smallbaselineApp.cfg

# vim: set filetype=cfg:
##------------------------ smallbaselineApp.cfg ------------------------##
########## computing resource configuration
mintpy.compute.maxMemory = auto #[float > 0.0], auto for 4, max memory to allocate in GB
## parallel processing with dask
## currently apply to steps: invert_network, correct_topography
## cluster   = none to turn off the parallel computing
## numWorker = all  to use all of locally available cores (for cluster = local only)
## numWorker = 80%  to use 80% of locally available cores (for cluster = local only)
## config    = none to rollback to the default name (same as the cluster type; for cluster != local)
mintpy.compute.cluster   = auto #[local / slurm / pbs / lsf / none], auto for none, cluster type
mintpy.compute.numWorker = auto #[int > 1 / all / num%], auto for 4 (local) or 40 (slurm / pbs / lsf), num of workers
mintpy.compute.config    = auto #[none / slurm / pbs / lsf ], auto for none (same as cluster), config name


########## 1. load_data
##---------add attributes manually
## MintPy requires attributes listed at: https://mintpy.readthedocs.io/en/latest/api/attributes/
## Missing attributes can be added below manually (uncomment #), e.g.
# ORBIT_DIRECTION = ascending
# PLATFORM = CSK
# ...
## a. autoPath - automatic path pattern defined in mintpy.defaults.auto_path.AUTO_PATH_*
## b. load_data.py -H to check more details and example inputs.
## c. compression to save disk usage for ifgramStack.h5 file:
## no   - save   0% disk usage, fast [default]
## lzf  - save ~57% disk usage, relative slow
## gzip - save ~62% disk usage, very slow [not recommend]
mintpy.load.processor       = auto  #[isce, aria, hyp3, gmtsar, snap, gamma, roipac, nisar], auto for isce
mintpy.load.autoPath        = auto  #[yes / no], auto for no, use pre-defined auto path
mintpy.load.updateMode      = auto  #[yes / no], auto for yes, skip re-loading if HDF5 files are complete
mintpy.load.compression     = auto  #[gzip / lzf / no], auto for no.
##---------for ISCE only:
mintpy.load.metaFile        = auto  #[path of common metadata file for the stack], i.e.: ./reference/IW1.xml, ./referenceShelve/data.dat
mintpy.load.baselineDir     = auto  #[path of the baseline dir], i.e.: ./baselines
##---------interferogram stack:
mintpy.load.unwFile         = auto  #[path pattern of unwrapped interferogram files]
mintpy.load.corFile         = auto  #[path pattern of spatial coherence       files]
mintpy.load.connCompFile    = auto  #[path pattern of connected components    files], optional but recommended
mintpy.load.intFile         = auto  #[path pattern of wrapped interferogram   files], optional
mintpy.load.magFile         = auto  #[path pattern of interferogram magnitude files], optional
##---------ionosphere stack (optional):
mintpy.load.ionUnwFile      = auto  #[path pattern of unwrapped interferogram files]
mintpy.load.ionCorFile      = auto  #[path pattern of spatial coherence       files]
mintpy.load.ionConnCompFile = auto  #[path pattern of connected components    files], optional but recommended
##---------offset stack (optional):
mintpy.load.azOffFile       = auto  #[path pattern of azimuth offset file]
mintpy.load.rgOffFile       = auto  #[path pattern of range   offset file]
mintpy.load.azOffStdFile    = auto  #[path pattern of azimuth offset variance file], optional but recommended
mintpy.load.rgOffStdFile    = auto  #[path pattern of range   offset variance file], optional but recommended
mintpy.load.offSnrFile      = auto  #[path pattern of offset signal-to-noise ratio file], optional
##---------geometry:
mintpy.load.demFile         = auto  #[path of DEM file]
mintpy.load.lookupYFile     = auto  #[path of latitude /row   /y coordinate file], not required for geocoded data
mintpy.load.lookupXFile     = auto  #[path of longitude/column/x coordinate file], not required for geocoded data
mintpy.load.incAngleFile    = auto  #[path of incidence angle file], optional but recommended
mintpy.load.azAngleFile     = auto  #[path of azimuth   angle file], optional
mintpy.load.shadowMaskFile  = auto  #[path of shadow mask file], optional but recommended
mintpy.load.waterMaskFile   = auto  #[path of water  mask file], optional but recommended
mintpy.load.bperpFile       = auto  #[path pattern of 2D perpendicular baseline file], optional
##---------subset (optional):
## if both yx and lalo are specified, use lalo option unless a) no lookup file AND b) dataset is in radar coord
mintpy.subset.yx            = auto    #[y0:y1,x0:x1 / no], auto for no
mintpy.subset.lalo          = auto    #[S:N,W:E / no], auto for no
##---------multilook (optional):
## multilook while loading data with the specified method, to reduce dataset size
## method - nearest, mean and median methods are applicable to interferogram/ionosphere/offset stack(s), except for:
##   connected components and all geometry datasets, for which nearest is hardwired.
## Use mean / median method with caution! It could smoothen the noise for a better SNR, but it could also smoothen the
##   unwrapping errors, breaking the integer 2pi relationship, which is used in the unwrapping error correction.
##   If you really want to increase the SNR, consider re-generate your stack of interferograms with more looks instead.
mintpy.multilook.method     = auto    #[nearest, mean, median], auto for nearest - lines/rows skipping approach
mintpy.multilook.ystep      = auto    #[int >= 1], auto for 1 - no multilooking
mintpy.multilook.xstep      = auto    #[int >= 1], auto for 1 - no multilooking


