NAME

       ncbo - netCDF Binary Operator

SYNTAX

       ncbo  [-3]  [-4]  [-5]  [-6] [-7] [-A] [--bfr sz_byt][-C][-c] [--cnk_byt sz_byt][--cnk_csh
       sz_byt][--cnk_dmn nm,sz_lmn] [--cnk_map map] [--cnk_min sz_byt] [--cnk_plc plc] [--cnk_scl
       sz_lmn][-D  dbg_lvl]  [-d  dim,[  min][,[  max]]]  [-F]  [--fl_fmt=fmt]  [-G  gpe_dsc] [-g
       grp[,...]]  [--glb att_name= att_val]] [-h]  [--hdf]  [--hdr_pad  sz_byt][--hpss_try]  [-L
       dfl_lvl] [-l path] [--msa] [--no_cll_msr] [--no_frm_trm] [--no_tmp_fl] [-O] [-p path] [-R]
       [-r] [--ram_all] [-t thr_nbr] [--unn] [-v var[,...]]  [-X box] [-x] file_1 file_2 file_3

DESCRIPTION

       ncbo subtracts variables in file_2 from the corresponding variables (those with  the  same
       name)  in  file_1  and stores the results in file_3.  Variables in file_2 are broadcast to
       conform to the corresponding variable in file_1 if  necessary.   Broadcasting  a  variable
       means  creating data in non-existing dimensions from the data in existing dimensions.  For
       example, a two dimensional variable in file_2 can be subtracted from a four, three, or two
       (but  not  one  or  zero)  dimensional  variable  (of  the  same  name)  in  file_1.  This
       functionality allows the user to compute anomalies from the mean.  Note that variables  in
       file_1  are  not broadcast to conform to the dimensions in file_2.  Thus, ncbo, the number
       of dimensions, or rank, of any processed variable in file_1 must be greater than or  equal
       to  the  rank  of  the  same  variable in file_2.  Furthermore, the size of all dimensions
       common to both file_1 and file_2 must be equal.

       When computing anomalies from the mean it is often the case that  file_2  was  created  by
       applying an averaging operator to a file with the same dimensions as file_1, if not file_1
       itself.  In these cases, creating file_2 with ncra rather than ncwa will  cause  the  ncbo
       operation  to  fail.   For  concreteness  say  the record dimension in file_1 is time.  If
       file_2 were created by averaging file_1 over the time dimension  with  the  ncra  operator
       rather  than  with  the  ncwa  operator,  then file_2 will have a time dimension of size 1
       rather than having no time dimension at all In this case the input files to  ncbo,  file_1
       and  file_2,  will  have  unequally  sized  time dimensions which causes ncbo to fail.  To
       prevent this from occurring, use ncwa to  remove  the  time  dimension  from  file_2.   An
       example is given below.

       ncbo  will  never difference coordinate variables or variables of type NC_CHAR or NC_BYTE.
       This  ensures  that  coordinates  like  (e.g.,  latitude  and  longitude)  are  physically
       meaningful  in the output file, file_3.  This behavior is hardcoded.  ncbo applies special
       rules to some NCAR CSM fields (e.g., ORO).   See  NCAR  CSM  Conventions  for  a  complete
       description.  Finally, we note that ncflint (ncflint netCDF File Interpolator) can be also
       perform file subtraction (as well as addition, multiplication and interpolation).

EXAMPLES

       Say files 85_0112.nc and 86_0112.nc each contain 12 months of data.  Compute the change in
       the monthly averages from 1985 to 1986:
              ncbo 86_0112.nc 85_0112.nc 86m85_0112.nc

       The  following  examples  demonstrate  the  broadcasting  feature of ncbo.  Say we wish to
       compute the monthly anomalies of T from the yearly average of T for the year 1985.   First
       we  create  the  1985  average  from  the  monthly  data,  which is stored with the record
       dimension time.
              ncra 85_0112.nc 85.nc
              ncwa -O -a time 85.nc 85.nc
       The second command, ncwa, gets rid of the time dimension of  size  1  that  ncra  left  in
       85.nc.   Now  none  of  the  variables  in  85.nc  has a time dimension.  A quicker way to
       accomplish this is to use ncwa from the beginning:
              ncwa -a time 85_0112.nc 85.nc
       We are now ready to use ncbo to compute the anomalies for 1985:
              ncbo -v T 85_0112.nc 85.nc t_anm_85_0112.nc
       Each of the 12 records in t_anm_85_0112.nc now contains the monthly deviation  of  T  from
       the annual mean of T for each gridpoint.

