def run_fem2(bdf_model,
out_model,
xref,
punch,
sum_load,
size,
precision,
reject,
debug=False,
log=None):
assert os.path.exists(bdf_model), bdf_model
assert os.path.exists(out_model), out_model
fem2 = BDF(debug=debug, log=log)
fem2.log.info('starting fem2')
sys.stdout.flush()
try:
fem2.read_bdf(out_model, xref=xref, punch=punch)
except:
print("failed reading %r" % out_model)
raise
#fem2.sumForces()
#fem2.sumMoments()
out_model2 = bdf_model + '_out2'
fem2.write_bdf(out_model2, interspersed=True)
#fem2.writeAsCTRIA3(out_model_2)
os.remove(out_model2)
return fem2
def run_fem2(bdf_model, out_model, xref, punch, sum_load, size, is_double, reject, debug=False, log=None):
"""
Reads/writes the BDF to verify nothing has been lost
Parameters
----------
bdf_model : str
the filename to run
xref : bool
xrefs
punch : bool
punches
"""
assert os.path.exists(bdf_model), bdf_model
assert os.path.exists(out_model), out_model
fem2 = BDF(debug=debug, log=log)
fem2.log.info("starting fem2")
sys.stdout.flush()
try:
fem2.read_bdf(out_model, xref=xref, punch=punch)
except:
print("failed reading %r" % out_model)
raise
# fem2.sumForces()
# fem2.sumMoments()
out_model2 = bdf_model + "_out2"
fem2.write_bdf(out_model2, interspersed=True)
# fem2.writeAsCTRIA3(out_model_2)
os.remove(out_model2)
return fem2
def run_fem2(bdf_model, out_model, xref, punch,
sum_load, size, precision,
reject, debug=False, log=None):
assert os.path.exists(bdf_model), bdf_model
assert os.path.exists(out_model), out_model
fem2 = BDF(debug=debug, log=log)
fem2.log.info('starting fem2')
sys.stdout.flush()
try:
fem2.read_bdf(out_model, xref=xref, punch=punch)
except:
print("failed reading %r" % out_model)
raise
#fem2.sumForces()
#fem2.sumMoments()
out_model2 = bdf_model + '_out2'
fem2.write_bdf(out_model2, interspersed=True)
#fem2.writeAsCTRIA3(out_model_2)
os.remove(out_model2)
return fem2
def run_fem2(bdf_model,
out_model,
xref,
punch,
sum_load,
size,
is_double,
reject,
debug=False,
log=None):
"""
Reads/writes the BDF to verify nothing has been lost
Parameters
----------
bdf_model : str
the filename to run
xref : bool
xrefs
punch : bool
punches
"""
assert os.path.exists(bdf_model), bdf_model
assert os.path.exists(out_model), out_model
fem2 = BDF(debug=debug, log=log)
fem2.log.info('starting fem2')
sys.stdout.flush()
try:
fem2.read_bdf(out_model, xref=xref, punch=punch)
except:
print("failed reading %r" % out_model)
raise
#fem2.sumForces()
#fem2.sumMoments()
out_model2 = bdf_model + '_out2'
fem2.write_bdf(out_model2, interspersed=True)
#fem2.writeAsCTRIA3(out_model_2)
os.remove(out_model2)
return fem2
def bdf_renumber(bdf_filename, bdf_filename_out, size=8, is_double=False,
starting_id_dict=None, round_ids=False, cards_to_skip=None):
"""
Renumbers a BDF
Parameters
----------
bdf_filename : str
a bdf_filename (string; supported) or a BDF model (BDF)
that has been cross referenced and is fully valid (a equivalenced deck is not valid)
bdf_filename_out : str
a bdf_filename to write
size : int; {8, 16}; default=8
the bdf write precision
is_double : bool; default=False
the field precision to write
starting_id_dict : dict, None (default=None)
None : renumber everything starting from 1
dict : {key : starting_id}
key : str
the key (e.g. eid, nid, cid, ...)
starting_id : int, None
int : the value to start from
None : don't renumber this key
round_ids : bool; default=False
Should a rounding up be applied for each variable?
This makes it easier to read a deck and verify that it's been renumbered properly.
This only really applies when starting_id_dict is None
cards_to_skip : List[str]; (default=None -> don't skip any cards)
There are edge cases (e.g. FLUTTER analysis) where things can break due to
uncross-referenced cards. You need to disable entire classes of cards in
that case (e.g. all aero cards).
