UM

Browse/Search Results:  1-10 of 49 Help

Selected(0)Clear Items/Page:    Sort:
Fluorometric determination of pesticides and organophosphates using nanoceria as a phosphatase mimic and an inner filter effect on carbon nanodots Journal article
Microchimica Acta, 2019,Volume: 186,Issue: 2
Authors:  Wei J.;  Yang Y.;  Dong J.;  Wang S.;  Li P.
Favorite  |  View/Download:1/0  |  Submit date:2019/04/08
CeO 2  Environmental pollution  Fluorescence  Nanomaterial  Nanoparticle  Nanozyme  Probe  Sensor  Water pollution  
Unconventional Antiferromagnetic Quantum Critical Point in Ba (Fe0.97Cr0.03)2 (As1-x Px)2 Journal article
Physical Review Letters, 2019,Volume: 122,Issue: 3
Authors:  Zhang W.;  Wei Y.;  Xie T.;  Liu Z.;  Gong D.;  Ma X.;  Hu D.;  Cermak P.;  Schneidewind A.;  Tucker G.;  Meng S.;  Huesges Z.;  Lu Z.;  Song J.;  Luo W.;  Xu L.;  Zhu Z.;  Yin X.;  Li H.-F.;  Yang Y.-F.;  Luo H.;  Li S.
Favorite  |  View/Download:4/0  |  Submit date:2019/04/08
A 0.2V energy-harvesting BLE transmitter with a micropower manager achieving 25% system efficiency at 0dBm output and 5.2nW sleep power in 28nm CMOS Journal article
IEEE Journal of Solid-State Circuits, 2019,Page: 1 - 12
Authors:  Shiheng Yang;  Jun Yin;  Haidong Yi;  Wei-Han Yu;  Pui-In Mak;  Rui P. Martins
Favorite  |  View/Download:8/0  |  Submit date:2019/03/12
Bluetooth Low Energy (Ble)  Cmos  Energy Harvesting  Master-slave Sampling Filter (Mssf)  Micropower Manager (Μpm)  Phase-locked Loop (Pll)  Power Amplifier (Pa)  Power Gating  Transmitter (Tx)  Ultralow-voltage (Ulv)  Voltage-controlled Oscillator (Vco)  
Ambient RF energy harvesting system: a review on integrated circuit design Journal article
ANALOG INTEGRATED CIRCUITS AND SIGNAL PROCESSING, 2018,Volume: 97,Issue: 3,Page: 515-531
Authors:  Chong, Gabriel;  Ramiah, Harikrishnan;  Yin, Jun;  Rajendran, Jagadheswaran;  Wong, Wei Ru;  Mak, Pui-In;  Martins, Rui P.
Favorite  |  View/Download:12/0  |  Submit date:2019/01/17
Ambient RF energy harvesting  Integrated circuit  Rectifier  Impedance matching network  Power management unit  
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:11/0  |  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:5/0  |  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 0.7-2.5 GHz, 61% EIRP System Efficiency, Four-Element MIMO TX System Exploiting Integrated Power-Relaxed Power Amplifiers and an Analog Spatial De-Interleaver Journal article
IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS I-REGULAR PAPERS, 2018,Volume: 65,Issue: 1,Page: 14-25
Authors:  Yu, Wei-Han;  Un, Ka-Fai;  Mak, Pui-In;  Martins, Rui P.
