97 research outputs found

    Deep learning for surface electromyography artifact contamination type detection

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    The quality of surface Electromyography (sEMG) signals could be an issue if highly contaminated by Power Line Interference (PLI), Electrocardiogram signal (ECG), Movement Artifact (MOA) or White Gaussian Noise (WGN), that could lead to unsafe operation of devices that is controlled by sEMG data, such as electro-mechanical prothesis. There are some mitigation methods proposed for some specifics sEMG contaminants and to use these methods in an efficient way is important to identify the contaminant in the sEMG signal. In this work we propose the use of a Recurrent Neural Network (RNN) using Long Short-Term Memory (LSTM) units in the hidden layer with no need of features extraction with the objective to classify the signal directly from sequences of the band-pass filtered data. The method proposed use the NinaPro database with amputee and non-amputee subjects. Only non-amputee subjects are used for parameters selection and then tested on both databases. The results show that 98% of the non-contaminated sEMG data was corrected classified and more than 95% of the contaminants were identified inside the training SNR range. Also, in this work is presented a SNR sensibility control and the contamination analysis in the range from −40 dB to 40 dB in 10 dB steps. The conclusion is that is possible to classify the contamination type in sEMG signals with a RNN-LSTM with a 112.5 ms time window and to predicted with a small error the classification hit rate for each SNR level in some cases

    The State of the Art of Information Integration in Space Applications

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    This paper aims to present a comprehensive survey on information integration (II) in space informatics. With an ever-increasing scale and dynamics of complex space systems, II has become essential in dealing with the complexity, changes, dynamics, and uncertainties of space systems. The applications of space II (SII) require addressing some distinctive functional requirements (FRs) of heterogeneity, networking, communication, security, latency, and resilience; while limited works are available to examine recent advances of SII thoroughly. This survey helps to gain the understanding of the state of the art of SII in sense that (1) technical drivers for SII are discussed and classified; (2) existing works in space system development are analyzed in terms of their contributions to space economy, divisions, activities, and missions; (3) enabling space information technologies are explored at aspects of sensing, communication, networking, data analysis, and system integration; (4) the importance of first-time right (FTR) for implementation of a space system is emphasized, the limitations of digital twin (DT-I) as technological enablers are discussed, and a concept digital-triad (DT-II) is introduced as an information platform to overcome these limitations with a list of fundamental design principles; (5) the research challenges and opportunities are discussed to promote SII and advance space informatics in future

    Application of Artificial Intelligence in Detection and Mitigation of Human Factor Errors in Nuclear Power Plants: A Review

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    Human factors and ergonomics have played an essential role in increasing the safety and performance of operators in the nuclear energy industry. In this critical review, we examine how artificial intelligence (AI) technologies can be leveraged to mitigate human errors, thereby improving the safety and performance of operators in nuclear power plants (NPPs). First, we discuss the various causes of human errors in NPPs. Next, we examine the ways in which AI has been introduced to and incorporated into different types of operator support systems to mitigate these human errors. We specifically examine (1) operator support systems, including decision support systems, (2) sensor fault detection systems, (3) operation validation systems, (4) operator monitoring systems, (5) autonomous control systems, (6) predictive maintenance systems, (7) automated text analysis systems, and (8) safety assessment systems. Finally, we provide some of the shortcomings of the existing AI technologies and discuss the challenges still ahead for their further adoption and implementation to provide future research directions

    Recent Developments in Smart Healthcare

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    Medicine is undergoing a sector-wide transformation thanks to the advances in computing and networking technologies. Healthcare is changing from reactive and hospital-centered to preventive and personalized, from disease focused to well-being centered. In essence, the healthcare systems, as well as fundamental medicine research, are becoming smarter. We anticipate significant improvements in areas ranging from molecular genomics and proteomics to decision support for healthcare professionals through big data analytics, to support behavior changes through technology-enabled self-management, and social and motivational support. Furthermore, with smart technologies, healthcare delivery could also be made more efficient, higher quality, and lower cost. In this special issue, we received a total 45 submissions and accepted 19 outstanding papers that roughly span across several interesting topics on smart healthcare, including public health, health information technology (Health IT), and smart medicine

    Run-time reconfiguration for efficient tracking of implanted magnets with a myokinetic control interface applied to robotic hands