.. todo:: bdf_model option for bdf_filename hasn't been tested
.. todo:: add support for subsets (e.g. renumber only a subset of nodes/elements)
.. todo:: doesn't support partial renumbering
.. todo:: doesn't support element material coordinate systems
..warning :: spoints might be problematic...check
..warning :: still in development, but it usually brutally crashes if it's not supported
..warning :: be careful of card unsupported cards (e.g. ones not read in)
Supports
========
- GRIDs
- no superelements
- COORDx
- elements
- CELASx/CONROD/CBAR/CBEAM/CQUAD4/CTRIA3/CTETRA/CPENTA/CHEXA
- RBAR/RBAR1/RBE1/RBE2/RBE3/RSPLINE
- properties
- PSHELL/PCOMP/PCOMPG/PSOLID/PSHEAR/PBAR/PBARL
PROD/PTUBE/PBEAM
- mass
- CMASSx/CONMx/PMASS
- aero
- FLFACT
- SPLINEx
- FLUTTER
- partial case control
- METHOD/CMETHOD/FREQENCY
- LOAD/DLOAD/LSEQ/LOADSET...LOADSET/LSEQ is iffy
- SET cards
- nodes
- elements
- SPC/MPC/FLUTTER/FLFACT
- constraints
- SPC/SPCADD/SPCAX/SPCD
- MPC/MPCADD
- SUPORT/SUPORT1
- solution control/methods
- TSTEP/TSTEPNL
- NLPARM
- EIGB/EIGC/EIGRL/EIGR
- sets
- USET
- other
- tables
- materials
- loads/dloads
Not Done
========
- SPOINT
- any cards with SPOINTs
- DMIG/DMI/DMIJ/DMIJI/DMIK/etc.
- CELASx
- CDAMPx
- superelements
- aero cards
- CAEROx
- PAEROx
- thermal cards?
- optimization cards
- SETx
- PARAM,GRDPNT,x; where x>0
- GRID SEID
- case control
- STATSUB
- SUBCASE
- global SET cards won't be renumbered properly
Example 1 - Renumber Everything; Start from 1
---------------------------------------------
bdf_renumber(bdf_filename, bdf_filename_out, size=8, is_double=False,
round_ids=False)
Example 2 - Renumber Everything; Start Material IDs from 100
------------------------------------------------------------
starting_id_dict = {
'mid' : 100,
}
bdf_renumber(bdf_filename, bdf_filename_out, size=8, is_double=False,
starting_ids_dict=starting_ids_dict, round_ids=False)
Example 3 - Only Renumber Material IDs
--------------------------------------
starting_id_dict = {
'cid' : None,
'nid' : None,
'eid' : None,
'pid' : None,
'mid' : 1,
'spc_id' : None,
'mpc_id' : None,
'load_id' : None,
'dload_id' : None,
'method_id' : None,
'cmethod_id' : None,
'spline_id' : None,
'table_id' : None,
'flfact_id' : None,
'flutter_id' : None,
'freq_id' : None,
'tstep_id' : None,
'tstepnl_id' : None,
'suport_id' : None,
'suport1_id' : None,
'tf_id' : None,
}
bdf_renumber(bdf_filename, bdf_filename_out, size=8, is_double=False,
starting_ids_dict=starting_ids_dict, round_ids=False)
"""
starting_id_dict_default = {
'cid' : 1,
'nid' : 1,
'eid' : 1,
'pid' : 1,
'mid' : 1,
'spc_id' : 1,
'mpc_id' : 1,
'load_id' : 1,
'dload_id' : 1,
'method_id' : 1,
'cmethod_id' : 1,
'spline_id' : 1,
'table_id' : 1,
'flfact_id' : 1,
'flutter_id' : 1,
'freq_id' : 1,
'tstep_id' : 1,
'tstepnl_id' : 1,
'suport_id' : 1,
'suport1_id' : 1,
'tf_id' : 1,
}
# fill up starting_id_dict
if starting_id_dict is None:
starting_id_dict = starting_id_dict_default
else:
for key, value in iteritems(starting_id_dict_default):
if key not in starting_id_dict:
starting_id_dict[key] = value
nid = None
cid = None
eid = None
pid = None
mid = None
spc_id = None
mpc_id = None
load_id = None
dload_id = None
