Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes

Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes

In the context of the Internet of Things, billions of devices—especially sensors—will be linked together in the next few years. A core component of wireless passive sensor nodes is the rectifier, which has to provide the circuit with sufficient operating voltage. In these devices...

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Main Authors: Dominik Mair, Manuel Ferdik, Christof Happ, Michael Renzler, Thomas Ussmueller
Format: Article
Language:English
Published: MDPI AG 2019-10-01
Series:Sensors
Subjects:
wireless sensors
rectifier
power conversion efficiency
voltage conversion efficiency
impedance matching
internet of things
radio frequency identification
circuit optimization
conjugate gradient
low-power electronics
wireless power transmission
Online Access:https://www.mdpi.com/1424-8220/19/20/4527
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spelling doaj-415f9d1349fe49bd9a1509e23bc396d62020-11-25T01:56:43ZengMDPI AGSensors1424-82202019-10-011920452710.3390/s19204527s19204527Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor NodesDominik Mair0Manuel Ferdik1Christof Happ2Michael Renzler3Thomas Ussmueller4Microelectronics and Implantable Systems Group, Department of Mechatronics, University of Innsbruck, 6020 Innsbruck, AustriaMicroelectronics and Implantable Systems Group, Department of Mechatronics, University of Innsbruck, 6020 Innsbruck, AustriaMicroelectronics and Implantable Systems Group, Department of Mechatronics, University of Innsbruck, 6020 Innsbruck, AustriaMicroelectronics and Implantable Systems Group, Department of Mechatronics, University of Innsbruck, 6020 Innsbruck, AustriaMicroelectronics and Implantable Systems Group, Department of Mechatronics, University of Innsbruck, 6020 Innsbruck, AustriaIn the context of the Internet of Things, billions of devices—especially sensors—will be linked together in the next few years. A core component of wireless passive sensor nodes is the rectifier, which has to provide the circuit with sufficient operating voltage. In these devices, the rectifier has to be as energy efficient as possible in order to guarantee an optimal operation. Therefore, a numerical optimization scheme is proposed in this paper, which is able to find a unique optimal solution for an integrated Complementary Metal-Oxide-Semiconductor (CMOS) rectifier circuit with Self-Vth-Cancellation (SVC). An exploration of the parameter space is carried out in order to generate a meaningful target function for enhancing the rectified power for a fixed communication distance. In this paper, a mean conversion efficiency is introduced, which is a more valid target function for optimization than the Voltage Conversion Efficiency (VCE) and the commonly used Power Conversion Efficiency (PCE) and is defined as the arithmetic mean between PCE and VCE. Various trade-offs between output voltage, PCE, VCE and MCE are shown, which provide valuable information for low power rectifier designs. With the proposed method, a rectifier in a low power 55 nm process from Globalfoundries (GF55LPe) is optimized and simulated at −30 dBm input power. A mean PCE of 63.33% and a mean VCE of 63.40% is achieved.https://www.mdpi.com/1424-8220/19/20/4527wireless sensorsrectifierpower conversion efficiencyvoltage conversion efficiencyimpedance matchinginternet of thingsradio frequency identificationcircuit optimizationconjugate gradientlow-power electronicswireless power transmission
collection DOAJ
language English
format Article
sources DOAJ
author Dominik Mair
Manuel Ferdik
Christof Happ
Michael Renzler
Thomas Ussmueller
spellingShingle Dominik Mair
Manuel Ferdik
Christof Happ
Michael Renzler
Thomas Ussmueller
Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes
Sensors
wireless sensors
rectifier
power conversion efficiency
voltage conversion efficiency
impedance matching
internet of things
radio frequency identification
circuit optimization
conjugate gradient
low-power electronics
wireless power transmission
author_facet Dominik Mair
Manuel Ferdik
Christof Happ
Michael Renzler
Thomas Ussmueller
author_sort Dominik Mair
title Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes
title_short Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes
title_full Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes
title_fullStr Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes
title_full_unstemmed Numerical Optimization of a Fully Cross-Coupled Rectifier Circuit for Wireless Passive Ultra Low Power Sensor Nodes
title_sort numerical optimization of a fully cross-coupled rectifier circuit for wireless passive ultra low power sensor nodes
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2019-10-01
description In the context of the Internet of Things, billions of devices—especially sensors—will be linked together in the next few years. A core component of wireless passive sensor nodes is the rectifier, which has to provide the circuit with sufficient operating voltage. In these devices, the rectifier has to be as energy efficient as possible in order to guarantee an optimal operation. Therefore, a numerical optimization scheme is proposed in this paper, which is able to find a unique optimal solution for an integrated Complementary Metal-Oxide-Semiconductor (CMOS) rectifier circuit with Self-Vth-Cancellation (SVC). An exploration of the parameter space is carried out in order to generate a meaningful target function for enhancing the rectified power for a fixed communication distance. In this paper, a mean conversion efficiency is introduced, which is a more valid target function for optimization than the Voltage Conversion Efficiency (VCE) and the commonly used Power Conversion Efficiency (PCE) and is defined as the arithmetic mean between PCE and VCE. Various trade-offs between output voltage, PCE, VCE and MCE are shown, which provide valuable information for low power rectifier designs. With the proposed method, a rectifier in a low power 55 nm process from Globalfoundries (GF55LPe) is optimized and simulated at −30 dBm input power. A mean PCE of 63.33% and a mean VCE of 63.40% is achieved.
topic wireless sensors
rectifier
power conversion efficiency
voltage conversion efficiency
impedance matching
internet of things
radio frequency identification
circuit optimization
conjugate gradient
low-power electronics
wireless power transmission
url https://www.mdpi.com/1424-8220/19/20/4527
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AT christofhapp numericaloptimizationofafullycrosscoupledrectifiercircuitforwirelesspassiveultralowpowersensornodes
AT michaelrenzler numericaloptimizationofafullycrosscoupledrectifiercircuitforwirelesspassiveultralowpowersensornodes
AT thomasussmueller numericaloptimizationofafullycrosscoupledrectifiercircuitforwirelesspassiveultralowpowersensornodes
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