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https://scholar.google.com/citations?user=hHxsez8AAAAJ&hl=zh-CN
[25] He D, Deng X, Chen Y, Zhang W, Hao J, Hu P, Chen L, Lee YK, Tang K. Feedrate-preserved motion planning for five-axis directed energy deposition of freeform metal parts[J]. Additive Manufacturing, 2024, 89: 104302.[Link]
[24] Chen Y1, He D1, Hao J, Deng X, Zhang W, Fu Z, Wang Y, Chen L, Hu P, Tang K. Five-axis hybrid manufacturing with DED and milling for complex multi-branched metallic parts[J]. International Journal of Computer Integrated Manufacturing, 2025: 1-30.[Link]
[23] He D, Li X, Li Z, Xie J, Hao J, Lee YK, Hu P, Tang K. Iso-force rough machining of freeform deep cavities based on volumetric fields[J]. Journal of Manufacturing Processes, 2024, 131: 1970-1986.[Link]
[22] He D, Li Z, Li X, Li Y, Tang K. Collision-conscious multi-pass flank milling of complicated parts based on stripification[J]. Computer-Aided Design, 2023, 157: 103469.[Link]
[21] He D, Li Z, Li Y, Tang K. Quasi-developable and signed multi-strip approximation of a freeform surface mesh for efficient flank milling[J]. Computer-Aided Design, 2021, 140: 103083.[Link]
[20] He D, Li Y, Li Z, Tang K. Geodesic distance field-based process planning for five-axis machining of complicated parts[J]. Journal of Manufacturing Science and Engineering, 2021, 143(6): 61009.[Link]
[19] He D, Cao H. Downsampling-based synchrosqueezing transform and its applications on large-scale vibration data[J]. Journal of Sound and Vibration, 2021, 496: 115938.[Link]
[18] He D, Cao H, Wang S, Chen X. Time-reassigned synchrosqueezing transform: the algorithm and its applications in mechanical signal processing[J]. Mechanical Systems and Signal Processing, 2019, 117: 255-279.(“ESI高被引”)[Link]
[18] Deng X, Hu P, Li Z, Zhang W, He D, Chen Y. Reinforcement Learning-based five-axis continuous inspection method for complex freeform surface[J]. Robotics and Computer-Integrated Manufacturing, 2025, 94: 102990.[Link]
[17] Xu S, Liu J, He D, Tang K, Yaji K. Self-support structure topology optimization for multi-axis additive manufacturing incorporated with curved layer slicing[J]. Computer Methods in Applied Mechanics and Engineering, 2025, 438: 117841.[Link]
[16] Wang N, Li Y, Liu C, Zhao Z, He D, Tang K. Parameter optimization of ultrasonic impact for deformation control based on dual information neural network[J]. Journal of Manufacturing Processes, 2025, 137: 113-124.[Link]
[15] Ding Y, Li Z, He D, Tang K, Hu P. Geodesic distance field-based five-axis continuous sweep scanning method for the multi-entrance inwall surface[J]. IEEE Transactions on Automation Science and Engineering, 2025.[Link]
[14] Deng X, Hu P, Li Z, Zhang W, He D, Chen Y. Reinforcement learning-based five-axis continuous inspection method for complex freeform surface[J]. Robotics and Computer-Integrated Manufacturing, 2025, 94: 102990.[Link]
[13] Li X, Li Z, He D, Ren J, Feng Q, Tang K. Efficient machining of a complex blisk channel using a disc cutter[J]. Chinese Journal of Aeronautics, 2024, 37(1): 414-437.[Link]
[12] Li Z, He D, Li X, Deng X, Hu P, Hao J, Hou Y, Yu H, Tang K. Efficient five-axis scanning-inspection path planning for complex freeform surfaces[J]. Robotics and Computer-Integrated Manufacturing, 2024, 86: 102687.[Link]
[11] Hao J, He D, Li Z, Hu P, Chen Y, Tang K. Efficient cutting path planning for a non-spherical tool based on an iso-scallop height distance field[J]. Chinese Journal of Aeronautics, 2024, 37(7): 496-510.[Link]
[10] Lau TY, Chen L, He D, Li Z, Tang K. Partition-based print sequence planning and adaptive slicing for scalar field-based multi-axis additive manufacturing[J]. Computer-Aided Design, 2023, 163: 103576.[Link]
[9] Wang E, Hao X, He D, Tang K. Physical prior and tikhonov regularization based residual stress inference method for annular parts using deformation force[J]. Journal of Advanced Manufacturing Science and Technology, 2023, 3(3).[Link]
[8] Zhao Y, Liu C, Zhao Z, Tang K, He D. Reinforcement learning method for machining deformation control based on meta-invariant feature space[J]. Visual Computing for Industry, Biomedicine, and Art, 2022, 5(1): 27.[Link]
[7] Xie F, Jing X, Zhang C, Chen S, Bi D, Li Z, He D, Tang K. Volume decomposition for multi-axis support-free and gouging-free printing based on ellipsoidal slicing[J]. Computer-Aided Design, 2022, 143: 103135.[Link]
[6] Lu X, Zhou Y, He D, Zheng F, Tang K, Tang J. A novel two-variable optimization algorithm of TCA for the design of face gear drives[J]. Mechanism and Machine Theory, 2022, 175: 104960.[Link]
[5] Li Z, He D, Xu K, Xie F, Tang K. Kinematics-based five-axis trochoidal milling process planning for deep and curved three-dimensional slots[J]. Journal of Manufacturing Science and Engineering, 2022, 144(2): 21005.[Link]
[4] Li Y, He D, Yuan S, Tang K, Zhu J. Vector field-based curved layer slicing and path planning for multi-axis printing[J]. Robotics and Computer-Integrated Manufacturing, 2022, 77: 102362.[Link]
[3] Hao J, Li Z, Li X, Xie F, He D, Tang K. Partition-based 3+ 2-axis tool path generation for freeform surface machining using a non-spherical tool[J]. Journal of Computational Design and Engineering, 2022, 9(5): 1585-1601.[Link]
[2] Li Y, Tang K, He D, Wang X. Multi-axis support-free printing of freeform parts with lattice infill structures[J]. Computer-Aided Design, 2021, 133: 102986.[Link]
[1] Cao H, He D, Xi S, Chen X. Vibration signal correction of unbalanced rotor due to angular speed fluctuation[J]. Mechanical Systems and Signal Processing, 2018, 107: 202-220.[Link]