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Yu Zhu 0001
Person information
- affiliation: Tsinghua University, Department of Mechanical Engineering, Beijing, China
Other persons with the same name
- Yu Zhu — disambiguation page
- Yu Zhu 0002
(aka: Mike Yu Zhu) — Fudan University, Department of Communication Science and Engineering, State Key Laboratory of ASIC and System, Shanghai, China (and 1 more)
- Yu Zhu 0003
- Yu Zhu 0004
- Yu Zhu 0005
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2020 – today
- 2025
- [j76]Yunan Wang, Chuxiong Hu, Zeyang Li, Zhirui He, Shiwen Lin, Yushuo Wang, Shize Lin, Jichuan Yu, Zhao Jin, Yu Zhu:
On the consistency of path smoothing and trajectory planning in CNC machining: A surface-centric evaluation. Robotics Comput. Integr. Manuf. 92: 102873 (2025) - 2024
- [j75]Bingyang Hou, Ze Wang
Gate recurrent unit neural network based high-precision feedforward control for piezoelectric nanopositioning stage. Eng. Appl. Artif. Intell. 133: 108126 (2024) - [j74]Guo Zhang, Shunyao Wang, Zhenwei Chen
Development of China's spaceborne SAR satellite, processing strategy, and application: take Gaofen-3 series as an example. Geo spatial Inf. Sci. 27(1): 221-236 (2024) - [j73]Shuaihu Wu
High-Accuracy Sensorless Control of Permanent Magnet Linear Synchronous Motors for Variable Speed Trajectories. IEEE Trans. Ind. Electron. 71(5): 4396-4406 (2024) - [j72]Ran Zhou
Intelligent GRU-RIC Position-Loop Feedforward Compensation Control Method With Application to an Ultraprecision Motion Stage. IEEE Trans. Ind. Informatics 20(4): 5609-5621 (2024) - [j71]Bingyang Hou
Energy-Selected Iterative Learning Control: A Novel Perspective to Analyze Precision Motion Control Tasks. IEEE Trans. Ind. Informatics 20(8): 10565-10575 (2024) - [j70]Ran Zhou
Real-Time Iterative Compensation Control Using Plant-Injection Feedforward Architecture With Application to Ultraprecision Wafer Stages. IEEE Trans. Ind. Informatics 20(10): 11708-11719 (2024) - [j69]Shize Lin
Real-Time Local Greedy Search for Multiaxis Globally Time-Optimal Trajectory. IEEE Trans. Syst. Man Cybern. Syst. 54(2): 960-971 (2024) - [c34]Jichuan Yu, Zhao Jin, Chuxiong Hu, Jizhou Yan, Ze Wang, Yu Zhu:
Hierarchical Real-time Motion Planning for Safe Multi-robot Manipulation in Dynamic Environments. ICARM 2024: 113-119 - [c33]Ran Zhou, Chuxiong Hu, Ze Wang, Yu Zhu:
Ultraprecision Contouring Control with Enhanced Accuracy and Robustness: An Online Prediction Based Real-Time Iterative Compensation Method. MESA 2024: 1-7 - 2023
- [j68]Luzheng Liu, Chuxiong Hu
Selective Detection of Mixtures via a Single Nonselective Sensor - Making the Unworkable Sensor Workable by Machine Learning. Adv. Intell. Syst. 5(1) (2023) - [j67]Luzheng Liu, Chuxiong Hu
Selective Detection of Mixtures via a Single Nonselective Sensor - Making the Unworkable Sensor Workable by Machine Learning. Adv. Intell. Syst. 5(1) (2023) - [j66]Suqin He
A hierarchical long short term safety framework for efficient robot manipulation under uncertainty. Robotics Comput. Integr. Manuf. 82: 102522 (2023) - [j65]Yunan Wang
