16 research outputs found
Performance Analysis of Decode-and-Forward Relaying in Gamma-Gamma Fading Channels
Decode-and-forward (DF) cooperative communication based on free space optical
(FSO) links is studied in this letter. We analyze performance of the DF
protocol in the FSO links following the Gamma-Gamma distribution. The
cumulative distribution function (CDF) and probability density function (PDF)
of a random variable containing mixture of the Gamma- Gamma and Gaussian random
variables is derived. By using the derived CDF and PDF, average bit error rate
of the DF relaying is obtained.Comment: 3 pages, 1 figure, journa
Outage Performance Analysis of Multicarrier Relay Selection for Cooperative Networks
In this paper, we analyze the outage performance of two multicarrier relay
selection schemes, i.e. bulk and per-subcarrier selections, for two-hop
orthogonal frequency-division multiplexing (OFDM) systems. To provide a
comprehensive analysis, three forwarding protocols: decode-and-forward (DF),
fixed-gain (FG) amplify-and-forward (AF) and variable-gain (VG) AF relay
systems are considered. We obtain closed-form approximations for the outage
probability and closed-form expressions for the asymptotic outage probability
in the high signal-to-noise ratio (SNR) region for all cases. Our analysis is
verified by Monte Carlo simulations, and provides an analytical framework for
multicarrier systems with relay selection
Comparing Layer 1 and Layer 3 Relay Stations Deployment in a LTE Network
The relay solution in planning of mobile networks, has the aim of increasing the network coverage and/or capacity. According to the open literature, this technique will be highly used in the next Long Term Evolution (LTE) Networks. The Relay Station (RS) performance varies with its position in the cell, with the radio conditions to which RSs and User Equipments (UEs) are subjected and with the RS capacity to receive, process and forward the information. The aim of this paper is to compare the performance of the Layer 1 (L1) and Layer 3 (L3) RS types, and to determine the ideal position in which a RS should be placed, with the aim of maximizing the UE throughput
Blockchain-based distributive auction for relay-assisted secure communications
Physical layer security (PLS) is considered as a promising technique to prevent information eavesdropping in wireless systems. In this context, cooperative relaying has emerged as a robust solution for achieving PLS due to multipath diversity and relatively lower transmission power. However, relays or the relay operators in the practical environment are unwilling for service provisioning unless they are incentivized for their cost of services. Thus, it is required to jointly consider network economics and relay cooperation to improve system efficiency. In this paper, we consider the problem of joint network economics and PLS using cooperative relaying and jamming. Based on the double auction theory, we model the interaction between transmitters seeking for a particular level of secure transmission of information and relay operators for suitable relay and jammer assignment, in a multiple source-destination networks. In addition, theoretical analyses are presented to justify that the proposed auction mechanism satisfies the desirable economic properties of individual rationality, budget balance, and truthfulness. As the participants in the traditional centralized auction framework may take selfish actions or collude with each other, we propose a decentralized and trustless auction framework based on blockchain technology. In particular, we exploit the smart contract feature of blockchain to construct a completely autonomous framework, where all the participants are financially enforced by smart contract terms. The security properties of the proposed framework are also discussed
Integration of network coding, spatial diversity and opportunistic routing/forwarding in wireless mesh networks
Wireless Mesh Network is an answer to the last mile problem. It offers easy deployment and provides coverage over large area with fewer wires. Nevertheless, its limited throughput is inadequate for next generation applications. Motivated by its features and advantages, we propose a solution to mitigate this problem of limited throughput by leveraging the broadcast nature of the wireless medium. In particular, network coding, spatial diversity and opportunistic routing/forwarding capitalize on the broadcast nature of the wireless links to improve the network performance. These techniques target different network conditions and usually are considered in separation. In this thesis a cross-layer based integration of the mentioned three techniques is presented to accumulate their potential gains using the same network protocol stack in wireless mesh networks. The proposed integration approach is based on a new CDARM metric (Coding opportunity and Data rate Aware Routing Metric) used for the route selection and a method for creating relay links at the MAC layer. In particular to leverage on the broadcast nature we developed a cooperative protocol, based on link creation at the MAC layer that introduces opportunism into the cooperative protocol. Based on this cooperative protocol and the routing metric, we integrate the network coding mechanism. Then we introduce cooperation between the network and MAC layers. The numerical study, based on the system level simulation results, shows significant improvement of the integrated protocol performance in terms of network throughput and reliability over the individual mechanisms. To the best of our knowledge this dissertation is the first attempt to integrate network coding, spatial diversity and opportunistic routing/forwarding mechanisms in the same protocol stack. The integrated protocol requires modifications into the network protocol stack that can be easily incorporated in future generation devices