Provided by: snaphu_1.4.2-2_amd64 bug

NAME

       snaphu - phase unwrapping algorithm for SAR interferometry

SYNOPSIS

       snaphu [options] [infile] [linelength] [options]

DESCRIPTION

       snaphu  is a statistical-cost network-flow algorithm for phase unwrapping.  Given an input
       interferogram and other observable data,  snaphu  attempts  to  compute  congruent  phase-
       unwrapped solutions that are maximally probable in an approximate a posteriori sense.  The
       algorithm's solver routine is based on network optimization.  By default,  snaphu  assumes
       that  its  input  is  a  synthetic  aperture  radar  (SAR) interferogram measuring surface
       topography.  Deformation measurements are assumed if the  -d  option  is  given.   Smooth,
       generic data are assumed if the -s option is given.

       This  man  page documents only snaphu's syntax and usage.  Its theoretical foundations are
       discussed in the references cited below.

       The most common input parameters may be given  on  the  command  line,  while  many  other
       twiddle  parameters  are  handled  via the -f option and configuration files.  At the very
       least, the name of a wrapped-phase input file and  its  line  length  must  be  specified.
       Range  should  increase  towards  the right in the interferogram, and the flat-earth phase
       ramp should be removed from the input interferogram before snaphu is run.  For deformation
       interferograms, phase variations due to topography should be removed as well.

       Except  for  the  input  file  name and the line length, all input parameters take default
       values if not specified.  However, these parameters should be customized whenever possible
       since  the  accuracy  of the solution depends on how well the statistics of the estimation
       problem are modeled.  To avoid poor-quality solutions, users are  strongly  encouraged  to
       provide  their  best  estimates of the relevant problem parameters.  Parameters are set in
       the order in which they are given on the command line, so multiple configuration files  or
       options may be given, with later values overriding earlier ones.

       Allowable  file  formats  are  detailed  below.   The default format for the input file is
       COMPLEX_DATA,  but  any  of  the  described  formats  may  be  used.   If  either  of  the
       ALT_LINE_DATA or ALT_SAMPLE_DATA formats are used, the magnitude and phase (in radians) of
       the interferogram should be in the first and second channels of  the  file,  respectively.
       If  the  FLOAT_DATA  format  is  used, the input file should contain only the phase of the
       interferogram (in radians); the magnitude may be passed with the -m option.

OPTIONS

       -a ampfile
              Read brightness data from the file ampfile.  The file should contain the amplitudes
              (not  powers)  of  the  two  individual SAR images forming the interferogram if the
              formats ALT_SAMPLE_DATA (default) or ALT_LINE_DATA are used.  It should contain  an
              average  of  those  two  images  if  the  FLOAT_DATA  format  is  used.  If (1) the
              amplitudes of both images are available, (2) the interferogram  magnitude  is  also
              available,  and  (3)  the  -c  option  is  not  used,  then a coherence estimate is
              automatically formed from the available data.  The number of looks  used  for  this
              estimate  can  be  set  in a configuration file.  If no amplitude or power data are
              specified, then the magnitude of the input interferogram is  used  as  the  average
              amplitude,  and  no  coherence  estimate is formed.  Note that the magnitude of the
              interferogram is not equal to  the  average  amplitude  of  the  SAR  images.   The
              amplitude  data  should  be  in  the  same  system  of  units  used  for  the input
              interferogram, and also coregistered to it.

       -A pwrfile
              Similar to the -a option, except the data in  the  specified  file  is  assumed  to
              represent the powers of the two individual SAR images.

       -b Bperp
              For  topography  mode,  use  Bperp  (decimal  value, in meters) as the value of the
              perpendicular component of the interferometric baseline.  The sign is defined  such
              that  Bperp  is  negative  if the unwrapped phase increases with the elevation.  By
              default, repeat-pass or ping-pong  mode  is  assumed;  for  single-antenna-transmit
              data,  the  value  of  Bperp  should  be halved, or the transmit mode should be set
              accordingly in a configuration file (see the -f option).   The  baseline  value  is
              only used in topography mode.

       -c corrfile
              Read  correlation  data from the file corrfile.  The correlation data should be the
              same size as, and registered to, the  input  interferogram.   Consequently,  a  raw
              correlation  estimate  may  need to be upsampled if it incorporates more looks than
              the interferogram.  If the -c option is not given, a coherence estimate  is  formed
              from  the  available  data  if possible.  Otherwise, a uniform default coherence is
              assumed  for  the  entire  interferogram.   If  the  ALT_LINE_DATA   (default)   or
              ALT_SAMPLE_DATA formats are used, the correlation data should be in the second data
              channel of the file; the first channel is ignored.  The FLOAT_DATA format may  also
              be used.  The correlation values should be between zero and one, inclusive.

