X-Git-Url: http://git.salome-platform.org/gitweb/?p=modules%2Fsmesh.git;a=blobdiff_plain;f=doc%2Fsalome%2Fexamples%2Fdefining_hypotheses_ex13.py;h=e952460016a7f4ef6d1eb14a414693ad1dd05d8d;hp=0bcdcf60a2bc2b777cf8576d8c4fdcf2f743b0fd;hb=646d8ac2aa54e6de74930bb3f2118c51e893b5b0;hpb=7a3ecab720cc517ace17c5c4677fd3c20c0051ee

diff --git a/doc/salome/examples/defining_hypotheses_ex13.py b/doc/salome/examples/defining_hypotheses_ex13.py
index 0bcdcf60a..e95246001 100644
--- a/doc/salome/examples/defining_hypotheses_ex13.py
+++ b/doc/salome/examples/defining_hypotheses_ex13.py
@@ -25,15 +25,18 @@ radial_Quad_algo = mesh.Quadrangle(algo=smeshBuilder.RADIAL_QUAD)
 
 # The Radial Quadrange algorithm can work without any hypothesis
 # In this case it uses "Default Nb of Segments" preferences parameter to discretize edges
+# So by default there will be 15 segments in both radial and circular directions
 mesh.Compute()
 
 # The Radial Quadrange uses global or local 1d hypotheses if it does
 # not have its own hypotheses.
 # Define global hypotheses to discretize radial edges and a local one for circular edge
+# So that there will be 5 radial layers and 10 circular segments
 global_Nb_Segments = mesh.Segment().NumberOfSegments(5)
 local_Nb_Segments  = mesh.Segment(circle).NumberOfSegments(10)
 mesh.Compute()
 
 # Define own parameters of Radial Quadrange algorithm
+# The number of radial layers will be 4
 radial_Quad_algo.NumberOfLayers( 4 )
 mesh.Compute()