Assessing Absolute Distributed Data Scheduling Functions in Global Grid-Based Cloud Computing

Abstract

In global grid-based cloud computing settings, performance optimization depends on effective data scheduling. The usefulness of the absolute distributed data scheduling function in controlling resource allocation, load balancing, and data dissemination across heterogeneous cloud infrastructures is assessed in this study. By taking into account variables including data locality, processing capacity, and network latency, we evaluate the function's capacity to increase system throughput while reducing scheduling overhead. Simulations that compare to current scheduling models show gains in fault tolerance, scalability, and efficiency. High-performance cloud computing is advanced by the findings, which offer insights on optimizing distributed scheduling systems. Cloud security is crucial for attracting customers and protecting data privacy. Online attackers disrupt cloud services, leading to financial growth for cloud-based organizations. Various methodologies are reviewed to develop strong security mechanisms for cloud computing, but machine learning is not enough. This research focuses on high-level technologies like Block chain and Quantum computing with Machine Learning (ML) concepts and algorithm conceptions like deep neural networks and quantum neural networks. These models reduce attacks and increase user trust, benefiting cloud service providers. The research aims to eradicate issues and promote end-to-end protection and secrecy in the cloud environment. Cloud computing is an on-demand technology that provides various services like vast computing power, unlimited storage, and on-demand web services over the internet without the need for internal infrastructure. This research focuses on data security and privacy of cloud customers using various experiments. Cyber-attacks can be Denial of Services (DoS), Distributed Denial of Services (DDoS), Man In The Middle (MITM), and malware attacks. To protect the cloud system from cyber-attacks, deep learning is used to train an intelligent honeynet system that not only protects the system from DDoS attacks but also redirects attacks towards another direction. Another approach is the Quantum Neural Network (QNN) approach, which helps identify attack patterns and categorizes them into different classes of DoS/DDoS attacks. The QNN training process addresses slowing down of the cloud system and allows valid cloud customers to access their private data in cloud storage. Another approach is Zero Knowledge Proof (ZKP) technology, which verifies the authenticity of cloud users by polarizing photons at a specific angle. This verifier model allows cloud customers to access sensitive data and only cloud services provided by the cloud service provider. Blockchain, a powerful security framework, is used to address increasing security vulnerabilities. The Quantum-Blockchain framework incorporates the quantum superimposition principle to prevent data tampering, ensuring data privacy and data security. This research aims to address intrusion detection and data storage security challenges in the cloud computing environment using collaborative efforts from Machine Learning and advanced technologies like Quantum Computing and Blockchain. The cloud manifesto and security alliance need to be standardized to ensure privacy and security. Current research is limited due to lack of security and privacy standards between cloud vendors and users. Future studies should focus on advanced technologies like hybrid cloud, artificial intelligence, quantum computing, data mining, machine learning, big data, and cryptography to enhance security and prevent cyber-attacks.