Abstract
This paper presents the design and implementation of two front-ends for RF (Radio Frequency) energy harvesting, comparing them with the commercial one—P2110 by Powercast Co. (Pittsburgh, PA, USA) Both devices are implemented on a discrete element board with microstrip lines combined with lumped elements and are optimized for two different input power levels (−10 dBm and 10 dBm, respectively), at the GSM900 frequencies. The load has been fixed at 5kΩ, after a load-pull analysis on systems. The rectifiers stages implement two different Schottky diodes in two different topologies: a single diode and a 2-stage Dickson’s charge pump. The second one is compared with the P2110 by generating RF fields at 915 MHz with the Powercast Powerspot. The main aim of this work is to design simple and efficient low-cost devices, which can be used as a power supply for low-power autonomous sensors, with better performances than the current solutions of state-of-the-art equipment, providing an acceptable voltage level on the load. Measurements have been conducted for input power range −20 dBm up to 10 dBm; the best power conversion efficiency (PCE) is obtained with the second design, which reaches a value of 70% at 915 MHz. In particular, the proposed device exhibited better performance compared to the P2110 commercial device, allowing a maximum distance of operation of up to 22 meters from the dedicated RF power source, making it suitable even for IoT (Internet of Things) applications.
Highlights
In recent years, the great use of low-power autonomous systems and sensors [1,2,3,4,5,6] increased the need for self-sustainable devices, which are capable of harvesting and using energy from the environment, for those that need a continuous power supply [7,8,9,10,11,12,13]
Since this energy is available in many different forms, some works focused on multi-source energy harvesters, combining techniques to compensate for this lack of retrievable energy [11]
We have presented the design of two RF energy harvesting circuits, compared with the commercial one—P2110 by Powercast Co
Summary
The great use of low-power autonomous systems and sensors [1,2,3,4,5,6] increased the need for self-sustainable devices, which are capable of harvesting and using energy from the environment, for those that need a continuous power supply (such as human health monitoring systems) [7,8,9,10,11,12,13] These devices, such as low-voltage front-ends for photomultiplier [4] or monitoring systems for buildings with a low power consumption [6], can use energy scavenged from the environment, which is typically poor but enough to ensure the system functionality. Despite their efficiency level (that usually reaches 50%), these have a complex design and are not simple to realize
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