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Wideband variable-gain amplifiers based on a pseudo-current steering gain-tuning technique Journal article
Kong, Lingshan, Chen, Yong, Yu, Haohong, Boon, Chirn Chye, Mak, Pui In, Martins, Rui P.. Wideband variable-gain amplifiers based on a pseudo-current steering gain-tuning technique[J]. IEEE Access, 2021, 9, 35814 -35823.
Authors:  Kong, Lingshan;  Chen, Yong;  Yu, Haohong;  Boon, Chirn Chye;  Mak, Pui In; et al.
Favorite | TC[WOS]:5 TC[Scopus]:7  IF:3.4/3.7 | Submit date:2022/01/25
Cmos  Wide-tuning Gain Control  Variable-gain Amplifier (Vga)  Active Inductor  Data-dependent Jitter (Ddj)  Dual-branch Current Mirror  High-speed Transceiver  Negative CapacitaNce (Nc)  Peak-to-peak Jitter  Pseudo-current Steering  
Wideband variable-gain amplifiers based on a pseudo-current-steering gain-tuning technique Journal article
Kong, Lingshan, Chen, Yong, Yu, Haohong, Boon, Chirn Chye, Mak, Pui In, Martins, Rui P.. Wideband variable-gain amplifiers based on a pseudo-current-steering gain-tuning technique[J]. IEEE Access, 2021, 9, 35814-35823.
Authors:  Kong, Lingshan;  Chen, Yong;  Yu, Haohong;  Boon, Chirn Chye;  Mak, Pui In; et al.
Favorite | TC[WOS]:5 TC[Scopus]:7  IF:3.4/3.7 | Submit date:2022/05/13
Active Inductor  Cmos  Data-dependent Jitter (Ddj)  Dual-branch Current Mirror  High-speed Transceiver  Negative CapacitaNce (Nc)  Peak-to-peak Jitter  Pseudo-current Steering  Variable-gain Amplifier (Vga)  Wide-tuning Gain Control  
Wideband Variable-Gain Amplifiers Based on a Pseudo-Current-Steering Gain-Tuning Technique Conference paper
Lingshan Kong, Yong Chen, Haohong Yu, Quan Pan, Chirn Chye Boon, Pui-In Mak, Rui P. Martins. Wideband Variable-Gain Amplifiers Based on a Pseudo-Current-Steering Gain-Tuning Technique[C]:IEEE, 2020, 153-156.
Authors:  Lingshan Kong;  Yong Chen;  Haohong Yu;  Quan Pan;  Chirn Chye Boon; et al.
Favorite | TC[WOS]:4 TC[Scopus]:5 | Submit date:2021/03/09
Variable-gain Amplifier (Vga)  Cmos  Pseudo-current Steering  Wide-tuning Gain Control  Bandwidth (Bw)  High-speed Transceiver  Negative Capacitance  Peak-to-peak Jitter  
A 0.096-mm2 1-20-GHz triple-path noise- canceling common-gate common-source LNA with dual complementary pMOS-nMOS configuration Journal article
Yu,Haohong, Chen,Yong, Boon,Chirn Chye, Mak,Pui In, Martins,Rui P.. A 0.096-mm2 1-20-GHz triple-path noise- canceling common-gate common-source LNA with dual complementary pMOS-nMOS configuration[J]. IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, 2019, 68(1), 144-159.
Authors:  Yu,Haohong;  Chen,Yong;  Boon,Chirn Chye;  Mak,Pui In;  Martins,Rui P.
Favorite | TC[WOS]:67 TC[Scopus]:75  IF:4.1/4.2 | Submit date:2021/03/09
Cmos  Common Gate (Cg)  Common Source (Cs)  Input Third-order Intercept Point (Iip3)  Noise Figure (Nf)  Partial Distortion Canceling  Pmos-nmos Configuration  Resistive Feedback  Triple-path And Dual-path Noise CaNceling (Nc)  Wideband Input Matching  Wideband Low-noise Amplifier (Lna)  
A 0.044-mm2 0.5-To-7-GHz Resistor-Plus-Source-Follower-Feedback Noise-Cancelling LNA Achieving a Flat NF of 3.3±0.45 dB Journal article
Haohong Yu, Yong Chen, Chirn Chye Boon, Chenyang Li, Pui-In Mak, Rui P. Martins. A 0.044-mm2 0.5-To-7-GHz Resistor-Plus-Source-Follower-Feedback Noise-Cancelling LNA Achieving a Flat NF of 3.3±0.45 dB[J]. IEEE Transactions on Circuits and Systems II: Express Briefs, 2019, 66(1), 71-75.
Authors:  Haohong Yu;  Yong Chen;  Chirn Chye Boon;  Chenyang Li;  Pui-In Mak; et al.
Favorite | TC[WOS]:60 TC[Scopus]:73  IF:4.0/3.7 | Submit date:2019/02/11
Cmos  Low-noise Amplifier (Lna)  Noise Cancelling  Noise Figure (Nf)  Resistor Feedback  Source Follower Feedback (Sff)  Wideband Input Impedance Matching  
An area-efficient and tunable Bandwidth-Extension Technique for a Wideband CMOS Amplifier Handling 50+ Gb/s Signaling Journal article
Yong Chen, Pui-In Mak, Haohong Yu, Chirn Chye Boon, Rui P. Martins. An area-efficient and tunable Bandwidth-Extension Technique for a Wideband CMOS Amplifier Handling 50+ Gb/s Signaling[J]. IEEE Transactions on Microwave Theory and Techniques, 2017, 65(12), 4960-4975.
Authors:  Yong Chen;  Pui-In Mak;  Haohong Yu;  Chirn Chye Boon;  Rui P. Martins
Favorite | TC[WOS]:30 TC[Scopus]:26  IF:4.1/4.2 | Submit date:2019/02/11
Ac charActeristic  Bandwidth (Bw)  Bridged-shunt Peaking  Cmos  Data-dependent Jitter (Ddj)  Figure Of Merit (Fom)  Grounded Active Inductor (Gai)  Group Delay Ripple (Gdr)  Intersymbol Interference (Isi)  Shunt Peaking  T-coil  Wideband Amplifier