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isce_utils.py
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isce_utils.py
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"""Utilities wrapped around ISCE."""
############################################################
# Program is part of MintPy #
# Copyright (c) 2013, Zhang Yunjun, Heresh Fattahi #
# Author: Zhang Yunjun, Heresh Fattahi, Apr 2020 #
############################################################
# 2020-07: Talib Oliver-Cabrera, add UAVSAR support
# 2020-10: Cunren Liang, add alosStack support
# 2022-06: Yujie Zheng, add standard processing from isce2
# Group contents:
# metadata
# geometry
# baseline
# multilook
# miscellaneous
# Recommend import:
# from mintpy.utils import isce_utils
import datetime
import glob
import logging
import os
import shelve
import time
import numpy as np
from scipy import ndimage
from mintpy.constants import EARTH_RADIUS, SPEED_OF_LIGHT
from mintpy.objects import sensor
from mintpy.utils import (
attribute as attr,
ptime,
readfile,
utils1 as ut,
writefile,
)
# suppress matplotlib DEBUG message
mpl_logger = logging.getLogger('matplotlib')
mpl_logger.setLevel(logging.WARNING)
def get_processor(meta_file):
"""
Get the name of ISCE processor (imaging mode)
"""
meta_dir = os.path.dirname(os.path.abspath(meta_file))
tops_meta_file = os.path.join(meta_dir, 'IW*.xml')
alos_meta_file = os.path.join(meta_dir, '*.track.xml')
stripmap_meta_files = [os.path.join(meta_dir, i) for i in ['data.db', 'data.dat', 'data']]
processor = None
if len(glob.glob(tops_meta_file)) > 0:
# topsStack
processor = 'tops'
elif len(glob.glob(alos_meta_file)) > 0:
# alosStack / alos2App
processor = 'alosStack'
elif any(os.path.isfile(i) for i in stripmap_meta_files):
# stripmapStack
processor = 'stripmap'
elif meta_file.endswith('.xml'):
# stripmapApp
processor = 'stripmap'
else:
raise ValueError(f'Un-recognized ISCE processor for metadata file: {meta_file}')
return processor
##################################### metadata #######################################
def load_product(xml_name):
"""Load the product using Product Manager."""
import isce
from iscesys.Component.ProductManager import ProductManager
pm = ProductManager()
pm.configure()
return pm.loadProduct(xml_name)
def extract_isce_metadata(meta_file, geom_dir=None, rsc_file=None, update_mode=True):
"""Extract metadata from ISCE stack products
Parameters: meta_file : str, path of metadata file, reference/IW1.xml or referenceShelve/data.dat
geom_dir : str, path of geometry directory.
rsc_file : str, output file name of ROIPAC format rsc file. None for not write to disk.
Returns: meta : dict
frame : object, isceobj.Scene.Frame.Frame / isceobj.Scene.Burst.Burst
"""
# check existing rsc_file
if update_mode and ut.run_or_skip(rsc_file, in_file=meta_file, readable=False) == 'skip':
return readfile.read_roipac_rsc(rsc_file), None
# 1. read/extract metadata from XML / shelve file
processor = get_processor(meta_file)
if processor == 'tops':
print('extract metadata from ISCE/topsStack xml file:', meta_file)
meta, frame = extract_tops_metadata(meta_file)
elif processor == 'alosStack':
print('extract metadata from ISCE/alosStack xml file:', meta_file)
meta, frame = extract_alosStack_metadata(meta_file, geom_dir)
else:
print('extract metadata from ISCE/stripmapStack shelve file:', meta_file)
meta, frame = extract_stripmap_metadata(meta_file)
# 2. extract metadata from geometry file
if geom_dir:
if processor != 'alosStack':
meta = extract_geometry_metadata(geom_dir, meta)
# 3. common metadata
meta['PROCESSOR'] = 'isce'
if 'ANTENNA_SIDE' not in meta.keys():
meta['ANTENNA_SIDE'] = '-1'
# convert all value to string format
for key, value in meta.items():
meta[key] = str(value)
# write to .rsc file
meta = readfile.standardize_metadata(meta)
if rsc_file:
print('writing ', rsc_file)
writefile.write_roipac_rsc(meta, rsc_file)
return meta, frame
def extract_tops_metadata(xml_file):
"""Read metadata from xml file for Sentinel-1/TOPS
Parameters: xml_file : str, path of the .xml file, i.e. reference/IW1.xml
Returns: meta : dict, metadata
burst : isceobj.Sensor.TOPS.BurstSLC.BurstSLC object
"""
import isce
import isceobj
from isceobj.Planet.Planet import Planet
obj = load_product(xml_file)
burst = obj.bursts[0]
burstEnd = obj.bursts[-1]
meta = {}
meta['prf'] = burst.prf
meta['startUTC'] = burst.burstStartUTC
meta['stopUTC'] = burstEnd.burstStopUTC
meta['radarWavelength'] = burst.radarWavelength
