Outage Analysis of Energy Harvested Relay-Aided Device-to-Device Communications in Nakagami Channel

Moghaddam, Shahriar Shirvani

doi:10.24138/jcomss.v14i4.490

Cited by 5 publications

(2 citation statements)

References 30 publications

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“…In addition to optimum mode selection, resource allocation, and power control, finding the proper power splitting (PS) factor of relay nodes in an energy-harvested D2D communication is a goal. Achieving low-complexity closed-form expressions for the outage probability and throughput helps us to do the optimization problem in an acceptable processing time [39]. Table 1 summarizes the advantages and disadvantages of different underlay and overlay scenarios in D2D communications, in view of interference, collision, outage probability, reuse factor, and achievable throughput.…”

Section: D2d Communicationsmentioning

confidence: 99%

Introductory Chapter: Primary and Secondary Users in Cognitive Radio-Based Wireless Communication Systems

Moghaddam¹

2018

Cognitive Radio in 4g/5g Wireless Communication Systems

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Additional information is available at the end of the chapter 1. Wireless communications and the necessity of cognitive radio Wireless communication systems play a special role in human life, facilitate the life, and change the world much more in the future. The diversity of applications and services of wireless communications indicates the widespread use of wireless systems and equipment in the future. Since the first radio link by Marconi in 1896, it has been more than 120 years, and several wireless communication systems have been introduced up to now. Meanwhile, the advancement of cellular wireless communications, whose idea came back to 1947 and their first generation in 1978 (namely advanced mobile phone service), has been well adopted and has grown dramatically, so that the researchers and operators are focused on standardization and design of 5G and 6G wireless communication systems [1]. From the beginning, one of the main problems in wireless communications is the scarcity of radio resources (frequency, time, and power). In recent years, the lack of frequency spectrum and the necessity of frequency reuse at different times and places and reduction of the consumed power are of great importance. Looking at the following laws: • Moore's law: The number of transistors that can be cheaply placed on a microchip doubles and the computer power exponentially increases approximately every 2 years [2] • Cooper's law: The number of voice calls or data that can be sent over the usable radio spectrum doubles every 30 months [2]

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Section: D2d Communicationsmentioning

confidence: 99%

Introductory Chapter: Primary and Secondary Users in Cognitive Radio-Based Wireless Communication Systems

Moghaddam¹

2018

Cognitive Radio in 4g/5g Wireless Communication Systems

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“…The design of wireless transmission systems with a TX relying exclusively on EH is proposed in [13]. Author in [14] has considered the energy harvesting for device-to-device communications in Nakagami fading channels with and decode-andforward (DF) scheme. Authors in [13] have presented a savethen-transmit (ST) protocol for SISO systems.…”

Section: Introductionmentioning

confidence: 99%

Save and Transmit Scheme for Energy Harvesting MIMO Systems with TAS/MRC

Issa

Ammari

2019

J. commun. softw. syst. (Online)

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In this paper, we propose and analyze a wirelesstransmitter, for multiple-input multiple-output (MIMO) systems,that relies exclusively on energy harvesting. We consider wirelesstransceivers where the transmitter harvests the total requiredenergy from its environment through various sources. We assumethat both transmitter and receiver are equipped with multipleantennas. At the transmitter, a single transmit antenna thatmaximizes the signal-to-noise ratio (SNR) at the receiver isselected for transmission. The remaining antennas are used forenergy harvesting. At the receiver side, maximal-ratio com-bining (MRC) is used. Furthermore, we assume that all theharvested power is used to power the transmitter immediately.The performance of the proposed scheme is analyzed in terms ofoutage probability (OP), symbol error rate (SER) and channelcapacity. The harvested energy comes from random sourcesand is considered as a random variable. Assuming that theharvested power follows a gamma distribution and the MIMOchannel is a Rayleigh flat fading process, we derive a closed-form expressions for the exact cumulative distribution function(CDF) and probability density function (PDF) of the SNR. Basedon this, we analyze the performance of the proposed energyharvesting scheme. The obtained analytical results are validatedby comparing them with the results of Monte-Carlo simulations.

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Disaster-Recovery Communications Utilizing SWIPT-based D2D Relay Network

Liu

2019

2019 IEEE 5th International Conference on Computer and Communications (ICCC)

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Outage Analysis of Energy Harvested Relay-Aided Device-to-Device Communications in Nakagami Channel

Cited by 5 publications

References 30 publications

Introductory Chapter: Primary and Secondary Users in Cognitive Radio-Based Wireless Communication Systems

Introductory Chapter: Primary and Secondary Users in Cognitive Radio-Based Wireless Communication Systems

Save and Transmit Scheme for Energy Harvesting MIMO Systems with TAS/MRC

Disaster-Recovery Communications Utilizing SWIPT-based D2D Relay Network

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