https://github.com/GeoscienceAustralia/PyRate
Tip revision: 3579612cbfec20e43cb2c7b8311c50851ae4fc4a authored by S M T Chua on 25 February 2022, 04:08:37 UTC
Merge pull request #380 from GeoscienceAustralia/develop
Merge pull request #380 from GeoscienceAustralia/develop
Tip revision: 3579612
test_orbital.py
# This Python module is part of the PyRate software package.
#
# Copyright 2022 Geoscience Australia
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
This Python module contains tests for the orbital.py PyRate module.
"""
import os
import shutil
import tempfile
import pytest
from itertools import product
from numpy import empty, dot, concatenate, float32
from numpy import nan, isnan, array
from os.path import join
from pathlib import Path
from datetime import date
import numpy as np
from numpy.linalg import pinv, inv
from numpy.testing import assert_array_equal, assert_array_almost_equal, assert_allclose
from scipy.linalg import lstsq
from osgeo import gdal, gdalconst
import pyrate.constants as C
import pyrate.core.orbital
from tests.common import small5_mock_ifgs, MockIfg
from pyrate.core.algorithm import first_second_ids, get_all_epochs
from pyrate.core.orbital import INDEPENDENT_METHOD, NETWORK_METHOD, PLANAR, \
QUADRATIC, PART_CUBIC
from pyrate.core.orbital import OrbitalError, __orb_correction, __orb_inversion
from pyrate.core.orbital import get_design_matrix, get_network_design_matrix, orb_fit_calc_wrapper
from pyrate.core.orbital import _get_num_params, remove_orbital_error, network_orbital_correction
from pyrate.core.orbital import calc_network_orb_correction
from pyrate.core.shared import Ifg, mkdir_p
from pyrate.core.shared import nanmedian
from pyrate.core import roipac
from pyrate import correct, conv2tif, prepifg
from pyrate.configuration import Configuration, MultiplePaths
from pyrate.constants import ORB_ERROR_DIR
from tests import common
from tests.common import IFMS16, TEST_CONF_GAMMA
from tests.common import SML_TEST_LEGACY_ORBITAL_DIR
from tests.common import SML_TEST_TIF, PY37GDAL302
from tests.common import small_ifg_file_list
# TODO: Purpose of this variable? Degrees are 1, 2 and 3 respectively
DEG_LOOKUP = {
2: PLANAR,
5: QUADRATIC,
6: PART_CUBIC}
NUM_COEF_LOOKUP = {
PLANAR: 2,
QUADRATIC: 5,
PART_CUBIC: 6}
class TestSingleDesignMatrixTests:
"""
Tests to verify correctness of basic planar & quadratic design matrices or
DMs. This class serves two purposes, ensuring the independent method DMs are
produced correctly. Secondly, these indivdual DMs are subsets of the larger
DM 'grid' required for the networked orbital correction method.
"""
def setup_class(cls):
# faked cell sizes
cls.xs = 0.75
cls.ys = 0.8
cls.ifg = Ifg(join(SML_TEST_TIF, 'geo_060619-061002_unw.tif'))
cls.ifg.open()
cls.ifg.nodata_value = 0
cls.m = MockIfg(cls.ifg, 3, 4)
cls.m.x_size = cls.xs
cls.m.y_size = cls.ys
# tests for planar model
def test_create_planar_dm(self):
act = get_design_matrix(self.m, PLANAR, intercept=False, scale=100)
assert act.shape == (self.m.num_cells, 2)
exp = unittest_dm(self.m, INDEPENDENT_METHOD, PLANAR, offset=False)
assert_array_equal(act, exp)
def test_create_planar_dm_offsets(self):
act = get_design_matrix(self.m, PLANAR, intercept=True, scale=100)
assert act.shape == (self.m.num_cells, 3)
exp = unittest_dm(self.m, INDEPENDENT_METHOD, PLANAR, offset=True)
assert_array_almost_equal(act, exp)
# tests for quadratic model
def test_create_quadratic_dm(self):
act = get_design_matrix(self.m, QUADRATIC, intercept=False, scale=100)
assert act.shape == (self.m.num_cells, 5)
exp = unittest_dm(self.m, INDEPENDENT_METHOD, QUADRATIC, offset=False)
assert_array_equal(act, exp)
def test_create_quadratic_dm_offsets(self):
act = get_design_matrix(self.m, QUADRATIC, intercept=True, scale=100)
assert act.shape == (self.m.num_cells, 6)
exp = unittest_dm(self.m, INDEPENDENT_METHOD, QUADRATIC, offset=True)
assert_array_equal(act, exp)
# tests for partial cubic model
def test_create_partcubic_dm(self):
act = get_design_matrix(self.m, PART_CUBIC, intercept=False, scale=100)
assert act.shape == (self.m.num_cells, 6)
exp = unittest_dm(self.m, INDEPENDENT_METHOD, PART_CUBIC, offset=False)
assert_array_equal(act, exp)
def test_create_partcubic_dm_offsets(self):
act = get_design_matrix(self.m, PART_CUBIC, intercept=True, scale=100)
assert act.shape == (self.m.num_cells, 7)
exp = unittest_dm(self.m, INDEPENDENT_METHOD, PART_CUBIC, offset=True)
assert_array_equal(act, exp)
# tests for unittest_dm() assuming network method
def test_create_planar_dm_network(self):
# networked method planar version should not have offsets col
ncol_exp = 2
exp = unittest_dm(self.m, NETWORK_METHOD, PLANAR, False)
assert exp.shape == (self.m.num_cells, ncol_exp)
exp2 = unittest_dm(self.m, NETWORK_METHOD, PLANAR, True)
assert exp2.shape == (self.m.num_cells, ncol_exp)
assert_array_equal(exp, exp2)
def test_create_quadratic_dm_network(self):
# quadratic version with networked method does not have offsets col
ncol_exp = 5
exp = unittest_dm(self.m, NETWORK_METHOD, QUADRATIC, False)
assert exp.shape == (self.m.num_cells, ncol_exp)
exp2 = unittest_dm(self.m, NETWORK_METHOD, QUADRATIC, True)
assert exp2.shape == (self.m.num_cells, ncol_exp)
assert_array_equal(exp, exp2)
def test_create_partcubic_dm_network(self):
# partial cubic version with networked method does not have offsets col
ncol_exp = 6
exp = unittest_dm(self.m, NETWORK_METHOD, PART_CUBIC, False)
assert exp.shape == (self.m.num_cells, ncol_exp)
exp2 = unittest_dm(self.m, NETWORK_METHOD, PART_CUBIC, True)
assert exp2.shape == (self.m.num_cells, ncol_exp)
assert_array_equal(exp, exp2)
class TestIndependentCorrection:
"""Test cases for the orbital correction component of PyRate."""