########## 2. modify_network
## 1) Network modification based on temporal/perpendicular baselines, date, num of connections etc.
mintpy.network.tempBaseMax     = auto  #[1-inf, no], auto for no, max temporal baseline in days
mintpy.network.perpBaseMax     = auto  #[1-inf, no], auto for no, max perpendicular spatial baseline in meter
mintpy.network.connNumMax      = auto  #[1-inf, no], auto for no, max number of neighbors for each acquisition
mintpy.network.startDate       = auto  #[20090101 / no], auto for no
mintpy.network.endDate         = auto  #[20110101 / no], auto for no
mintpy.network.excludeDate     = auto  #[20080520,20090817 / no], auto for no
mintpy.network.excludeDate12   = auto  #[20080520_20090817 / no], auto for no
mintpy.network.excludeIfgIndex = auto  #[1:5,25 / no], auto for no, list of ifg index (start from 0)
mintpy.network.referenceFile   = auto  #[date12_list.txt / ifgramStack.h5 / no], auto for no

## 2) Data-driven network modification
## a - Coherence-based network modification = (threshold + MST) by default
## reference: Yunjun et al. (2019, section 4.2 and 5.3.1); Chaussard et al. (2015, GRL)
## It calculates a average coherence for each interferogram using spatial coherence based on input mask (with AOI)
## Then it finds a minimum spanning tree (MST) network with inverse of average coherence as weight (keepMinSpanTree)
## Next it excludes interferograms if a) the average coherence < minCoherence AND b) not in the MST network.
mintpy.network.coherenceBased  = auto  #[yes / no], auto for no, exclude interferograms with coherence < minCoherence
mintpy.network.minCoherence    = auto  #[0.0-1.0], auto for 0.7

## b - Effective Coherence Ratio network modification = (threshold + MST) by default
## reference: Kang et al. (2021, RSE)
## It calculates the area ratio of each interferogram that is above a spatial coherence threshold.
## This threshold is defined as the spatial coherence of the interferograms within the input mask.
## It then finds a minimum spanning tree (MST) network with inverse of the area ratio as weight (keepMinSpanTree)
## Next it excludes interferograms if a) the area ratio < minAreaRatio AND b) not in the MST network.
mintpy.network.areaRatioBased  = auto  #[yes / no], auto for no, exclude interferograms with area ratio < minAreaRatio
mintpy.network.minAreaRatio    = auto  #[0.0-1.0], auto for 0.75

## Additional common parameters for the 2) data-driven network modification
mintpy.network.keepMinSpanTree = auto  #[yes / no], auto for yes, keep interferograms in Min Span Tree network
mintpy.network.maskFile        = auto  #[file name, no], auto for waterMask.h5 or no [if no waterMask.h5 found]
mintpy.network.aoiYX           = auto  #[y0:y1,x0:x1 / no], auto for no, area of interest for coherence calculation
mintpy.network.aoiLALO         = auto  #[S:N,W:E / no], auto for no - use the whole area


