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A 0.18-V 382-mu W Bluetooth Low-Energy Receiver Front-End With 1.33-nW Sleep Power for Energy-Harvesting Applications in 28-nm CMOS Journal article
IEEE JOURNAL OF SOLID-STATE CIRCUITS, 2018,Volume: 53,Issue: 6,Page: 1618-1627
Authors:  Yi, Haidong;  Yu, Wei-Han;  Mak, Pui-In;  Yin, Jun;  Martins, Rui P.
Favorite | View/Download:30/0 | TC[WOS]:8 TC[Scopus]:21 | Submit date:2018/10/30
Bandgap reference (BGR)  Bluetooth low energy (BLE)  charge pump (CP)  class-D voltage-controlled oscillator (VCO)  CMOS  energy harvesting  low-noise amplifier (LNA)  micropower manager (mu PM)  power-gating  receiver (RX)  ultra-low power (ULP)  ultra-low voltage (ULV)  
A 0.18V 382µW Bluetooth Low-Energy (BLE) Receiver Front-End with 1.33nW Sleep Power for Energy-Harvesting Applications in 28nm CMOS Journal article
IEEE Journal of Solid-State Circuits, 2018,Volume: 53,Issue: 6,Page: 1618 - 1627
Authors:  Haidong Yi;  Wei-Han Yu;  Pui-In Mak;  Jun Yin;  Rui P. Martins
Favorite | View/Download:29/0 | TC[WOS]:8 TC[Scopus]:21 | Submit date:2019/03/12
Bandgap Reference (Bgr)  Bluetooth Low Energy (Ble)  Charge Pump (Cp)  Class-d Voltage-controlled Oscillator (Vco)  Cmos  Energy Harvesting  Low-noise Amplifier (Lna)  Micropower Manager (Μpm)  Power-gating  Receiver (Rx)  Ultra-low Power (Ulp)  Ultra-low Voltage (Ulv)  
A 0.18-V 382-μ W Bluetooth Low-Energy Receiver Front-End with 1.33-nW Sleep Power for Energy-Harvesting Applications in 28-nm CMOS Journal article
IEEE Journal of Solid-State Circuits, 2018,Volume: 53,Issue: 6,Page: 1618-1627
Authors:  Yi H.;  Yu W.-H.;  Mak P.-I.;  Yin J.;  Martins R.P.
Favorite | View/Download:9/0 | TC[WOS]:8 TC[Scopus]:21 | Submit date:2019/02/11
Bandgap reference (BGR)  Bluetooth low energy (BLE)  charge pump (CP)  class-D voltage-controlled oscillator (VCO)  CMOS  energy harvesting  low-noise amplifier (LNA)  micropower manager (μPM)  power-gating  receiver (RX)  ultra-low power (ULP)  ultra-low voltage (ULV)  
Nano-Watt Class Energy-Efficient Capacitive Sensor Interface with On-Chip Temperature Drift Compensation Journal article
IEEE Sensors Journal, 2018,Volume: 18,Issue: 7,Page: 2870-2882
Authors:  Zhang T.-T.;  Law M.-K.;  Mak P.-I.;  Vai M.-I.;  Martins R.P.
Favorite | View/Download:29/0 | TC[WOS]:2 TC[Scopus]:6 | Submit date:2019/02/11
Capacitive Sensor Interface  Energy Efficiency  High Accuracy  Mismatch Errors  Pressure Sensor  Temperature Compensation  Two-step Incremental-adc  Ultra-low Power  
A 0.4V 4.8μW 16MHz CMOS crystal oscillator achieving 74-fold startup-time reduction using momentary detuning Conference paper
Proceedings - IEEE International Symposium on Circuits and Systems, Baltimore, MD, MAY 28-31, 2017
Authors:  Ka-Meng Lei;  Pui-In Mak;  R. P. Martins
Favorite | View/Download:27/0 | TC[WOS]:0 TC[Scopus]:5 | Submit date:2019/02/11
Cmos  Crystal Oscillator  Fast Startup  Low-power  Low-voltage  Ultra-low-power  
A sub-1V 78-nA bandgap reference with curvature compensation Journal article
MICROELECTRONICS JOURNAL, 2017,Volume: 63,Page: 35-40
Authors:  Ziyang Luo;  Yan Lu;  Mo Huang;  Junmin Jiang;  Sai-Weng Sin;  Seng-Pan U;  Rui P. Martins
Favorite | View/Download:47/0 | TC[WOS]:5 TC[Scopus]:7 | Submit date:2018/10/30
Bandgap Reference  Cmos Analog Integrated Circuits  Internet-of-things (Iot)  Ultra-low Power  Curvature Compensation  Temperature Coefficient  
A 0.4V 4.8 mu W 16MHz CMOS Crystal Oscillator Achieving 74-Fold Startup-Time Reduction Using Momentary Detuning Conference paper
Authors:  Lei, Ka-Meng;  Mak, Pui-In;  Martins, R. P.;  IEEE
Favorite | View/Download:5/0 | TC[WOS]:0 TC[Scopus]:0 | Submit date:2018/10/30
CMOS  crystal oscillator  fast startup  low-voltage  low-power  ultra-low-power  
A 310 nW 14.2-bit iterative-incremental ADC for wearable sensing systems Conference paper
Proceedings - IEEE International Symposium on Circuits and Systems, Baltimore, MD, MAY 28-31, 2017
Authors:  Zhang T.-T.;  Law M.-K.;  Wang B.;  Mak P.-I.;  Vai M.-I.;  Martins R.P.
Favorite | View/Download:23/0 | TC[WOS]:1 TC[Scopus]:0 | Submit date:2019/02/11
Chopping  Dynamic Element Matching  Energy Efficiency  Incremental Adc  Sensor Interface  Two-step  Ultra-low-power  Vearable Sensing System  
A 1.1 μW CMOS smart temperature sensor with an inaccuracy of ±0.2 °C (3σ) for clinical temperature monitoring Journal article
IEEE Sensors Journal, 2016,Volume: 16,Issue: 8,Page: 2272-2281
Authors:  Man-Kay Law;  Sanfeng Lu;  Tao Wu;  Amine Bermak;  Pui-In Mak;  Rui P. Martins
Favorite | View/Download:19/0 | TC[WOS]:11 TC[Scopus]:18 | Submit date:2019/02/11
Smart Temperature Sensor  Ultra-low Power  High Accuracy  Incremental Analog-to-digital Converter (I-adc),  Multi-ratio Pre-gain  Block-based Data Weighted Averaging (Bdwa)  
Ultra-Low-Power and Ultra-Low-Cost Short-Range Wireless Receivers in Nanoscale CMOS Book
Switzerland:Springer International Publishing, 2016
Authors:  Zhicheng Lin;  Pui-In Mak (Elvis);  Rui Paulo Martins
Favorite | View/Download:144/0 | TC[WOS]:0 TC[Scopus]:3 | Submit date:2019/02/27
Analog Circuits And Signal Processing  Internet Of Things  Ultra-low-power Wireless Receivers  Ultra-low-power Rf Circuit Design  Wireless Receivers In Nanoscale Cmos  Zigbee