Publications: [1] Sun C, Tian J, Huang R, Dong H, Li H, Ma Y. Internal layout optimization of the blended-wing-body underwater glider based on a range target. Ocean Engineering. 2023. 280: N. PAG. doi: 10.1016/j.oceaneng. 2023. 114450. [2] Sun C, Song B, Wang P. Parametric geometric model and shape optimization of an underwater glider with blended-wing-body [J]. International Journal of Naval Architecture & Ocean Engineering, 2015, 7(6): 995-1006. [3] Sun C, Song B, Peng W, et al. Shape optimization of blended-wing-body underwater glider by using gliding range as the optimization target [J]. International Journal of Naval Architecture & Ocean Engineering, 2017, 9(6): S2092678216305416. [4] Sun C, Song B, Peng W, et al. Energy consumption optimization of steady-state gliding for a Blended-Wing-Body underwater glider [C]// Oceans. 2016. [5]Zhao L, Wang P, Sun C Y, et al. Modeling and Motion Simulation for A Flying-Wing Underwater Glider with A Symmetrical Airfoil [J]. China Ocean Eng (2019) 33: 322. [6]Wang, X., Song, B., Wang, P., & Sun, C. (2018). Hydrofoil optimization of underwater glider using free-form deformation and surrogate-based optimization. International Journal of Naval Architecture and Ocean Engineering, S2092678217301395. [7]Zhang, B., Song, B., Mao, Z., Jiang, J., & Sun, C. (2016). Hydrodynamic characteristics and stability simulation of four-rotor dish-shaped UUV landing on the seabed. Oceans. IEEE. |