method_id = None
cmethod_id = None
spline_id = None
table_id = None
flfact_id = None
flutter_id = None
freq_id = None
tstep_id = None
tstepnl_id = None
suport_id = None
suport1_id = None
tf_id = None
# turn them into variables
for key, value in sorted(iteritems(starting_id_dict)):
#assert isinstance(key, string_types), key
assert key in starting_id_dict_default, 'key=%r is invalid' % (key)
if value is None:
pass
else:
if not isinstance(value, integer_types):
msg = 'key=%r value=%r must be an integer; type(value)=%s' % (
key, value, type(value))
raise TypeError(msg)
if key == 'nid':
nid = int(value)
elif key == 'cid':
if value is None:
cid = None
else:
cid = int(value)
elif key == 'eid':
eid = int(value)
elif key == 'pid':
if value is None:
pid = None
else:
pid = int(value)
elif key == 'mid':
if value is None:
mid = None
else:
mid = int(value)
elif key == 'spc_id':
spc_id = int(value)
elif key == 'mpc_id':
mpc_id = int(value)
elif key == 'load_id':
load_id = int(value)
elif key == 'dload_id':
dload_id = int(value)
elif key == 'method_id':
method_id = int(value)
elif key == 'cmethod_id':
cmethod_id = int(value)
elif key == 'spline_id':
spline_id = int(value)
elif key == 'table_id':
table_id = int(value)
elif key == 'flfact_id':
flfact_id = int(value)
elif key == 'flutter_id':
flutter_id = int(value)
elif key == 'freq_id':
freq_id = int(value)
elif key == 'tstep_id':
tstep_id = int(value)
elif key == 'tstepnl_id':
tstepnl_id = int(value)
elif key == 'suport_id':
suport_id = int(value)
elif key == 'suport1_id':
suport1_id = int(value)
elif key == 'tf_id':
tf_id = int(value)
else:
raise NotImplementedError('key=%r' % key)
# build the maps
#eid_map = {}
#nid_map = {}
#reverse_nid_map = {}
#pid_map = {}
#mid_map = {}
#mpc_map = {}
#spc_map = {}
dload_map = {}
load_map = {}
cmethod_map = {}
method_map = {}
#flfact_map = {}
#flutter_map = {}
#aefact_map = {}
#freq_map = {}
tstep_map = {}
tstepnl_map = {}
suport_map = {}
suport1_map = {}
if isinstance(bdf_filename, string_types):
model = BDF(debug=False)
model.disable_cards(cards_to_skip)
model.read_bdf(bdf_filename)
else:
model = bdf_filename
elements = [
model.celas1,
model.celas2,
model.celas3,
model.celas4,
#model.cdamp1,
#model.cdamp2,
#model.cdamp3,
#model.cdamp4,
model.conrod,
model.crod,
model.ctube,
model.cbar,
model.cbeam,
model.cshear,
model.cquad4,
model.ctria3,
model.cquad8,
model.ctria6,
#model.ctriax,
model.ctriax6,
model.ctetra4, model.ctetra10,
model.cpenta6, model.cpenta15,
#model.cpyram5, model.cpyram13,
model.chexa8, model.chexa20,
]
props = [
model.pelas,
#model.pdamp,
model.ptube,
model.ptube,
model.pbar,
model.pbarl,
model.pbeam,
model.pbeaml,
model.pshear,
model.pshell,
model.pcomp,
#model.pcompg,
model.psolid,
model.plsolid,
]
materials = [
model.mat1,
#model.mat2,
#model.mat3,
#model.mat4,
#model.mat5,
model.mat8,
#model.mat9,
#model.mat10,
#model.mat11,
]
loads = [
model.force,
model.force1,
model.force2,
model.moment,
model.moment1,
model.moment2,
model.pload,
model.pload1,
model.pload2,
model.pload4,
#model.rforce,
#model.dload,
#model.load,
#model.sload,
]
nid_map = {}
#reverse_nid_map = {}
if 'nid' in starting_id_dict and nid is not None:
#i = nid
