Breaking the Bandwidth Limit: A Review of Broadband Doherty Power Amplifier Design for 5G G Nikandish, RB Staszewski, A Zhu IEEE Microwave Magazine 21 (4), 57-75, 2020 | 97 | 2020 |
A broadband multistage LNA with bandwidth and linearity enhancement G Nikandish, A Yousefi, M Kalantari IEEE Microwave and Wireless Components Letters 26 (10), 834-836, 2016 | 73 | 2016 |
A 40-GHz bandwidth tapered distributed LNA G Nikandish, A Medi IEEE Transactions on Circuits and Systems II: Express Briefs 65 (11), 1614-1618, 2017 | 70 | 2017 |
Transformer-feedback interstage bandwidth enhancement for MMIC multistage amplifiers G Nikandish, A Medi IEEE Transactions on Microwave Theory and Techniques 63 (2), 441-448, 2014 | 62 | 2014 |
A harmonic termination technique for single-and multi-band high-efficiency class-F MMIC power amplifiers G Nikandish, E Babakrpur, A Medi IEEE Transactions on Microwave Theory and Techniques 62 (5), 1212-1220, 2014 | 62 | 2014 |
The (R) evolution of distributed amplifiers: From vacuum tubes to modern CMOS and GaN ICs G Nikandish, RB Staszewski, A Zhu IEEE Microwave Magazine 19 (4), 66-83, 2018 | 61 | 2018 |
Unilateralization of MMIC distributed amplifiers G Nikandish, A Medi IEEE Transactions on Microwave Theory and Techniques 62 (12), 3041-3052, 2014 | 60 | 2014 |
Bandwidth enhancement of GaN MMIC Doherty power amplifiers using broadband transformer-based load modulation network G Nikandish, RB Staszewski, A Zhu IEEE Access 7, 119844-119855, 2019 | 43 | 2019 |
A design procedure for high-efficiency and compact-size 5–10-W MMIC power amplifiers in GaAs pHEMT technology G Nikandish, A Medi IEEE transactions on microwave theory and techniques 61 (8), 2922-2933, 2013 | 40 | 2013 |
Broadband Fully Integrated GaN Power Amplifier With Minimum-Inductance BPF Matching and Two-Transistor AM-PM Compensation GR Nikandish, RB Staszewski, A Zhu IEEE Transactions on Circuits and Systems I: Regular Papers, 2020 | 32 | 2020 |
Design of Highly Linear Broadband Continuous Mode GaN MMIC Power Amplifiers for 5G G Nikandish, RB Staszewski, A Zhu IEEE Access 7 (1), 57138-57150, 2019 | 31 | 2019 |
GaN integrated circuit power amplifiers: Developments and prospects R Nikandish IEEE Journal of Microwaves 3 (1), 441-452, 2022 | 28 | 2022 |
Design and analysis of broadband Darlington amplifiers with bandwidth enhancement in GaAs pHEMT technology G Nikandish, A Medi IEEE transactions on microwave theory and techniques 62 (8), 1705-1715, 2014 | 27 | 2014 |
Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement GR Nikandish, RB Staszewski, A Zhu IEEE Journal of Solid-State Circuits, 2020 | 26 | 2020 |
Semiconductor quantum computing: Toward a CMOS quantum computer on chip R Nikandish, E Blokhina, D Leipold, RB Staszewski IEEE Nanotechnology Magazine 15 (6), 8-20, 2021 | 22 | 2021 |
A broadband fully integrated power amplifier using waveform shaping multi-resonance harmonic matching network GR Nikandish, A Nasri, A Yousefi, A Zhu, RB Staszewski IEEE Transactions on Circuits and Systems I: Regular Papers 69 (1), 2-15, 2021 | 20 | 2021 |
A Fully Integrated GaN Dual-Channel Power Amplifier With Crosstalk Suppression for 5G Massive MIMO Transmitters GR Nikandish, RB Staszewski, A Zhu IEEE Transactions on Circuits and Systems II: Express Briefs, 2020 | 18 | 2020 |
Broadband Fully Integrated GaN Power Amplifier With Embedded Minimum Inductor Bandpass Filter and AM–PM Compensation G Nikandish, RB Staszewski, A Zhu IEEE Solid-State Circuits Letters 2 (9), 159-162, 2019 | 12 | 2019 |
Broadband Fully Integrated GaN Power Amplifier With Embedded Minimum Inductor Bandpass Filter and AM–PM Compensation G Nikandish, RB Staszewski, A Zhu IEEE 45th European Solid State Circuits Conference (ESSCIRC), 159-162, 2019 | 12 | 2019 |
INL prediction method in pipeline ADCs G Nikandish, B Sedighi, MS Bakhtiar APCCAS 2006-2006 IEEE Asia Pacific Conference on Circuits and Systems, 13-16, 2006 | 11 | 2006 |