       -d     Run  in  deformation mode.  The problem statistics and resulting cost functions are
              based  on  the  assumption  that  the  true  unwrapped  phase  represents   surface
              displacement rather than elevation.

       -e estimatefile
              Flatten  using the unwrapped phase estimate in the file estimatefile.  The estimate
              is subtracted from the input interferogram before unwrapping, and is inserted  back
              into the solution just before the output is written.  The estimate also affects the
              cost functions used, since subtracting a constant from a random variable shifts the
              probability  density function of the random variable.  If the formats ALT_LINE_DATA
              (default) or ALT_SAMPLE_DATA are used, the unwrapped estimate (in  radians)  should
              be  in  the  second  data  channel  of the file; the first channel is ignored.  The
              FLOAT_DATA format may also be used.

       -f configfile
              Read configuration parameters from file configfile.  The file  is  parsed  line  by
              line  for  key-value  pairs.   Template  configuration  files are included with the
              snaphu  source  code:  snaphu.conf.full  contains  all   valid   key-value   pairs;
              snaphu.conf.brief contains the most important parameters.  Lines not beginning with
              alphanumeric characters  are  treated  as  comment  lines.   Command  line  options
              specified  after  -f  will override parameters specified in the configfile and vice
              versa.  The -f option may be given  multiple  times  with  different  configuration
              files, with parameters in later-specified files overriding those in earlier ones.

       -g maskfile
              Grow  a  connected  component mask for the unwrapped solution and write the mask to
              the file maskfile.  A connected component is a region of  pixels  in  the  solution
              that  is  believed to have been unwrapped in a relative, internally self-consistent
              manner according to the statistical costs used.  Regions that are  smaller  than  a
              preselected threshold are masked out.  Parameters for this option can be set in the
              configuration  file.   The  connected  component  file  is  composed  of   unsigned
              characters,  with  all  pixels  of  the  same value belonging to the same connected
              component and zero corresponding to masked pixels.

       -G maskfile
              Grow a connected component mask (see the -g  option)  for  the  input  data  array,
              assuming  that  it  is  already unwrapped, and write the mask to the file maskfile.
              Statistical cost functions are computed for forming the mask, but a  new  unwrapped
              solution is not computed.

       -h     Print a help message summarizing command-line options and exit.

       -i     Run  in  initialize-only mode.  Normally, snaphu uses either an approximate minimum
              spanning tree (MST) algorithm or a minimum cost flow (MCF) algorithm for generating
              the  initialization  to  its  iterative, modified network-simplex solver.  If -i is
              given, the initialization is written to the output and the  program  exits  without
              running the iterative solver.

       -l logfile
              Log  all  runtime  parameters  and  some  other  environment  information  into the
              specified file.  The log file is a text file in the same format as a  configuration
              file.

       -m magfile
              Read  interferogram  magnitude data from the specified file.  This option is useful
              mainly if the wrapped-phase input file is given as  a  set  of  real  phase  values
              rather  than  complex interferogram values.  The interferogram magnitude is used to
              form a coherence estimate if appropriate amplitude data are  given  as  well.   The
              default file format is FLOAT_DATA.  If the formats ALT_LINE_DATA or ALT_SAMPLE_DATA
              are used, the magnitude should be in the first data channel of the file; the second
              channel  is  ignored.  If the COMPLEX_DATA format is used, the phase information is
              ignored.

       -n     Run in no-statistical-costs mode.  If the -i or -p options are given,  snaphu  will
              not  use  statistical costs.  Information from a weight file (-w option) will still
              be used if given.

       -o outfile
              Write  the  unwrapped  output  to  file  called  outfile.   If  the  file   formats
              ALT_LINE_DATA (default) or ALT_SAMPLE_DATA are used, the unwrapped phase is written
              into the second data channel, while the interferogram magnitude is written into the
              first channel.  The format FLOAT_DATA may also be used.

       -p value
              Run in Lp-norm mode with p=value, where value is a nonnegative decimal.  Instead of
              statistical cost functions, the program uses Lp cost functions  with  statistically
              based  weights  (unless  -n  is also given).  Solutions are still always congruent.
              Moreover, congruence is  enforced  within  the  solver  routine,  not  as  a  post-
              optimization  processing  step.  Therefore, if p=2, for example, least-squares cost
              functions are used, but the solution  will  probably  be  more  accurate  than  one
              generated from a transform-based least-squares algorithm.