#nid_map = {}
ngrids = model.grid.n
if ngrids:
nids = model.grid.node_id - 1
nid_map.update(
{(nid + nids[i]) : (i+1) for i in range(ngrids)})
#reverse_nid_map.update(
#{(i+1) : (nid + nids[i]) for i in range(ngrids)}) # index to nid
#print(min(nid_map))
# TODO: SPOINTs
# TODO: EPOINTs
#if model.spoints.points:
cid_map = {}
if 'cid' in starting_id_dict and cid is not None:
cids = model.coords.coords.keys()
#print(cids)
ncoords = len(cids)
cids.sort()
#print('cids =', cids)
cid_map.update(
{(cid + cids[i] - 1) : (i) for i in range(ncoords)})
#print('cid_map =', cid_map)
eid_map = {}
if 'eid' in starting_id_dict and pid is not None:
eids = [element.element_id for element in elements if element.n]
eids.append(model.rigid_elements.keys())
eids = np.hstack(eids)
neids = len(eids)
eids.sort()
eid_map.update(
{eids[i] : (i + eid) for i in range(neids)})
pid_map = {}
if 'pid' in starting_id_dict and pid is not None:
pids = np.hstack([prop.property_id for prop in props if prop.n])
npids = len(pids)
pids.sort()
pid_map.update(
{pids[i] : (i + pid) for i in range(npids)})
mid_map = {}
if 'mid' in starting_id_dict and mid is not None:
mids = np.hstack([mat.material_id for mat in materials])
nmids = len(mids)
mids.sort()
mid_map.update(
{mids[i] : (mid + i) for i in range(nmids)})
load_map = {}
if 'load_id' in starting_id_dict and load_id is not None:
loadsi = [load.load_id for load in loads if load.n]
if loadsi:
#print(loadsi)
load_ids = np.unique(np.hstack(loadsi))
del loadsi
nload_ids = len(load_ids)
load_ids.sort()
load_map.update(
{load_ids[i] : (load_id + i) for i in range(nload_ids)})
spc_map = {}
if 'spc_id' in starting_id_dict and spc_map is not None:
spcs = [model.spc, model.spc1, model.spcadd]
spcsi = []
for spc_obj in spcs:
#print(spc_obj)
#spc_ids = [spc.spc_id for spc_id, spc in iteritems(spc_obj) if spc.n]
spc_ids = spc_obj.keys()
if spc_ids:
spcsi.append(spc_ids)
#spcsi = [spc_id for spc_id in spcs]
#print('spcsi =', spcsi)
#asdf
if spcsi:
#print(loadsi)
spc_ids = np.unique(np.hstack(spcsi))
#del spcsi
nspc_ids = len(spc_ids)
spc_ids.sort()
spc_map.update(
{spc_ids[i] : (spc_id + i) for i in range(nspc_ids)})
#print('spc_ids =', spc_ids)
caero_map = {}
#if model.caeros:
#caeros = model.caeros.keys()
#caeros.sort()
#ncaeros = len(caeros)
#caero_map = {caeros[i] : (i+1) for i in range(ncaeros)}
paero_map = {}
if model.paeros:
paeros = model.paeros.keys()
paeros.sort()
npaeros = len(paeros)
paero_map = {paeros[i] : (i+1) for i in range(npaeros)}
aefact_map = {}
if model.aefacts:
aefacts = model.aefacts.keys()
aefacts.sort()
naefacts = len(aefacts)
aefact_map = {aefacts[i] : (i+1) for i in range(naefacts)}
spline_map = {}
#if model.splines:
#splines = model.splines.keys()
#splines.sort()
#nsplines = len(splines)
#spline_map = {splines[i] : (i+1) for i in range(nsplines)}
set_map = {}
if model.sets:
sets = model.sets.keys()
sets.sort()
nsets = len(sets)
set_map = {sets[i] : (i+1) for i in range(nsets)}
#load_map = {}
maps = {
'node' : nid_map,
'coord' : cid_map,
'property' : pid_map,
'element' : eid_map,
'load' : load_map,
'material' : mid_map,
'caero' : caero_map, # ???
'paero' : paero_map, # PAEROx
'aefact' : aefact_map, # ???