@classmethod
def setup_class(cls):
cls.ifgs = small5_mock_ifgs()
_add_nodata(cls.ifgs)
for ifg in cls.ifgs:
ifg.x_size = 90.0
ifg.y_size = 89.5
ifg.open()
def alt_orbital_correction(self, ifg, deg, offset, scale):
data = ifg.phase_data.reshape(ifg.num_cells)
dm = get_design_matrix(ifg, deg, intercept=True, scale=scale)[~isnan(data)]
fd = data[~isnan(data)].reshape((dm.shape[0], 1))
dmt = dm.T
invNbb = inv(dmt.dot(dm))
orbparams = invNbb.dot(dmt.dot(fd))
alt_params = lstsq(dm, fd)[0]
# FIXME: precision
assert_array_almost_equal(orbparams, alt_params, decimal=1)
dm2 = get_design_matrix(ifg, deg, intercept=True, scale=scale)
fullorb = np.reshape(np.dot(dm2, orbparams), ifg.phase_data.shape)
if offset:
offset_removal = nanmedian(np.ravel(ifg.phase_data - fullorb))
else:
offset_removal = 0
fwd_correction = fullorb - offset_removal
# ifg.phase_data -= (fullorb - offset_removal)
return ifg.phase_data - fwd_correction
def check_correction(self, degree, method, offset, decimal=2):
orig = array([c.phase_data.copy() for c in self.ifgs])
exp = [self.alt_orbital_correction(i, degree, offset, scale=100) for i in self.ifgs]
params = dict()
params[C.ORBITAL_FIT_METHOD] = method
params[C.ORBITAL_FIT_DEGREE] = degree
params[C.ORBFIT_OFFSET] = offset
params[C.ORBFIT_INTERCEPT] = 1
params[C.ORBFIT_SCALE] = 100
params[C.PARALLEL] = False
params[C.NO_DATA_VALUE] = 0
params[C.NAN_CONVERSION] = False
params[C.OUT_DIR] = tempfile.mkdtemp()
params[C.ORBITAL_FIT_LOOKS_X] = 1
params[C.ORBITAL_FIT_LOOKS_Y] = 1
params[C.TEMP_MLOOKED_DIR] = tempfile.mkdtemp()
for i in self.ifgs:
i.mm_converted = True
remove_orbital_error(self.ifgs, params)
corrected = array([c.phase_data for c in self.ifgs])
assert ~(orig == corrected).all()
self.check_results(self.ifgs, orig) # test shape, data is non zero
# FIXME: is decimal=2 close enough?
for i, (e, a) in enumerate(zip(exp, corrected)):
assert_array_almost_equal(e, a, decimal=decimal)
def check_results(self, ifgs, corrections):
"""Helper method for result verification"""
for i, c in zip(ifgs, corrections):
ys, xs = c.shape
assert i.nrows == ys
assert i.ncols == xs
# ensure there is real data
assert ~ isnan(i.phase_data).all()
assert ~ isnan(c).all()
assert c.ptp() != 0 # ensure range of values in grid
def test_independent_correction_planar(self):
self.check_correction(PLANAR, INDEPENDENT_METHOD, False)
def test_independent_correction_planar_offsets(self):
self.check_correction(PLANAR, INDEPENDENT_METHOD, True)
def test_independent_correction_quadratic(self):
self.check_correction(QUADRATIC, INDEPENDENT_METHOD, False)
def test_independent_correction_quadratic_offsets(self):
self.check_correction(QUADRATIC, INDEPENDENT_METHOD, True)
def test_independent_correction_partcubic(self):
self.check_correction(PART_CUBIC, INDEPENDENT_METHOD, False)
def test_independent_correction_partcubic_offsets(self):
self.check_correction(PART_CUBIC, INDEPENDENT_METHOD, True, decimal=1)
class TestError:
"""Tests for the networked correction method"""
@classmethod
def setup_method(cls):
out_dir = tempfile.mkdtemp()
cls.params = common.min_params(out_dir)
cls.ifgs = small5_mock_ifgs()
def test_invalid_ifgs_arg(self):
# min requirement is 1 ifg, can still subtract one epoch from the other
with pytest.raises(OrbitalError):
get_network_design_matrix([], PLANAR, 100, True)
def test_invalid_degree_arg(self):
# test failure of a few different args for 'degree'
for d in range(-5, 1):
with pytest.raises(OrbitalError):
get_network_design_matrix(self.ifgs, d, 100, True)
for d in range(4, 7):
with pytest.raises(OrbitalError):
get_network_design_matrix(self.ifgs, d, 100, True)
def test_invalid_method(self):
# test failure of a few different args for 'method'
for m in [None, 5, -1, -3, 45.8]:
self.params[C.ORBITAL_FIT_METHOD] = m
with pytest.raises(OrbitalError):
remove_orbital_error(self.ifgs, self.params)
def test_different_looks_raise(self):
# different x/y looks factors should be accepted
self.params[C.ORBITAL_FIT_LOOKS_X] = 1
self.params[C.ORBITAL_FIT_LOOKS_Y] = 5
try:
remove_orbital_error(self.ifgs, self.params)
except:
pytest.fail
def test_looks_as_int(self):
self.params[C.ORBITAL_FIT_LOOKS_X] = 1.1
self.params[C.ORBITAL_FIT_LOOKS_Y] = 5
with pytest.raises(OrbitalError):
remove_orbital_error(self.ifgs, self.params)
self.params[C.ORBITAL_FIT_LOOKS_X] = 1
self.params[C.ORBITAL_FIT_LOOKS_Y] = '5'
with pytest.raises(OrbitalError):
remove_orbital_error(self.ifgs, self.params)
class TestNetworkDesignMatrixTests:
"""Contains tests verifying creation of sparse network design matrix."""
