def test_cord2r_02(self): grid = ['GRID 20143 7 -9.31-4 .11841 .028296'] coord = ['CORD2R 7 1.135 .089237 -.0676 .135 .089237 -.0676', ' 1.135 .089237 .9324'] model = BDF(debug=False) card_count = { 'GRID' : 1, 'CORD2R' : 1, } model.allocate(card_count) card = model.process_card(grid) model.add_card(card, card[0]) card = model.process_card(coord) model.add_card(card, card[0]) model.cross_reference() g = model.Node(20143) #xyz = g.Position() xyz = model.coords.get_global_position_by_node_id(20143, g.cp[0])[0] # by running it through Patran... #GRID 20143 1.1067 .207647 -.068531 expected = array([1.106704, .207647, -0.068531]) diff = xyz - expected msg = '\nexpected=%s \nactual =%s \ndiff =%s' % (expected, xyz, diff) assert allclose(diff, 0.), msg coord = model.Coord(7) coord.T() self.assertTrue(array_equal(coord.T(), coord.beta_n(2)))
def test_grid_01(self): nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = {'GRID': 1,} model = BDF() model.allocate(card_count) data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) nodes = model.grid nodes.add(data1) #print n1 f = StringIO() nodes.write_bdf(f, size=8, write_header=False) nodes.write_bdf(f, size=16, write_header=False) nodes.write_bdf(f, size=16, is_double=True, write_header=False) # small field f = StringIO() nodes.write_bdf(f, size=8, write_header=False) msg = f.getvalue() card = 'GRID 1 2 0. 0. 0.\n' self.assertCardEqual(msg, card) # large field f = StringIO() nodes.write_bdf(f, size=16, write_header=False) card = ('GRID* 1 2 0. 0.\n' '* 0.\n') msg = f.getvalue() self.assertCardEqual(msg, card)
def test_cord1_01(self): model = BDF(debug=False) card_count = { 'CCORD1R' : 1, 'GRID' : 3, } model.allocate(card_count) cards = [ ['CORD1R', 1, 1, 2, 3], # fails on self.k ['GRID', 1, 0, 0., 0., 0.], ['GRID', 2, 0, 1., 0., 0.], ['GRID', 3, 0, 1., 1., 0.], ] for card in cards: model.add_card(card, card[0], comment='comment', is_list=True) c1 = model.Coord(1) self.assertEquals(c1.G1(), 1) self.assertEquals(c1.G2(), 2) self.assertEquals(c1.G3(), 3) model.cross_reference() self.assertEquals(c1.G1(), 1) self.assertEquals(c1.G2(), 2) self.assertEquals(c1.G3(), 3) self.assertEquals(c1.NodeIDs(), [1, 2, 3])
def test_cord1c_01(self): lines = ['cord1c,2,1,4,3'] grids = [ ['GRID', 4, 0, 0.0, 0., 0.], ['GRID', 3, 0, 0.0, 0., 1.], ['GRID', 1, 0, 0.0, 1., 0.], ] card_count = { 'CORD1C': 1, 'GRID': 3, } model = BDF(debug=False) model.allocate(card_count) model.add_card(lines, 'CORD1C', is_list=False) for grid in grids: model.add_card(grid, grid[0], is_list=True) model.build() size = 8 bdf_file = StringIO() card = model.coords.slice_by_coord_id(2) self.assertEquals(card.get_cid_by_coord_id(), 2) self.assertEquals(card.get_rid_by_coord_id(), 0) card.write_card(bdf_file, size=8, is_double=False)
def test_solid_02(self): mid = 2 pid = 4 rho = 0.1 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes ['GRID', 21, 0, 0., 0., 0., 0,], ['GRID', 22, 0, 1., 0., 0., 0,], ['GRID', 23, 0, 1., 1., 0., 0,], ['GRID', 24, 0, 0., 0., 2., 0,], ['GRID', 25, 0, 1., 0., 2., 0,], ['GRID', 26, 0, 1., 1., 2., 0,], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # hyperelastic ['PLSOLID', pid, mid, 'GRID'], ['MATHP', mid, None, None, None, rho], ] card_count = { 'GRID' : 14, 'CTETRA4': 1, 'CPENTA6': 1, 'CHEXA8' : 1, 'PLSOLID': 1, 'MATHP': 1, } model = BDF(debug=True) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference() # CTETRA eid = 8 nsm = 0. V = 1. / 3. self.check_solid(model, eid, 'CTETRA4', pid, 'PLSOLID', mid, 'MATHP', nsm, rho, V) eid = 9 V = 1.0 self.check_solid(model, eid, 'CPENTA6', pid, 'PLSOLID', mid, 'MATHP', nsm, rho, V) eid = 7 V = 2.0 self.check_solid(model, eid, 'CHEXA8', pid, 'PLSOLID', mid, 'MATHP', nsm, rho, V)
def test_cord1c_01(self): lines = ['cord1c,2,1,4,3'] grids = [ ['GRID', 4, 0, 0.0, 0., 0.], ['GRID', 3, 0, 0.0, 0., 1.], ['GRID', 1, 0, 0.0, 1., 0.], ] card_count = { 'CORD1C' : 1, 'GRID' : 3, } model = BDF(debug=False) model.allocate(card_count) model.add_card(lines, 'CORD1C', is_list=False) for grid in grids: model.add_card(grid, grid[0], is_list=True) model.build() size = 8 bdf_file = StringIO() card = model.coords.slice_by_coord_id(2) self.assertEquals(card.get_cid_by_coord_id(), 2) self.assertEquals(card.get_rid_by_coord_id(), 0) card.write_card(bdf_file, size=8, is_double=False)
def test_grid_03(self): model = BDF() nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = { 'GRID': 2, } model = BDF() model.allocate(card_count) nodes = model.grid data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) data2 = BDFCard(['GRID', nid + 1, cp, 0., 0., 0., cd, ps, seid]) data3 = BDFCard(['GRID', nid + 2, cp, 0., 0., 0., cd, ps, seid]) nodes.add(data1) nodes.add(data2) nodes.resize(3, refcheck=False) #print('nodes.node_id = %s' % nodes.node_id) nodes.add(data3) f = StringIO() nodes.write_bdf(f, size=8, write_header=False)
def test_grid_01(self): nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = {'GRID': 1,} model = BDF(debug=False) model.allocate(card_count) data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) nodes = model.grid nodes.add(data1) #print(n1) f = StringIO() nodes.write_card(f, size=8, write_header=False) nodes.write_card(f, size=16, write_header=False) nodes.write_card(f, size=16, is_double=True, write_header=False) # small field f = StringIO() nodes.write_card(f, size=8, write_header=False) msg = f.getvalue() card = 'GRID 1 2 0. 0. 0.\n' self.assertCardEqual(msg, card) # large field f = StringIO() nodes.write_card(f, size=16, write_header=False) card = ('GRID* 1 2 0. 0.\n' '* 0.\n') msg = f.getvalue() self.assertCardEqual(msg, card)
def getNodes(self, grids, grids_expected, coords): model = BDF(debug=False) card_count = { 'GRID' : len(grids), 'CORD2R' : len(coords), } model.allocate(card_count) for grid in grids: (nid, cid, x, y, z) = grid model.add_card(['GRID', nid, cid, x, y, z], 'GRID') for coord in coords: (cid, rid, x, y, z) = coord model.add_card(['CORD2R', cid, rid] + x + y + z, 'CORD2R') #coordObj = model.Coord(cid) model.cross_reference() for (i, grid) in enumerate(grids_expected): (nid, cid, x, y, z) = grid nodes = model.grid pos = nodes.get_position_by_node_id([nid])[0] n = array([x, y, z]) msg = 'i=%s expected=%s actual=%s\n' % (i, n, pos) print(msg) assert allclose(n, pos), msg
def test_solid_03(self): """checks linear static solid material""" mid = 2 pid = 4 rho = 0.1 tableID = 42 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes ['GRID', 21, 0, 0., 0., 0., 0,], ['GRID', 22, 0, 1., 0., 0., 0,], ['GRID', 23, 0, 1., 1., 0., 0,], ['GRID', 24, 0, 0., 0., 2., 0,], ['GRID', 25, 0, 1., 0., 2., 0,], ['GRID', 26, 0, 1., 1., 2., 0,], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # static ['PSOLID', pid, mid, 0], ['MAT1', mid, 1.0, 2.0, 3.0, rho], ['MATS1', mid, tableID, 'PLASTIC', 0.0, 1, 1, 100000., ], #['TABLEST'], ['TABLES1', tableID, 1, None, None, None, None, None, None, 1.0, 10.0, 2.0, 10.0, 'ENDT'], ] card_count = { 'GRID' : 14, 'CPENTA6': 1, 'CTETRA4': 1, 'PSOLID': 1, 'CHEXA8' : 1, 'MAT1': 1, 'MATS1': 1, 'TABLES1': 1, } model = BDF(debug=False) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference() mat = model.materials[mid] print('----MAT----', type(mat)) print(mat) print('E = %s' % mat.get_E_by_material_index()) print('E = %s' % mat.get_E_by_material_id())
