def test_check_ab(capsys):
# This is another way how check_ab could have been done: hard-coded.
# We use it here to check the output of check_ab.
iab = [
11, 12, 13, 14, 15, 16, 21, 22, 23, 24, 25, 26, 31, 32, 33, 34, 35, 36,
41, 42, 43, 44, 45, 46, 51, 52, 53, 54, 55, 56, 61, 62, 63, 64, 65, 66
]
oab = [
11, 12, 13, 14, 15, 16, 21, 22, 23, 24, 25, 26, 31, 32, 33, 34, 35, 36,
14, 24, 34, 11, 12, 13, 15, 25, 35, 21, 22, 23, 16, 26, 36, 31, 32, 33
]
omsrc = np.array([[
False,
] * 3 + [
True,
] * 3] * 6).ravel()
omrec = [
False,
] * 18 + [
True,
] * 18
for i, val in enumerate(iab):
ab, msrc, mrec = utils.check_ab(val, 0)
assert ab == oab[i]
assert msrc == omsrc[i]
assert mrec == omrec[i]
utils.check_ab(36, 3)
out, _ = capsys.readouterr()
outstr = " Input ab : 36\n\n> <ab> IS 36 WHICH IS ZERO; "
assert out == outstr + "returning\n"
utils.check_ab(44, 3)
out, _ = capsys.readouterr()
outstr = " Input ab : 44\n Calculated ab : 11\n"
assert out == outstr
# Check it raises a ValueError if a non-existing ab is provided.
with pytest.raises(ValueError):
utils.check_ab(77, 0)
# We just check one other thing here, that it fails with a TypeError if a
# list instead of one value is provided. Generally the try/except statement
# with int() should take proper care of all the checking right in check_ab.
with pytest.raises(TypeError):
utils.check_ab([
12,
], 0)
Bx = dx * (np.tile(g_x, maxint) + 1) + np.repeat(xint[:-1], nquad)
SS = np.sin(Bx) * np.tile(g_w, maxint)
tEM_iint = iuSpline(np.log(2 * np.pi * freq), fEM.imag)
sEM = tEM_iint(np.log(Bx / t[:, None])) * SS
fqwe0['sEM'] = sEM
fqwe0['intervals'] = intervals
# # G -- QWE - HQWE # #
# Model
model = utils.check_model([], 10, 2, 2, 5, 1, 10, True, 0)
depth, res, aniso, epermH, epermV, mpermH, mpermV, isfullspace = model
frequency = utils.check_frequency(1, res, aniso, epermH, epermV, mpermH,
mpermV, 0)
freq, etaH, etaV, zetaH, zetaV = frequency
src, nsrc = utils.check_dipole([0, 0, 0], 'src', 0)
ab, msrc, mrec = utils.check_ab(11, 0)
ht, htarg = utils.check_hankel('qwe', None, 0)
rec = [np.arange(1, 11) * 500, np.zeros(10), 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
# Frequency-domain result
freqres = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH, zetaV,
ab, msrc, mrec)
# The following is a condensed version of transform.hqwe
etaH = etaH[0, :]
etaV = etaV[0, :]
zetaH = zetaH[0, :]
zetaV = zetaV[0, :]
