Publications - Link Lab

Steven Bowers Publications

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2024 (7)
Kudelin, I.; Groman, W.; Ji, Q.; Guo, J.; Kelleher, M.; Lee, D.; Nakamura, T.; McLemore, C. A.; Shirmohammadi, P.; Hanifi, S.; Cheng, H.; Jin, N.; Wu, L.; Halladay, S.; Luo, Y.; Dai, Z.; Jin, W.; Bai, J.; Liu, Y.; Zhang, W.; Xiang, C.; Chang, L.; Iltchenko, V.; Miller, O. D.; Matsko, A. B.; Bowers, S. M. ; Rakich, P. T.; Campbell, J. C.; Bowers, J. E.; Vahala, K. J.; Quinlan, F.; and Diddams, S. A. Photonic chip-based low-noise microwave oscillator. Nature . 2024.
Photonic chip-based low-noise microwave oscillator [link] Paper link bibtex
Sun, S.; Wang, B.; Liu, K.; Harrington, M.; Tabatabaei, F.; Liu, R.; Wang, J.; Hanifi, S.; Morgan, J. D.; Jahanbozorgi, M.; Yang, Z.; Bowers, S. M. ; Morton, P. A.; Nelson, K.; Beling, A.; Blumenthal, D.; and Yi, X. Integrated optical frequency division for microwave and mmWave generation. Nature (London) . 2024.
Integrated optical frequency division for microwave and mmWave generation [link] Paper link bibtex
Shen, X.; Costanzo, R.; Singaraju, P.; Blalock, T. N.; Beling, A.; and Bowers, S. M. Compact Heterogeneously Integrated Optical Phase-Locked Loop for 10 GHz to 40 GHz Optical Frequency Difference Locking. Journal of lightwave technology (Print) . 2024.
Compact Heterogeneously Integrated Optical Phase-Locked Loop for 10 GHz to 40 GHz Optical Frequency Difference Locking [link] Paper link bibtex
Sun, S.; Harrington, M.; Tabatabaei, F. S.; Hanifi, S.; Liu, K.; Wang, J.; Wang, B.; Yang, Z.; Liu, R.; Morgan, J. D.; Bowers, S. M. ; Morton, P. A.; Nelson, K.; Beling, A.; Blumenthal, D. J.; and Xu, Y. Kerr optical frequency division with integrated photonics for stable microwave and mmWave generation. arXiv (Cornell University) . 2024.
Kerr optical frequency division with integrated photonics for stable microwave and mmWave generation [link] Paper link bibtex
Shirmohammadi, P.; and Bowers, S. M. A Wideband 2.18-13.51 GHz Ultra-Low Additive Phase Noise Power Amplifier in InP 250nm HBT. Unknown Journal . 2024.
A Wideband 2.18-13.51 GHz Ultra-Low Additive Phase Noise Power Amplifier in InP 250nm HBT [link] Paper link bibtex
Hanifi, S.; and Bowers, S. M. Low-Additive Phase Noise Low-Power Static Frequency Dividers. Unknown Journal . 2024.
Low-Additive Phase Noise Low-Power Static Frequency Dividers [link] Paper link bibtex
Kudelin, I.; Shirmohammadi, P.; Groman, W.; Hanifi, S.; Kelleher, M.; Lee, D.; Nakamura, T.; McLemore, C. A.; Lind, A.; Meyer, D. G.; Bai, J.; Campbell, J. C.; Bowers, S. M. ; Quinlan, F.; and Diddams, S. A. Tunable X-band opto-electronic synthesizer with ultralow phase noise. arXiv (Cornell University) . 2024.
Tunable X-band opto-electronic synthesizer with ultralow phase noise [link] Paper link bibtex
2023 (9)
Sun, S.; Wang, B.; Liu, K.; Harrington, M.; Tabatabaei, F. S.; Liu, R.; Wang, J.; Hanifi, S.; Morgan, J. D.; Jahanbozorgi, M.; Yang, Z.; Bowers, S. M. ; Morton, P. A.; Nelson, K.; Beling, A.; Blumenthal, D. J.; and Xu, Y. Integrated optical frequency division for stable microwave and mmWave generation. arXiv (Cornell University) . 2023.