       Say  we  wish  to  compute  the monthly gridpoint anomalies from the zonal annual mean.  A
       zonal mean is a quantity that has been averaged over the longitudinal  (or  x)  direction.
       First  we  use  ncwa  to average over longitudinal direction lon, creating xavg_85.nc, the
       zonal mean of 85.nc.  Then we use ncbo to subtract the zonal annual means from the monthly
       gridpoint data:
              ncwa -a lon 85.nc xavg_85.nc
              ncbo 85_0112.nc xavg_85.nc tx_anm_85_0112.nc
       Assuming 85_0112.nc has dimensions time and lon, this example only works if xavg_85.nc has
       no time or lon dimension.

       As a final example, say we have five years of monthly data (i.e.,  60  months)  stored  in
       8501_8912.nc  and  we wish to create a file which contains the twelve month seasonal cycle
       of the average monthly anomaly from the five-year mean of this data.  The following method
       is  just one permutation of many which will accomplish the same result.  First use ncwa to
       create the file containing the five-year mean:
              ncwa -a time 8501_8912.nc 8589.nc
       Next use ncbo to create a file containing the difference of each  month's  data  from  the
       five-year mean:
              ncbo 8501_8912.nc 8589.nc t_anm_8501_8912.nc
       Now  use  ncks  to  group the five January anomalies together in one file, and use ncra to
       create the average anomaly for all five Januarys.  These commands are embedded in a  shell
       loop so they are repeated for all twelve months:
              foreach idx (01 02 03 04 05 06 07 08 09 10 11 12)
              ncks -F -d time,,,12 t_anm_8501_8912.nc foo.
              ncra foo. t_anm_8589_.nc
              end
       Note  that ncra understands the stride argument so the two commands inside the loop may be
       combined into the single command
              ncra -F -d time,,,12 t_anm_8501_8912.nc foo.
       Finally, use ncrcat to concatenate the 12 average monthly anomaly files into  one  twelve-
       record file which contains the entire seasonal cycle of the monthly anomalies:
              ncrcat t_anm_8589_??.nc t_anm_8589_0112.nc

AUTHOR

       NCO manual pages written by Charlie Zender and originally formatted by Brian Mays.

REPORTING BUGS

       Report bugs to <http://sf.net/bugs/?group_id=3331>.

COPYRIGHT

       Copyright © 1995-2018 Charlie Zender
       This  is  free software; see the source for copying conditions.  There is NO warranty; not
       even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.

SEE ALSO

       The full documentation for NCO is maintained as a Texinfo  manual  called  the  NCO  Users
       Guide.   Because  NCO  is mathematical in nature, the documentation includes TeX-intensive
       portions  not  viewable  on  character-based  displays.   Hence  the  only  complete   and
       authoritative  versions  of  the  NCO  Users  Guide  are  the  PDF (recommended), DVI, and
       Postscript  versions  at  <http://nco.sf.net/nco.pdf>,  <http://nco.sf.net/nco.dvi>,   and
       <http://nco.sf.net/nco.ps>,   respectively.   HTML  and  XML  versions  are  available  at
       <http://nco.sf.net/nco.html> and <http://nco.sf.net/nco.xml>, respectively.

       If the info and NCO programs are properly installed at your site, the command

              info nco

       should give you access to the complete manual, except for the TeX-intensive portions.

HOMEPAGE

       The NCO homepage at <http://nco.sf.net> contains more information.

                                                                                          NCBO(1)