rtol, atol, nquad, maxint, pts_per_dec, diff_quad, a, b, limit = htarg
def test_dlf(): # 10. dlf
# DLF is integral of hankel_dlf and fourier_dlf, and therefore tested a lot
# through those. Here we just ensure status quo. And if a problem arises in
# hankel_dlf or fourier_dlf, it would make it obvious if the problem arises
# from dlf or not.
# Check DLF for Fourier
t = DATA['t'][()]
for i in [0, 1, 2]:
dat = DATA['fourier_dlf' + str(i)][()]
tres = DATA['tEM' + str(i)][()]
finp = dat['fEM']
ftarg = dat['ftarg']
if i > 0:
finp /= 2j * np.pi * dat['f']
if i > 1:
finp *= -1
if ftarg['pts_per_dec'] == 0:
finp = finp.reshape(t.size, -1)
tEM = transform.dlf(finp,
2 * np.pi * dat['f'],
t,
ftarg['dlf'],
ftarg['pts_per_dec'],
kind=ftarg['kind'])
assert_allclose(tEM * 2 / np.pi, tres, rtol=1e-3)
# Check DLF for Hankel
for ab in [12, 22, 13, 33]:
model = utils.check_model([], 10, 2, 2, 5, 1, 10, True, 0)
depth, res, aniso, epermH, epermV, mpermH, mpermV, _ = model
frequency = utils.check_frequency(1, res, aniso, epermH, epermV,
mpermH, mpermV, 0)
_, etaH, etaV, zetaH, zetaV = frequency
src = [0, 0, 0]
src, nsrc = utils.check_dipole(src, 'src', 0)
ab, msrc, mrec = utils.check_ab(ab, 0)
ht, htarg = utils.check_hankel('dlf', {}, 0)
xdirect = False # Important, as we want to comp. wavenumber-frequency!
rec = [np.arange(1, 11) * 500, np.zeros(10), 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
dlf = htarg['dlf']
pts_per_dec = htarg['pts_per_dec']
# # # 0. No Spline # # #
# dlf calculation
lambd = dlf.base / off[:, None]
PJ = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec)
# Angle factor, one example with None instead of 1's.
if ab != 13:
ang_fact = kernel.angle_factor(angle, ab, msrc, mrec)
else:
ang_fact = None
# dlf calculation
fEM0 = transform.dlf(PJ, lambd, off, dlf, 0, ang_fact=ang_fact, ab=ab)
# Analytical frequency-domain solution
freq1 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(np.squeeze(fEM0), np.squeeze(freq1))
# # # 1. Spline; One angle # # #
# dlf calculation
lambd, _ = transform.get_dlf_points(dlf, off, pts_per_dec)
PJ1 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec)
# dlf calculation
fEM1 = transform.dlf(PJ1,
lambd,
off,
dlf,
pts_per_dec,
ang_fact=ang_fact,
ab=ab)
# Compare
assert_allclose(np.squeeze(fEM1), np.squeeze(freq1), rtol=1e-4)
# # # 2.a Lagged; One angle # # #
rec = [np.arange(1, 11) * 500, np.arange(-5, 5) * 0, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
# dlf calculation
lambd, _ = transform.get_dlf_points(dlf, off, -1)
PJ2 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec)
ang_fact = kernel.angle_factor(angle, ab, msrc, mrec)
# dlf calculation
fEM2 = transform.dlf(PJ2,
lambd,
off,
dlf,
-1,
ang_fact=ang_fact,
ab=ab)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(np.squeeze(fEM2), np.squeeze(freq2), rtol=1e-4)
# # # 2.b Lagged; Multi angle # # #
rec = [np.arange(1, 11) * 500, np.arange(-5, 5) * 200, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
# dlf calculation
lambd, _ = transform.get_dlf_points(dlf, off, -1)
PJ2 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec)
ang_fact = kernel.angle_factor(angle, ab, msrc, mrec)
# dlf calculation
fEM2 = transform.dlf(PJ2,
lambd,
off,
dlf,
-1,
ang_fact=ang_fact,
ab=ab)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(np.squeeze(fEM2), np.squeeze(freq2), rtol=1e-4)
# # # 3. Spline; Multi angle # # #
lambd, _ = transform.get_dlf_points(dlf, off, 30)
# dlf calculation
PJ3 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec)
# dlf calculation
fEM3 = transform.dlf(PJ3,
lambd,
off,
dlf,
30,
ang_fact=ang_fact,
ab=ab)
# Compare
assert_allclose(np.squeeze(fEM3), np.squeeze(freq2), rtol=1e-3)
def test_hankel(htype): # 1. DLF / 2. QWE / 3. QUAD
# Compare wavenumber-domain calculation / DLF with analytical
# frequency-domain fullspace solution
calc = getattr(transform, 'hankel_' + htype)
model = utils.check_model([], 10, 2, 2, 5, 1, 10, True, 0)
depth, res, aniso, epermH, epermV, mpermH, mpermV, _ = model
frequency = utils.check_frequency(1, res, aniso, epermH, epermV, mpermH,
mpermV, 0)
_, etaH, etaV, zetaH, zetaV = frequency
src = [0, 0, 0]
src, nsrc = utils.check_dipole(src, 'src', 0)
for ab_inp in [11, 12, 13, 33]:
ab, msrc, mrec = utils.check_ab(ab_inp, 0)
_, htarg = utils.check_hankel(htype, {}, 0)
xdirect = False # Important, as we want to compare wavenr-frequency!