Integrated optical frequency division for stable microwave and mmWave generation [link] Paper link bibtex
Kudelin, I.; Groman, W.; Ji, Q.; Guo, J.; Kelleher, M.; Lee, D.; Nakamura, T.; McLemore, C. A.; Shirmohammadi, P.; Hanifi, S.; Cheng, H.; Jin, N.; Halliday, S.; Dai, Z.; Wu, L.; Jin, W.; Liu, Y.; Zhang, W.; Xiang, C.; Iltchenko, V.; Miller, O. D.; Matsko, A. B.; Bowers, S. M. ; Rakich, P. T.; Campbell, J. C.; Bowers, J. E.; Vahala, K. J.; Quinlan, F.; and Diddams, S. A. Photonic chip-based low noise microwave oscillator. arXiv (Cornell University) . 2023.
Photonic chip-based low noise microwave oscillator [link] Paper link bibtex
Zhang, L.; Duvvuri, D.; Bhattacharya, S.; Dissanayake, A.; Liu, X.; Bishop, H. L.; Zhang, Y.; Blalock, T. N.; Calhoun, B. H.; and Bowers, S. M. A -102dBm Sensitivity, 2.2μA Packet-Level-Duty-cycled Wake-Up Receiver with ADPLL achieving -30dB SIR. Unknown Journal . 2023.
A -102dBm Sensitivity, 2.2μA Packet-Level-Duty-cycled Wake-Up Receiver with ADPLL achieving -30dB SIR [link] Paper link bibtex
Sheth, J.; Zhang, L.; Shen, X.; Iyer, V.; and Bowers, S. M. A Current-Mode Multiphase Digital Transmitter With a Single-Footprint Transformer-Based Asymmetric Doherty Output Network. IEEE open journal of the Solid-State Circuits Society . 2023.
A Current-Mode Multiphase Digital Transmitter With a Single-Footprint Transformer-Based Asymmetric Doherty Output Network [link] Paper link bibtex
Zhang, L.; Iyer, V.; Sheth, J.; Xie, L.; Weikle, R. M.; and Bowers, S. M. $F$ Band Distributed Active Transformer Power Amplifier Achieving 12 Gb/s in InP 130-nm HBT. IEEE Transactions on Microwave Theory and Techniques . 2023.
$F$ Band Distributed Active Transformer Power Amplifier Achieving 12 Gb/s in InP 130-nm HBT [link] Paper link bibtex
Iyer, V.; Sheth, J.; Zhang, L.; Weikle, R. M.; and Bowers, S. M. A 15.3-dBm, 18.3% PAE F-Band Power Amplifier in 130-nm InP HBT With Modulation Measurements. IEEE microwave and wireless technology letters . 2023.
A 15.3-dBm, 18.3% PAE F-Band Power Amplifier in 130-nm InP HBT With Modulation Measurements [link] Paper link bibtex
Kudelin, I.; Shirmohammadi, P.; Groman, W.; Hanifi, S.; Kelleher, M.; Lee, D.; McLemore, C. A.; Lind, A.; Bowers, S. M. ; Quinlan, F.; and Diddams, S. A. Tunable opto-electronic synthesizer at 10 GHz with ultralow phase noise. Unknown Journal . 2023.
Tunable opto-electronic synthesizer at 10 GHz with ultralow phase noise [link] Paper link bibtex
Tabatabaei, F. S.; Morgan, J. D.; Sun, S.; Hanifi, S.; Liu, R.; Estrella, S.; Woodson, M.; Bowers, S. M. ; Xu, Y.; and Beling, A. Generation of 10.2 dBm millimeter-wave power at 100 GHz using soliton microcomb and modified uni-traveling carrier photodiode. Unknown Journal . 2023.
Generation of 10.2 dBm millimeter-wave power at 100 GHz using soliton microcomb and modified uni-traveling carrier photodiode [link] Paper link bibtex
Zhang, L.; Duvvuri, D.; Bhattacharya, S.; Dissanayake, A.; Liu, X.; Bishop, H. L.; Zhang, Y.; Blalock, T. N.; Calhoun, B. H.; and Bowers, S. M. A -102dBm Sensitivity, 2.2μA Packet-Level-Duty-cycled Wake-Up Receiver with ADPLL achieving -30dB SIR. Unknown Journal . 2023.
A -102dBm Sensitivity, 2.2μA Packet-Level-Duty-cycled Wake-Up Receiver with ADPLL achieving -30dB SIR [link] Paper link bibtex
2022 (10)
Dissanayake, A.; Bishop, H. L.; Bowers, S. M. ; and Calhoun, B. H. A 2.4 GHz-91.5 dBm Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver. IEEE Journal of Solid-state Circuits . 2022.
