def exercise_debye_waller(): ucell = uctbx.unit_cell((5,7,9,80,100,130)) assert abs(adptbx.debye_waller_factor_u_iso(ucell.d_star_sq((7,8,9))/4,0.025) - 0.006625427) < 1.e-6 assert abs(adptbx.debye_waller_factor_u_iso(ucell, (7, 8, 9), 0.025) - 0.006625427) < 1.e-6 u = (0.1, 0.2, 0.3, -0.04, 0.05, -0.06) assert abs(adptbx.debye_waller_factor_u_cif(ucell, (1, 2, 3), u) - 0.335822877927) < 1.e-6 # u_star=(0.000002, 0.000001, 0.000003, 0.0000005, 0.0000004, 0.0000006) assert approx_equal( adptbx.debye_waller_factor_u_star_gradient_coefficients(h=(5,2,-1)), [25, 4, 1, 20, -10, -4]) g = adptbx.debye_waller_factor_u_star_gradients(h=(5,2,-1), u_star=u_star) assert approx_equal(g*1.e-3, [-0.49289027387879081, -0.078862443820606531, -0.019715610955151633, -0.39431221910303266, 0.19715610955151633, 0.078862443820606531]) assert approx_equal( adptbx.debye_waller_factor_u_star_curvature_coefficients(h=(5,2,-1)), [625,100,25,500,-250,-100, 16,4,80,-40,-16, 1,20,-10,-4, 400,-200,-80, 100,40, 16]) c = adptbx.debye_waller_factor_u_star_curvatures(h=(5,2,-1), u_star=u_star) assert approx_equal(c*1.e-6, [0.24323160081641265, 0.038917056130626029, 0.0097292640326565073, 0.1945852806531301, -0.097292640326565052, -0.038917056130626029, 0.006226728980900164, 0.001556682245225041, 0.031133644904500817, -0.015566822452250408, -0.006226728980900164, 0.00038917056130626025, 0.0077834112261252041, -0.0038917056130626021, -0.001556682245225041, 0.15566822452250412, -0.077834112261252059, -0.031133644904500817, 0.038917056130626029, 0.015566822452250408, 0.006226728980900164])
def exercise_debye_waller(): ucell = uctbx.unit_cell((5, 7, 9, 80, 100, 130)) assert abs(adptbx.debye_waller_factor_u_iso(ucell.d_star_sq((7, 8, 9)) / 4, 0.025) - 0.006625427) < 1.0e-6 assert abs(adptbx.debye_waller_factor_u_iso(ucell, (7, 8, 9), 0.025) - 0.006625427) < 1.0e-6 u = (0.1, 0.2, 0.3, -0.04, 0.05, -0.06) assert abs(adptbx.debye_waller_factor_u_cif(ucell, (1, 2, 3), u) - 0.335822877927) < 1.0e-6 # u_star = (0.000002, 0.000001, 0.000003, 0.0000005, 0.0000004, 0.0000006) assert approx_equal(adptbx.debye_waller_factor_u_star_gradient_coefficients(h=(5, 2, -1)), [25, 4, 1, 20, -10, -4]) g = adptbx.debye_waller_factor_u_star_gradients(h=(5, 2, -1), u_star=u_star) assert approx_equal( g * 1.0e-3, [ -0.49289027387879081, -0.078862443820606531, -0.019715610955151633, -0.39431221910303266, 0.19715610955151633, 0.078862443820606531, ], ) assert approx_equal( adptbx.debye_waller_factor_u_star_curvature_coefficients(h=(5, 2, -1)), [625, 100, 25, 500, -250, -100, 16, 4, 80, -40, -16, 1, 20, -10, -4, 400, -200, -80, 100, 40, 16], ) c = adptbx.debye_waller_factor_u_star_curvatures(h=(5, 2, -1), u_star=u_star) assert