Directional Modulation for Enhanced Privacy in Smartwatch Devices: Proposing a security solution compatible with Internet of Things devices [Bioelectromagnetics]
IF 4.2 4区 计算机科学Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
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引用次数: 0
Abstract
This article studies the security aspects of data transmission in on-body Internet of Things (IoT) devices through the use of Directional Modulation (DM) from a smartwatch integrated antenna. DM is a beam steering-based Physical Layer Security (PLS) method used to transmit baseband constellations to known secure locations while simultaneously scrambling them in other directions. However, in the state of the art, DM is implemented using large arrays, which are outsized for many on-body IoT devices. To overcome this challenge, this study proposes multimodal ultrathin compact antennas suitable for integration into smartwatches. These antennas present advanced beam steering capabilities that allow the implementation of DM from a low-thickness structure of up to 0.57 mm or 1/100th of the wavelength at the center operating frequency. Two different DM implementations (simultaneous multiport transmission and an energy-efficient single-port transmission) are tested using a multilayer phantom. Overall, secure steerable transmissions are realized, and experimental verifications are carried out to validate the proposed concept. Ultimately, this article demonstrates the feasibility of applying new energy-efficient and low-cost security techniques to enhance the privacy of resource-constrained IoT devices.
期刊介绍:
IEEE Antennas and Propagation Magazine actively solicits feature articles that describe engineering activities taking place in industry, government, and universities. All feature articles are subject to peer review. Emphasis is placed on providing the reader with a general understanding of either a particular subject or of the technical challenges being addressed by various organizations, as well as their capabilities to cope with these challenges. Articles presenting new results, review, tutorial, and historical articles are welcome, as are articles describing examples of good engineering. The technical field of interest of the Magazine is the same as the IEEE Antennas and Propagation Society, and includes the following: antennas, including analysis, design, development, measurement, and testing; radiation, propagation, and the interaction of electromagnetic waves with discrete and continuous media; and applications and systems pertinent to antennas, propagation, and sensing, such as applied optics, millimeter- and sub-millimeter-wave techniques, antenna signal processing and control, radio astronomy, and propagation and radiation aspects of terrestrial and space-based communication, including wireless, mobile, satellite, and telecommunications.