A 2.4 GHz-91.5 dBm Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver [link] Paper link bibtex
Shen, X.; Duvvuri, D.; Bassirian, P.; Bishop, H. L.; Liu, X.; Dissanayake, A.; Zhang, Y.; Blalock, T. N.; Calhoun, B. H.; and Bowers, S. M. A 184-nW, −78.3-dBm Sensitivity Antenna-Coupled Supply, Temperature, and Interference-Robust Wake-Up Receiver at 4.9 GHz. IEEE transactions on microwave theory and techniques . 2022.
A 184-nW, −78.3-dBm Sensitivity Antenna-Coupled Supply, Temperature, and Interference-Robust Wake-Up Receiver at 4.9 GHz [link] Paper link bibtex
Mercier, P. P.; Calhoun, B. H.; Wang, P. P.; Dissanayake, A.; Zhang, L.; Hall, D. A.; and Bowers, S. M. Low-Power RF Wake-Up Receivers: Analysis, Tradeoffs, and Design. IEEE open journal of the Solid-State Circuits Society . 2022.
Low-Power RF Wake-Up Receivers: Analysis, Tradeoffs, and Design [link] Paper link bibtex
Yu, F.; Tzu, T.; Gao, J.; Fatema, T.; Sun, K.; Singaraju, P.; Bowers, S. M. ; Reyes, C.; and Beling, A. High-Power High-Speed MUTC Waveguide Photodiodes Integrated on Si 3 N 4 /Si Platform Using Micro-Transfer Printing. IEEE Journal of Selected Topics in Quantum Electronics . 2022.
High-Power High-Speed MUTC Waveguide Photodiodes Integrated on Si<sub>3</sub>N<sub>4</sub>/Si Platform Using Micro-Transfer Printing [link] Paper link bibtex
Zhang, L.; Iyer, V.; Sheth, J.; Xie, L.; Weikle, R. M.; and Bowers, S. M. A 117.5-130 GHz 22.1 dBm 11.5% PAE DAT Based Power Amplifier in InP 130 nm HBT Technology. Unknown Journal . 2022.
A 117.5-130 GHz 22.1 dBm 11.5% PAE DAT Based Power Amplifier in InP 130 nm HBT Technology [link] Paper link bibtex
Iyer, V.; Sheth, J.; Zhang, L.; Weikle, R. M.; and Bowers, S. M. A 90-125 GHz Stacked PA in 130 nm InP HBT with 18.3 % peak PAE at 15.3 dBm Output Power. Unknown Journal . 2022.
A 90-125 GHz Stacked PA in 130 nm InP HBT with 18.3 % peak PAE at 15.3 dBm Output Power [link] Paper link bibtex
Shen, X.; Costanzo, R.; Singaraju, P.; and Bowers, S. M. Compact Integrated Phase Locked Loop for Optical Frequency Difference Locking. Unknown Journal . 2022.
Compact Integrated Phase Locked Loop for Optical Frequency Difference Locking [link] Paper link bibtex
Dissanayake, A.; Bishop, H. L.; Bowers, S. M. ; and Calhoun, B. H. A 2.4 GHz-91.5 dBm Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver. IEEE Journal of Solid-state Circuits . 2022.
A 2.4 GHz-91.5 dBm Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver [link] Paper link bibtex
Shen, X.; Duvvuri, D.; Bassirian, P.; Bishop, H. L.; Liu, X.; Dissanayake, A.; Zhang, Y.; Blalock, T. N.; Calhoun, B. H.; and Bowers, S. M. A 184-nW, −78.3-dBm Sensitivity Antenna-Coupled Supply, Temperature, and Interference-Robust Wake-Up Receiver at 4.9 GHz. IEEE transactions on microwave theory and techniques . 2022.
A 184-nW, −78.3-dBm Sensitivity Antenna-Coupled Supply, Temperature, and Interference-Robust Wake-Up Receiver at 4.9 GHz [link] Paper link bibtex
Mercier, P. P.; Calhoun, B. H.; Wang, P. P.; Dissanayake, A.; Zhang, L.; Hall, D. A.; and Bowers, S. M. Low-Power RF Wake-Up Receivers: Analysis, Tradeoffs, and Design. IEEE open journal of the Solid-State Circuits Society . 2022.