def setup_class(self):
self.ifgs = small5_mock_ifgs()
_add_nodata(self.ifgs)
self.nifgs = len(self.ifgs)
self.ncells = self.ifgs[0].num_cells
self.date_ids = get_date_ids(self.ifgs)
self.nepochs = len(self.date_ids)
assert self.nepochs == 6
for ifg in self.ifgs:
ifg.X_SIZE = 90.0
ifg.Y_SIZE = 89.5
def test_planar_network_dm(self):
ncoef = 2
offset = False
act = get_network_design_matrix(self.ifgs, PLANAR, 100, intercept=offset)
assert act.shape == (self.ncells * self.nifgs, ncoef * self.nepochs)
assert act.ptp() != 0
self.check_equality(ncoef, act, self.ifgs, offset)
def test_planar_network_dm_offset(self):
ncoef = 2 # NB: doesn't include offset col
offset = True
act = get_network_design_matrix(self.ifgs, PLANAR, 100, intercept=offset)
assert act.shape[0] == self.ncells * self.nifgs
assert act.shape[1] == (self.nepochs * (ncoef + offset))
assert act.ptp() != 0
self.check_equality(ncoef, act, self.ifgs, offset)
def test_quadratic_network_dm(self):
ncoef = 5
offset = False
act = get_network_design_matrix(self.ifgs, QUADRATIC, 100, intercept=offset)
assert act.shape == (self.ncells * self.nifgs, ncoef * self.nepochs)
assert act.ptp() != 0
self.check_equality(ncoef, act, self.ifgs, offset)
def test_quadratic_network_dm_offset(self):
ncoef = 5
offset = True
act = get_network_design_matrix(self.ifgs, QUADRATIC, 100, intercept=offset)
assert act.shape[0] == self.ncells * self.nifgs
assert act.shape[1] == (self.nepochs * (ncoef + offset))
assert act.ptp() != 0
self.check_equality(ncoef, act, self.ifgs, offset)
def test_partcubic_network_dm(self):
ncoef = 6
offset = False
act = get_network_design_matrix(self.ifgs, PART_CUBIC, 100, intercept=offset)
assert act.shape == (self.ncells * self.nifgs, ncoef * self.nepochs)
assert act.ptp() != 0
self.check_equality(ncoef, act, self.ifgs, offset)
def test_partcubic_network_dm_offset(self):
ncoef = 6
offset = True
act = get_network_design_matrix(self.ifgs, PART_CUBIC, 100, intercept=offset)
assert act.shape[0] == self.ncells * self.nifgs
assert act.shape[1] == (self.nepochs * (ncoef + offset))
assert act.ptp() != 0
self.check_equality(ncoef, act, self.ifgs, offset)
def check_equality(self, ncoef, dm, ifgs, offset):
"""
Internal test function to check subsets against network design matrix
ncoef - base number of coefficients, without extra col for offsets
dm - network design matrix to check the results
ifgs - sequence of Ifg objs
offset - boolean to include extra parameters for model offsets
"""
deg = DEG_LOOKUP[ncoef]
np = ncoef * self.nepochs # index of 1st offset col
for i, ifg in enumerate(ifgs):
exp = unittest_dm(ifg, NETWORK_METHOD, deg, offset)
assert exp.shape == (ifg.num_cells, ncoef)
ib1, ib2 = [x * self.ncells for x in (i, i + 1)] # row start/end
jbm = (ncoef + offset) * self.date_ids[ifg.first] # starting col index for first image
jbs = (ncoef + offset) * self.date_ids[ifg.second] # col start for second image
assert_array_almost_equal(-exp, dm[ib1:ib2, jbm:jbm + ncoef])
assert_array_almost_equal(exp, dm[ib1:ib2, jbs:jbs + ncoef])
# ensure remaining rows/cols are zero for this ifg NOT inc offsets
assert_array_equal(0, dm[ib1:ib2, :jbm]) # all cols leading up to first image
assert_array_equal(0, dm[ib1:ib2, jbm + ncoef + offset:jbs]) # cols btwn mas/slv
assert_array_equal(0, dm[ib1:ib2, jbs + ncoef + offset:np]) # to end of non offsets
# components for network correction testing
def network_correction(ifgs, deg, intercept, ml_ifgs=None, tol=1e-6):
"""
Compares results of orbital_correction() to alternate implementation.
deg - PLANAR, QUADRATIC or PART_CUBIC
off - True/False to calculate correction with offsets
"""
ncells = ifgs[0].num_cells
if ml_ifgs:
ml_nc = ml_ifgs[0].num_cells
ml_data = concatenate([i.phase_data.reshape(ml_nc) for i in ml_ifgs])
dm = get_network_design_matrix(ml_ifgs, deg, 100, intercept)[~isnan(ml_data)]
fd = ml_data[~isnan(ml_data)].reshape((dm.shape[0], 1))
else:
data = concatenate([i.phase_data.reshape(ncells) for i in ifgs])
dm = get_network_design_matrix(ifgs, deg, 100, intercept)[~isnan(data)]
fd = data[~isnan(data)].reshape((dm.shape[0], 1))
params = pinv(dm, tol).dot(fd)
assert params.shape == (dm.shape[1], 1)
# calculate forward correction
sdm = unittest_dm(ifgs[0], NETWORK_METHOD, deg)
ncoef = _get_num_params(deg, intercept=False) # NB: ignore offsets for network method
assert sdm.shape == (ncells, ncoef)
orbs = _expand_corrections(ifgs, sdm, params, ncoef, intercept)
# tricky: get expected result before orbital_correction() modifies ifg phase
return [i.phase_data - orb for i, orb in zip(ifgs, orbs)]
def _expand_corrections(ifgs, dm, params, ncoef, offset):
"""
Convenience func returns model converted to data points.
dm: design matrix (do not filter/remove nan cells)
params: model parameters array from pinv() * dm
ncoef: number of model coefficients (2 planar, 5 quadratic)
offsets: True/False to calculate correction with offsets
"""
# NB: cannot work on singular ifgs due to date ID id/indexing requirement
date_ids = get_date_ids(ifgs)
corrections = []
for ifg in ifgs:
jbm = date_ids[ifg.first] * ncoef # starting row index for first image
jbs = date_ids[ifg.second] * ncoef # row start for second image
par = params[jbs:jbs + ncoef] - params[jbm:jbm + ncoef]
# estimate orbital correction effects
# corresponds to "fullorb = B*parm + offset" in orbfwd.m
cor = dm.dot(par).reshape(ifg.phase_data.shape)
if offset:
off = np.ravel(ifg.phase_data - cor)
# bring all ifgs to same base level
cor -= nanmedian(off)
corrections.append(cor)
return corrections
class TestNetworkCorrectionTests:
"""Verifies orbital correction using network method and no multilooking"""
def setup_class(cls):
# fake some real ifg data by adding nans
cls.ifgs = small5_mock_ifgs()
_add_nodata(cls.ifgs)
# use different sizes to differentiate axes results
for ifg in cls.ifgs:
ifg.X_SIZE = 90.0
ifg.Y_SIZE = 89.5
cls.nc_tol = 1e-6
"""
this test checks that the network orbital fit will return the same
parameters if we add a constant to every interferogram. The current
network method actually uses the constant parameters, which are
assigned per epoch rather than per interferogram, so this test will
fail (and should fail).
"""
@pytest.mark.skip(reason="legacy test against old network method")
def test_offset_inversion(self):
"""
Ensure pinv(DM)*obs gives equal results given constant change to fd
"""
def get_orbital_params():
"""Returns pseudo-inverse of the DM"""
ncells = self.ifgs[0].num_cells
data = concatenate([i.phase_data.reshape(ncells) for i in self.ifgs])
dm = get_network_design_matrix(self.ifgs, PLANAR, 100, True)[~isnan(data)]
fd = data[~isnan(data)].reshape((dm.shape[0], 1))
return dot(pinv(dm, self.nc_tol), fd)
tol = 1e-5
nifgs = len(self.ifgs)
params0 = get_orbital_params()
# apply constant change to the observed values (fd)
for value in [5.2, -23.5]:
for i in self.ifgs: # change ifgs in place
i.phase_data += value
assert isnan(i.phase_data).any()
params = get_orbital_params()
diff = params - params0
assert (diff[:-nifgs] < tol).all()
assert_array_almost_equal(diff[-nifgs:], value, decimal=5)
# reset back to orig data
for i in self.ifgs:
i.phase_data -= value
# These functions test full size data for orbital correction. The options
# are separated as the ifg.phase_data arrays are modified in place, allowing
# setUp() reset phase data between tests.
def test_network_correction_planar(self):
deg, intercept = PLANAR, False
exp = network_correction(self.ifgs, deg, intercept)
self.verify_corrections(self.ifgs, exp, deg, intercept)
"""
the test_network_correction_{DEGREE}_offset tests check against a method
that fits a constant offset to each interferogram but doesn't remove it.