approx_equal( c * 1.0e-6, [ 0.24323160081641265, 0.038917056130626029, 0.0097292640326565073, 0.1945852806531301, -0.097292640326565052, -0.038917056130626029, 0.006226728980900164, 0.001556682245225041, 0.031133644904500817, -0.015566822452250408, -0.006226728980900164, 0.00038917056130626025, 0.0077834112261252041, -0.0038917056130626021, -0.001556682245225041, 0.15566822452250412, -0.077834112261252059, -0.031133644904500817, 0.038917056130626029, 0.015566822452250408, 0.006226728980900164, ], )
def exercise_interface(): episq = 8*(math.pi**2) assert approx_equal(adptbx.u_as_b(2.3), 2.3*episq) assert approx_equal(adptbx.b_as_u(adptbx.u_as_b(2.3)), 2.3) u = (3,4,9, 2,1,7) assert approx_equal(adptbx.u_as_b(u), [x*episq for x in u]) assert approx_equal(adptbx.b_as_u(adptbx.u_as_b(u)), u) uc = uctbx.unit_cell((5,4,7,80,110,100)) for fw,bw in ((adptbx.u_cif_as_u_star, adptbx.u_star_as_u_cif), (adptbx.u_cart_as_u_star, adptbx.u_star_as_u_cart), (adptbx.u_cart_as_u_cif, adptbx.u_cif_as_u_cart), (adptbx.u_cart_as_beta, adptbx.beta_as_u_cart), (adptbx.u_cif_as_beta, adptbx.beta_as_u_cif)): assert approx_equal(bw(uc, fw(uc, u)), u) assert approx_equal(adptbx.beta_as_u_star(adptbx.u_star_as_beta(u)), u) assert approx_equal(adptbx.u_cart_as_u_iso(adptbx.u_iso_as_u_cart(2.3)), 2.3) for fw,bw in ((adptbx.u_iso_as_u_star, adptbx.u_star_as_u_iso), (adptbx.u_iso_as_u_cif, adptbx.u_cif_as_u_iso), (adptbx.u_iso_as_beta, adptbx.beta_as_u_iso)): assert approx_equal(bw(uc, fw(uc, 2.3)), 2.3) fc = adptbx.factor_u_cart_u_iso(u_cart=u) assert approx_equal(fc.u_iso, adptbx.u_cart_as_u_iso(u)) assert approx_equal( fc.u_cart_minus_u_iso, [uii-fc.u_iso for uii in u[:3]]+list(u[3:])) f = adptbx.factor_u_star_u_iso( unit_cell=uc, u_star=adptbx.u_cart_as_u_star(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal( f.u_star_minus_u_iso, adptbx.u_cart_as_u_star(uc, fc.u_cart_minus_u_iso)) f = adptbx.factor_u_cif_u_iso( unit_cell=uc, u_cif=adptbx.u_cart_as_u_cif(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal( f.u_cif_minus_u_iso, adptbx.u_cart_as_u_cif(uc, fc.u_cart_minus_u_iso)) f = adptbx.factor_beta_u_iso( unit_cell=uc, beta=adptbx.u_cart_as_beta(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal( f.beta_minus_u_iso, adptbx.u_cart_as_beta(uc, fc.u_cart_minus_u_iso)) assert approx_equal(adptbx.debye_waller_factor_b_iso(0.25,2.3), math.exp(-2.3*0.25)) assert approx_equal(adptbx.debye_waller_factor_u_iso(0.25,2.3), math.exp(-2.3*episq*0.25)) assert approx_equal(adptbx.debye_waller_factor_b_iso(uc, (1,2,3), 2.3), adptbx.debye_waller_factor_u_iso(uc, (1,2,3), 2.3/episq)) u_star = adptbx.u_cart_as_u_star(uc, u) dw = adptbx.debye_waller_factor_u_star((1,2,3), u_star) assert