Low-Power RF Wake-Up Receivers: Analysis, Tradeoffs, and Design [link] Paper link bibtex
2021 (13)
Margalit, N.; Xiang, C.; Bowers, S. M. ; Bjorlin, A.; Blum, R.; and Bowers, J. E. Perspective on the future of silicon photonics and electronics. Applied physics letters . 2021.
Perspective on the future of silicon photonics and electronics [link] Paper link bibtex
Shen, X.; Morgan, J. D.; Costanzo, R.; Sun, K.; Woodson, M.; Estrella, S.; Beling, A.; and Bowers, S. M. High-Power V -Band-to- G -Band Photonically Driven Electromagnetic Emitters. IEEE Transactions on Microwave Theory and Techniques . 2021.
High-Power <i>V</i>-Band-to-<i>G</i>-Band Photonically Driven Electromagnetic Emitters [link] Paper link bibtex
Costanzo, R.; Gao, J.; Shen, X.; Yu, Q.; Alabdulwahab, A.; Beling, A.; and Bowers, S. M. Low-Noise Balanced Photoreceiver With InP-on-Si Photodiodes and SiGe BiCMOS Transimpedance Amplifier. Journal of lightwave technology . 2021.
Low-Noise Balanced Photoreceiver With InP-on-Si Photodiodes and SiGe BiCMOS Transimpedance Amplifier [link] Paper link bibtex
Sheth, J.; and Bowers, S. M. A Four-Way Nested Digital Doherty Power Amplifier for Low-Power Applications. IEEE Transactions on Microwave Theory and Techniques . 2021.
A Four-Way Nested Digital Doherty Power Amplifier for Low-Power Applications [link] Paper link bibtex
Bishop, H. L.; Dissanayake, A.; Bowers, S. M. ; and Calhoun, B. H. 21.5 An Integrated 2.4GHz -91.5dBm-Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver Achieving 2μ W at 100ms Latency. Unknown Journal . 2021.
21.5 An Integrated 2.4GHz -91.5dBm-Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver Achieving 2μ W at 100ms Latency [link] Paper link bibtex
Sun, K.; Gao, J.; Costanzo, R.; Tzu, T.; Bowers, S. M. ; and Beling, A. Germanium Photodiode Arrays on Silicon-On-Insulator With On-Chip Bias Circuit. IEEE photonics technology letters . 2021.
Germanium Photodiode Arrays on Silicon-On-Insulator With On-Chip Bias Circuit [link] Paper link bibtex
Duvvuri, D.; Shen, X.; Bassirian, P.; Bishop, H. L.; Liu, X.; Chen, C.; Dissanayake, A.; Zhang, Y.; Blalock, T. N.; Calhoun, B. H.; and Bowers, S. M. A 366 nW, −74.5 dBm Sensitivity Antenna-Coupled Wakeup Receiver at 4.9 GHz with Integrated Voltage Regulation and References. Unknown Journal . 2021.
A 366 nW, −74.5 dBm Sensitivity Antenna-Coupled Wakeup Receiver at 4.9 GHz with Integrated Voltage Regulation and References [link] Paper link bibtex
Dissanayake, A.; Bowers, S. M. ; and Calhoun, B. H. Stacked Transconductance Boosting for Ultra-Low Power 2.4GHz RF Front-End Design. Unknown Journal . 2021.
Stacked Transconductance Boosting for Ultra-Low Power 2.4GHz RF Front-End Design [link] Paper link bibtex
Nanzer, J. A.; and Bowers, S. M. IMS2021 Technical Lectures. IEEE microwave magazine . 2021.
IMS2021 Technical Lectures [link] Paper link bibtex
Bishop, H. L.; Dissanayake, A.; Bowers, S. M. ; and Calhoun, B. H. 21.5 An Integrated 2.4GHz -91.5dBm-Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver Achieving 2μ W at 100ms Latency. Unknown Journal . 2021.
21.5 An Integrated 2.4GHz -91.5dBm-Sensitivity Within-Packet Duty-Cycled Wake-Up Receiver Achieving 2μ W at 100ms Latency [link] Paper link bibtex
Duvvuri, D.; Shen, X.; Bassirian, P.; Bishop, H. L.; Liu, X.; Chen, C.; Dissanayake, A.; Zhang, Y.; Blalock, T. N.; Calhoun, B. H.; and Bowers, S. M. A 366 nW, −74.5 dBm Sensitivity Antenna-Coupled Wakeup Receiver at 4.9 GHz with Integrated Voltage Regulation and References. Unknown Journal . 2021.
