Publications
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, “A 2.3-5.7μW Tri-Modal Self-Adaptive Photoplethysmography Sensor Interface IC for Heart Rate, SpO2 , and Pulse Transit Time Co-Monitoring”, IEEE Transactions on Biomedical Circuits and Systems, 2024.
, “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 1.02 μW Battery-Less, Continuous Sensing and Post-Processing SiP for Wearable Applications”, IEEE Transactions on Biomedical Circuits and Systems, 2019.
08625544.pdf (3.22 MB)
08625544.pdf (3.22 MB), “A 1.02 μW Battery-Less, Continuous Sensing and Post-Processing SiP for Wearable Applications”, IEEE Transactions on Biomedical Circuits and Systems, 2019. 08625544.pdf (3.22 MB)
08625544.pdf (3.22 MB), “A 1.02 μW Battery-Less, Continuous Sensing and Post-Processing SiP for Wearable Applications”, IEEE Transactions on Biomedical Circuits and Systems, 2019. 08625544.pdf (3.22 MB)
08625544.pdf (3.22 MB), “A -102 dBm Sensitivity Multi-Channel Heterodyne Wake-Up Receiver with Integrated ADPLL”, IEEE Open Journal of the Solid-State Circuits Society, 2024.
, “A 0.5V 560-kHz 18.8-fJ/Cycle On-Chip Oscillator with 96.1-ppm/°C Steady-State Stability Using a Duty-Cycled Digital Frequency-Locked Loop”, IEEE Journal of Solid-State Circuits, 2021. A 0.5-V 560-kHz 18.8-fJ_Cycle On-Chip Oscillator With 96.1ppm_C Steady-State Stability Using a Duty-Cycled Digital Frequency-Locked Loop.pdf (2.95 MB)
A 0.5-V 560-kHz 18.8-fJ_Cycle On-Chip Oscillator With 96.1ppm_C Steady-State Stability Using a Duty-Cycled Digital Frequency-Locked Loop.pdf (2.95 MB), “A 0.5 V 68 nW ECG Monitoring Analog Front-End for Arrhythmia Diagnosis”, Journal of Low Power Electronics and Applications (JLPEA), 2018.
, “An Ultra-low Power System On Chip Enabling DVS with SR Level Shifting Latches”, in IEEE International Symposium on Circuits and Systems (ISCAS), Florence, Italy, 2018.
, “A Tunnel FET Design for High-Current, 120 mV Operation”, in IEDM, 2016.
, “A Temperature-robust 27.6nW -65dBm Wakeup Receiver at 9.6GHz X Band”, in 2020 IEEE International Solid-State Circuits Conference (ISSCC), 2020.
, “A Sub-Threshold FPGA: Energy-Efficient Reconfigurable Logic”, in GOMAC Tech, 2011.
, “Sub-microAmp Energy Harvesting and Power Management Units for Self-Powered IoT SoCs: Analog vs. Digital Implementations”, in 2020 IEEE Custom Integrated Circuits Conference (CICC), (invited paper), 2020.
, “Stepped Supply Voltage Switching for Energy Constrained Systems”, in ISQED, 2011.
, “A Self-Powered SoC with Distributed Cooperative Energy Harvesting and Multi-Chip Power Management for System-in-Fiber”, in IEEE International Solid-State Circuits Conference (ISSCC), 2023. 15.1_A_Self-Powered_SoC_with_Distributed_Cooperative_Energy_Harvesting_and_Multi-Chip_Power_Management_for_System-in-Fiber.pdf (1.51 MB)
15.1_A_Self-Powered_SoC_with_Distributed_Cooperative_Energy_Harvesting_and_Multi-Chip_Power_Management_for_System-in-Fiber.pdf (1.51 MB), “Scalable All-Analog LDOs With Reduced Input Offset Variability Using Digital Synthesis Flow in 65-nm CMOS”, in IEEE Transactions on Very Large Scale Integration (TVLSI) Systems, 2023.
, “REESES: Rapid Efficient Energy Scalable ElectronicS”, in GOMAC Tech, 2010.
, “Reducing the Cost of Safety-Critical Systems with On-Demand Redundancy”, in SRC Techcon, 2012.
, “Reducing the Cost of Redundant Execution in Safety-Critical Systems using Relaxed Dedication”, in Design Automation and Test in Europe (DATE), 2011.
, “A Programmable Resistive Power Grid for Post-Fabrication Flexibility and Energy Tradeoffs”, in International Symposium on Low Power Electronics and Design, 2012.
, “Power Switch Characterization for Fine-Grained Dynamic Voltage Scaling”, in International Conference on Computer Design, pages 605-611, 2008.
, “A Piezoelectric Energy-Harvesting System with Parallel-SSHI Rectifier and Integrated MPPT Achieving 417% Energy-Extraction Improvement and 97% Tracking Efficiency”, in 2019 Symposium on VLSI Circuits, Kyoto, Japan, 2019.
, “Panoptic DVS: A Fine-Grained Dynamic Voltage Scaling Framework for Energy Scalable CMOS Design”, in International Conference on Computer Design (ICCD), 2009, pp. 491-497.
, “NanoWattch: A Self-Powered 3-nW RISC-V SoC Operable from 160mV Photovoltaic Input with Integrated Temperature Sensing and Adaptive Performance Scaling”, in 2022 IEEE Symposium on VLSI Circuits (VLSI), (Equally-Credited Authors), 2022. NanoWattch A Self-Powered 3-nW RISC-V SoC Operable from 160mV Photovoltaic Input with Integrated Temperature Sensing and Adaptive Performance Scaling.pdf (11.11 MB)
NanoWattch A Self-Powered 3-nW RISC-V SoC Operable from 160mV Photovoltaic Input with Integrated Temperature Sensing and Adaptive Performance Scaling.pdf (11.11 MB)