Optimal Transmit Antenna Deployment and Power Allocation for Wireless Power Supply in an Indoor Space

As Internet of Things (IoT) devices proliferate, sustainable methods for powering them are becoming indispensable. The wireless provision of power enables battery-free operation and is crucial for complying with weight and size restrictions. For the energy harvesting components of these devices to be small, a high operating frequency is necessary. In conjunction with an electrically large antenna, the receivers may be located in the radiating near-field (Fresnel) region, e.g., in indoor scenarios. In this paper, we propose a wireless power transfer system to ensure a reliable supply of power to an arbitrary number of mobile, low-power, and single-antenna receivers, which are located in a three-dimensional cuboid room. To this end, we formulate a max-min optimisation problem to determine the optimal allocation of transmit power among an infinite number of radiating elements of the system's transmit antenna array. Thereby, the optimal deployment, i.e, the set of transmit antenna positions that are allocated non-zero transmit power according to the optimal allocation, is obtained implicitly. Generally, the set of transmit antenna positions corresponding to the optimal deployment has Lebesgue measure zero and the closure of the set has empty interior. Moreover, for a one-dimensional transmit antenna array, the set of transmit antenna positions is proven to be finite. The proposed optimal solution is validated through simulation. Simulation results indicate that the optimal deployment requires a finite number of transmit antennas and depends on the geometry of the environment and the dimensionality of the transmit antenna array. The robustness of the solution, which is obtained under a line-of-sight (LoS) assumption between the transmitter and receiver, is assessed in an isotropic scattering environment containing a strong LoS component.

[1]  J. S. Ho,et al.  Microwave-Enabled Wearables: Underpinning Technologies, Integration Platforms, and Next-Generation Roadmap , 2023, IEEE Journal of Microwaves.

[2]  F. Alimenti,et al.  Next-Generation IoT Devices: Sustainable Eco-Friendly Manufacturing, Energy Harvesting, and Wireless Connectivity , 2023, IEEE Journal of Microwaves.

[3]  P. Solanki,et al.  Internet of things (IoT) in nano-integrated wearable biosensor devices for healthcare applications , 2022, Biosensors and Bioelectronics: X.

[4]  Y. Eldar,et al.  6G Wireless Communications: From Far-Field Beam Steering to Near-Field Beam Focusing , 2022, IEEE Communications Magazine.

[5]  Shi Jin,et al.  Near-Field Modeling and Performance Analysis of Modular Extremely Large-Scale Array Communications , 2022, IEEE Communications Letters.

[6]  Bruno Clerckx,et al.  Foundations of Wireless Information and Power Transfer: Theory, Prototypes, and Experiments , 2022, Proceedings of the IEEE.

[7]  Yonina C. Eldar,et al.  Near-Field Wireless Power Transfer for 6G Internet of Everything Mobile Networks: Opportunities and Challenges , 2021, IEEE Communications Magazine.

[8]  Davide Dardari,et al.  Beam Focusing for Near-Field Multi-User MIMO Communications , 2021, IEEE Transactions on Wireless Communications.

[9]  Davide Dardari,et al.  Holographic Communication Using Intelligent Surfaces , 2020, IEEE Communications Magazine.

[10]  Mahmoud Wagih,et al.  Millimeter-Wave Power Harvesting: A Review , 2020, IEEE Open Journal of Antennas and Propagation.

[11]  Emil Björnson,et al.  Rayleigh Fading Modeling and Channel Hardening for Reconfigurable Intelligent Surfaces , 2020, IEEE Wireless Communications Letters.

[12]  Heedong Do,et al.  Terahertz Line-Of-Sight MIMO Communication: Theory and Practical Challenges , 2020, IEEE Commun. Mag..

[13]  Reza Vahidnia,et al.  Wearables and the Internet of Things (IoT), Applications, Opportunities, and Challenges: A Survey , 2020, IEEE Access.

[14]  T. Marzetta,et al.  Spatially-Stationary Model for Holographic MIMO Small-Scale Fading , 2019, IEEE Journal on Selected Areas in Communications.

[15]  Derrick Wing Kwan Ng,et al.  Conditional Capacity and Transmit Signal Design for SWIPT Systems With Multiple Nonlinear Energy Harvesting Receivers , 2019, IEEE Transactions on Communications.

[16]  Shlomo Shamai,et al.  When are discrete channel inputs optimal? — Optimization techniques and some new results , 2018, 2018 52nd Annual Conference on Information Sciences and Systems (CISS).

[17]  Emil Björnson,et al.  Massive MIMO Networks: Spectral, Energy, and Hardware Efficiency , 2018, Found. Trends Signal Process..

[18]  Nitakshi Goyal,et al.  General Topology-I , 2017 .

[19]  Stephen P. Boyd,et al.  A Rewriting System for Convex Optimization Problems , 2017, J. Control. Decis..

[20]  Fredrik Rusek,et al.  Beyond Massive MIMO: The Potential of Data Transmission With Large Intelligent Surfaces , 2017, IEEE Transactions on Signal Processing.

[21]  Michael Schwartz,et al.  Wearables and the Internet of Things for Health: Wearable, Interconnected Devices Promise More Efficient and Comprehensive Health Care , 2016, IEEE Pulse.

[22]  Stephen P. Boyd,et al.  CVXPY: A Python-Embedded Modeling Language for Convex Optimization , 2016, J. Mach. Learn. Res..

[23]  Vivek K Goyal,et al.  Foundations of Signal Processing , 2014 .

[24]  R. Cooke Real and Complex Analysis , 2011 .

[25]  Stephen P. Boyd,et al.  Convex Optimization , 2004, IEEE Transactions on Automatic Control.

[26]  David Tse,et al.  Fundamentals of Wireless Communication , 2005 .

[27]  Joel G. Smith,et al.  The Information Capacity of Amplitude- and Variance-Constrained Scalar Gaussian Channels , 1971, Inf. Control..

[28]  W. Hager,et al.  and s , 2019, Shallow Water Hydraulics.

[29]  Hyunjoong Kim,et al.  Functional Analysis I , 2017 .

[30]  Harold R. Parks,et al.  A Primer of Real Analytic Functions , 1992 .