Optimal save-then-transmit protocol for energy harvesting wireless transmitters

Luo, Shuai; Zhang, Rui; Lim, Teng Joon

doi:10.1109/isit.2012.6284704

Cited by 72 publications

(116 citation statements)

References 25 publications

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“…The best proportion that www.ijacsa.thesai.orgreduces outage probability is extracted, and some essential guiding principle is given [18]. The development of Carbon dioxide (CO 2 ) sensor nodes that are powered by artificial light was proposed in [19].…”

Section: Literature Reviewmentioning

confidence: 99%

Improving Energy Conservation in Wireless Sensor Network Using Energy Harvesting System

Rashid¹,

Khan²,

Gul³

et al. 2018

ijacsa

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Abstract-Wireless Sensor Networks assume an imperative part to monitor and gather information from complex geological ranges. Energy conservation plays a fundamental role in WSNs since such sensor networks are designed to be located in dangerous and non-accessible areas and has gained popularity since the last decade. The main issue of Wireless Sensor Network is energy consumption. Therefore, management of energy consumption of the sensor node is the main area of our research. Sensor nodes use non-changeable batteries for power supply and the lifetime of Sensor node greatly depends on these batteries. The replacement of these batteries is very difficult in many applications, such as an alternative solution to this problem is to use Energy Harvesting system in Wireless Sensor Network to provide a permanent power supply to sensor nodes. This process of extracting energies from nature and converting it into electrical energy is called energy harvesting. Energy can be harvested from the environment for sensor nodes. There are many sources of energies in nature like solar, wind and thermal which can be harvested and used for WSNs. In this research, we suggest to use energy harvesting system for Cluster Heads in a clustering based Wireless Sensor Networks. We will compare our proposed technique to a well-known clustering algorithm Low Energy Adaptive Cluster Hierarchy (LEACH).

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Section: Literature Reviewmentioning

confidence: 99%

Improving Energy Conservation in Wireless Sensor Network Using Energy Harvesting System

Rashid¹,

Khan²,

Gul³

et al. 2018

ijacsa

View full text Add to dashboard Cite

show abstract

“…We also assume that the user is a low-cost and low-complexity device such that it is only equipped with simple storage (e.g., supercapacitors) to hold the energy harvested within each transmission block and has no capability of performing energy accumulation across different blocks. Moreover, the dual-storage scheme proposed in [20] is adopted to support the user's FD operation.…”

Section: System Model and Proposed Protocolsmentioning

confidence: 99%

Wireless-Powered Communication Networks

Niyato¹,

Hossain²,

Kim³

et al. 2016

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Learn the fundamentals of architecture design, protocol optimization, and application development for wireless-powered communication networks with this authoritative guide. Readers will gain a detailed understanding of the issues surrounding architecture and protocol design, with key topics covered including relay-based energy harvesting systems, multiple-antenna systems for simultaneous wireless information and power transfer (SWIPT), performance modeling and analysis, and ambient wireless energy harvesting based cellular systems. Current applications of energy harvesting and transfer in different wireless networking scenarios are discussed, aiding the understanding of practical system development and implementation issues from an engineering perspective. The first book to provide a unified view of energy harvesting and wireless power transfer networks from a communications perspective, this is an essential text for researchers working on wireless communication networks and wireless systems, RF engineers, and wireless application developers.

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“…The termination threshold for the GP approximation case η equals to 10 −2 . The energy arrival in each time slot is assumed to be Gamma distributed, i.e., [t] ∼ G(α, θ), since it can be used to approximate many positive continuous random variables [12]. We set α = 2 and scale θ to obtain different mean average rate¯ = αθ J/slot.…”

Section: Numerical Comparisonmentioning

confidence: 99%

Downlink multiuser beamforming and power control for base stations empowered by renewable energy

Wang

Hong

Chen

2013

2013 IEEE 24th Annual International Symposium on Personal, Indoor, and Mobile Radio Communications (PIMRC)

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Abstract-This work examines offline and online power control policies for efficient usage of renewable energy in the downlink of a multi-antenna wireless system. Two multiuser beamforming schemes are considered, namely, channel inversion (CI) and maximal ratio transmit (MRT) beamforming schemes. Power control policies are derived for both schemes, respectively, with the goal of maximizing the sum throughput by a deadline subject to energy causality and battery storage constraints. With CI beamforming, the power control problem can be formulated as a convex optimization problem, whose solution can be obtained using the directional water-filling algorithm. With MRT beamforming, the power control problem becomes non-convex, due to interference between the signals intended for different users, and, thus, is difficult to solve exactly. However, an efficient solution can be obtained by performing successive approximation into a sequence of geometric programming problems, i.e., by employing the condensation method. Offline power control policies are first derived assuming non-causal knowledge of the energy arrival and channel coefficients over time. Online power control policies are then proposed based on observations gained from the offline policy. The performance of the proposed schemes are demonstrated through numerical simulations.

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Optimal save-then-transmit protocol for energy harvesting wireless transmitters

Cited by 72 publications

References 25 publications

Improving Energy Conservation in Wireless Sensor Network Using Energy Harvesting System

Improving Energy Conservation in Wireless Sensor Network Using Energy Harvesting System

Wireless-Powered Communication Networks

Downlink multiuser beamforming and power control for base stations empowered by renewable energy

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