########## 3. reference_point
## Reference all interferograms to one common point in space
## auto - randomly select a pixel with coherence > minCoherence
## however, manually specify using prior knowledge of the study area is highly recommended
##   with the following guideline (section 4.3 in Yunjun et al., 2019):
## 1) located in a coherence area, to minimize the decorrelation effect.
## 2) not affected by strong atmospheric turbulence, i.e. ionospheric streaks
## 3) close to and with similar elevation as the AOI, to minimize the impact of spatially correlated atmospheric delay
mintpy.reference.yx            = auto   #[257,151 / auto]
mintpy.reference.lalo          = auto   #[31.8,130.8 / auto]
mintpy.reference.maskFile      = auto   #[filename / no], auto for maskConnComp.h5
mintpy.reference.coherenceFile = auto   #[filename], auto for avgSpatialCoh.h5
mintpy.reference.minCoherence  = auto   #[0.0-1.0], auto for 0.85, minimum coherence for auto method


########## quick_overview
## A quick assessment of:
## 1) possible groud deformation
##    using the velocity from the traditional interferogram stacking
##    reference: Zebker et al. (1997, JGR)
## 2) distribution of phase unwrapping error
##    from the number of interferogram triplets with non-zero integer ambiguity of closue phase
##    reference: T_int in Yunjun et al. (2019, CAGEO). Related to section 3.2, equation (8-9) and Fig. 3d-e.


########## 4. correct_unwrap_error (optional)
## connected components (mintpy.load.connCompFile) are required for this step.
## SNAPHU (Chem & Zebker,2001) is currently the only unwrapper that provides connected components as far as we know.
## reference: Yunjun et al. (2019, section 3)
## supported methods:
## a. phase_closure          - suitable for highly redundant network
## b. bridging               - suitable for regions separated by narrow decorrelated features, e.g. rivers, narrow water bodies
## c. bridging+phase_closure - recommended when there is a small percentage of errors left after bridging
mintpy.unwrapError.method          = auto  #[bridging / phase_closure / bridging+phase_closure / no], auto for no
mintpy.unwrapError.waterMaskFile   = auto  #[waterMask.h5 / no], auto for waterMask.h5 or no [if not found]
mintpy.unwrapError.connCompMinArea = auto  #[1-inf], auto for 2.5e3, discard regions smaller than the min size in pixels

## phase_closure options:
## numSample - a region-based strategy is implemented to speedup L1-norm regularized least squares inversion.
##     Instead of inverting every pixel for the integer ambiguity, a common connected component mask is generated,
##     for each common conn. comp., numSample pixels are radomly selected for inversion, and the median value of the results
##     are used for all pixels within this common conn. comp.
mintpy.unwrapError.numSample       = auto  #[int>1], auto for 100, number of samples to invert for common conn. comp.

## bridging options:
## ramp - a phase ramp could be estimated based on the largest reliable region, removed from the entire interferogram
##     before estimating the phase difference between reliable regions and added back after the correction.
## bridgePtsRadius - half size of the window used to calculate the median value of phase difference
mintpy.unwrapError.ramp            = auto  #[linear / quadratic], auto for no; recommend linear for L-band data
mintpy.unwrapError.bridgePtsRadius = auto  #[1-inf], auto for 50, half size of the window around end points


########## 5. invert_network
## Invert network of interferograms into time-series using weighted least square (WLS) estimator.
## weighting options for least square inversion [fast option available but not best]:
## a. var - use inverse of covariance as weight (Tough et al., 1995; Guarnieri & Tebaldini, 2008) [recommended]
## b. fim - use Fisher Information Matrix as weight (Seymour & Cumming, 1994; Samiei-Esfahany et al., 2016).
## c. coh - use coherence as weight (Perissin & Wang, 2012)
## d. no  - uniform weight (Berardino et al., 2002) [fast]
## SBAS (Berardino et al., 2002) = minNormVelocity (yes) + weightFunc (no)
mintpy.networkInversion.weightFunc      = auto #[var / fim / coh / no], auto for var
mintpy.networkInversion.waterMaskFile   = auto #[filename / no], auto for waterMask.h5 or no [if not found]
mintpy.networkInversion.minNormVelocity = auto #[yes / no], auto for yes, min-norm deformation velocity / phase

