https://orcid.org/0000-0003-1603-2325
References
- Fang J, Sun G, Qiu N, et al. On design optimization for structural crashworthiness and its state of the art. Struct Multidisc Optim. 2017;55(3):1091–1119.
- Gang Z, Tong P, Sun G, et al. Theoretical, numerical, and experimental study on laterally variable thickness (LVT) multi-cell tubes for crashworthiness. Int J Mech Sci. 2016;118:283–297.
- Yang K, Xu S, Zhou S, et al. Multi-objective optimization of multi-cell tubes with origami patterns for energy absorption. Thin-Walled Struct. 2018;123:100–113.
- Liu W, Lin Z, Wang N, et al. Dynamic performances of thin-walled tubes with star-shaped cross section under axial impact. Thin-Walled Struct. 2016;100:25–37.
- Zhang X, Leng K, Zhang H. Axial crushing of embedded multi-cell tubes. Int J Mech Sci. 2017;131-132:459–470.
- Xie S, Du X, Zhou H, et al. Crashworthiness of nomex honeycomb-filled anti-climbing energy absorbing devices. Int J Crashworthiness. 2021;26(2):121–132.
- Ha NS, Pham TM, Hao H, et al. Energy absorption characteristics of bio-inspired hierarchical multi-cell square tubes under axial crushing. Int J Mech Sci. 2021;201:106464.
- Ganilova OA, Low JJ. Application of smart honeycomb structures for automotive passive safety. Proc Inst Mech Eng D J Automob Eng. 2018;232(6):797–811.
- Lv X, Gu X, He L, et al. Reliability design optimization of vehicle front-end structure for pedestrian lower extremity protection under multiple impact cases. Thin-Walled Struct. 2015;94:500–511.
- Sun G, Pang T, Fang J, et al. Parameterization of criss-cross configurations for multiobjective crashworthiness optimization. Int J Mech Sci. 2017;124-125:145–157.
- Zhang Y, Xu X, Wang J, et al. Crushing analysis for novel bio-inspired hierarchical circular structures subjected to axial load. Int J Mech Sci. 2018;140:407–431.
- Jusuf A, Dirgantara T, Gunawan L, et al. Crashworthiness analysis of multi-cell prismatic structures. Int J Impact Eng. 2015;78:34–50.
- Yamashita M, Gotoh M, Sawairi Y. Axial crush of hollow cylindrical structures with various polygonal cross-sections: numerical simulation and experiment. J Mater Process Technol. 2003;140(1–3):59–64.
- Huang ZL, Jiang C, Zhou YS, et al. Reliability-based design optimization for problems with interval distribution parameters. Struct Multidiscipl Optim. 2017;55:1–16.
- Mck M, Hanss MF. Efficient possibilistic uncertainty analysis of a car crash scenario using a multi-fidelity approach. ASCE-ASME J Risk Uncert Eng Syst Part B Mech Eng. 2019;5(4):72–89.
- Wu HX, Mao HF, Hou HB. Study on crashworthiness and reliability of compositebamboo-like thin-walled tube. J Nanjing Univ Sci Technol. 2017;41:186–190.
- Hao Z. A hybrid GA-FS algorithm with fuzzy approximation scheme for solving credibilistic reliability optimization problem. Evolut Intell. 2;2021:1–11.
- Wu H, Kuang S, Hou H. Research on application of electric vehicle collision based on reliability optimization design method. Int J Comput Methods. 2019;16(07):1950034.
- Wang W, Dai S, Zhao W, et al. Reliability-based optimization of a novel negative Poisson’s ratio door anti-collision beam under side impact. Thin-Walled Struct. 2020;154(1):106863.
- Wang XR, Li SJ, Ma RM. Optimal design of interval reliability for uncertain structures. J Northeastern Univ. 2020;41:521–527.
- Xu X, Chen X, Liu Z, et al. Reliability-based design for lightweight vehicle structures with uncertain manufacturing accuracy. Appl Math Modell. 2021;95:22–37.
- Sun G, Zhang H, Wang R, et al. Multiobjective reliability-based optimization for crashworthy structures coupled with metal forming process. Struct Multidiscipl Optim. 2017;56:1571–1587.
- Kumar A, Sharma R. Multi-response optimization of magnetic field assisted EDM through desirability function using response surface methodology. J Mech Behav Mater. 2020;29(1):19–35.
- Gu X, Sun G, Li G, et al. Multiobjective optimization design for vehicle occupant restraint system under frontal impact. Struct Multidisc Optim. 2013;47(3):465–477.
- Qin RX, Zhou JX, Chen BZ. Crashworthiness design and multiobjective optimization for hexagon honeycomb structure with functionally graded thickness. Adv Mater Sci Eng. 2019;2019:1–13.
- Sun G, Li G, Stone M, et al. A two-stage multi-fidelity optimization procedure for honeycomb-type cellular materials. Comput Mater Sci. 2010;49(3):500–511.
- Liu HB, Song YJ, Gong YF. Static finite element model updating for special-shaped bridge based on response surface method. Appl Mech Mater. 2012;236:611–616.
- Sun G, Liu T, Fang J, et al. Configurational optimization of multi-cell topologies for multiple oblique loads. Struct Multidisc Optim. 2018;57(2):469–488.
- Cui J, Zhao Z, Liu JW, et al. Uncertainty analysis of mechanical dynamics by combining response surface method with signal decomposition technique. Mech Syst Signal Process. 2021;158:107570.
- Abdullahi HS, Gao S. A novel multi-cell square tubal structure based on Voronoi tessellation for enhanced crashworthiness. Thin-Walled Struct. 2020;150:106690.
- Zhang X, Zhang H. Numerical and theoretical studies on energy absorption of three-panel angle elements. Int J Impact Eng. 2012;46:23–40.
- Abramowicz W. Thin-walled structures as impact energy absorbers. Thin-Walled Struct. 2003;41(2–3):91–107.
- Nia AA, Parsapour M. An investigation on the energy absorption characteristics of multi-cell square tubes. Thin-Walled Struct. 2013;68(10):26–34.
- Xiong Z, Huh H. Crushing analysis of polygonal columns and angle elements. Int J Impact Eng. 2010;37(4):441–451.
- Wei J, Zhang J, Du X. Interval motion accuracy reliability analysis of manipulators based on chebyshev inclusion polynomial. J Harbin Inst Technol. 2019;26(02):36–44.