EH and MEC are here combined to build energy-sustainable mobile networks. We consider an edge infrastructure shared among several mobile operators and equipped with a solar EH farm for energy efficiency purposes together with an edge MEC server for low-latency computation, where two main goals are pursued: (i) to maximally and fairly exploit the available resources at the edge, allotting them among BS belonging to different operators; and (ii) to decrease the monetary cost incurred by energy purchases from the power grid. To do so, we devise an online framework combining ANN-based pattern forecasting that learns energy harvesting and traffic load profiles over time, and MPC-based adaptive algorithms. Numerical results, obtained with real-world harvested energy, traffic load, and energy price traces, show that our proposal effectively reduces the amount of purchased energy from the electrical grid by more than 50% with respect to the case where no EH is considered, and by about 30% with respect to the case where the optimization is performed disregarding future energy and traffic load forecasts. Moreover, it is capable of reducing the energy consumption related to edge computation by about 20% with respect to two benchmark policies.
A Sharing Framework for Energy and Computing Resources in Multi-Operator Mobile Networks
Gambin, Angel Fernandez;Rossi, Michele
2020
Abstract
EH and MEC are here combined to build energy-sustainable mobile networks. We consider an edge infrastructure shared among several mobile operators and equipped with a solar EH farm for energy efficiency purposes together with an edge MEC server for low-latency computation, where two main goals are pursued: (i) to maximally and fairly exploit the available resources at the edge, allotting them among BS belonging to different operators; and (ii) to decrease the monetary cost incurred by energy purchases from the power grid. To do so, we devise an online framework combining ANN-based pattern forecasting that learns energy harvesting and traffic load profiles over time, and MPC-based adaptive algorithms. Numerical results, obtained with real-world harvested energy, traffic load, and energy price traces, show that our proposal effectively reduces the amount of purchased energy from the electrical grid by more than 50% with respect to the case where no EH is considered, and by about 30% with respect to the case where the optimization is performed disregarding future energy and traffic load forecasts. Moreover, it is capable of reducing the energy consumption related to edge computation by about 20% with respect to two benchmark policies.Pubblicazioni consigliate
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