Energy/Performance Trade-Off in RANs with Dynamic Management of Frequency Bands

The on-demand activation of frequency bands in radio access networks can lead to a significant reduction of energy consumption, but risks to adversely impact performance. This approach to frequency band management can be applied either to a group of co-located base stations whose operators adopt a network sharing approach or to a single base station that uses multiple frequency bands. We develop a stochastic model based on the Matrix Analytic Method for the quantification of system performance and energy consumption in the case of coexisting streaming and elastic services. By computing numerical results in a specific setting, we show that the on-demand (de)activation succeeds in greatly reducing energy consumption with respect to the case in which frequency bands are always active, with limited impact on the performance experienced by users. We also show that the introduction of a hysteresis in the frequency band activation/deactivation process allows the optimization of the energy/performance tradeoff. Finally, we show that performance is not drastically altered by the burstiness of the elastic service request arrival process, and we prove that the separate analysis of streaming and elastic services provides quite optimistic results with respect to the joint analysis made possible by our model.