This differs from the current implementation of the network correction
so these tests will fail.
"""
@pytest.mark.skip(reason="legacy test against old network method")
def test_network_correction_planar_offset(self):
deg, intercept = PLANAR, True
exp = network_correction(self.ifgs, deg, intercept)
self.verify_corrections(self.ifgs, exp, deg, intercept)
def test_network_correction_quadratic(self):
deg, intercept = QUADRATIC, False
offset = intercept
exp = network_correction(self.ifgs, deg, intercept)
self.verify_corrections(self.ifgs, exp, deg, intercept)
@pytest.mark.skip(reason="legacy test against old network method")
def test_network_correction_quadratic_offset(self):
deg, intercept = QUADRATIC, True
exp = network_correction(self.ifgs, deg, intercept)
self.verify_corrections(self.ifgs, exp, deg, intercept)
def test_network_correction_partcubic(self):
deg, intercept = PART_CUBIC, False
exp = network_correction(self.ifgs, deg, intercept)
self.verify_corrections(self.ifgs, exp, deg, intercept)
@pytest.mark.skip(reason="legacy test against old network method")
def test_network_correction_partcubic_offset(self):
deg, intercept = PART_CUBIC, True
exp = network_correction(self.ifgs, deg, intercept)
self.verify_corrections(self.ifgs, exp, deg, intercept)
@staticmethod
def verify_corrections(ifgs, exp, deg, intercept):
# checks orbital correction against unit test version
params = dict()
params[C.ORBITAL_FIT_METHOD] = NETWORK_METHOD
params[C.ORBITAL_FIT_DEGREE] = deg
params[C.ORBITAL_FIT_LOOKS_X] = 1
params[C.ORBITAL_FIT_LOOKS_Y] = 1
params[C.PARALLEL] = False
params[C.OUT_DIR] = tempfile.mkdtemp()
params[C.ORBFIT_OFFSET] = intercept
params[C.ORBFIT_INTERCEPT] = intercept
params[C.ORBFIT_SCALE] = 100
params[C.PREREAD_IFGS] = None
mkdir_p(Path(params[C.OUT_DIR]).joinpath(C.ORB_ERROR_DIR))
network_orbital_correction(ifgs, params)
act = [i.phase_data for i in ifgs]
assert_array_almost_equal(act, exp, decimal=5)
class TestNetworkCorrectionTestsMultilooking:
'Verifies orbital correction with multilooking and network method'
@classmethod
def setup_class(cls):
# fake some real ifg data by adding nans
cls.ml_ifgs = small5_mock_ifgs()
# 2x data of default Small mock
cls.ifgs = small5_mock_ifgs(xs=6, ys=8)
# use different sizes to differentiate axes results
for ifg in cls.ifgs:
ifg.X_SIZE = 90.0
ifg.Y_SIZE = 89.5
# add common nodata to all ifgs
for i in cls.ifgs + cls.ml_ifgs:
i.phase_data[0, :] = nan
# These functions test multilooked data for orbital correction. The options
# are separated as the ifg.phase_data arrays are modified in place, allowing
# setUp() refresh phase data between tests.
def test_mlooked_network_correction_planar(self):
deg, intercept = PLANAR, False
exp = network_correction(self.ifgs, deg, intercept, self.ml_ifgs)
self.verify_corrections(self.ifgs, exp, deg, intercept)
@pytest.mark.skip(reason="legacy test against old network method")
def test_mlooked_network_correction_planar_offset(self):
deg, intercept = PLANAR, True
exp = network_correction(self.ifgs, deg, intercept, self.ml_ifgs)
self.verify_corrections(self.ifgs, exp, deg, intercept)
def test_mlooked_network_correction_quadratic(self):
deg, intercept = QUADRATIC, False
exp = network_correction(self.ifgs, deg, intercept, self.ml_ifgs)
self.verify_corrections(self.ifgs, exp, deg, intercept)
@pytest.mark.skip(reason="legacy test against old network method")
def test_mlooked_network_correction_quadratic_offset(self):
deg, intercept = QUADRATIC, True
exp = network_correction(self.ifgs, deg, intercept, self.ml_ifgs)
self.verify_corrections(self.ifgs, exp, deg, intercept)
def test_mlooked_network_correction_partcubic(self):
deg, intercept = PART_CUBIC, False
exp = network_correction(self.ifgs, deg, intercept, self.ml_ifgs)
self.verify_corrections(self.ifgs, exp, deg, intercept)
@pytest.mark.skip(reason="legacy test against old network method")
def test_mlooked_network_correction_partcubic_offset(self):
deg, intercept = PART_CUBIC, True
exp = network_correction(self.ifgs, deg, intercept, self.ml_ifgs)
self.verify_corrections(self.ifgs, exp, deg, intercept)
def verify_corrections(self, ifgs, exp, deg, intercept):
# checks orbital correction against unit test version
params = dict()
params[C.ORBITAL_FIT_METHOD] = NETWORK_METHOD
params[C.ORBITAL_FIT_DEGREE] = deg
params[C.ORBITAL_FIT_LOOKS_X] = 1
params[C.ORBITAL_FIT_LOOKS_Y] = 1
params[C.PARALLEL] = False
params[C.ORBFIT_OFFSET] = intercept
params[C.ORBFIT_INTERCEPT] = intercept
params[C.ORBFIT_SCALE] = 100
params[C.PREREAD_IFGS] = None
params[C.OUT_DIR] = tempfile.mkdtemp()
mkdir_p(Path(params[C.OUT_DIR]).joinpath(C.ORB_ERROR_DIR))
network_orbital_correction(ifgs, params, self.ml_ifgs)
act = [i.phase_data for i in ifgs]
assert_array_almost_equal(act, exp, decimal=4)
def unittest_dm(ifg, method, degree, offset=False, scale=100.0):
'''Helper/test func to create design matrix segments. Includes handling for
making quadratic DM segments for use in network method.
