Optimal Radio Frequency Energy Harvesting with Limited Energy Arrival Knowledge

TL;DR

This paper develops optimal policies for RF energy harvesting in wireless nodes with intermittent energy arrivals, considering scenarios with known and unknown energy state transition probabilities, using POMDP and Bayesian methods.

Contribution

It introduces a threshold-based optimal policy for RF energy harvesting with known transition probabilities and a Bayesian adaptive approach for unknown parameters.

Findings

Optimal threshold policy derived for known transition probabilities.

Bayesian adaptive method effectively estimates unknown parameters.

Numerical results demonstrate improved energy harvesting efficiency.

Abstract

In this paper, we develop optimal policies for deciding when a wireless node with radio frequency (RF) energy harvesting (EH) capabilities should try and harvest ambient RF energy. While the idea of RF-EH is appealing, it is not always beneficial to attempt to harvest energy; in environments where the ambient energy is low, nodes could consume more energy being awake with their harvesting circuits turned on than what they can extract from the ambient radio signals; it is then better to enter a sleep mode until the ambient RF energy increases. Towards this end, we consider a scenario with intermittent energy arrivals and a wireless node that wakes up for a period of time (herein called the time-slot) and harvests energy. If enough energy is harvested during the time-slot, then the harvesting is successful and excess energy is stored; however, if there does not exist enough energy the harvesting is unsuccessful and energy is lost. We assume that the ambient energy level is constant during the time-slot, and changes at slot boundaries. The energy level dynamics are described by a two-state Gilbert-Elliott Markov chain model, where the state of the Markov chain can only be observed during the harvesting action, and not when in sleep mode. Two scenarios are studied under this model. In the first scenario, we assume that we have knowledge of the transition probabilities of the Markov chain and formulate the problem as a Partially Observable Markov Decision Process (POMDP), where we find a threshold-based optimal policy. In the second scenario, we assume that we don't have any knowledge about these parameters and formulate the problem as a Bayesian adaptive POMDP; to reduce the complexity of the computations we also propose a heuristic posterior sampling algorithm. The performance of our approaches is demonstrated via numerical examples.