Qian Yang scite author profile

Non-orthogonal multiple access (NOMA) has been recognized as a promising technique for providing high data rates in 5G systems. This letter is to study physical layer security in a single-input single-output (SISO) NOMA system consisting of a transmitter, multiple legitimate users and an eavesdropper. The aim of this letter is to maximize the secrecy sum rate (SSR) of the NOMA system subject to the users' quality of service (QoS) requirements. We firstly identify the feasible region of the transmit power for satisfying all users' QoS requirements. Then we derive the closed-form expression of an optimal power allocation policy that maximizes the SSR. Numerical results are provided to show a significant SSR improvement by NOMA compared with conventional orthogonal multiple access (OMA).Index Terms-Non-orthogonal multiple access, physical layer security, power allocation, optimization.

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Energy-Efficient Transmission Design in Non-orthogonal Multiple Access

Zhang

Wang

Zheng

et al. 2017

IEEE Trans. Veh. Technol.

278

183

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Non-orthogonal multiple access (NOMA) is considered as a promising technology for improving the spectral efficiency (SE) in 5G. In this correspondence, we study the benefit of NOMA in enhancing energy efficiency (EE) for a multi-user downlink transmission, where the EE is defined as the ratio of the achievable sum rate of the users to the total power consumption. Our goal is to maximize the EE subject to a minimum required data rate for each user, which leads to a non-convex fractional programming problem. To solve it, we first establish the feasible range of the transmitting power that is able to support each user's data rate requirement. Then, we propose an EE-optimal power allocation strategy that maximizes the EE. Our numerical results show that NOMA has superior EE performance in comparison with conventional orthogonal multiple access (OMA).Index Terms-Non-orthogonal multiple access, energy efficiency, power allocation, fractional programming optimization.

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Secure Short-Packet Communications for Mission-Critical IoT Applications

Wang

Yang

Ding

et al. 2019

IEEE Trans. Wireless Commun.

156

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In pervasive Internet of Things (IoT) applications, the use of short packets is expected to meet the stringent latency requirement in ultra-reliable low-latency communications; however, the incurred security issues and the impact of finite blocklength coding on the physical-layer security have not been well understood. This paper comprehensively investigates the performance of secure short-packet communications in a mission-critical IoT system with an external multi-antenna eavesdropper. An analytical framework is proposed to approximate the average achievable secrecy throughput of the system with finite blocklength coding. To gain more insight, a simple case with a single-antenna access point (AP) is considered first, in which the secrecy throughput is approximated in a closed form. Based on that result, the optimal blocklengths to maximize the secrecy throughput with and without the reliability and latency constraints, respectively, are derived. For the case with a multiantenna AP, following the proposed analytical framework, closedform approximations for the secrecy throughput are obtained under both beamforming and artificial-noise-aided transmission schemes. Numerical results verify the accuracy of the proposed approximations and illustrate the impact of the system parameters on the tradeoff between transmission latency and reliability under the secrecy constraint.

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Enhancing Luminescence and Photostability of CsPbBr₃ Nanocrystals via Surface Passivation with Silver Complex

Yang

Xing

et al. 2018

J. Phys. Chem. C

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We demonstrate that Ag(I) complex can fix bromide on the nanocrystal surface, reduce surface trap density, and as a result efficiently passivate the surface of CsPbBr3 nanocrystals. This passivation makes the photoluminescence (PL) intensity increase several times. The PL kinetics study clearly shows that the decay lifetime increased after the passivation. TEM and XPS analyses demonstrated the existence of Ag on the nanocrystal surface. In addition, we utilize single-particle spectroscopy combined with in situ light analysis to further confirm the PL enhancement effect. On the contrary, the passivation leads to the extraordinary photostability of CsPbBr3 nanocrystals, with 80% PL intensity retained after UV illumination for 5 days under ambient conditions.

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Qian Yang

Secrecy Sum Rate Maximization in Non-orthogonal Multiple Access

Energy-Efficient Transmission Design in Non-orthogonal Multiple Access

Secure Short-Packet Communications for Mission-Critical IoT Applications

Enhancing Luminescence and Photostability of CsPbBr₃ Nanocrystals via Surface Passivation with Silver Complex

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Qian Yang

Secrecy Sum Rate Maximization in Non-orthogonal Multiple Access

Energy-Efficient Transmission Design in Non-orthogonal Multiple Access

Secure Short-Packet Communications for Mission-Critical IoT Applications

Enhancing Luminescence and Photostability of CsPbBr3 Nanocrystals via Surface Passivation with Silver Complex

Contact Info

Product

Resources

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Enhancing Luminescence and Photostability of CsPbBr₃ Nanocrystals via Surface Passivation with Silver Complex