def test_cord2_rcs_03(self): """ all points are located at <30,40,50> """ model = BDF(debug=False) #card_count = { #'GRID' : 3, #'CORD2R' : 1, #'CORD2C' : 1, #'CORD2S' : 2, #} card_lines = [ [ 'CORD2S* 2 0 0. 0.', '* 0. 0. 0. 1.* ', '* 1. 0. 1.', ], [ #'$ Femap with NX Nastran Coordinate System 30 : rectangular in spherical', 'CORD2R* 30 2 14. 30.', '* 70. 13.431863852 32.1458443949 75.2107442927* ', '* 14.4583462334 33.4569982885 68.2297989286', ], [ #'$ Femap with NX Nastran Coordinate System 31 : cylindrical in spherical', 'CORD2C* 31 2 3. 42.', '* -173. 2.86526881213 45.5425615252 159.180363517* ', '* 3.65222385965 29.2536614627 -178.631312271', ], [ #'$ Femap with NX Nastran Coordinate System 32 : spherical in spherical', 'CORD2S* 32 2 22. 14.', '* 85. 22.1243073983 11.9537753718 77.9978191005* ', '* 21.0997242967 13.1806120497 88.4824763008', ], [ 'GRID* 30 30 40.7437952957 -23.6254877994', '* -33.09784854 0', ], [ 'GRID* 31 31 62.9378078196 15.9774797923', '* 31.0484428362 0', ], [ 'GRID* 32 32 53.8270847449 95.8215692632', '* 159.097767463 0', ], ] cards, card_count = model.add_cards_lines(card_lines) model.allocate(card_count, cards) model.build() for nid in model.nodes: a = array([30., 40., 50.]) b = model.Node(nid).get_position() self.assertTrue( allclose(array([30., 40., 50.]), model.Node(nid).get_position()), str(a - b))
def test_cord2_rcs_01(self): """ all points are located at <30,40,50> """ model = BDF(debug=False) card_count = { 'GRID': 3, 'CORD2R': 1, 'CORD2C': 1, 'CORD2S': 1, } cards = [] card_lines = [ [ #'$ Femap with NX Nastran Coordinate System 10 : rectangular defined in a rectangular', 'CORD2R* 10 0 10. 5.', '* 3. 10.3420201433 4.53015368961 3.81379768136* ', '* 10.7198463104 5.68767171433 3.09449287122', ], [ #'$ Femap with NX Nastran Coordinate System 11 : cylindrical defined in rectangular', 'CORD2C* 11 0 7. 3.', '* 9. 7.64278760969 2.73799736977 9.71984631039* ', '* 7.75440650673 3.37968226211 8.46454486422', ], [ #'$ Femap with NX Nastran Coordinate System 12 : spherical defined in rectangular', 'CORD2S* 12 0 12. 8.', '* 5. 12.6427876097 7.86697777844 5.75440650673* ', '* 12.6634139482 8.58906867688 4.53861076379', ], [ 'GRID* 10 10 42.9066011565 34.2422137135', '* 28.6442730262 0', ], [ 'GRID* 11 11 48.8014631871 78.8394787869', '* 34.6037164304 0', ], [ 'GRID* 12 12 58.0775343829 44.7276544324', '* 75.7955331161 0', ], ] cards, card_count = model.add_cards_lines(card_lines) model.allocate(card_count, cards) model.build() for nid in model.nodes: a = array([30., 40., 50.]) b = model.Node(nid).get_position() self.assertTrue( allclose(array([30., 40., 50.]), model.Node(nid).get_position()), str(a - b))
def test_cord2_rcs_02(self): """ all points are located at <30,40,50> """ model = BDF(debug=False) #card_count = { #'GRID' : 3, #'CORD2R' : 1, #'CORD2C' : 2, #'CORD2S' : 1, #} #model.allocate(card_count) card_lines = [ [ 'CORD2C* 1 0 0. 0.', '* 0. 0. 0. 1.* ', '* 1. 0. 1.',], [ #'$ Femap with NX Nastran Coordinate System 20 : rectangular defined in cylindrical', 'CORD2R* 20 1 7. 20.', '* -6. 7.07106781187 28.1301023542 -6.* ', '* 7.70710678119 20. -5.29289321881',], [ #'$ Femap with NX Nastran Coordinate System 21 : cylindrical defined in cylindrical', 'CORD2C* 21 1 15. -30.', '* 12. 14.6565766735 -30.3177805524 12.9355733712* ', '* 14.6234241583 -26.4257323272 11.9304419665',], [ #'$ Femap with NX Nastran Coordinate System 22 : spherical defined in cylindrical', 'CORD2S* 22 1 5. -75.', '* 20. 5.66032384035 -82.9319986389 19.8502545865* ', '* 4.88876051026 -73.8006653677 19.0116094889',], [ 'GRID* 20 20 64.2559135157 -14.9400459772', '* 27.3271005317 0',], [ 'GRID* 21 21 52.8328862418 -28.8729017195', '* 34.615939507 0',], [ 'GRID* 22 22 61.1042111232 158.773483595', '* -167.4951724 0',], ] cards, card_count = model.add_cards_lines(card_lines) model.allocate(card_count, cards) #for lines in cards: #card = model.add(lines) #model.add_card(card, card[0]) model.build() for nid in model.nodes: a = array([30., 40., 50.]) b = model.Node(nid).get_position() self.assertTrue(allclose(array([30., 40., 50.]), model.Node(nid).get_position()), str(a - b))
def test_cord2_rcs_03(self): """ all points are located at <30,40,50> """ model = BDF(debug=False) card_count = { 'GRID' : 3, 'CORD2R' : 1, 'CORD2C' : 1, 'CORD2S' : 2, } model.allocate(card_count) cards = [ [ 'CORD2S* 2 0 0. 0.', '* 0. 0. 0. 1.* ', '* 1. 0. 1.',], [ #'$ Femap with NX Nastran Coordinate System 30 : rectangular in spherical', 'CORD2R* 30 2 14. 30.', '* 70. 13.431863852 32.1458443949 75.2107442927* ', '* 14.4583462334 33.4569982885 68.2297989286',], [ #'$ Femap with NX Nastran Coordinate System 31 : cylindrical in spherical', 'CORD2C* 31 2 3. 42.', '* -173. 2.86526881213 45.5425615252 159.180363517* ', '* 3.65222385965 29.2536614627 -178.631312271',], [ #'$ Femap with NX Nastran Coordinate System 32 : spherical in spherical', 'CORD2S* 32 2 22. 14.', '* 85. 22.1243073983 11.9537753718 77.9978191005* ', '* 21.0997242967 13.1806120497 88.4824763008',], [ 'GRID* 30 30 40.7437952957 -23.6254877994', '* -33.09784854 0',], [ 'GRID* 31 31 62.9378078196 15.9774797923', '* 31.0484428362 0',], [ 'GRID* 32 32 53.8270847449 95.8215692632', '* 159.097767463 0',], ] for lines in cards: card = model.process_card(lines) model.add_card(card, card[0]) model.build() for nid in model.nodes: a = array([30., 40., 50.]) b = model.Node(nid).get_position() self.assertTrue(allclose(array([30., 40., 50.]), model.Node(nid).get_position()), str(a - b))
def test_grid_04(self): model = BDF() nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = { 'GRID': 2, } model = BDF() model.allocate(card_count) nodes = model.grid data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) data2 = BDFCard(['GRID', nid + 1, cp, 0., 0., 0., cd, ps, seid]) data3 = BDFCard(['GRID', nid + 2, cp, 0., 0., 0., cd, ps, seid]) data4 = BDFCard(['GRID', nid + 3, cp, 0., 0., 0., cd, ps, seid]) nodes.add(data1) nodes.add(data2) nodes.resize(4, refcheck=False) #print('nodes.node_id = %s' % nodes.node_id) nodes.add(data3) self.assertEqual(len(nodes.node_id), 4) self.assertEqual(nodes.n, 4) self.assertEqual(nodes.i, 3) nodes.shrink(refcheck=False) #print('nodes.node_id = %s' % nodes.node_id) self.assertEqual(len(nodes.node_id), 3) self.assertEqual(nodes.n, 3) self.assertEqual(nodes.i, 3) nodes.resize(4, refcheck=False) nodes.add(data4) self.assertEqual(len(nodes.node_id), 4) self.assertEqual(nodes.n, 4) self.assertEqual(nodes.i, 4) f = StringIO() nodes.write_bdf(f, size=8, write_header=False) #print(f.getvalue()) nodes.resize(2, refcheck=False) self.assertEqual(len(nodes.node_id), 2) self.assertEqual(nodes.n, 2) self.assertEqual(nodes.i, 2) f = StringIO() nodes.write_bdf(f, size=8, write_header=False)
def test_solid_03(self): """checks linear static solid material""" mid = 2 pid = 4 rho = 0.1 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes ['GRID', 21, 0, 0., 0., 0., 0,], ['GRID', 22, 0, 1., 0., 0., 0,], ['GRID', 23, 0, 1., 1., 0., 0,], ['GRID', 24, 0, 0., 0., 2., 0,], ['GRID', 25, 0, 1., 0., 2., 0,], ['GRID', 26, 0, 1., 1., 2., 0,], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # static ['PSOLID', pid, mid, 0], ['MAT1', mid, 1.0, 2.0, 3.0, rho], ['MATS1', mid, None, 'PLASTIC', 0.0, 1, 1, 100000., ], ] card_count = { 'GRID' : 14, 'CTETRA4': 1, 'CPENTA6': 1, 'CHEXA8' : 1, 'PSOLID': 1, 'MAT1': 1, 'MATS1': 1, } model = BDF(debug=True) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference()
def test_crod_01(self): model = BDF(debug=debug) model.allocate({"CROD": 1}) lines = ["CROD 10 100 10 2"] model.add_card(lines, "CROD", is_list=False) size = 8 f = StringIO() # card = CROD(card) card = model.crod.slice_by_element_id([10]) card.write_card(f, size) # card.rawFields() self.assertEquals(card.get_element_id_by_element_index(), 10) self.assertEquals(card.get_property_id_by_element_index(), 100)
