Logo
ScienceStack
Table of Contents
Fetching ...
Sign In

Effect of Correlation between Information and Energy Links in Secure Wireless Powered Communications

Antonio Tarrías-Muñoz, José Luis Matez-Bandera, Pablo Ramírez-Espinosa, F. Javier López-Martínez

TL;DR

It is quantified that even though link correlation improves the average signal-to-noise ratio (SNR) for a fixed transmit power, it also increases its variance, which ultimately degrades capacity, and points out that when link correlation between the energy and wiretap links is rigorously accounted for, it barely affects secrecy performance.

Abstract

In this paper, we investigate the impact of correlation between the energy and information links in wireless power transfer systems, from a physical layer security perspective. With that aim, we first determine how correlation can affect system capacity in practical energy harvesting set-ups in the absence of eavesdroppers. We quantify that even though link correlation improves the average signal-to-noise ratio (SNR) for a fixed transmit power, it also increases its variance, which ultimately degrades capacity. Based on this observation, we show that correlation between the energy and information links may be detrimental/beneficial for the secrecy capacity in the high/low legitimate SNR regime, whenever such correlation affects the legitimate user. Conversely, we also point out that when link correlation for the wiretap link is rigorously accounted for, it barely affects secrecy performance, causing only a minor degradation in some instances.

Effect of Correlation between Information and Energy Links in Secure Wireless Powered Communications

TL;DR

It is quantified that even though link correlation improves the average signal-to-noise ratio (SNR) for a fixed transmit power, it also increases its variance, which ultimately degrades capacity, and points out that when link correlation between the energy and wiretap links is rigorously accounted for, it barely affects secrecy performance.

Abstract

In this paper, we investigate the impact of correlation between the energy and information links in wireless power transfer systems, from a physical layer security perspective. With that aim, we first determine how correlation can affect system capacity in practical energy harvesting set-ups in the absence of eavesdroppers. We quantify that even though link correlation improves the average signal-to-noise ratio (SNR) for a fixed transmit power, it also increases its variance, which ultimately degrades capacity. Based on this observation, we show that correlation between the energy and information links may be detrimental/beneficial for the secrecy capacity in the high/low legitimate SNR regime, whenever such correlation affects the legitimate user. Conversely, we also point out that when link correlation for the wiretap link is rigorously accounted for, it barely affects secrecy performance, causing only a minor degradation in some instances.

Paper Structure

This paper contains 12 sections, 37 equations, 11 figures.

Table of Contents

  1. Introduction
  2. System Model
  3. Effect of Correlation in System's Capacity
  4. Preliminary definitions
  5. Performance analysis
  6. Numerical results
  7. Effect of Correlation on Secrecy Capacity
  8. Preliminary definitions
  9. Correlation between WPT and Bob's links
  10. Correlation between WPT and Eve's links
  11. Numerical evaluation
  12. Conclusions

Figures (11)

  • Figure 1: Wireless power transfer-based system set-up
  • Figure 2: Average capacity $\overline{C}$ vs. $\overline\gamma_B$, for different values of the correlation coefficient through $p=\rho^2$ and LOS conditions through $K$. Solid lines correspond to theoretical expressions using \ref{['eqCint']} and \ref{['eq7']}. Dashed lines correspond to the asymptotic results using \ref{['eqC']}. Markers correspond to MC simulations.
  • Figure 3: Outage probability vs. $\overline\gamma_B$, for different values of the correlation coefficient through $p=\rho^2$ and LOS conditions through $K$. Solid lines correspond to theoretical expressions using \ref{['eqOPint']} and \ref{['eqCDF1']}. Markers correspond to MC simulations.
  • Figure 4: Scenario 1: Correlation between the energy and legitimate information links.
  • Figure 5: Scenario 2: Correlation between the energy and wiretap links.
  • ...and 6 more figures