def unwrap(self):
snp = Snaphu()
snp.setInput(self.wrapName)
snp.setOutput(self.unwrapName)
snp.setWidth(self.width)
snp.setCostMode(self.costMode)
snp.setEarthRadius(self.earthRadius)
snp.setWavelength(self.wavelength)
snp.setAltitude(self.altitude)
snp.setCorrfile(self.corrfile)
snp.setInitMethod(self.initMethod)
snp.setCorrLooks(self.corrLooks)
snp.setMaxComponents(self.maxComponents)
snp.setDefoMaxCycles(self.defomax)
snp.setRangeLooks(self.rangeLooks)
snp.setAzimuthLooks(self.azimuthLooks)
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createImage()
outImage.setFilename(self.unwrapName)
outImage.setWidth(self.width)
outImage.bands = 2
outImage.scheme = 'BIL'
outImage.imageType='unw'
outImage.dataType='FLOAT'
outImage.setAccessMode('read')
outImage.createImage()
outImage.finalizeImage()
outImage.renderHdr()
def unwrap_snaphu(inps, length, width):
import isce
import isceobj
from contrib.Snaphu.Snaphu import Snaphu
altitude = 800000.0
earthRadius = 6371000.0
wavelength = 0.056
snp = Snaphu()
snp.setInitOnly(False)
snp.setInput(inps.interferogramFile)
snp.setOutput(inps.unwrapFile)
snp.setWidth(width)
snp.setCostMode('DEFO')
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(inps.coherenceFile)
snp.setInitMethod('MST')
# snp.setCorrLooks(corrLooks)
snp.setMaxComponents(100)
snp.setDefoMaxCycles(2.0)
snp.setRangeLooks(1)
snp.setAzimuthLooks(1)
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
write_xml(inps.unwrapFile, width, length, 2 , "FLOAT", "BIL")
write_xml(inps.unwrapFile+'.conncomp', width, length, 1, "BYTE", "BIP")
def main(iargs=None):
"""
Unwrap interferograms.
"""
Parser = MinoPyParser(iargs, script='unwrap_minopy')
inps = Parser.parse()
if not 'unwrap_2stage' in inps:
inps.unwrap_2stage = False
dateStr = datetime.datetime.strftime(datetime.datetime.now(), '%Y%m%d:%H%M%S')
if not iargs is None:
msg = os.path.basename(__file__) + ' ' + ' '.join(iargs[:])
string = dateStr + " * " + msg
print(string)
else:
msg = os.path.basename(__file__) + ' ' + ' '.join(sys.argv[1::])
string = dateStr + " * " + msg
print(string)
time0 = time.time()
inps.work_dir = os.path.dirname(inps.input_ifg)
if not os.path.exists(inps.work_dir + '/filt_fine.unw.conncomp.vrt'):
unwObj = Snaphu(inps)
do_tiles, metadata = unwObj.need_to_split_tiles()
try:
if do_tiles:
#print('1')
unwObj.unwrap_tile()
else:
#print('2')
unwObj.unwrap()
except:
#print('3')
runUnwrap(inps.input_ifg, inps.unwrapped_ifg, inps.input_cor, metadata, inps.unwrap_2stage)
if inps.unwrap_2stage:
temp_unwrap = os.path.dirname(inps.unwrapped_ifg) + '/temp_filt_fine.unw'
inpFile = temp_unwrap
ccFile = glob.glob(os.path.dirname(inps.unwrapped_ifg) + '/*conncomp')[0]
outFile = inps.unwrapped_ifg
unwrap_2stage(inpFile, ccFile, outFile, unwrapper_2stage_name=None, solver_2stage=None)
if inps.remove_filter_flag and not os.path.exists(inps.unwrapped_ifg + '.old'):
input_ifg_nofilter = os.path.join(os.path.dirname(inps.input_ifg), 'fine.int')
remove_filter(input_ifg_nofilter, inps.input_ifg, inps.unwrapped_ifg)
print('Time spent: {} m'.format((time.time() - time0)/60))
return
def main():
inputFilename = sys.argv[1]
outputFilename = sys.argv[2]
snaphu = Snaphu()
snaphu.setInput(inputFilename)
snaphu.setOutput(outputFilename)
snaphu.setWidth(710)
snaphu.setCostMode('DEFO')
snaphu.setEarthRadius(6356236.24233467)
snaphu.setWavelength(0.0562356424)
snaphu.setAltitude(788151.7928135)
print "Preparing"
snaphu.prepare()
snaphu.unwrap()
def runUnwrap(self,costMode = None,initMethod = None, defomax = None, initOnly = None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
wrapName = self.insar.topophaseFlatFilename
unwrapName = self.insar.unwrappedIntFilename
wavelength = self.insar.masterFrame.getInstrument().getRadarWavelength()
