Spherical Modes Driven Directional Modulation With a Compact MIMO Antenna

Zandamela, Abel; Marchetti, Nicola; Ammann, Max J.; Narbudowicz, Adam

doi:10.1109/lawp.2022.3215707

Cited by 9 publications

(10 citation statements)

References 19 publications

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“…To realize beam steering within sizeconstrained spaces, the proposed multimodal ultrathin antenna exploits the different phase variations of each radiated mode-the method is detailed in [53]-and it is based on the fact that the E v -field at a large distance ( ) kr " 3 can be expressed as a weighted sum of the far-field spherical wave pattern functions Ksmn v defined as [54] ( , , )…”

Section: Calculated Beam Steering Resultsmentioning

confidence: 99%

“…Two DM schemes are studied with the proposed antenna. In scheme 1, all the complex patterns generated by exciting each port are used as DM weights, and artificial noise is added to scramble the IQ constellations in all undesired directions [53]. In scheme 2, only the complex patterns generated by a single port are used, with no excessive artificial noise in undesired directions [31].…”

Section: Proposed Dm Schemesmentioning

confidence: 99%

See 1 more Smart Citation

Directional Modulation for Enhanced Privacy in Smartwatch Devices: Proposing a security solution compatible with Internet of Things devices [Bioelectromagnetics]

Zandamela,

Marchetti,

Narbudowicz

2024

IEEE Antennas Propag. Mag.

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his 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 energyefficient and low-cost security techniques to enhance the privacy of resource-constrained IoT devices.

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Section: Calculated Beam Steering Resultsmentioning

confidence: 99%

Section: Proposed Dm Schemesmentioning

confidence: 99%

Directional Modulation for Enhanced Privacy in Smartwatch Devices: Proposing a security solution compatible with Internet of Things devices [Bioelectromagnetics]

Zandamela,

Marchetti,

Narbudowicz

2024

IEEE Antennas Propag. Mag.

Self Cite

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“…To realize beamsteering within size-constrained space, the proposed multimodal ultra-thin antenna exploits the different phase variations of each radiated mode -the method is detailed in [53] and it is based on the fact that the ⃗ E-field at a large distance (kr → ∞) can be expressed as a weighted sum of the far-field spherical wave pattern functions ⃗ K smn defined as [54]…”

Section: Calculated Beamsteering Resultsmentioning

confidence: 99%

Directional Modulation for Enhanced Privacy in Smart Watch Devices

Zandamela,

Marchetti,

Narbudowicz

2023

Preprint

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<p>This article studies security aspects of data transmission in on-body Internet of Things (IoT) devices through the use of Directional Modulation (DM) from a smart watch integrated antenna. DM is a beamsteering-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 out-sized for many on-body IoT devices. To overcome this challenge, this study proposes multimodal ultra-thin compact antennas suitable for integration into smart watches. These antennas present advanced beamsteering capabilities that allow the implementation of DM from a low-thickness structure of up to 0.57 mm or 1/100th of wavelength at the center operating frequency. Two different DM implementations<br> (simultaneous multiport transmission and an energy-efficient single-port transmission) are tested using a multi-layer 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. </p>

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“…The smartwatch antenna in [125] demonstrated enhanced physical layer security through directional modulation using beam-steerable wrist-worn antennas. Furthermore, the antenna described in [126] utilizes the theory of spherical modes to design a 3D beam-steering MIMO antenna to enhance the physical layer security. While the antennas in [125], [126] are tailored for Sub-6 GHz frequencies (5.57 GHz and 5.75 GHz), the implementation of a similar beam-steerable design concept holds the potential for enhancing physical layer security in Sub-GHz wrist-worn antennas, facilitating secure communication over LoRaWAN, NB-IoT, and Sigfox wireless technologies.…”

Section: Future Perspectivesmentioning

confidence: 99%

Sub-GHz Wrist-Worn Antennas for Wireless Sensing Applications: A Review

Kumar,

Moloudian,

Simorangkir

et al. 2024

IEEE Open J. Antennas Propag.

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With recent advances in wearable wrist-worn wireless sensing applications, the demand for smartwatches and wristbands is rapidly increasing due to their widespread adoption in applications such as smart health monitoring, security, and fitness tracking. Currently, these devices primarily operate in the 2.45 GHz band, leveraging the availability of Bluetooth and Wi-Fi wireless technologies. However, the use of 433 MHz, 868 MHz, 915 MHz, 923 MHz) for wearable systems has also gained interest due to the emergence of wireless technologies like long-range wide area network (LoRaWAN), narrowband-IoT (NB-IoT) and Sigfox, which offer the potential for long-range wireless communications and sensing applications. In recent times, there has been a notable surge in the commercial production of a variety of Sub-GHz wrist-worn wireless sensing devices for health monitoring and tracking applications. Nevertheless, communications at Sub-GHz frequencies present significant challenges in antenna design, primarily due to the practical size constraints of wrist-worn devices and the necessity for using electrically small antennas. This paper meticulously reviews wrist-worn Sub-GHz antennas reported in the literature, analyzing key antenna parameters such as antenna topology, size, impedance bandwidth, peak realized gain, radiation efficiency, and specific absorption rate (SAR). Additionally, it underlines antenna design challenges, limitations, current trends, and presents potential future perspectives. To the best of the author's knowledge, there is currently no existing literature comprehensively reviewing Sub-GHz wristworn antennas. Therefore, this paper represents the inaugural effort to provide a comprehensive review in this specific domain.

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Spherical Modes Driven Directional Modulation With a Compact MIMO Antenna

Cited by 9 publications

References 19 publications

Directional Modulation for Enhanced Privacy in Smartwatch Devices: Proposing a security solution compatible with Internet of Things devices [Bioelectromagnetics]

Directional Modulation for Enhanced Privacy in Smartwatch Devices: Proposing a security solution compatible with Internet of Things devices [Bioelectromagnetics]

Directional Modulation for Enhanced Privacy in Smart Watch Devices

Sub-GHz Wrist-Worn Antennas for Wireless Sensing Applications: A Review

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