def test_crod_01(self): model = BDF(debug=debug) model.allocate({'CROD': 1}) lines = ['CROD 10 100 10 2'] model.add_card(lines, 'CROD', is_list=False) size = 8 f = StringIO() #card = CROD(card) card = model.crod.slice_by_element_id([10]) card.write_card(f, size) #card.rawFields() self.assertEquals(card.get_element_id_by_element_index(), 10) self.assertEquals(card.get_property_id_by_element_index(), 100)
def test_grid_04(self): model = BDF() nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = {'GRID': 2,} model = BDF() model.allocate(card_count) nodes = model.grid data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) data2 = BDFCard(['GRID', nid+1, cp, 0., 0., 0., cd, ps, seid]) data3 = BDFCard(['GRID', nid+2, cp, 0., 0., 0., cd, ps, seid]) data4 = BDFCard(['GRID', nid+3, cp, 0., 0., 0., cd, ps, seid]) nodes.add(data1) nodes.add(data2) nodes.resize(4, refcheck=False) #print('nodes.node_id = %s' % nodes.node_id) nodes.add(data3) self.assertEqual(len(nodes.node_id), 4) self.assertEqual(nodes.n, 4) self.assertEqual(nodes.i, 3) nodes.shrink(refcheck=False) #print('nodes.node_id = %s' % nodes.node_id) self.assertEqual(len(nodes.node_id), 3) self.assertEqual(nodes.n, 3) self.assertEqual(nodes.i, 3) nodes.resize(4, refcheck=False) nodes.add(data4) self.assertEqual(len(nodes.node_id), 4) self.assertEqual(nodes.n, 4) self.assertEqual(nodes.i, 4) f = StringIO() nodes.write_bdf(f, size=8, write_header=False) #print(f.getvalue()) nodes.resize(2, refcheck=False) self.assertEqual(len(nodes.node_id), 2) self.assertEqual(nodes.n, 2) self.assertEqual(nodes.i, 2) f = StringIO() nodes.write_bdf(f, size=8, write_header=False)
def test_cord2_rcs_01(self): """ all points are located at <30,40,50> """ model = BDF(debug=False) card_count = { 'GRID' : 3, 'CORD2R' : 1, 'CORD2C' : 1, 'CORD2S' : 1, } cards = [] card_lines = [ [ #'$ Femap with NX Nastran Coordinate System 10 : rectangular defined in a rectangular', 'CORD2R* 10 0 10. 5.', '* 3. 10.3420201433 4.53015368961 3.81379768136* ', '* 10.7198463104 5.68767171433 3.09449287122',], [ #'$ Femap with NX Nastran Coordinate System 11 : cylindrical defined in rectangular', 'CORD2C* 11 0 7. 3.', '* 9. 7.64278760969 2.73799736977 9.71984631039* ', '* 7.75440650673 3.37968226211 8.46454486422',], [ #'$ Femap with NX Nastran Coordinate System 12 : spherical defined in rectangular', 'CORD2S* 12 0 12. 8.', '* 5. 12.6427876097 7.86697777844 5.75440650673* ', '* 12.6634139482 8.58906867688 4.53861076379',], [ 'GRID* 10 10 42.9066011565 34.2422137135', '* 28.6442730262 0',], [ 'GRID* 11 11 48.8014631871 78.8394787869', '* 34.6037164304 0',], [ 'GRID* 12 12 58.0775343829 44.7276544324', '* 75.7955331161 0',], ] cards, card_count = model.add_cards_lines(card_lines) model.allocate(card_count, cards) model.build() for nid in model.nodes: a = array([30., 40., 50.]) b = model.Node(nid).get_position() self.assertTrue(allclose(array([30., 40., 50.]), model.Node(nid).get_position()), str(a - b))
def test_cord1r_02(self): model = BDF(debug=False) card_count = { 'CORD1R' : 1, 'GRID' : 3, } model.allocate(card_count) cards = [ ['CORD1R', 1, 1, 2, 3], # fails on self.k ['GRID', 1, 0, 0., 0., 0.], ['GRID', 2, 0, 1., 0., 0.], ['GRID', 3, 0, 1., 1., 0.], ] for card in cards: model.add_card(card, card[0], comment='comment\n', is_list=True) model.build() c1 = model.coords.slice_by_coord_id(1)
def test_conrod_01(self): model = BDF(debug=debug) model.allocate({"CONROD": 1}) eid = 10 nid1 = 2 nid2 = 3 mid = 5 A = 27.0 lines = ["conrod,%i, %i, %i, %i, %f" % (eid, nid1, nid2, mid, A)] model.add_card(lines, "CONROD", is_list=False) size = 8 card = model.conrod.slice_by_element_id([eid]) f = StringIO() card.write_card(f, size) # card.rawFields() self.assertEquals(card.get_element_id_by_element_index(), eid) self.assertEquals(card.get_material_id_by_element_index(), mid)
def test_conrod_01(self): model = BDF(debug=debug) model.allocate({'CONROD': 1}) eid = 10 nid1 = 2 nid2 = 3 mid = 5 A = 27.0 lines = ['conrod,%i, %i, %i, %i, %f' % (eid, nid1, nid2, mid, A)] model.add_card(lines, 'CONROD', is_list=False) size = 8 card = model.conrod.slice_by_element_id([eid]) f = StringIO() card.write_card(f, size) #card.rawFields() self.assertEquals(card.get_element_id_by_element_index(), eid) self.assertEquals(card.get_material_id_by_element_index(), mid)
def test_grid_02(self): model = BDF(debug=False) nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = {'GRID': 2,} model = BDF(debug=False) model.allocate(card_count) nodes = model.grid data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) data2 = BDFCard(['GRID', nid+1, cp, 0., 0., 0., cd, ps, seid]) nodes.add(data1) nodes.add(data2) f = StringIO() nodes.write_card(f, size=8, write_header=False)
def test_grid_02(self): model = BDF() nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = {'GRID': 2,} model = BDF() model.allocate(card_count) nodes = model.grid data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) data2 = BDFCard(['GRID', nid+1, cp, 0., 0., 0., cd, ps, seid]) nodes.add(data1) nodes.add(data2) f = StringIO() nodes.write_bdf(f, size=8, write_header=False)
def test_cord2_rcs_02(self): """ all points are located at <30,40,50> """ model = BDF(debug=False) card_count = { 'GRID' : 3, 'CORD2R' : 1, 'CORD2C' : 2, 'CORD2S' : 1, } model.allocate(card_count) cards = [ ['CORD2C* 1 0 0. 0.', '* 0. 0. 0. 1.* ', '* 1. 0. 1.',], [#'$ Femap with NX Nastran Coordinate System 20 : rectangular defined in cylindrical', 'CORD2R* 20 1 7. 20.', '* -6. 7.07106781187 28.1301023542 -6.* ', '* 7.70710678119 20. -5.29289321881',], [#'$ Femap with NX Nastran Coordinate System 21 : cylindrical defined in cylindrical', 'CORD2C* 21 1 15. -30.', '* 12. 14.6565766735 -30.3177805524 12.9355733712* ', '* 14.6234241583 -26.4257323272 11.9304419665',], [#'$ Femap with NX Nastran Coordinate System 22 : spherical defined in cylindrical', 'CORD2S* 22 1 5. -75.', '* 20. 5.66032384035 -82.9319986389 19.8502545865* ', '* 4.88876051026 -73.8006653677 19.0116094889',], ['GRID* 20 20 64.2559135157 -14.9400459772', '* 27.3271005317 0',], ['GRID* 21 21 52.8328862418 -28.8729017195', '* 34.615939507 0',], ['GRID* 22 22 61.1042111232 158.773483595', '* -167.4951724 0',], ] for lines in cards: card = model.process_card(lines) model.add_card(card, card[0]) model.cross_reference() for nid in model.nodes: a = array([30.,40.,50.]) b = model.Node(nid).Position() self.assertTrue(allclose(array([30.,40.,50.]), model.Node(nid).Position()), str(a-b))
def test_cord2c_01(self): lines_a = [ 'CORD2C* 3 0 0. 0.', '* 0. 0. 0. 1.*', '* 1. 0. 1.' ] lines_b = [ 'CORD2R 4 3 10. 0. 5. 10. 90. 5.', ' 10. 0. 6.' ] card_count = { 'CORD2C' : 1, 'CORD2R' : 1, } model = BDF(debug=False) model.allocate(card_count) card = model.add_card(lines_a, 'CORD2C', is_list=False) card = model.add_card(lines_b, 'CORD2R', is_list=False) model.build() cord2r = model.coords.slice_by_coord_id(3) #print(type(cord2r)) self.assertEquals(cord2r.get_cid_by_coord_id(), 3) self.assertEquals(cord2r.get_rid_by_coord_id(), 0) cord2r = model.coords.slice_by_coord_id(4) #print(type(cord2r)) self.assertEquals(cord2r.get_cid_by_coord_id(), 4) self.assertEquals(cord2r.get_rid_by_coord_id(), 3) i = model.coords.get_coord_index_by_coord_id(4) T = model.coords.T[i, :, :].reshape(3, 3) Ti = T[0, :] Tj = T[1, :] Tk = T[2, :] msg = 'i=%s expected=(0., 0., 1.)' % Ti self.assertTrue(allclose(Ti, array([0., 0., 1.])), msg) delta = Tj - array([1., 1., 0.]) / 2**0.5 self.assertTrue(allclose(Tj, array([1., 1., 0.]) / 2**0.5), str(delta)) delta = Tk - array([-1., 1., 0.]) / 2**0.5 self.assertTrue(allclose(Tk, array([-1., 1., 0.]) / 2**0.5), str(delta))
