Dynamic model of a deep-groove ball bearing including localized and distributed defects. Part 1: Theory J Sopanen, A Mikkola Proceedings of the Institution of Mechanical Engineers, Part K: Journal of …, 2003 | 380 | 2003 |
Dynamic model of a deep-groove ball bearing including localized and distributed defects. Part 2: Implementation and results J Sopanen, A Mikkola Proceedings of the Institution of Mechanical Engineers, Part K: Journal of …, 2003 | 227 | 2003 |
Description of elastic forces in absolute nodal coordinate formulation JT Sopanen, AM Mikkola Nonlinear Dynamics 34, 53-74, 2003 | 213 | 2003 |
Multidisciplinary design process of a 6-slot 2-pole high-speed permanent-magnet synchronous machine N Uzhegov, E Kurvinen, J Nerg, J Pyrhönen, JT Sopanen, S Shirinskii IEEE Transactions on Industrial Electronics 63 (2), 784-795, 2015 | 197 | 2015 |
A two-dimensional shear deformable beam element based on the absolute nodal coordinate formulation KE Dufva, JT Sopanen, AM Mikkola Journal of Sound and Vibration 280 (3-5), 719-738, 2005 | 131 | 2005 |
Dynamic torque analysis of a wind turbine drive train including a direct-driven permanent-magnet generator J Sopanen, V Ruuskanen, J Nerg, J Pyrhonen IEEE Transactions on Industrial Electronics 58 (9), 3859-3867, 2010 | 126 | 2010 |
Chatter avoidance in cutting highly flexible workpieces G Stepan, AK Kiss, B Ghalamchi, J Sopanen, D Bachrathy CIRP Annals 66 (1), 377-380, 2017 | 77 | 2017 |
Planetary gear sets power loss modeling: Application to wind turbines C Nutakor, A Kłodowski, J Sopanen, A Mikkola, JI Pedrero Tribology International 105, 42-54, 2017 | 65 | 2017 |
Dynamic simulation of a flexible rotor during drop on retainer bearings A Kärkkäinen, J Sopanen, A Mikkola Journal of Sound and Vibration 306 (3-5), 601-617, 2007 | 59 | 2007 |
A linear beam finite element based on the absolute nodal coordinate formulation KS Kerkkänen, JT Sopanen, AM Mikkola | 56 | 2005 |
Simple and versatile dynamic model of spherical roller bearing B Ghalamchi, J Sopanen, A Mikkola International Journal of Rotating Machinery 2013, 2013 | 55 | 2013 |
Active magnetic bearing-supported rotor with misaligned cageless backup bearings: A dropdown event simulation model O Halminen, A Kärkkäinen, J Sopanen, A Mikkola Mechanical Systems and Signal Processing 50, 692-705, 2015 | 53 | 2015 |
Multidisciplinary design of a permanent-magnet traction motor for a hybrid bus taking the load cycle into account P Lindh, MG Tehrani, T Lindh, JH Montonen, J Pyrhönen, JT Sopanen, ... IEEE Transactions on Industrial Electronics 63 (6), 3397-3408, 2016 | 50 | 2016 |
Ball bearing model performance on various sized rotors with and without centrifugal and gyroscopic forces E Kurvinen, J Sopanen, A Mikkola Mechanism and Machine Theory 90, 240-260, 2015 | 45 | 2015 |
Computationally efficient approach for simulation of multibody and hydraulic dynamics J Rahikainen, M Kiani, J Sopanen, P Jalali, A Mikkola Mechanism and Machine Theory 130, 435-446, 2018 | 43 | 2018 |
Three-dimensional beam element based on a cross-sectional coordinate system approach KE Dufva, JT Sopanen, AM Mikkola Nonlinear Dynamics 43, 311-327, 2006 | 39 | 2006 |
Deformable terrain model for the real-time multibody simulation of a tractor with a hydraulically driven front-loader S Jaiswal, P Korkealaakso, R Åman, J Sopanen, A Mikkola IEEE Access 7, 172694-172708, 2019 | 35 | 2019 |
On the cosimulation of multibody systems and hydraulic dynamics J Rahikainen, F González, MÁ Naya, J Sopanen, A Mikkola Multibody System Dynamics 50 (2), 143-167, 2020 | 34 | 2020 |
Efficiency comparison of various friction models of a hydraulic cylinder in the framework of multibody system dynamics S Jaiswal, J Sopanen, A Mikkola Nonlinear Dynamics 104 (4), 3497-3515, 2021 | 31 | 2021 |
Combined semi-recursive formulation and lumped fluid method for monolithic simulation of multibody and hydraulic dynamics J Rahikainen, A Mikkola, J Sopanen, J Gerstmayr Multibody System Dynamics 44 (3), 293-311, 2018 | 29 | 2018 |