Optimization-based non-equidistant toolpath planning for robotic additive manufacturing with non-underfill orientation. Robotics Comput. Integr. Manuf. 84: 102599 (2023) - [j64]Ran Zhou
Nonlinearity Compensation and High-Frequency Flexibility Suppression Based RIC Method for Precision Motion Control Systems. IEEE Trans. Ind. Informatics 19(2): 1332-1342 (2023) - [j63]Min Li
Rational Feedforward Tuning Using Variance-Optimal Instrumental Variables Method Based on Dual-Loop Iterative Learning Control. IEEE Trans. Ind. Informatics 19(3): 2585-2595 (2023) - [j62]Ziyan Zhao
Back EMF-Based Dynamic Position Estimation in the Whole Speed Range for Precision Sensorless Control of PMLSM. IEEE Trans. Ind. Informatics 19(5): 6525-6536 (2023) - [c32]Chinchin Liu, Chuxiong Hu, Bingyang Hou, Ze Wang, Yu Zhu:
Model-Free Adaptive Nonlinearity and Hysteresis Compensation Control Strategy with Application to Nano-Precision Piezoelectric Stage. ICCMA 2023: 363-368 - [c31]Yunan Wang, Chuxiong Hu, Ze Wang, Shize Lin, Ziyan Zhao, Yu Zhu:
Slice Extension for High-Quality Hybrid Additive-Subtractive Manufacturing. IECON 2023: 1-6 - [c30]Luzheng Liu, Chuxiong Hu, Jichuan Yu, Wenxiang Zhao, Ze Wang, Yu Zhu:
Odors Can Be Amplified by Noses: Sensitivity Enhancing Bio-Inspired Nasal Structures for Micro Cataluminescence Gas Sensors. SENSORS 2023: 1-4 - [c29]Jiayue Zhang, Ze Wang, Chuxiong Hu, Yu Zhu:
A Real-Time Contour Error Estimation Method Based on Triple Taylor Expansion for Multiaxis Motion Systems. RCAR 2023: 469-474 - [c28]Bingyang Hou, Ze Wang, Chuxiong Hu, Yu Zhu:
Hysteresis Effect Suppression: Replacing Modeling with Linear and Nonlinear Methods Combination. ROBIO 2023: 1-6 - [c27]Ze Wang, Zihang Shang, Chuxiong Hu, Yu Zhu:
A Highly Integrated Shape Memory Alloy Actuator With Precision Real-time Self-sensing Control. ROBIO 2023: 1-6 - [i1]Yunan Wang, Chuxiong Hu, Zeyang Li, Shize Lin, Suqin He, Ze Wang, Yu Zhu:
Time-Optimal Control for High-Order Chain-of-Integrators Systems with Full State Constraints and Arbitrary Terminal States. CoRR abs/2311.07039 (2023) - 2022
- [j61]Ran Zhou
Comparative Study of Performance-Oriented Feedforward Compensation Strategies for Precision Mechatronic Motion Systems. IEEE Access 10: 100812-100823 (2022) - [j60]Chuxiong Hu, Ran Zhou
Real-Time Iterative Compensation Framework for Precision Mechatronic Motion Control Systems. IEEE CAA J. Autom. Sinica 9(7): 1218-1232 (2022) - [j59]Suqin He
An Online Time-Optimal Trajectory Planning Method for Constrained Multi-Axis Trajectory With Guaranteed Feasibility. IEEE Robotics Autom. Lett. 7(3): 7375-7382 (2022) - [j58]Chuxiong Hu
Task Space Contouring Error Estimation and Precision Iterative Control of Robotic Manipulators. IEEE Robotics Autom. Lett. 7(3): 7826-7833 (2022) - [j57]Weinan Ye, Rong Cheng, Ming Zhang, Yu Zhu, Leijie Wang, Jinchun Hu, Xin Li:
Grating Interferometer with Redundant Design for Performing Wide-Range Displacement Measurements. Sensors 22(10): 3738 (2022) - [j56]Taoyang Wang