rec = [np.arange(1, 11) * 500, np.zeros(10), 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
ang_fact = kernel.angle_factor(angle, ab, msrc, mrec)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
# # # 0. No Spline # # #
if htype != 'quad': # quad is always using spline
# Wavenumber solution plus transform
# Adjust htarg for dlf
if htype == 'dlf':
lambd, int_pts = transform.get_dlf_points(
htarg['dlf'], off, htarg['pts_per_dec'])
htarg['lambd'] = lambd
htarg['int_pts'] = int_pts
wvnr0, _, conv = calc(zsrc, zrec, lsrc, lrec, off, ang_fact, depth,
ab, etaH, etaV, zetaH, zetaV, xdirect, htarg,
msrc, mrec)
# Analytical frequency-domain solution
freq0 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr0), np.squeeze(freq0))
# # # 1. Spline; One angle # # #
_, htarg = utils.check_hankel(htype, {'pts_per_dec': 80}, 0)
if htype == 'quad': # Lower atol to ensure convergence
_, htarg = utils.check_hankel('quad', {'rtol': 1e-8}, 0)
elif htype == 'dlf': # Adjust htarg for dlf
lambd, int_pts = transform.get_dlf_points(htarg['dlf'], off,
htarg['pts_per_dec'])
htarg['lambd'] = lambd
htarg['int_pts'] = int_pts
# Wavenumber solution plus transform
wvnr1, _, conv = calc(zsrc, zrec, lsrc, lrec, off, ang_fact, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, msrc,
mrec)
# Analytical frequency-domain solution
freq1 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
if htype == 'qwe' and ab in [13, 33]:
assert_allclose(conv, False)
else:
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr1), np.squeeze(freq1), rtol=1e-4)
# # # 2. Spline; Multi angle # # #
rec = [np.arange(1, 11) * 500, np.arange(-5, 5) * 200, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
ang_fact = kernel.angle_factor(angle, ab, msrc, mrec)
if htype == 'qwe': # Put a very low diff_quad, to test it.; lower err
_, htarg = utils.check_hankel(
'qwe', {
'rtol': 1e-8,
'maxint': 200,
'pts_per_dec': 80,
'diff_quad': .1,
'a': 1e-6,
'b': .1,
'limit': 1000
}, 0)
elif htype == 'dlf': # Adjust htarg for dlf
lambd, int_pts = transform.get_dlf_points(htarg['dlf'], off,
htarg['pts_per_dec'])
htarg['lambd'] = lambd
htarg['int_pts'] = int_pts
# Analytical frequency-domain solution
wvnr2, _, conv = calc(zsrc, zrec, lsrc, lrec, off, ang_fact, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, msrc,
mrec)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr2), np.squeeze(freq2), rtol=1e-4)
# # # 3. Spline; pts_per_dec # # #
if htype == 'dlf':
_, htarg = utils.check_hankel('dlf', {
'dlf': 'key_201_2012',
'pts_per_dec': 20
}, 0)
lambd, int_pts = transform.get_dlf_points(htarg['dlf'], off,
