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Dae-Woong Park
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2020 – today
- 2024
- [j8]Abdul Qahir, Dzuhri Radityo Utomo, Byeonghun Yun, Kyung-Sik Choi, Dae-Woong Park, Sang-Gug Lee:
High-Power 150/245-GHz Fundamental Oscillators With 12.1/-2.54-dBm Peak Output Power for Phased Array Transceivers. IEEE J. Solid State Circuits 59(11): 3683-3693 (2024) - [j7]Hyo-Ryeong Jeon, Dae-Woong Park, Sang-Gug Lee:
A D-Band Differential Amplifier With Cross-Couple of Series-Connected Capacitor and Transmission Line-Based Dual-Frequency Gmax-Core. IEEE Trans. Circuits Syst. II Express Briefs 71(6): 2996-3000 (2024) - 2023
- [j6]Byeonghun Yun, Dae-Woong Park, Sang-Gug Lee:
H-Band Power Amplifiers in 65-nm CMOS by Adopting Output Power Maximized Gmax-Core and Transmission Line-Based Zero-Degree Power Combining Networks. IEEE J. Solid State Circuits 58(11): 3089-3102 (2023) - [c7]Pratap Tumkur Renukaswamy, Kristof Vaesen, Nereo Markulic, Veerle Derudder, Dae-Woong Park, Piet Wambacq, Jan Craninckx:
A 16GHz, $41\text{kHz}_{\text{rms}}$ Frequency Error, Background-Calibrated, Duty-Cycled FMCW Charge-Pump PLL. ISSCC 2023: 74-75 - 2022
- [j5]Anirudh Kankuppe, Sehoon Park, Kristof Vaesen, Dae-Woong Park, Barend van Liempd, Siddhartha Sinha, Piet Wambacq, Jan Craninckx:
A 67-mW D-Band FMCW I/Q Radar Receiver With an N-Path Spillover Notch Filter in 28-nm CMOS. IEEE J. Solid State Circuits 57(7): 1982-1996 (2022) - [j4]Sehoon Park, Dae-Woong Park, Kristof Vaesen, Anirudh Kankuppe, Siddhartha Sinha, Barend van Liempd, Piet Wambacq, Jan Craninckx:
A D-Band Low-Power and High-Efficiency Frequency Multiply-by-9 FMCW Radar Transmitter in 28-nm CMOS. IEEE J. Solid State Circuits 57(7): 2114-2129 (2022) - 2021
- [j3]Dae-Woong Park, Dzuhri Radityo Utomo, Byeonghun Yun, Hafiz Usman Mahmood, Sang-Gug Lee:
A D-Band Power Amplifier in 65-nm CMOS by Adopting Simultaneous Output Power-and Gain-Matched Gmax-Core. IEEE Access 9: 99039-99049 (2021) - [j2]Dae-Woong Park, Dzuhri Radityo Utomo, Byeonghun Yun, Hafiz Usman Mahmood, Jong-Phil Hong, Sang-Gug Lee:
Design of High-Gain Sub-THz Regenerative Amplifiers Based on Double-Gmax Gain Boosting Technique. IEEE J. Solid State Circuits 56(11): 3388-3398 (2021) - [c6]Byeonghun Yun, Dae-Woong Park, Kyung-Sik Choi, Ho-Jin Song, Sang-Gug Lee:
245/243GHz, 9.2/10.5dBm Saturated Output Power, 4.6/2.8% PAE, and 28/26dB Gain Power Amplifiers in 65nm CMOS Adopting 2-and 4-way Power Combining. A-SSCC 2021: 1-3 - [c5]Anirudh Kankuppe, Sehoon Park, Kristof Vaesen, Dae-Woong Park, Barend van Liempd, Piet Wambacq, Jan Craninckx:
A 67mW D-band FMCW I/Q Radar Receiver with an N-path Spillover Notch Filter in 28nm CMOS. ESSCIRC 2021: 471-474 - 2020
- [c4]Dae-Woong Park, Dzuhri Radityo Utomo, Jong-Phil Hong, Kristof Vaesen, Piet Wambacq, Sang-Gug Lee:
A 247 and 272 GHz Two-Stage Regenerative Amplifiers in 65 nm CMOS with 18 and 15 dB Gain Based on Double-Gmax Gain Boosting Technique. VLSI Circuits 2020: 1-2 - [c3]Dzuhri Radityo Utomo, Dae-Woong Park, Byeonghun Yun, Sang-Gug Lee:
A 293/440 GHz Push-Push Double Feedback Oscillators with 5.0/-3.9 dBm Output Power and 2.9/0.6 % DC-to-RF Efficiency in 65 nm CMOS. VLSI Circuits 2020: 1-2
2010 – 2019
- 2019
- [j1]Dae-Woong Park, Dzuhri Radityo Utomo, Bao Huu Lam, Sang-Gug Lee, Jong-Phil Hong:
A 230-260-GHz Wideband and High-Gain Amplifier in 65-nm CMOS Based on Dual-Peak $G_{{\mathrm{max}}}$ -Core. IEEE J. Solid State Circuits 54(6): 1613-1623 (2019) - 2018
- [c2]Dae-Woong Park, Dzuhri Radityo Utomo, Jong-Phil Hong, Sang-Gug Lee:
A 230-260GHz wideband amplifier in 65nm CMOS based on dual-peak Gmax-core. ASP-DAC 2018: 301-302 - 2017
- [c1]Sun-a Kim, Kyoung-Yong Choi, Dae-Woong Park, Joo-Myoung Kim, Seok-Kyun Han, Sang-Gug Lee:
0.5 and 1.5 THz monolithic imagers in a 65 nm CMOS adopting a VCO-based signal processing. A-SSCC 2017: 149-152
Coauthor Index
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last updated on 2024-12-02 21:29 CET by the dblp team
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