Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
Sharifzadeh, Mohammad
and
Aukes, Daniel M.
2021.
Curvature-Induced Buckling for Flapping-Wing Vehicles.
IEEE/ASME Transactions on Mechatronics,
Vol. 26,
Issue. 1,
p.
503.
Qiu, Hongcheng
Bi, Shusheng
Wang, Bo
and
Cai, Yueri
2021.
Design and Hydrodynamic Analysis of a Robotic Boxfish Using Lift-based and Drag-based Swimming Modes for Propulsion.
p.
323.
Piskur, Paweł
Szymak, Piotr
Przybylski, Michał
Naus, Krzysztof
Jaskólski, Krzysztof
and
Żokowski, Mariusz
2021.
Innovative Energy-Saving Propulsion System for Low-Speed Biomimetic Underwater Vehicles.
Energies,
Vol. 14,
Issue. 24,
p.
8418.
Chen, Di
Wu, Zhengxing
Dong, Huijie
Tan, Min
and
Yu, Junzhi
2021.
Exploration of swimming performance for a biomimetic multi-joint robotic fish with a compliant passive joint.
Bioinspiration & Biomimetics,
Vol. 16,
Issue. 2,
p.
026007.
White, Carl H
Lauder, George V
and
Bart-Smith, Hilary
2021.
Tunabot Flex: a tuna-inspired robot with body flexibility improves high-performance swimming.
Bioinspiration & Biomimetics,
Vol. 16,
Issue. 2,
p.
026019.
Sharifzadeh, Mohammad
Jiang, Yuhao
and
Aukes, Daniel M.
2021.
Reconfigurable Curved Beams for Selectable Swimming Gaits in an Underwater Robot.
IEEE Robotics and Automation Letters,
Vol. 6,
Issue. 2,
p.
3437.
Naser, Farah Abbas
and
Rashid, Mofeed Turky
2021.
Labriform Swimming Robot with Steering and Diving Capabilities.
Journal of Intelligent & Robotic Systems,
Vol. 103,
Issue. 1,
Wang, Zhuo
Wang, Luoyao
Wang, Tao
and
Zhang, Bo
2022.
Research and experiments on electromagnetic-driven multi-joint bionic fish.
Robotica,
Vol. 40,
Issue. 3,
p.
720.
Naser, Farah Abbas
and
Rashid, Mofeed Turky
2022.
Design and implementation of a swimming robot with pectoral fins only.
Robotica,
Vol. 40,
Issue. 10,
p.
3557.
Lee, Jinwoo
Yoon, Yeosang
Park, Huijae
Choi, Joonhwa
Jung, Yeongju
Ko, Seung Hwan
and
Yeo, Woon-Hong
2022.
Bioinspired Soft Robotic Fish for Wireless Underwater Control of Gliding Locomotion.
Advanced Intelligent Systems,
Vol. 4,
Issue. 7,
Chen, Di
Wu, Zhengxing
Meng, Yan
Tan, Min
and
Yu, Junzhi
2022.
Development of a High-Speed Swimming Robot With the Capability of Fish-Like Leaping.
IEEE/ASME Transactions on Mechatronics,
Vol. 27,
Issue. 5,
p.
3579.
Xu, Yaohui
Hu, Junzhe
Song, Jinhua
Xie, Fengran
Zuo, Qiyang
and
He, Kai
2022.
A Novel Multiple Synchronous Compliant and Passive Propeller Inspired by Loons for Swimming Robot.
p.
563.
Su, Zhengguo
Yu, Fusheng
Zhu, Baoxing
Han, Wenjun
Wang, Qingda
and
Li, Wentao
2022.
Dynamic analysis of the sinusoidal actuation of a flexible fin for paired fin propulsion.
Physics of Fluids,
Vol. 34,
Issue. 5,
p.
051909.
Tong, Ru
Wu, Zhengxing
Chen, Di
Wang, Jian
Du, Sheng
Tan, Min
and
Yu, Junzhi
2022.
Design and Optimization of an Untethered High-Performance Robotic Tuna.
IEEE/ASME Transactions on Mechatronics,
Vol. 27,
Issue. 5,
p.
4132.
Li, Yi
Xu, Yuteng
Wu, Zhenguo
Ma, Lei
Guo, Mingfei
Li, Zhixin
and
Li, Yanbiao
2022.
A comprehensive review on fish-inspired robots.
International Journal of Advanced Robotic Systems,
Vol. 19,
Issue. 3,
Liu, Yanwen
and
Jiang, Hongzhou
2022.
Research Development on Fish Swimming.
Chinese Journal of Mechanical Engineering,
Vol. 35,
Issue. 1,
Su, Zhengguo
Shen, Xiaoqin
Han, Wenjun
Zhu, Baoxing
Wang, Qingda
and
Li, Wentao
2023.
Dynamic analysis of symmetric oscillation and turning characteristics of a flexible fin underwater robot propelled by double fins.
Physics of Fluids,
Vol. 35,
Issue. 3,
Kwak, Bokeon
Choi, Soyoung
and
Bae, Joonbum
2023.
Development of a Stiffness‐Adjustable Articulated Paddle and its Application to a Swimming Robot.
Advanced Intelligent Systems,
Vol. 5,
Issue. 5,
Pham, Van Anh
Tran, Thanh Tung
Dao, Minh Duc
Nguyen, Vinh Phoi
Bui, Trung Kien
Nguyen, Quan
and
Vo, Tuong Quan
2023.
A Dynamic Analysis and Realization of Diodontiform Fish Robot.
p.
156.
Xu, Yaohui
Li, Hanlin
Yu, Furui
Zuo, Qiyang
Xie, Fengran
Xie, Xiang
and
He, Kai
2023.
A Novel Omnidirectional Swimming Robot With Articulated-Compliant Legs.
IEEE Robotics and Automation Letters,
Vol. 8,
Issue. 9,
p.
5664.