'spline' : spline_map, # SPLINE1-SPLINE5
'set' : set_map,
}
model.grid.update(maps)
model.coords.update(maps)
for elem in elements:
elem.update(maps)
rigid_elements2 = {}
for eid, elem in iteritems(model.rigid_elements):
eid2 = eid_map[eid]
rigid_elements2[eid2] = eid_map[eid]
elem.update(maps)
for prop in props:
prop.update(maps)
for mat in materials:
mat.update(maps)
for spc_dict in spcs:
for spc_id, spc in iteritems(spc_dict):
spc.update(maps)
if model.aero is not None:
model.aero.update(maps)
if model.aeros is not None:
model.aeros.update(maps)
for caero in itervalues(model.caeros):
caero.update(maps)
for spline in itervalues(model.splines):
spline.update(model, maps)
for flutter in itervalues(model.flutters):
flutter.update(maps)
for flfact in itervalues(model.flfacts):
flfact.update(maps)
for flutter in itervalues(model.flutters):
flutter.update(maps)
for desvar in itervalues(model.desvars):
desvar.update(maps)
for dconstr in itervalues(model.dconstrs):
dconstr.update(maps)
for dresp in itervalues(model.dresps):
dresp.update(maps)
for dconadd in itervalues(model.dconadds):
dconadd.update(maps)
for dvgrid in itervalues(model.dvgrids):
dvgrid.update(maps)
for dvcrel in itervalues(model.dvcrels):
dvcrel.update(maps)
for dvmrel in itervalues(model.dvmrels):
dvmrel.update(maps)
for dvprel in itervalues(model.dvprels):
dvprel.update(maps)
model.darea.update(maps)
model.dphase.update(maps)
if bdf_filename_out is not None:
model.write_bdf(bdf_filename_out, size=size, is_double=is_double,
interspersed=False)
return model
def get_mass(self, nid1, nid2, xyz1, xyz2, eid, pid, mid, A, J, c, nsm, E,
G, nu, rho, L):
"""tests a CROD and a CONROD"""
card_count = {
'CONROD': 1,
'CTUBE': 1,
'PTUBE': 1,
'CROD': 1,
'PROD': 1,
'GRID': 2,
'MAT1': 1,
}
model = BDF(debug=debug)
model.allocate(card_count)
lines = [
'conrod,%i, %i, %i, %i, %f, %f, %f, %f' %
(eid, nid1, nid2, mid, A, J, c, nsm)
]
model.add_card(lines, 'conrod', is_list=False)
lines = ['crod,%i, %i, %i, %i' % (eid + 1, pid, nid1, nid2)]
model.add_card(lines, 'crod', is_list=False)
lines = ['ctube,%i, %i, %i, %i' % (eid + 2, pid + 1, nid1, nid2)]
model.add_card(lines, 'ctube', is_list=False)
lines = ['prod,%i, %i, %f, %f, %f, %f' % (pid, mid, A, J, c, nsm)]
model.add_card(lines, 'prod', is_list=False)
OD1 = sqrt(4 * A / pi)
t = 0.
OD2 = OD1
lines = [
'ptube,%i, %i, %f, %f, %f, %f' % (pid + 1, mid, OD1, t, nsm, OD2)
]
model.add_card(lines, 'ptube', is_list=False)
lines = ['mat1,%i, %.2e, %.2e, %f, %f' % (mid, E, G, nu, rho)]
model.add_card(lines, 'mat1', is_list=False)
lines = [
'grid,%i, %i, %f, %f, %f' % (nid1, 0, xyz1[0], xyz1[1], xyz1[2])
]
model.add_card(lines, 'grid', is_list=False)
lines = [
'grid,%i, %i, %f, %f, %f' % (nid2, 0, xyz2[0], xyz2[1], xyz2[2])
]
model.add_card(lines, 'grid', is_list=False)
model.build()
mass = L * (rho * A + nsm)
f = StringIO()
model.write_bdf(out_filename=f,
interspersed=True,
size=8,
precision='single',
enddata=None)
print(f.getvalue())
#positions = model.get_positions()
grid_cid0 = None
# conrod
conrod = model.conrod.slice_by_element_id(eid)
self.assertEquals(conrod.get_element_id_by_element_index(), eid)
#self.assertEquals(conrod.get_property_id_by_element_id(), None)
self.assertEquals(conrod.get_material_id_by_element_id(eid), mid)
self.assertEquals(
conrod.get_length_by_element_index(i=None, grid_cid0=grid_cid0), L)
#self.assertEquals(conrod.Nsm(), nsm)
