X-Git-Url: http://git.salome-platform.org/gitweb/?a=blobdiff_plain;f=doc%2Fsalome%2Fgui%2FSMESH%2Finput%2Fconstructing_meshes.doc;h=dcb55a785c548afb2e2a8741deed54b8cca7849c;hb=3216bba91f0f6820a77147ac84a35ebab6cf3e5b;hp=126dcfbd905327f434bf7a67510cfbad5307c210;hpb=88068fce89e10cb32b60ea51cae3440240d42e9f;p=modules%2Fsmesh.git
diff --git a/doc/salome/gui/SMESH/input/constructing_meshes.doc b/doc/salome/gui/SMESH/input/constructing_meshes.doc
index 126dcfbd9..dcb55a785 100644
--- a/doc/salome/gui/SMESH/input/constructing_meshes.doc
+++ b/doc/salome/gui/SMESH/input/constructing_meshes.doc
@@ -33,14 +33,15 @@ written in Python.
Apply \subpage basic_meshing_algos_page "meshing algorithms" and
- \subpage about_hypo_page "hypotheses" which will be used at computation of
+ \subpage about_hypo_page "hypotheses" which will be used to compute
this mesh.
"Create mesh" dialog box contains several tab pages titled \b 3D,
\b 2D, \b 1D and \b 0D. The title of each page reflects the
dimension of the CAD model (geometry) the algorithms listed on
- this page affect. For example, \b 3D page lists the algorithms
- that affect 3D geometrical objects (solids).
+ this page affect and the maximal dimension of elements the algorithms
+ generate. For example, \b 3D page lists the algorithms that affect
+ 3D geometrical objects (solids).
\note
- Some page(s) can be disabled if the source geometrical
@@ -86,9 +87,24 @@ written in Python.
"Edit Hypothesis" button
- Most standard 2D and 3D algorithms can work without hypotheses
- using some default parameters. The use of additional hypotheses
- is optional (i.e. you may leave "None" in this box).
+ Most 2D and 3D algorithms can work without hypotheses using some
+ default meshing parameters. Some algorithms does not require any
+ hypothesis. After selection of an algorithm "Hypothesis" field of
+ the dialog can contain:
+
+ - if the algorithm can work using default
+ parameters.
+ - if the algorithm requires a hypothesis defining
+ its parameters.
+ - Nothing if the algorithm has no parameters to tune.
+
+ After selection of an algorithm "Add. Hypothesis" field of
+ the dialog can contain:
+
+ - if the algorithm can be additionally tuned
+ using an additional hypothesis.
+ - Nothing if the algorithm has no additional parameters to tune.
+
Proceed in the same way with 2D and 1D Algorithms and Hypotheses that
will be used to mesh faces and edges of your geometry. (Note
@@ -251,7 +267,7 @@ And the last mesh computation is made with:
"Result mesh with order SubMesh_3, SubMesh_2, SubMesh_1 "
As we can see, each mesh computation has a different number of result
-elements and a different mesh discretisation on the shared edges (the edges
+elements and a different mesh discretization on the shared edges (the edges
that are shared between Face_1, Face_2 and Face_3)
Additionally, submesh priority (the order of applied algorithms) can
@@ -314,8 +330,8 @@ or/and hidden by other mesh elements. They can be seen after
switching the mesh to Wireframe visualization mode or switching off
the visualization of faces and volumes (if any).
-Bad Mesh to Group button creates groups of the bad mesh entities,
-thus allowing you for more comfortable analysis of these entities.
+Bad Mesh to Group button creates groups of bad mesh entities
+to facilitate their analysis.
\image html show_bad_mesh.png
Edges bounding a hole in the surface are shown in magenta using Show
@@ -341,8 +357,8 @@ this, there exist two algorithms: Use existing edges and Use
For example, you want to use standard algorithms to generate 1D and 3D
meshes and to create 2D mesh by your python code. Then you
- - create a mesh object, assign an 1D algorithm,
- - invoke \b Compute command, which computes an 1D mesh,
+ - create a mesh object, assign a 1D algorithm,
+ - invoke \b Compute command, which computes a 1D mesh,
- assign Use existing faces and a 3D algorithm,
- run your python code, which creates a 2D mesh,
- invoke \b Compute command, which computes a 3D mesh.