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Physical Layer Security Performance of Cooperative Dual RIS-aided V2V NOMA Communications

Farshad Rostami Ghadi, Masoud Kaveh, Kai-Kit Wong, Diego Martin

TL;DR

The numerical results indicate that incorporating the dual RIS in the secure V2V communication under the NOMA scheme can significantly provide ultrareliable transmission and guarantee more secure communication for intelligent transportation systems.

Abstract

This paper investigates the performance of physical layer security (PLS) in a vehicle-to-vehicle (V2V) communication system, where a transmitter vehicle exploits a dual reconfigurable intelligent surface (RIS) to send confidential information to legitimate receiver vehicles under the non-orthogonal multiple access (NOMA) scheme in the presence of an eavesdropper vehicle. In particular, it is assumed that an RIS is near the transmitter vehicle and another RIS is close to the receiver vehicles to provide a wider smart radio environment. Besides, we suppose that the channels between two RISs suffer from the Fisher-Snedecor F fading model. Under this scenario, we first provide the marginal distributions of equivalent channels at the legitimate receiver vehicles by exploiting the central limit theorem (CLT). Then, in order to evaluate the PLS performance of the considered secure communication system, we derive analytical expressions of the average secrecy capacity (ASC), secrecy outage probability (SOP), and secrecy energy efficiency (SEE) by using the Gauss-Laguerre quadrature and the Gaussian quadrature techniques. Moreover, to gain more insights into the secrecy performance, the asymptotic expression of the ASC is obtained. The numerical results indicate that incorporating the dual RIS in the secure V2V communication under the NOMA scheme can significantly provide ultra-reliable transmission and guarantee more secure communication for intelligent transportation systems (ITS).

Physical Layer Security Performance of Cooperative Dual RIS-aided V2V NOMA Communications

TL;DR

The numerical results indicate that incorporating the dual RIS in the secure V2V communication under the NOMA scheme can significantly provide ultrareliable transmission and guarantee more secure communication for intelligent transportation systems.

Abstract

This paper investigates the performance of physical layer security (PLS) in a vehicle-to-vehicle (V2V) communication system, where a transmitter vehicle exploits a dual reconfigurable intelligent surface (RIS) to send confidential information to legitimate receiver vehicles under the non-orthogonal multiple access (NOMA) scheme in the presence of an eavesdropper vehicle. In particular, it is assumed that an RIS is near the transmitter vehicle and another RIS is close to the receiver vehicles to provide a wider smart radio environment. Besides, we suppose that the channels between two RISs suffer from the Fisher-Snedecor F fading model. Under this scenario, we first provide the marginal distributions of equivalent channels at the legitimate receiver vehicles by exploiting the central limit theorem (CLT). Then, in order to evaluate the PLS performance of the considered secure communication system, we derive analytical expressions of the average secrecy capacity (ASC), secrecy outage probability (SOP), and secrecy energy efficiency (SEE) by using the Gauss-Laguerre quadrature and the Gaussian quadrature techniques. Moreover, to gain more insights into the secrecy performance, the asymptotic expression of the ASC is obtained. The numerical results indicate that incorporating the dual RIS in the secure V2V communication under the NOMA scheme can significantly provide ultra-reliable transmission and guarantee more secure communication for intelligent transportation systems (ITS).
Paper Structure (21 sections, 9 theorems, 38 equations, 6 figures, 1 table)

This paper contains 21 sections, 9 theorems, 38 equations, 6 figures, 1 table.

Table of Contents

  1. Introduction
  2. Related Works
  3. Motivation and Contributions
  4. Organization
  5. System Model
  6. Channel Model
  7. Instantaneous SNR/SINR
  8. Statistical Characterization
  9. Distribution of $\gamma_{{\mathrm{r}}_i}$
  10. Distribution of $\gamma_{{\mathrm{e}}}$
  11. Secrecy Metrics Analysis
  12. ASC Analysis
  13. SOP Analysis
  14. SEE Analysis
  15. Numerical Results
  16. ...and 6 more sections

Key Result

Proposition 1

The ASC for the receiver vehicle $v_\mathrm{r_1}$ for the studied secure dual RIS-aided V2V NOMA communication system is given by in which $\epsilon_{\tilde{n}}$ is the $\tilde{n}$-th root of Laguerre polynomial $L_{\tilde{N}}\left(\epsilon_{\tilde{n}}\right)$, $\tilde{N}$ defines the parameter to ensure a complexity-accuracy trade-off, $\mathrm{erfc}(s)=1-\mathrm{erf}(s)$, $A_i=p_{\mathrm{r_i}}

Figures (6)

  • Figure 1: System model indicates a secure dual RIS-aided V2V NOMA communication.
  • Figure 2: ASC versus the transmit power $P$ when $M=50$.
  • Figure 3: ASC versus the number of dual RIS elements $M$ when $P=20$dBm.
  • Figure 4: SOP versus the transmit power $P$ for selected values of $M$.
  • Figure 5: SOP versus the transmit power $P$ for selected values of fading parameters $m_1$ and $m_2$ when $M=80$.
  • ...and 1 more figures

Theorems & Definitions (15)

  • Proposition 1
  • proof
  • Proposition 2
  • proof
  • Corollary 1
  • proof
  • Remark 1
  • Proposition 3
  • Proposition 4
  • proof
  • ...and 5 more