A 366 nW, −74.5 dBm Sensitivity Antenna-Coupled Wakeup Receiver at 4.9 GHz with Integrated Voltage Regulation and References [link] Paper link bibtex
Dissanayake, A.; Bowers, S. M. ; and Calhoun, B. H. Stacked Transconductance Boosting for Ultra-Low Power 2.4GHz RF Front-End Design. Unknown Journal . 2021.
Stacked Transconductance Boosting for Ultra-Low Power 2.4GHz RF Front-End Design [link] Paper link bibtex
2020 (13)
Bassirian, P.; Duvvuri, D.; Liu, N.; Truesdell, D. S.; Tsao, H.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. Design of an S-Band Nanowatt-Level Wakeup Receiver With Envelope Detector-First Architecture. IEEE transactions on microwave theory and techniques . 2020.
Design of an S-Band Nanowatt-Level Wakeup Receiver With Envelope Detector-First Architecture [link] Paper link bibtex
Costanzo, R.; and Bowers, S. M. A 10-GHz Bandwidth Transimpedance Amplifier With Input DC Photocurrent Compensation Loop. IEEE microwave and wireless components letters . 2020.
A 10-GHz Bandwidth Transimpedance Amplifier With Input DC Photocurrent Compensation Loop [link] Paper link bibtex
Bassirian, P.; Duvvuri, D.; Truesdell, D. S.; Liu, N.; Calhoun, B. H.; and Bowers, S. M. 30.1 A Temperature-Robust 27.6nW −65dBm Wakeup Receiver at 9.6GHz X-Band. Unknown Journal . 2020.
30.1 A Temperature-Robust 27.6nW −65dBm Wakeup Receiver at 9.6GHz X-Band [link] Paper link bibtex
Dissanayake, A.; Bishop, H. L.; Moody, J.; Muhlbauer, H.; Calhoun, B. H.; and Bowers, S. M. A Multichannel, MEMS-Less −99dBm 260nW Bit-Level Duty Cycled Wakeup Receiver. Unknown Journal . 2020.
A Multichannel, MEMS-Less −99dBm 260nW Bit-Level Duty Cycled Wakeup Receiver [link] Paper link bibtex
Dissanayake, A.; Moody, J.; Bishop, H. L.; Truesdell, D. S.; Muhlbauer, H.; Lu, R.; Gao, A.; Gong, S.; Calhoun, B. H.; and Bowers, S. M. A- 108dBm Sensitivity, -28dB SIR, 130nW to 41µW, Digitally Reconfigurable Bit-Level Duty-Cycled Wakeup and Data Receiver. Unknown Journal . 2020.
A- 108dBm Sensitivity, -28dB SIR, 130nW to 41µW, Digitally Reconfigurable Bit-Level Duty-Cycled Wakeup and Data Receiver [link] Paper link bibtex
Sheth, J.; and Bowers, S. M. A Differential Digital 4-Way Doherty Power Amplifier with 48% Peak Drain Efficiency for Low Power Applications. Unknown Journal . 2020.
A Differential Digital 4-Way Doherty Power Amplifier with 48% Peak Drain Efficiency for Low Power Applications [link] Paper link bibtex
Costanzo, R.; Yu, Q.; Shen, X.; Gao, J.; Beling, A.; and Bowers, S. M. Low-Noise Balanced Photoreceiver with Waveguide SiN Photodetectors and SiGe TIA. Conference on Lasers and Electro-Optics . 2020.
Low-Noise Balanced Photoreceiver with Waveguide SiN Photodetectors and SiGe TIA [link] Paper link bibtex
Sun, K.; Costanzo, R.; Tzu, T.; Bowers, S. M. ; and Beling, A. Foundry-Enabled Ge Photodiode Arrays on Si on Insulator (SOI) with On-Chip Biasing Circuit. Unknown Journal . 2020.
Foundry-Enabled Ge Photodiode Arrays on Si on Insulator (SOI) with On-Chip Biasing Circuit [link] Paper link bibtex
Bassirian, P.; Duvvuri, D.; Liu, N.; Truesdell, D. S.; Tsao, H.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. Design of an S-Band Nanowatt-Level Wakeup Receiver With Envelope Detector-First Architecture. IEEE transactions on microwave theory and techniques . 2020.
Design of an S-Band Nanowatt-Level Wakeup Receiver With Envelope Detector-First Architecture [link] Paper link bibtex
Bassirian, P.; Duvvuri, D.; Truesdell, D. S.; Liu, N.; Calhoun, B. H.; and Bowers, S. M. 30.1 A Temperature-Robust 27.6nW −65dBm Wakeup Receiver at 9.6GHz X-Band. Unknown Journal . 2020.