def test_grid_01(self): model = BDF(debug=False) cards = [ #['CORD1R', 1, 1, 2, 3], # fails on self.k ['GRID', 1, 0, 0., 0., 0.], ['GRID', 2, 0, 1., 0., 0.], ['GRID', 4, 0, 1., 2., 3.], ] card_count = { 'GRID': 3, } model.allocate(card_count) for card in cards: model.add_card(card, card[0], comment='comment', is_list=True) #+------+-----+----+----+----+----+----+----+------+ #| 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | #+======+=====+====+====+====+====+====+====+======+ #| GRID | NID | CP | X1 | X2 | X3 | CD | PS | SEID | #+------+-----+----+----+----+----+----+----+------+ node = model.Node(4)
def test_grid_01(self): model = BDF(debug=False) card_lines = [ #['CORD1R', 1, 1, 2, 3], # fails on self.k ['GRID', 1, 0, 0., 0., 0.], ['GRID', 2, 0, 1., 0., 0.], ['GRID', 4, 0, 1., 2., 3.], ] #card_count = { #'GRID': 3, #} cards, card_count = model.add_cards_lines(card_lines) model.allocate(card_count, cards) for card in cards: model.add_card(card, card[0], comment='comment', is_list=True) model.build() #+------+-----+----+----+----+----+----+----+------+ #| 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | #+======+=====+====+====+====+====+====+====+======+ #| GRID | NID | CP | X1 | X2 | X3 | CD | PS | SEID | #+------+-----+----+----+----+----+----+----+------+ node = model.grid.slice_by_node_id(4)
def test_grid_03(self): model = BDF() nid = 1 cp = 2 cd = 0 ps = '' seid = 0 card_count = {'GRID': 2,} model = BDF() model.allocate(card_count) nodes = model.grid data1 = BDFCard(['GRID', nid, cp, 0., 0., 0., cd, ps, seid]) data2 = BDFCard(['GRID', nid+1, cp, 0., 0., 0., cd, ps, seid]) data3 = BDFCard(['GRID', nid+2, cp, 0., 0., 0., cd, ps, seid]) nodes.add(data1) nodes.add(data2) nodes.resize(3, refcheck=False) #print('nodes.node_id = %s' % nodes.node_id) nodes.add(data3) f = StringIO() nodes.write_bdf(f, size=8, write_header=False)
def test_solid_02(self): mid = 2 pid = 4 rho = 0.1 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes [ 'GRID', 21, 0, 0., 0., 0., 0, ], [ 'GRID', 22, 0, 1., 0., 0., 0, ], [ 'GRID', 23, 0, 1., 1., 0., 0, ], [ 'GRID', 24, 0, 0., 0., 2., 0, ], [ 'GRID', 25, 0, 1., 0., 2., 0, ], [ 'GRID', 26, 0, 1., 1., 2., 0, ], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # hyperelastic ['PLSOLID', pid, mid, 'GRID'], ['MATHP', mid, None, None, None, rho], ] card_count = { 'GRID': 14, 'CTETRA4': 1, 'CPENTA6': 1, 'CHEXA8': 1, 'PLSOLID': 1, 'MATHP': 1, } model = BDF(debug=True) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference() # CTETRA eid = 8 nsm = 0. V = 1. / 3. self.check_solid(model, eid, 'CTETRA4', pid, 'PLSOLID', mid, 'MATHP', nsm, rho, V) eid = 9 V = 1.0 self.check_solid(model, eid, 'CPENTA6', pid, 'PLSOLID', mid, 'MATHP', nsm, rho, V) eid = 7 V = 2.0 self.check_solid(model, eid, 'CHEXA8', pid, 'PLSOLID', mid, 'MATHP', nsm, rho, V)
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 test_pcomp_01(self): """ asymmetrical, nsm=0.0 and nsm=1.0 """ #self.pid = data[0] #self.z0 = data[1] #self.nsm = data[2] #self.sb = data[3] #self.ft = data[4] #self.TRef = data[5] #self.ge = data[6] #self.lam = data[7] #Mid = data[8] #T = data[9] #Theta = data[10] #Sout = data[11] pid = 1 z0 = 0. nsm = 0. sb = 0. ft = 'HILL' TRef = 0. ge = 0. #lam = 'NO' # isSymmetrical YES/NO lam = 'BEND' # isSymmetrical YES/NO Mid = [1, 2, 3] Theta = [0., 10., 20.] T = [.1, .2, .3] Sout = ['YES', 'YES', 'NO'] # 0-NO, 1-YES card_lines = [ 'PCOMP', pid, z0, nsm, sb, ft, TRef, ge, lam, Mid[0], T[0], Theta[0], Sout[0], Mid[1], T[1], Theta[1], Sout[1], Mid[2], T[2], Theta[2], Sout[2], ] model = BDF(debug=False) card_count = { 'PCOMP': 1, 'MAT1': 3, } model.allocate(card_count) model.add_card(card_lines, 'PCOMP', comment='', is_list=True) # material... mid = 1 E = 1e7 G = None nu = None rho = 1.0 a = None St = None Sc = None Ss = None Mcsid = None mat1_a = ['MAT1', mid, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] mat1_b = [ 'MAT1', mid + 1, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid ] mat1_c = [ 'MAT1', mid + 2, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid ] model.add_card(mat1_a, 'MAT1', comment='', is_list=True) model.add_card(mat1_b, 'MAT1', comment='', is_list=True) model.add_card(mat1_c, 'MAT1', comment='', is_list=True) #card = BDFCard(mat1) #m = MAT1(model) #m.allocate(1) #m.add(card) #m.build() model.build() #card = BDFCard(data) #p = PCOMP(model) #p = model.properties.pcomp #p.add(card) #p.build() p = model.properties_shell.pcomp m = model.materials.mat1 #self.assertFalse(p.is_symmetrical()) self.assertEqual(p.get_nplies_by_property_id(), 3) self.assertAlmostEqual(p.get_thickness_by_property_id(pid), 0.6) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 2), 0.3) with self.assertRaises(IndexError): p.get_thickness_by_property_id_ply(pid, 3) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 0), 0.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 1), 10.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 2), 20.) with self.assertRaises(IndexError): p.get_theta_by_property_id_ply(pid, 3) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 0), 1) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 1), 2) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 2), 3) with self.assertRaises(IndexError): p.get_material_id_by_property_id_ply(pid, 3) #print('get_material_id_by_property_id = ', p.get_material_id_by_property_id(pid)) self.assertEqual(p.get_material_ids_by_property_id(pid)[0], 1) self.assertEqual(p.get_material_ids_by_property_id(pid)[0], 1) self.assertEqual(p.get_material_ids_by_property_id(pid)[1], 2) self.assertEqual(p.get_material_ids_by_property_id(pid)[2], 3) self.assertEqual(p.get_sout_by_property_id_ply(pid, 0), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 1), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 2), 'NO') with self.assertRaises(IndexError): p.get_sout_by_property_id_ply(pid, 3) #for iply in range(len(p.plies)): #mid = p.plies[iply][0] #p.plies[iply][0] = m # MAT1 ##p.mids = [m, m, m] from StringIO import StringIO f = StringIO() #print(m.write_card(f, size=8, material_id=None)) p.write_card(f) m.write_card(f) print(f.getvalue()) #Mid self.assertAlmostEqual(p.get_material_id_by_property_id_ply(pid, 0), 1) self.assertAlmostEqual(p.get_material_id_by_property_id_ply(pid, 1), 2) self.assertAlmostEqual(p.get_material_id_by_property_id_ply(pid, 2), 3) with self.assertRaises(IndexError): p.get_density_by_property_id_ply(pid, 3) #Rho self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 0), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 1), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 2), 1.0) with self.assertRaises(IndexError): p.get_density_by_property_id_ply(pid, 3) # MassPerArea self.assertAlmostEqual(p.get_mass_per_area_by_property_id(), 0.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id(pid), 0.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id([pid]), 0.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2), 0.3) #with self.assertRaises(IndexError): #p.MassPerArea(3) #---------------------- # change the nsm to 1.0 p.set_nonstructural_mass_by_property_id(pid, 1.0) self.assertEqual(p.get_nonstructural_mass_by_property_id(), 1.0) # MassPerArea self.assertAlmostEqual(p.get_mass_per_area_by_property_id(), 1.6) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 0, method='nplies'), 0.1 + 1 / 3.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 1, method='nplies'), 0.2 + 1 / 3.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 2, method='nplies'), 0.3 + 1 / 3.