## mask options for unwrapPhase of each interferogram before inversion (recommend if weightFunct=no):
## a. coherence              - mask out pixels with spatial coherence < maskThreshold
## b. connectComponent       - mask out pixels with False/0 value
## c. no                     - no masking [recommended].
## d. range/azimuthOffsetStd - mask out pixels with offset std. dev. > maskThreshold [for offset]
mintpy.networkInversion.maskDataset   = auto #[coherence / connectComponent / rangeOffsetStd / azimuthOffsetStd / no], auto for no
mintpy.networkInversion.maskThreshold = auto #[0-inf], auto for 0.4
mintpy.networkInversion.minRedundancy = auto #[1-inf], auto for 1.0, min num_ifgram for every SAR acquisition

## Temporal coherence is calculated and used to generate the mask as the reliability measure
## reference: Pepe & Lanari (2006, IEEE-TGRS)
mintpy.networkInversion.minTempCoh  = auto #[0.0-1.0], auto for 0.7, min temporal coherence for mask
mintpy.networkInversion.minNumPixel = auto #[int > 1], auto for 100, min number of pixels in mask above
mintpy.networkInversion.shadowMask  = auto #[yes / no], auto for yes [if shadowMask is in geometry file] or no.


########## correct_LOD
## Local Oscillator Drift (LOD) correction (for Envisat only)
## reference: Marinkovic and Larsen (2013, Proc. LPS)
## automatically applied to Envisat data (identified via PLATFORM attribute)
## and skipped for all the other satellites.


########## 6. correct_SET
## Solid Earth tides (SET) correction [need to install insarlab/PySolid]
## reference: Milbert (2018); Yunjun et al. (2022, IEEE-TGRS)
mintpy.solidEarthTides = auto #[yes / no], auto for no


########## 7. correct_ionosphere (optional but recommended)
## correct ionospheric delay [need split spectrum results from ISCE-2 stack processors]
## reference:
##   ISCE-2 topsApp/topsStack: Liang et al. (2019, IEEE-TGRS)
##   ISCE-2 stripmapApp/stripmapStack: Fattahi et al. (2017, IEEE-TGRS)
##   ISCE-2 alos2App/alosStack: Liang et al. (2018, IEEE-TGRS)
mintpy.ionosphericDelay.method        = auto  #[split_spectrum / no], auto for no
mintpy.ionosphericDelay.excludeDate   = auto  #[20080520,20090817 / no], auto for no
mintpy.ionosphericDelay.excludeDate12 = auto  #[20080520_20090817 / no], auto for no


########## 8. correct_troposphere (optional but recommended)
## correct tropospheric delay using the following methods:
## a. height_correlation - correct stratified tropospheric delay (Doin et al., 2009, J Applied Geop)
## b. pyaps - use Global Atmospheric Models (GAMs) data (Jolivet et al., 2011; 2014)
##      ERA5  - ERA5    from ECMWF [need to install PyAPS from GitHub; recommended and turn ON by default]
##      MERRA - MERRA-2 from NASA  [need to install PyAPS from Caltech/EarthDef]
##      NARR  - NARR    from NOAA  [need to install PyAPS from Caltech/EarthDef; recommended for N America]
## c. gacos - use GACOS with the iterative tropospheric decomposition model (Yu et al., 2018, JGR)
##      need to manually download GACOS products at http://www.gacos.net for all acquisitions before running this step
mintpy.troposphericDelay.method = auto  #[pyaps / height_correlation / gacos / no], auto for pyaps

## Notes for pyaps:
## a. GAM data latency: with the most recent SAR data, there will be GAM data missing, the correction
##    will be applied to dates with GAM data available and skipped for the others.
## b. WEATHER_DIR: if you define an environment variable named WEATHER_DIR to contain the path to a
##    directory, then MintPy applications will download the GAM files into the indicated directory.
##    MintPy application will look for the GAM files in the directory before downloading a new one to
##    prevent downloading multiple copies if you work with different dataset that cover the same date/time.
mintpy.troposphericDelay.weatherModel = auto  #[ERA5 / MERRA / NARR], auto for ERA5
mintpy.troposphericDelay.weatherDir   = auto  #[path2directory], auto for WEATHER_DIR or "./"