width = self.insar.resampIntImage.width
earthRadius = self.insar.peg.radiusOfCurvature
altitude = self.insar.averageHeight
corrfile = self.insar.getCoherenceFilename()
rangeLooks = self.insar.topo.numberRangeLooks
azimuthLooks = self.insar.topo.numberAzimuthLooks
azres = self.insar.masterFrame.platform.antennaLength/2.0
azfact = self.insar.topo.numberAzimuthLooks *azres / self.insar.topo.azimuthSpacing
rBW = self.insar.masterFrame.instrument.pulseLength * self.insar.masterFrame.instrument.chirpSlope
rgres = abs(SPEED_OF_LIGHT / (2.0 * rBW))
rngfact = rgres/self.insar.topo.slantRangePixelSpacing
corrLooks = self.insar.topo.numberRangeLooks * self.insar.topo.numberAzimuthLooks/(azfact*rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName+'.conncomp')
#At least one can query for the name used
self.insar.connectedComponentsFilename = unwrapName+'.conncomp'
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.finalizeImage()
connImage.renderHdr()
return
def snaphuUnwrap(track,
t,
wrapName,
corName,
unwrapName,
nrlks,
nalks,
costMode='DEFO',
initMethod='MST',
defomax=4.0,
initOnly=False):
#runUnwrap(self, costMode = 'SMOOTH',initMethod = 'MCF', defomax = 2, initOnly = True)
'''
track: track object
t: time for computing earth radius and altitude, normally mid azimuth time
wrapName: input interferogram
corName: input coherence file
unwrapName: output unwrapped interferogram
nrlks: number of range looks of the interferogram
nalks: number of azimuth looks of the interferogram
'''
import datetime
import numpy as np
import isceobj
from contrib.Snaphu.Snaphu import Snaphu
from isceobj.Planet.Planet import Planet
corImg = isceobj.createImage()
corImg.load(corName + '.xml')
width = corImg.width
length = corImg.length
#get altitude
orbit = track.orbit
peg = orbit.interpolateOrbit(t, method='hermite')
refElp = Planet(pname='Earth').ellipsoid
llh = refElp.xyz_to_llh(peg.getPosition())
hdg = orbit.getENUHeading(t)
refElp.setSCH(llh[0], llh[1], hdg)
earthRadius = refElp.pegRadCur
altitude = llh[2]
rangeLooks = nrlks
azimuthLooks = nalks
azfact = 0.8
rngfact = 0.8
corrLooks = rangeLooks * azimuthLooks / (azfact * rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(track.radarWavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corName)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
if corImg.bands == 1:
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.renderVRT()
outImage.createImage()
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.renderVRT()
connImage.createImage()
connImage.finalizeImage()
connImage.renderHdr()
del connImage
del corImg
del snp
del outImage
#remove wired things in no-data area
amp = np.memmap(unwrapName,
dtype='float32',
mode='r+',
shape=(length * 2, width))
wrap = np.fromfile(wrapName, dtype=np.complex64).reshape(length, width)
(amp[0:length * 2:2, :])[np.nonzero(wrap == 0)] = 0
(amp[1:length * 2:2, :])[np.nonzero(wrap == 0)] = 0
del amp
del wrap
return
def runUnwrap(self,
costMode=None,
initMethod=None,
defomax=None,
initOnly=None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
wavelength = self.insar.masterFrame.getInstrument().getRadarWavelength()
width = self.insar.resampIntImage.width
earthRadius = self.insar.peg.radiusOfCurvature
altitude = self.insar.averageHeight
corrfile = self.insar.getCoherenceFilename()
rangeLooks = self.insar.topo.numberRangeLooks
azimuthLooks = self.insar.topo.numberAzimuthLooks
azres = self.insar.masterFrame.platform.antennaLength / 2.0
azfact = self.insar.topo.numberAzimuthLooks * azres / self.insar.topo.azimuthSpacing
rBW = self.insar.masterFrame.instrument.pulseLength * self.insar.masterFrame.instrument.chirpSlope
rgres = abs(SPEED_OF_LIGHT / (2.0 * rBW))
rngfact = rgres / self.insar.topo.slantRangePixelSpacing