htarg['pts_per_dec'])
htarg['lambd'] = lambd
htarg['int_pts'] = int_pts
elif htype == 'qwe':
_, htarg = utils.check_hankel('qwe', {
'maxint': 80,
'pts_per_dec': 100
}, 0)
if htype != 'quad': # quad is always pts_per_dec
# Analytical frequency-domain solution
wvnr3, _, conv = calc(zsrc, zrec, lsrc, lrec, off, ang_fact, depth,
ab, etaH, etaV, zetaH, zetaV, xdirect, htarg,
msrc, mrec)
# Analytical frequency-domain solution
freq3 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr3), np.squeeze(freq3), rtol=1e-4)
# # # 4. Spline; Only one offset # # #
rec = [5000, 0, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
ang_fact = kernel.angle_factor(angle, ab, msrc, mrec)
if htype == 'qwe':
_, htarg = utils.check_hankel('qwe', {
'maxint': 200,
'pts_per_dec': 80
}, 0)
elif htype == 'quad':
_, htarg = utils.check_hankel('quad', {}, 0)
elif htype == 'dlf':
lambd, int_pts = transform.get_dlf_points(htarg['dlf'], off,
htarg['pts_per_dec'])
htarg['lambd'] = lambd
htarg['int_pts'] = int_pts
# Analytical frequency-domain solution
wvnr4, _, conv = calc(zsrc, zrec, lsrc, lrec, off, ang_fact, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, msrc,
mrec)
# Analytical frequency-domain solution
freq4 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr4), np.squeeze(freq4), rtol=1e-4)
def test_dlf(): # 10. dlf
# DLF is integral of fht and ffht, and therefore tested a lot through
# those. Here we just ensure status quo. And if a problem arises in fht or
# ffht, it would make it obvious if the problem arises from dlf or not.
# Check DLF for Fourier
t = DATA['t'][()]
for i in [0, 1, 2]:
dat = DATA['ffht' + str(i)][()]
tres = DATA['tEM' + str(i)][()]
finp = dat['fEM']
ftarg = dat['ftarg']
if i > 0:
finp /= 2j * np.pi * dat['f']
if i > 1:
finp *= -1
if ftarg[1] == 0:
finp = finp.reshape(t.size, -1)
tEM = transform.dlf(finp,
2 * np.pi * dat['f'],
t,
ftarg[0],
ftarg[1],
kind=ftarg[2])
assert_allclose(tEM * 2 / np.pi, tres, rtol=1e-3)
# Check DLF for Hankel
for ab in [12, 22, 13, 33]:
model = utils.check_model([], 10, 2, 2, 5, 1, 10, True, 0)
depth, res, aniso, epermH, epermV, mpermH, mpermV, isfullspace = model
frequency = utils.check_frequency(1, res, aniso, epermH, epermV,
mpermH, mpermV, 0)
freq, etaH, etaV, zetaH, zetaV = frequency
src = [0, 0, 0]
src, nsrc = utils.check_dipole(src, 'src', 0)
ab, msrc, mrec = utils.check_ab(ab, 0)
ht, htarg = utils.check_hankel('fht', None, 0)
options = utils.check_opt(None, None, ht, htarg, 0)
use_ne_eval, loop_freq, loop_off = options
xdirect = False # Important, as we want to comp. wavenumber-frequency!