Large-Scale Orthorectification of GF-3 SAR Images Without Ground Control Points for China's Land Area. IEEE Trans. Geosci. Remote. Sens. 60: 1-17 (2022) - [j55]Min Li
Dual-Loop Iterative Learning Control With Application to an Ultraprecision Wafer Stage. IEEE Trans. Ind. Electron. 69(11): 11590-11599 (2022) - [j54]Ze Wang
Online Iterative Learning Compensation Method Based on Model Prediction for Trajectory Tracking Control Systems. IEEE Trans. Ind. Informatics 18(1): 415-425 (2022) - [j53]Tingrui Wen
A Signal Processing Method for Homodyne Laser Interferometer Based on Model Parameter Self-Calibration With Redundant Information. IEEE Trans. Instrum. Meas. 71: 1-11 (2022) - [c26]Hong Fu, Yixuan Liang, Chuxiong Hu, Yu Zhu:
High-Accuracy Oriented CILC Motion Control of Mechatronic Systems with Comparative Experiments. AIM 2022: 1309-1314 - [c25]Shuaihu Wu, Chuxiong Hu, Ziyan Zhao
A Novel Flux Estimator Using α-β Orthogonality Drift Elimination for High Performance Full-Speed-Range Sensorless Control. AIM 2022: 1315-1320 - [c24]Yunan Wang
Learning Latent Object-Centric Representations for Visual-Based Robot Manipulation. ICARM 2022: 138-143 - [c23]Tiansheng Ou, Chuxiong Hu, Yu Zhu, Ming Zhang:
Advanced LARC Strategy of Maglev Planar Motor with GRU Neural Network Prediction. MESA 2022: 1-6 - 2021
- [j52]Jiayu Wang
Dynamics Learning With Object-Centric Interaction Networks for Robot Manipulation. IEEE Access 9: 68277-68288 (2021) - [j51]Yujie Li, Ming Zhang, Yu Zhu, Xin Li, Leijie Wang:
Soft Sensor Model for Estimating the POI Displacement Based on a Dynamic Neural Network. J. Adv. Comput. Intell. Intell. Informatics 25(6): 963-973 (2021) - [j50]Jiayu Wang
CPG-Based Hierarchical Locomotion Control for Modular Quadrupedal Robots Using Deep Reinforcement Learning. IEEE Robotics Autom. Lett. 6(4): 7193-7200 (2021) - [j49]Luyao Dai
Quantitative Tracking Error Analysis and Feedforward Compensation Under Different Model-Based Feedforward Controllers in Different Control Architectures. IEEE Trans. Ind. Electron. 68(1): 381-390 (2021) - [j48]Chuxiong Hu
GRU-Type LARC Strategy for Precision Motion Control With Accurate Tracking Error Prediction. IEEE Trans. Ind. Electron. 68(1): 812-820 (2021) - [j47]Luyao Dai
Enhancing Settling Performance of Precision Motion Systems by Phase-Based Variable Gain Feedback Control. IEEE Trans. Ind. Electron. 68(5): 4099-4108 (2021) - [j46]Tiansheng Ou
Intelligent Feedforward Compensation Motion Control of Maglev Planar Motor With Precise Reference Modification Prediction. IEEE Trans. Ind. Electron. 68(9): 7768-7777 (2021) - [j45]Luyao Dai
Feedforward Tuning by Fitting Iterative Learning Control Signal for Precision Motion Systems. IEEE Trans. Ind. Electron. 68(9): 8412-8421 (2021) - [c22]Weicai Huang, Kaiming Yang
MIMO Data-Driven Feedforward Tuning for the Ultra-precision Wafer Stage Using Rational Basis Functions. ICIRA (2) 2021: 353-363 - [c21]Jiayu Wang, Chuxiong Hu, Yu Zhu:
Hierarchical Gait Generation for Modular Robots Using Deep Reinforcement Learning. ICM 2021: 1-6 - [c20]Ran Zhou
