Jaehak Yu scite author profile

Recently, excellent by Internet of Things (IoT), the era of connected everything device is coming. However, the devices hardly show the manner to autonomous connectivity on it and the self-cooperation for applied to real-world environments. In this paper, we proposed a smart building on IoT and cloud-based technology that can perform collaboration and efficient operation with various sensing devices in building and facilities. The smart building is very important to reduce on a huge amount of building energy is consumed by the management system of buildings. The proposed system selects an optimum device feature subset from the computing resources and storages by our cloud-based building management system. The performance of our proposed system is tested via experiments which verify that its measures are satisfactory.

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Deep Learning-Based Stroke Disease Prediction System Using Real-Time Bio Signals

Choi

Park

Jun

et al. 2021

Sensors

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The emergence of an aging society is inevitable due to the continued increases in life expectancy and decreases in birth rate. These social changes require new smart healthcare services for use in daily life, and covid-19 has also led to a contactless trend necessitating more non-face-to-face health services. Due to the improvements that have been achieved in healthcare technologies, an increasing number of studies have attempted to predict and analyze certain diseases in advance. Research on stroke diseases is actively underway, particularly with the aging population. Stroke, which is fatal to the elderly, is a disease that requires continuous medical observation and monitoring, as its recurrence rate and mortality rate are very high. Most studies examining stroke disease to date have used MRI or CT images for simple classification. This clinical approach (imaging) is expensive and time-consuming while requiring bulky equipment. Recently, there has been increasing interest in using non-invasive measurable EEGs to compensate for these shortcomings. However, the prediction algorithms and processing procedures are both time-consuming because the raw data needs to be separated before the specific attributes can be obtained. Therefore, in this paper, we propose a new methodology that allows for the immediate application of deep learning models on raw EEG data without using the frequency properties of EEG. This proposed deep learning-based stroke disease prediction model was developed and trained with data collected from real-time EEG sensors. We implemented and compared different deep-learning models (LSTM, Bidirectional LSTM, CNN-LSTM, and CNN-Bidirectional LSTM) that are specialized in time series data classification and prediction. The experimental results confirmed that the raw EEG data, when wielded by the CNN-bidirectional LSTM model, can predict stroke with 94.0% accuracy with low FPR (6.0%) and FNR (5.7%), thus showing high confidence in our system. These experimental results demonstrate the feasibility of non-invasive methods that can easily measure brain waves alone to predict and monitor stroke diseases in real time during daily life. These findings are expected to lead to significant improvements for early stroke detection with reduced cost and discomfort compared to other measuring techniques.

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AI-Based Stroke Disease Prediction System Using Real-Time Electromyography Signals

Park

Kwon

et al. 2020

Applied Sciences

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Stroke is a leading cause of disabilities in adults and the elderly which can result in numerous social or economic difficulties. If left untreated, stroke can lead to death. In most cases, patients with stroke have been observed to have abnormal bio-signals (i.e., ECG). Therefore, if individuals are monitored and have their bio-signals measured and accurately assessed in real-time, they can receive appropriate treatment quickly. However, most diagnosis and prediction systems for stroke are image analysis tools such as CT or MRI, which are expensive and difficult to use for real-time diagnosis. In this paper, we developed a stroke prediction system that detects stroke using real-time bio-signals with artificial intelligence (AI). Both machine learning (Random Forest) and deep learning (Long Short-Term Memory) algorithms were used in our system. EMG (Electromyography) bio-signals were collected in real time from thighs and calves, after which the important features were extracted, and prediction models were developed based on everyday activities. Prediction accuracies of 90.38% for Random Forest and of 98.958% for LSTM were obtained for our proposed system. This system can be considered an alternative, low-cost, real-time diagnosis system that can obtain accurate stroke prediction and can potentially be used for other diseases such as heart disease.

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An in-depth analysis on traffic flooding attacks detection and system using data mining techniques

Kang

Park

et al. 2013

Journal of Systems Architecture

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Jaehak Yu

Traffic flooding attack detection with SNMP MIB using SVM

IoT as a applications: cloud-based building management systems for the internet of things

Deep Learning-Based Stroke Disease Prediction System Using Real-Time Bio Signals

AI-Based Stroke Disease Prediction System Using Real-Time Electromyography Signals

An in-depth analysis on traffic flooding attacks detection and system using data mining techniques

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