rec = [np.arange(1, 11) * 500, np.zeros(10), 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
fhtfilt = htarg[0]
pts_per_dec = htarg[1]
# # # 0. No Spline # # #
# fht calculation
lambd = fhtfilt.base / off[:, None]
PJ = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec,
use_ne_eval)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
# dlf calculation
fEM0 = transform.dlf(PJ,
lambd,
off,
fhtfilt,
0,
factAng=factAng,
ab=ab)
# Analytical frequency-domain solution
freq1 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(np.squeeze(fEM0), np.squeeze(freq1))
# # # 1. Spline; One angle # # #
options = utils.check_opt('spline', None, ht, htarg, 0)
use_ne_eval, loop_freq, loop_off = options
# fht calculation
lambd, _ = transform.get_spline_values(fhtfilt, off, pts_per_dec)
PJ1 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec,
use_ne_eval)
# dlf calculation
fEM1 = transform.dlf(PJ1,
lambd,
off,
fhtfilt,
pts_per_dec,
factAng=factAng,
ab=ab)
# Compare
assert_allclose(np.squeeze(fEM1), np.squeeze(freq1), rtol=1e-4)
# # # 2.a Lagged; One angle # # #
rec = [np.arange(1, 11) * 500, np.arange(-5, 5) * 0, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
# fht calculation
lambd, _ = transform.get_spline_values(fhtfilt, off, -1)
PJ2 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec,
use_ne_eval)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
# dlf calculation
fEM2 = transform.dlf(PJ2,
lambd,
off,
fhtfilt,
-1,
factAng=factAng,
ab=ab)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(np.squeeze(fEM2), np.squeeze(freq2), rtol=1e-4)
# # # 2.b Lagged; Multi angle # # #
rec = [np.arange(1, 11) * 500, np.arange(-5, 5) * 200, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
# fht calculation
lambd, _ = transform.get_spline_values(fhtfilt, off, -1)
PJ2 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec,
use_ne_eval)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
# dlf calculation
fEM2 = transform.dlf(PJ2,
lambd,
off,
fhtfilt,
-1,
factAng=factAng,
ab=ab)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(np.squeeze(fEM2), np.squeeze(freq2), rtol=1e-4)
# # # 3. Spline; Multi angle # # #
lambd, _ = transform.get_spline_values(fhtfilt, off, 10)
# fht calculation
PJ3 = kernel.wavenumber(zsrc, zrec, lsrc, lrec, depth, etaH, etaV,
zetaH, zetaV, lambd, ab, xdirect, msrc, mrec,
use_ne_eval)
# dlf calculation
fEM3 = transform.dlf(PJ3,
lambd,
off,
fhtfilt,
10,
factAng=factAng,
ab=ab)
# Compare
assert_allclose(np.squeeze(fEM3), np.squeeze(freq2), rtol=1e-3)
def test_hankel(htype): # 1. fht / 2. hqwe / 3. hquad
# Compare wavenumber-domain calculation / FHT with analytical
# frequency-domain fullspace solution
calc = getattr(transform, htype)
model = utils.check_model([], 10, 2, 2, 5, 1, 10, True, 0)
depth, res, aniso, epermH, epermV, mpermH, mpermV, isfullspace = model
frequency = utils.check_frequency(1, res, aniso, epermH, epermV, mpermH,
mpermV, 0)
freq, etaH, etaV, zetaH, zetaV = frequency
src = [0, 0, 0]
src, nsrc = utils.check_dipole(src, 'src', 0)
ab, msrc, mrec = utils.check_ab(11, 0)
ht, htarg = utils.check_hankel(htype, None, 0)
options = utils.check_opt(None, None, htype, htarg, 0)
use_ne_eval, loop_freq, loop_off = options
xdirect = False # Important, as we want to compare wavenumber-frequency!
