Ambient RF Energy-Harvesting Technologies for Self-Sustainable Standalone Wireless Sensor Platforms

Kim, Sangkil; Vyas, Rushi; Bito, Jo; Niotaki, Kyriaki; Collado, Ana; Georgiadis, Apostolos; Tentzeris, Manos M.

doi:10.1109/jproc.2014.2357031

Cited by 613 publications

(284 citation statements)

References 50 publications

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“…Exploiting multiple antenna technologies in WPT has been widely studied: multiple-input-multiple-output broadcast channels [8], beamforming designs for multiuser multiple-input-single-output (MISO) [23], physical-layer security problems for multiuser MISO [24], and multiple-antenna interference channels [25]. On the other hand, there are a relatively limited number of studies on WPT for WSNs; different WPT technologies for addressing energy/lifetime problems in WSNs were reviewed in [26], [27]; in [28], the authors studied a distributed estimation system in which some of the multiple-antenna sensors, named super sensors, are capable of WPT to its neighboring sensors via beamforming; and in [29], several multiple-antenna RF-based chargers were used to replenish the wireless sensors and then to switch to the information transmission phase, where each sensor sent a quantized version of its measurement to the FC for estimation.…”

Section: A Previous Workmentioning

confidence: 99%

Wireless Power Transfer for Distributed Estimation in Sensor Networks

Vien¹,

Shin²,

Ishibashi³

2017

IEEE J. Sel. Top. Signal Process.

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This paper studies power allocation for distributed estimation of an unknown scalar random source in sensor networks with a multiple-antenna fusion center (FC), where wireless sensors are equipped with radio-frequency based energy harvesting technology. The sensors' observation is locally processed by using an uncoded amplifyand-forward scheme. The processed signals are then sent to the FC, and are coherently combined at the FC, at which the best linear unbiased estimator (BLUE) is adopted for reliable estimation. We aim to solve the following two power allocation problems: 1) minimizing distortion under various power constraints; and 2) minimizing total transmit power under distortion constraints, where the distortion is measured in terms of mean-squared error of the BLUE. Two iterative algorithms are developed to solve the non-convex problems, which converge at least to a local optimum. In particular, the above algorithms are designed to jointly optimize the amplification coefficients, energy beamforming, and receive filtering. For each problem, a suboptimal design, a single-antenna FC scenario, and a common harvester deployment for colocated sensors, are also studied. Using the powerful semidefinite relaxation framework, our result is shown to be valid for any number of sensors, each with different noise power, and for an arbitrarily number of antennas at the FC. Index TermsAmplify-and-forwarding, best linear unbiased estimator (BLUE), distributed estimation, mean-squared error (MSE), wireless power transfer (WPT).

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Section: A Previous Workmentioning

confidence: 99%

Wireless Power Transfer for Distributed Estimation in Sensor Networks

Vien¹,

Shin²,

Ishibashi³

2017

IEEE J. Sel. Top. Signal Process.

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“…Among these ambient energy sources, there has been a dramatic growth of RF energy harvesting mainly because of the abundant availability of electromagnetic signals such as television/ digital television (TV/DTV) [11][12][13], FM/AM radio [14,15], mobile base stations and mobile phones [16][17][18][19], and Wi-Fi signals [20][21][22][23][24]. The recent interest in RF harvesting has also been driven by the great progress in both wireless communication systems and broadcasting technologies that have availed a lot of freely propagating ambient RF energy [25][26][27][28][29]. While ambient RF sources have a comparably low power density of 0.2 nW/cm 2 to 1 W/cm 2 [26,[30][31] relative to other ambient energy sources such as solar, RF signals have the advantage of being fairly ubiquitous and the associated energy is radiated continuously.…”

Section: Introductionmentioning

confidence: 99%

“…As we get into the future, and the society gets even more wirelessly interconnected, the number of RF energy sources will continue to increase, especially as the number of mobile subscribers to wireless networks increases. The increase in the number of operating mobile phones, together with Wi-Fi routers, laptops and smartphones will greatly avail electromagnetic signals from which useful electrical energy can be extracted [25][26][27][28][29][30][31][32][33][34]. The ubiquitous ambient RF energy can be extracted and used to charge batteries [27] or energize a multiple range of low-power electronic devices, including wearable smart devices [21], RFID tracking tags [35], and wireless sensor devices [13][14][15]36].…”

Section: Introductionmentioning

confidence: 99%

Radio Frequency Energy Harvesting Sources

Nechibvute¹,

Chawanda²,

Taruvinga³

et al. 2017

AEI

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“…Therefore, ambient RF backscatter devices must depend on a relatively large array antenna to fully use weak ambient RF power. By contrast, solar power has a high power density of 100 mW/cm 2 during daytime [4]. Various lighting infrastructures, including white LEDs, have been widely deployed for illumination purposes.…”

Section: Introductionmentioning

confidence: 99%

Ambient Light Backscatter Communication for IoT Applications

Yun¹,

Jang²

2016

Journal of electromagnetic engineering and science

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In this paper, we present an ambient light backscatter communication design that enables Internet of Things (IoT) devices to communicate through the backscattering ambient light emitted from lighting infrastructure or sunlight. The device can selectively modulate ambient light by switching a liquid crystal display (LCD) shutter located on its surface, so that a nearby smart device, which includes a photodiode or a camera, can demodulate this backscattered light information. To verify the practicality of the proposed concept, we design an IoT device equipped with a commercial LCD shutter and a microcontroller. Our device produces ambient light backscattered data at a speed of 100 bps, and these data are successfully decoded by a commercial photodiode module 10 cm away from the IoT device. We believe that our ambient light backscatter communication design is appropriate for implementation in various IoT applications

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Ambient RF Energy-Harvesting Technologies for Self-Sustainable Standalone Wireless Sensor Platforms

Cited by 613 publications

References 50 publications

Wireless Power Transfer for Distributed Estimation in Sensor Networks

Wireless Power Transfer for Distributed Estimation in Sensor Networks

Radio Frequency Energy Harvesting Sources

Ambient Light Backscatter Communication for IoT Applications

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