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 0, method='t'), 0.1 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 1, method='t'), 0.2 + 2 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 2, method='t'), 0.3 + 3 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 0, method='rho*t'), 0.1 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 1, method='rho*t'), 0.2 + 2 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 2, method='rho*t'), 0.3 + 3 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 0, method='t'), 0.1 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 1, method='t'), 0.2 + 2 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 2, method='t'), 0.3 + 3 / 6.) with self.assertRaises(IndexError): p.get_mass_per_area_by_property_id_ply(pid, 3, method='nplies') z0 = p.get_z0_by_property_id(pid) z = p.get_z_locations_by_property_id(pid) z_expected = array([0., T[0], T[0] + T[1], T[0] + T[1] + T[2]]) for za, ze in zip(z, z_expected): self.assertAlmostEqual(za, ze) #z0 = p.z0[0] = 1.0 z_expected = 1.0 + z_expected z = p.get_z_locations_by_property_id(pid) for za, ze in zip(z, z_expected): self.assertAlmostEqual(za, ze)
def test_cord2r_bad_01(self): model = BDF(debug=True) card_count = { 'GRID' : 4, 'CORD2R' : 3, } model.allocate(card_count) grids = [ ['GRID', 1, 0], ['GRID', 20, 0], ['GRID', 30, 0], ['GRID', 11, 5], ] for grid in grids: model.add_card(grid, 'GRID', is_list=True) cards = [ ['CORD2R', 1, 0, 0., 0., 0., 0., 0., 0., 0., 0., 0.], # fails on self.k ['CORD2R', 2, 0, 0., 0., 0., 1., 0., 0., 0., 0., 0.], # fails on normalize self.j ['CORD2R', 3, 0, 0., 0., 0., 1., 0., 0., 1., 1., 0.], # passes ['CORD2R', 4, 0, 0., 1., 0., 1., 0., 0., 1., 1., 0.], # passes ['CORD2R', 5, 4, 0., 1., 0., 1., 0., 0., 1., 1., 0.], # passes ] for card in cards: cid = card[1] if cid in [1, 2]: with self.assertRaises(RuntimeError): model.add_card(card, card[0], is_list=True) else: model.add_card(card, card[0], is_list=True) model.build() # this runs because it's got rid=0 coords = model.coords #.slice_by_coord_id(4) coords.transform_node_id_to_global_xyz(30) # nid coords.transform_node_id_to_global_xyz([30, 1, 11]) # [nid, nid, nid] coords.transform_node_id_to_local_by_coord_id([30, 1, 11], 4) # [nid, ...], cp_goal coords.transform_node_id_to_local_by_coord_id([30, 1, 11], 0) # [nid, ...], cp_goal xyz = [0., 0., 0.] coords.transform_xyz_to_global_by_coord_id(xyz, 4) # [xyz], cp_initial xyz = [ [0., 0., 0.], [1., 1., 1.], ] coords.transform_xyz_to_global_by_coord_id(xyz, 4) # [xyz], cp_initial # global from global coords.transform_xyz_to_global_by_coord_id(xyz, 0) # [xyz], cp_initial # this doesn't run because rid != 0 with self.assertRaises(RuntimeError): # cp=0 doesn't exist coords.transform_xyz_to_global_by_coord_id(xyz, 2)
def test_pcomp_01(self): """ asymmetrical, nsm=0.0 and nsm=1.0 """ #self.pid = data[0] #self.z0 = data[1] #self.nsm = data[2] #self.sb = data[3] #self.ft = data[4] #self.TRef = data[5] #self.ge = data[6] #self.lam = data[7] #Mid = data[8] #T = data[9] #Theta = data[10] #Sout = data[11] pid = 1 z0 = 0. nsm = 0. sb = 0. ft = 'HILL' TRef = 0. ge = 0. #lam = 'NO' # isSymmetrical YES/NO lam = 'BEND' # isSymmetrical YES/NO Mid = [1, 2, 3] Theta = [0., 10., 20.] T = [.1, .2, .3] Sout = ['YES', 'YES', 'NO'] # 0-NO, 1-YES card_lines = [ 'PCOMP', pid, z0, nsm, sb, ft, TRef, ge, lam, Mid[0], T[0], Theta[0], Sout[0], Mid[1], T[1], Theta[1], Sout[1], Mid[2], T[2], Theta[2], Sout[2], ] model = BDF() card_count = { 'PCOMP' : 1, 'MAT1' : 3, } model.allocate(card_count) model.add_card(card_lines, 'PCOMP', comment='', is_list=True) # material... mid = 1 E = 1e7 G = None nu = None rho = 1.0 a = None St = None Sc = None Ss = None Mcsid = None mat1_a = ['MAT1', mid, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] mat1_b = ['MAT1', mid + 1, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] mat1_c = ['MAT1', mid + 2, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] model.add_card(mat1_a, 'MAT1', comment='', is_list=True) model.add_card(mat1_b, 'MAT1', comment='', is_list=True) model.add_card(mat1_c, 'MAT1', comment='', is_list=True) #card = BDFCard(mat1) #m = MAT1(model) #m.allocate(1) #m.add(card) #m.build() model.build() #card = BDFCard(data) #p = PCOMP(model) #p = model.properties.pcomp #p.add(card) #p.build() p = model.properties_shell.pcomp m = model.materials.mat1 #self.assertFalse(p.is_symmetrical()) self.assertEqual(p.get_nplies_by_property_id(), 3) self.assertAlmostEqual(p.get_thickness_by_property_id(pid), 0.6) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 2), 0.3) with self.assertRaises(IndexError): p.get_thickness_by_property_id_ply(pid, 3) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 0), 0.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 1), 10.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 2), 20.) with self.assertRaises(IndexError): p.get_theta_by_property_id_ply(pid, 3) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 0), 1) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 1), 2) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 2), 3) with self.assertRaises(IndexError): p.get_material_id_by_property_id_ply(pid, 3) #print('get_material_id_by_property_id = ', p.get_material_id_by_property_id(pid)) self.assertEqual(p.get_material_ids_by_property_id(pid)[0], 1) self.assertEqual(p.get_material_ids_by_property_id(pid)[0], 1) self.assertEqual(p.get_material_ids_by_property_id(pid)[1], 2) self.assertEqual(p.get_material_ids_by_property_id(pid)[2], 3) self.assertEqual(p.get_sout_by_property_id_ply(pid, 0), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 1), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 2), 'NO') with self.assertRaises(IndexError): p.get_sout_by_property_id_ply(pid, 3) #for iply in range(len(p.plies)): #mid = p.plies[iply][0] #p.plies[iply][0] = m # MAT1 ##p.mids = [m, m, m] from StringIO import StringIO f = StringIO() #print(m.write_card(f, size=8, material_id=None)) p.write_card(f) m.write_card(f) print(f.getvalue()) #Mid self.assertAlmostEqual(p.get_material_id_by_property_id_ply(pid, 0), 1) self.assertAlmostEqual(p.get_material_id_by_property_id_ply(pid, 1), 2) self.assertAlmostEqual(p.get_material_id_by_property_id_ply(pid, 2), 3) with self.assertRaises(IndexError): p.get_density_by_property_id_ply(pid, 3) #Rho self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 0), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 1), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 2), 1.0) with self.assertRaises(IndexError): p.get_density_by_property_id_ply(pid, 3) # MassPerArea self.assertAlmostEqual(p.get_mass_per_area_by_property_id(), 0.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id(pid), 0.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id([pid]), 0.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2), 0.3) #with self.assertRaises(IndexError): #p.MassPerArea(3) #---------------------- # change the nsm to 1.0 p.set_nonstructural_mass_by_property_id(pid, 1.0) self.assertEqual(p.get_nonstructural_mass_by_property_id(), 1.0) # MassPerArea self.assertAlmostEqual(p.get_mass_per_area_by_property_id(), 1.6) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0, method='nplies'), 0.1+1/3.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1, method='nplies'), 0.2+1/3.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2, method='nplies'), 0.3+1/3.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0, method='t'), 0.1+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1, method='t'), 0.2+2/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2, method='t'), 0.3+3/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0, method='rho*t'), 0.1+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1, method='rho*t'), 0.2+2/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2, method='rho*t'), 0.3+3/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0, method='t'), 0.1+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1, method='t'), 0.2+2/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2, method='t'), 0.3+3/6.) with self.assertRaises(IndexError): p.get_mass_per_area_by_property_id_ply(pid, 3, method='nplies') z0 = p.get_z0_by_property_id(pid) z = p.get_z_locations_by_property_id(pid) z_expected = array([0., T[0], T[0]+T[1], T[0]+T[1]+T[2]]) for za, ze in zip(z, z_expected): self.assertAlmostEqual(za, ze) #z0 = p.z0[0] = 1.0 z_expected = 1.0 + z_expected z = p.get_z_locations_by_property_id(pid) for za, ze in zip(z, z_expected): self.assertAlmostEqual(za, ze)