meta['startingRange'] = burst.startingRange
meta['passDirection'] = burst.passDirection
meta['polarization'] = burst.polarization
meta['trackNumber'] = burst.trackNumber
meta['orbitNumber'] = burst.orbitNumber
try:
meta['PLATFORM'] = sensor.standardize_sensor_name(obj.spacecraftName)
except:
if os.path.basename(xml_file).startswith('IW'):
meta['PLATFORM'] = 'sen'
time_seconds = (burst.sensingMid.hour * 3600.0 +
burst.sensingMid.minute * 60.0 +
burst.sensingMid.second)
meta['CENTER_LINE_UTC'] = time_seconds
orbit = burst.orbit
peg = orbit.interpolateOrbit(burst.sensingMid, method='hermite')
# Sentinel-1 TOPS pixel spacing
Vs = np.linalg.norm(peg.getVelocity()) #satellite speed
meta['satelliteSpeed'] = Vs
meta['azimuthPixelSize'] = Vs * burst.azimuthTimeInterval
meta['rangePixelSize'] = burst.rangePixelSize
# Sentinel-1 TOPS spatial resolution
iw_str = 'IW2'
if os.path.basename(xml_file).startswith('IW'):
iw_str = os.path.splitext(os.path.basename(xml_file))[0]
meta['azimuthResolution'] = sensor.SENSOR_DICT['sen'][iw_str]['azimuth_resolution']
meta['rangeResolution'] = sensor.SENSOR_DICT['sen'][iw_str]['range_resolution']
elp = Planet(pname='Earth').ellipsoid
llh = elp.xyz_to_llh(peg.getPosition())
elp.setSCH(llh[0], llh[1], orbit.getENUHeading(burst.sensingMid))
meta['HEADING'] = orbit.getENUHeading(burst.sensingMid)
meta['earthRadius'] = elp.pegRadCur
meta['altitude'] = llh[2]
# for Sentinel-1
meta['beam_mode'] = 'IW'
meta['swathNumber'] = burst.swathNumber
# 1. multipel subswaths
xml_files = glob.glob(os.path.join(os.path.dirname(xml_file), 'IW*.xml'))
if len(xml_files) > 1:
swath_num = [load_product(fname).bursts[0].swathNumber for fname in xml_files]
meta['swathNumber'] = ''.join(str(i) for i in sorted(swath_num))
# 2. calculate ASF frame number for Sentinel-1
meta['firstFrameNumber'] = int(0.2 * (burst.burstStartUTC - obj.ascendingNodeTime).total_seconds())
meta['lastFrameNumber'] = int(0.2 * (burstEnd.burstStopUTC - obj.ascendingNodeTime).total_seconds())
return meta, burst
def extract_stripmap_metadata(meta_file):
"""Read metadata from shelve file for StripMap stack from ISCE
Parameters: meta_file : str, path of the shelve file, i.e. referenceShelve/data.dat
Returns: meta : dict, metadata
frame : isceobj.Scene.Frame.Frame object
"""
import isce
import isceobj
from isceobj.Planet.Planet import Planet
if os.path.basename(meta_file).startswith('data'):
# shelve file from stripmapStack
# referenceShelve/data for uavsar
# referenceShelve/data.dat for all the others
fbase = os.path.splitext(meta_file)[0]
with shelve.open(fbase, flag='r') as mdb:
frame = mdb['frame']
elif meta_file.endswith(".xml"): #XML file from stripmapApp
frame = load_product(meta_file)
else:
raise ValueError(f'un-recognized isce/stripmap metadata file: {meta_file}')
meta = {}
meta['prf'] = frame.PRF
meta['startUTC'] = frame.sensingStart
meta['stopUTC'] = frame.sensingStop
meta['radarWavelength'] = frame.radarWavelegth
meta['startingRange'] = frame.startingRange
meta['trackNumber'] = frame.trackNumber
meta['orbitNumber'] = frame.orbitNumber
meta['PLATFORM'] = sensor.standardize_sensor_name(frame.platform.getSpacecraftName())
meta['polarization'] = str(frame.polarization).replace('/', '')
if meta['polarization'].startswith("b'"):
meta['polarization'] = meta['polarization'][2:4]
time_seconds = (frame.sensingMid.hour * 3600.0 +
frame.sensingMid.minute * 60.0 +
frame.sensingMid.second)
meta['CENTER_LINE_UTC'] = time_seconds
orbit = frame.orbit
peg = orbit.interpolateOrbit(frame.sensingMid, method='hermite')
Vs = np.linalg.norm(peg.getVelocity()) #satellite speed
meta['satelliteSpeed'] = Vs
meta['azimuthResolution'] = frame.platform.antennaLength / 2.0
meta['azimuthPixelSize'] = Vs / frame.PRF
frame.getInstrument()
rgBandwidth = frame.instrument.pulseLength * frame.instrument.chirpSlope
meta['rangeResolution'] = abs(SPEED_OF_LIGHT / (2.0 * rgBandwidth))
meta['rangePixelSize'] = frame.instrument.rangePixelSize
elp = Planet(pname='Earth').ellipsoid
llh = elp.xyz_to_llh(peg.getPosition())
elp.setSCH(llh[0], llh[1], orbit.getENUHeading(frame.sensingMid))
meta['HEADING'] = orbit.getENUHeading(frame.sensingMid)
meta['earthRadius'] = elp.pegRadCur
meta['altitude'] = llh[2]
# for StripMap
meta['beam_mode'] = 'SM'
return meta, frame
def extract_alosStack_metadata(meta_file, geom_dir):
"""Read metadata for ISCE/alosStack from the following files:
pairs/*-*/
{date1}.track.xml
f1_{frame1}/{date1}.frame.xml
f2_{frame2}/{date1}.frame.xml
...