rec = [np.arange(1, 11) * 500, np.zeros(10), 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
# # # 0. No Spline # # #
if htype != 'hquad': # hquad is always using spline
# Wavenumber solution plus transform
wvnr0, _, conv = calc(zsrc, zrec, lsrc, lrec, off, angle, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, False,
msrc, mrec)
# Analytical frequency-domain solution
freq0 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr0), np.squeeze(freq0))
# # # 1. Spline; One angle # # #
htarg, opt = utils.spline_backwards_hankel(htype, None, 'spline')
ht, htarg = utils.check_hankel(htype, htarg, 0)
options = utils.check_opt(None, None, htype, htarg, 0)
use_ne_eval, loop_freq, loop_off = options
if htype == 'hquad': # Lower atol to ensure convergence
ht, htarg = utils.check_hankel('quad', [1e-8], 0)
# Wavenumber solution plus transform
wvnr1, _, conv = calc(zsrc, zrec, lsrc, lrec, off, angle, depth, ab, etaH,
etaV, zetaH, zetaV, xdirect, htarg, False, msrc,
mrec)
# Analytical frequency-domain solution
freq1 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH, zetaV,
ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr1), np.squeeze(freq1), rtol=1e-4)
# # # 2. Spline; Multi angle # # #
rec = [np.arange(1, 11) * 500, np.arange(-5, 5) * 200, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
if htype == 'hqwe': # Put a very low diff_quad, to test it.; lower err
ht, htarg = utils.check_hankel(
'qwe', [1e-8, '', '', 200, 80, .1, 1e-6, .1, 1000], 0)
# Analytical frequency-domain solution
wvnr2, _, conv = calc(zsrc, zrec, lsrc, lrec, off, angle, depth, ab, etaH,
etaV, zetaH, zetaV, xdirect, htarg, False, msrc,
mrec)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH, zetaV,
ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr2), np.squeeze(freq2), rtol=1e-4)
# # # 3. Spline; pts_per_dec # # #
if htype == 'fht':
ht, htarg = utils.check_hankel('fht', ['key_201_2012', 20], 0)
elif htype == 'hqwe':
ht, htarg = utils.check_hankel('qwe', ['', '', '', 80, 100], 0)
if htype != 'hquad': # hquad is always pts_per_dec
# Analytical frequency-domain solution
wvnr3, _, conv = calc(zsrc, zrec, lsrc, lrec, off, angle, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, False,
msrc, mrec)
# Analytical frequency-domain solution
freq3 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr3), np.squeeze(freq3), rtol=1e-4)
# # # 4. Spline; Only one offset # # #
rec = [5000, 0, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
if htype == 'hqwe':
ht, htarg = utils.check_hankel('qwe', ['', '', '', 200, 80], 0)
elif htype == 'hquad':
ht, htarg = utils.check_hankel('quad', None, 0)
# Analytical frequency-domain solution
wvnr4, _, conv = calc(zsrc, zrec, lsrc, lrec, off, angle, depth, ab, etaH,
etaV, zetaH, zetaV, xdirect, htarg, False, msrc,
mrec)
# Analytical frequency-domain solution
freq4 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH, zetaV,
ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr4), np.squeeze(freq4), rtol=1e-4)
def test_hankel(htype): # 1. fht / 2. hqwe / 3. hquad
# Compare wavenumber-domain calculation / FHT with analytical
# frequency-domain fullspace solution
calc = getattr(transform, htype)
model = utils.check_model([], 10, 2, 2, 5, 1, 10, True, 0)
depth, res, aniso, epermH, epermV, mpermH, mpermV, _ = model
frequency = utils.check_frequency(1, res, aniso, epermH, epermV, mpermH,
mpermV, 0)
_, etaH, etaV, zetaH, zetaV = frequency
src = [0, 0, 0]
src, nsrc = utils.check_dipole(src, 'src', 0)
for ab_inp in [11, 12, 13, 33]:
ab, msrc, mrec = utils.check_ab(ab_inp, 0)
_, htarg = utils.check_hankel(htype, None, 0)
xdirect = False # Important, as we want to compare wavenr-frequency!