rhoi = conrod.get_density_by_element_id(eid)
Ai = conrod.get_area_by_element_id(eid)
Li = conrod.get_length_by_element_id(eid, grid_cid0=grid_cid0)
nsmi = conrod.get_non_structural_mass_by_element_id(eid)
massa = conrod.get_mass_by_element_index()
mass_msg_conrod = 'mass = L * (rho * A + nsm)\n'
mass_msg_conrod += 'L=%s expected=%s\n' % (Li, L)
mass_msg_conrod += 'rho=%s expected=%s\n' % (rhoi, rho)
mass_msg_conrod += 'A=%s expected=%s\n' % (Ai, A)
mass_msg_conrod += 'nsm=%s expected=%s\n' % (nsmi, nsm)
mass_msg_conrod += 'mass=%s actual=%s expected=%s\n' % (
Li * (rhoi * Ai + nsmi), massa, mass)
#mass_msg_conrod += 'mass=%s expected=%s\n' % (Li * (rhoi*Ai + nsmi), mass)
self.assertEquals(massa, mass, mass_msg_conrod)
#self.assertEquals(conrod.E(), E)
#self.assertEquals(conrod.G(), G)
#self.assertEquals(conrod.area(), A)
#self.assertEquals(conrod.J(), J)
#self.assertEquals(conrod.C(), c)
#self.assertEquals(conrod.Rho(), rho)
# crod
crod_eid = eid + 1
crod = model.crod.slice_by_element_id([crod_eid])
self.assertEquals(crod.get_element_id_by_element_index(), crod_eid)
self.assertEquals(crod.get_property_id_by_element_id(crod_eid), pid)
self.assertEquals(crod.get_material_id_by_element_id(crod_eid), mid)
rhoi = crod.get_density_by_element_id(crod_eid)
Ai = crod.get_area_by_element_id(crod_eid)
Li = crod.get_length_by_element_id(crod_eid, grid_cid0=grid_cid0)
nsmi = crod.get_non_structural_mass_by_element_id(crod_eid)
self.assertEquals(Li, L)
#self.assertEquals(crod.Nsm(), nsm)
massa = crod.get_mass_by_element_id(crod_eid)
mass_msg_crod = 'mass = L * (rho * A + nsm)\n'
mass_msg_crod += 'L=%s expected=%s\n' % (Li, L)
mass_msg_crod += 'rho=%s expected=%s\n' % (rhoi, rho)
mass_msg_crod += 'A=%s expected=%s\n' % (Ai, A)
mass_msg_crod += 'nsm=%s expected=%s\n' % (nsmi, nsm)
mass_msg_crod += 'mass=%s actual=%s expected=%s\n' % (
Li * (rhoi * Ai + nsmi), massa, mass)
self.assertEquals(massa, mass, mass_msg_crod)
#self.assertEquals(crod.E(), E)
#self.assertEquals(crod.G(), G)
#self.assertEquals(crod.area(), A)
#self.assertEquals(crod.J(), J)
#self.assertEquals(crod.C(), c)
#self.assertEquals(crod.Rho(), rho)
#self.assertEquals(crod.Nu(), nu)
# prod
prod = model.prod.slice_by_property_id([pid])
self.assertEquals(prod.property_id[0], pid)
self.assertEquals(prod.get_material_id_by_property_id(pid), mid)
self.assertEquals(prod.get_non_structural_mass_by_property_id(pid),
nsm)
self.assertEquals(prod.get_E_by_property_id(pid), E)
self.assertEquals(prod.get_G_by_property_id(pid), G)
self.assertEquals(prod.get_area_by_property_id(pid), A)
self.assertEquals(prod.get_J_by_property_id(pid), J)
self.assertEquals(prod.get_c_by_property_id(pid), c)
self.assertEquals(prod.get_density_by_property_id(pid), rho)
# ctube
if 1:
ctube_eid = eid + 2
ptube_pid = pid + 1
assert ctube_eid == 12, ctube_eid
assert ptube_pid == 68, ptube_pid
ctube = model.ctube.slice_by_element_id(ctube_eid)
self.assertEquals(ctube.get_element_id_by_element_index(),
ctube_eid)
self.assertEquals(ctube.get_property_id_by_element_id(ctube_eid),
ptube_pid)
self.assertEquals(ctube.get_material_id_by_element_id(ctube_eid),
mid)
self.assertEquals(
ctube.get_length_by_element_id(ctube_eid, grid_cid0), L)
self.assertEquals(
ctube.get_non_structural_mass_by_element_id(ctube_eid), nsm)
self.assertAlmostEquals(ctube.get_mass_by_element_id(ctube_eid),
mass, 5)