Parameters: meta_file : str, path of the track xml file, i.e. pairs/*-*/150408/track.xml
geom_dir : str, path of the geometry directory, i.e. dates_resampled/150408/insar
Returns: meta : dict, metadata
track : isceobj.Sensor.MultiMode.Track.Track object
"""
import isce
import isceobj
from isceobj.Planet.Planet import Planet
# default geom_dir
if not geom_dir:
geom_dir_cand = os.path.join(os.path.dirname(meta_file), 'insar')
if os.path.isdir(geom_dir_cand):
geom_dir = geom_dir_cand
track = load_track(os.path.dirname(meta_file), dateStr=os.path.basename(meta_file).strip('.track.xml'))
rlooks, alooks, width, length = extract_image_size_alosStack(geom_dir)
spotlightModes, stripmapModes, scansarNominalModes, scansarWideModes, scansarModes = alos2_acquisition_modes()
meta = {}
meta['prf'] = track.prf
meta['startUTC'] = track.sensingStart + datetime.timedelta(seconds=(alooks-1.0)/2.0*track.azimuthLineInterval)
meta['stopUTC'] = meta['startUTC'] + datetime.timedelta(seconds=(length-1)*alooks*track.azimuthLineInterval)
meta['radarWavelength'] = track.radarWavelength
meta['startingRange'] = track.startingRange + (rlooks-1.0)/2.0*track.rangePixelSize
meta['passDirection'] = track.passDirection.upper()
meta['polarization'] = track.frames[0].swaths[0].polarization
#meta['trackNumber'] = track.trackNumber
#meta['orbitNumber'] = track.orbitNumber
meta['PLATFORM'] = sensor.standardize_sensor_name('alos2')
sensingSec = (meta['stopUTC'] - meta['startUTC']).total_seconds()
sensingMid = meta['startUTC'] + datetime.timedelta(seconds=sensingSec/2.0)
time_seconds = (sensingMid.hour * 3600.0 +
sensingMid.minute * 60.0 +
sensingMid.second)
meta['CENTER_LINE_UTC'] = time_seconds
peg = track.orbit.interpolateOrbit(sensingMid, method='hermite')
Vs = np.linalg.norm(peg.getVelocity())
meta['satelliteSpeed'] = Vs
meta['azimuthPixelSize'] = Vs * track.azimuthLineInterval
meta['rangePixelSize'] = track.rangePixelSize
azBandwidth = track.prf * 0.8
if track.operationMode in scansarNominalModes:
azBandwidth /= 5.0
if track.operationMode in scansarWideModes:
azBandwidth /= 7.0
#use a mean burst synchronizatino here
if track.operationMode in scansarModes:
azBandwidth *= 0.85
meta['azimuthResolution'] = Vs * (1.0/azBandwidth)
meta['rangeResolution'] = 0.5 * SPEED_OF_LIGHT * (1.0/track.frames[0].swaths[0].rangeBandwidth)
elp = Planet(pname='Earth').ellipsoid
llh = elp.xyz_to_llh(peg.getPosition())
elp.setSCH(llh[0], llh[1], track.orbit.getENUHeading(sensingMid))
meta['HEADING'] = track.orbit.getENUHeading(sensingMid)
meta['earthRadius'] = elp.pegRadCur
meta['altitude'] = llh[2]
meta['beam_mode'] = track.operationMode
meta['swathNumber'] = ''.join(str(swath.swathNumber) for swath in track.frames[0].swaths)
meta['firstFrameNumber'] = track.frames[0].frameNumber
meta['lastFrameNumber'] = track.frames[-1].frameNumber
meta['ALOOKS'] = alooks
meta['RLOOKS'] = rlooks
# NCORRLOOKS for coherence calibration
rgfact = float(meta['rangeResolution']) / float(meta['rangePixelSize'])
azfact = float(meta['azimuthResolution']) / float(meta['azimuthPixelSize'])
meta['NCORRLOOKS'] = meta['RLOOKS'] * meta['ALOOKS'] / (rgfact * azfact)
# update pixel_size for multilooked data
meta['rangePixelSize'] *= meta['RLOOKS']
meta['azimuthPixelSize'] *= meta['ALOOKS']
# LAT/LON_REF1/2/3/4
lat_files = glob.glob(os.path.join(geom_dir, f'*_{rlooks}rlks_{alooks}alks.lat'))
if len(lat_files) > 0:
# geometry files from alosStack
lat_files = glob.glob(os.path.join(geom_dir, f'*_{rlooks}rlks_{alooks}alks.lat'))
lon_files = glob.glob(os.path.join(geom_dir, f'*_{rlooks}rlks_{alooks}alks.lon'))
los_files = glob.glob(os.path.join(geom_dir, f'*_{rlooks}rlks_{alooks}alks.los'))
else:
# geometry files from alos2App / dense offset, which are then multilooked by mintpy
lat_files = [os.path.join(geom_dir, 'lat.rdr.mli')]
lon_files = [os.path.join(geom_dir, 'lon.rdr.mli')]
los_files = [os.path.join(geom_dir, 'los.rdr.mli')]
edge = 3
img = isceobj.createImage()
img.load(lat_files[0] + '.xml')
width = img.width
length = img.length
data = np.memmap(lat_files[0], dtype='float64', mode='r', shape=(length, width))
meta['LAT_REF1'] = str(data[ 0+edge, 0+edge])
meta['LAT_REF2'] = str(data[ 0+edge, -1-edge])
meta['LAT_REF3'] = str(data[-1-edge, 0+edge])
meta['LAT_REF4'] = str(data[-1-edge, -1-edge])
data = np.memmap(lon_files[0], dtype='float64', mode='r', shape=(length, width))
meta['LON_REF1'] = str(data[ 0+edge, 0+edge])
meta['LON_REF2'] = str(data[ 0+edge, -1-edge])
meta['LON_REF3'] = str(data[-1-edge, 0+edge])
meta['LON_REF4'] = str(data[-1-edge, -1-edge])
# CENTER_INCIDENCE_ANGLE is optional
if len(los_files) > 0:
# use readfile.read() instead of np.memmap() to better handle different interleaves
data = readfile.read(los_files[0], datasetName='incidenceAngle')[0]
inc_angle = data[int(length/2), int(width/2)]
meta['CENTER_INCIDENCE_ANGLE'] = str(inc_angle)
pointingDirection = {'right': -1, 'left' :1}
meta['ANTENNA_SIDE'] = str(pointingDirection[track.pointingDirection])
return meta, track
def alos2_acquisition_modes():
'''
return ALOS-2 acquisition mode
'''
spotlightModes = ['SBS']
# StripMap: Ultrafine [3 m], High sensitive [6 m], Fine [10 m]
stripmapModes = ['UBS', 'UBD', 'HBS', 'HBD', 'HBQ', 'FBS', 'FBD', 'FBQ']
scansarNominalModes = ['WBS', 'WBD', 'WWS', 'WWD']
scansarWideModes = ['VBS', 'VBD']
scansarModes = scansarNominalModes + scansarWideModes
return (spotlightModes, stripmapModes, scansarNominalModes, scansarWideModes, scansarModes)
def extract_image_size_alosStack(geom_dir):
# grab the number of looks in azimuth / range direction
lat_files = glob.glob(os.path.join(geom_dir, '*_*rlks_*alks.lat'))
lat_xml_files = [os.path.join(geom_dir, f'lat.rdr{x}.xml') for x in ['', '.mli']]
lat_xml_files = [x for x in lat_xml_files if os.path.exists(x)]
if len(lat_files) > 0:
# alosStack for InSAR
rlooks = max(int(os.path.splitext(os.path.basename(x))[0].split('_')[1].strip('rlks')) for x in lat_files)
alooks = max(int(os.path.splitext(os.path.basename(x))[0].split('_')[2].strip('alks')) for x in lat_files)
lat_xml_file = glob.glob(os.path.join(geom_dir, f'*_{rlooks}rlks_{alooks}alks.lat.xml'))[0]
elif len(lat_xml_files) == 2:
# alos2App for dense offset, which are multilooked by mintpy
meta_ori = readfile.read_isce_xml(lat_xml_files[0])
meta_mli = readfile.read_isce_xml(lat_xml_files[1])
rlooks = int(np.floor( int(meta_ori['WIDTH']) / int(meta_mli['WIDTH']) ))
alooks = int(np.floor( int(meta_ori['LENGTH']) / int(meta_mli['LENGTH']) ))
lat_xml_file = lat_xml_files[1]
else:
raise ValueError(f'Un-recognized lookup table files in directory: {geom_dir}!')
# grab the number of rows / coluns
meta_mli = readfile.read_isce_xml(lat_xml_file)
width = int(meta_mli['WIDTH'])
length = int(meta_mli['LENGTH'])
return (rlooks, alooks, width, length)
def load_track(trackDir, dateStr):
'''Load the track using Product Manager.
