Deep Learning-Based Predictive Resource Allocation Framework for Energy-Efficient Cloud Systems
DOI:
https://doi.org/10.65405/j6zd9z67الكلمات المفتاحية:
Deep learning , Predictive resource allocation, Energy efficiency , Cloud computing, LSTM, GRU, CNN; Workload forecasting, Virtual machine consolidation; Service Level Agreement; Quality of Serviceالملخص
Energy efficiency and service provisioning are the two major challenges in current days cloud computing paradigm. In this article, a new dynamic energy-efficient Deep Learning-Based Predictive Resource Allocation Framework (DLPRAF) is introduced for timely allocation of resources while upholding SLA adherence. This framework incorporates several deep learning architectures—namely Long Short-Term Memory (LSTM), Gated Recurrent Unit (GRU) and Convolutional Neural Networks (CNN)—to accurately forecast cloud workload trends. We incorporate temporal and spatial feature extraction ability to capture complex nonlinear dependencies in cloud workloads. By allowing for proactive resource provisioning instead of reactive approaches, the recommended system in better use of resources, lower energy consumption and improved QoS. We experimentally evaluate the effectiveness of DLPRAF and show on real-world cloud datasets (Google Cluster Data and Alibaba traces), that DLPRAF are 32.5% more resource utilization efficient, 43.3% timely and incur 26.6% lower operational costs than threshold-based approaches2. We are able to achieve 98.6% SLA compliance for our framework while providing cloud infrastructure with meaningful sustainability benefits.
التنزيلات
المراجع
[1] Suhad Ibrahim Mohammad, Ziyad Tariq, Mustafa Al-Ta'i. Enhancing Cloud Resource Allocation with a Hybrid Deep Learning-Based Framework: A Comparative Study. 2025.
[2] Torana Kamble et al. Predictive Resource Allocation Strategies for Cloud Computing Environments Using Machine Learning. 2024.
[3] Farman Ullah, Muhammad Bilal, Su-Kyung Yoon. Intelligent time-series forecasting framework for non-linear dynamic workload and resource prediction in cloud. 2023.
[4] Archana Naik, K. Sooda. Machine Utilization Prediction in Cloud Using Informer Model. 2024.
[5] Feiyu Zhao, Weiwei Lin, Shengsheng Lin, Haocheng Zhong, Keqin Li. TFEGRU: Time-Frequency Enhanced Gated Recurrent Unit With Attention for Cloud Workload Prediction. 2025.
[6] Lidia Kidane, Paul Townend, Thijs Metsch, Erik Elmroth. Balancing Compression and Prediction: A Hybrid Autoencoder–LSTM Framework for Cloud Workloads. 2025.
[7] Yuqing Wang, Xiao Yang. Intelligent Resource Allocation Optimization for Cloud Computing via Machine Learning. 2025.
[8] Govind Venugopal, Prithvi Kumar Badiga. Deep Reinforcement Learning for SLA-Aware Cloud Resource. 2025.
[9] Sarita Simaiya et al. A hybrid cloud load balancing and host utilization prediction method using deep learning and optimization techniques. 2024.
[10] Sasibhushan Rao Chanthati. Leveraging Artificial Intelligence for smart cloud migration, reducing cost and enhancing efficiency. 2025.
[11] Srinivasu Yalamati. Sparse Matrix Factorization for Scalable Machine Learning in Cloud Environments. 2025.
[12] Yuxuan Chen, Zhen Zhang, Yuhui Deng, Geyong Min, Lin Cui. A Combined Trend Virtual Machine Consolidation Strategy for Cloud Data Centers. 2024.
[13] Jing Zeng, Ding Ding, Kaixuan Kang, Huamao Xie, Qian Yin. Adaptive DRL-Based Virtual Machine Consolidation in Energy-Efficient Cloud Data Center. 2022.
[14] Abushafa, M. (2026). Academic conferences as transitional learning infrastructures: Supporting AI engagement and professional learning in Libyan higher education. مجلة العلوم الشاملة, 10(39), 3338-3347.
[15] Al-Souri, L. M., Abuadla, A. M., Mubarak, J. R., Al-Qablawi, S. S. K., & Makari, I. M. (2026). Developing a Critical Inquiry-Based E-Educational Model (CIEM) to Enhance Critical Thinking Skills among High School Students: A Mixed-Methods Study in the Libyan Context. Al-Farooq Journal of Sciences, 2(4), 525-540.
[16] Ali, R. S. (2025). EFL Pre-Service Teachers’ Attitudes Towards Using AI Applications. Al-Farooq Journal of Sciences, 1(1), 93-109.
[17] Othman, E. A. (2026). A Contrastive Study of Relative Clauses between English and Libyan Arabic. مجلة العلوم الشاملة, 11(41), 1219-1225.











