediction accuracy. The choice of feature-selection methods can help in improving the prediction accuracy of the model and efficient data management of the archived input features. In this paper, we systematically analyze the various features in EHR records for the detection of stroke. We propose a novel rough-set based technique for ranking the importance of the various EHR records in detecting stroke. Unlike the conventional rough-set techniques, our proposed technique can be applied on any dataset that comprises binary feature sets. stroke. We evaluated our proposed method in a publicly available dataset of EHR, and concluded that age, average glucose level, heart disease, and hypertension were the most essential attributes for detecting stroke in patients. Furthermore, we benchmarked the proposed technique with other popular feature-selection techniques. We obtained the best performance in ranking the importance of individual features in detecting stroke.

Published
2020
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6. Special Section on Edge AI and Accelerators

Author

Deepu John, Yongfu Li, and Xinmiao Zhang

Subjects
Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4
Abstract

This special section presents seven state-of-the-art design techniques for AI hardware accelerators that lead to substantial improvements on energy efficiency, reconfigurability, and resource utilization.

Published
2021
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42. ANNet: A Lightweight Neural Network for ECG Anomaly Detection in IoT Edge Sensors

Author

Gawsalyan Sivapalan, Koushik Kumar Nundy, Soumyabrata Dev, Barry Cardiff, and Deepu John

Subjects
Electrocardiography, Heart Rate, Biomedical Engineering, Humans, Arrhythmias, Cardiac, Neural Networks, Computer, Electrical and Electronic Engineering, Algorithms
Abstract

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 stand-alone operation in the edge node, without the need for always-on wireless connectivity making it ideal for IoT wearable devices.

Published
2022
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43. Multimodal Multiresolution Data Fusion Using Convolutional Neural Networks for IoT Wearable Sensing

Author

Arlene John, Koushik Kumar Nundy, Barry Cardiff, and Deepu John

Subjects
Electrocardiography, Wearable Electronic Devices, Sleep Apnea Syndromes, Databases, Factual, Biomedical Engineering, Humans, Neural Networks, Computer, Electrical and Electronic Engineering
Abstract

With advances in circuit design and sensing technology, the acquisition of data from a large number of Internet of Things (IoT) sensors simultaneously to enable more accurate inferences has become mainstream. In this work, we propose a novel convolutional neural network (CNN) model for the fusion of multimodal and multiresolution data obtained from several sensors. The proposed model enables the fusion of multiresolution sensor data, without having to resort to padding/ resampling to correct for frequency resolution differences even when carrying out temporal inferences like high-resolution event detection. The performance of the proposed model is evaluated for sleep apnea event detection, by fusing three different sensor signals obtained from UCD St. Vincent University Hospital's sleep apnea database. The proposed model is generalizable and this is demonstrated by incremental performance improvements, proportional to the number of sensors used for fusion. A selective dropout technique is used to prevent overfitting of the model to any specific high-resolution input, and increase the robustness of fusion to signal corruption from any sensor source. A fusion model with electrocardiogram (ECG), Peripheral oxygen saturation signal (SpO2), and abdominal movement signal achieved an accuracy of 99.72% and a sensitivity of 98.98%. Energy per classification of the proposed fusion model was estimated to be approximately 5.61 μJ for on-chip implementation. The feasibility of pruning to reduce the complexity of the fusion models was also studied.

Published
2021
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45. Low Complexity Binarized 2D-CNN Classifier for Wearable Edge AI Devices

Author

David Liang Tai Wong, Yongfu Li, Deepu John, Weng Khuen Ho, and Chun-Huat Heng

Subjects
Wearable Electronic Devices, Artificial Intelligence, Biomedical Engineering, Neural Networks, Computer, Electrical and Electronic Engineering, Algorithms
Abstract

Wearable Artificial Intelligence-of-Things (AIoT) devices exhibit the need to be resource and energy-efficient. In this paper, we introduced a quantized multilayer perceptron (qMLP) for converting ECG signals to binary image, which can be combined with binary convolutional neural network (bCNN) for classification. We deploy our model into a low-power and low-resource field programmable gate array (FPGA) fabric. The model requires 5.8× lesser multiply and accumulate (MAC) operations than known wearable CNN models. Our model also achieves a classification accuracy of 98.5%, sensitivity of 85.4%, specificity of 99.5%, precision of 93.3%, and F1-score of 89.2%, along with dynamic power dissipation of 34.9 μW.

