The study aimed to develop models and methods for analysing infrastructure performance in cloud environments that consider the complexity and dynamism of modern IT systems. The development of adaptive resource management models capable of responding to changing loads in real time was emphasised. New methods of process optimisation were developed, including the use of artificial neural networks for load forecasting and dynamic resource allocation. Solutions for efficient management of computing and storage capacities were modelled and simulated. The use of adaptive models based on neural network technologies has increased the accuracy of load forecasting by up to 95% and reduced costs by 20% through the automation of resource management. Practical experiments conducted in the Amazon Web Services (AWS) and Microsoft Azure environments confirmed the effectiveness of the approaches under various load conditions. These results help to improve the stability of cloud services, reducing the risk of overload, downtime and data loss. The proposed models are universal and can be applied in various industries, including the financial sector, e-commerce and healthcare, which allows them to effectively solve the problems faced by modern information systems. The findings of the study highlight the importance of integrating artificial intelligence into performance management, which ensures the flexibility and scalability of cloud environments. This creates new opportunities to optimise processes, improve service quality and reduce operating costs, creating the basis for further research and development in the field of cloud computing.

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