Parameters: trackDir - str, directory of the *.track.xml file
dateStr - str, date in YYMMDD format
Returns: track - isceobj.Sensor.MultiMode.Track.Track object
'''
# read *.track.xml file
track = load_product(os.path.join(trackDir, f'{dateStr}.track.xml'))
# read *.frame.xml files
track.frames = []
fnames = sorted(glob.glob(os.path.join(trackDir, f'f*_*/{dateStr}.frame.xml')))
for fname in fnames:
track.frames.append(load_product(fname))
return track
##################################### geometry #######################################
def extract_multilook_number(geom_dir, meta=dict(), fext_list=['.rdr','.geo','.rdr.full','.geo.full']):
for fbase in ['hgt','lat','lon','los','shadowMask']:
fbase = os.path.join(geom_dir, fbase)
# get the file name of the geometry file of interest
for fext in fext_list:
fnames = glob.glob(fbase+fext)
if len(fnames) > 0:
fname = fnames[0]
# get the file name of the full resolution metadata file
full_meta_files = [f'{fname}.full.xml', f'{fname}.full.vrt']
full_meta_files = [x for x in full_meta_files if os.path.isfile(x)]
if len(full_meta_files) > 0:
full_meta_file = full_meta_files[0]
# calc A/RLOOKS
if full_meta_file.endswith('.xml'):
full_dict = readfile.read_isce_xml(full_meta_file)
else:
full_dict = readfile.read_gdal_vrt(full_meta_file)
mli_dict = readfile.read_attribute(fname)
meta['ALOOKS'] = int(int(full_dict['LENGTH']) / int(mli_dict['LENGTH']))
meta['RLOOKS'] = int(int(full_dict['WIDTH']) / int(mli_dict['WIDTH']))
break
# default value
for key in ['ALOOKS', 'RLOOKS']:
if key not in meta:
meta[key] = 1
# NCORRLOOKS for coherence calibration
rgfact = float(meta['rangeResolution']) / float(meta['rangePixelSize'])
azfact = float(meta['azimuthResolution']) / float(meta['azimuthPixelSize'])
meta['NCORRLOOKS'] = meta['RLOOKS'] * meta['ALOOKS'] / (rgfact * azfact)
return meta
def extract_geometry_metadata(geom_dir, meta=dict(), box=None, fbase_list=['hgt','lat','lon','los'],
fext_list=['.rdr','.geo','.rdr.full','.geo.full']):
"""Extract / update metadata from geometry files
extract LAT_REF1/2/3/4 from lat*
extract LON_REF1/2/3/4 from lon*
extract HEADING from los (azimuth angle)
extract A/RLOOKS by comparing hgt.xml and hgt.full.xml file
update azimuthPixelSize / rangePixelSize based on A/RLOOKS
extract LENGTH/WIDTH from the first geom file
update corresponding metadata if box is not None
"""
def get_nonzero_row_number(data, buffer=2):
"""Find the first and last row number of rows without zero value
for multiple swaths data
"""
if np.all(data):
r0, r1 = 0 + buffer, -1 - buffer
else:
row_flag = np.sum(data != 0., axis=1) == data.shape[1]
row_idx = np.where(row_flag)[0]
r0, r1 = row_idx[0] + buffer, row_idx[-1] - buffer
return r0, r1
# grab existing files
geom_dir = os.path.abspath(geom_dir)
for fext in fext_list:
geom_files = [os.path.join(geom_dir, fbase+fext) for fbase in fbase_list]
geom_files = [i for i in geom_files if os.path.isfile(i)]
if len(geom_files) > 0:
break
# printout message
if len(geom_files) == 0:
msg = 'WARNING: No geometry files found with the following pattern!'
msg += f'\n file basenme: {fbase_list}'
msg += f'\n file extension: {fext_list}'
print(msg)
return meta
print(f'extract metadata from geometry files: {[os.path.basename(i) for i in geom_files]}')
# get A/RLOOKS
meta = extract_multilook_number(geom_dir, meta, fext_list=fext_list)
# update pixel_size for multilooked data
meta['rangePixelSize'] *= meta['RLOOKS']
meta['azimuthPixelSize'] *= meta['ALOOKS']
# get LENGTH/WIDTH
atr = readfile.read_attribute(geom_files[0])
meta['LENGTH'] = atr['LENGTH']
meta['WIDTH'] = atr['WIDTH']
# update due to subset
if box:
meta = attr.update_attribute4subset(meta, box)
# get LAT/LON_REF1/2/3/4 into metadata
for geom_file in geom_files:
if 'lat' in os.path.basename(geom_file):
data = readfile.read(geom_file, box=box)[0]
r0, r1 = get_nonzero_row_number(data)
meta['LAT_REF1'] = str(data[r0, 0])
meta['LAT_REF2'] = str(data[r0, -1])
meta['LAT_REF3'] = str(data[r1, 0])
meta['LAT_REF4'] = str(data[r1, -1])
if 'lon' in os.path.basename(geom_file):
data = readfile.read(geom_file, box=box)[0]
r0, r1 = get_nonzero_row_number(data)
meta['LON_REF1'] = str(data[r0, 0])
meta['LON_REF2'] = str(data[r0, -1])
meta['LON_REF3'] = str(data[r1, 0])
meta['LON_REF4'] = str(data[r1, -1])
if 'los' in os.path.basename(geom_file):
# CENTER_INCIDENCE_ANGLE
data = readfile.read(geom_file, datasetName='inc', box=box)[0]
data[data == 0.] = np.nan
inc_angle = data[int(data.shape[0]/2), int(data.shape[1]/2)]
meta['CENTER_INCIDENCE_ANGLE'] = str(inc_angle)
return meta
##################################### baseline #######################################
def read_tops_baseline(baseline_file):
"""Read baseline file generated by ISCE/topsStack processor.
