<scp>IOT‐HML</scp>: A hybrid machine learning technique for <scp>IoT</scp> enabled industrial monitoring and control system

Kota, P. N.; Chandak, Ashok S.; Patil, B. P.

doi:10.1002/cpe.7458

Cited by 18 publications

(8 citation statements)

References 36 publications

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“…Framework (IoT-HML) addresses myriad challenges in both areas [22]. Integrating data from diverse sensors bolsters prediction precision.…”

Section: Leveraging Hybrid Machine Learning (Hml) Methods Within the ...mentioning

confidence: 99%

Revolutionizing Neurostimulator Care: Enhancing Remote Health Monitoring through SDN-Cloud Networks

Antony,

Elangovan

2024

Preprint

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The Internet of Things (IoT) and artificial intelligence (AI) are the fastest-growing technological approaches globally. With the rising urban population, the concept of a smart city isn't new. To effectively integrate IoT and AI into remote healthcare monitoring (RHM) systems within smart cities, we must have a comprehensive grasp of smart city frameworks. Our proposed model focuses on gathering data from an auricular therapy device, a neurostimulator that provides non-invasive stimulation to the outer ear. This device communicates via Bluetooth, allowing data exchange between the patient's and doctor's phones. After collecting the brain signal data, it's processed to eliminate noise and is normalized. This data is then classified using the adaptive fuzzy based Bayesian metasalp neural network (AFBBMNN) combined with levy flight secure offloading analysis in Software Defined Networking (SDN). The results prominently emphasize the need for enhanced healthcare provision. This information is then relayed to doctors via a cloud-SDN module that comprises a communication phase, cloud server, and cloud database where the signals are stored. The proposed method offers promising outcomes, emphasizing its viability as an efficient tool for early neurological disease detection and treatment within a smart city healthcare framework.

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“…Framework (IoT-HML) addresses myriad challenges in both areas [22]. Integrating data from diverse sensors bolsters prediction precision.…”

Section: Leveraging Hybrid Machine Learning (Hml) Methods Within the ...mentioning

confidence: 99%

Revolutionizing Neurostimulator Care: Enhancing Remote Health Monitoring through SDN-Cloud Networks

Antony,

Elangovan

2024

Preprint

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“…4,5 The high mobility situations cannot be adapted by the current interpolation techniques. 6 In order to improve performance, deep learning (DL) techniques have recently been used to wireless communications, including channel estimation, channel state information (CSI) feedback, and data identification. 7,8 In beam space millimeter wave massive MIMO schemes, the receiver is designed with a small number of radio-frequency (RF) chains using learned denoising-base approximate message passing network.…”

Section: Introductionmentioning

confidence: 99%

“…Due to a lack of a priori statistical channel knowledge, the traditional algorithms perform worse 4,5 . The high mobility situations cannot be adapted by the current interpolation techniques 6 . In order to improve performance, deep learning (DL) techniques have recently been used to wireless communications, including channel estimation, channel state information (CSI) feedback, and data identification 7,8 .…”

Section: Introductionmentioning

confidence: 99%

Dual interactive Wasserstein generative adversarial networks optimized with hybrid Archimedes optimization and chimp optimization algorithm‐based channel estimation in OFDM

Mydhili

2024

Int J Communication

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SummaryDual interactive Wasserstein generative adversarial networks optimized with hybrid Archimedes optimization and chimp optimization algorithm‐based channel estimation in OFDM (DiWGAN‐Hyb AOA‐COA‐MIMO‐OFDM) is proposed in this manuscript. In OFDM, there is a non‐stationary channel physical appearance during channel estimation (CE). Therefore in this work, Hyb AOA‐COA is employed to enhance the DiWGAN weight parameters. The proposed DiWGAN‐Hyb AOA‐COA‐MIMO‐OFDM technique is executed in network simulator (NS2) tool. The proposed technique attains lower computational cost 99.67%, 92.34%, and 97.45%; lesser bit error rate 98.33%, 83.12%, and 88.96%; and lesser mean square error 93.15%, 79.90%, and 92.88% compared with existing methods, like MIMO‐OFDM system using deep neural network and MN‐based improved AMO model (DNN‐IAMO‐MIMO‐OFDM), MIMO‐OFDM systems using the deep learning and optimization (RBFNN‐PSO‐MIMO‐OFDM), and MIMO‐OFDM systems using hybrid neural network (HNN‐CSI‐MIMO‐OFDM) respectively.

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“…24 Additionally, the structure of the deep unfolding for any application involves signals processing, also the creative investigation possibilities to support future communication networks. 25…”

Section: Introductionmentioning

confidence: 99%

“…The deep unfolded approaches carry out sophisticated error correction, self‐interference cancelation, and signal estimation and identification, among other receiver activities 24 . Additionally, the structure of the deep unfolding for any application involves signals processing, also the creative investigation possibilities to support future communication networks 25 …”

Section: Introductionmentioning

confidence: 99%

Optimized wireless communication for 6G signal processing using memory‐augmented deep unfolding network

Eswaramoorthi,

Prasad,

et al. 2024

Int J Communication

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SummaryIn this manuscript, optimized wireless communication for 6G signals processing using memory‐augmented deep unfolding network (WC‐6G‐SP‐MADUN) is proposed. The aim of this work is to give a memory‐augmented deep unfolding network approach with a focus on belief propagation decoding of error correction codes and multiple‐input multiple‐output (MIMO) wireless systems. In contrast, compares and tabulates the performance of memory‐augmented deep unfolding methodologies with classic principled procedures, which could potentially enable 6G. Here, the wireless communication for 6G signal processing methods was used for a variety of receiver functions, including self‐interference cancelation, signal estimation and detection using memory‐augmented deep unfolding Network (MADUN), and advanced error correction by clouded leopard optimization algorithm (CLOA). Furthermore, outline the general framework of memory‐augmented deep unfolding method for any kind of signal processing application and talk about cutting edge research paths that will make it possible to build communication networks in the future. The proposed approach is implemented in MATLAB; the performance is analyzed with performance metrics such as reliability, complexity, SNR gain, convergence rate, hardware efficiency, and quantization bit width. The proposed approach attains higher SNR gain 17.96%, 24.75%, and 30.09%; lower complexity 17.92%, 23.41%, and 30.13%; and higher convergence 18.01%, 25.41%, and 31.39% when analyzed with existing techniques such as redefined wireless communication for 6G: signal processing meets deep learning and deep unfolding (RWC‐6G‐SP‐DU), lower complication deep unfolded neural network receiver for MIMO under probability data association detector (LC‐DUNN‐MIMO‐PDAD), and deep learning in physical layer communications: evolution with prospects on 5G and 6G networks (DL‐PLC‐6G), respectively.

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IOT‐HML: A hybrid machine learning technique for IoT enabled industrial monitoring and control system

Cited by 18 publications

References 36 publications

Revolutionizing Neurostimulator Care: Enhancing Remote Health Monitoring through SDN-Cloud Networks

Revolutionizing Neurostimulator Care: Enhancing Remote Health Monitoring through SDN-Cloud Networks

Dual interactive Wasserstein generative adversarial networks optimized with hybrid Archimedes optimization and chimp optimization algorithm‐based channel estimation in OFDM

Optimized wireless communication for 6G signal processing using memory‐augmented deep unfolding network

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