FEniCS/FEniCSx complete code for magnetic actuation on magnetorheological elastomers modelling the entire boundary value problem for the permanent magnet and electromagnet actuation setups. The content includes two cases: 1. A simulation case where the magnetic actuation is imposed using a permanent magnet: simulation_permanentmagnet_slender_fenics.py: python code for running the simulation; mesh_permanentmagnet_slender.msh and mesh_permanentmagnet_slender.geo: files related to the meshes of the domains. 2. A simulation case where the magnetic actuation is imposed using an electromagnet. The code is provided for both FEniCS and FEniCSx. 2.1. FEniCS case. simulation_electromagnet_slender_fenics.py: python code for running the simulation; mesh_electromagnet_slender.msh and mesh_electromagnet_slender.geo: files related to the meshes of the domains. 2.2. FEniCSx case. simulation_electromagnet_slender_fenicsx.py: python code for running the simulation; mesh_electromagnet_slender.msh and mesh_electromagnet_slender.geo: files related to the meshes of the domains. Copyright (C) 2023: Miguel Angel Moreno-Mateos, Kostas Danas, Daniel Garcia-Gonzalez If using this code for research or industrial purposes, please cite: M.A. Moreno-Mateos, K. Danas, D. Garcia-Gonzalez. Influence of magnetic boundary conditions on the quantitative modelling of magnetorheological elastomers. Mechanics of Materials, 2023.

{"references": ["M.A. Moreno-Mateos, K. Danas, D. Garcia-Gonzalez. Influence of magnetic boundary conditions on the quantitative modelling of magnetorheological elastomers. Mechanics of Materials, 2023."]}