def test_empy_hankel():
# 1. Simple test to compare ['j0', 'j1'] with 'j0' and 'j1'
out1 = fdesign.empy_hankel(['j0', 'j1'], 50, 100, [2e14, 1], 1, 0)
out2 = fdesign.empy_hankel('j0', 50, 100, [2e14, 1], 1, 0)
out3 = fdesign.empy_hankel('j1', 50, 100, [2e14, 1], 1, 0)
assert out1[0].name == out2.name
assert out1[1].name == out3.name
# 2. Check J0, J1 with analytical, wavenumber
zsrc = -50
zrec = 0
r = np.arange(1, 101)
f = 100
model1 = {'res': 100,
'aniso': 2,
'epermH': 15,
'epermV': 30,
'mpermH': 1,
'mpermV': 5}
out4a = fdesign.empy_hankel(['j0', 'j1'], zsrc, zrec, freqtime=f, depth=[],
**model1)
out4b = model.analytical([0, 0, zsrc], [r/np.sqrt(2), r/np.sqrt(2), zrec],
freqtime=f, verb=0, **model1)
out4c = model.analytical([0, 0, zsrc], [r, r*0, zrec], freqtime=f, verb=0,
ab=31, **model1)
out4d, _ = model.dipole_k(src=[0, 0, zsrc],
rec=[1/np.sqrt(2), 1/np.sqrt(2), zrec],
freq=f, depth=[], wavenumber=1/r, **model1)
_, out4e = model.dipole_k(src=[0, 0, zsrc], ab=31, rec=[1, 0, zrec],
freq=f, depth=[], wavenumber=1/r, **model1)
assert_allclose(out4a[0].rhs(r), out4b)
assert_allclose(out4a[1].rhs(r), out4c)
assert_allclose(out4a[0].lhs(1/r), out4d)
assert_allclose(out4a[1].lhs(1/r), out4e)
# 2. Check J2 with dipole, wavenumber
zsrc = 950
zrec = 1000
r = np.arange(1, 101)*20
f = 0.1
model2 = {'depth': [0, 1000],
'res': [2e14, 0.3, 1],
'aniso': [1, 1, 1.5],
'epermH': [1, 15, 1],
'epermV': [1, 1, 30],
'mpermH': [1, 1, 10],
'mpermV': [1, 1, 5]}
out5a = fdesign.empy_hankel('j2', zsrc, zrec, freqtime=f, **model2)
out5b = model.dipole([0, 0, zsrc], [r/np.sqrt(2), r/np.sqrt(2), zrec],
freqtime=f, verb=0, ab=12, **model2)
out5c, out5d = model.dipole_k(src=[0, 0, zsrc],
rec=[1/np.sqrt(2), 1/np.sqrt(2), zrec],
ab=12, freq=f, wavenumber=1/r, **model2)
assert_allclose(out5a.rhs(r), out5b)
assert_allclose(out5a.lhs(1/r)[0], out5c)
assert_allclose(out5a.lhs(1/r)[1], out5d)
def test_dipole_k():
# This is like `frequency`, without the Hankel transform. We just run a
# test here, to check that it remains the status quo.
res = DATAEMPYMOD['wout'][()]
w_res0, w_res1 = dipole_k(**res['inp'])
assert_allclose(w_res0, res['PJ0'])
assert_allclose(w_res1, res['PJ1'])
# Check that ab=36 returns zeros
res['inp']['ab'] = 36
w_res0, w_res1 = dipole_k(**res['inp'])
assert_allclose(w_res0, np.zeros(res['PJ0'].shape, dtype=complex))
assert_allclose(w_res1, np.zeros(res['PJ1'].shape, dtype=complex))
def lhs(k):
lhs0, lhs1 = dipole_k(rec=[x, y, zrec], wavenumber=k, verb=verblhs,
freq=freqtime, **model)
if ftype == 'j0':
return lhs0
elif ftype == 'j1':
return lhs1
elif ftype == 'j2':
return (lhs0, lhs1)
winp = {
'src': [330, -200, 500],
'rec': [3000, 1000, 600],
'depth': [0, 550],
'res': [1e12, 5.55, 11],
'freq': 3.33,
'wavenumber': np.logspace(-3.6, -3.4, 10),
'ab': 25,
'aniso': [1, 2, 1.5],
'epermH': [1, 50, 10],
'epermV': [80, 20, 1],
'mpermH': [1, 20, 50],
'mpermV': [1, 30, 4],
'verb': 0
}
PJ0, PJ1 = dipole_k(**winp)
# # C -- FULLSPACE # #
# More or less random values, to test a wide range of models.
# src fixed at [0, 0, 0]; Never possible to test all combinations...
pab = [
11, 12, 13, 14, 15, 16, 21, 22, 23, 24, 25, 26, 31, 32, 33, 34, 35, 41, 42,
43, 44, 45, 46, 51, 52, 53, 54, 55, 56, 61, 62, 64, 65, 66
]
prec = [[100000, 0, 500], [10000, 0, 400], [1000, 0, 300], [100, 0, 100],
[10, 0, 10], [1, 0, 1], [1, 0, -1], [10, 0, -10], [100, 0, -100],
[1000, 0, -300], [10000, 0, -400], [100000, 100, -500], [0, 100000, 0],
[0, 10000, 0], [0, 1000, 500], [0, 100, 0], [10, 10, 0], [0, 1, 0],
[0, 1, 0], [0, 10, 0], [0, 100, 500], [100, 1000, 300], [0, 10000, 0],
[0, 100000, 0], [-1, 0, 0], [-10, 0, 500], [-100, 100, 300],
[-1000, 0, 0], [0, -1, 0], [0, -10, 0], [-100, -100, -500],
