Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications

Billion-plus devices will reportedly be connected to the internet via the "Internet of Things" (IoT). Most of these gadgets, including wireless sensors that are wirelessly connected to the internet, will not have a wired connection to the electrical grid and will instead rely on the ene...

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Main Author: Zareianjahromi, Seyed Arash
Format: Thesis
Language:English
Published: 2022
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Online Access:http://psasir.upm.edu.my/id/eprint/104089/1/SEYED%20ARASH%20-%20IR.pdf
http://psasir.upm.edu.my/id/eprint/104089/
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spelling my.upm.eprints.1040892023-07-07T02:57:37Z http://psasir.upm.edu.my/id/eprint/104089/ Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications Zareianjahromi, Seyed Arash Billion-plus devices will reportedly be connected to the internet via the "Internet of Things" (IoT). Most of these gadgets, including wireless sensors that are wirelessly connected to the internet, will not have a wired connection to the electrical grid and will instead rely on the energy stored in the batteries to operate themselves. Due to its lifespan and capacity constraints, the battery power source is a barrier to expanding a wireless sensor network to hundreds or millions of nodes. Energy harvesting is a practical method for powering at least specific wireless sensors and devices. Since RF energy harvesting is becoming more widely available, integrated, and compatible with wireless networks, it has become one of the most common energy scavenging technologies. Due to route loss, fast signal attenuation over distance, poor power efficiency of RF-DC converters, and restrictions restricting the highest allowable broadcast signal intensity, RF energy harvesting is severely constrained in its ability to capture large amounts of energy. Even if a matching network is utilized to minimize the input power losses received by the antenna and enhance the power transfer to the rectifier, transistors cannot function at the minimal power level required without an effective rectifier design. Enhancement of the efficiency of RF rectifiers and the reduction of the power consumption of the sensor circuitry and wireless transmitter necessary for the transmission of sensed data to a reader are both critical to enhancing the radio frequency energy harvester (RFEH) system’s overall power conversion energy (PCE). Due to distance and other considerations such as the unavailability of precise and consistent power; consequently, the RF rectifier's design will need to be able to handle a broad range of input power with acceptable efficiency. This work presents a five-stage self-compensated charge pump rectifier in 4 different implementations with the application of the diode-connected MOS transistors technique to decrease the leakage current and the threshold voltage in reverse and forward operation regions respectively with the objectives to achieve high PCE dynamic range above 20% and 1V sensitivity by generating optimal compensation voltage using auxiliary circuit. Each of these implementations has a unique auxiliary circuit that is designed to generate an optimal compensation voltage for each transistor in the main charge pump path, to convert RF signals to DC voltage efficiently. In comparison to conventional threshold voltage compensation circuits, where the level of compensation is restricted by the circuit construction and changes with input power, the proposed implementation achieves greater dynamic PCE throughout a wide input power range. This work is conceived and executed in a 130nm CMOS Silterra technology and obtained a broad range of 15 dBm with an efficiency of more than 20% and a sensitivity of -21 dBm for 1V output and a maximum PCE of 39.9% at -9 dBm of input power while driving a 1 MΩ load at 920 MHz. 2022-05 Thesis NonPeerReviewed text en http://psasir.upm.edu.my/id/eprint/104089/1/SEYED%20ARASH%20-%20IR.pdf Zareianjahromi, Seyed Arash (2022) Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications. Masters thesis, Universiti Putra Malaysia. Semiconductor rectifiers Compensated semiconductors Radio frequency
institution Universiti Putra Malaysia
building UPM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
language English
topic Semiconductor rectifiers
Compensated semiconductors
Radio frequency
spellingShingle Semiconductor rectifiers
Compensated semiconductors
Radio frequency
Zareianjahromi, Seyed Arash
Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
description Billion-plus devices will reportedly be connected to the internet via the "Internet of Things" (IoT). Most of these gadgets, including wireless sensors that are wirelessly connected to the internet, will not have a wired connection to the electrical grid and will instead rely on the energy stored in the batteries to operate themselves. Due to its lifespan and capacity constraints, the battery power source is a barrier to expanding a wireless sensor network to hundreds or millions of nodes. Energy harvesting is a practical method for powering at least specific wireless sensors and devices. Since RF energy harvesting is becoming more widely available, integrated, and compatible with wireless networks, it has become one of the most common energy scavenging technologies. Due to route loss, fast signal attenuation over distance, poor power efficiency of RF-DC converters, and restrictions restricting the highest allowable broadcast signal intensity, RF energy harvesting is severely constrained in its ability to capture large amounts of energy. Even if a matching network is utilized to minimize the input power losses received by the antenna and enhance the power transfer to the rectifier, transistors cannot function at the minimal power level required without an effective rectifier design. Enhancement of the efficiency of RF rectifiers and the reduction of the power consumption of the sensor circuitry and wireless transmitter necessary for the transmission of sensed data to a reader are both critical to enhancing the radio frequency energy harvester (RFEH) system’s overall power conversion energy (PCE). Due to distance and other considerations such as the unavailability of precise and consistent power; consequently, the RF rectifier's design will need to be able to handle a broad range of input power with acceptable efficiency. This work presents a five-stage self-compensated charge pump rectifier in 4 different implementations with the application of the diode-connected MOS transistors technique to decrease the leakage current and the threshold voltage in reverse and forward operation regions respectively with the objectives to achieve high PCE dynamic range above 20% and 1V sensitivity by generating optimal compensation voltage using auxiliary circuit. Each of these implementations has a unique auxiliary circuit that is designed to generate an optimal compensation voltage for each transistor in the main charge pump path, to convert RF signals to DC voltage efficiently. In comparison to conventional threshold voltage compensation circuits, where the level of compensation is restricted by the circuit construction and changes with input power, the proposed implementation achieves greater dynamic PCE throughout a wide input power range. This work is conceived and executed in a 130nm CMOS Silterra technology and obtained a broad range of 15 dBm with an efficiency of more than 20% and a sensitivity of -21 dBm for 1V output and a maximum PCE of 39.9% at -9 dBm of input power while driving a 1 MΩ load at 920 MHz.
format Thesis
author Zareianjahromi, Seyed Arash
author_facet Zareianjahromi, Seyed Arash
author_sort Zareianjahromi, Seyed Arash
title Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
title_short Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
title_full Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
title_fullStr Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
title_full_unstemmed Design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
title_sort design of self-compensated rectifier with auxiliary circuit for radio frequency energy-harvesting applications
publishDate 2022
url http://psasir.upm.edu.my/id/eprint/104089/1/SEYED%20ARASH%20-%20IR.pdf
http://psasir.upm.edu.my/id/eprint/104089/
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score 13.211869