Example:
baselines/20141213_20160418/20141213_20160418.txt:
swath: IW1
Bperp (average): 62.62863491739495
Bpar (average): -29.435602419751426
swath: IW2
Bperp (average): 60.562020649374034
Bpar (average): -34.56105358031081
"""
bperps = []
with open(baseline_file) as f:
for line in f:
c = line.split(":")
if c[0] == "Bperp (average)":
bperps.append(float(c[1]))
bperp_top = np.mean(bperps)
bperp_bottom = np.mean(bperps)
return [bperp_top, bperp_bottom]
def read_stripmap_baseline(baseline_file):
"""Read baseline file generated by ISCE/stripmapStack processor.
Example:
baselines/20200111_20200125.txt
PERP_BASELINE_BOTTOM 173.97914535263297
PERP_BASELINE_TOP 174.05612879066618
"""
fDict = readfile.read_template(baseline_file, delimiter=' ')
bperp_top = float(fDict['PERP_BASELINE_TOP'])
bperp_bottom = float(fDict['PERP_BASELINE_BOTTOM'])
return [bperp_top, bperp_bottom]
def read_alosStack_baseline(baseline_file):
'''read baseline file generated by alosStack
'''
bDict = {}
with open(baseline_file) as f:
lines = [line for line in f if line.strip() != '']
for x in lines[2:]:
blist = x.split()
#to fit into the format of other processors, all alos satellites are after 2000
blist[0] = '20' + blist[0]
blist[1] = '20' + blist[1]
bDict[blist[1]] = [float(blist[3]), float(blist[3])]
bDict[blist[0]] = [0, 0]
return bDict, blist[0]
def read_baseline_timeseries(baseline_dir, processor='tops', ref_date=None):
"""Read bperp time-series from files in baselines directory
Parameters: baseline_dir : str, path to the baselines directory
processor : str, tops for Sentinel-1/TOPS
stripmap for StripMap data
ref_date : str, reference date in (YY)YYMMDD
Returns: bDict : dict, in the following format:
{'20141213': [0.0, 0.0],
'20141225': [104.6, 110.1],
...
}
"""
# grab all existed baseline files
print(f'read perp baseline time-series from {baseline_dir}')
if processor == 'tops':
bFiles = sorted(glob.glob(os.path.join(baseline_dir, '*/*.txt')))
elif processor == 'stripmap':
bFiles = sorted(glob.glob(os.path.join(baseline_dir, '*.txt')))
elif processor == 'alosStack':
# all baselines are in baseline_center.txt
bFiles = glob.glob(os.path.join(baseline_dir, 'baseline_center.txt'))
else:
raise ValueError(f'Un-recognized ISCE stack processor: {processor}')
if len(bFiles) == 0:
print(f'WARNING: no baseline text file found in dir {os.path.abspath(baseline_dir)}')
return None
if processor in ['tops', 'stripmap']:
# ignore files with different date1
# when re-run with different reference date
date1s = [os.path.basename(i).split('_')[0] for i in bFiles]
date1c = ut.most_common(date1s)
bFiles = [i for i in bFiles if os.path.basename(i).split('_')[0] == date1c]
# ignore empty files
bFiles = [i for i in bFiles if os.path.getsize(i) > 0]
# read files into dict
bDict = {}
for bFile in bFiles:
dates = os.path.basename(bFile).split('.txt')[0].split('_')
if processor == 'tops':
bDict[dates[1]] = read_tops_baseline(bFile)
else:
bDict[dates[1]] = read_stripmap_baseline(bFile)
bDict[dates[0]] = [0, 0]
ref_date0 = dates[0]
elif processor == 'alosStack':
bDict, ref_date0 = read_alosStack_baseline(bFiles[0])
else:
raise ValueError(f'Un-recognized ISCE stack processor: {processor}')
# change reference date
if ref_date is not None and ref_date != ref_date0:
ref_date = ptime.yyyymmdd(ref_date)
print(f'change reference date to {ref_date}')
ref_bperp = bDict[ref_date]
for key in bDict.keys():
bDict[key][0] -= ref_bperp[0]
bDict[key][1] -= ref_bperp[1]
return bDict
##################################### multilook #######################################
def multilook_number2resolution(meta_file, az_looks, rg_looks):
# get full resolution info
az_pixel_size, az_spacing, rg_pixel_size, rg_spacing = get_full_resolution(meta_file)
# print out message
print(f'Azimuth pixel size : {az_pixel_size:.1f}')
print(f'Azimuth ground spacing : {az_spacing:.1f}')
print(f'Azimuth ground spacing : {az_spacing*az_looks:.1f} after multilooking by {az_looks}')
print(f'Range pixel size : {rg_pixel_size:.1f}')
print(f'Range ground spacing : {rg_spacing:.1f}')
print(f'Range ground spacing : {rg_spacing*rg_looks:.1f} after multilooking by {rg_looks}')
return
def resolution2multilook_number(meta_file, resolution):
"""