Model Prediction based Online Feedforward Compensation Control of Maglev Planar Motor with Comparative Investigation. ICM 2021: 1-6 - [c19]Ze Wang, Ran Zhou
Precision RIC Contouring Control Method for Polar Coordinate Motion Systems. RCAR 2021: 744-749 - [c18]Shize Lin, Ze Wang, Chuxiong Hu, Yu Zhu:
Time-Optimal Trajectory Planning for Robots with Identified Dynamics. ROBIO 2021: 1890-1895 - 2020
- [j44]Suqin He, Chuxiong Hu, Yu Zhu, Masayoshi Tomizuka:
Time optimal control of triple integrator with input saturation and full state constraints. Autom. 122: 109240 (2020) - [j43]Yuyang Qian, Kaiming Yang, Yu Zhu, Wei Wang, Chenhui Wan
Combining deep learning and model-based method using Bayesian Inference for walking speed estimation. Biomed. Signal Process. Control. 62: 102117 (2020) - [j42]Weicai Huang, Kaiming Yang
Data-driven rational feedforward tuning: With application to an ultraprecision wafer stage. J. Syst. Control. Eng. 234(6) (2020) - [j41]Jiayu Wang
Learning Semantic Keypoint Representations for Door Opening Manipulation. IEEE Robotics Autom. Lett. 5(4): 6980-6987 (2020) - [j40]Yizhou Xia
Analysis of the Errors Caused by Disturbed Multimode Fibers in the Interferometer with Fiber-Coupled Delivery. Sensors 20(5): 1513 (2020) - [j39]Zhouyu Huai
A Novel Electrodynamic Reaction Sphere Prototype for Spacecraft Attitude Control. IEEE Trans. Ind. Electron. 67(5): 3879-3890 (2020) - [j38]Min Li
Data-Based Iterative Dynamic Decoupling Control for Precision MIMO Motion Systems. IEEE Trans. Ind. Informatics 16(3): 1668-1676 (2020) - [j37]Wei Wang
Speed adaptation and acceleration ripple suppression of treadmill user system using a virtual force moment balance model. Trans. Inst. Meas. Control 42(2): 322-329 (2020)
2010 – 2019
- 2019
- [j36]Weinan Ye, Ming Zhang, Yu Zhu, Leijie Wang, Jinchun Hu, Xin Li, Chuxiong Hu:
Ultraprecision Real-Time Displacements Calculation Algorithm for the Grating Interferometer System. Sensors 19(10): 2409 (2019) - [j35]Fuzhong Yang, Ming Zhang, Yu Zhu, Weinan Ye, Leijie Wang, Yizhou Xia
Two Degree-of-Freedom Fiber-Coupled Heterodyne Grating Interferometer with Milli-Radian Operating Range of Rotation. Sensors 19(14): 3219 (2019) - [j34]Min Li
Convergence Rate Oriented Iterative Feedback Tuning With Application to an Ultraprecision Wafer Stage. IEEE Trans. Ind. Electron. 66(3): 1993-2003 (2019) - [j33]Luyao Dai
The Generation Mechanism of Tracking Error During Acceleration or Deceleration Phase in Ultraprecision Motion Systems. IEEE Trans. Ind. Electron. 66(9): 7109-7119 (2019) - [j32]Tao Huang
LFT-Structured Uncertainty State-Space Modeling for State Feedback Robust Control of the Ultra-Precision Wafer Stage. IEEE Trans. Ind. Electron. 66(11): 8567-8577 (2019) - [j31]Min Li
Data-Based Switching Feedforward Control for Repeating and Varying Tasks: With Application to an Ultraprecision Wafer Stage. IEEE Trans. Ind. Electron. 66(11): 8670-8680 (2019) - [j30]Ze Wang
Double Taylor Expansion-Based Real-Time Contouring Error Estimation for Multiaxis Motion Systems. IEEE Trans. Ind. Electron. 66(12): 9490-9499 (2019) - [j29]Ze Wang
