Energy-Efficient Physical Layer Security for Wearable IoT Devices

TL;DR

This paper introduces an energy-efficient directional modulation scheme for wearable IoT devices, demonstrating secure, steerable wireless transmissions with low error rates in realistic on-body scenarios.

Contribution

It presents a novel, energy-efficient DM scheme using a compact MIMO antenna for secure on-body communications in wearable IoT devices.

Findings

Achieves steerable secure transmissions with low BER at desired directions.

Eavesdroppers face high error rates, ensuring security.

Some antenna configurations offer low BER with reduced size, despite higher side-lobes.

Abstract

This work proposes an energy-efficient Directional Modulation (DM) scheme for on-body Internet of Things (IoT) devices. DM performance is tested using a 5-port stacked-patch MIMO antenna under two scenarios: a free space case and using a four-layer human forearm phantom to simulate the user's wrist. It is demonstrated that the scheme achieves steerable secure transmissions across the entire horizontal plane. With a low Bit Error Rate (BER) of ${1.5\times10^{-5}}$ at the desired directions, eavesdroppers experience a high error rate of up to ${0.498}$. Furthermore, this work investigates the DM performance using a subset of the stacked patches in the MIMO antenna, revealing that some combinations achieve a low BER performance using a lower antenna profile, albeit high side-lobes of BER${<10^{-2}}$ seen outside the desired region. Overall, the solution is proposed as a good candidate to enable secure wireless communications in emerging wearable IoT devices that are subject to size and energy constraints.