崔健（研究員）檢視原始碼討論檢視歷史

崔健 北京大學集成電路學院

崔健，男，北京大學集成電路學院研究員。

人物履歷

科研/教育經歷

2011年獲得北京大學固體電子學與微電子學專業博士學位；2009-2010年 德國弗萊堡大學微系統研究所訪問學者；隨後在中國航天三院任高級工程師、副主任設計師，從事高精度導航級微慣性器件研究。2018年，加入北京大學微電子學研究院，任副研究員，高級工程師，現任北京大學集成電路學院院長助理、測試實驗室主任。

研究領域

微納慣性傳感器、微納工藝技術、複雜控制系統設計、精密信號處理技術

研究成果

崔健博士長期致力於微納傳感器件與系統的研究，在MEMS慣性器件、集成諧振器件、傳感器微弱信號檢測、精密信號處理電路、傳感器控制系統設計、自動化測試等方面取得多項重要創新性成果。承擔及參與國家重點研發計劃子課題、973項目子課題、裝發共性基金、航天創新基金及創新特區課題、裝發「十二五」預研、「十三五」預研、探索一代等項目十餘項，其中四項目結題獲評優秀。近年來的主要研究方向是高端傳感器產業化技術、微納加工及封裝技術，發表國內外SCI/EI 期刊和學術會議論文60餘篇，申請和授權國家發明專利20餘項。

歡迎對MEMS慣性傳感器、微導航系統及應用感興趣，喜歡廣泛閱讀、推導理論公式、自己動手設計和搭建設備的同學加入課題組。

學術成果

論文

• J. Cui and Q. Zhao, "A High Performance Tactical-grade Monolithic Horizontal Dual-axis MEMS Gyroscope with Off-plane Coupling Suppression Silicon Gratings," in IEEE Transactions on Industrial Electronics, 2022. doi: 10.1109/TIE.2021.3127036.
• Dong Li, Mengxia Liu, Qiancheng Zhao and Jian Cui*, 「Phase noise modelling of MEMS resonant accelerometer with non-AGC-driven circuit」, J. Micromech. Microeng.,32 064001.
• J. Cui, Q. Zhao and G. Yan, 「Effective bias warm-up time reduction for MEMS gyroscopes based on active suppression of the coupling stiffness」, MICROSYST NANOENG, vol. 5, (no. 1), pp. 18, 2019-01-01 2019.
• J. Cui, G. Yan, Q. Zhao, 「Enhanced temperature stability of scale factor in MEMS gyroscope based on multi parameters fusion compensation method」, Measurement, 2019, 148(106947).
• J. Cui, and Q. Zhao, 「Bias thermal stability improvement of MEMS gyroscope with quadrature motion correction and temperature self-sensing compensation,」 Micro & Nano Letters, 2020, 15(4), pp. 234-238.
• J. Cui, Yang H, Li D, Song Z, Zhao Q., 「A Silicon Resonant Accelerometer Embedded in an Isolation Frame with Stress Relief Anchor」, Micromachines. 2019; 10(9):571.
• Li D, Zhao Q. and J. Cui*, 「High-precision frequency measurement for microresonant sensors based on improved modified multi-phase clock method」, Review of Scientific Instruments, 92, 015004 (2021)
• Bai, Z., J. Cui*, Zhao, Q., Yang, Z. and Yan, G., 「Initial frequency split reduction of MEMS ring gyroscope based on cascaded springs geometrical compensation」. Electron. Lett., 2019, 55: 806-808.
• S. Chen, J. Cui* and Q. Zhao, "Proton Radiation Effect On Mechanical Structure of Silicon Mems Gyroscopes," IEEE MEMS 2022, pp. 758-761.
• M. Liu, J. Cui*, D. Li and Q. Zhao, "A 3 PPM/°C Temperature Coefficient of Scale Factor for a Silicon Resonant Accelerometer Based on Crystallographic Orientation Optimization," IEEE Transducers 2021, pp. 116-119.
• J. Cui and Q. Zhao, "In-Situ Mode-Matching Control for a Single-Chip Horizontal Dual-Axis MEMS Gyroscope Based on Modulating Quadrature Coupling with Silicon Gratings," IEEE Transducers 2021, pp. 1198-1201.
• J. Cui and Q. Zhao, "A Tactical-Grade Monolithic Horizontal Dual-Axis Mems Gyroscope Based on off-Plane Quadrature Coupling Suppression Silicon Gratings," IEEE MEMS 2021, Gainesville, FL, USA, pp. 814-817.
• J. Cui, M. Liu, H. Yang, D. Li and Q. Zhao, "Temperature Robust Silicon Resonant Accelerometer with Stress Isolation Frame Mounted on Axis-Symmetrical Anchors," IEEE MEMS 2020, Vancouver, BC, Canada, pp. 791-794.
• Yang, H., J. Cui *. and Zhao, Q., 「A wheeled horizontal dual-axis mems gyroscope based on single proof mass with mechanical coupling suppression silicon gratings,」 IEEE MEMS 2020, Vancouver, Canada, Jan. 18-22, pp. 749-752.
• J. Cui, Q. Zhao, Y. Wang and G. Yan, "Shortening Bias Warm-Up Time with Active Control of the Coupling Stiffness for Mems Gyroscopes," IEEE Transducers 2019, Berlin, Germany, pp. 2041-2044.
• J. Cui, Q. Zhao, Z. Bai and G. Yan, "An 8PPM/°C Temperature Sensitivity of the Scale Factor in MEMS Gyroscope Based on Multi Parameters Fusion Compensation Method," IEEE MEMS 2019, Seoul, Korea (South), pp. 696-699.
• Z. Bai, J. Cui*, Q. Zhao, Y. Wang and Z. Yang, "Geometric Compensation of (100) SCS Vibrating Ring Gyroscope for Mode-Matching Achieving High Immunity to Fabrication Imperfections," IEEE Transducers 2019, Berlin, Germany, pp. 1858-1861.
• J. Cui, C.H. He, Z.C. Yang, Z.Y. Guo, Y.L. Hao and G.Z. Yan, 「Virtual Rate-Table Method for Characterization of Microgyroscopes」, IEEE Sensors Journal, vol 12, pp.2192-2198, 2012.
• J. Cui, Z. Guo, Q. Zhao, Z. Yang, Y. Hao, and G. Yan, "Force Rebalance Controller Synthesis for a Micromachined Vibratory Gyroscope Based on Sensitivity Margin Specifications," Journal of Microelectromechanical Systems, vol. 20, pp. 1382-1394, 2011.
• J. Cui, Z. Y. Guo, Z. C. Yang, Y. L. Hao, and G. Z. Yan, "Electrical coupling suppression and transient response improvement for a microgyroscope using ascending frequency drive with a 2-DOF PID controller," Journal of Micromechanics and Microengineering, vol. 21, 2011.
• J. Cui, X. Liu, Z. Guo, Q. Zhao, L. Lin, Z. Yang, Y. Hao, and G. Yan, "An experimental investigation on decoupling performance for a lateral axis micromachined gyroscope with varying environmental parameters," SCIENCE CHINA Technological Sciences, vol. 54, pp. 3415-3423, 2011.
• J. Cui, X.Z. Chi, H.T. Ding, L.T. Lin, Z.C. Yang and G.Z. Yan, "Transient response and stability of the AGC-PI closed-loop controlled MEMS vibratory gyroscopes, " Journal of Micromechanics and Microengineering, vol. 19, Dec 2009.^[1]

參考資料