Robust Resource Allocation for MIMO Wireless Powered Communication Networks Based on a Non-linear EH Model (1609.03836v2)

Abstract: In this paper, we consider a multiple-input multiple-output wireless powered communication network (MIMO-WPCN), where multiple users harvest energy from a dedicated power station in order to be able to transmit their information signals to an information receiving station. Employing a practical non-linear energy harvesting (EH) model, we propose a joint time allocation and power control scheme, which takes into account the uncertainty regarding the channel state information (CSI) and provides robustness against imperfect CSI knowledge. In particular, we formulate two non-convex optimization problems for different objectives, namely system sum throughput maximization and maximization of the minimum individual throughput across all wireless powered users. To overcome the non-convexity, we apply several transformations along with a one-dimensional search to obtain an efficient resource allocation algorithm. Numerical results reveal that a significant performance gain can be achieved when the resource allocation is designed based on the adopted non-linear EH model instead of the conventional linear EH model. Besides, unlike a non-robust baseline scheme designed for perfect CSI, the proposed resource allocation schemes are shown to be robust against imperfect CSI knowledge.

• The paper presents non-convex optimization formulations to maximize total throughput and ensure fairness under a realistic non-linear energy harvesting model.
• It develops efficient allocation algorithms using convex approximations and one-dimensional search techniques to overcome channel state imperfections.
• Simulations confirm that the proposed schemes outperform traditional linear models, achieving a favorable trade-off between system efficiency and fairness.

An Examination of Robust Resource Allocation for MIMO Wireless Powered Communication Networks

The paper "Robust Resource Allocation for MIMO Wireless Powered Communication Networks Based on a Non-linear EH Model" by Boshkovska et al. presents an in-depth exploration of effective resource allocation strategies within Multiple-input Multiple-output Wireless Powered Communication Networks (MIMO-WPCNs). The paper is particularly focused on leveraging a non-linear energy harvesting (EH) model, which more accurately reflects real-world conditions compared to traditional linear models typically employed in similar analyses.

The authors acknowledge the growing interest in wireless energy transfer (WET) as a sustainable means of powering low-power wireless sensor networks. Within this context, they address existing challenges related to efficient power and time resource allocation due to path loss and other factors impacting energy distribution, particularly given the non-linearity characteristic of real EH circuits.

Key Contributions and Methods

The paper contributes several significant advances to the field:

1. Optimization Formulation: It defines two non-convex optimization problems: one aimed at maximizing the total system throughput (max-sum) and the other at achieving fairness by maximizing the minimum individual throughput (max-min) among all users. These formulations capture the non-linear characteristics of end-to-end WET, departing from the simpler linear models.
2. Algorithm Development: To tackle non-convexity, the paper outlines transformations and solutions employing convex approximation methods and one-dimensional searches to arrive at efficient resource allocation algorithms. The paper's robust designs consider imperfections in channel state information (CSI), using both a deterministic model for CSI errors and various analytical methods for addressing these issues.
3. Empirical Validation: Through simulations, the authors demonstrate the performance superiority of their proposed allocation schemes, which are more efficient and resilient against imperfect CSI compared to baseline approaches dependent on linear models. These simulations reveal important trade-offs between maximizing throughput and ensuring fairness—key considerations for practical implementation.

Implications and Future Research

The implications of this work are significant for both theoretical and practical perspectives. The incorporation of non-linear EH characteristics into resource allocation models provides a more reliable foundation for system design in real-life applications, promising enhanced efficacy in energy-constrained communication environments.

The theoretical implications extend to the demonstrated optimality of energy beamforming and water-filling power distribution strategies under imperfect CSI conditions, which may spur further exploration into more complex network environments and distribution models. On a practical level, the enhancement of wireless communication infrastructures could directly improve technology deployment and sensor network sustainability, particularly in remote or resource-limited locations.

In future research, potential avenues may include expanding the considered network topologies, enhancing the robustness of EH models, and refining optimization techniques to accommodate more diverse environmental factors and additional multi-user scenarios. Integrating machine learning methods for real-time adjustment and prediction could also provide substantial benefits in dynamically changing network environments.

Overall, Boshkovska et al. successfully establish a foundational approach in resource allocation for MIMO-WPCNs using non-linear EH models, setting a path for continued innovation and optimization in wireless power communications.