Distributed link selection in multirelay multiuser networks

2018 IEEE 29th Annual International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC)

Olivo

Alves

2018

We propose a destination-based jamming scheme for cooperative networks with multiple untrusted amplify-and-forward relays, in which the destination operates in full-duplex mode so as to enable simultaneous reception of the information coming directly from the source and the transmission of jamming signals to the untrusted relay. An approximate analytical expression for the secrecy outage probability, under the effect of residual self-interference at the destination, is presented. The developed analysis is verified through Monte Carlo simulations.

“…Proof. From (12), by considering the relay selection criterion in (9) and applying the Total Probability Theorem [11], the SOP can be determined as…”

Section: Proposition 1 An Approximate Expression For the Secrecy Outmentioning

confidence: 99%

Secrecy Performance for Multiple Untrusted Relay Networks Using Destination-Based Jamming with Direct Link

2018 IEEE 29th Annual International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC)

Olivo

Alves

2018

“…where the step (a) is obtained by applying the Total Probability Theorem [21], and (b) is obtained by using the well known approximation of Θ l by its upper-bound Φ l = min {A, B l }, which has proved to render a tight approximation [22]. Also, as A and B l are independent random variables, then the CDF of Φ l can be expressed as…”

Section: Appendix B Proof Of Propositionmentioning

confidence: 99%

“…7, that is: 1) A > τ − C l and B < τ − C l , 2) A < τ − C l and B > τ − C l , and 3) A < τ − C l and B < τ − C l . For the first region, we have that B l is always lower than A, thus the destination selection is dominated by B l , and the expression in (22) for this region can be rewritten as…”

Section: Appendix C Proof Of Propositionmentioning

confidence: 99%

“…In this case, as all destinations present the same first-hop link, the probability of selection of each one of them is equal to 1/L, thus, for this region, (22) can be rewritten as…”

Section: Appendix C Proof Of Propositionmentioning

confidence: 99%

“…For the second subregion, we have the same condition of region 1, thus (22) for this case can be rewritten as…”

Section: Appendix C Proof Of Propositionmentioning

confidence: 99%

See 2 more Smart Citations

Impact of Primary-User Interference on Multiuser Cognitive Relaying Networks

Olivo

Tojeiro

et al. 2018

JCIS

Abstract-This paper investigates the impact of primary-user interference on the performance of a cognitive relaying network consisting of a source, an amplify-and-forward relay and multiple destinations. With the aim of exploiting multiuser diversity at the secondary network, two different destination-selection policies are considered, which are based on partial channel state information of the network, accounting for either the direct links or the relaying links. In the setup under investigation, the source's information signal is conveyed to the selected destination by both the direct link and the relaying link, after which a maximalratio combining of the signals coming from the source and relay is performed. In addition, we consider that the transmit power of the secondary nodes is constrained by key aspects of underlay spectrum sharing, i.e., the interference temperature at the primary network and the maximum transmit power available at the source and relay. The system performance of the considered destination-selection schemes is analyzed in terms of the outage probability and compared to the optimal criterion. Monte Carlo simulations are provided to verify the attained analytical results.Index Terms-amplify-and-forward relaying, cooperative diversity, interference, multiuser diversity, underlay spectrum sharing.

Imperfect jamming cancellation on NOMA networks with randomly located eavesdroppers

Silva

2021 IEEE 32nd Annual International Symposium on Personal, Indoor and Mobile Radio Communications (PIMRC)

2021

This paper addresses the secrecy performance of the downlink of a non-orthogonal multiple access network in the presence of multiple randomly located eavesdroppers. The network consists of a base station and a near receiver that are located inside a protected zone, free of eavesdroppers, while a far user is located outside. Herein, it is considered that the source transmits a superposed jamming signal to enhance the secrecy performance. In this sense, imperfections on the removal of the jamming signal by the legitimate receivers are also investigated. Integral-form exact and closed-form approximate expressions for the secrecy outage probability are derived by employing stochastic geometry tools. The expressions are corroborated via Monte Carlo simulations.