approx_equal(dw, adptbx.debye_waller_factor_beta((1,2,3), adptbx.u_star_as_beta(u_star))) assert approx_equal(dw, adptbx.debye_waller_factor_u_cif(uc, (1,2,3), adptbx.u_star_as_u_cif(uc, u_star))) assert approx_equal(dw, adptbx.debye_waller_factor_u_cart(uc, (1,2,3), adptbx.u_star_as_u_cart(uc, u_star))) for e in adptbx.eigenvalues(u): check_eigenvalue(u, e) assert not adptbx.is_positive_definite(adptbx.eigenvalues(u)) assert not adptbx.is_positive_definite(adptbx.eigenvalues(u), 0) assert adptbx.is_positive_definite(adptbx.eigenvalues(u), 1.22) assert not adptbx.is_positive_definite(u) assert not adptbx.is_positive_definite(u, 0) assert adptbx.is_positive_definite(u, 1.22) up = (0.534, 0.812, 0.613, 0.0166, 0.134, -0.0124) s = adptbx.eigensystem(up) assert approx_equal(s.values(), (0.813132, 0.713201, 0.432668)) for i in xrange(3): check_eigenvector(up, s.values()[i], s.vectors(i)) c = (1,2,3, 3,-4,5, 4,5,6) v = (198,18,1020,116,447,269) assert approx_equal(adptbx.c_u_c_transpose(c, u), v) assert approx_equal(adptbx.eigensystem(u).values(), (14.279201519086316, 2.9369143826320214, -1.2161159017183376)) s = adptbx.eigensystem(up) try: s.vectors(4) except RuntimeError, e: assert str(e).endswith("Index out of range.") else: raise Exception_expected uf = adptbx.eigenvalue_filtering(u_cart=u, u_min=0) assert approx_equal(uf, (3.0810418, 4.7950710, 9.3400030, 1.7461615, 1.1659954, 6.4800706)) uf = adptbx.eigenvalue_filtering(u_cart=u, u_min=0, u_max=3) assert approx_equal(uf, (2.7430890, 1.0378360, 2.1559895, 0.6193215, -0.3921632, 1.2846854)) uf = adptbx.eigenvalue_filtering(u_cart=u, u_min=0, u_max=3) assert approx_equal(scitbx.linalg.eigensystem.real_symmetric(u).values(), (14.2792015, 2.9369144, -1.2161159)) assert approx_equal(scitbx.linalg.eigensystem.real_symmetric(uf).values(), (3, 2.9369144, 0)) uf = adptbx.eigenvalue_filtering(up) assert approx_equal(uf, up)
def exercise_interface(): episq = 8 * (math.pi**2) assert approx_equal(adptbx.u_as_b(2.3), 2.3 * episq) assert approx_equal(adptbx.b_as_u(adptbx.u_as_b(2.3)), 2.3) u = (3, 4, 9, 2, 1, 7) assert approx_equal(adptbx.u_as_b(u), [x * episq for x in u]) assert approx_equal(adptbx.b_as_u(adptbx.u_as_b(u)), u) uc = uctbx.unit_cell((5, 4, 7, 80, 110, 100)) for fw, bw in ((adptbx.u_cif_as_u_star, adptbx.u_star_as_u_cif), (adptbx.u_cart_as_u_star, adptbx.u_star_as_u_cart), (adptbx.u_cart_as_u_cif, adptbx.u_cif_as_u_cart), (adptbx.u_cart_as_beta, adptbx.beta_as_u_cart), (adptbx.u_cif_as_beta, adptbx.beta_as_u_cif)): assert approx_equal(bw(uc, fw(uc, u)), u) assert approx_equal(adptbx.beta_as_u_star(adptbx.u_star_as_beta(u)), u) assert approx_equal(adptbx.u_cart_as_u_iso(adptbx.u_iso_as_u_cart(2.3)), 