A Hybrid Binary Bird Swarm Optimization (BSO) and Dragonfly Algorithm (DA) for VM Allocation and Load Balancing in Cloud

Kassanuk, Thanwamas; Phasinam, Khongdet

doi:10.4018/ijcac.318698

International Journal of Cloud Applications and Computing

2023

DOI: 10.4018/ijcac.318698

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A Hybrid Binary Bird Swarm Optimization (BSO) and Dragonfly Algorithm (DA) for VM Allocation and Load Balancing in Cloud

Thanwamas Kassanuk

Khongdet Phasinam

Abstract: The cloud platform is becoming one of the fastest-rising environments in human activities, connecting the whole world in the upcoming decades. The three crucial aspects of cloud computing that enhance the quality of service are load balancing, task scheduling, and resource allocation. To address these issues, the research proposed dynamic degree balance with CPU_based VM allocation policy integrated with hybrid bird swarm optimization (BSO) and dragonfly algorithm (DA). The proposed algorithm focuses on improv… Show more

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2024

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Cited by 2 publications

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AI-powered VM selection: Amplifying cloud performance with dragonfly algorithm

Rashmi,

Siwach,

Sehrawat

et al. 2024

Heliyon

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AI-powered VM selection: Amplifying cloud performance with dragonfly algorithm

Rashmi,

Siwach,

Sehrawat

et al. 2024

Heliyon

View full text Add to dashboard Cite

AI-powered COVID-19 forecasting: a comprehensive comparison of advanced deep learning methods

Tariq,

Ismail

2024

PHRP

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Objectives: The coronavirus disease 2019 (COVID-19) pandemic continues to pose significant challenges to the public health sector, including that of the United Arab Emirates (UAE). The objective of this study was to assess the efficiency and accuracy of various deep-learning models in forecasting COVID-19 cases within the UAE, thereby aiding the nation’s public health authorities in informed decision-making.Methods: This study utilized a comprehensive dataset encompassing confirmed COVID-19 cases, demographic statistics, and socioeconomic indicators. Several advanced deep learning models, including long short-term memory (LSTM), bidirectional LSTM, convolutional neural network (CNN), CNN-LSTM, multilayer perceptron, and recurrent neural network (RNN) models, were trained and evaluated. Bayesian optimization was also implemented to fine-tune these models.Results: The evaluation framework revealed that each model exhibited different levels of predictive accuracy and precision. Specifically, the RNN model outperformed the other architectures even without optimization. Comprehensive predictive and perspective analytics were conducted to scrutinize the COVID-19 dataset.Conclusion: This study transcends academic boundaries by offering critical insights that enable public health authorities in the UAE to deploy targeted data-driven interventions. The RNN model, which was identified as the most reliable and accurate for this specific context, can significantly influence public health decisions. Moreover, the broader implications of this research validate the capability of deep learning techniques in handling complex datasets, thus offering the transformative potential for predictive accuracy in the public health and healthcare sectors.

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A Hybrid Binary Bird Swarm Optimization (BSO) and Dragonfly Algorithm (DA) for VM Allocation and Load Balancing in Cloud

Cited by 2 publications

References 21 publications

AI-powered VM selection: Amplifying cloud performance with dragonfly algorithm

AI-powered VM selection: Amplifying cloud performance with dragonfly algorithm

AI-powered COVID-19 forecasting: a comprehensive comparison of advanced deep learning methods

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