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1. Physical Layer Encryption for Wireless OFDM Communication Systems

   https://doi.org/10.1007/s41635-020-00097-8  

   Jacovic, Marko ; Juretus, Kyle ; Kandasamy, Nagarajan ; Savidis, Ioannis ; Dandekar, Kapil R. ( July 2020 , Journal of Hardware and Systems Security)

   Our everyday lives are impacted by the widespread adoption of wireless communication systems integral to residential, industrial, and commercial settings. Devices must be secure and reliable to support the emergence of large scale heterogeneous networks. Higher layer encryption techniques such as Wi-Fi Protected Access (WPA/WPA2) are vulnerable to threats, including even the latest WPA3 release. Physical layer security leverages existing components of the physical or PHY layer to provide a low-complexity solution appropriate for wireless devices. This work presents a PHY layer encryption technique based on frequency induction for Orthogonal Frequency Division Multiplexing (OFDM) signals to increase security against eavesdroppers. The secure transceiver consists of a key to frequency shift mapper, encryption module, and modified synchronizer for decryption. The system has been implemented on a Virtex-7 FPGA. The additional hardware overhead incurred on the Virtex-7 for both the transmitter and the receiver is low. Both simulation and hardware evaluation results demonstrate that the proposed system is capable of providing secure communication from an eavesdropper with no decrease in performance as compared with the baseline case of a standard OFDM transceiver. The techniques developed in this paper provide greater security to OFDM-based wireless communication systems. 

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2. Time-Varying Metamaterial-Enabled Directional Modulation Schemes for Physical Layer Security in Wireless Communication Links

   https://doi.org/10.1145/3513088  

   Nooraiepour, Alireza ; Vosoughitabar, Shaghayegh ; Wu, Chung-Tse Michael ; Bajwa, Waheed U. ; Mandayam, Narayan B. ( January 2022 , ACM Journal on Emerging Technologies in Computing Systems)

   Novel transmission schemes, enabled by recent advances in the fields of metamaterial (MTM), leaky-wave antenna (LWA) and directional modulation, are proposed for enhancing the physical layer (PHY) security. MTM-LWAs, which offer compact, integrated, and cost-effective alternatives to the classic phased-array architectures, are particularly of interest for emerging wireless communication systems including Internet-of-Things (IoT). The proposed secure schemes are devised to accomplish the functionalities of directional modulation (DM) transmitters for orthogonal frequency-division multiplexing (OFDM) and non-contiguous (NC) OFDM transmissions, while enjoying the implementation benefits of MTM-LWAs. Specifically, transmitter architectures based on the idea of time-modulated MTM-LWA have been put forth as a promising solution for PHY security for the first time. The PHY security for the proposed schemes are investigated from the point of view of both passive and active attacks where an adversary aims to decode secret information and feed spurious data to the legitimate receiver, respectively. Numerical simulations reveal that even when the adversary employs sophisticated state-of-the-art deep learning based attacks, the proposed transmission schemes are resistant to these attacks and reliably guarantee system security. 

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3. Physical gate based preamble obfuscation for securing wireless communication

   https://doi.org/10.1109/ICCNC.2017.7876142  

   Chacko, James ; Juretus, Kyle ; Jacovic, Marko ; Sahin, Cem ; Kandasamy, Nagarajan ; Savidis, Ioannis ; Dandekar, Kapil ( January 2017 , 2017 International Conference on Computing, Networking and Communications (ICNC))

   As wireless devices hold prominent roles as means of communication, developing strong security methods against sophisticated cyber-attacks has become paramount. A novel physical layer based technique for securing wireless communication between the transmitter and receiver is described in this paper. The technique involves obfuscating the preamble data of the baseband signal through unique keys that are independently generated at both the transmitter and the receiver based on channel characteristics known only to the pair. The obfuscation technique is developed on the Drexel Software Defined Communication testbed on a Xilinx Virtex 6 ML605 board. 

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4. Synthesizing Efficient Hardware from High-Level Functional Hardware Description Languages

   https://doi.org/10.1109/ICECS46596.2019.8964954  

   Shahmohammadian, Mahshid ; Mainland, Geoffrey ( November 2019 , 26th IEEE International Conference on Electronics, Circuits and Systems)

   Functional hardware description languages (FHDL) provide powerful tools for building new abstractions that enable sophisticated hardware system to be constructed by composing small reusable parts. Raising the level of abstractions in hardware designs means the programmer can focus on high-level circuit structure rather than mundane low-level details. The language features that facilitate this include high-order functions, rich static type system with type inference, and parametric polymorphism. We use hand-written structural and behavioral VHDL, Simulink, and the Kansas Lava FHDL to re-implement several components taken from a Simulink model of an orthogonal frequency-division multiplexing (OFDM) physical layer (PHY). Our development demonstrates that an FHDL can require fewer lines of code than traditional design languages without sacrificing performance. 

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5. Wireless link pairing toward secured 6G networks

   https://doi.org/10.1364/OL.395542  

   Hussein, Ahmed F. ; Elgala, Hany ( July 2020 , Optics Letters)

   Hybrid wireless networks are foreseen to play a major role in the visioning and planning of the sixth generation (6G) network. Most of the 6G applications are human-centric, and thus high security and privacy are key features. Recently, physical layer (PHY) security has become an emerging area of research. This work introduces a novel, to the best of our knowledge, PHY security approach called wireless link pairing (WiLP). In WiLP, signals received from both air interfaces in a hybrid radio frequency and optical network are required for successful signal reconstruction and processing at the receiver. The transmitted packets based on the IEEE 802.11 standards are redesigned, and improvements in performance are validated via simulations and experimental measurements using software-defined radio platforms. The obtained results demonstrate improvements in bit-error rate (BER) and the secrecy capacity for multiple modulation and coding schemes.

    

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