30.1 A Temperature-Robust 27.6nW −65dBm Wakeup Receiver at 9.6GHz X-Band [link] Paper link bibtex
Dissanayake, A.; Bishop, H. L.; Moody, J.; Muhlbauer, H.; Calhoun, B. H.; and Bowers, S. M. A Multichannel, MEMS-Less −99dBm 260nW Bit-Level Duty Cycled Wakeup Receiver. Unknown Journal . 2020.
A Multichannel, MEMS-Less −99dBm 260nW Bit-Level Duty Cycled Wakeup Receiver [link] Paper link bibtex
Dissanayake, A.; Moody, J.; Bishop, H. L.; Truesdell, D. S.; Muhlbauer, H.; Lu, R.; Gao, A.; Gong, S.; Calhoun, B. H.; and Bowers, S. M. A- 108dBm Sensitivity, -28dB SIR, 130nW to 41µW, Digitally Reconfigurable Bit-Level Duty-Cycled Wakeup and Data Receiver. Unknown Journal . 2020.
A- 108dBm Sensitivity, -28dB SIR, 130nW to 41µW, Digitally Reconfigurable Bit-Level Duty-Cycled Wakeup and Data Receiver [link] Paper link bibtex
2019 (14)
Moody, J.; Bassirian, P.; Roy, A.; Liu, N.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. Interference Robust Detector-First Near-Zero Power Wake-Up Receiver. IEEE journal of solid-state circuits . 2019.
Interference Robust Detector-First Near-Zero Power Wake-Up Receiver [link] Paper link bibtex
Bassirian, P.; Moody, J.; Lu, R.; Gao, A.; Manzaneque, T.; Roy, A.; Barker, N. S.; Calhoun, B. H.; Gong, S.; and Bowers, S. M. Nanowatt-Level Wakeup Receiver Front Ends Using MEMS Resonators for Impedance Transformation. IEEE transactions on microwave theory and techniques . 2019.
Nanowatt-Level Wakeup Receiver Front Ends Using MEMS Resonators for Impedance Transformation [link] Paper link bibtex
Tzu, T.; Sun, K.; Costanzo, R.; Ayoub, D.; Bowers, S. M. ; and Beling, A. Foundry-Enabled High-Power Photodetectors for Microwave Photonics. IEEE Journal of Selected Topics in Quantum Electronics . 2019.
Foundry-Enabled High-Power Photodetectors for Microwave Photonics [link] Paper link bibtex
Moody, J.; Dissanayake, A.; Bishop, H. L.; Lu, R.; Liu, N.; Duvvuri, D.; Gao, A.; Truesdell, D. S.; Barker, N. S.; Gong, S.; Calhoun, B. H.; and Bowers, S. M. A -106dBm 33nW Bit-Level Duty-Cycled Tuned RF Wake-up Receiver. Unknown Journal . 2019.
A -106dBm 33nW Bit-Level Duty-Cycled Tuned RF Wake-up Receiver [link] Paper link bibtex
Moody, J.; Gong, S.; Calhoun, B. H.; Bowers, S. M. ; Dissanayake, A.; Bishop, H. L.; Lu, R.; Liu, N.; Duvvuri, D.; Gao, A.; Truesdell, D. S.; and Barker, N. S. A Highly Reconfigurable Bit-Level Duty-Cycled TRF Receiver Achieving −106-dBm Sensitivity and 33-nW Average Power Consumption. IEEE solid-state circuits letters . 2019.
A Highly Reconfigurable Bit-Level Duty-Cycled TRF Receiver Achieving −106-dBm Sensitivity and 33-nW Average Power Consumption [link] Paper link bibtex
Costanzo, R.; Yang, Z.; Beling, A.; and Bowers, S. M. Wideband Balanced Photoreceivers With InP-Based Photodiodes and 65 nm CMOS TIAs for Use in Optical Frequency Synthesis Systems. Journal of lightwave technology . 2019.
Wideband Balanced Photoreceivers With InP-Based Photodiodes and 65 nm CMOS TIAs for Use in Optical Frequency Synthesis Systems [link] Paper link bibtex
Moody, J.; and Bowers, S. M. Triode-mode Envelope Detectors for Near Zero Power Wake-up Receivers. Unknown Journal . 2019.