Favorite  |  View/Download:12/0  |  Submit date:2018/10/30
Antenna Array  Beamforming  Cmos  Diversity Gain  Error-vector Magnitude (Evm)  Fading Channel  Mobile  Multiple-input Multiple-output (Mimo)  Mimo Decoder  Matching Network (Mn)  Pulse-shaping Filter (Psf)  Power Amplifier (Pa)  Transmitter (Tx)  Signal-to-noise Ratio (Snr)  Wideband  
A 0.2V energy-harvesting BLE transmitter with a micropower manager achieving 25% system efficiency at 0dBm output and 5.2nW sleep power in 28nm CMOS Conference paper
2018 IEEE International Solid - State Circuits Conference - (ISSCC), San Francisco, CA, USA, FEB 11-15, 2018
Authors:  Jun Yin;  Shiheng Yang;  Haidong Yi;  Wei-Han Yu;  Pui-In Mak;  Rui P. Martins
Favorite  |  View/Download:10/0  |  Submit date:2018/11/06
THE CONCISE GUIDE TO PHARMACOLOGY 2017/18: Overview Journal article
British Journal of Pharmacology, 2017,Volume: 174,Page: S1-S16
Authors:  Alexander S.P.H.;  Kelly E.;  Marrion N.V.;  Peters J.A.;  Faccenda E.;  Harding S.D.;  Pawson A.J.;  Sharman J.L.;  Southan C.;  Buneman O.P.;  Cidlowski J.A.;  Christopoulos A.;  Davenport A.P.;  Fabbro D.;  Spedding M.;  Striessnig J.;  Davies J.A.;  Abbracchio M.-P.;  Aldrich R.;  Al-Hosaini K.;  Arumugam T.V.;  Attali B.;  Back M.;  Barnes N.M.;  Bathgate R.;  Beart P.M.;  Becirovic E.;  Bettler B.;  Biel M.;  Birdsall N.J.;  Blaho V.;  Boison D.;  Brauner-osborne H.;  Broer S.;  Bryant C.;  Burnstock G.;  Calo G.;  Catterall W.A.;  Ceruti S.;  Chan S.L.;  Chandy K.G.;  Chazot P.;  Chiang N.;  Chun J.J.;  Chung J.-J.;  Clapham D.E.;  Clapp L.;  Connor M.A.;  Cox H.M.;  Davies P.;  Dawson P.A.;  Decaen P.;  Dent G.;  Doherty P.;  Douglas S.D.;  Dubocovich M.L.;  Fong T.M.;  Fowler C.J.;  Frantz A.;  Fuller P.;  Fumagalli M.;  Futerman A.H.;  Gainetdinov R.R.;  Gershengorn M.A.;  Goldin A.;  Goldstein S.A.N.;  Goudet C.;  Gregory K.;  Grissmer S.;  Gundlach A.L.;  Hagenbuch B.;  Hamann J.;  Hammond J.R.;  Hancox J.C.;  Hanson J.;  Hanukoglu I.;  Hay D.L.;  Hobbs A.J.;  Hollenberg A.N.;  Holliday N.D.;  Hoyer D.;  Ijzerman A.P.;  Inui K.I.;  Irving A.J.;  Ishii S.;  Jacobson K.A.;  Jan L.Y.;  Jarvis M.F.;  Jensen R.;  Jockers R.;  Kaczmarek L.K.;  Kanai Y.;  Karnik S.;  Kellenberger S.;  Kemp S.;  Kennedy C.;  Kerr I.D.;  Kihara Y.;  Kukkonen J.;  Larhammar D.;  Leach K.;  Lecca D.;  Leeman S.;  Leprince J.;  Lolait S.J.;  Macewan D.;  Maguire J.J.;  Marshall F.;  Mazella J.;  Mcardle C.A.;  Michel M.C.;  Miller L.J.;  Mitolo V.;  Mizuno H.;  Monk P.N.;  Mouillac B.;  Murphy P.M.;  Nahon J.-L.;  Nerbonne J.;  Nichols C.G.;  Norel X.;  Offermanns S.;  Palmer L.G.;  Panaro M.A.;  Papapetropoulos A.;  Perez-reyes E.;  Pertwee R.G.;  Pintor S.;  Pisegna J.R.;  Plant L.D.;  Poyner D.R.;  Prossnitz E.R.;  Pyne S.;  Ramachandran R.;  Ren D.;  Rondard P.;  Ruzza C.;  Sackin H.;  Sanger G.;  Sanguinetti M.C.;  Schild L.;  Schioth H.;  Schulte G.;  Schulz S.;  Segaloff D.L.;  Serhan C.N.;  Singh K.D.;  Slesinger P.A.;  Snutch T.P.;  Sobey C.G.;  Stewart G.;  Stoddart L.A.;  Summers R.J.;  Szabo C.;  Thwaites D.;  Toll L.;  Trimmer J.S.;  Tucker S.;  Vaudry H.;  Verri T.;  Vilargada J.-P.;  Waldman S.A.;  Ward D.T.;  Waxman S.G.;  Wei A.D.;  Willars G.B.;  Wong S.S.;  Woodruff T.M.;  Wulff H.;  Ye R.D.;  Yung Y.;  Zajac J.-M.
Favorite  |  View/Download:6/0  |  Submit date:2018/11/07
Part II: Phase transformation-induced bloating behavior in diopside glass-ceramics for microwave dielectrics Conference paper
Authors:  Chou, Chen Chia;  Feng, Kuei Chih;  Raevski, Igor P.;  Chu, Li Wen;  Chen, Haydn;  Chen, Pin-Yi;  Chen, Cheng-Sao;  Lee, Hao Wei;  Tu, Chi-Shun
Favorite  |  View/Download:1/0  |  Submit date:2018/10/30
Diopside  Glass-ceramics  Nucleating agent  Activation energy