       -q     Run in quantify-only mode.  The input data are assumed to be unwrapped already, and
              the total cost of this solution is calculated and printed.  The unwrapped phase  is
              wrapped  assuming  congruence for the cost calculation.  Round-off errors may limit
              the precision of the quantified  cost.   See  the  -u  option  for  allowable  file
              formats.

       -s     Run  in  smooth-solution mode.  The problem statistics and resulting cost functions
              are based on the assumption that the true  unwrapped  phase  represents  a  generic
              surface  with  no  discontinuities.   This is the same as deformation mode with the
              DEFOMAX parameter set to zero.

       -t     Run in topography mode.  The problem statistics and resulting  cost  functions  are
              based on the assumption that the true unwrapped phase represents surface elevation.
              This is the default.

       -u     Assume that the input file is unwrapped rather than wrapped.  The  algorithm  makes
              iterative improvements to this solution instead of using an initialization routine.
              The input file may be in the formats ALT_LINE_DATA  (default)  or  ALT_SAMPLE_DATA;
              the  interferogram  magnitude should be in the first data channel and the unwrapped
              phase should be in the second data channel.  The  format  FLOAT_DATA  may  also  be
              used.

       -v     Run  in  verbose mode.  Extra information on the algorithm's progress is printed to
              the standard output.

       -w weightfile
              Read external, scalar weights from file weightfile.  The weights, which  should  be
              positive  short  integers, are applied to whichever cost functions are used.  There
              is one weight value for each arc in  the  network,  so  weightfile  should  be  the
              concatenation  of  raster horizontal-flow and vertical-flow arc weights.  Thus, for
              an N row by M column interferogram, weightfile would consist of a rasterized  (N-1)
              by  M  array followed by a rasterized N by (M-1) array of short integer data.  This
              option is not well tested.

       --aa ampfile1 ampfile2
              Amplitude data are read from the files specified.  The data from the two individual
              SAR  images  forming the interferogram are assumed to be separately stored in files
              ampfile1 and ampfile2.  These files should  be  in  the  format  FLOAT_DATA.   This
              option is similar to the -a option.

       --AA pwrfile1 pwrfile2
              Similar to the --aa option, but power data are read from the specified files.

       --assemble dirname
              Assemble   the   tile-mode  temporary  files  in  the  specified  directory.   Most
              configuration options (from the command line and any configuration files)  must  be
              specified.   This  option  is  useful  if  the  user wishes to modify tile-assembly
              parameters without unwrapping the individual tiles over again.

       --copyright, --info
              Print the software copyright notice and bug report info, then exit.

       --costinfile costfile
              Read statistical cost arrays from file costfile.  This file should be in the format
              written by the --costoutfile option.  The cost file does not control whether snaphu
              runs in topography, deformation, or smooth-solution mode; the latter  two  must  be
              specified explicitly even if costfile was generated while running in those modes.

       --costoutfile costfile
              Write  statistical  cost arrays to file costfile.  This option can be used with the
              --costinfile option to save the time of generating statistical costs  if  the  same
              costs are used multiple times.

       --debug, --dumpall
              Dump all sorts of intermediate arrays to files.

       --mst  Use  a  minimum  spanning tree (MST) algorithm for the initialization.  This is the
              default.

       --mcf  Use a minimum cost flow (MCF) algorithm for the initialization.  The cs2 solver  by
              Goldberg  and  Cherkassky  is used.  The modified network-simplex solver in L1 mode
              may give different results than the cs2 solver, though in principle both should  be
              L1 optimal.

       --nproc n
              Use  n  parallel  processes when in tile mode.  The program forks a new process for
              each tile so that tiles can be unwrapped in parallel; at most n processes will  run
              concurrently.  Forking is done before data is read.  The standard output streams of
              child processes are directed to log files in the temporary tile directory.

       --piece firstrow firstcol nrow ncol
              Read and unwrap only a subset or part of the input interferogram.  The  read  piece
              is  the nrow by ncol rectangle whose upper left corner is the pixel at row firstrow
              and column firstcol  (indexed  from  1).   All  input  files  (such  as  amplitude,
              coherence,  etc.)  are  assumed  to  be the same size as the input phase file.  All
              output files are nrow by ncol.