2.3) for fw, bw in ((adptbx.u_iso_as_u_star, adptbx.u_star_as_u_iso), (adptbx.u_iso_as_u_cif, adptbx.u_cif_as_u_iso), (adptbx.u_iso_as_beta, adptbx.beta_as_u_iso)): assert approx_equal(bw(uc, fw(uc, 2.3)), 2.3) fc = adptbx.factor_u_cart_u_iso(u_cart=u) assert approx_equal(fc.u_iso, adptbx.u_cart_as_u_iso(u)) assert approx_equal(fc.u_cart_minus_u_iso, [uii - fc.u_iso for uii in u[:3]] + list(u[3:])) f = adptbx.factor_u_star_u_iso(unit_cell=uc, u_star=adptbx.u_cart_as_u_star(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal(f.u_star_minus_u_iso, adptbx.u_cart_as_u_star(uc, fc.u_cart_minus_u_iso)) f = adptbx.factor_u_cif_u_iso(unit_cell=uc, u_cif=adptbx.u_cart_as_u_cif(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal(f.u_cif_minus_u_iso, adptbx.u_cart_as_u_cif(uc, fc.u_cart_minus_u_iso)) f = adptbx.factor_beta_u_iso(unit_cell=uc, beta=adptbx.u_cart_as_beta(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal(f.beta_minus_u_iso, adptbx.u_cart_as_beta(uc, fc.u_cart_minus_u_iso)) assert approx_equal(adptbx.debye_waller_factor_b_iso(0.25, 2.3), math.exp(-2.3 * 0.25)) assert approx_equal(adptbx.debye_waller_factor_u_iso(0.25, 2.3), math.exp(-2.3 * episq * 0.25)) assert approx_equal( adptbx.debye_waller_factor_b_iso(uc, (1, 2, 3), 2.3), adptbx.debye_waller_factor_u_iso(uc, (1, 2, 3), 2.3 / episq)) u_star = adptbx.u_cart_as_u_star(uc, u) dw = adptbx.debye_waller_factor_u_star((1, 2, 3), u_star) assert approx_equal( dw, adptbx.debye_waller_factor_beta((1, 2, 3), adptbx.u_star_as_beta(u_star))) assert approx_equal( dw, adptbx.debye_waller_factor_u_cif(uc, (1, 2, 3), adptbx.u_star_as_u_cif(uc, u_star))) assert approx_equal( dw, adptbx.debye_waller_factor_u_cart(uc, (1, 2, 3), adptbx.u_star_as_u_cart(uc, u_star))) for e in adptbx.eigenvalues(u): check_eigenvalue(u, e) assert not adptbx.is_positive_definite(adptbx.eigenvalues(u)) assert not adptbx.is_positive_definite(adptbx.eigenvalues(u), 0) assert adptbx.is_positive_definite(adptbx.eigenvalues(u), 1.22) assert not adptbx.is_positive_definite(u) assert not adptbx.is_positive_definite(u, 0) assert adptbx.is_positive_definite(u, 1.22) up = (0.534, 0.812, 0.613, 0.0166, 0.134, -0.0124) s = adptbx.eigensystem(up) assert approx_equal(s.values(), (0.813132, 0.713201, 0.432668)) for i in xrange(3): check_eigenvector(up, s.values()[i], s.vectors(i)) c = (1, 2, 3, 3, -4, 5, 4, 5, 6) v = (198, 18, 1020, 116, 447, 269) assert approx_equal(adptbx.c_u_c_transpose(c, u), v) assert approx_equal( adptbx.eigensystem(u).values(), (14.279201519086316, 2.9369143826320214, -1.2161159017183376)) s = adptbx.eigensystem(up) try: s.vectors(4) except RuntimeError, e: assert str(e).endswith("Index out of range.")