Dynamical Model Based Contouring Error Position-Loop Feedforward Control for Multiaxis Motion Systems. IEEE Trans. Ind. Informatics 15(8): 4686-4695 (2019) - [c17]Luyao Dai, Xin Li, Yu Zhu, Ming Zhang:
Quantitative Analysis on Tracking Error Under Different Control Architectures and Feedforward Methods. ACC 2019: 5680-5686 - 2018
- [j28]Chuxiong Hu
Generalized GTCF Coordination Mechanism Based LARC Contouring Control of Industrial Motion Stages for Complex Contours. IEEE Access 6: 20067-20076 (2018) - [j27]Chuxiong Hu
Model-Data Driven Learning Adaptive Robust Control of Precision Mechatronic Motion Systems With Comparative Experiments. IEEE Access 6: 78286-78296 (2018) - [j26]Sen Lu, Kaiming Yang, Yu Zhu, Leijie Wang, Ming Zhang, Jin Yang:
Yaw error correction of ultra-precision stage for scanning beam interference lithography systems. J. Syst. Control. Eng. 232(7): 869-878 (2018) - [j25]Guo Zhang
Block Adjustment without GCPs for Chinese Spaceborne SAR GF-3 Imagery. Sensors 18(11): 4023 (2018) - [j24]Ze Wang, Chuxiong Hu
Newton-ILC Contouring Error Estimation and Coordinated Motion Control for Precision Multiaxis Systems With Comparative Experiments. IEEE Trans. Ind. Electron. 65(2): 1470-1480 (2018) - [c16]Chuxiong Hu, Tiansheng Ou, Haonan Chang, Yu Zhu, Ze Wang:
Neural-Network Feedforward Compensation for Precision Contouring Control of Multi-Axis Motion Systems. ICIA 2018: 306-311 - [c15]Haonan Chang, Chuxiong Hu, Ze Wang, Yu Zhu:
Precision Tracking Motion Control Using Deep GRU Network. ICIA 2018: 826-831 - [c14]Yu Zhu, Jing Wen, Liang Zhang, Yi Wang:
Visual Tracking with Dynamic Model Update and Results Fusion. ICIP 2018: 2685-2689 - 2017
- [j23]Chuxiong Hu
Advanced GTCF-LARC Contouring Motion Controller Design for an Industrial X-Y Linear Motor Stage With Experimental Investigation. IEEE Trans. Ind. Electron. 64(4): 3308-3318 (2017) - [j22]Min Li
An Integrated Model-Data-Based Zero-Phase Error Tracking Feedforward Control Strategy With Application to an Ultraprecision Wafer Stage. IEEE Trans. Ind. Electron. 64(5): 4139-4149 (2017) - [j21]Min Li
State/Model-Free Variable-Gain Discrete Sliding Mode Control for an Ultraprecision Wafer Stage. IEEE Trans. Ind. Electron. 64(8): 6695-6705 (2017) - [j20]Ze Wang, Chuxiong Hu, Yu Zhu, Suqin He
Neural Network Learning Adaptive Robust Control of an Industrial Linear Motor-Driven Stage With Disturbance Rejection Ability. IEEE Trans. Ind. Informatics 13(5): 2172-2183 (2017) - [j19]Shengwu Du, Jinchun Hu
An Improved Displacement Measurement Based on Model Reconstruction for Permanent Magnet Synchronous Motor. IEEE Trans. Instrum. Meas. 66(11): 3044-3051 (2017) - [c13]Ze Wang, Chuxiong Hu, Yu Zhu, Bin Yao:
Precision LARC motion control of an industrial biaxial mechatronic system for complex contours based on a generalized GTCF coordination mechanism. AIM 2017: 100-105 - [c12]Ze Wang, Chuxiong Hu, Yu Zhu, Bin Yao:
Newton-AGTCF reference trajectory modification scheme for precision biaxial contouring motion control. ICIA 2017: 124-129 - 2016