       --tile ntilerow ntilecol rowovrlp colovrlp
              Unwrap the interferogram in tile  mode.   The  interferogram  is  partitioned  into
              ntilerow  by  ntilecol  tiles,  each  of  which  is unwrapped independently.  Tiles
              overlap by rowovrlp and colovrlp pixels in the  row  and  column  directions.   The
              tiles are then segmented into reliable regions based on the cost functions, and the
              regions are reassembled.  The program creates a subdirectory for temporary files in
              the  directory  of the eventual output file.  This option is currently enabled only
              for statistical cost functions.

FILE FORMATS

       The formats of input files may be specified in a configuration file.  All of these formats
       are composed of raster, single-precision (float, real*4, or complex*8) floating-point data
       types in the platform's native byte order.  Data are read line by line (across then down).
       Regardless  of  the  file  format,  all  input  data arrays should have the same number of
       samples in width and depth and should be coregistered to one another.   Note  that  weight
       files  and  cost files have their own formats.  The allowable formats for other data files
       are described below.

       COMPLEX_DATA
              Alternating floats correspond to the real  (in-phase)  and  imaginary  (quadrature)
              components of complex data samples.  The specified line length should be the number
              of complex samples (pairs of real and imaginary samples) per line.

       ALT_LINE_DATA
              Alternating lines (rows) of data correspond to lines of purely real data  from  two
              separate  arrays.  The first array is often the magnitude of the interferogram, and
              the second may be unwrapped phase, coherence, etc.  This is also  sometimes  called
              hgt or line-interleaved format.

       ALT_SAMPLE_DATA
              Alternating  samples  correspond  to  purely real samples from two separate arrays.
              This format is sometimes used for the amplitudes of the two SAR images.

       FLOAT_DATA
              The file contains data for only one channel or array, and the data are purely real.

EXAMPLES

       Unwrap a wrapped topographic interferogram called ``wrappedfile''  whose  line  length  is
       1024  complex  samples  (output  will be written to a file whose name is compiled into the
       program):

            snaphu wrappedfile 1024

       Unwrap the same file as above, but use brightness information from the  file  ``ampfile,''
       set  the  perpendicular  baseline  to  -165  m at midswath, and place the output in a file
       called ``unwrappedfile'' (coherence data are generated  automatically  if  ``wrappedfile''
       contains complex data and ``ampfile'' contains amplitude data from both SAR images):

            snaphu wrappedfile 1024 -a ampfile \
                 -b -165 -o unwrappedfile

       Unwrap  the  interferogram  as  above,  but  read  correlation  information  from the file
       ``corrfile'' instead of generating it from the interferogram and amplitude data:

            snaphu wrappedfile 1024 -a ampfile -c corrfile \
                 -b -165 -o unwrappedfile

       The following is equivalent to the previous example, but input parameters are read from  a
       configuration file, and verbose output is displayed:

            cat > configfile
            # This is a comment line which will be ignored
            AMPFILE      ampfile
            CORRFILE     corrfile
            BPERP        -165
            OUTFILE      unwrappedfile
            <Ctrl-D>

            snaphu -v -f configfile wrappedfile 1024

       Unwrap  the  same  interferogram,  but  use  only  the  MST  initialization  (with  scalar
       statistical weights) and write the output to ``mstfile'':

            snaphu -f configfile -i wrappedfile 1024 -o mstfile

       Read the unwrapped data in ``mstfile'' and use that as the initialization to the  modified
       network-simplex solver:

            snaphu -f configfile -u mstfile 1024 -o unwrappedfile

       Note  that in the previous two examples, the output file name in the configuration file is
       overrided by the one given on the command line.  The previous two commands together are in
       principle  equivalent  to  the  preceding  one, although round-off errors in flow-to-phase
       conversions may cause minor differences

       Unwrap the interferogram as above, but use the MCF algorithm for initialization:

            snaphu -f configfile wrappedfile 1024 --mcf

       Unwrap the interferogram once again, but first flatten  it  with  the  unwrapped  data  in
       ``estfile,'' then reinsert the subtracted phase after unwrapping:

            snaphu -f configfile wrappedfile 1024 -e estfile

       The  following  assumes  that  the  wrapped  input interferogram measures deformation, not
       topography.  Unwrap the interferogram with the given correlation data:

            snaphu -d wrappedfile 1024 -c corrfile

       Unwrap the input interferogram by minimizing the unweighted congruent L2 norm:

            snaphu -p 2 -n wrappedfile 1024

       Unwrap the interferogram as a three-by-four set of tiles that overlap by 30  pixels,  with
       the specified configuration file, using two processors:

            snaphu wrappedfile 1024 -f configfile \
                 --tile 3 4 30 30 --nproc 2

HINTS AND TIPS

       The  program  may print a warning message about costs being clipped to avoid overflow.  If
       too many costs are clipped, the  value  of  COSTSCALE  may  need  to  be  decreased  in  a
       configuration  file (via the -f option).  If the program prints a warning message about an
       unexpected increase in the total solution cost, this is an indication that too many  costs
       are clipped.  It is usually okay if just a few costs are clipped.

