[2] H GAO, H ZHANG, Q WU et al. Investigation on influences of initial residual stress on thin-walled part machining deformation based on a semi-analytical model. Journal of Materials Processing Technology, 437-448(2018).

[4] N HUANG, Q BI, Y WANG et al. 5-Axis adaptive flank milling of flexible thin-walled parts based on the on-machine measurement. International Journal of Machine Tools and Manufacture, 1-8(2014).

[5] S K ZHANG, Y L JI, N D HUANG et al. Integrated profile and thickness error compensation for curved part based onon-machine measurement. Robotics and Computer-Integrated Manufacturing, 1-9(2023).

[7] Z L LI, L M ZHU. Compensation of deformation errors in five-axis flank milling of thin-walledparts via tool path optimization. Precision Engineering, 77-87(2019).

[10] X Z WANG, Z L LI, Q Z BI et al. An accelerated convergence approach for real-time deformationcompensation in large thin-walled parts machining. International Journal of Machine Tools and Manufacture, 98-106(2019).

[12] Q Z BI, N D HUANG, S K ZHANG et al. Adaptive machining for curved contour on deformed large skin based on on-machine measurement and isometric mapping. International Journal of Machine Tools and Manufacture, 34-44(2019).

[16] T BERA, K DESAI, P RAO. Error compensation in flexible end milling of tubular geometries. Journal of Materials Processing Technology, 211, 24-34(2010).

[17] X JIANG, Y WANG, Z DING et al. An approach to predict the distortion of thin-walled parts affected by residual stress during the milling process. The International Journal of Advanced Manufacturing Technology, 4203-4216(2017).

[18] X HUANG, J SUN, J LI. Finite element simulation and experimental investigation on the residual stress-related monolithic component deformation. The International Journal of Advanced Manufacturing Technology, 1035-1041(2015).

[20] Y YANG, M LI, K R LI. Comparison and analysis of main effect elements of machining distortion for aluminum alloy and titanium alloy aircraft monolithic component. The International Journal of Advanced Manufacturing Technology, 1803-1811(2014).

[21] Y CHEN, Y HUANG, K WU et al. Cutting force validation and volumetric errors compensation of thin workpieces with sensory tool holder. The International Journal of Advanced Manufacturing Technology, 299-312(2020).

[23] J HAO, Z LI, X LI et al. Partition-based 3+2-axis tool path generation for freeform surface machining using a non-spherical tool. Journal of Computational Design and Engineering, 9, 1585-1601(2022).

[24] H WEN, C YE, Z ZHANG. Data Transformation for the Optimal Projection Direction of Mesh Surface, 1203-1207(2023).

[25] V GIRI, D BEZBARUAH, P BUBNA et al. Selection of master cutter paths in sculptured surface machining by employing curvature principle. International Journal of Machine Tools and Manufacture, 45, 1202-1209(2005).

[26] Y LIU, G ZHAO, O ZAVALNYI et al. Toolpath generation for partition machining of T-spline surface based on local refinement. The International Journal of Advanced Manufacturing Technology, 102, 3051-3064(2019).