Calculate multilook number for InSAR processing given a desired output resolution on the ground
Parameters: meta_file : str, path of ISCE metadata file, i.e. IW1.xml, data.dat
resolution : float, target output resolution on the ground in meters
Returns: az/rg_looks : int, number of looks in azimuth / range direction
"""
# get full resolution info
az_pixel_size, az_spacing, rg_pixel_size, rg_spacing = get_full_resolution(meta_file)
# calculate number of looks
# 1. adjust the final resolution in one direction closest to the input resolution
az_looks = resolution / az_spacing
rg_looks = resolution / rg_spacing
az_round_frac = abs(az_looks - np.rint(az_looks))
rg_round_frac = abs(rg_looks - np.rint(rg_looks))
if az_round_frac < rg_round_frac:
resolution = np.rint(az_looks) * az_spacing
else:
resolution = np.rint(rg_looks) * rg_spacing
# 2. calculate the multilook number based on the adjusted resolution
az_looks = np.rint(resolution / az_spacing).astype(int)
rg_looks = np.rint(resolution / rg_spacing).astype(int)
# print out message
print(f'Azimuth pixel size : {az_pixel_size:.1f}')
print(f'Azimuth ground spacing : {az_spacing:.1f}')
print(f'Azimuth ground spacing : {az_spacing*az_looks:.1f} after multilooking by {az_looks}')
print(f'Range pixel size : {rg_pixel_size:.1f}')
print(f'Range ground spacing : {rg_spacing:.1f}')
print(f'Range ground spacing : {rg_spacing*rg_looks:.1f} after multilooking by {rg_looks}')
return az_looks, rg_looks
def get_full_resolution(meta_file):
"""
Grab the full resolution in terms of pixel_size and ground spacing
"""
# check metadata file extension: only ISCE format is supported.
fext = os.path.splitext(meta_file)[1]
if fext not in ['.xml', '.dat']:
raise ValueError(f'input ISCE metadata file extension "{fext}" not in [.xml, .dat]')
# get middle sub-swath xml file for Sentinel-1 data
if meta_file.endswith('.xml'):
meta_files = glob.glob(meta_file)
mid_idx = int(len(meta_files) / 2)
meta_file = meta_files[mid_idx]
# extract metadata
meta, frame = extract_isce_metadata(meta_file, update_mode=False)
meta['WIDTH'] = frame.numberOfSamples
# calculate the full azimuth/range ground resolution
az_pixel_size = float(meta['AZIMUTH_PIXEL_SIZE']) #azimuth pixel size on the orbit
rg_pixel_size = float(meta['RANGE_PIXEL_SIZE']) #range pixel size in LOS direction
az_pixel_size /= int(meta.get('ALOOKS', 1))
rg_pixel_size /= int(meta.get('RLOOKS', 1))
height = float(meta['HEIGHT'])
inc_angle = ut.incidence_angle(meta, dimension=0)
az_spacing = az_pixel_size * EARTH_RADIUS / (EARTH_RADIUS + height) #azimuth pixel size on the ground
rg_spacing = rg_pixel_size / np.sin(inc_angle / 180. * np.pi) #range pixel size on the ground
return az_pixel_size, az_spacing, rg_pixel_size, rg_spacing
##################################### miscellaneous #######################################
def get_IPF(proj_dir, ts_file):
"""Grab the IPF version number of each sub-swatch for Sentinel-1 time-series
Parameters: proj_dir - str, path of the project directory
E.g.: ~/data/AtacamaSenDT149
ts_file - str, path of HDF5 file for time-series
Returns: date_list - list of str, dates in YYYYMMDD format
IFP_IW1/2/3 - list of str, IFP version number
"""
from mintpy.objects import timeseries
s_dir = os.path.join(proj_dir, 'secondarys')
m_dir = os.path.join(proj_dir, 'reference')
# date list
date_list = timeseries(ts_file).get_date_list()
num_date = len(date_list)
# reference date
m_date = [i for i in date_list if not os.path.isdir(os.path.join(s_dir, i))][0]
# grab IPF number
IPF_IW1, IPF_IW2, IPF_IW3 = [], [], []
prog_bar = ptime.progressBar(maxValue=num_date)
for i in range(num_date):
date_str = date_list[i]
# get xml_dir
if date_str == m_date:
xml_dir = m_dir
else:
xml_dir = os.path.join(s_dir, date_str)
# grab IPF version number
for j, IPF_IW in enumerate([IPF_IW1, IPF_IW2, IPF_IW3]):
xml_file = os.path.join(xml_dir, f'IW{j+1}.xml')
IPFv = load_product(xml_file).processingSoftwareVersion
IPF_IW.append(f'{float(IPFv):.02f}')
prog_bar.update(i+1, suffix=f'{date_str} IW1/2/3')
prog_bar.close()
return date_list, IPF_IW1, IPF_IW2, IPF_IW3
def get_sensing_datetime_list(proj_dir, date_list=None):
"""Get the sensing datetime objects from ISCE stack results.