- [j18]Longmin Chen, Jinchun Hu, Yu Zhu, Rong Cheng:
A position measurement method for 3-degree-of-freedom motion based on magnetic detection. J. Syst. Control. Eng. 230(5): 467-479 (2016) - [j17]Chuxiong Hu, Ze Wang, Yu Zhu, Ming Zhang
Performance-Oriented Precision LARC Tracking Motion Control of a Magnetically Levitated Planar Motor With Comparative Experiments. IEEE Trans. Ind. Electron. 63(9): 5763-5773 (2016) - [c11]Chuxiong Hu, Yu Zhu, Zhipeng Hu, Ze Wang:
GTCF based LARC contouring motion control of an industrial X-Y linear-motor-driven stage. ACC 2016: 2162-2167 - [c10]Ze Wang, Chuxiong Hu, Yu Zhu, Bin Yao:
Precision NNLARC motion controller design for industrial mechatronic systems under complicated disturbances: A case study with comparative experiments. ICIA 2016: 252-257 - [c9]Chuxiong Hu, Suqin He
Desired compensation neural network adaptive robust control of an industrial linear motor motion system with comparative experimental investigation. ICIA 2016: 479-484 - [c8]Ji Chen, Chuxiong Hu, Yu Zhu, Ze Wang:
High-performance motion control of an XY stage for complicated contours with BFC trajectory planning. ICIA 2016: 1473-1478 - [c7]Mohan Chen, Jing Wen, Yu Zhu, Hao-Yang Xing, Yi Wang:
Multi-level thresholding for pupil location in eye-gaze tracking systerm. ICMLC 2016: 1009-1014 - 2015
- [j16]Tao Huang
Navigation of Mobile robot in unknown Environment Based on T-S Neuro-fuzzy System. Int. J. Robotics Autom. 30(4) (2015) - [j15]Yi Jiang, Yu Zhu, Kaiming Yang, Chuxiong Hu, Dongdong Yu:
A Data-Driven Iterative Decoupling Feedforward Control Strategy With Application to an Ultraprecision Motion Stage. IEEE Trans. Ind. Electron. 62(1): 620-627 (2015) - [j14]Min Li
A Data-Driven Variable-Gain Control Strategy for an Ultra-Precision Wafer Stage With Accelerated Iterative Parameter Tuning. IEEE Trans. Ind. Informatics 11(5): 1179-1189 (2015) - [c6]Zhipeng Hu, Chuxiong Hu, Yu Zhu, Jin Yang:
Performance-oriented investigation of adaptive robust control in iterative learning control framework with comparative experiments. AIM 2015: 743-748 - [c5]Yi Jiang, Yu Zhu, Kaiming Yang, Chuxiong Hu, Haihua Mu:
A novel data-driven controller tuning method for improving convergence performance. ACC 2015: 3230-3235 - [c4]Ze Wang, Chuxiong Hu, Yu Zhu, Ming Zhang:
Precision LARC motion controller design for a magnetically levitated planar motor. ICIA 2015: 1359-1364 - 2014
- [j13]Yi Jiang, Kaiming Yang, Yu Zhu, Xin Li, Dongdong Yu:
Optimal feedforward control with a parametric structure applied to a wafer stage. J. Syst. Control. Eng. 228(2): 97-106 (2014) - [j12]Dongdong Yu, Yu Zhu, Kaiming Yang, Chuxiong Hu, Min Li
A time-varying Q-filter design for iterative learning control with application to an ultra-precision dual-stage actuated wafer stage. J. Syst. Control. Eng. 228(9): 658-667 (2014) - [j11]Jin Yang, Yu Zhu, Wensheng Yin, Chuxiong Hu, Kaiming Yang, Haihua Mu:
LFT Structured Uncertainty Modeling and Robust Loop-Shaping Controller Optimization for an Ultraprecision Positioning Stage. IEEE Trans. Ind. Electron. 61(12): 7013-7025 (2014) - [c3]Han Chen, Chuxiong Hu, Haihua Mu, Yu Zhu, Tian Cai, Ming Zhang:
Structure design and trajectory planning of a precision repetitive-scanning stage with separated drive units for heat-reduction. AIM 2014: 859-564 - 2013
- [j10]Yu Zhu, Chuxiong Hu, Jinchun Hu, Kaiming Yang:
Accuracy- and Simplicity-Oriented Self-Calibration Approach for Two-Dimensional Precision Stages. IEEE Trans. Ind. Electron. 60(6): 2264-2272 (2013) - [j9]Chuxiong Hu, Yu Zhu, Jinchun Hu, Dengfeng Xu, Ming Zhang:
A Holistic Self-Calibration Approach for Determination of Three-Dimensional Stage Error. IEEE Trans. Instrum. Meas. 62(2): 483-494 (2013) - [c2]Chuxiong Hu, Yu Zhu, Jinchun Hu, Dengfeng Xu, Ming Zhang:
A novel on-axis self-calibration approach for precision rotary metrology stages. AIM 2013: 1072-1077 - [c1]Yu Zhu, Chuxiong Hu, Jinchun Hu, Ming Zhang, Dengfeng Xu:
On-axis self-calibration of precision XYθz metrology systems: An approach framework. AIM 2013: 1078-1083 - 2012
- [j8]Badong Chen, José C. Príncipe, Jinchun Hu, Yu Zhu:
Stochastic Information Gradient Algorithm with Generalized Gaussian Distribution Model. J. Circuits Syst. Comput. 21(1) (2012) - [j7]Jin Yang, Yu Zhu, Wensheng Yin, Chuxiong Hu:
Optimization of a phase stabilization controller for an ultra-precision positioning stage using a structured genetic algorithm. J. Syst. Control. Eng. 226(6): 841-851 (2012) - [j6]Dongdong Yu, Kaiming Yang, Yu Zhu, Xin Li, Leqing Cui:
Nonlinear iterative learning control applied to an aerostatic X-Y planar motion stage. J. Syst. Control. Eng. 226(9): 1174-1182 (2012) - [j5]Chuxiong Hu, Yu Zhu, Jinchun Hu, Ming Zhang, Dengfeng Xu:
A Holistic Self-Calibration Algorithm for xy Precision Metrology Systems. IEEE Trans. Instrum. Meas. 61(9): 2492-2500 (2012) - 2011
- [j4]Badong Chen, Yu Zhu, Jinchun Hu, José C. Príncipe:
Δ-Entropy: Definition, properties and applications in system identification with quantized data. Inf. Sci. 181(7): 1384-1402 (2011) - 2010
- [j3]Badong Chen, Yu Zhu, Jinchun Hu, Ming Zhang:
On optimal estimations with minimum error entropy criterion. J. Frankl. Inst. 347(2): 545-558 (2010) - [j2]Badong Chen, Yu Zhu, Jinchun Hu, Ming Zhang:
A new interpretation on the MMSE as a robust MEE criterion. Signal Process. 90(12): 3313-3316 (2010) - [j1]Badong Chen, Yu Zhu, Jinchun Hu:
Mean-square convergence analysis of ADALINE training with minimum error entropy criterion. IEEE Trans. Neural Networks 21(7): 1168-1179 (2010)
Coauthor Index
[j76] [j75] [j73] [j72] [j71] [j70] [j69] [c34] [c33] [j68] [j67] [j66] [j65] [j64] [j62] [c32] [c31] [c30] [c29] [c28] [c27] [i1] [j61] [j60] [j59] [j58] [j54] [c26] [c25] [c24] [c23] [j52] [j50] [j48] [j46] [c21] [c20] [c19] [c18] [j44] [j41] [j39] [j36] [j34] [j33] [j31] [j30] [j29] [j28] [j27] [j24] [c16] [c15] [j23] [j22] [j21] [j20] [c13] [c12] [j17] [c11] [c10] [c9] [c8] [j15] [j14] [c6] [c5] [c4] [j12] [j11] [c3] [j10] [j9] [c2] [c1] [j7] [j5]
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