def test_pshell_01(self): """tests a CQUAD4 and a PSHELL""" rho = 0.1 nu = 0.3 G = None E = 1e7 t = 0.3 nsm = 0.0 card_count = { 'GRID': 4, 'CQUAD4': 1, #'CTRIA3': 1, 'PSHELL': 1, 'PCOMP': 1, 'MAT1': 1, 'MAT8': 1, } #print('starting BDF1') model = BDF(debug=True) model.allocate(card_count) self._make_cquad4(model, rho, nu, G, E, t, nsm) card_count1 = { 'GRID': 3, #'CQUAD4': 1, 'CTRIA3': 2, 'PSHELL': 1, 'PCOMP': 1, 'MAT1': 1, 'MAT8': 1, } #print('starting BDF2') model = BDF(debug=True) model.allocate(card_count1) self._make_ctria3(model, rho, nu, G, E, t, nsm) card_count = { 'GRID': 4, 'CQUAD4': 1, #'CTRIA3': 2, 'PSHELL': 1, 'PCOMP': 1, 'MAT1': 1, 'MAT8': 1, } #print('starting BDF3') nsm = 1.0 model = BDF(debug=False) model.allocate(card_count) self._make_cquad4(model, rho, nu, G, E, t, nsm) card_count = { 'GRID': 3, #'CQUAD4': 1, 'CTRIA3': 2, 'PSHELL': 1, 'PCOMP': 1, 'MAT1': 1, 'MAT8': 1, } #print('starting BDF4') model = BDF(debug=False) model.allocate(card_count) self._make_ctria3(model, rho, nu, G, E, t, nsm)
def test_spoint_01(self): model = BDF() card_count = {'SPOINT': 2,} model = BDF() model.allocate(card_count) spoints = model.spoint data1 = BDFCard(['SPOINT', 1, 2]) data2 = BDFCard(['SPOINT', 4, 5]) data3 = BDFCard(['SPOINT', 10, 20]) data4 = BDFCard(['SPOINT', 30, 'THRU', 40]) spoints.add(data1) spoints.add(data2) f = StringIO() spoints.write_bdf(f, size=8) #print('spoints %s' % f.getvalue()) self.assertEqual(len(spoints), 4) self.assertEqual(spoints.n, 4) spoints.add(data3) f = StringIO() spoints.write_bdf(f, size=8) #print('spoints %s' % f.getvalue()) self.assertEqual(len(spoints), 6) self.assertEqual(spoints.n, 6) spoints.add(data4) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(len(spoints), 17) self.assertEqual(spoints.n, 17) spoints.add(data4) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(spoints.max(), 40) self.assertEqual(spoints.min(), 1) self.assertEqual(spoints.n, 17) if 1 in spoints: pass else: raise RuntimeError('invalid catch') if 29 in spoints: raise RuntimeError('invalid catch') data5 = BDFCard(['SPOINT', 50, 'THRU', 55, 59, '61', 'THRU', '64']) spoints.add(data5) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(spoints.max(), 64) self.assertEqual(spoints.min(), 1) self.assertEqual(spoints.n, 28) spoints.remove([1, 2, 64]) #self.assertRaises(KeyError, spoints.remove([1, 2])) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(spoints.n, 25)
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)
def test_solid_01(self): """checks linear static solid material""" mid = 2 pid = 4 rho = 0.1 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes [ 'GRID', 21, 0, 0., 0., 0., 0, ], [ 'GRID', 22, 0, 1., 0., 0., 0, ], [ 'GRID', 23, 0, 1., 1., 0., 0, ], [ 'GRID', 24, 0, 0., 0., 2., 0, ], [ 'GRID', 25, 0, 1., 0., 2., 0, ], [ 'GRID', 26, 0, 1., 1., 2., 0, ], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # static ['PSOLID', pid, mid, 0], ['MAT1', mid, 1.0, 2.0, 3.0, rho] ] card_count = { 'GRID': 14, 'CTETRA4': 1, 'CPENTA6': 1, 'CHEXA8': 1, 'PSOLID': 1, 'MAT1': 1, } model = BDF(debug=True) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference() # CTETRA eid = 8 mid = 2 pid = 4 nsm = 0. V = 1. / 3. rho = 0.1 self.check_solid(model, eid, 'CTETRA4', pid, 'PSOLID', mid, 'MAT1', nsm, rho, V) eid = 9 V = 1.0 self.check_solid(model, eid, 'CPENTA6', pid, 'PSOLID', mid, 'MAT1', nsm, rho, V) eid = 7 V = 2.0 self.check_solid(model, eid, 'CHEXA8', pid, 'PSOLID', mid, 'MAT1', nsm, rho, V)
def test_spoint_01(self): model = BDF() card_count = { 'SPOINT': 2, } model = BDF() model.allocate(card_count) spoints = model.spoint data1 = BDFCard(['SPOINT', 1, 2]) data2 = BDFCard(['SPOINT', 4, 5]) data3 = BDFCard(['SPOINT', 10, 20]) data4 = BDFCard(['SPOINT', 30, 'THRU', 40]) spoints.add(data1) spoints.add(data2) f = StringIO() spoints.write_bdf(f, size=8) #print('spoints %s' % f.getvalue()) self.assertEqual(len(spoints), 4) self.assertEqual(spoints.n, 4) spoints.add(data3) f = StringIO() spoints.write_bdf(f, size=8) #print('spoints %s' % f.getvalue()) self.assertEqual(len(spoints), 6) self.assertEqual(spoints.n, 6) spoints.add(data4) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(len(spoints), 17) self.assertEqual(spoints.n, 17) spoints.add(data4) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(spoints.max(), 40) self.assertEqual(spoints.min(), 1) self.assertEqual(spoints.n, 17) if 1 in spoints: pass else: raise RuntimeError('invalid catch') if 29 in spoints: raise RuntimeError('invalid catch') data5 = BDFCard(['SPOINT', 50, 'THRU', 55, 59, '61', 'THRU', '64']) spoints.add(data5) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(spoints.max(), 64) self.assertEqual(spoints.min(), 1) self.assertEqual(spoints.n, 28) spoints.remove([1, 2, 64]) #self.assertRaises(KeyError, spoints.remove([1, 2])) f = StringIO() spoints.write_bdf(f, size=16) #print('spoints %s' % f.getvalue()) self.assertEqual(spoints.n, 25)
def test_solid_01(self): """checks linear static solid material""" mid = 2 pid = 4 rho = 0.1 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes ['GRID', 21, 0, 0., 0., 0., 0,], ['GRID', 22, 0, 1., 0., 0., 0,], ['GRID', 23, 0, 1., 1., 0., 0,], ['GRID', 24, 0, 0., 0., 2., 0,], ['GRID', 25, 0, 1., 0., 2., 0,], ['GRID', 26, 0, 1., 1., 2., 0,], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # static ['PSOLID', pid, mid, 0], ['MAT1', mid, 1.0, 2.0, 3.0, rho] ] card_count = { 'GRID' : 14, 'CTETRA4': 1, 'CPENTA6': 1, 'CHEXA8' : 1, 'PSOLID': 1, 'MAT1': 1, } model = BDF(debug=True) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference() # CTETRA eid = 8 mid = 2 pid = 4 nsm = 0. V = 1. / 3. rho = 0.1 self.check_solid(model, eid, 'CTETRA4', pid, 'PSOLID', mid, 'MAT1', nsm, rho, V) eid = 9 V = 1.0 self.check_solid(model, eid, 'CPENTA6', pid, 'PSOLID', mid, 'MAT1', nsm, rho, V) eid = 7 V = 2.0 self.check_solid(model, eid, 'CHEXA8', pid, 'PSOLID', mid, 'MAT1', nsm, rho, V)