self.assertEquals(ctube.get_E_by_element_id(ctube_eid), E)
self.assertEquals(ctube.get_G_by_element_id(ctube_eid), G)
self.assertAlmostEquals(ctube.get_area_by_element_id(ctube_eid), A,
5)
ctube.get_J_by_element_id(ctube_eid)
self.assertEquals(ctube.get_density_by_element_id(), rho)
# ptube
ptube = model.ptube.slice_by_property_id(pid + 1)
self.assertEquals(ptube.get_property_id_by_property_index(),
pid + 1)
self.assertEquals(ptube.get_material_id_by_property_id(), mid)
self.assertEquals(ptube.get_non_structural_mass_by_property_id(),
nsm)
self.assertEquals(ptube.get_E_by_property_id(), E)
self.assertEquals(ptube.get_G_by_property_id(), G)
self.assertAlmostEquals(ptube.get_area_by_property_id(), A, 5)
ptube.get_J_by_property_id()
self.assertEquals(ptube.get_density_by_property_id(), rho)
def get_mass(self, nid1, nid2, xyz1, xyz2, eid, pid, mid, A, J, c, nsm, E, G, nu, rho, L):
"""tests a CROD and a CONROD"""
card_count = {"CONROD": 1, "CTUBE": 1, "PTUBE": 1, "CROD": 1, "PROD": 1, "GRID": 2, "MAT1": 1}
model = BDF(debug=debug)
model.allocate(card_count)
lines = ["conrod,%i, %i, %i, %i, %f, %f, %f, %f" % (eid, nid1, nid2, mid, A, J, c, nsm)]
model.add_card(lines, "conrod", is_list=False)
lines = ["crod,%i, %i, %i, %i" % (eid + 1, pid, nid1, nid2)]
model.add_card(lines, "crod", is_list=False)
lines = ["ctube,%i, %i, %i, %i" % (eid + 2, pid + 1, nid1, nid2)]
model.add_card(lines, "ctube", is_list=False)
lines = ["prod,%i, %i, %f, %f, %f, %f" % (pid, mid, A, J, c, nsm)]
model.add_card(lines, "prod", is_list=False)
OD1 = sqrt(4 * A / pi)
t = 0.0
OD2 = OD1
lines = ["ptube,%i, %i, %f, %f, %f, %f" % (pid + 1, mid, OD1, t, nsm, OD2)]
model.add_card(lines, "ptube", is_list=False)
lines = ["mat1,%i, %.2e, %.2e, %f, %f" % (mid, E, G, nu, rho)]
model.add_card(lines, "mat1", is_list=False)
lines = ["grid,%i, %i, %f, %f, %f" % (nid1, 0, xyz1[0], xyz1[1], xyz1[2])]
model.add_card(lines, "grid", is_list=False)
lines = ["grid,%i, %i, %f, %f, %f" % (nid2, 0, xyz2[0], xyz2[1], xyz2[2])]
model.add_card(lines, "grid", is_list=False)
model.build()
mass = L * (rho * A + nsm)
f = StringIO()
model.write_bdf(out_filename=f, interspersed=True, size=8, precision="single", enddata=None)
print(f.getvalue())
# positions = model.get_positions()
grid_cid0 = None
# conrod
conrod = model.conrod.slice_by_element_id(eid)
self.assertEquals(conrod.get_element_id_by_element_index(), eid)
# self.assertEquals(conrod.get_property_id_by_element_id(), None)
self.assertEquals(conrod.get_material_id_by_element_id(eid), mid)
self.assertEquals(conrod.get_length_by_element_index(i=None, grid_cid0=grid_cid0), L)
# self.assertEquals(conrod.Nsm(), nsm)
rhoi = conrod.get_density_by_element_id(eid)
Ai = conrod.get_area_by_element_id(eid)
Li = conrod.get_length_by_element_id(eid, grid_cid0=grid_cid0)
nsmi = conrod.get_non_structural_mass_by_element_id(eid)
massa = conrod.get_mass_by_element_index()
mass_msg_conrod = "mass = L * (rho * A + nsm)\n"
mass_msg_conrod += "L=%s expected=%s\n" % (Li, L)
mass_msg_conrod += "rho=%s expected=%s\n" % (rhoi, rho)
mass_msg_conrod += "A=%s expected=%s\n" % (Ai, A)
mass_msg_conrod += "nsm=%s expected=%s\n" % (nsmi, nsm)
mass_msg_conrod += "mass=%s actual=%s expected=%s\n" % (Li * (rhoi * Ai + nsmi), massa, mass)
# mass_msg_conrod += 'mass=%s expected=%s\n' % (Li * (rhoi*Ai + nsmi), mass)
self.assertEquals(massa, mass, mass_msg_conrod)