corrLooks = self.insar.topo.numberRangeLooks * self.insar.topo.numberAzimuthLooks / (
azfact * rngfact)
maxComponents = 20
#Unfortunately isce changes topophaseFlatFilename to the filtered one so need to change
#it back
self._unwrapList = [
(self.insar.topophaseFlatFilename.replace('filt_', ''),
self.insar.topophaseFlatFilename.replace('.flat',
'.unw').replace('filt_',
'')),
(self.insar.filt_topophaseFlatFilename,
self.insar.filt_topophaseFlatFilename.replace('.flat', '.unw'))
]
#need to add them to the instance so they can later be part of the geolist
self._unwrappedIntFilename = self._unwrapList[0][1]
self._unwrappedIntFiltFilename = self._unwrapList[1][1]
for wrapName, unwrapName in self._unwrapList:
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.createImage()
outImage.renderHdr()
outImage.finalizeImage()
return
def runUnwrap(infile, outfile, corfile, config, unwrap_2stage=False):
from contrib.Snaphu.Snaphu import Snaphu
costMode = 'DEFO'
initMethod = config['init_method']
defomax = config['defomax']
wrapName = infile
unwrapName = outfile
if unwrap_2stage:
unwrapName = os.path.dirname(outfile) + '/temp_filt_fine.unw'
img = isceobj.createImage()
img.load(infile + '.xml')
wavelength = float(config['wavelength'])
width = img.getWidth()
length = img.getLength()
earthRadius = float(config['earth_radius'])
altitude = float(config['height'])
rangeLooks = int(config['rglooks'])
azimuthLooks = int(config['azlooks'])
snp = Snaphu()
snp.setInitOnly(False)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corfile)
snp.setInitMethod(initMethod)
snp.setMaxComponents(100)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setLength(length)
outImage.setAccessMode('read')
# outImage.createImage()
outImage.renderHdr()
outImage.renderVRT()
# outImage.finalizeImage()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
# At least one can query for the name used
connImage.setWidth(width)
connImage.setLength(length)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
# connImage.createImage()
connImage.renderHdr()
connImage.renderVRT()
# connImage.finalizeImage()
return
def runSnaphu(self,
igramSpectrum="full",
costMode=None,
initMethod=None,
defomax=None,
initOnly=None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
print("igramSpectrum: ", igramSpectrum)
if igramSpectrum == "full":
ifgDirname = self.insar.ifgDirname
elif igramSpectrum == "low":
if not self.doDispersive:
print(
'Estimating dispersive phase not requested ... skipping sub-band interferogram unwrapping'
)
return
ifgDirname = os.path.join(self.insar.ifgDirname,
self.insar.lowBandSlcDirname)
elif igramSpectrum == "high":
if not self.doDispersive:
print(
'Estimating dispersive phase not requested ... skipping sub-band interferogram unwrapping'
)
return
ifgDirname = os.path.join(self.insar.ifgDirname,
self.insar.highBandSlcDirname)
wrapName = os.path.join(ifgDirname, 'filt_' + self.insar.ifgFilename)
if '.flat' in wrapName:
unwrapName = wrapName.replace('.flat', '.unw')
elif '.int' in wrapName:
unwrapName = wrapName.replace('.int', '.unw')
else:
unwrapName = wrapName + '.unw'
corName = os.path.join(ifgDirname, self.insar.coherenceFilename)
referenceFrame = self._insar.loadProduct(
self._insar.referenceSlcCropProduct)
wavelength = referenceFrame.getInstrument().getRadarWavelength()
img1 = isceobj.createImage()
img1.load(wrapName + '.xml')
width = img1.getWidth()
#width = self.insar.resampIntImage.width
orbit = referenceFrame.orbit
prf = referenceFrame.PRF
elp = copy.copy(referenceFrame.instrument.platform.planet.ellipsoid)
sv = orbit.interpolate(referenceFrame.sensingMid, method='hermite')
hdg = orbit.getHeading()
llh = elp.xyz_to_llh(sv.getPosition())
elp.setSCH(llh[0], llh[1], hdg)
earthRadius = elp.pegRadCur
sch, vsch = elp.xyzdot_to_schdot(sv.getPosition(), sv.getVelocity())