## Notes for height_correlation:
## Extra multilooking is applied to estimate the empirical phase/elevation ratio ONLY.
## For an dataset with 5 by 15 looks, looks=8 will generate phase with (5*8) by (15*8) looks
## to estimate the empirical parameter; then apply the correction to original phase (with 5 by 15 looks),
## if the phase/elevation correlation is larger than minCorrelation.
mintpy.troposphericDelay.polyOrder      = auto  #[1 / 2 / 3], auto for 1
mintpy.troposphericDelay.looks          = auto  #[1-inf], auto for 8, extra multilooking num
mintpy.troposphericDelay.minCorrelation = auto  #[0.0-1.0], auto for 0

## Notes for gacos:
## Set the path below to directory that contains the downloaded *.ztd* files
mintpy.troposphericDelay.gacosDir = auto # [path2directory], auto for "./GACOS"


########## 9. deramp (optional)
## Estimate and remove a phase ramp for each acquisition based on the reliable pixels.
## Recommended for localized deformation signals, i.e. volcanic deformation, landslide and land subsidence, etc.
## NOT recommended for long spatial wavelength deformation signals, i.e. co-, post- and inter-seimic deformation.
mintpy.deramp          = auto  #[no / linear / quadratic], auto for no - no ramp will be removed
mintpy.deramp.maskFile = auto  #[filename / no], auto for maskTempCoh.h5, mask file for ramp estimation


########## 10. correct_topography (optional but recommended)
## Topographic residual (DEM error) correction
## reference: Fattahi and Amelung (2013, IEEE-TGRS)
## stepDate          - specify stepDate option if you know there are sudden displacement jump in your area,
##                     e.g. volcanic eruption, or earthquake
## excludeDate       - dates excluded for the error estimation
## pixelwiseGeometry - use pixel-wise geometry (incidence angle & slant range distance)
##                     yes - use pixel-wise geometry if they are available [slow; used by default]
##                     no  - use the mean   geometry [fast]
mintpy.topographicResidual                   = auto  #[yes / no], auto for yes
mintpy.topographicResidual.polyOrder         = auto  #[1-inf], auto for 2, poly order of temporal deformation model
mintpy.topographicResidual.phaseVelocity     = auto  #[yes / no], auto for no - use phase velocity for minimization
mintpy.topographicResidual.stepDate          = auto  #[20080529,20190704T1733 / no], auto for no, date of step jump
mintpy.topographicResidual.excludeDate       = auto  #[20070321 / txtFile / no], auto for exclude_date.txt
mintpy.topographicResidual.pixelwiseGeometry = auto  #[yes / no], auto for yes, use pixel-wise geometry info


########## 11.1 residual_RMS (root mean squares for noise evaluation)
## Calculate the Root Mean Square (RMS) of residual phase time-series for each acquisition
## reference: Yunjun et al. (2019, section 4.9 and 5.4)
## To get rid of long spatial wavelength component, a ramp is removed for each acquisition
## Set optimal reference date to date with min RMS
## Set exclude dates (outliers) to dates with RMS > cutoff * median RMS (Median Absolute Deviation)
mintpy.residualRMS.maskFile = auto  #[file name / no], auto for maskTempCoh.h5, mask for ramp estimation
mintpy.residualRMS.deramp   = auto  #[quadratic / linear / no], auto for quadratic
mintpy.residualRMS.cutoff   = auto  #[0.0-inf], auto for 3

########## 11.2 reference_date
## Reference all time-series to one date in time
## reference: Yunjun et al. (2019, section 4.9)
## no     - do not change the default reference date (1st date)
mintpy.reference.date = auto   #[reference_date.txt / 20090214 / no], auto for reference_date.txt


