FSM Inspired Unconventional Hardware Watermark Using Field-Assisted SOT-MTJ

Divyanshu, Divyanshu; Kumar, Rajat; Khan, Danial; Amara, Selma; Massoud, Yehia

doi:10.1109/access.2023.3238807

Cited by 7 publications

(2 citation statements)

References 34 publications

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“…In recent years, much interest has grown in investigating the spin Hall effect (SHE) in electrons, which is a collection of relativistic SOI phenomenon 1 . The ability to generate, manipulate, and detect spin-currents has given rise to applications such as boolean logic, memories, computing, and hardware security [2][3][4] etc. Similarly, the photonic spin hall effect (PSHE) has shown various promising applications and is expected to show superior performance owing to its inherent advantage.…”

Section: Introductionmentioning

confidence: 99%

Nanophotonic Resonator Assisted Photonic Spin Hall Enhancement for Sensing Application

Goyal

Divyanshu

Massoud

2023

Preprint

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This manuscript presents a dielectric resonator structure with altered dispersion characteristics to enhance the photonic spin hall effect (PSHE). The structural parameters are optimized to enhance the PSHE at 632.8 nm operating wavelength. The thickness-dependent angular dispersion analysis is carried out to optimize the structure and obtain the exceptional points. The PSHE-induced spin splitting shows a high sensitivity to the optical thickness of the defect layer. This gives a maximum PSHE-based transverse displacement (PSHE-TD) of around 56.66 times the operating wavelength at an incidence angle of 61.68°. Moreover, the structure’s capability as a PSHE-based refractive index sensor is also evaluated. The analytical results demonstrate an average sensitivity of around 33,720 μm/RIU. The structure exhibits around five times higher PSHE-TD and approximately 150% improvement in sensitivity than the recently reported values in lossy mode resonance structures. Due to the purely dielectric material-assisted PhC resonator configurations and significantly higher PSHE-TD, the development of low-cost PSHE-based devices for commercial applications is envisaged.

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Section: Introductionmentioning

confidence: 99%

Nanophotonic Resonator Assisted Photonic Spin Hall Enhancement for Sensing Application

Goyal

Divyanshu

Massoud

2023

Preprint

View full text Add to dashboard Cite

show abstract

“…In recent years, much interest has grown in investigating the spin Hall effect (SHE) in electrons, which is a collection of relativistic SOI phenomenon 1 . The ability to generate, manipulate, and detect spin-currents has given rise to applications such as boolean logic, memories, computing, and hardware security 2 – 4 etc. Similarly, the photonic spin Hall effect (PSHE) has shown various promising applications and is expected to show superior performance owing to its inherent advantage.…”

Section: Introductionmentioning

confidence: 99%

Nanophotonic resonator assisted photonic spin Hall enhancement for sensing application

Goyal

Divyanshu

Massoud

2023

Sci Rep

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This manuscript presents a dielectric resonator structure with altered dispersion characteristics to enhance the photonic spin Hall effect (PSHE). The structural parameters are optimized to enhance the PSHE at 632.8 nm operating wavelength. The thickness-dependent angular dispersion analysis is carried out to optimize the structure and obtain the exceptional points. The PSHE-induced spin splitting shows a high sensitivity to the optical thickness of the defect layer. This gives a maximum PSHE-based transverse displacement (PSHE-TD) of around 56.66 times the operating wavelength at an incidence angle of 61.68°. Moreover, the structure’s capability as a PSHE-based refractive index sensor is also evaluated. The analytical results demonstrate an average sensitivity of around 33,720 μm/RIU. The structure exhibits around five times higher PSHE-TD and approximately 150% improvement in sensitivity than the recently reported values in lossy mode resonance structures. Due to the purely dielectric material-assisted PhC resonator configurations and significantly higher PSHE-TD, the development of low-cost PSHE-based devices for commercial applications is envisaged.

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Era of Sentinel Tech: Charting Hardware Security Landscapes Through Post-Silicon Innovation, Threat Mitigation and Future Trajectories

Srinivas,

Elango

2024

IEEE Access

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To meet the demanding requirements of VLSI design, including improved speed, reduced power consumption, and compact architectures, various IP cores from trusted and untrusted platforms are often integrated into a single System-on-Chip (SoC). However, this convergence poses a significant security challenge, as adversaries can exploit it to extract unauthorized information, compromise system performance, and obtain secret keys. Meanwhile, traditional CMOS features have limitations in addressing hardware vulnerabilities and security threats, so promising post-silicon technologies offer potential solutions. Beyond-CMOS technologies offer avenues to fortify hardware security through distinct physical properties and nontraditional computing paradigms. These advancements bolster authentication processes, enhance key generation mechanisms, ensure hardware integrity and fortify resilience against side-channel attacks, hardware Trojans and quantum-resistant cryptography in securing hardware systems. This article provides a detailed review of hardware security, encompassing the identification and mitigation of threats, the implementation of robust countermeasures, the utilization of innovative primitives, countermeasures, various methodologies and distinct features offered by emerging technologies to resist hardware threats.Moreover, strategies to address challenges, explore future directions, and outline plans for achieving further research outcomes have been put forth in this field.

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FSM Inspired Unconventional Hardware Watermark Using Field-Assisted SOT-MTJ

Cited by 7 publications

References 34 publications

Nanophotonic Resonator Assisted Photonic Spin Hall Enhancement for Sensing Application

Nanophotonic Resonator Assisted Photonic Spin Hall Enhancement for Sensing Application

Nanophotonic resonator assisted photonic spin Hall enhancement for sensing application

Era of Sentinel Tech: Charting Hardware Security Landscapes Through Post-Silicon Innovation, Threat Mitigation and Future Trajectories

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