azimuthSpacing = vsch[0] * earthRadius / ((earthRadius + sch[2]) * prf)
earthRadius = elp.pegRadCur
altitude = sch[2]
rangeLooks = 1 # self.numberRangeLooks #insar.topo.numberRangeLooks
azimuthLooks = 1 # self.numberAzimuthLooks #insar.topo.numberAzimuthLooks
if not self.numberAzimuthLooks:
self.numberAzimuthLooks = 1
if not self.numberRangeLooks:
self.numberRangeLooks = 1
azres = referenceFrame.platform.antennaLength / 2.0
azfact = self.numberAzimuthLooks * azres / azimuthSpacing
rBW = referenceFrame.instrument.pulseLength * referenceFrame.instrument.chirpSlope
rgres = abs(SPEED_OF_LIGHT / (2.0 * rBW))
rngfact = rgres / referenceFrame.getInstrument().getRangePixelSize()
corrLooks = self.numberRangeLooks * self.numberAzimuthLooks / (azfact *
rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corName)
snp.setInitMethod(initMethod)
#snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.renderHdr()
outImage.renderVRT()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
#At least one can query for the name used
self.insar.connectedComponentsFilename = unwrapName + '.conncomp'
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.renderHdr()
connImage.renderVRT()
return
def runUnwrap(self,
costMode=None,
initMethod=None,
defomax=None,
initOnly=None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
wrapName = self.insar.topophaseFlatFilename
unwrapName = self.insar.unwrappedIntFilename
wavelength = self.insar.masterFrame.getInstrument().getRadarWavelength()
width = self.insar.resampIntImage.width
orbit = self.insar.masterFrame.orbit
prf = self.insar.masterFrame.PRF
elp = copy.copy(
self.insar.masterFrame.instrument.platform.planet.ellipsoid)
sv = orbit.interpolate(self.insar.masterFrame.sensingMid, method='hermite')
hdg = orbit.getHeading()
llh = elp.xyz_to_llh(sv.getPosition())
elp.setSCH(llh[0], llh[1], hdg)
earthRadius = elp.pegRadCur
sch, vsch = elp.xyzdot_to_schdot(sv.getPosition(), sv.getVelocity())
azimuthSpacing = vsch[0] * earthRadius / ((earthRadius + sch[2]) * prf)
earthRadius = elp.pegRadCur
altitude = sch[2]
corrfile = self.insar.getCoherenceFilename()
rangeLooks = self.insar.topo.numberRangeLooks
azimuthLooks = self.insar.topo.numberAzimuthLooks
azres = self.insar.masterFrame.platform.antennaLength / 2.0
azfact = self.insar.topo.numberAzimuthLooks * azres / azimuthSpacing
rBW = self.insar.masterFrame.instrument.pulseLength * self.insar.masterFrame.instrument.chirpSlope
rgres = abs(SPEED_OF_LIGHT / (2.0 * rBW))
rngfact = rgres / self.insar.topo.slantRangePixelSpacing
corrLooks = self.insar.topo.numberRangeLooks * self.insar.topo.numberAzimuthLooks / (
azfact * rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.createImage()
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
#At least one can query for the name used
self.insar.connectedComponentsFilename = unwrapName + '.conncomp'
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.createImage()
connImage.finalizeImage()
connImage.renderHdr()
return
def run(frame1,
width,
costMode,
initMethod,
defomax,
initOnly,
infos,
sceneid='NO_ID'):
logger.info("Unwrapping interferogram using Snaphu %s: %s" %
(initMethod, sceneid))
topo = infos['topo']
wrapName = infos['outputPath'] + '.' + infos['topophaseFlatFilename']
unwrapName = infos['outputPath'] + '.' + infos['unwrappedIntFilename']
corrfile = infos['outputPath'] + '.' + infos['coherenceFilename']
altitude = infos['averageHeight']
wavelength = frame1.getInstrument().getRadarWavelength()
earthRadius = infos['peg'].radiusOfCurvature
rangeLooks = topo.numberRangeLooks
azimuthLooks = topo.numberAzimuthLooks
azres = frame1.platform.antennaLength / 2.0
azfact = topo.numberAzimuthLooks * azres / topo.azimuthSpacing
rBW = frame1.instrument.pulseLength * frame1.instrument.chirpSlope