Published
2022

47. Binary Classifiers for Data Integrity Detection in Wearable IoT Edge Devices

Author

Yong Lian, Arlene John, Rajesh C. Panicker, Barry Cardiff, and Deepu John

Subjects
Artificial neural network, Edge device, business.industry, Computer science, electrocardiography, Feature vector, Binary number, Wearable computer, Pattern recognition, Data integrity detection, ComputingMethodologies_PATTERNRECOGNITION, lcsh:Electric apparatus and materials. Electric circuits. Electric networks, Data integrity, IoT sensors, Kurtosis, signal quality index, Artificial intelligence, lcsh:TK452-454.4, business, Classifier (UML)
Abstract

This paper presents a comparison of several artificial intelligence (AI) based binary classifiers for detecting the integrity of data obtained from Internet of Things (IoT) enabled wearable sensors. Detecting the integrity of data at the network edge facilitates the elimination of corrupted or unusable data, which translates to a lower amount of data stored and transmitted. This reduces the storage and power requirements of IoT devices without a reduction in functionality. In this work, we explore several machine learning-based classifiers to check the integrity of electrocardiogram (ECG) data. The feature vectors are derived from low complexity kurtosis and skewness based Signal Quality Indices (SQIs). From the experiments, it is found that a bagged ensemble of 3 neural networks achieves the highest detection accuracy of 99.47%. We also estimated the complexity and power consumed by the various classifier implementations and classifier fusion implementations. The energy consumed by the ensemble classifier was estimated to be around 0.039 nJ.

Published
2020
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48. Identifying Stroke Indicators Using Rough Sets

Author

Avishek Nag, Deepu John, Muhammad Salman Pathan, Soumyabrata Dev, and Zhang Jianbiao

Subjects
FOS: Computer and information sciences, Computer Science - Machine Learning, General Computer Science, Heart disease, Computer science, Data management, Feature extraction, 02 engineering and technology, computer.software_genre, Machine Learning (cs.LG), risk prediction, feature selection, 020204 information systems, Health care, 0202 electrical engineering, electronic engineering, information engineering, medicine, General Materials Science, Stroke, rough set theory, business.industry, General Engineering, data mining, medicine.disease, Common cause and special cause, Feature (computer vision), 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, Rough set, Data mining, business, lcsh:TK1-9971, computer
Abstract

Stroke is widely considered as the second most common cause of mortality. The adverse consequences of stroke have led to global interest and work for improving the management and diagnosis of stroke. Various techniques for data mining have been used globally for accurate prediction of occurrence of stroke based on the risk factors that are associated with the electronic health care records (EHRs) of the patients. In particular, EHRs routinely contain several thousands of features and most of them are redundant and irrelevant that need to be discarded to enhance the prediction accuracy. The choice of feature-selection methods can help in improving the prediction accuracy of the model and efficient data management of the archived input features. In this paper, we systematically analyze the various features in EHR records for the detection of stroke. We propose a novel rough-set based technique for ranking the importance of the various EHR records in detecting stroke. Unlike the conventional rough-set techniques, our proposed technique can be applied on any dataset that comprises binary feature sets. We evaluated our proposed method in a publicly available dataset of EHR, and concluded that age, average glucose level, heart disease, and hypertension were the most essential attributes for detecting stroke in patients. Furthermore, we benchmarked the proposed technique with other popular feature-selection techniques. We obtained the best performance in ranking the importance of individual features in detecting stroke., Accepted in IEEE Access, 2020

Published
2020
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49. Low Power Optimisations for IoT Wearable Sensors Based on Evaluation of Nine QRS Detection Algorithms

Author

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

Subjects
Electronic system-level design and verification, business.industry, Computer science, on-chip processing, wearable sensors, Internet of Things, Wearable computer, Bluetooth low energy, Data acquisition, Transmission (telecommunications), lcsh:Electric apparatus and materials. Electric circuits. Electric networks, QRS detection, Algorithm design, direct memory access, lcsh:TK452-454.4, business, Direct memory access, Algorithm, Wearable technology, Data transmission
Abstract

This paper aims to reduce the power consumption of electrocardiography based wearable healthcare devices, by introducing power reduction approaches and considerations at system level design, where we have the highest potential to influence power. It focuses, in particular, on algorithm design and implementation, data acquisition, and transmission under constrained resources. A thorough investigation of the suitability of nine existing algorithms for on-sensor QRS feature detection is conducted, with respect to metrics such as sensitivity, positive predictivity, power consumption, parameter choice and time delay. Optimisation of data acquisition on CPU-based IoT systems is performed, and the current consumption is reduced by a factor of 3 using a combination of direct memory access (DMA) list approach and low-level register manipulations for task delegation. The acquisition data rate, sampling rate, buffer and batch size are also optimised. To reduce the power consumption by data transmission, the effect of on-sensor versus off-sensor processing is investigated. While focusing on CPU-based systems with experiments performed on a generic low-power wearable platform, the design optimisation and considerations proposed in this work could be extended to custom designs and allow further investigation into QRS detection algorithm optimisation for wearable devices.

Published
2020

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