def exercise_interface(): episq = 8 * (math.pi ** 2) assert approx_equal(adptbx.u_as_b(2.3), 2.3 * episq) assert approx_equal(adptbx.b_as_u(adptbx.u_as_b(2.3)), 2.3) u = (3, 4, 9, 2, 1, 7) assert approx_equal(adptbx.u_as_b(u), [x * episq for x in u]) assert approx_equal(adptbx.b_as_u(adptbx.u_as_b(u)), u) uc = uctbx.unit_cell((5, 4, 7, 80, 110, 100)) for fw, bw in ( (adptbx.u_cif_as_u_star, adptbx.u_star_as_u_cif), (adptbx.u_cart_as_u_star, adptbx.u_star_as_u_cart), (adptbx.u_cart_as_u_cif, adptbx.u_cif_as_u_cart), (adptbx.u_cart_as_beta, adptbx.beta_as_u_cart), (adptbx.u_cif_as_beta, adptbx.beta_as_u_cif), ): assert approx_equal(bw(uc, fw(uc, u)), u) assert approx_equal(adptbx.beta_as_u_star(adptbx.u_star_as_beta(u)), u) assert approx_equal(adptbx.u_cart_as_u_iso(adptbx.u_iso_as_u_cart(2.3)), 2.3) for fw, bw in ( (adptbx.u_iso_as_u_star, adptbx.u_star_as_u_iso), (adptbx.u_iso_as_u_cif, adptbx.u_cif_as_u_iso), (adptbx.u_iso_as_beta, adptbx.beta_as_u_iso), ): assert approx_equal(bw(uc, fw(uc, 2.3)), 2.3) fc = adptbx.factor_u_cart_u_iso(u_cart=u) assert approx_equal(fc.u_iso, adptbx.u_cart_as_u_iso(u)) assert approx_equal(fc.u_cart_minus_u_iso, [uii - fc.u_iso for uii in u[:3]] + list(u[3:])) f = adptbx.factor_u_star_u_iso(unit_cell=uc, u_star=adptbx.u_cart_as_u_star(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal(f.u_star_minus_u_iso, adptbx.u_cart_as_u_star(uc, fc.u_cart_minus_u_iso)) f = adptbx.factor_u_cif_u_iso(unit_cell=uc, u_cif=adptbx.u_cart_as_u_cif(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal(f.u_cif_minus_u_iso, adptbx.u_cart_as_u_cif(uc, fc.u_cart_minus_u_iso)) f = adptbx.factor_beta_u_iso(unit_cell=uc, beta=adptbx.u_cart_as_beta(uc, u)) assert approx_equal(f.u_iso, fc.u_iso) assert approx_equal(f.beta_minus_u_iso, adptbx.u_cart_as_beta(uc, fc.u_cart_minus_u_iso)) assert approx_equal(adptbx.debye_waller_factor_b_iso(0.25, 2.3), math.exp(-2.3 * 0.25)) assert approx_equal(adptbx.debye_waller_factor_u_iso(0.25, 2.3), math.exp(-2.3 * episq * 0.25)) assert approx_equal( adptbx.debye_waller_factor_b_iso(uc, (1, 2, 3), 2.3), adptbx.debye_waller_factor_u_iso(uc, (1, 2, 3), 2.3 / episq), ) u_star = adptbx.u_cart_as_u_star(uc, u) dw = adptbx.debye_waller_factor_u_star((1, 2, 3), u_star) assert approx_equal(dw, adptbx.debye_waller_factor_beta((1, 2, 3), adptbx.u_star_as_beta(u_star))) assert approx_equal(dw, adptbx.debye_waller_factor_u_cif(uc, (1, 2, 3), adptbx.u_star_as_u_cif(uc, u_star))) assert approx_equal(dw, adptbx.debye_waller_factor_u_cart(uc, (1, 2, 3), adptbx.u_star_as_u_cart(uc, u_star))) for e in adptbx.eigenvalues(u): check_eigenvalue(u, e) assert not adptbx.is_positive_definite(adptbx.eigenvalues(u)) assert not adptbx.is_positive_definite(adptbx.eigenvalues(u), 0) assert adptbx.is_positive_definite(adptbx.eigenvalues(u), 1.22) assert not adptbx.is_positive_definite(u) assert not adptbx.is_positive_definite(u, 0) assert adptbx.is_positive_definite(u, 1.22) up = (0.534, 0.812, 0.613, 0.0166, 0.134, -0.0124) s = adptbx.eigensystem(up) assert approx_equal(s.values(), (0.813132, 0.713201, 0.432668)) for i in xrange(3): check_eigenvector(up, s.values()[i], s.vectors(i)) c = (1, 2, 3, 3, -4, 5, 4, 5, 6) v = (198, 18, 1020, 116, 447, 269) assert approx_equal(adptbx.c_u_c_transpose(c, u), v) assert approx_equal(adptbx.eigensystem(u).values(), (14.279201519086316, 2.9369143826320214, -1.2161159017183376)) s = adptbx.eigensystem(up) try: s.vectors(4) except RuntimeError, e: assert str(e).endswith("Index out of range.")