A DC–Ka-Band 7-Bit Passive Attenuator with Capacitive-Compensation-Based Bandwidth Extension Technique in 55-nm CMOS
Zhang, Z.; Li, N.; Gao, H.; Li, M.; Wang, S.; Kuan, Y.; Song, C.; Yu, X.; Gu, Q.J.; Xu, Z.
IEEE Transactions on Microwave Theory and Techniques 69(8): 3861-3874
2021
ISSN/ISBN: 0018-9480 DOI: 10.1109/tmtt.2021.3074635
Accession: 080987707
Full-Text Article emailed within 0-6 h
Payments are secure & encrypted
References
Zhang, Z.; Li, N.; Gao, H.; Li, M.; Wang, S.; Kuan, Y.C.; Yu, X.; Xu, Z. 2020: A DC-32GHz 7-bit passive attenuator with capacitive compensation bandwidth extension technique in 55 nm CMOS IEEE MTT-S International Microwave Symposium Digest 2020-August: 1303-1306Gu, P.; Zhao, D.; You, X. 2020: A DC-50 GHz CMOS Switched-Type Attenuator with Capacitive Compensation Technique IEEE Transactions on Circuits and Systems I: Regular Papers 67(10): 3389-3399
Zhao, X.; Zhang, K. 2025: A K-Band CMOS Switched-Type Attenuator with Temperature Compensation Technique Proceedings of International Conference on ASIC
Yang, G.; Tang, K.; Wang, Z. 2020: 3.6‐8.1 GHz CMOS balun with 1.8° in‐band phase difference by using capacitive balance compensation technique Microwave and Optical Technology Letters 62(4): 1548-1551
Sun, A.; Gu, J.; Xu, H.; Liu, W.; Yin, R.; Han, K.; Duan, Z.; Gao, H.; Yan, N. 2025: A 26–32-GHz CMOS Attenuator With Optimized Capacitive Compensation and High Linearity Enhancement IEEE Transactions on Microwave Theory and Techniques 73(7): 3997-4009
Min, D.; Park, C. 2025: Ka-Band CMOS Variable-Gain Amplifier Using Capacitive Compensation Technique to Suppress Phase Error IEEE Transactions on Circuits and Systems II: Express Briefs 72(1): 118-122
Wang, C.; Wang, Y.; Zhu, L.; Gao, Z.; Ma, K. 2025: A Ka-Band 5-bit Passive Attenuator in 28 nm CMOS 2025 International Applied Computational Electromagnetics Society Symposium, ACES-China 2025 - Proceedings
Sun, J.; Liu, Z.; Hua, J.; Zhao, M. 2024: Ka-Band High-Linearity Attenuator with PVT Fluctuation Calibration for Temperature Compensation in 65-nm CMOS 2024 IEEE International Symposium on Radio-Frequency Integration Technology, RFIT 2024 - Proceedings
Zhao, C.; Zeng, X.; Zhang, L.; Liu, H.; Yu, Y.; Wu, Y.; Kang, K. 2020: A 37–40-GHz Low-Phase-Imbalance CMOS Attenuator with Tail-Capacitor Compensation Technique IEEE Transactions on Circuits and Systems I: Regular Papers 67(10): 3400-3409
Kayanselcuk, T.; Zencir, E. 2021: Ultra-Wide Bandwidth Fully Differential CMOS Opamp with a Novel Bandwidth Extension Technique for SoC Active Filter Applications Journal of Circuits, Systems and Computers 30(12): A19
Dong, H.; Deng, K.; Qiu, B.; Shaohui; Feng, H. 2024: A 0.6-8.1 GHz, 2 dB NF inductorless LNTA in 22 nm CMOS with novel bandwidth extension technique 2024 IEEE International Conference on Integrated Circuits, Technologies and Applications, ICTA 2024: 154-155
Ben-Esmael, M.; Hart, B.; Hayatleh, K.; Lidgey, F. 2014: CMRR-bandwidth extension technique for CMOS differential amplifiers AEU - International Journal of Electronics and Communications 68(10): 990-993
Bhatt, N; Kosta, Y 2015: A novel approach for artificial bandwidth extension of speech signals by LPC technique over proposed GSM FR NB coder using high band feature extraction and various extension of excitation methods International Journal of Speech Technology 18(1): 57-64
Liu, Y.; Kong, D.; Guo, R.; Wang, J.J.; Ning, N.; Yu, Q.; Wei, J.; Liu, Y. 2017: A 3–10 GHz UWB LNA Using gm-Boosting Structure and Inductive-Peaking-Based Bandwidth Extension Technique in a 180 nm CMOS Technology Nanoscience and Nanotechnology Letters 9(4): 453-457
Chen, Y.; Mak, P.; Yu, H.; Boon, C.C.; Martins, R.P. 2017: An Area-Efficient and Tunable Bandwidth- Extension Technique for a Wideband CMOS Amplifier Handling 50+ Gb/s Signaling IEEE Transactions on Microwave Theory and Techniques 65(12): 4960-4975
Baek, M.-s.; Lee, B.-c.; Song, J.-h.; Kim, J.-h.; Lim, J.-t.; Kim, C.Y. 2025: A 6-bit CMOS Attenuator With Low Phase Variation Using a Bandpass Response Capacitive π-Bridge Network IEEE Microwave and Wireless Technology Letters 35(11): 1744-1747
Wang, C.; Deng, B.; Liu, M.; Wang, Y.; Pan, D.; Sun, L. 2025: An E-Band Frequency Quadrupler With Temperature Compensation Technique in 28-nm Bulk CMOS IEEE Microwave and Wireless Technology Letters 35(11): 1811-1814
Cho, M.; Song, I.; Fleetwood, Z.E.; Cressler, J.D. 2018: A Si Ge-Bi CMOS Wideband Active Bidirectional Digital Step Attenuator with Bandwidth Tuning and Equalization IEEE Transactions on Microwave Theory and Techniques 66(8): 3866-3876
Wang, X.; Zhang, Q.; Wang, K. 2024: A DC-40GHz Switched-Type Attenuator with Combined Capacitive-Inductive Compensation Achieving RMS Amplitude/Phase Errors of <0.23dB/1.3° 2024 IEEE MTT-S International Wireless Symposium, IWS 2024 - Proceedings
Ozkan, B.ır; Zencir, E. 2026: A Highly Linear Passive Attenuator and Mixer Designs for an Observation Receiver in 130-nm SOI CMOS International Journal of Circuit Theory and Applications