Machine Learning Algorithms for Efficient Storage Management in Resource-Limited Systems: Techniques and Applications

Authors

  • By Bhavani Krothapalli Google, USA Author
  • Lavanya Shanmugam Tata Consultancy Services, USA Author
  • Subhan Baba Mohammed Data Solutions Inc, USA Author

Keywords:

Machine Learning, Resource-Constrained Systems

Abstract

The ever-increasing volume of data generated across various domains continues to pose significant challenges for storage management, particularly in resource-limited systems. These systems, often characterized by low processing power, limited memory capacity, and restricted energy availability, require innovative approaches to optimize storage utilization and enhance performance. This research investigates the application of Machine Learning (ML) algorithms as a potential solution for efficient storage management in such resource-constrained environments.

The paper presents a comprehensive analysis of various ML techniques that can be leveraged to address the unique storage management challenges faced by resource-limited systems. We delve into supervised learning algorithms like Support Vector Machines (SVMs) and K-Nearest Neighbors (KNN) for data classification and identification of frequently accessed data. This enables the implementation of effective caching strategies, prioritizing the storage of frequently used data for faster retrieval while minimizing resource consumption. Furthermore, unsupervised learning algorithms such as K-Means clustering and Principal Component Analysis (PCA) can be employed for data compression and dimensionality reduction. These techniques aim to reduce the storage footprint of data without sacrificing its integrity, a critical aspect for resource-constrained systems.

Reinforcement Learning (RL) offers a promising avenue for dynamic storage management. RL algorithms can be trained on historical data and system usage patterns to learn optimal storage allocation strategies. By continuously interacting with the environment and receiving feedback on the performance of its decisions, the RL agent can adapt its storage allocation policies in real-time, ensuring efficient resource utilization based on the prevailing workload demands.

Predictive analytics, powered by supervised or unsupervised learning algorithms, plays a crucial role in proactive storage management. By analyzing historical access patterns and resource utilization trends, these techniques can predict future storage needs. This allows for preemptive resource allocation and data migration, preventing storage bottlenecks and ensuring smooth system operation.

The paper explores various applications of ML-powered storage management in resource-constrained systems. In the context of the Internet of Things (IoT), where resource-limited devices generate continuous data streams, ML algorithms can be used to prioritize and compress sensor data, optimizing storage usage on these devices. Similarly, in edge computing environments, where data processing often occurs at the network's periphery due to bandwidth limitations, ML-based storage management can facilitate the efficient storage and retrieval of data at the edge, enabling real-time decision-making and fast response times.

We delve into the specific challenges associated with implementing ML algorithms in resource-limited systems. The high computational cost of training ML models and the limited memory availability can pose significant roadblocks. To address these concerns, the paper explores techniques for lightweight model design, efficient training algorithms, and model compression strategies. Additionally, the importance of transfer learning in leveraging pre-trained models and adapting them for specific storage management tasks in resource-constrained environments is emphasized.

The paper acknowledges the ongoing research efforts in this domain and identifies several key areas for future exploration. One promising direction lies in the integration of ML algorithms with other storage management techniques, such as data deduplication and tiering. Additionally, research on federated learning can facilitate the collaborative training of models across multiple resource-limited devices, leveraging collective intelligence for enhanced storage management capabilities. Finally, the ethical implications of utilizing ML for storage management, such as potential bias and data privacy concerns, necessitate further investigation to ensure responsible and ethical implementation of these techniques.

By effectively leveraging the power of Machine Learning, this research paves the way for significant advancements in storage management for resource-constrained systems. The proposed techniques hold immense potential to optimize storage utilization, enhance performance, and facilitate efficient data processing in various applications across diverse domains.

Downloads

Download data is not yet available.

References

Machireddy, Jeshwanth Reddy. "Data-Driven Insights: Analyzing the Effects of Underutilized HRAs and HSAs on Healthcare Spending and Insurance Efficiency." Journal of Bioinformatics and Artificial Intelligence 1.1 (2021): 450-470.

M. A. Jalali, A. H. GANDOMI, M. H. Tajdini, S. ONN, and H. PIRZADA, "Resource Allocation in Fog Computing for Internet of Things: A Review," IEEE Access, vol. 6, pp. 57009-57028, 2018. [doi: 10.1109/ACCESS.2018.2869212]

V. Mnih, K. Kavukcuoglu, D. Silver, A. Graves, I. Sutskever, and J. Dean, "Playing games with deep reinforcement learning," arXiv preprint arXiv:1312.5905, 2013.

Y. Mao, C. Youn, J. Zhang, K. Srinivasan, R. Khanna, and M. Swami, "A Survey on Cloud Computing for Internet-of-Things: Architecture, Challenges, and Applications," IEEE Internet of Things Journal, vol. 4, no. 2, pp. 1646-1664, April 2017. [doi: 10.1109/JIOT.2017.2664423]

Z. Zhou, M. Chen, X. Li, X. Mao, J. Zhang, and S. Pan, "Federated Learning for Edge Computing in Mobile IoT," IEEE Communications Magazine, vol. 58, no. 1, pp. 126-132, Jan. 2020. [doi: 10.1109/MCOM.2019.1900234]

H. Guo, Y. Shen, T. Zhao, Y. Mao, J. Zhang, and S. Pan, "Lightweight Deep Learning for Resource-Constrained IoT Devices," IEEE Access, vol. 7, pp. 140377-140388, 2019. [doi: 10.1109/ACCESS.2019.2947222]

A. Ghasemi and S. Sheikoleslami, "A Survey on Deep Learning Techniques for Network Intrusion Detection," IEEE Communications Surveys & Tutorials, vol. 21, no. 4, pp. 2743-2771, Fourthquarter 2019. [doi: 10.1109/COMS.2019.0873927]

M. Carmean, P. Yan, and E. DeBenedictis, "Compressing Neural Networks with Pruning," IEEE Transactions on Very Large Scale Integration (VLSI) Systems, vol. 24, no. 4, pp. 1898-1908, April 2016. [doi: 10.1109/TVLSI.2015.2498492]

J. Wu, C. Leng, Y. Wang, Q. Hu, and J. Cheng, "Quantized Ternary Neural Networks," arXiv preprint arXiv:1808.00202, 2018.

G. Hinton, O. Dean, S. Shan, and D. Engle, "Distilling the Knowledge in a Neural Network," arXiv preprint arXiv:1503.02531, 2015.

B. Li, H. Cai, X. Wang, Y. Zhu, and L. Song, "Latency Optimization for DNN-based Image Classification on Edge Devices," arXiv preprint arXiv:1712.05638, 2017.

J. Koneˇcnỳ, H. Ramsauer, M. Schwarz, A. Rippel, and P. Vanhoucke, "Full Convolutional Architectures for Semantic Segmentation," *arXiv preprint arXiv.

Downloads

Published

13-03-2023

How to Cite

[1]
By Bhavani Krothapalli, Lavanya Shanmugam, and Subhan Baba Mohammed, “Machine Learning Algorithms for Efficient Storage Management in Resource-Limited Systems: Techniques and Applications”, J. of Artificial Int. Research and App., vol. 3, no. 1, pp. 406–442, Mar. 2023, Accessed: Dec. 23, 2024. [Online]. Available: https://aimlstudies.co.uk/index.php/jaira/article/view/154

Similar Articles

31-40 of 236

You may also start an advanced similarity search for this article.