rgres = abs(SPEED_OF_LIGHT / (2.0 * rBW))
rngfact = rgres / topo.slantRangePixelSpacing
corrLooks = topo.numberRangeLooks * topo.numberAzimuthLooks / (azfact *
rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.imageType = 'unw'
outImage.bands = 2
outImage.scheme = 'BIL'
outImage.dataType = 'FLOAT'
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.finalizeImage()
connImage.renderHdr()
def runUnwrap(infile,
outfile,
corfile,
config,
costMode=None,
initMethod=None,
defomax=None,
initOnly=None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
wrapName = infile
unwrapName = outfile
img = isceobj.createImage()
img.load(infile + '.xml')
wavelength = config['wavelength']
width = img.getWidth()
length = img.getLength()
earthRadius = config['earthRadius']
altitude = config['altitude']
rangeLooks = config['rglooks']
azimuthLooks = config['azlooks']
#corrLooks = config['corrlooks']
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corfile)
snp.setInitMethod(initMethod)
# snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setLength(length)
outImage.setAccessMode('read')
#outImage.createImage()
outImage.renderHdr()
outImage.renderVRT()
#outImage.finalizeImage()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
#At least one can query for the name used
connImage.setWidth(width)
connImage.setLength(length)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
# connImage.createImage()
connImage.renderHdr()
connImage.renderVRT()
# connImage.finalizeImage()
return
def runUnwrap(self,costMode = None,initMethod = None, defomax = None, initOnly = None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
wrapName = os.path.join( self._insar.mergedDirname, self._insar.filtFilename)
unwrapName = os.path.join( self._insar.mergedDirname, self._insar.unwrappedIntFilename)
img = isceobj.createImage()
img.load(wrapName + '.xml')
swathList = self._insar.getValidSwathList(self.swaths)
for swath in swathList[0:1]:
ifg = self._insar.loadProduct( os.path.join(self._insar.fineIfgDirname, 'IW{0}.xml'.format(swath)))
wavelength = ifg.bursts[0].radarWavelength
width = img.getWidth()
####tmid
tstart = ifg.bursts[0].sensingStart
tend = ifg.bursts[-1].sensingStop
tmid = tstart + 0.5*(tend - tstart)
orbit = ifg.bursts[0].orbit
peg = orbit.interpolateOrbit(tmid, method='hermite')
refElp = Planet(pname='Earth').ellipsoid
llh = refElp.xyz_to_llh(peg.getPosition())
hdg = orbit.getENUHeading(tmid)
refElp.setSCH(llh[0], llh[1], hdg)
earthRadius = refElp.pegRadCur
altitude = llh[2]
corrfile = os.path.join(self._insar.mergedDirname, self._insar.coherenceFilename)
rangeLooks = self.numberRangeLooks
azimuthLooks = self.numberAzimuthLooks
azfact = 0.8
rngfact = 0.8
corrLooks = rangeLooks * azimuthLooks/(azfact*rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.renderVRT()
outImage.createImage()
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName+'.conncomp')
#At least one can query for the name used
self._insar.connectedComponentsFilename = unwrapName+'.conncomp'
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.renderVRT()
connImage.createImage()
connImage.finalizeImage()
connImage.renderHdr()
return
def runUnwrap(inps_json):
costMode = 'SMOOTH'
initMethod = 'MCF'
defomax = 2.0
initOnly = True
if isinstance(inps_json,str):
inps = json.load(open(inps_json))
elif isinstance(inps_json,dict):
inps = inps_json
else:
print('Expecting a json filename or a dictionary')
raise ValueError
wrapName = inps['flat_name']
unwrapName = inps['unw_name']
img = isceobj.createImage()
img.load(wrapName + '.xml')
width = img.getWidth()
earthRadius = inps['earth_radius']
altitude = inps['altitude']
corrfile = inps['cor_name']
rangeLooks = inps['range_looks']
azimuthLooks = inps['azimuth_looks']
wavelength = inps['wavelength']