ifg - source interferogram to model design matrix on
method - INDEPENDENT_METHOD or NETWORK_METHOD
degree - PLANAR, QUADRATIC or PART_CUBIC
offset - True/False to include additional cols for offsets
'''
assert method in [INDEPENDENT_METHOD, NETWORK_METHOD]
xlen = ncoef = NUM_COEF_LOOKUP[degree]
if offset and method == INDEPENDENT_METHOD:
ncoef += 1
else:
offset = False # prevent offsets in DM sections for network method
# NB: avoids meshgrid to prevent copying production implementation
data = empty((ifg.num_cells, ncoef), dtype=float32)
rows = iter(data)
yr = range(1, ifg.nrows + 1) # simulate meshgrid starting from 1
xr = range(1, ifg.ncols + 1)
xsz, ysz = [i / scale for i in [ifg.x_size, ifg.y_size]]
if degree == PLANAR:
for y, x in product(yr, xr):
row = next(rows)
row[:xlen] = [x * xsz, y * ysz]
elif degree == QUADRATIC:
for y, x in product(yr, xr):
ys = y * ysz
xs = x * xsz
row = next(rows)
row[:xlen] = [xs ** 2, ys ** 2, xs * ys, xs, ys]
else:
for y, x in product(yr, xr):
ys = y * ysz
xs = x * xsz
row = next(rows)
row[:xlen] = [xs * ys ** 2, xs ** 2, ys ** 2, xs * ys, xs, ys]
if offset:
data[:, -1] = 1
return data
def get_date_ids(ifgs):
'''
Returns unique epoch date IDs from the given Ifgs.
'''
dates = []
for ifg in ifgs:
dates += [ifg.first, ifg.second]
return first_second_ids(dates)
def _add_nodata(ifgs):
"""Adds some NODATA/nan cells to the small mock ifgs"""
ifgs[0].phase_data[0, :] = nan # 3 error cells
ifgs[1].phase_data[2, 1:3] = nan # 2 error cells
ifgs[2].phase_data[3, 2:3] = nan # 1 err
ifgs[3].phase_data[1, 2] = nan # 1 err
ifgs[4].phase_data[1, 1:3] = nan # 2 err
class TestLegacyComparisonTestsOrbfitMethod1:
"""
This is the legacy comparison test of orbital correction functionality.
Tests use the following config
orbfit: 1
orbfitmethod: 1
orbfitdegrees: 1
orbfitlksx: 1
orbfitlksy: 1
"""
@classmethod
@pytest.fixture(autouse=True)
def setup_class(cls, roipac_params):
cls.params = roipac_params
cls.BASE_DIR = cls.params[C.OUT_DIR]
# change to orbital error correction method 1
cls.params[C.ORBITAL_FIT_METHOD] = INDEPENDENT_METHOD
cls.params[C.ORBITAL_FIT_LOOKS_X] = 1
cls.params[C.ORBITAL_FIT_LOOKS_Y] = 1
cls.params[C.PARALLEL] = False
cls.params[C.ORBFIT_OFFSET] = True
data_paths = [os.path.join(SML_TEST_TIF, p) for p in IFMS16]
cls.ifg_paths = [os.path.join(cls.BASE_DIR, os.path.basename(d)) for d in data_paths]
for d in data_paths:
shutil.copy(d, os.path.join(cls.BASE_DIR, os.path.basename(d)))
@classmethod
def teardown_class(cls):
"roipac_params fixture auto cleans"
pass
@pytest.mark.skipif(True, reason="Does not work anymore")
def test_orbital_correction_legacy_equality(self):
from pyrate import correct
from pyrate.configuration import MultiplePaths
multi_paths = [MultiplePaths(p, params=self.params) for p in self.ifg_paths]
for m in multi_paths: # cheat
m.sampled_path = m.converted_path
self.params[C.INTERFEROGRAM_FILES] = multi_paths
self.params['rows'], self.params['cols'] = 2, 3
self.params[C.ORBFIT_OFFSET] = False
Path(self.BASE_DIR).joinpath('tmpdir').mkdir(exist_ok=True, parents=True)
correct._copy_mlooked(self.params)
correct._update_params_with_tiles(self.params)
correct._create_ifg_dict(self.params)
correct._copy_mlooked(self.params)
pyrate.core.orbital.orb_fit_calc_wrapper(self.params)
onlyfiles = [f for f in os.listdir(SML_TEST_LEGACY_ORBITAL_DIR)
if os.path.isfile(os.path.join(SML_TEST_LEGACY_ORBITAL_DIR, f))
and f.endswith('.csv') and f.__contains__('_method1_')]
count = 0
for i, f in enumerate(onlyfiles):
ifg_data = np.genfromtxt(os.path.join(SML_TEST_LEGACY_ORBITAL_DIR, f), delimiter=',')
for k, j in enumerate([m.tmp_sampled_path for m in multi_paths]):
ifg = Ifg(j)
ifg.open()
if os.path.basename(j).split('_ifg.')[0] == os.path.basename(f).split(
'_orb_planar_1lks_method1_geo_')[1].split('.')[0]:
count += 1
# all numbers equal
np.testing.assert_array_almost_equal(ifg_data, ifg.phase_data, decimal=2)
# means must also be equal
assert np.nanmean(ifg_data) == pytest.approx(np.nanmean(ifg.phase_data), abs=1e-2)
# number of nans must equal
assert np.sum(np.isnan(ifg_data)) == np.sum(np.isnan(ifg.phase_data))
ifg.close()
# ensure that we have expected number of matches
assert count == len(self.ifg_paths)
def test_orbfit_treats_process_inputs_as_read_only(self):
pass
class TestLegacyComparisonTestsOrbfitMethod2:
"""
This is the legacy comparison test of orbital correction functionality.