It assumes the default directory structure from topsStack, as below:
/proj_dir
/reference/IW*.xml
/secondarys
/20150521/IW*.xml
/20150614/IW*.xml
...
/20210113/IW*.xml
Parameters: proj_dir - str, path to the root directory of stack processing
Returns: sensingMid - list of datetime.datetime.obj
sensingStart - list of datetime.datetime.obj
sensingStop - list of datetime.datetime.obj
"""
# determine xml file basename
ref_fname = glob.glob(os.path.join(proj_dir, 'reference', 'IW*.xml'))[0]
fbase = os.path.basename(ref_fname)
# get xml files for all acquisitions
sec_fnames = sorted(glob.glob(os.path.join(proj_dir, 'secondarys', '*', fbase)))
fnames = [ref_fname] + sec_fnames
num_file = len(fnames)
# loop to read file one by one
sensingStart = []
sensingStop = []
for i, fname in enumerate(fnames):
print(f'[{i+1}/{num_file}] read {fname}')
obj = load_product(fname)
sensingStart.append(obj.bursts[0].sensingStart)
sensingStop.append(obj.bursts[-1].sensingStop)
sensingStart = sorted(sensingStart)
sensingStop = sorted(sensingStop)
# sensingStart/Stop --> sensingMid
sensingMid = [i + (j - i)/2 for i, j in zip(sensingStart, sensingStop)]
# round to the nearest second
print('round sensingStart/Stop/Mid to the nearest second.')
sensingStart = [ptime.round_seconds(i) for i in sensingStart]
sensingStop = [ptime.round_seconds(i) for i in sensingStop]
sensingMid = [ptime.round_seconds(i) for i in sensingMid]
if date_list is not None:
date_str_format = ptime.get_date_str_format(date_list[0])
date_list_out = [i.strftime(date_str_format) for i in sensingMid]
# check possible missing dates
dates_missing = [i for i in date_list if i not in date_list_out]
if dates_missing:
raise ValueError(f'The following dates are missing:\n{dates_missing}')
# prune dates not-needed
flag = np.array([i in date_list for i in date_list_out], dtype=np.bool_)
if np.sum(flag) > 0:
sensingMid = np.array(sensingMid)[flag].tolist()
sensingStart = np.array(sensingStart)[flag].tolist()
sensingStop = np.array(sensingStop)[flag].tolist()
dates_removed = np.array(date_list_out)[~flag].tolist()
print(f'The following dates are not needed and removed:\n{dates_removed}')
return sensingMid, sensingStart, sensingStop
############################## Standard Processing ###########################################
def gaussian_kernel(sx, sy, sig_x, sig_y):
'''Generate a Gaussian kernel (with all elements sum to 1).
Parameters: sx/y - int, dimensions of kernel
sig_x/y - float, standard deviation of the Gaussian distribution
'''
# ensure sx/y are odd number
sx += 1 if np.mod(sx, 2) == 0 else 0
sy += 1 if np.mod(sy, 2) == 0 else 0
x, y = np.meshgrid(np.arange(sx), np.arange(sy))
x += 1
y += 1
xc = (sx + 1) / 2
yc = (sy + 1) / 2
fx = ((x-xc)**2.) / (2.*sig_x**2.)
fy = ((y-yc)**2.) / (2.*sig_y**2.)
k = np.exp(-1.0 * (fx+fy))
a = 1./np.sum(k)
k = a * k
return k
def convolve(data, kernel):
'''Convolve / filter the complex data based on the given kernel.
Parameters: data - 2D np.ndarray in complex
kernel - 2D np.ndarray in float, convolution kernel
'''
real = ndimage.convolve(data.real, kernel, mode='constant', cval=0.0)
imag = ndimage.convolve(data.imag, kernel, mode='constant', cval=0.0)
return real + 1J * imag
def crop_slc(slc_file, sub_slc_file, x0=None, y0=None, x1=None, y1=None):
"""Crop / subset the complex ISCE-2 SLC file in complex64.
Parameters: slc_file - str, path to the SLC data file
sub_slc_file - str, path to the cropped SLC data file
x0/y0/x1/y1 - int, starting column / row, and ending column/row
Returns: sub_slc_file - str, path to the cropped SLC data file
"""
# default arg values
atr = readfile.read_attribute(slc_file)
length, width = int(atr['LENGTH']), int(atr['WIDTH'])
x0 = 0 if x0 is None else x0
y0 = 0 if y0 is None else y0
x1 = width if x1 is None else x1
y1 = length if y1 is None else y1
# read
slc_data = readfile.read_binary(
slc_file,
shape=(length, width),
box=(x0, y0, x1, y1),
data_type='complex64',
cpx_band='complex',
)
# create output directory if not exist
if not os.path.isdir(os.path.dirname(sub_slc_file)):
os.makedirs(os.path.dirname(sub_slc_file), exist_ok=True)
print('create diretory:', os.path.dirname(sub_slc_file))