This work is licensed under the Creative Commons Attribution 4.0 International License.
Y. Li, M. Yang, H. Sun, Z. Liu, Y. Zhang, A novel amphibious spherical robot equipped with flywheel, pendulum, and propeller, Journal of Intelligent & Robotic Systems. 89 (2018) 485–501.LiY.YangM.SunH.LiuZ.ZhangY.A novel amphibious spherical robot equipped with flywheel, pendulum, and propellerJournal of Intelligent & Robotic Systems89201848550110.1007/s10846-017-0558-xSearch in Google Scholar
T.B. Ivanova, A.A. Kilin, E.N. Pivovarova, Controlled motion of a spherical robot with feedback I, Journal of Dynamical and Control Systems. 24 (2018) 497–510.IvanovaT.B.KilinA.A.PivovarovaE.N.Controlled motion of a spherical robot with feedback IJournal of Dynamical and Control Systems24201849751010.1007/s10883-017-9387-2Search in Google Scholar
Y.L. Karavaev, A.A. Kilin, The dynamics and control of a spherical robot with an internal omniwheel platform, Regular and Chaotic Dynamics. 20 (2015) 134–152.KaravaevY.L.KilinA.A.The dynamics and control of a spherical robot with an internal omniwheel platformRegular and Chaotic Dynamics20201513415210.1134/S1560354715020033Search in Google Scholar
S. Guo, S. Pan, L. Shi, P. Guo, Y. He, K. Tang, Visual detection and tracking system for a spherical amphibious robot, Sensors. 17 (2017) 870–890.GuoS.PanS.ShiL.GuoP.HeY.TangK.Visual detection and tracking system for a spherical amphibious robotSensors17201787089010.3390/s17040870542474728420134Search in Google Scholar
S. Guo, Y He, L Shi, S Pan, K Tang, R Xiao, P Guo, Modal and fatigue analysis of critical components of an amphibious spherical robot, Microsystem Technologies. 23 (2017) 2233–2247.GuoS.HeYShiLPanSTangKXiaoRGuoPModal and fatigue analysis of critical components of an amphibious spherical robotMicrosystem Technologies2320172233224710.1007/s00542-016-3083-0Search in Google Scholar
F. Michaud, J.F. Laplante, H. Larouche, A. Duquette, S. Caron, D. Letourneau, P. Masson, Autoniomous spherical mobile robot for child-development studies, IEEE Transactions on Systems, Man and Cybernetics-Part A: Systems and Humans. 4 (2005) 471–480.MichaudF.LaplanteJ.F.LaroucheH.DuquetteA.CaronS.LetourneauD.MassonP.Autoniomous spherical mobile robot for child-development studiesIEEE Transactions on Systems, Man and Cybernetics-Part A: Systems and Humans4200547148010.1109/TSMCA.2005.850596Search in Google Scholar
H. Sun, Y. Zheng, Q. Jia, D. Liu, C. Shi, Design of spherical robot with telescopic manipulator, Robot. 31(2009) 404–409.SunH.ZhengY.JiaQ.LiuD.ShiC.Design of spherical robot with telescopic manipulatorRobot312009404409Search in Google Scholar
Y. Ou, Y. Xu, Learning human control strategy for dynamically stable robots: support vector machine approach, Proc. of IEEE International Conference on Robotics and Automation. 3 (2003) 3455–3460.OuY.XuY.Learning human control strategy for dynamically stable robots: support vector machine approachProc. of IEEE International Conference on Robotics and Automation3200334553460Search in Google Scholar
L. Chen, M Zhou, M Wu, J She, Z Liu, F Dong, K Hirota, Three-layer weighted fuzzy support vector regression for emotional intention understanding in human-robot interaction, IEEE Transactions on Fuzzy Systems. 26 (2018) 2524–2538.ChenL.ZhouMWuMSheJLiuZDongFHirotaKThree-layer weighted fuzzy support vector regression for emotional intention understanding in human-robot interactionIEEE Transactions on Fuzzy Systems2620182524253810.1109/TFUZZ.2018.2809691Search in Google Scholar
E. Hortal, D. Planelles, A. Costa, E. Iáñez, A. Úbeda, J.M. Azorín, E. Fernández, SVM-based brain-machine interface for controlling a robot arm through four mental tasks, Neurocomputing. 151 (2015) 116–121.HortalE.PlanellesD.CostaA.IáñezE.ÚbedaA.AzorínJ.M.FernándezE.SVM-based brain-machine interface for controlling a robot arm through four mental tasksNeurocomputing151201511612110.1016/j.neucom.2014.09.078Search in Google Scholar