Tests use the following config
orbfit: 1
orbfitmethod: 2
orbfitdegrees: 1
orbfitlksx: 1
orbfitlksy: 1
"""
@classmethod
def setup_class(cls):
# change to orbital error correction method 2
cls.params = Configuration(common.TEST_CONF_ROIPAC).__dict__
cls.BASE_DIR = cls.params[C.OUT_DIR]
cls.params[C.ORBITAL_FIT_METHOD] = NETWORK_METHOD
cls.params[C.ORBITAL_FIT_LOOKS_X] = 1
cls.params[C.ORBITAL_FIT_LOOKS_Y] = 1
cls.params[C.ORBFIT_OFFSET] = True
cls.params[C.OUT_DIR] = cls.BASE_DIR
data_paths = [os.path.join(SML_TEST_TIF, p) for p in small_ifg_file_list()]
cls.new_data_paths = [os.path.join(cls.BASE_DIR, os.path.basename(d)) for d in data_paths]
cls.params[C.INTERFEROGRAM_FILES] = [MultiplePaths(file_name=d, params=cls.params) for d in data_paths]
for p in cls.params[C.INTERFEROGRAM_FILES]:
p.sampled_path = p.converted_path
# copy the files from the dir into temp dir
for d in data_paths:
d_copy = os.path.join(cls.BASE_DIR, os.path.basename(d))
shutil.copy(d, d_copy)
os.chmod(d_copy, 0o660)
cls.headers = [roipac.roipac_header(i, cls.params) for i in cls.new_data_paths]
cls.orb_error_dir = Path(cls.params[C.OUT_DIR]).joinpath(ORB_ERROR_DIR)
cls.orb_error_dir.mkdir(parents=True, exist_ok=True)
@classmethod
def teardown_class(cls):
shutil.rmtree(cls.BASE_DIR, ignore_errors=True)
def test_orbital_correction_legacy_equality_orbfit_method_2(self):
correct._copy_mlooked(self.params)
correct._create_ifg_dict(self.params)
remove_orbital_error(self.new_data_paths, self.params)
onlyfiles = [f for f in os.listdir(SML_TEST_LEGACY_ORBITAL_DIR)
if os.path.isfile(os.path.join(SML_TEST_LEGACY_ORBITAL_DIR, f))
and f.endswith('.csv') and f.__contains__('_method2_')]
count = 0
for i, f in enumerate(onlyfiles):
legacy_phase_data = np.genfromtxt(os.path.join(
SML_TEST_LEGACY_ORBITAL_DIR, f), delimiter=',')
for k, j in enumerate(self.new_data_paths):
if os.path.basename(j).split('_unw.')[0] == os.path.basename(f).split('_method2_')[1].split('.')[0]:
count += 1
ifg = Ifg(j)
ifg.open()
# all numbers equal
# Note this changed as the nodata mask in the gdal_python.gdal_average changed to nan from 0
# np.testing.assert_array_almost_equal(legacy_phase_data, ifg.phase_data, decimal=3)
# number of nans must equal
assert np.sum(np.isnan(legacy_phase_data)) == np.sum(np.isnan(ifg.phase_data))
# ensure that we have expected number of matches
assert count == len(self.new_data_paths)
def test_orbital_error_method2_dummy(self):
"""
does not test anything except that the method is working
"""
# change to orbital error correction method 2
self.params[C.ORBITAL_FIT_METHOD] = NETWORK_METHOD
self.params[C.ORBITAL_FIT_LOOKS_X] = 2
self.params[C.ORBITAL_FIT_LOOKS_Y] = 2
correct._copy_mlooked(self.params)
correct._create_ifg_dict(self.params)
remove_orbital_error(self.new_data_paths, self.params)
onlyfiles = [f for f in os.listdir(SML_TEST_LEGACY_ORBITAL_DIR)
if os.path.isfile(os.path.join(SML_TEST_LEGACY_ORBITAL_DIR, f))
and f.endswith('.csv') and f.__contains__('_method2_')]
count = 0
for i, f in enumerate(onlyfiles):
legacy_phase_data = np.genfromtxt(os.path.join(SML_TEST_LEGACY_ORBITAL_DIR, f), delimiter=',')
for k, j in enumerate(self.new_data_paths):
if os.path.basename(j).split('_unw.')[0] == os.path.basename(f).split('_method2_')[1].split('.')[0]:
count += 1
ifg = Ifg(j)
ifg.open()
# number of nans must equal
assert np.sum(np.isnan(legacy_phase_data)) == np.sum(np.isnan(ifg.phase_data))
# ensure that we have expected number of matches
assert count == len(self.new_data_paths)
# TODO: Write tests for various looks and degree combinations
# TODO: write mpi tests
class TestOrbErrorCorrectionsOnDiscReused:
@classmethod
def setup_class(cls):
cls.conf = TEST_CONF_GAMMA
params = Configuration(cls.conf).__dict__
conv2tif.main(params)
params = Configuration(cls.conf).__dict__
prepifg.main(params)
cls.params = Configuration(cls.conf).__dict__
correct._copy_mlooked(cls.params)
correct._create_ifg_dict(cls.params)
@classmethod
def teardown_class(cls):
shutil.rmtree(cls.params[C.OUT_DIR])
def test_orb_error(self, orbfit_method, orbfit_degrees):
self.params[C.ORBITAL_FIT_METHOD] = orbfit_method
self.params[C.ORBITAL_FIT_DEGREE] = orbfit_degrees
multi_paths = self.params[C.INTERFEROGRAM_FILES]
self.ifg_paths = [p.tmp_sampled_path for p in multi_paths]
remove_orbital_error(self.ifg_paths, self.params)
# test_orb_errors_written
orb_error_files = [MultiplePaths.orb_error_path(i, self.params) for i in self.ifg_paths]
assert all(p.exists() for p in orb_error_files)
last_mod_times = np.array([os.stat(o).st_mtime for o in orb_error_files])
# run orbit removal again
remove_orbital_error(self.ifg_paths, self.params)
orb_error_files2 = [MultiplePaths.orb_error_path(i, self.params) for i in self.ifg_paths]
# if files are written again - times will change
last_mod_times_2 = np.array([os.stat(o).st_mtime for o in orb_error_files2])
# test_orb_error_reused_if_params_unchanged
assert all(a == b for a, b in zip(last_mod_times, last_mod_times_2))
# change one of the params
_degrees = set(C.ORB_DEGREE_NAMES.keys())
_degrees.discard(orbfit_degrees)
# test_orb_errors_recalculated_if_params_change
self.params[C.ORBITAL_FIT_DEGREE] = _degrees.pop()
import time
time.sleep(0.1)
remove_orbital_error(self.ifg_paths, self.params)
orb_error_files3 = [MultiplePaths.orb_error_path(i, self.params) for i in self.ifg_paths]
last_mod_times_3 = np.array([os.stat(o).st_mtime for o in orb_error_files3])
assert all(a != b for a, b in zip(last_mod_times, last_mod_times_3))
class TestOrbErrorCorrectionsReappliedDoesNotChangePhaseData:
@classmethod
def setup_method(cls):
cls.conf = TEST_CONF_GAMMA
params = Configuration(cls.conf).__dict__
conv2tif.main(params)
params = Configuration(cls.conf).__dict__
prepifg.main(params)
cls.params = Configuration(cls.conf).__dict__
correct._copy_mlooked(cls.params)
correct._create_ifg_dict(cls.params)
multi_paths = cls.params[C.INTERFEROGRAM_FILES]
cls.ifg_paths = [p.tmp_sampled_path for p in multi_paths]
@classmethod
def teardown_method(cls):
shutil.rmtree(cls.params[C.OUT_DIR])
def test_orb_error_multiple_run_does_not_change_phase_data(self, orbfit_method, orbfit_degrees):
self.params[C.ORBITAL_FIT_METHOD] = orbfit_method
self.params[C.ORBITAL_FIT_DEGREE] = orbfit_degrees
remove_orbital_error(self.ifg_paths, self.params)
ifgs = [Ifg(i) for i in self.ifg_paths]
for i in ifgs:
i.open()
phase_prev = [i.phase_data for i in ifgs]
# orb correct once more
correct._copy_mlooked(self.params)
remove_orbital_error(self.ifg_paths, self.params)
# and again
correct._copy_mlooked(self.params)
remove_orbital_error(self.ifg_paths, self.params)
ifgs = [Ifg(i) for i in self.ifg_paths]
for i in ifgs:
i.open()
phase_now = [i.phase_data for i in ifgs]
np.testing.assert_array_equal(phase_now, phase_prev)
@pytest.fixture(params=[2, 3, 4])
def orbfit_looks(request):
x_lk = request.param
y_lk = np.random.choice([2, 3, 4])
return x_lk, y_lk
class TestOrbfitIndependentMethodWithMultilooking:
@classmethod
def setup_class(cls):
cls.conf = TEST_CONF_GAMMA
params = Configuration(cls.conf).__dict__
conv2tif.main(params)
params = Configuration(cls.conf).__dict__
prepifg.main(params)
cls.params = Configuration(cls.conf).__dict__
correct._copy_mlooked(cls.params)
correct._create_ifg_dict(cls.params)
@classmethod
def teardown_class(cls):
shutil.rmtree(cls.params[C.OUT_DIR])
def test_independent_method_works_with_multilooking(self, orbfit_looks, orbfit_degrees, orbfit_method=1):
"""
tests when multilooking is used in orbfit method 1 correction
also tests that multilooking factors in x and y can be different
"""
xlks, ylks = orbfit_looks
self.params[C.ORBITAL_FIT_METHOD] = orbfit_method
self.params[C.ORBITAL_FIT_DEGREE] = orbfit_degrees
self.params[C.ORBITAL_FIT_LOOKS_Y] = int(ylks)
self.params[C.ORBITAL_FIT_LOOKS_X] = int(xlks)
multi_paths = self.params[C.INTERFEROGRAM_FILES]
self.ifg_paths = [p.tmp_sampled_path for p in multi_paths]
remove_orbital_error(self.ifg_paths, self.params)
ifgs = [Ifg(p) for p in self.ifg_paths]
for i in ifgs:
i.open()
assert i.shape == (72, 47) # shape should not change
from pyrate.core.shared import cell_size
class SyntheticIfg:
"""
This class will generate a mock interferogram whose signal consists entirely
of a synthetic orbital error. The orbital error is generated as a 2D
polynomial signal with zero noise.
