Wireless Energy Harvesting for Autonomous Reconfigurable Intelligent Surfaces

In the current contribution, we examine the feasibility of fully-energy-autonomous operation of reconfigurable intelligent surfaces (RIS) through wireless energy harvesting (EH) from incident information signals. Towards this, we first identify the main RIS energy-consuming components and present a suitable and accurate energy-consumption model that is based on the recently proposed integrated controller architecture and includes the energy consumption needed for channel estimation. Building on this model, we introduce a novel RIS architecture that enables EH through RIS unit-cell (UC) splitting. Subsequently, we introduce an EH policy, where a subset of the UCs is used for beamsteering, while the remaining UCs absorb energy. In particular, we formulate a subset al.ocation optimization problem that aims at maximizing the signal-to-noise ratio (SNR) at the receiver without violating the RIS's energy consumption demands. As a problem solution, we present low-complexity heuristic algorithms. The presented numerical results reveal the feasibility of the proposed architecture and the efficiency of the presented algorithms with respect to both the optimal and very high-complexity brute-force approach and the one corresponding to random subset selection. Furthermore, the results reveal how important the placement of the RIS as close to the transmitter as possible is, for increasing the harvesting effectiveness.

Automated summary

In this paper, the feasibility of fully-energy-autonomous operation of reconfigurable intelligent surfaces (RIS) through wireless energy harvesting (EH) is examined. A suitable energy-consumption model is proposed, based on the integrated controller architecture, to identify the main RIS energy-consuming components and include the energy consumption needed for channel estimation. A novel RIS architecture is introduced, enabling EH through RIS unit-cell (UC) splitting. An EH policy is presented, where a subset of the UCs is used for beamsteering while the remaining UCs absorb energy. The results demonstrate the feasibility of the proposed architecture and the efficiency of the presented algorithms.