       In  topography  mode,  if  the  unwrapped  result  contains  too many discontinuities, try
       increasing the value of  LAYMINEI  or  decreasing  the  value  of  LAYCONST.   The  former
       determines  the normalized intensity threshold for layover, and the latter is the relative
       layover probability.  If there are  too  many  discontinuities  running  in  azimuth,  try
       decreasing the value of AZDZFACTOR, which affects the ratio of azimuth to range costs.  If
       the baseline is not known, take a guess at it and be sure its sign  is  correct.   Specify
       the  SAR  imaging  geometry  parameters as well as possible.  The defaults assume ERS data
       with five looks taken in azimuth.

       In deformation mode, if the  unwrapped  result  contains  too  many  discontinuities,  try
       increasing  the  value  of  DEFOTHRESHFACTOR or decreasing the value of DEFOCONST.  If the
       surface displacement varies slowly and true  discontinuities  are  not  expected  at  all,
       DEFOMAX_CYCLE  can be set to zero.  This behavior is also invoked with the -s option.  The
       resulting cost functions will be similar to correlation-weighted L2 cost functions, though
       the  former  are  not  necessarily centered on the wrapped gradients.  Congruence is still
       enforced during rather than after optimization.

       The program can be run in initialize-only (-i) mode for quick down-and-dirty  MST  or  MCF
       solutions.

SIGNALS

       Once  the  iterative solver has started, snaphu traps the interrupt (INT) and hangup (HUP)
       signals.  Upon receiving an interrupt, for example if the user types Ctrl-C,  the  program
       finishes  a  minor  iteration,  dumps its current solution to the output, and exits.  If a
       second  interrupt  is  given  after  the  first  (caught)  interrupt,  the  program  exits
       immediately.   If a hangup signal is received, the program dumps its current solution then
       continues to execute normally.

EXIT STATUS

       Upon successful termination, the program exits with code 0.  Errors result in exit code 1.

FILES

       The following files may be useful for reference, but are not required.  They are  included
       in the program source distribution and may be installed somewhere on the system.

       snaphu.conf.full
              Template  configuration file setting all valid input parameters (though some may be
              commented out).

       snaphu.conf.brief
              General-purpose template configuration file setting the most important or  commonly
              modified input parameters.

       In  addition  to  parameters  read from configuration files specified on the command line,
       default parameters may be read from a system-wide configuration file if  such  a  file  is
       named when the program is compiled.

BUGS

       The -w option has not been tested exhaustively.

       Extreme  shadow  discontinuities  (i.e., abrupt elevation drops in increasing range due to
       cliffs facing away from the radar) are not modeled that well in  the  cost  functions  for
       topography mode.

       Abrupt  changes  in  surface reflectivity, such as those of coastlines between bright land
       and dark water, might be misinterpreted as layover and assigned inappropriate costs.

       The algorithm's  behavior  may  be  unpredictable  if  the  costs  are  badly  scaled  and
       excessively clipped to fit into their short-integer data types.

       There  is  no  error  checking  that  ensures that the network node potentials (incost and
       outcost) do not overflow their long-integer data types.

       Automatic flow clipping is built into the MST initialization,  but  it  can  give  erratic
       results  and  may  loop infinitely for certain input data sets.  It is consequently turned
       off by default.

       Dedicated programs for specific Lp objective functions may work better than snaphu  in  Lp
       mode.   Note  that snaphu enforces congruence as part of the problem formulation, however,
       not as a post-optimization processing step.

REFERENCES

       C. W. Chen and H. A. Zebker, ``Two-dimensional phase unwrapping with  use  of  statistical
       models  for  cost functions in nonlinear optimization,'' Journal of the Optical Society of
       America A, 18, 338-351 (2001).

       C. W. Chen and H. A. Zebker, ``Network approaches  to  two-dimensional  phase  unwrapping:
       intractability  and two new algorithms,'' Journal of the Optical Society of America A, 17,
       401-414 (2000).

       C. W. Chen and H. A. Zebker, ``Phase unwrapping for large SAR interferograms:  Statistical
       segmentation  and generalized network models,'' IEEE Transactions on Geoscience and Remote
       Sensing, 40, 1709-1719 (2002).

                                                                                        snaphu(1)