Triode-mode Envelope Detectors for Near Zero Power Wake-up Receivers [link] Paper link bibtex
Sun, K.; Tzu, T.; Costanzo, R.; Yu, Q.; Bowers, S. M. ; and Beling, A. Ge-on-Si Balanced Periodic Traveling-Wave Photodetector. Unknown Journal . 2019.
Ge-on-Si Balanced Periodic Traveling-Wave Photodetector [link] Paper link bibtex
Shen, X.; Costanzo, R.; Morgan, J. D.; Sun, K.; Woodson, M.; Estrella, S.; Beling, A.; and Bowers, S. M. High-Power W-band to G-band Photonically-Driven Electromagnetic Emitter with 8.8 dBm EIRP. Unknown Journal . 2019.
High-Power W-band to G-band Photonically-Driven Electromagnetic Emitter with 8.8 dBm EIRP [link] Paper link bibtex
Bowers, J. E.; Beling, A.; Bowers, S. M. ; Briles, T. C.; Chang, L.; Chiles, J.; Costanzo, R.; Davanço, M.; Diddams, S. A.; Drake, T. E.; Geiselmann, M.; Ghadiani, B.; Ilić, B.; Jain, A.; Kinghorn, D.; Kippenberg, T. J.; Li, Q.; Liu, J.; Mirin, R. P.; Moille, G.; Morais, T.; Morton, J. L.; Morton, P. A.; Nader, N.; Papp, S. B.; Raduazo, N.; Raja, A. S.; Shen, B.; Srinivasan, K.; Stanton, E. J.; Stone, J. A.; Theogarajan, L.; Tran, M. A.; Vahala, K. J.; Volet, N.; Wang, R. N.; Wang, Y.; Westly, D.; Yang, Q.; Yang, Z.; Xu, Y.; and Zervas, M. Chip-scale Optical Resonator Enabled Synthesizer (CORES). Unknown Journal . 2019.
Chip-scale Optical Resonator Enabled Synthesizer (CORES) [pdf] Paper link bibtex
Moody, J.; Bassirian, P.; Roy, A.; Liu, N.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. Interference Robust Detector-First Near-Zero Power Wake-Up Receiver. IEEE journal of solid-state circuits . 2019.
Interference Robust Detector-First Near-Zero Power Wake-Up Receiver [link] Paper link bibtex
Bassirian, P.; Moody, J.; Lu, R.; Gao, A.; Manzaneque, T.; Roy, A.; Barker, N. S.; Calhoun, B. H.; Gong, S.; and Bowers, S. M. Nanowatt-Level Wakeup Receiver Front Ends Using MEMS Resonators for Impedance Transformation. IEEE transactions on microwave theory and techniques . 2019.
Nanowatt-Level Wakeup Receiver Front Ends Using MEMS Resonators for Impedance Transformation [link] Paper link bibtex
Moody, J.; Dissanayake, A.; Bishop, H. L.; Lu, R.; Liu, N.; Duvvuri, D.; Gao, A.; Truesdell, D. S.; Barker, N. S.; Gong, S.; Calhoun, B. H.; and Bowers, S. M. A -106dBm 33nW Bit-Level Duty-Cycled Tuned RF Wake-up Receiver. Unknown Journal . 2019.
A -106dBm 33nW Bit-Level Duty-Cycled Tuned RF Wake-up Receiver [link] Paper link bibtex
Moody, J.; Gong, S.; Calhoun, B. H.; Bowers, S. M. ; Dissanayake, A.; Bishop, H. L.; Lu, R.; Liu, N.; Duvvuri, D.; Gao, A.; Truesdell, D. S.; and Barker, N. S. A Highly Reconfigurable Bit-Level Duty-Cycled TRF Receiver Achieving −106-dBm Sensitivity and 33-nW Average Power Consumption. IEEE solid-state circuits letters . 2019.
A Highly Reconfigurable Bit-Level Duty-Cycled TRF Receiver Achieving −106-dBm Sensitivity and 33-nW Average Power Consumption [link] Paper link bibtex
2018 (5)
Moody, J.; Bassirian, P.; Roy, A.; Liu, N.; Pancrazio, S.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. A −76dBm 7.4nW wakeup radio with automatic offset compensation. Unknown Journal . 2018.
A −76dBm 7.4nW wakeup radio with automatic offset compensation [link] Paper link bibtex
Costanzo, R.; and Bowers, S. M. A Current Reuse Regulated Cascode CMOS Transimpedance Amplifier With 11-GHz Bandwidth. IEEE microwave and wireless components letters . 2018.