def test_pcomp_02(self): """ symmetrical, nsm=0.0 and nsm=1.0 """ model = BDF() pid = 1 z0 = 0. nsm = 0. sb = 0. ft = 'HOFF' TRef = 0. ge = 0. lam = 'SYM' # isSymmetrical SYM Mid = [1, 2, 3] Theta = [0., 10., 20.] T = [.1, .2, .3] Sout = ['YES', 'YES', 'NO'] # 0-NO, 1-YES pcomp = ['PCOMP', pid, z0, nsm, sb, ft, TRef, ge, lam, Mid[0], T[0], Theta[0], Sout[0], Mid[1], T[1], Theta[1], Sout[1], Mid[2], T[2], Theta[2], Sout[2]] #---- mid = 1 E = 3.0e7 G = None nu = None rho = 1.0 a = None St = None Sc = None Ss = None Mcsid = None mat1_a = ['MAT1', mid, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] mat1_b = ['MAT1', mid + 1, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] mat1_c = ['MAT1', mid + 2, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] card_count = { 'PCOMP' : 1, 'MAT1' : 3, } model.allocate(card_count) model.add_card(pcomp, pcomp[0], is_list=True) model.add_card(mat1_a, 'MAT1', is_list=True) model.add_card(mat1_b, 'MAT1', is_list=True) model.add_card(mat1_c, 'MAT1', is_list=True) model.build() p = model.properties.properties_shell.pcomp[0] self.assertTrue(p.is_symmetrical_by_property_id()) self.assertTrue(p.is_symmetrical_by_property_index()) self.assertEqual(p.get_nplies_by_property_id(), 6) self.assertAlmostEqual(p.get_thickness_by_property_id()[0], 1.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 2), 0.3) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 3), 0.1) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 4), 0.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 5), 0.3) with self.assertRaises(IndexError): p.get_thickness_by_property_id_ply(pid, 6) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 0), 0.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 1), 10.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 2), 20.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 3), 0.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 4), 10.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 5), 20.) with self.assertRaises(IndexError): p.get_theta_by_property_id_ply(pid, 6) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 0), 1) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 1), 2) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 2), 3) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 3), 1) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 4), 2) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 5), 3) with self.assertRaises(IndexError): p.get_material_id_by_property_id_ply(pid, 6) self.assertTrue(allclose( p.get_material_ids_by_property_id(pid), [1, 2, 3, 1, 2, 3]) ) self.assertEqual(p.get_sout_by_property_id_ply(pid, 0), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 1), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 2), 'NO') self.assertEqual(p.get_sout_by_property_id_ply(pid, 3), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 4), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 5), 'NO') with self.assertRaises(IndexError): p.get_sout_by_property_id_ply(pid, 6) #--------------- #Rho self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 0), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 1), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 2), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 3), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 4), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 5), 1.0) with self.assertRaises(IndexError): p.get_density_by_property_id_ply(pid, 6) # MassPerArea #self.assertAlmostEqual(p.get_mass_per_area_by_property_id(), 1.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id(pid), 1.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2), 0.3) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 3), 0.1) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 4), 0.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 5), 0.3) with self.assertRaises(IndexError): p.get_mass_per_area_by_property_id_ply(pid, 6) self.assertEqual(p.get_nonstructural_mass_by_property_id(pid), 0.0) #---------------------- # change the nsm to 1.0 p.set_nonstructural_mass_by_property_id(pid, 1.0) self.assertEqual(p.get_nonstructural_mass_by_property_id(pid), 1.0) # MassPerArea self.assertAlmostEqual(p.get_mass_per_area_by_property_id(pid), 2.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0, method='nplies'), 0.1+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1, method='nplies'), 0.2+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2, method='nplies'), 0.3+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 3, method='nplies'), 0.1+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 4, method='nplies'), 0.2+1/6.) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 5, method='nplies'), 0.3+1/6.) with self.assertRaises(IndexError): p.get_mass_per_area_by_property_id_ply(pid, 6)
def test_solid_03(self): """checks linear static solid material""" mid = 2 pid = 4 rho = 0.1 tableID = 42 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes [ 'GRID', 21, 0, 0., 0., 0., 0, ], [ 'GRID', 22, 0, 1., 0., 0., 0, ], [ 'GRID', 23, 0, 1., 1., 0., 0, ], [ 'GRID', 24, 0, 0., 0., 2., 0, ], [ 'GRID', 25, 0, 1., 0., 2., 0, ], [ 'GRID', 26, 0, 1., 1., 2., 0, ], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # static ['PSOLID', pid, mid, 0], ['MAT1', mid, 1.0, 2.0, 3.0, rho], [ 'MATS1', mid, tableID, 'PLASTIC', 0.0, 1, 1, 100000., ], #['TABLEST'], [ 'TABLES1', tableID, 1, None, None, None, None, None, None, 1.0, 10.0, 2.0, 10.0, 'ENDT' ], ] card_count = { 'GRID': 14, 'CPENTA6': 1, 'CTETRA4': 1, 'PSOLID': 1, 'CHEXA8': 1, 'MAT1': 1, 'MATS1': 1, 'TABLES1': 1, } model = BDF(debug=False) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference() mat = model.materials[mid] print('----MAT----', type(mat)) print(mat) print('E = %s' % mat.get_E_by_material_index()) print('E = %s' % mat.get_E_by_material_id())
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.cross_reference() mass = L * (rho * A + nsm) # conrod conrod = model.conrod[eid] self.assertEquals(conrod.get_element_id_by_element_index(), eid) #self.assertEquals(conrod.get_property_id_by_element_index(), None) self.assertEquals(conrod.get_material_id_by_element_index(), mid) self.assertEquals(conrod.get_length_by_element_index(), L) #self.assertEquals(conrod.Nsm(), nsm) self.assertEquals(conrod.get_mass_by_element_index(), mass) #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 conrod = model.conrod[eid + 1] self.assertEquals(crod.get_element_id_by_element_index(), eid + 1) self.assertEquals(crod.get_property_id_by_element_index(), pid) self.assertEquals(crod.get_material_id_by_element_index(), mid) self.assertEquals(crod.get_length_by_element_index(), L) #self.assertEquals(crod.Nsm(), nsm) self.assertEquals(crod.get_mass_by_element_index(), mass) #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 self.assertEquals(prod.Pid(), pid) self.assertEquals(prod.Mid(), mid) self.assertEquals(prod.Nsm(), nsm) self.assertEquals(prod.E(), E) self.assertEquals(prod.G(), G) self.assertEquals(prod.Area(), A) self.assertEquals(prod.J(), J) self.assertEquals(prod.C(), c) self.assertEquals(prod.Rho(), rho) # ctube if 0: self.assertEquals(ctube.Eid(), eid + 2) self.assertEquals(ctube.Pid(), pid + 1) self.assertEquals(ctube.Mid(), mid) self.assertEquals(ctube.Length(), L) self.assertEquals(ctube.Nsm(), nsm) self.assertAlmostEquals(ctube.Mass(), mass, 5) self.assertEquals(ctube.E(), E) self.assertEquals(ctube.G(), G) self.assertAlmostEquals(ctube.Area(), A, 5) ctube.J() self.assertEquals(ctube.Rho(), rho) # ptube self.assertEquals(ptube.Pid(), pid + 1) self.assertEquals(ptube.Mid(), mid) self.assertEquals(ptube.Nsm(), nsm) self.assertEquals(ptube.E(), E) self.assertEquals(ptube.G(), G) self.assertAlmostEquals(ptube.Area(), A, 5) ptube.J() self.assertEquals(ptube.Rho(), rho)
