33 research outputs found
Load Balanced Dynamic Resource Allocation for MTC Relay
A Load Balancing Relay Algorithm (LBRA) was proposed to solve the unfair
spectrum resource allocation in the traditional mobile MTC relay. In order to
obtain reasonable use of spectrum resources, and a balanced MTC devices (MTCDs)
distribution, spectrum resources are dynamically allocated by MTCDs regrouped
on the MTCD to MTC gateway link. Moreover, the system outage probability and
transmission capacity are derived when using LBRA. The numerical results show
that the proposed algorithm has better performance in transmission capacity and
outage probability than the traditional method. LBRA had an increase in
transmission capacity of about 0.7dB, and an improvement in outage probability
of about 0.8dB with a high MTCD density.Comment: 6pages, 5figure
Security enhancement for NOMA-UAV networks
Owing to its distinctive merits, non-orthogonal multiple access (NOMA) techniques have been utilized in unmanned aerial vehicle (UAV) enabled wireless base stations to provide effective coverage for terrestrial users. However, the security of NOMA-UAV systems remains a challenge due to the line-of-sight air-to-ground channels and higher transmission power of weaker users in NOMA. In this paper, we propose two schemes to guarantee the secure transmission in UAV-NOMA networks. When only one user requires secure transmission, we derive the hovering position for the UAV and the power allocation to meet rate threshold of the secure user while maximizing the sum rate of remaining users. This disrupts the eavesdropping towards the secure user effectively. When multiple users require secure transmission, we further take the advantage of beamforming via multiple antennas at the UAV to guarantee their secure transmission. Due to the non-convexity of this problem, we convert it into a convex one for an iterative solution by using the second order cone programming. Finally, simulation results are provided to show the effectiveness of the proposed scheme
UAV-assisted emergency networks in disasters
Reliable and flexible emergency communication is a key challenge for search and rescue in the event of disasters, especially for the case when base stations (BSs) are no longer functioning. Unmanned aerial vehicle (UAV) assisted network is emerging as a promising method to establish emergency networks. In this article, a unified framework of UAV-assisted emergency network is established in disasters. First, the trajectory and scheduling of UAV are jointly optimized to provide wireless service to ground devices with surviving BSs. Then, the transceiver design of UAV and establishment of multi-hop ground device-to- device (D2D) communication are studied to extend the wireless coverage of UAV. In addition, multi-hop UAV relaying is added to realize information exchange between the disaster areas and outside through optimizing the hovering positions of UAVs. Simulation results are presented to show the effectiveness of these three schemes. Finally, open research issues and challenges are discussed
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Agent-based spectrum management scheme in satellite communication systems
Efficient spectrum management has always been an important issue due to the scarcity of satellite spectral resource, especially with the ever-increasing broadband demand. This paper proposes a market-driven technique to improve spectrum efficiency. In practice, spectrum resources are typically allocated in bulk to terrestrial agents which in turn will resell the bandwidth to end users of satellite communications. This paper explores the important role of terrestrial agents which serve as spectrum sales agents in satellite communications systems. The proposed approach aims to provide an incentive scheme for the agents to participate in the spectrum optimization process so as to result in maximizing the benefit of the agents as well as the satellite systems. We propose a dynamically optimal cooperation scheme between terrestrial agents and satellite systems, which is based on a stochastic process and optimal contract principle. By taking into consideration the satellite system's marginal cost related to transmission capacity in the given bandwidth, terrestrial agent's effort and the impact of market volatility, we designed an optimal incentive model which allows the satellite systems to determine a threshold value for paying sales commission to terrestrial agents or triggering contract termination if spectrum utilization is inefficient. Numerical results are presented to evaluate the performances of satellite systems' profits in changing spectrum market and agency cost undertaken by satellite systems
Intelligent Reflecting Surface Aided Power Control for Physical-Layer Broadcasting
Reconfigurable intelligent surface (RIS), a recently introduced technology
for future wireless com-munication systems, enhances the spectral and energy
efficiency by intelligently adjusting the propaga-tion conditions between a
base station (BS) and mobile equipments (MEs). An RIS consists of manylow-cost
passive reflecting elements to improve the quality of the received signal. In
this paper, westudy the problem of power control at the BS for the RIS aided
physical-layer broadcasting. Our goalis to minimize the transmit power at the
BS by jointly designing the transmit beamforming at the BSand the phase shifts
of the passive elements at the RIS. Furthermore, to help validate the
proposedoptimization methods, we derive lower bounds to quantify the average
transmit power at the BS as afunction of the number of MEs, the number of RIS
elements, and the number of antennas at the BS.The simulation results
demonstrated that the average transmit power at the BS is close to the
lowerbound in an RIS aided system, and is significantly lower than the average
transmit power in conventionalschemes without the RIS
Subcarrier Allocation Based Cooperative Spectrum Sharing with Wireless Energy Harvesting in OFDM Relaying Networks
In this paper, we propose subcarrier allocation based cooperative spectrum sharing protocol for OFDM relaying networks with wireless energy harvesting. In the proposed protocol, the cognitive relay node utilizes different subcarriers to forward the primary information to obtain the spectrum access for the cognitive system transmission. The primary system consists of two parts, a primary transmitter (PT) and primary receiver (PR), and cognitive system includes a cognitive source node (CSN), cognitive destination node (CDN) and cognitive relay node (CRN). In the first phase, CRN splits a fraction of the power received from the PT and CSN transmission to decode information, while the remaining power is used for energy harvesting. Then CRN uses disjoint subcarriers to forward the signals of PT and CSN by utilizing the harvested energy in the second phase. Three parameters which consist of power splitting ratio, power allocation and subcarriers allocation are optimized in our algorithm to maximize the cognitive transmission rate with the constraint of primary target transmission rate. Numerical and simulation results are shown to give useful insights into the proposed cooperative spectrum sharing protocol, and we also found that various system parameters have a great effect for the simulation results