create_figure_scheduler = fk.schedules(times=WHEN)
################################################################################
#
# Mesh:
#--------------------
# .. math::
#
# L = 25 m, l = 1 m
#
dir_path = os.path.abspath(os.path.dirname(sys.argv[0]))
triangular_mesh = fk.TriangularMesh.from_msh_file(dir_path +
'/inputs/bump.mesh')
if not args.nographics:
fk_plt.plot_mesh(triangular_mesh)
################################################################################
#
# 1D Steady state analytic solutions:
#------------------------------------
#
#1D steady state analytic solution is defined in a Bump class.
#Computation of the solution depends on intial state, boundary conditions
#and flow type.
#The topography is defined as a function of x:
#
X_B = 10.
output_scheduler = fk.schedules(count=NB_VTK)
output_scheduler_lag = fk.schedules(count=NB_VTK)
################################################################################
#
# Mesh:
#--------------------
dir_path = os.path.abspath(os.path.dirname(sys.argv[0]))
triangular_mesh = fk.TriangularMesh.from_msh_file(dir_path +
'/inputs/raceway.msh')
NC = triangular_mesh.NV
if WITH_PARTICLES: triangular_mesh.set_neighbours()
if not args.nographics:
fk_plt.plot_mesh(triangular_mesh, plot_labels=False)
################################################################################
#
# Layers:
#--------------------
layer = fk.Layer(NL, triangular_mesh, topography=ZB)
################################################################################
#
# Primitives:
#--------------------
primitives = fk.Primitive(triangular_mesh, layer, height=H0)
TG, vertex_labels, boundary_labels = fk.read_msh('inputs/bump{}.msh'.format(First_mesh))
triangular_mesh = fk.TriangularMesh(TG, vertex_labels, boundary_labels)
triangular_mesh_list.append(triangular_mesh)
os.system('rm inputs/bump{}.msh'.format(First_mesh))
else:
triangular_mesh = triangular_mesh.refine_by_splitting()
triangular_mesh_list.append(triangular_mesh)
else:
#Generates all meshes from bump#.geo files
os.system('gmsh -2 inputs/bump{}.geo -o inputs/bump{}.msh'.format(M, M))
TG, vertex_labels, boundary_labels = fk.read_msh('inputs/bump{}.msh'.format(M))
triangular_mesh_list.append(fk.TriangularMesh(TG, vertex_labels, boundary_labels))
os.system('rm inputs/bump{}.msh'.format(M))
NT.append(triangular_mesh_list[M].NT)
if PLOT_MESH: fk_plt.plot_mesh(triangular_mesh_list[M])
################################################################################
#
# Cases:
#--------------------
#
#Here we define cases based on a ``case`` class containing info such as space order
#or time order for each simulation we want to run.
class case():
def __init__(self, NL=1, mesh_id=0, time_order=False, space_order=False):
self.NL = NL
self.mesh_id = mesh_id
self.time_order = time_order
self.space_order = space_order