def test_solid_03(self): """checks linear static solid material""" mid = 2 pid = 4 rho = 0.1 cards = [ #$ Solid Nodes ['GRID', 11, 0, 0., 0., 0., 0], ['GRID', 12, 0, 1., 0., 0., 0], ['GRID', 13, 0, 1., 1., 0., 0], ['GRID', 14, 0, 0., 1., 0., 0], ['GRID', 15, 0, 0., 0., 2., 0], ['GRID', 16, 0, 1., 0., 2., 0], ['GRID', 17, 0, 1., 1., 2., 0], ['GRID', 18, 0, 0., 1., 2., 0], # Solids ['CHEXA', 7, pid, 11, 12, 13, 14, 15, 16, 17, 18], ['CTETRA', 8, pid, 11, 12, 13, 15], # Solid Nodes [ 'GRID', 21, 0, 0., 0., 0., 0, ], [ 'GRID', 22, 0, 1., 0., 0., 0, ], [ 'GRID', 23, 0, 1., 1., 0., 0, ], [ 'GRID', 24, 0, 0., 0., 2., 0, ], [ 'GRID', 25, 0, 1., 0., 2., 0, ], [ 'GRID', 26, 0, 1., 1., 2., 0, ], ['CPENTA', 9, pid, 21, 22, 23, 24, 25, 26], # static ['PSOLID', pid, mid, 0], ['MAT1', mid, 1.0, 2.0, 3.0, rho], [ 'MATS1', mid, None, 'PLASTIC', 0.0, 1, 1, 100000., ], ] card_count = { 'GRID': 14, 'CTETRA4': 1, 'CPENTA6': 1, 'CHEXA8': 1, 'PSOLID': 1, 'MAT1': 1, 'MATS1': 1, } model = BDF(debug=True) model.allocate(card_count) for fields in cards: model.add_card(fields, fields[0], is_list=True) model.cross_reference()
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.cross_reference() mass = L * (rho * A + nsm) # conrod conrod = model.conrod[eid] self.assertEquals(conrod.get_element_id_by_element_index(), eid) #self.assertEquals(conrod.get_property_id_by_element_index(), None) self.assertEquals(conrod.get_material_id_by_element_index(), mid) self.assertEquals(conrod.get_length_by_element_index(), L) #self.assertEquals(conrod.Nsm(), nsm) self.assertEquals(conrod.get_mass_by_element_index(), mass) #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 conrod = model.conrod[eid+1] self.assertEquals(crod.get_element_id_by_element_index(), eid+1) self.assertEquals(crod.get_property_id_by_element_index(), pid) self.assertEquals(crod.get_material_id_by_element_index(), mid) self.assertEquals(crod.get_length_by_element_index(), L) #self.assertEquals(crod.Nsm(), nsm) self.assertEquals(crod.get_mass_by_element_index(), mass) #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 self.assertEquals(prod.Pid(), pid) self.assertEquals(prod.Mid(), mid) self.assertEquals(prod.Nsm(), nsm) self.assertEquals(prod.E(), E) self.assertEquals(prod.G(), G) self.assertEquals(prod.Area(), A) self.assertEquals(prod.J(), J) self.assertEquals(prod.C(), c) self.assertEquals(prod.Rho(), rho) # ctube if 0: self.assertEquals(ctube.Eid(), eid+2) self.assertEquals(ctube.Pid(), pid+1) self.assertEquals(ctube.Mid(), mid) self.assertEquals(ctube.Length(), L) self.assertEquals(ctube.Nsm(), nsm) self.assertAlmostEquals(ctube.Mass(), mass, 5) self.assertEquals(ctube.E(), E) self.assertEquals(ctube.G(), G) self.assertAlmostEquals(ctube.Area(), A, 5) ctube.J() self.assertEquals(ctube.Rho(), rho) # ptube self.assertEquals(ptube.Pid(), pid+1) self.assertEquals(ptube.Mid(), mid) self.assertEquals(ptube.Nsm(), nsm) self.assertEquals(ptube.E(), E) self.assertEquals(ptube.G(), G) self.assertAlmostEquals(ptube.Area(), A, 5) ptube.J() self.assertEquals(ptube.Rho(), rho)
def test_pcomp_02(self): """ symmetrical, nsm=0.0 and nsm=1.0 """ model = BDF(debug=False) pid = 1 z0 = 0. nsm = 0. sb = 0. ft = 'HOFF' TRef = 0. ge = 0. lam = 'SYM' # isSymmetrical SYM Mid = [1, 2, 3] Theta = [0., 10., 20.] T = [.1, .2, .3] Sout = ['YES', 'YES', 'NO'] # 0-NO, 1-YES pcomp = [ 'PCOMP', pid, z0, nsm, sb, ft, TRef, ge, lam, Mid[0], T[0], Theta[0], Sout[0], Mid[1], T[1], Theta[1], Sout[1], Mid[2], T[2], Theta[2], Sout[2] ] #---- mid = 1 E = 3.0e7 G = None nu = None rho = 1.0 a = None St = None Sc = None Ss = None Mcsid = None mat1_a = ['MAT1', mid, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid] mat1_b = [ 'MAT1', mid + 1, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid ] mat1_c = [ 'MAT1', mid + 2, E, G, nu, rho, a, TRef, ge, St, Sc, Ss, Mcsid ] card_count = { 'PCOMP': 1, 'MAT1': 3, } model.allocate(card_count) model.add_card(pcomp, pcomp[0], is_list=True) model.add_card(mat1_a, 'MAT1', is_list=True) model.add_card(mat1_b, 'MAT1', is_list=True) model.add_card(mat1_c, 'MAT1', is_list=True) model.build() p = model.properties.properties_shell.pcomp[0] self.assertTrue(p.is_symmetrical_by_property_id()) self.assertTrue(p.is_symmetrical_by_property_index()) self.assertEqual(p.get_nplies_by_property_id(), 6) self.assertAlmostEqual(p.get_thickness_by_property_id()[0], 1.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 2), 0.3) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 3), 0.1) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 4), 0.2) self.assertAlmostEqual(p.get_thickness_by_property_id_ply(pid, 5), 0.3) with self.assertRaises(IndexError): p.get_thickness_by_property_id_ply(pid, 6) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 0), 0.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 1), 10.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 2), 20.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 3), 0.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 4), 10.) self.assertAlmostEqual(p.get_theta_by_property_id_ply(pid, 5), 20.) with self.assertRaises(IndexError): p.get_theta_by_property_id_ply(pid, 6) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 0), 1) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 1), 2) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 2), 3) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 3), 1) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 4), 2) self.assertEqual(p.get_material_id_by_property_id_ply(pid, 5), 3) with self.assertRaises(IndexError): p.get_material_id_by_property_id_ply(pid, 6) self.assertTrue( allclose(p.get_material_ids_by_property_id(pid), [1, 2, 3, 1, 2, 3])) self.assertEqual(p.get_sout_by_property_id_ply(pid, 0), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 1), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 2), 'NO') self.assertEqual(p.get_sout_by_property_id_ply(pid, 3), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 4), 'YES') self.assertEqual(p.get_sout_by_property_id_ply(pid, 5), 'NO') with self.assertRaises(IndexError): p.get_sout_by_property_id_ply(pid, 6) #--------------- #Rho self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 0), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 1), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 2), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 3), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 4), 1.0) self.assertAlmostEqual(p.get_density_by_property_id_ply(pid, 5), 1.0) with self.assertRaises(IndexError): p.get_density_by_property_id_ply(pid, 6) # MassPerArea #self.assertAlmostEqual(p.get_mass_per_area_by_property_id(), 1.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id(pid), 1.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 0), 0.1) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 1), 0.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 2), 0.3) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 3), 0.1) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 4), 0.2) self.assertAlmostEqual(p.get_mass_per_area_by_property_id_ply(pid, 5), 0.3) with self.assertRaises(IndexError): p.get_mass_per_area_by_property_id_ply(pid, 6) self.assertEqual(p.get_nonstructural_mass_by_property_id(pid), 0.0) #---------------------- # change the nsm to 1.0 p.set_nonstructural_mass_by_property_id(pid, 1.0) self.assertEqual(p.get_nonstructural_mass_by_property_id(pid), 1.0) # MassPerArea self.assertAlmostEqual(p.get_mass_per_area_by_property_id(pid), 2.2) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 0, method='nplies'), 0.1 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 1, method='nplies'), 0.2 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 2, method='nplies'), 0.3 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 3, method='nplies'), 0.1 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 4, method='nplies'), 0.2 + 1 / 6.) self.assertAlmostEqual( p.get_mass_per_area_by_property_id_ply(pid, 5, method='nplies'), 0.3 + 1 / 6.) with self.assertRaises(IndexError): p.get_mass_per_area_by_property_id_ply(pid, 6)