rec = [np.arange(1, 11)*500, np.zeros(10), 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
# # # 0. No Spline # # #
if htype != 'hquad': # hquad is always using spline
# Wavenumber solution plus transform
# Adjust htarg for fht
if htype == 'fht':
lambd, int_pts = transform.get_spline_values(htarg[0], off,
htarg[1])
htarg = (htarg[0], htarg[1], lambd, int_pts)
wvnr0, _, conv = calc(zsrc, zrec, lsrc, lrec, off, factAng, depth,
ab, etaH, etaV, zetaH, zetaV, xdirect, htarg,
False, msrc, mrec)
# Analytical frequency-domain solution
freq0 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr0), np.squeeze(freq0))
# # # 1. Spline; One angle # # #
htarg, _ = utils.spline_backwards_hankel(htype, None, 'spline')
_, htarg = utils.check_hankel(htype, htarg, 0)
if htype == 'hquad': # Lower atol to ensure convergence
_, htarg = utils.check_hankel('quad', [1e-8], 0)
elif htype == 'fht': # Adjust htarg for fht
lambd, int_pts = transform.get_spline_values(htarg[0], off,
htarg[1])
htarg = (htarg[0], htarg[1], lambd, int_pts)
# Wavenumber solution plus transform
wvnr1, _, conv = calc(zsrc, zrec, lsrc, lrec, off, factAng, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, False,
msrc, mrec)
# Analytical frequency-domain solution
freq1 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
if htype == 'hqwe' and ab in [13, 33]:
assert_allclose(conv, False)
else:
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr1), np.squeeze(freq1), rtol=1e-4)
# # # 2. Spline; Multi angle # # #
rec = [np.arange(1, 11)*500, np.arange(-5, 5)*200, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
if htype == 'hqwe': # Put a very low diff_quad, to test it.; lower err
_, htarg = utils.check_hankel('qwe', [1e-8, '', '', 200, 80, .1,
1e-6, .1, 1000], 0)
elif htype == 'fht': # Adjust htarg for fht
lambd, int_pts = transform.get_spline_values(htarg[0], off,
htarg[1])
htarg = (htarg[0], htarg[1], lambd, int_pts)
# Analytical frequency-domain solution
wvnr2, _, conv = calc(zsrc, zrec, lsrc, lrec, off, factAng, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, False,
msrc, mrec)
# Analytical frequency-domain solution
freq2 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr2), np.squeeze(freq2), rtol=1e-4)
# # # 3. Spline; pts_per_dec # # #
if htype == 'fht':
_, htarg = utils.check_hankel('fht', ['key_201_2012', 20], 0)
lambd, int_pts = transform.get_spline_values(htarg[0], off,
htarg[1])
htarg = (htarg[0], htarg[1], lambd, int_pts)
elif htype == 'hqwe':
_, htarg = utils.check_hankel('qwe', ['', '', '', 80, 100], 0)
if htype != 'hquad': # hquad is always pts_per_dec
# Analytical frequency-domain solution
wvnr3, _, conv = calc(zsrc, zrec, lsrc, lrec, off, factAng, depth,
ab, etaH, etaV, zetaH, zetaV, xdirect, htarg,
False, msrc, mrec)
# Analytical frequency-domain solution
freq3 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr3), np.squeeze(freq3), rtol=1e-4)
# # # 4. Spline; Only one offset # # #
rec = [5000, 0, 300]
rec, nrec = utils.check_dipole(rec, 'rec', 0)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, 0)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
if htype == 'hqwe':
_, htarg = utils.check_hankel('qwe', ['', '', '', 200, 80], 0)
elif htype == 'hquad':
_, htarg = utils.check_hankel('quad', None, 0)
elif htype == 'fht':
lambd, int_pts = transform.get_spline_values(htarg[0], off,
htarg[1])
htarg = (htarg[0], htarg[1], lambd, int_pts)
# Analytical frequency-domain solution
wvnr4, _, conv = calc(zsrc, zrec, lsrc, lrec, off, factAng, depth, ab,
etaH, etaV, zetaH, zetaV, xdirect, htarg, False,
msrc, mrec)
# Analytical frequency-domain solution
freq4 = kernel.fullspace(off, angle, zsrc, zrec, etaH, etaV, zetaH,
zetaV, ab, msrc, mrec)
# Compare
assert_allclose(conv, True)
assert_allclose(np.squeeze(wvnr4), np.squeeze(freq4), rtol=1e-4)
def setup_cache(self):
"""setup_cache is not parametrized, so we do it manually. """
data = {}
for size in self.params[0]: # size
data[size] = {}
# One big, one small model
if size == 'Small': # Small; Total size: 5*1*1*1 = 5
x = np.array([500., 1000.])
