Exact Outage Probability of a Hybrid Satellite Terrestrial Cooperative System with Best Relay Selection

International audienceIn this paper, we derive the exact outage probability of a hybrid satellite-terrestrial cooperative system (HSTCS). A selective decode-and-forward scheme is implemented between a source node (the satellite) and a destination node (a terrestrial station), and a selection of the best relay terminal is performed. In this proposed system, a two time-slot scenario is considered. During the first time slot, the satellite is broadcasting the information to the terrestrial relays and the destination. In the second time slot, only the best relay is transmitting toward the destination node. Then, both signals are combined using the maximum ratio combining (MRC) technique. The analytical expression of the outage probability is evaluated and is then verified with the simulation. The results show that our analytical expression matched well to the simulation results

Internet of Things-Enabled Overlay Satellite-Terrestrial Networks in the Presence of Interference

In this paper, we consider an overlay satellite-terrestrial network (OSTN) where an opportunistically selected terrestrial IoT network assist primary satellite communications as well as access the spectrum for its own communications in the presence of combined interference from extra-terrestrial and terrestrial sources. Hereby, a power domain multiplexing is adopted by the IoT network by splitting its power appropriately among the satellite and IoT signals. Relying upon an amplify-and-forward (AF)-based opportunistic IoT network selection strategy that minimizes the outage probability (OP) of satellite network, we derive the closed-form lower bound OP expressions for both the satellite and IoT networks. We further derive the corresponding asymptotic OP expressions to examine the achievable diversity order of two networks. We show that the proposed OSTN with adaptive power splitting factor benefits IoT network while guaranteeing the quality of service (QoS) of satellite network. We verify the numerical results by simulations.Comment: 7 pages, 3 figures, Submitted to National Conference on Communications 202

Performance analysis of NOMA-based land mobile satellite networks

Non-orthogonal multiple access (NOMA) scheme, which has the ability to superpose information in the power domain and serve multiple users on the same time/frequency resource, is regarded as an effective solution to increase transmit rate and fairness. In this paper, we introduce the NOMA scheme in a downlink land mobile satellite (LMS) network and present a comprehensive performance analysis for the considered system. Specifically, we first obtain the power allocation coefficients by maximizing the sum rate while meeting the predefined target rates of each NOMA user. Then, we derive the theoretical expressions for the ergodic capacity and the energy efficiency of the considered system. Moreover, the outage probability (OP) and average symbol error rate performances of NOMA users are derived analytically. To gain further insights, we derive the asymptotic OP at the high signal-to-noise ratio regime to characterize the diversity orders and coding gains of NOMA users. Finally, simulation results are provided to validate the theoretical analysis as well as the superiority of employing the NOMA scheme in the LMS system, and show the impact of key parameters, such as fading configurations and user selection strategy on the performance of NOMA users

Systèmes coopératifs hybride Satellite-Terrestre : analyse de performance et dimensionnement du système