"""
def __init__(self, orbfit_degrees):
self.x_step = 0.001388888900000 # pixel size - same as cropA
self.y_step = 0.001388888900000
self.nrows = 100
self.ncols = 100
self.num_cells = self.nrows * self.ncols
self.is_open = False
self.orbfit_degrees = orbfit_degrees
self.first = None
self.second = None
self._phase_data = None
self._phase_data_first = None
self._phase_data_second = None
self.y_first = 0
self.x_first = 0
self.add_geographic_data()
def add_geographic_data(self):
"""
Determine and add geographic data to object
"""
# add some geographic data
self.x_centre = int(self.ncols / 2)
self.y_centre = int(self.nrows / 2)
self.lat_centre = self.y_first + (self.y_step * self.y_centre)
self.long_centre = self.x_first + (self.x_step * self.x_centre)
# use cell size from centre of scene
self.x_size, self.y_size = cell_size(self.lat_centre, self.long_centre, self.x_step, self.y_step)
@property
def phase_data(self):
"""
Returns phase band as an array.
"""
if self._phase_data is None:
self.open()
return self._phase_data
def open(self):
x, y = np.meshgrid(np.arange(self.nrows) * self.x_step, np.arange(self.ncols) * self.y_step)
x += self.x_step
y += self.y_step
# define some random coefficients, different for each date
x_slope, y_slope, x2_slope, y2_slope, x_y_slope, x_y2_slope, const = np.ravel(np.random.rand(1, 7))
x_slope_, y_slope_, x2_slope_, y2_slope_, x_y_slope_, x_y2_slope_, const_ = np.ravel(np.random.rand(1, 7))
# compute the 2D polynomial separately for first and second dates
self._phase_data_first = x_slope * x + y_slope * y + const # planar
self._phase_data_second = x_slope_ * x + y_slope_ * y + const_ # planar
if self.orbfit_degrees == QUADRATIC:
self._phase_data_first += x2_slope * x ** 2 + y2_slope * y ** 2 + x_y_slope * x * y
self._phase_data_second += x2_slope_ * x ** 2 + y2_slope_ * y ** 2 + x_y_slope_ * x * y
elif self.orbfit_degrees == PART_CUBIC:
self._phase_data_first += x2_slope * x ** 2 + y2_slope * y ** 2 + x_y_slope * x * y + \
x_y2_slope * x * (y ** 2)
self._phase_data_second += x2_slope_ * x ** 2 + y2_slope_ * y ** 2 + x_y_slope_ * x * y + \
x_y2_slope_ * x * (y ** 2)
# combine orbit error for first and second dates to give synthetic phase data for this ifg
self._phase_data = self._phase_data_first - self._phase_data_second
self.is_open = True
from pyrate.core.gdal_python import _gdalwarp_width_and_height
from pyrate.core.orbital import __orb_inversion
# helper function to multilook a synthetic ifg with gdal
def mlk_ifg(ifg, nlooks):
src = gdal.GetDriverByName('MEM').Create('', ifg.ncols, ifg.nrows, 1, gdalconst.GDT_Float32)
gt = (0, ifg.x_step, 0, 0, 0, ifg.y_step)
src.SetGeoTransform(gt)
src.GetRasterBand(1).WriteArray(ifg.phase_data)
resampled_gt = (0, ifg.x_step * nlooks, 0, 0, 0, ifg.y_step * nlooks)
min_x, min_y = 0, 0
max_x, max_y = ifg.x_step * ifg.ncols, ifg.y_step * ifg.nrows
px_height, px_width = _gdalwarp_width_and_height(max_x, max_y, min_x, min_y, resampled_gt)
dst = gdal.GetDriverByName('MEM').Create('', px_height, px_width, 1, gdalconst.GDT_Float32)
dst.SetGeoTransform(resampled_gt)
gdal.ReprojectImage(src, dst, '', '', gdal.GRA_Average)
mlooked = Ifg(dst)
mlooked.first = ifg.first
mlooked.second = ifg.second
return mlooked
@pytest.fixture(params=[1, 2, 3, 4])
def orb_lks(request):
return request.param
def test_single_synthetic_ifg_independent_method(orbfit_degrees, orb_lks, ifg=None):
"""
These tests are checking that perfect orbital errors, those matching the assumed orbital error model, can be
completely removed by the independent orbital correction with and without multilooking.
These tests also prove that orbital error estimates using orbfit multilooking is a valid approach and matches the
modelled error with acceptable numerical accuracy, with the accuracy depending on the multilooking factor used.
These tests also prove that the orbital error parameters can be approximated using multilooking in the
independent method.
"""
if ifg is None:
ifg = SyntheticIfg(orbfit_degrees)
fullres_dm = get_design_matrix(ifg, orbfit_degrees, intercept=True, scale=1)
m_looked_ifg = mlk_ifg(ifg, orb_lks)
mlooked_phase = np.reshape(m_looked_ifg.phase_data, m_looked_ifg.num_cells)
mlooked_dm = get_design_matrix(m_looked_ifg, orbfit_degrees, intercept=True, scale=1)
orb_corr = __orb_correction(fullres_dm, mlooked_dm, ifg.phase_data, mlooked_phase, offset=True)
if orb_lks == 1:
assert_array_almost_equal(fullres_dm, mlooked_dm)
decimal = 4
else:
decimal = 2
assert_array_almost_equal(ifg.phase_data, orb_corr, decimal=decimal)
@pytest.mark.slow
@pytest.mark.skipif((not PY37GDAL302), reason="Only run in one CI env")
def test_set_synthetic_ifgs_independent_method(mexico_cropa_params, orbfit_degrees, orb_lks):
"""
Test that the independent method can generate a set of orbital corrections
that matches a set of synthetic ifg for a range of multi-look factors and
polynomial degrees.