# self.assertEquals(conrod.E(), E)
# self.assertEquals(conrod.G(), G)
# self.assertEquals(conrod.area(), A)
# self.assertEquals(conrod.J(), J)
# self.assertEquals(conrod.C(), c)
# self.assertEquals(conrod.Rho(), rho)
# crod
crod_eid = eid + 1
crod = model.crod.slice_by_element_id([crod_eid])
self.assertEquals(crod.get_element_id_by_element_index(), crod_eid)
self.assertEquals(crod.get_property_id_by_element_id(crod_eid), pid)
self.assertEquals(crod.get_material_id_by_element_id(crod_eid), mid)
rhoi = crod.get_density_by_element_id(crod_eid)
Ai = crod.get_area_by_element_id(crod_eid)
Li = crod.get_length_by_element_id(crod_eid, grid_cid0=grid_cid0)
nsmi = crod.get_non_structural_mass_by_element_id(crod_eid)
self.assertEquals(Li, L)
# self.assertEquals(crod.Nsm(), nsm)
massa = crod.get_mass_by_element_id(crod_eid)
mass_msg_crod = "mass = L * (rho * A + nsm)\n"
mass_msg_crod += "L=%s expected=%s\n" % (Li, L)
mass_msg_crod += "rho=%s expected=%s\n" % (rhoi, rho)
mass_msg_crod += "A=%s expected=%s\n" % (Ai, A)
mass_msg_crod += "nsm=%s expected=%s\n" % (nsmi, nsm)
mass_msg_crod += "mass=%s actual=%s expected=%s\n" % (Li * (rhoi * Ai + nsmi), massa, mass)
self.assertEquals(massa, mass, mass_msg_crod)
# self.assertEquals(crod.E(), E)
# self.assertEquals(crod.G(), G)
# self.assertEquals(crod.area(), A)
# self.assertEquals(crod.J(), J)
# self.assertEquals(crod.C(), c)
# self.assertEquals(crod.Rho(), rho)
# self.assertEquals(crod.Nu(), nu)
# prod
prod = model.prod.slice_by_property_id([pid])
self.assertEquals(prod.property_id[0], pid)
self.assertEquals(prod.get_material_id_by_property_id(pid), mid)
self.assertEquals(prod.get_non_structural_mass_by_property_id(pid), nsm)
self.assertEquals(prod.get_E_by_property_id(pid), E)
self.assertEquals(prod.get_G_by_property_id(pid), G)
self.assertEquals(prod.get_area_by_property_id(pid), A)
self.assertEquals(prod.get_J_by_property_id(pid), J)
self.assertEquals(prod.get_c_by_property_id(pid), c)
self.assertEquals(prod.get_density_by_property_id(pid), rho)
# ctube
if 1:
ctube_eid = eid + 2
ptube_pid = pid + 1
assert ctube_eid == 12, ctube_eid
assert ptube_pid == 68, ptube_pid
ctube = model.ctube.slice_by_element_id(ctube_eid)
self.assertEquals(ctube.get_element_id_by_element_index(), ctube_eid)
self.assertEquals(ctube.get_property_id_by_element_id(ctube_eid), ptube_pid)
self.assertEquals(ctube.get_material_id_by_element_id(ctube_eid), mid)
self.assertEquals(ctube.get_length_by_element_id(ctube_eid, grid_cid0), L)
self.assertEquals(ctube.get_non_structural_mass_by_element_id(ctube_eid), nsm)
self.assertAlmostEquals(ctube.get_mass_by_element_id(ctube_eid), mass, 5)
self.assertEquals(ctube.get_E_by_element_id(ctube_eid), E)
self.assertEquals(ctube.get_G_by_element_id(ctube_eid), G)
self.assertAlmostEquals(ctube.get_area_by_element_id(ctube_eid), A, 5)
ctube.get_J_by_element_id(ctube_eid)
self.assertEquals(ctube.get_density_by_element_id(), rho)
# ptube
ptube = model.ptube.slice_by_property_id(pid + 1)
self.assertEquals(ptube.get_property_id_by_property_index(), pid + 1)
self.assertEquals(ptube.get_material_id_by_property_id(), mid)
self.assertEquals(ptube.get_non_structural_mass_by_property_id(), nsm)
self.assertEquals(ptube.get_E_by_property_id(), E)
self.assertEquals(ptube.get_G_by_property_id(), G)
self.assertAlmostEquals(ptube.get_area_by_property_id(), A, 5)
ptube.get_J_by_property_id()
self.assertEquals(ptube.get_density_by_property_id(), rho)