azfact = 0.8
rngfact = 0.8
corrLooks = rangeLooks * azimuthLooks/(azfact*rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly)
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode)
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod)
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax)
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.renderVRT()
outImage.createImage()
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName+'.conncomp')
#At least one can query for the name used
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.renderVRT()
connImage.createImage()
connImage.finalizeImage()
connImage.renderHdr()
return
def runUnwrap(inps,
costMode=None,
initMethod=None,
defomax=None,
initOnly=None):
if costMode is None:
costMode = 'DEFO'
if initMethod is None:
initMethod = 'MST'
if defomax is None:
defomax = 4.0
if initOnly is None:
initOnly = False
#get earth radius and altitude using master's orbit
with open(inps.mframe, 'rb') as f:
mframe = pickle.load(f)
azti = 1.0 / mframe.PRF
tmid = mframe.getSensingStart() + datetime.timedelta(
seconds=azti * (mframe.getNumberOfLines() / 2.0))
orbit = mframe.getOrbit()
peg = orbit.interpolateOrbit(tmid, method='hermite')
refElp = Planet(pname='Earth').ellipsoid
llh = refElp.xyz_to_llh(peg.getPosition())
hdg = orbit.getHeading(tmid)
#change to the following after updated to the newest version of isce
#hdg = orbit.getENUHeading(tmid)
refElp.setSCH(llh[0], llh[1], hdg)
earthRadius = refElp.pegRadCur
altitude = llh[2]
wrapName = inps.inf
unwrapName = inps.unw
corrfile = inps.cor
width = getWidth(wrapName + '.xml')
wavelength = mframe.getInstrument().getRadarWavelength()
rangeLooks = inps.rlks
azimuthLooks = inps.alks
#calculate azimuth resolution and pixel size
azres = mframe.platform.antennaLength / 2.0
vel = np.sqrt(peg.velocity[0] * peg.velocity[0] +
peg.velocity[1] * peg.velocity[1] +
peg.velocity[2] * peg.velocity[2])
hgt = np.sqrt(peg.position[0] * peg.position[0] +
peg.position[1] * peg.position[1] +
peg.position[2] * peg.position[2])
azimuthPixelSpacing = earthRadius / hgt * vel * azti
azfact = azres / azimuthPixelSpacing
#calculate range resolution and pixel size
rBW = mframe.instrument.pulseLength * mframe.instrument.chirpSlope
rgres = abs(SPEED_OF_LIGHT / (2.0 * rBW))
slantRangePixelSpacing = 0.5 * SPEED_OF_LIGHT / mframe.rangeSamplingRate
rngfact = rgres / slantRangePixelSpacing
print('azfact: {}, rngfact: {}'.format(azfact, rngfact))
corrLooks = azimuthLooks * rangeLooks / (azfact * rngfact)
maxComponents = 20
snp = Snaphu()
snp.setInitOnly(initOnly) # follow
snp.setInput(wrapName)
snp.setOutput(unwrapName)
snp.setWidth(width)
snp.setCostMode(costMode) # follow
snp.setEarthRadius(earthRadius)
snp.setWavelength(wavelength)
snp.setAltitude(altitude)
snp.setCorrfile(corrfile)
snp.setInitMethod(initMethod) # follow
snp.setCorrLooks(corrLooks)
snp.setMaxComponents(maxComponents)
snp.setDefoMaxCycles(defomax) # follow
snp.setRangeLooks(rangeLooks)
snp.setAzimuthLooks(azimuthLooks)
#snp.setCorFileFormat('FLOAT_DATA')
snp.prepare()
snp.unwrap()
######Render XML
outImage = isceobj.Image.createUnwImage()
outImage.setFilename(unwrapName)
outImage.setWidth(width)
outImage.setAccessMode('read')
outImage.renderVRT()
outImage.createImage()
outImage.finalizeImage()
outImage.renderHdr()
#####Check if connected components was created
if snp.dumpConnectedComponents:
connImage = isceobj.Image.createImage()
connImage.setFilename(unwrapName + '.conncomp')
#At least one can query for the name used
#self._insar.connectedComponentsFilename = unwrapName+'.conncomp'
connImage.setWidth(width)
connImage.setAccessMode('read')
connImage.setDataType('BYTE')
connImage.renderVRT()
connImage.createImage()
connImage.finalizeImage()
connImage.renderHdr()
return