Energy Beamforming for RF Wireless Power Transfer With Dynamic Metasurface Antennas

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Abstract

Radio frequency (RF) wireless power transfer (WPT) is a promising technology for charging the Internet of Things. Practical RF-WPT systems usually require energy beamforming (EB), which can compensate for the severe propagation loss by directing beams toward the devices. The EB flexibility depends on the transmitter architecture, existing a trade-off between cost/complexity and degrees of freedom. Thus, simpler architectures such as dynamic metasurface antennas (DMAs) are gaining attention. Herein, we consider an RF-WPT system with a transmit DMA for meeting the energy harvesting requirements of multiple devices and formulate an optimization problem for the minimum-power design. First, we provide a mathematical model to capture the frequency-dependant signal propagation effect in the DMA architecture. Next, we propose a solution based on semi-definite programming and alternating optimization. Results show that a DMA-based structure can outperform a fully-digital implementation and that the required transmit power decreases with the antenna array size, while it increases and remains almost constant with frequency in DMA and FD, respectively.

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APA

Azarbahram, A., Lopez, O. L. A., Souza, R. D., Zhang, R., & Latva-Aho, M. (2024). Energy Beamforming for RF Wireless Power Transfer With Dynamic Metasurface Antennas. IEEE Wireless Communications Letters, 13(3), 781–785. https://doi.org/10.1109/LWC.2023.3343563

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