Abstract
In this interdisciplinary work, a low-power varactor-tunable frequency selective surface is presented for use with a multiplexed remote sensor system. Combined with a low power sensor and control system, voltage biasing of the proposed frequency selective surface panel can be used to modulate the center frequency of a reflection peak, which in turn may be detected by remote interrogation through a radar system. The control board and frequency selective surface were found to draw only $200~\mu \text{A}$ of current during typical operation from two 3V CR2032 button batteries, enabling continuous operation for weeks at a time (even longer if operated in wake-up mode) when used in conjunction with a suitably low power sensor. Centered at 3 GHz, the backscatter peak can be modulated across a range of 200 MHz, and the combined system was shown to successfully differentiate between various concentrations of ammonia under test conditions.
Highlights
Low-power remote wireless sensing and networking is a critical technology for numerous emerging applications, from environmental monitoring to Internet of Things (IoT) solutions [1]–[5]
As visible from this curve, we found the predicted range of reactances at the 3 GHz target center frequency covered over 50, while maintaining a low resistance of around 0.5 [36]
The frequency selective surface (FSS) was illuminated identically to the isolated panel test discussed above, using the same custom WR-284 fed pyramidal horn antenna connected to a Vector Network Analyzer (VNA)
Summary
JENKINS 1, (Student Member, IEEE), MICAH D. GREGORY2, (Member, IEEE), LEN CARDILLO3, BENJAMIN R. WERNER1, (Life Senior Member, IEEE), AND DOUGLAS H.
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