A Current Reuse Regulated Cascode CMOS Transimpedance Amplifier With 11-GHz Bandwidth [link] Paper link bibtex
Sun, K.; Moody, J.; Li, Q.; Bowers, S. M. ; and Beling, A. High Power Integrated Photonic W-Band Emitter. IEEE Transactions on Microwave Theory and Techniques . 2018.
High Power Integrated Photonic W-Band Emitter [link] Paper link bibtex
Sun, K.; Costanzo, R.; Tzu, T.; Yu, Q.; Bowers, S. M. ; and Beling, A. Ge-on-Si Waveguide Photodiode Array for High-Power Applications. Unknown Journal . 2018.
Ge-on-Si Waveguide Photodiode Array for High-Power Applications [link] Paper link bibtex
Moody, J.; Bassirian, P.; Roy, A.; Liu, N.; Pancrazio, S.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. A −76dBm 7.4nW wakeup radio with automatic offset compensation. Unknown Journal . 2018.
A −76dBm 7.4nW wakeup radio with automatic offset compensation [link] Paper link bibtex
2017 (9)
Moody, J.; Bassirian, P.; Roy, A.; Feng, Y.; Li, S.; Costanzo, R.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. An 8.3 nW −72 dBm event driven IoE wake up receiver RF front end. Unknown Journal . 2017.
An 8.3 nW −72 dBm event driven IoE wake up receiver RF front end [link] Paper link bibtex
Bassirian, P.; Moody, J.; and Bowers, S. M. Event-driven wakeup receivers: Applications and design challenges. Unknown Journal . 2017.
Event-driven wakeup receivers: Applications and design challenges [link] Paper link bibtex
Bassirian, P.; Moody, J.; Gao, A.; Manzaneque, T.; Calhoun, B. H.; Barker, N. S.; Gong, S.; and Bowers, S. M. A passive 461 MHz AlN-CMOS RF front-end for event-driven wakeup receivers. Unknown Journal . 2017.
A passive 461 MHz AlN-CMOS RF front-end for event-driven wakeup receivers [link] Paper link bibtex
Bassirian, P.; Moody, J.; and Bowers, S. M. Analysis of quadratic dickson based envelope detectors for IoE sensor node applications. Unknown Journal . 2017.
Analysis of quadratic dickson based envelope detectors for IoE sensor node applications [link] Paper link bibtex
Parveg, D.; Varonen, M.; Safaripour, A.; Bowers, S. M. ; Tikka, T.; Kangaslahti, P.; Gaier, T.; Hajimiri, A.; and Halonen, K. A 180-GHz CMOS down-converter MMIC for atmospheric remote sensing applications. Unknown Journal . 2017.
A 180-GHz CMOS down-converter MMIC for atmospheric remote sensing applications [link] Paper link bibtex
Costanzo, R.; Yang, Z.; Raduazo, N.; Beling, A.; and Bowers, S. M. A 10 GHz bandwidth balanced photoreceiver with 41 V/W optical conversion gain. Unknown Journal . 2017.
A 10 GHz bandwidth balanced photoreceiver with 41 V/W optical conversion gain [link] Paper link bibtex
Yang, Z.; Costanzo, R.; Raduazo, N.; Zang, J.; Bowers, S. M. ; and Beling, A. Low-Noise Balanced Photoreceiver with 21 V/W Optical Conversion Gain. Unknown Journal . 2017.
Low-Noise Balanced Photoreceiver with 21 V/W Optical Conversion Gain [link] Paper link bibtex
Moody, J.; Bassirian, P.; Roy, A.; Feng, Y.; Li, S.; Costanzo, R.; Barker, N. S.; Calhoun, B. H.; and Bowers, S. M. An 8.3 nW −72 dBm event driven IoE wake up receiver RF front end. Unknown Journal . 2017.
An 8.3 nW −72 dBm event driven IoE wake up receiver RF front end [link] Paper link bibtex
Bassirian, P.; Moody, J.; Gao, A.; Manzaneque, T.; Calhoun, B. H.; Barker, N. S.; Gong, S.; and Bowers, S. M. A passive 461 MHz AlN-CMOS RF front-end for event-driven wakeup receivers. Unknown Journal . 2017.
A passive 461 MHz AlN-CMOS RF front-end for event-driven wakeup receivers [link] Paper link bibtex