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    Tese (doutorado)—Universidade de Brasília, Faculdade de Tecnologia, Departamento de Engenharia Mecânica, 2021.Este trabalho introduz a aplicação de soluções de aprendizagem de máquinas visado ao problema do rastreamento de posição do antebraço baseado em sensores magnéticos. Especi ficamente, emprega-se uma estratégia baseada em dados para criar modelos matemáticos que possam traduzir as informações magnéticas medidas em entradas utilizáveis para dispositivos protéticos. Estes modelos são implementados em FPGAs usando operadores customizados de ponto flutuante para otimizar o consumo de hardware e energia, que são importantes em dispositivos embarcados. A arquitetura de hardware é proposta para ser implementada como um sistema com reconfiguração dinâmica parcial, reduzindo potencialmente a utilização de recursos e o consumo de energia da FPGA. A estratégia de dados proposta e sua implemen tação de hardware pode alcançar uma latência na ordem de microssegundos e baixo consumo de energia, o que encoraja mais pesquisas para melhorar os métodos aqui desenvolvidos para outras aplicações.Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES).This work introduces the application of embedded machine learning solutions for the problem of magnetic sensors-based limb tracking. Namely, we employ a data-driven strat egy to create mathematical models that can translate the magnetic information measured to usable inputs for prosthetic devices. These models are implemented in FPGAs using cus tomized floating-point operations to optimize hardware and energy consumption, which are important in wearable devices. The hardware architecture is proposed to be implemented as a dynamically partial reconfigured system, potentially reducing resource utilization and power consumption of the FPGA. The proposed data-driven strategy and its hardware implementa tion can achieve a latency in the order of microseconds and low energy consumption, which encourages further research on improving the methods herein devised for other application

    Uso de redes recorrentes para identificação automática de contaminantes e para a estimação de um sensor virtual de eletromiografia no contexto de um sistema tolerante a falhas

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    O desenvolvimento de sistemas inteligentes controlados por eletromiografia que possam se adaptar a possíveis contaminações extrínsecas e intrínsecas, que afetem a taxa de acerto do classificador de movimentos, leva a dispositivos mais robustos e seguros, vistos que evitariam acionamentos indevidos e inesperados. Esse trabalho apresenta uma solução para contaminações por Artefato de Movimento, Ruído de Linha Elétrica, Ruído Branco Aditivo e ECG em 9 diferentes níveis de SNR, de -40dB a 40dB, utilizando Redes Neurais Recorrentes (RNR) com unidades LSTM nas duas etapas deste trabalho. A primeira etapa é o sistema de identificação da contaminação, que traz como inovação a identificação do contaminante diretamente do sinal bruto de sEMG, deixando para a rede a extração das características temporais, onde os resultados apontaram uma taxa de mais de 90% de acerto do tipo de contaminante para SNR = -30dB. A segunda etapa é a geração de um Sensor Virtual a partir de 7 estudos de caso em falhas de eletrodos, que traz como inovação a regressão do sinal retificado e suavizado por um filtro AVT. A geração do sensor virtual é realizada a partir dos canais não contaminados também utilizando uma RNR - LSTM com o objetivo de recuperar a taxa de acerto em 18 classes de um classificador Extreme Learning Machine (ELM), aplicado nas bases NinaPro e IEE. Os resultados indicaram que foi possível recuperar a taxa média de acerto para 2 canais contaminados com ruído branco aditivo em -30dB, de um total de 12 canais, de 7,28% para 68,34% em 4 indivíduos não amputados e de 15,07% para 43,67% em 9 indivíduos amputados.The development of electromyographic controlled systems adaptable to possibles extrinsic and intrisec contaminations, affecting the movement classification hit rate, lead to more robust and secure devices avoiding unexpected situations. This work presents a solution for Movement Artifact, Electrical Noise, White Gaussian Noise and ECG in nine SNR levels, ranging from -40dB to 40dB in 10dB steps, using Recurrent Neural Networks with LSTM units in the two stages of this work. The first stage is an automatic contamination detector, that has the contaminant identification made direct from the raw sEMG signal as a novelty, where the the tests point to 90% correct identification for SNR = -30dB. The second stage is the development of a virtual sensor, that generates the corrupted channel using the non-corrupted ones using a RNR-LSTM with the objective to recover the 18 movement class classification hit rate for an Extreme Learning Machine (ELM). The results shows that was possible to recovery the classification hit rate for 2 contaminated channels from 7.28% to 63.34% in 4 non-amputee subjects and from 15,07% to 43.67% in 9 amputee subjects

    Distributed approach to analyze physiological time series signals in medical telemetry

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    Research in healthcare domain is primarily focused on diseases based on the physiological changes of an individual. Physiological changes are often linked to multiple streams originated from different biological systems of a person. The streams from various biological systems together form attributes for evaluation of symptoms or diseases. The interconnected nature of different biological systems encourages the use of an aggregated approach to understand symptoms and predict diseases. These streams or physiological signals obtained from healthcare systems contribute to a vast amount of vital information in healthcare data. The advent of technologies allows to capture physiological signals over the period, but most of the data acquired from patients are observed momentarily or remains underutilized. The continuous nature of physiological signals demands context aware real-time analysis. The research aspects are addressed in this thesis using large-scale data processing solution. We have developed a general-purpose distributed pipeline for cumulative analysis of physiological signals in medical telemetry. The pipeline is built on the top of a framework which performs computation on a cluster in a distributed environment. The emphasis is given to the creation of a unified pipeline for processing streaming and non-streaming physiological time series signals. The pipeline provides fault-tolerance guarantees for the processing of signals and scalable to multiple cluster nodes. Besides, the pipeline enables indexing of physiological time series signals and provides visualization of real-time and archived time series signals. The pipeline provides interfaces to allow physicians or researchers to use distributed computing for low-latency and high-throughput signals analysis in medical telemetry
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