else: # Big; Total size: 5*100*100*201 = 10'050'000
x = np.arange(1, 101)*200.
# Define model parameters
freq = np.array([1])
src = [0, 0, 250]
rec = [x, np.zeros(x.shape), 300]
depth = np.array([-np.infty, 0, 300, 2000, 2100])
res = np.array([2e14, .3, 1, 50, 1])
ab = 11
xdirect = False
verb = 0
if not VERSION2:
use_ne_eval = False
# Checks (since DLF exists the `utils`-checks haven't changed, so
# we just use them here.
model = utils.check_model(depth, res, None, None, None, None, None,
xdirect, verb)
depth, res, aniso, epermH, epermV, mpermH, mpermV, _ = model
frequency = utils.check_frequency(freq, res, aniso, epermH, epermV,
mpermH, mpermV, verb)
freq, etaH, etaV, zetaH, zetaV = frequency
ab, msrc, mrec = utils.check_ab(ab, verb)
src, nsrc = utils.check_dipole(src, 'src', verb)
rec, nrec = utils.check_dipole(rec, 'rec', verb)
off, angle = utils.get_off_ang(src, rec, nsrc, nrec, verb)
lsrc, zsrc = utils.get_layer_nr(src, depth)
lrec, zrec = utils.get_layer_nr(rec, depth)
for htype in self.params[1]: # htype
# pts_per_dec depending on htype
if htype == 'Standard':
pts_per_dec = 0
elif htype == 'Lagged':
pts_per_dec = -1
else:
pts_per_dec = 10
# Compute kernels for dlf
if VERSION2:
# HT arguments
_, fhtarg = utils.check_hankel(
'dlf',
{'dlf': 'key_201_2009',
'pts_per_dec': pts_per_dec},
0)
inp = (fhtarg['dlf'], off, fhtarg['pts_per_dec'])
lambd, _ = transform.get_dlf_points(*inp)
else:
# HT arguments
_, fhtarg = utils.check_hankel(
'fht', ['key_201_2009', pts_per_dec], 0)
inp = (fhtarg[0], off, fhtarg[1])
lambd, _ = transform.get_spline_values(*inp)
if VERSION2:
inp = (zsrc, zrec, lsrc, lrec, depth, etaH, etaV, zetaH,
zetaV, lambd, ab, xdirect, msrc, mrec)
else:
inp = (zsrc, zrec, lsrc, lrec, depth, etaH,
etaV, zetaH, zetaV, lambd, ab, xdirect,
msrc, mrec, use_ne_eval)
PJ = kernel.wavenumber(*inp)
factAng = kernel.angle_factor(angle, ab, msrc, mrec)
# Signature changed at commit a15af07 (20/05/2018; before
# v1.6.2)
try:
dlf = {'signal': PJ, 'points': lambd, 'out_pts': off,
'ab': ab}
if VERSION2:
dlf['ang_fact'] = factAng
dlf['filt'] = fhtarg['dlf']
dlf['pts_per_dec'] = fhtarg['pts_per_dec']
else:
dlf['factAng'] = factAng
dlf['filt'] = fhtarg[0]
dlf['pts_per_dec'] = fhtarg[1]
transform.dlf(**dlf)
except VariableCatch:
dlf = {'signal': PJ, 'points': lambd, 'out_pts': off,
'targ': fhtarg, 'factAng': factAng}
data[size][htype] = dlf
return data