Les systèmes de communications par satellite sont utilisés dans le contexte de la radiodiffusion, de la navigation, du sauvetage et du secours aux sinistrés, car ils permettent de fournir des services sur une large zone de couverture. Cependant, cette zone de couverture est limitée par l'effet de masquage provoqué par des obstacles qui bloquent la liaison directe entre le satellite et un utilisateur terrestre. L'effet de masquage devient plus sévère en cas de satellites à faibles angles d'élévation ou lorsque l'utilisateur est à l'intérieur. Pour résoudre ce problème, les Systèmes Coopératifs Hybride Satellite-Terrestre (HSTCS) ont été proposés. Dans un système HSTCS, l'utilisateur mobile peut profiter de la diversité spatiale en recevant des signaux à la fois du satellite et des relais terrestres. Les gap-fillers fixes ou mobiles sont utilisés pour relayer le signal satellite. La plupart des systèmes de diffusion par satellite utilisent les gap-fillers fixes alors que les gap-fillers mobiles sont nécessaires en cas de communications d'urgence lorsque l'infrastructure fixe n'est pas disponible. Dans les scénarios d'urgence (incendie, tremblement de terre, inondations, explosion) l'infrastructure terrestre existante est endommagée, donc les HSTCSs sont appropriés pour mettre à jour des informations qui permettent aux sauveteurs d'intervenir efficacement et en toute sécurité. En particulier, une mise en œuvre rapide et souple est nécessaire, ce qui pourrait être fourni par le déploiement de gap-fillers mobiles (véhicule ou portable). Plusieurs scénarios coopératifs et techniques de transmission ont déjà été proposés et étudiés. Cependant, la plupart des méthodes proposées ne fournissent qu'une analyse de performance fondée sur la simulation alors que les expressions analytiques de la probabilité de coupure et de la Probabilité d'Erreur Symbole (SEP) n'ont pas encore été établies. Cette thèse se focalise sur l'analyse de performances des systèmes HSTCS. La probabilité de coupure et SEP du système utilisant le schéma de transmission Selective Decode-and-Forward (SDF), avec ou sans sélection de relais, est évaluée dans le cas des modulations MPSK et MQAM. Cette expression analytique permet de concevoir le système HSTCS. Ces résultats sont applicables aux cas des relais fixes ou mobiles. La seconde partie de cette thèse est consacrée à des problèmes de synchronisation (décalage en temps et en fréquence ainsi que l'étalement Doppler). La mobilité des utilisateurs crée l'étalement Doppler qui détruit l'orthogonalité des sous-porteuses dans les signaux de type Orthogonal Frequency Division Multiplexing (OFDM). Cette perte d'orthogonalité engendre de l'interférence entre sous-porteuses (ICI) et donc une dégradation des performances du système en termes de SEP. Dans ce cas, on présente les conditions dans lesquelles cette dégradation peut être compensée par une augmentation du Rapport Signal sur Bruit (SNR) du côté de l'émetteur. Le résultat dépend du schéma de modulation et aussi de la vitesse des utilisateurs. ABSTRACT : Satellite communication systems are used in the context of broadcasting, navigation, rescue, and disaster relief since they allow the provision of services over a wide coverage area. However, this coverage area is limited by the masking effect caused by obstacles that block the Line-Of-Sight (LOS) link between the satellite and a terrestrial user. The masking effect becomes more severe in case of low satellite elevation angles or when the user is indoor. To address this issue, Hybrid Satellite-Terrestrial Cooperative Systems (HSTCSs) have been proposed. In an HSTCS, the mobile user can exploit the diversity advantages by receiving signals from both satellite and terrestrial components. Fixed or mobile gap-fillers are used to relay the satellite signal. Most of satellites broadcasting systems have been implemented using fixed gap-fillers while mobile gap-fillers are needed in emergency cases when the fixed infrastructure is not available. In emergency scenarios (e.g., fire, earthquake, flood and explosion), the existing terrestrial infrastructure has been destroyed. So, an HSTCS is appropriate for transmitting the information between the rescuers and the central office. This allows the rescuers to operate efficiently. In particular, a fast and flexible implementation is needed and this could be provided by deploying mobile gap fillers (vehicle or mobile handheld). Recently, the topic of HSTCSs has gain interest in the research community. Several cooperative scenarios and transmission techniques have been proposed and studied. However, most of existing approaches only provide a performance analysis based on simulation results and the analytical expression of the exact Symbol Error Probability (SEP) is generally not provided. This dissertation focuses on the performance analysis of HSTCSs. The exact closed-form outage probability and SEP of Selective Decode-and-Forward (SDF) transmission scheme with and without relay selection are derived for both M-ary phase shift keying (MPSK) and M-ary quadrature amplitude modulation (MQAM) schemes. This analytical SEP helps in designing and dimensioning HSTCSs. Our results are applicable to both fixed and mobile relaying techniques. Another part of the dissertation is dedicated to synchronization issues (time, frequency shifting/spreading). The mobility of users induces a Doppler spread in the Orthogonal Frequency Division Multiplexing (OFDM) signal that destroys the orthogonality of subcarriers. The loss of orthogonality produces Inter-subCarrier Interference (ICI) and hence a degradation of the system performance in terms of SEP. In this case, we present the conditions in which this degradation can be compensated for by an increase in the Signal to Noise Ratio (SNR) at the transmitter side. The result depends on both the modulation scheme and the speed of the mobile users

Ultra Reliable UAV Communication Using Altitude and Cooperation Diversity

The use of unmanned aerial vehicles (UAVs) that serve as aerial base stations is expected to become predominant in the next decade. However, in order for this technology to unfold its full potential it is necessary to develop a fundamental understanding of the distinctive features of air-to-ground (A2G) links. As a contribution in this direction, this paper proposes a generic framework for the analysis and optimization of the A2G systems. In contrast to the existing literature, this framework incorporates both height-dependent path loss exponent and small-scale fading, and unifies a widely used ground-to-ground channel model with that of A2G for analysis of large-scale wireless networks. We derive analytical expressions for the optimal UAV height that minimizes the outage probability of a given A2G link. Moreover, our framework allows us to derive a height-dependent closed-form expression and a tight lower bound for the outage probability of an \textit{A2G cooperative communication} network. Our results suggest that the optimal location of the UAVs with respect to the ground nodes does not change by the inclusion of ground relays. This enables interesting insights in the deployment of future A2G networks, as the system reliability could be adjusted dynamically by adding relaying nodes without requiring changes in the position of the corresponding UAVs

Performance Analysis of Multi-Antenna Hybrid Satellite-Terrestrial Relay Networks in the Presence of Interference

Abstract—The integration of cooperative transmission into satellite networks is regarded as an effective strategy to increase the energy efficiency as well as the coverage of satellite communications. This paper investigates the performance of an amplifyand-forward (AF) hybrid satellite-terrestrial relay network (HSTRN), where the links of the two hops undergo Shadowed- Rician andRayleigh fadingdistributions, respectively.By assuming that a single antenna relay is used to assist the signal transmission between the multi-antenna satellite and multi-antenna mobile terminal, and multiple interferers corrupt both the relay and destination, we first obtain the equivalent end-to-end signal-to-interference-plus-noise ratio (SINR) of the system. Then, an approximate yet very accurate closed-form expression for the ergodic capacity of the HSTRN is derived. The analytical lower bound expressions are also obtained to efficiently evaluate the outage probability (OP) and average symbol error rate (ASER) of the system. Furthermore, the asymptotic OP and ASER expressions are developed at high signal-to-noise ratio (SNR) to reveal the achievable diversity order and array gain of the considered HSTRN. Finally, simulation results are provided to validate of the analytical results, and show the impact of various parameters on the system performance