def test_dmiax(self): """tests DMIAX""" model = BDF(debug=None) ifo = 1 # square tin = 1 tout = None polar = None ncol = None gj = 2 cj = 8 g1 = 10 c1 = 20 a1 = 30 b1 = 40 lines = [ ['DMIAX', 'B2PP', 0, 1, 3], [ 'DMIAX', 'B2PP', 32, None, None, None, None, None, None, 1027, 3, None, 4.25 + 6, '2.27+3' ], #['DMIAX', 'AX', '0', ifo, tin, tout, polar, None, ncol], #['DMIAX', 'AX', gj, cj, None, g1, c1, a1, b1], ] for line in lines: model.add_card(line, 'DMIAX') fill_dmigs(model) str(model.dmigs) str(model.get_bdf_stats()) name = 'B2PPB' tin = 1 ncols = 3 GCNj = [(1, 2, 3)] GCNi = [[(10, 6, 30)]] Real = [0.1] matrix_form = 1 #load_sequences = { # lseq : [ncx] #10 : [[1001, 4, 1003.0]], #20 : [[1, 2, 3.], [11, 12, 13.], ], #30 : [[1, 2, 3.], [11, 12, 13.], [101, 4, 103.]], #} uaccel = model.add_dmiax(name, matrix_form, tin, tout, polar, ncols, GCNj, GCNi, Real, Complex=None, comment='dmiax') uaccel.raw_fields() str(uaccel) #uaccel.tin = 2 #str(uaccel) save_load_deck(model, run_save_load_hdf5=False)
def test_dmig_09(self): cards = [ ['DMIG, A, 0, 9, 1, 1, , , 1'], ['DMIG, A, 1, , , 2, 1, 1.0,'], ['DMIG, A, 1, , , 2, 2, 1.0,'], ['DMIG, A, 1, , , 2, 3, 1.0,'], ] model = BDF(debug=False) for card_lines in cards: model.add_card(card_lines, 'DMIG', is_list=False) fill_dmigs(model) a_matrix = model.dmigs['A'] assert len(a_matrix.GCi) == 3, 'len(GCi)=%s GCi=%s matrix=\n%s' % (len(a_matrix.GCi), a_matrix.GCi, a_matrix) assert len(a_matrix.GCj) == 3, 'len(GCj)=%s GCj=%s matrix=\n%s' % (len(a_matrix.GCj), a_matrix.GCj, a_matrix) #a_matrix.get_matrix() save_load_deck(model)
def test_dmig_10(self): """symmetric""" cards = [ ['DMIG,AMTRXX,0,6,1,0'], ['DMIG,AMTRXX,2,1, ,2,1,201.0, ,+DM1', '+DM1,2,3,203.0'], ['DMIG,AMTRXX,3,1, ,3,1,301.0, ,+DM2', '+DM2,3,3,303.0'], ] model = BDF(debug=False) for card_lines in cards: model.add_card(card_lines, 'DMIG', is_list=False) fill_dmigs(model) a_matrix = model.dmigs['AMTRXX'] assert len(a_matrix.GCi) == 4, 'len(GCi)=%s GCi=%s matrix=\n%s' % (len( a_matrix.GCi), a_matrix.GCi, a_matrix) assert len(a_matrix.GCj) == 4, 'len(GCj)=%s GCj=%s matrix=\n%s' % (len( a_matrix.GCj), a_matrix.GCj, a_matrix) assert a_matrix.shape == (4, 4), 'shape=%s' % str(a_matrix.shape) a_matrix.get_matrix()
def test_dmig_uaccel(self): """tests DMIG,UACCEL""" model = BDF(debug=None) lines = [ ['DMIG', 'UACCEL', '0', 9, 1, None, None, None, 4], ['DMIG', 'UACCEL', 2, None, None, 2, 3, 386.4], ['DMIG', 'UACCEL', 3, None, None, 2, 4, 3.0], ['DMIG', 'UACCEL', 4, None, None, 2, 6, 1.0], ] for line in lines: model.add_card(line, 'DMIG') fill_dmigs(model) str(model.dmigs) str(model.get_bdf_stats()) tin = 1 ncol = 3 load_sequences = { # lseq : [ncx] 10: [[1001, 4, 1003.0]], 20: [ [1, 2, 3.], [11, 12, 13.], ], 30: [[1, 2, 3.], [11, 12, 13.], [101, 4, 103.]], } uaccel = model.add_dmig_uaccel(tin, ncol, load_sequences, comment='uaccel') uaccel.raw_fields() str(uaccel) uaccel.tin = 2 str(uaccel) save_load_deck(model)
def test_dmiax(self): """tests DMIAX""" model = BDF(debug=None) #ifo = 1 # square tin = 1 tout = None #ncol = None #gj = 2 #cj = 8 #g1 = 10 #c1 = 20 #a1 = 30 #b1 = 40 lines = [ ['DMIAX', 'B2PP', 0, 1, 3], [ 'DMIAX', 'B2PP', 32, None, None, None, None, None, None, 1027, 3, None, 4.25 + 6, '2.27+3' ], #['DMIAX', 'AX', '0', ifo, tin, tout, polar, None, ncol], #['DMIAX', 'AX', gj, cj, None, g1, c1, a1, b1], ] for line in lines: model.add_card(line, 'DMIAX') fill_dmigs(model) str(model.dmiax) str(model.get_bdf_stats()) str(model.dmiax['B2PP']) name = 'AXREAL1' tin = 1 tout = 2 ncols = 3 GCNj = [(1, 2, 3)] GCNi = [[(10, 6, 30)]] Real = [0.1] matrix_form = 1 dmiax_real = model.add_dmiax(name, matrix_form, tin, tout, ncols, GCNj, GCNi, Real, Complex=None, comment='dmiax') assert dmiax_real.is_real is True, dmiax_real.is_real assert dmiax_real.is_complex is False, dmiax_real.is_complex assert dmiax_real.is_polar is False, dmiax_real.is_polar name = 'AXREAL1' tin = 2 tout = 1 dmiax_real = model.add_dmiax(name, matrix_form, tin, tout, ncols, GCNj, GCNi, Real, Complex=None, comment='dmiax') assert dmiax_real.is_real is True, dmiax_real.is_real assert dmiax_real.is_complex is False, dmiax_real.is_complex assert dmiax_real.is_polar is False, dmiax_real.is_polar name = 'AXIMAG1' Complex = [0.2] tin = 3 tout = 4 dmiax_mag = model.add_dmiax(name, matrix_form, tin, tout, ncols, GCNj, GCNi, Real, Complex=Complex, comment='dmiax') assert dmiax_mag.is_real is False, dmiax_mag.is_real assert dmiax_mag.is_complex is True, dmiax_mag.is_complex assert dmiax_mag.is_polar is False, dmiax_mag.is_polar name = 'AXIMAG2' Complex = [0.2] tout = 4 tin = 3 dmiax_imag = model.add_dmiax(name, matrix_form, tin, tout, ncols, GCNj, GCNi, Real, Complex=Complex, comment='dmiax') assert dmiax_imag.is_real is False, dmiax_imag.is_real assert dmiax_imag.is_complex is True, dmiax_imag.is_complex assert dmiax_imag.is_polar is False, dmiax_imag.is_polar dmiax_real.raw_fields() dmiax_imag.raw_fields() str(dmiax_real) str(dmiax_imag) save_load_deck(model)