Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting
This article presents a two-stage rectifier with novel DC-boosted gate bias for RF energy harvesting. The auxiliary gate bias enables rectifier to operate when input amplitude is smaller than its transistor threshold voltage while constraining the positive gate voltage during off state to reduce the...
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sg-ntu-dr.10356-1521042021-08-26T08:43:57Z Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting Lau, Wendy Wee Yee Ho, Heng Wah Siek, Liter School of Electrical and Electronic Engineering Global Foundries VIRTUS, IC Design Centre of Excellence Engineering::Electrical and electronic engineering::Electric power Energy Harvesting Rectifiers RF-DC Converters Deep Neural Network Deep Learning Design Automation Design Optimization This article presents a two-stage rectifier with novel DC-boosted gate bias for RF energy harvesting. The auxiliary gate bias enables rectifier to operate when input amplitude is smaller than its transistor threshold voltage while constraining the positive gate voltage during off state to reduce the reverse leakage current. An automated design optimization methodology using Deep Neural Network (DNN) to maximize efficiency is presented. The DNN is shown to accurately model SPICE simulated response of rectifier. Hence, the design phase turnaround time is minimized with fast prediction of optimized design parameters. The proposed rectifier has been fabricated in 65 nm standard CMOS technology. A maximum power conversion efficiency of 73.6% is measured at 2.45 GHz with input power of -6 dBm. The proposed rectifier has a measured sensitivity of -12 dBm for 1 V output voltage. Economic Development Board (EDB) This work was supported in part by the Singapore Economic Development Board (EDB) and in part by the GlobalFoundries Singapore Pte. Ltd 2021-08-26T08:43:57Z 2021-08-26T08:43:57Z 2020 Journal Article Lau, W. W. Y., Ho, H. W. & Siek, L. (2020). Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting. IEEE Transactions On Circuits and Systems I: Regular Papers, 67(12), 4322-4333. https://dx.doi.org/10.1109/TCSI.2020.3022280 1549-8328 https://hdl.handle.net/10356/152104 10.1109/TCSI.2020.3022280 12 67 4322 4333 en IEEE Transactions on Circuits and Systems I: Regular Papers © 2020 IEEE. All rights reserved. |
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Engineering::Electrical and electronic engineering::Electric power Energy Harvesting Rectifiers RF-DC Converters Deep Neural Network Deep Learning Design Automation Design Optimization |
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Engineering::Electrical and electronic engineering::Electric power Energy Harvesting Rectifiers RF-DC Converters Deep Neural Network Deep Learning Design Automation Design Optimization Lau, Wendy Wee Yee Ho, Heng Wah Siek, Liter Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting |
| description |
This article presents a two-stage rectifier with novel DC-boosted gate bias for RF energy harvesting. The auxiliary gate bias enables rectifier to operate when input amplitude is smaller than its transistor threshold voltage while constraining the positive gate voltage during off state to reduce the reverse leakage current. An automated design optimization methodology using Deep Neural Network (DNN) to maximize efficiency is presented. The DNN is shown to accurately model SPICE simulated response of rectifier. Hence, the design phase turnaround time is minimized with fast prediction of optimized design parameters. The proposed rectifier has been fabricated in 65 nm standard CMOS technology. A maximum power conversion efficiency of 73.6% is measured at 2.45 GHz with input power of -6 dBm. The proposed rectifier has a measured sensitivity of -12 dBm for 1 V output voltage. |
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School of Electrical and Electronic Engineering |
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School of Electrical and Electronic Engineering Lau, Wendy Wee Yee Ho, Heng Wah Siek, Liter |
| format |
Article |
| author |
Lau, Wendy Wee Yee Ho, Heng Wah Siek, Liter |
| author_sort |
Lau, Wendy Wee Yee |
| title |
Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting |
| title_short |
Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting |
| title_full |
Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting |
| title_fullStr |
Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting |
| title_full_unstemmed |
Deep neural network (DNN) optimized design of 2.45 GHz CMOS rectifier with 73.6% peak efficiency for RF energy harvesting |
| title_sort |
deep neural network (dnn) optimized design of 2.45 ghz cmos rectifier with 73.6% peak efficiency for rf energy harvesting |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/152104 |
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1709685308822388736 |