An Energy-Efficient UWB Transmitter with Wireless Injection Locking for RF Energy-Harvesting Sensors

Kim, Jun-Tae; Heo, Bo-Ram; Kwon, Ickjin

doi:10.3390/s21041426

Cited by 3 publications

(6 citation statements)

References 43 publications

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“…where P IN is the input power which fluctuates over time according to the distribution in Figure 5, the DC output power P DC can be calculated for each rectifier design based on expected value of P IN . By substituting the channel power P CHest from equation (7) as the input power of equation ( 8) and with the simulated PCE of each rectifier design from Figure 13, the DC output power over time can be plotted in Figure 14. To compare the performance of each rectifier based on estimated input power with an isotropic antenna, the total energy within the testing period was calculated by integrating the graph in Figure 14 overtime.…”

Section: Rectifier Optimization Based On Survey Resultsmentioning

confidence: 99%

“…With additional wireless energy sources, the read range can be increased or additional functionalities e.g., temperature or moisture sensing can be added to the tags [4,5]. In wireless sensor networks, battery time of the sensor nodes e.g., wearable sensors can be prolonged by reducing their power consumption or by including the RFEH capability in the devices [6][7][8]. In general, the power consumption of a wireless sensor node ranges from 1 to 12 mW depending on their applications [9,10].…”

Section: Introductionmentioning

confidence: 99%

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Estimation of Harvested RF Energy Based on Survey of Ambient RF Power for Optimized Rectifier Design

Arpanutud

Tontisirin²,

Chudpooti

et al. 2022

Wireless Communications and Mobile Computing

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This paper presents estimation of harvested RF energy by means of measurement survey and rectifier circuit simulation. The survey was done in an indoor environment in Bangkok, Thailand using a low-cost in-house developed measurement system. From the survey, channel power distribution of a signal with 950 MHz center frequency and 20 MHz bandwidth was created. The maximum time averaged channel power is -7.6 dBm whereas the mean value with maximum signal statistic is -11.1 dBm. A single stage rectifier is simulated with 5 different nominal values of RF input power which is used to optimize the rectifier for maximum RF-to-DC power conversion efficiency. The rectifier composes a Schottky diode, a matching network and a simple load consisting of a resistor and a storage capacitor. Parameters of the simplified LC matching network have been varied to match the rectifier’s input impedance to 50 Ω for various nominal values of the RF input power. In addition, the load resistance was varied according to the nominal RF input power for an optimal power conversion efficiency of the rectifier. The rectifier delivers the highest harvested RF energy with a nominal RF input power of -9 dBm which is a value between the maximum and the mean values from the survey. The DC energy converted from ambient RF energy by the rectifier can be estimated. With this information, it can be assessed what type of applications based on available RF energy can be applied for the test area. This rectifier optimization strategy can be applied to any kind of RF signal since it is based on actual measurement results. Moreover, the proposed rectifier can be designed for reconfigurability regarding nominal RF input power at the location of interest by varying the matching network parameters and the load resistance. In practical applications, the reconfigurable rectifier can maintain a high level of power conversion efficiency over a wide range of RF input power. This can be done by optimizing the rectifier’s input matching network and the load resistance for the highest possible power harvested from the environment where the rectifier is located.

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Section: Rectifier Optimization Based On Survey Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Estimation of Harvested RF Energy Based on Survey of Ambient RF Power for Optimized Rectifier Design

Arpanutud

Tontisirin²,

Chudpooti

et al. 2022

Wireless Communications and Mobile Computing

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show abstract

“…To preserve energy efficiency in the complete system, the LC-ADC should be interfaced to an asynchronous processor, such as the SNN described in [6], or send data using a communication protocol which does not require time discretization, such as e.g. the body channel communication used in [10] or a UWB transmitter [26].…”

Section: Discussionmentioning

confidence: 99%

A 1.8–65 fJ/Conv.-Step 64-dB SNDR Continuous- Time Level Crossing ADC Exploiting Dynamic Self-Biasing Comparators

Timmermans,

van Oosterhout,

Fattori

et al. 2024

IEEE J. Solid-State Circuits

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published version features the final layout of the paper including the volume, issue and page numbers. Link to publication General rightsCopyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights.• Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal.If the publication is distributed under the terms of Article 25fa of the Dutch Copyright Act, indicated by the "Taverne" license above, please follow below link for the End User

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“…In case 2 , where C STOR is already fully charged, the V STOR >= V REF condition is detected by the HIC. Therefore, in this case, all of the energy on the inductor needs to be transferred to the battery.…”

Section: Case2: C Stor Fully Chargedmentioning

confidence: 99%

“…These devices are usually powered with lightweight batteries having low capacity that require frequent battery re-charging or replacement, which is undesirable and sometimes difficult in the case of implantable devices. To achieve energy autonomy, widely investigated energy harvesting sources include RF [1][2][3][4], light [5], heat [6], and vibrations [7][8][9]. Among these sources, vibration energy has been extensively investigated due to the abundance of vibrations in the ambient environment.…”

Section: Introductionmentioning

confidence: 99%

Dual Piezoelectric Energy Investing and Harvesting Interface for High-Voltage Input

Khan

Saif

Lee

et al. 2021

Sensors

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A novel harvesting interface for multiple piezoelectric transducers (PZTs) is proposed for high-voltage energy harvesting. Pre-biasing a PZT prior to its mechanical deformation increases its damping force, resulting in higher energy extraction. Unlike the conventional harvesters where a PZT-generated output is assumed to be continuous sinusoidal and output polarity is assumed to be alternating every cycle, PZT-generated output from human motion is expected to be random. Therefore, in the proposed approach, energy is invested to the PZT only when PZT deformation is detected. Upon the motion detection, energy stored at a storage capacitor (CSTOR) from earlier energy harvesting cycle is invested to pre-bias PZT, enhancing energy extraction. The harvested energy is transferred to back CSTOR for energy investment on the next cycle and then excess energy is transferred to the battery. In addition, partial electric charge extraction (PECE) is adapted to extract a partial amount of charges from the PZT every time its voltage approaches the process limit of 40 V. Simulations with 0.35 µm BCD process show 7.61× (with PECE only) and 8.38× (with PECE and energy investment) improvement compared to the conventional rectifier-based harvesting scheme Proposed harvesting interface successfully harvests energy from excitations with open-circuit voltages up to 100 V.

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An Energy-Efficient UWB Transmitter with Wireless Injection Locking for RF Energy-Harvesting Sensors

Cited by 3 publications

References 43 publications

Estimation of Harvested RF Energy Based on Survey of Ambient RF Power for Optimized Rectifier Design

Estimation of Harvested RF Energy Based on Survey of Ambient RF Power for Optimized Rectifier Design

A 1.8–65 fJ/Conv.-Step 64-dB SNDR Continuous- Time Level Crossing ADC Exploiting Dynamic Self-Biasing Comparators

Dual Piezoelectric Energy Investing and Harvesting Interface for High-Voltage Input

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