"""
# Use the CropA ifg network configuration
ifgs = [Ifg(i.converted_path) for i in mexico_cropa_params[C.INTERFEROGRAM_FILES]]
for i in ifgs:
i.open()
test_ifg = SyntheticIfg(orbfit_degrees)
test_single_synthetic_ifg_independent_method(orbfit_degrees, orb_lks, test_ifg)
# an in-memory "open" interferogram that we can pass to top-level orb correction methods
class FakeIfg:
def __init__(self, orbfit_deg, model_params, date_first, date_second):
self.x_step = 0.001388888900000 # pixel size - same as cropA
self.y_step = 0.001388888900000
self.nrows = 100
self.ncols = 100
self.num_cells = self.nrows * self.ncols
self.is_open = False
self.orbfit_degrees = orbfit_deg
self.model_params = model_params
self.first = date_first
self.second = date_second
self._phase_data = None
self.y_first = 0
self.x_first = 0
self.nan_fraction = 0
self.add_geographic_data()
def add_geographic_data(self):
"""
Determine and add geographic data to object
"""
# add some geographic data
self.x_centre = int(self.ncols / 2)
self.y_centre = int(self.nrows / 2)
self.lat_centre = self.y_first + (self.y_step * self.y_centre)
self.long_centre = self.x_first + (self.x_step * self.x_centre)
# use cell size from centre of scene
self.x_size, self.y_size = cell_size(self.lat_centre, self.long_centre, self.x_step, self.y_step)
@property
def phase_data(self):
"""
Returns phase band as an array.
"""
if self._phase_data is None:
self.open()
return self._phase_data
def open(self):
x, y = np.meshgrid(np.arange(self.nrows) * self.x_step, np.arange(self.ncols) * self.y_step)
x += self.x_step
y += self.y_step
# use provided coefficients
if self.orbfit_degrees == PLANAR:
mx, my = self.model_params
self._phase_data = mx * x + my * y
elif self.orbfit_degrees == QUADRATIC:
mx, my, mx2, my2, mxy = self.model_params
self._phase_data = mx * x + my * y + mx2 * x ** 2 + my2 * y ** 2 + mxy * x * y
else:
mx, my, mx2, my2, mxy, mxy2 = self.model_params
self._phase_data = mx * x + my * y + mx2 * x ** 2 + my2 * y ** 2 + mxy * x * y + mxy2 * x * y ** 2
self.is_open = True
# tests for network method to recover synthetic orbital error
class SyntheticNetwork:
"""
This class will generate a network of synthetic ifgs, based on
orbital errors for each epoch. The signal will be purely from the synthetic
orbital error with no noise.
"""
def __init__(self, orbfit_deg, epochs, network, model_params):
"""
orbfit_deg: synthesise ifgs with planar, quadratic, or part cubic
orbit error models.
epochs: list of epoch dates in the network
network: list of lists, spec of the ifgs to generate for each epoch as
primary
model_params: list of iterable - model parameters of correct degree for
each epoch
"""
ifgs = []
for i, e1 in enumerate(epochs):
for j in network[i]:
ifg_err_model = [model_params[j][k] - model_params[i][k] for k in range(len(model_params[0]))]
ifgs.append(FakeIfg(orbfit_deg, ifg_err_model, e1, epochs[j]))
self.ifgs = ifgs
self.epochs = epochs
@pytest.mark.skip(reason="test is non-deterministic due to float calculation errors in array comparison")
def test_synthetic_network_correction(orbfit_degrees, orb_lks):
epochs = [
date(2000, 1, 1),
date(2000, 1, 13),
date(2000, 1, 25),
date(2000, 2, 6),
date(2000, 2, 18),
date(2000, 3, 1)
]
# start with the network as a connected tree so mst does nothing
network = [[2], [2], [3], [4, 5], [], []]
# six sets of model parameters - one for each epoch
model_params = [[-1, 1, -1, 1, -1, 1],
[0, 1, 2, 3, 4, 5],
[5, 4, 3, 2, 1, 0],
[3, 6, 9, 6, 3, 0],
[9, 4, 1, 0, 1, 4],
[1, 1, 1, 1, 1, 1]]
if orbfit_degrees == PLANAR:
nparam = 2
elif orbfit_degrees == QUADRATIC:
nparam = 5
else:
nparam = 6
model_params = [mi[:nparam] for mi in model_params]
# network method uses a hard coded scale of 100
scale = 100
syn_data = SyntheticNetwork(orbfit_degrees, epochs, network, model_params)
# id_dict = {date: i for date, i in enumerate(epochs)}
nepochs = len(epochs)
mlk_ifgs = [mlk_ifg(ifg, orb_lks) for ifg in syn_data.ifgs]
coeffs = calc_network_orb_correction(mlk_ifgs, orbfit_degrees, scale, nepochs, intercept=True)
# reconstruct correction
reconstructed = []
# ifgs are built with lat/long metadata,
# orbfit modelling is done with metres coordinates
csx = syn_data.ifgs[0].x_size
csy = syn_data.ifgs[0].y_size
x, y = (coord + 1 for coord in np.meshgrid(np.arange(100, dtype=float), np.arange(100, dtype=float)))
x *= csx
y *= csy
x /= scale
y /= scale
for i, js in enumerate(network):
for j in js:
cpair = [cj - ci for ci, cj in zip(coeffs[i], coeffs[j])]
if orbfit_degrees == PLANAR:
reconstructed.append(cpair[0] * x + cpair[1] * y)
elif orbfit_degrees == QUADRATIC:
reconstructed.append(cpair[0] * x ** 2 + cpair[1] * y ** 2 + cpair[2] * x * y \
+ cpair[3] * x + cpair[4] * y)
else:
reconstructed.append(cpair[0] * x * y ** 2 + cpair[1] * x ** 2 + cpair[2] * y ** 2 + \
cpair[3] * x * y + cpair[4] * x + cpair[5] * y)
for orig, recon in zip(syn_data.ifgs, reconstructed):
assert_array_almost_equal(orig.phase_data, recon, decimal=2)
def test_orbital_inversion():
"""Small unit to test the application of numpy pseudoinverse"""
A = np.array([[1, 1, 0], [1, 0, 1], [0, 1, 1]])
d = np.array([2, 4, 3])
exp = np.array([1.5, 0.5, 2.5])
res = __orb_inversion(A, d)
assert_array_almost_equal(res, exp, decimal=9)