########## 12. velocity
## Estimate a suite of time functions [linear velocity by default]
## from final displacement file (and from tropospheric delay file if exists)
mintpy.timeFunc.startDate   = auto   #[20070101 / no], auto for no
mintpy.timeFunc.endDate     = auto   #[20101230 / no], auto for no
mintpy.timeFunc.excludeDate = auto   #[exclude_date.txt / 20080520,20090817 / no], auto for exclude_date.txt

## Fit a suite of time functions
## reference: Hetland et al. (2012, JGR) equation (2-9)
## polynomial function    is  defined by its degree in integer. 1 for linear, 2 for quadratic, etc.
## periodic   function(s) are defined by a list of periods in decimal years. 1 for annual, 0.5 for semi-annual, etc.
## step       function(s) are defined by a list of onset times in str in YYYYMMDD(THHMM) format
## exp & log  function(s) are defined by an onset time followed by an charateristic time in integer days.
##   Multiple exp and log functions can be overlaied on top of each other, achieved via e.g.:
##   20110311,60,120          - two functions sharing the same onset time OR
##   20110311,60;20170908,120 - separated by ";"
mintpy.timeFunc.polynomial = auto   #[int >= 0], auto for 1, degree of the polynomial function
mintpy.timeFunc.periodic   = auto   #[1,0.5 / list_of_float / no], auto for no, periods in decimal years
mintpy.timeFunc.stepDate   = auto   #[20110311,20170908 / 20120928T1733 / no], auto for no, step function(s)
mintpy.timeFunc.exp        = auto   #[20110311,60 / 20110311,60,120 / 20110311,60;20170908,120 / no], auto for no
mintpy.timeFunc.log        = auto   #[20110311,60 / 20110311,60,120 / 20110311,60;20170908,120 / no], auto for no

## Uncertainty quantification methods:
## a. residue    - propagate from fitting residue assuming normal dist. in time (Fattahi & Amelung, 2015, JGR)
## b. covariance - propagate from time series (co)variance matrix
## c. bootstrap  - bootstrapping (independently resampling with replacement; Efron & Tibshirani, 1986, Stat. Sci.)
mintpy.timeFunc.uncertaintyQuantification = auto   #[residue, covariance, bootstrap], auto for residue
mintpy.timeFunc.timeSeriesCovFile         = auto   #[filename / no], auto for no, time series covariance file
mintpy.timeFunc.bootstrapCount            = auto   #[int>1], auto for 400, number of iterations for bootstrapping


########## 13.1 geocode (post-processing)
# for input dataset in radar coordinates only
# commonly used resolution in meters and in degrees (on equator)
# 100,         90,          60,          50,          40,          30,          20,          10
# 0.000925926, 0.000833334, 0.000555556, 0.000462963, 0.000370370, 0.000277778, 0.000185185, 0.000092593
mintpy.geocode              = auto  #[yes / no], auto for yes
mintpy.geocode.SNWE         = auto  #[-1.2,0.5,-92,-91 / none ], auto for none, output extent in degree
mintpy.geocode.laloStep     = auto  #[-0.000555556,0.000555556 / None], auto for None, output resolution in degree
mintpy.geocode.interpMethod = auto  #[nearest], auto for nearest, interpolation method
mintpy.geocode.fillValue    = auto  #[np.nan, 0, ...], auto for np.nan, fill value for outliers.

########## 13.2 google_earth (post-processing)
mintpy.save.kmz             = auto   #[yes / no], auto for yes, save geocoded velocity to Google Earth KMZ file

########## 13.3 hdfeos5 (post-processing)
mintpy.save.hdfEos5         = auto   #[yes / no], auto for no, save time-series to HDF-EOS5 format
mintpy.save.hdfEos5.update  = auto   #[yes / no], auto for no, put XXXXXXXX as endDate in output filename
mintpy.save.hdfEos5.subset  = auto   #[yes / no], auto for no, put subset range info   in output filename

########## 13.4 plot
# for high-resolution plotting, increase mintpy.plot.maxMemory
# for fast plotting with more parallelization, decrease mintpy.plot.maxMemory
mintpy.plot           = auto  #[yes / no], auto for yes, plot files generated by default processing to pic folder
mintpy.plot.dpi       = auto  #[int], auto for 150, number of dots per inch (DPI)
mintpy.plot.maxMemory = auto  #[float], auto for 4, max memory used by one call of view.py for plotting.