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ORCIDJung-Dong Park
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2020 – today
- 2023
[j22]Jeong-Moon Song
, Van-Son Trinh, Sooyeon Kim, Jung-Dong Park:
275 GHz Quadrature Receivers for THz-Band 6G Indoor Network in 130-nm SiGe Technology. IEEE Access 11: 138540-138548 (2023)- [j21]Hyeonseok Lee, Hyeong-Geun Park, Van-Du Le, Van-Phu Nguyen, Jeong-Moon Song, Bok-Hyung Lee, Jung-Dong Park:
X-band MMICs for a Low-Cost Radar Transmit/Receive Module in 250 nm GaN HEMT Technology. Sensors 23(10): 4840 (2023) - 2022
- [j20]Jeong-Moon Song, Jung-Dong Park:
A 5-11 GHz 8-bit Precision Passive True-Time Delay in 65-nm CMOS Technology. IEEE Access 10: 18456-18462 (2022) - [j19]Van-Son Trinh, Jung-Dong Park:
An 85-GHz Power Amplifier Utilizing a Transformer-Based Power Combiner Operating Beyond the Self-Resonance Frequency. IEEE J. Solid State Circuits 57(3): 882-891 (2022) - [j18]Hyeonseok Lee, Van-Son Trinh, Jung-Dong Park:
A 90 GHz Broadband Balanced 8-Way Power Amplifier for High Precision FMCW Radar Sensors in 65-nm CMOS. Sensors 22(9): 3114 (2022) - [j17]Van-Son Trinh, Hyohyun Nam, Jeong-Moon Song, Jung-Dong Park:
A 78.8-84 GHz Phase Locked Loop Synthesizer for a W-Band Frequency-Hopping FMCW Radar Transceiver in 65 nm CMOS. Sensors 22(10): 3626 (2022) - [j16]Jun-Hee Lee, Mun-Kyo Lee, Jung-Dong Park:
A Direct Feedback FVF LDO for High Precision FMCW Radar Sensors in 65-nm CMOS Technology. Sensors 22(24): 9672 (2022) - 2021
- [j15]Van-Son Trinh, Jung-Dong Park:
A 25.1 dBm 25.9-dB Gain 25.4% PAE X-band Power Amplifier Utilizing Voltage Combining Transformer in 65-nm CMOS. IEEE Access 9: 6513-6521 (2021) - [j14]Van-Son Trinh, Jung-Dong Park:
A 16.4-dBm 20.3% PAE 22-dB Gain 77 GHz Power Amplifier in 65-nm CMOS Technology. IEEE Access 9: 159541-159548 (2021) - 2020
- [j13]Van-Son Trinh, Jung-Dong Park:
Common-Mode Stability Test and Design Guidelines for a Transformer-Based Push-Pull Power Amplifier. IEEE Access 8: 42243-42250 (2020) - [j12]Hyohyun Nam, Van-Viet Nguyen, Van-Son Trinh, Jeong-Moon Song, Bok-Hyung Lee, Jung-Dong Park:
A Full X-Band Phased-Array Transmit/Receive Module Chip in 65-nm CMOS Technology. IEEE Access 8: 76182-76192 (2020)
2010 – 2019
- 2019
- [j11]Jung-Dong Park, MuhibUr Rahman, Hsiang Nerng Chen:
Isolation Enhancement of Wide-Band MIMO Array Antennas Utilizing Resistive Loading. IEEE Access 7: 81020-81026 (2019) - [j10]Hsiang Nerng Chen, Jeong-Moon Song, Jung-Dong Park:
A Compact Circularly Polarized MIMO Dielectric Resonator Antenna Over Electromagnetic Band-Gap Surface for 5G Applications. IEEE Access 7: 140889-140898 (2019) - [j9]Van-Son Trinh, Jung-Dong Park:
Theory and Design of Impedance Matching Network Utilizing a Lossy On-Chip Transformer. IEEE Access 7: 140980-140989 (2019) - 2018
- [j8]Hyohyun Nam, Junsik Park, Jung-Dong Park:
A 1-13 GHz CMOS low-noise amplifier using compact transformer-based inter-stage networks. IEICE Electron. Express 15(2): 20171019 (2018) - [j7]MuhibUr Rahman, Jung-Dong Park:
The Smallest Form Factor UWB Antenna with Quintuple Rejection Bands for IoT Applications Utilizing RSRR and RCSRR. Sensors 18(3): 911 (2018) - [j6]Van-Viet Nguyen, Hyohyun Nam, Young Joe Choe, Bok-Hyung Lee, Jung-Dong Park:
An X-band Bi-Directional Transmit/Receive Module for a Phased Array System in 65-nm CMOS. Sensors 18(8): 2569 (2018) - 2017
- [j5]MuhibUr Rahman, Dong-Sik Ko, Jung-Dong Park:
A Compact Multiple Notched Ultra-Wide Band Antenna with an Analysis of the CSRR-TO-CSRR Coupling for Portable UWB Applications. Sensors 17(10): 2174 (2017) - 2014
- [j4]Jung-Dong Park:
260 GHz spatially combined transmitter with a V-band distributed OOK modulator. IEICE Electron. Express 11(18): 20140736 (2014) - [j3]Jung-Dong Park:
Design of switching-mode CMOS frequency multipliers in sub-Terahertz regime. IEICE Electron. Express 11(18): 20140806 (2014) - 2012
- [j2]Jung-Dong Park, Shinwon Kang, Ali M. Niknejad:
A 0.38 THz Fully Integrated Transceiver Utilizing a Quadrature Push-Push Harmonic Circuitry in SiGe BiCMOS. IEEE J. Solid State Circuits 47(10): 2344-2354 (2012) - [c2]Jung-Dong Park, Shinwon Kang, Siva V. Thyagarajan, Elad Alon, Ali M. Niknejad:
A 260 GHz fully integrated CMOS transceiver for wireless chip-to-chip communication. VLSIC 2012: 48-49
2000 – 2009
- 2009
- [j1]Cristian Marcu, Debopriyo Chowdhury, Chintan Thakkar, Jung-Dong Park, Lingkai Kong, Maryam Tabesh, Yanjie Wang, Bagher Afshar, Abhinav Gupta, Amin Arbabian, Simone Gambini, Reza Zamani, Elad Alon, Ali M. Niknejad:
A 90 nm CMOS Low-Power 60 GHz Transceiver With Integrated Baseband Circuitry. IEEE J. Solid State Circuits 44(12): 3434-3447 (2009) - [c1]Cristian Marcu, Debopriyo Chowdhury, Chintan Thakkar, Lingkai Kong, Maryam Tabesh, Jung-Dong Park, Yanjie Wang, Bagher Afshar, Abhinav Gupta, Amin Arbabian, Simone Gambini, Reza Zamani, Ali M. Niknejad, Elad Alon:
A 90nm CMOS low-power 60GHz transceiver with integrated baseband circuitry. ISSCC 2009: 314-315
Coauthor Index
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