) applies a rational coordinate scaling to a layer of virtual domains surrounding the physical region of interest. When the dependent variables vary slowly with radial distance from the center of the physical domain, the finite elements can be stretched in the radial direction such that boundary conditions on the outside of the infinite element layer are effectively applied at a very large distance from any region of interest.
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To display the Equation View node under all nodes creating variables, click the Show button and select Equation View. See also Equation View.
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If Spherical is selected, enter the position of the center of the spherical geometry in the Center coordinate table. For axisymmetric models, only the z coordinate is required since the geometry must be centered on the axis.
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If Cylindrical is selected, enter the position of a point on the cylinder axis in the Center coordinate table. For 3D models, also enter a Center axis direction vector.
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If User defined is selected, fist choose the Number of stretching directions appropriate for the geometrical configuration. Then for each stretching direction specify a Distance function, evaluating to the distance from the inner boundary of the infinite element domain measured in the stretching direction, and the Thickness of the domain in the same direction.
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Modeling of a 3D Inductor: Application Library path ACDC_Moduke/Inductive_Devices_and_Coils/inductor3D
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Voltammetry at a Microdisk Electrode: Application Library path Batteries_and_Fuel_Cells_Module/General_Electrochemistry/microdisk_voltammetry Corrosion_Module/General_Electrochemistry/microdisk_voltammetry Electrochemistry_Module/Electroanalysis/microdisk_voltammetry Electrodeposition_Module/Tutorials/microdisk_voltammetry
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