def setup_inlets(domain, project):
    """
    Add inlets to domain
    """

    inlet_data = project.inlet_data

    for i in range(len(inlet_data)):
        name = inlet_data[i][0]
        line_file = inlet_data[i][1]
        timeseries_file = inlet_data[i][2]
        start_time = inlet_data[i][3]

        # Add inlet
        timeseries = numpy.genfromtxt(timeseries_file,
                                      delimiter=',',
                                      skip_header=1)

        # Adjust start time
        timeseries[:, 0] = timeseries[:, 0] - start_time

        # Make discharge function
        qfun = scipy.interpolate.interp1d(timeseries[:, 0],
                                          timeseries[:, 1],
                                          kind='linear')

        # Make cross-section line
        line = su.read_polygon(line_file)

        anuga.Inlet_operator(domain, line, qfun, label='Inlet: ' + str(name))
    return
center=(craterlength/2.0,craterwidth/2.0)
radius=(0.1)
region0 = anuga.Region(domain, center=center, radius=radius)
outletregion0=anuga.Region(domain, polygon=outletregion)
lakeregion0=anuga.Region(domain, polygon=lakeregion)
nextregion0=anuga.Region(domain, polygon=nextregion)
endregion0=anuga.Region(domain, polygon=endregion)


#operatezero = suspension_erosion_operator(domain, outletregion,grainD=grainD, gravity=anuga.g)    #NO SUSPENSION IN THESE EXPERIMENTS
operateone = bedloadtransport_operator(domain)
#operatetwo = friction_operator(domain)   #FRICTION IS CONSTANT
operatethree = AoR_operator(domain)  #no grainsize or gravity dependence for the angle of repose change
#operatefour = stagelimiter_operator(domain,polygon=endregion)   #probably a bad idea
#pumprate=1L/min = 0.001m^3/min = 1.667e-5 m3/s
fixed_inflow = anuga.Inlet_operator(domain, region0 , Q=50.0*0.00001667)
#Add water to domain in lake



count=0
ystep=1.0
ftime=80.0
for t in domain.evolve(yieldstep=ystep, finaltime=ftime):
    print domain.timestepping_statistics()
    volume = (domain.quantities['stage'].get_integral()-domain.quantities['elevation'].get_integral())
    volume2 = domain.quantities['stage'].get_integral(region=lakeregion0)-domain.quantities['elevation'].get_integral(region=lakeregion0)
    volume3 = domain.quantities['stage'].get_integral(region=nextregion0)-domain.quantities['elevation'].get_integral(region=nextregion0)
    volume4 = domain.quantities['stage'].get_integral(region=endregion0)-domain.quantities['elevation'].get_integral(region=endregion0)
    print str(t)+","+str(volume)+","+str(volume2)+","+str(volume3)+","+str(volume4)
    if t==21: fixed_inflow.set_Q(1.0*0.00001667)
Beispiel #3
0
    #Set quantities for domain, set dry bed
    domain.set_quantity('elevation', filename='11_fbe_c.pts')
    domain.set_quantity('friction', 0.040)
    domain.set_quantity('stage', expression='elevation')

    #Define and set boundaries
    Br = anuga.Reflective_boundary(domain)  # Solid reflective wall
    Bt = anuga.Transmissive_boundary(domain)  # Continue all values on boundary
    domain.set_boundary({'exterior': Bt})

    # Setup inlet flow
    center = (538416.0, 4190718.0)
    radius = 10.0

    region0 = anuga.Region(domain, center=center, radius=radius)
    fixed_inflow = anuga.Inlet_operator(domain, region0, Q=20)
else:
    domain = None

#------------------------------------------------------------------------------
# Now produce parallel domain
#------------------------------------------------------------------------------
domain = distribute(domain)

domain.set_store_vertices_uniquely(False)

for t in domain.evolve(yieldstep=500, finaltime=20000):
    if myid == 0:
        print domain.timestepping_statistics()

domain.sww_merge(delete_old=True)
Beispiel #4
0
#=====================================================
# Parallel Domain
#=====================================================
domain = distribute(domain)

#---------------------------------------------------------------------
# Define inlet operator
#---------------------------------------------------------------------
flow_in_yval = 5.0
line1 = [ [floodplain_width/2. - chan_width/2., flow_in_yval],\
          [floodplain_width/2. + chan_width/2., flow_in_yval] ]

Qin = 0.5*(floodplain_slope*(chan_width*chan_initial_depth)**2.*man_n**(-2.)\
            *chan_initial_depth**(4./3.) )**0.5
anuga.Inlet_operator(domain, line1, Qin)

if myid == 0 and verbose: print 'Discharge in = ', Qin

#---------------------------------------------------------------------
# Setup boundary conditions
#---------------------------------------------------------------------

Br = anuga.Reflective_boundary(domain)  # Solid reflective wall


def outflow_stage_boundary(t):
    return -floodplain_length*floodplain_slope \
            + chan_initial_depth - chan_bankfull_depth