Somayyeh Taheri scite author profile

Nowadays, in the age of big data and more data generation, there is a growing need to store and process large-scale data in real-time which has led to the deployment of cloud computing. The significant growth of the DC market has led to its rapid growth of power consumption as well as cost. By 2025, the DC market is predicted to account Abstract Nowadays, the fast rate of technological advances, such as cloud computing, has led to the rapid growth of the Data Center (DC) market as well as their power consumption. Therefore, DC power management has become increasingly important. While power forecasting can greatly help DC power management and reduce energy consumption and cost. Power forecasting predicts the potential energy failures or sudden fluctuations in power intake from utility grid. However, it is hard especially when variable renewable energies (RE) as well as free cooling such as air economizers are also used. Geo-distributed DCs face an even harder issue: since in addition to local conditions, the overall status of the entire system of collaborating DCs should also be considered. The conventional approach to forecast power consumption in such complicated cases is to construct a closed form formula for power. This is a tedious task that not only needs expert knowledge of how each single cooling or RE system works, but also needs to be done individually for each DC and repeated all over again for each new DC or change of equipment. One alternative is to use machine learning so as to learn over time how the system consumes power in varying conditions of weather, workload, and internal structure in multiple geo-distributed locations. However, due to the wide range of effective features as well as trade-off between the accuracy and processing overhead, one important issue is to obtain an optimal set of more influential features. In this study, we analyze the correlation among geo-distributed DC power patterns with their weather parameters (based on different DC situations and infrastructure) and extract a set of influential features. Afterward, we apply the obtained features to provide a power consumption forecasting model that predict the power pattern of each collaborating DC in a cloud. Our experimental results show that the proposed prediction model for geo-distributed DCs reaches the accuracy of 87.2%.

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Tariff-aware power management for reducing the break-even time of on-site solar power installation in data center

Taheri

Goudarzi

2020

Renewable Energy Focus

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Providing RS Participation for Geo-Distributed Data Centers Using Deep Learning-Based Power Prediction

Taheri

Goudarzi

Yoshie

2019

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Somayyeh Taheri

Infrastructure Aware Heterogeneous-Workloads Scheduling for Data Center Energy Cost Minimization

Learning-based power prediction for geo-distributed Data Centers: weather parameter analysis

Tariff-aware power management for reducing the break-even time of on-site solar power installation in data center

Providing RS Participation for Geo-Distributed Data Centers Using Deep Learning-Based Power Prediction

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