.. index:: ! talwani2d .. include:: ../module_supplements_purpose.rst_ ********* talwani2d ********* |talwani2d_purpose| Synopsis -------- .. include:: ../../common_SYN_OPTs.rst_ **gmt talwani2d** [ *table* ] [ |-A| ] [ |-D|\ *density* ] ] [ |-F|\ **f**\|\ **n**\ [*lat*]\|\ **v** ] [ |-M|\ [**h**]\ [**v**] ] [ |-N|\ *trackfile* ] [ |-T|\ *min*\ /*max*\ /\ *inc*\ [**+i**\|\ **n**]\ \|\ *file*\|\ *list* ] [ |-Z|\ *level*\ [/*ymin*\ /*ymax*] ] [ |SYN_OPT-V| ] [ |SYN_OPT-bi| ] [ |SYN_OPT-d| ] [ |SYN_OPT-e| ] [ |SYN_OPT-h| ] [ |SYN_OPT-i| ] [ |SYN_OPT-o| ] [ |SYN_OPT-x| ] [ |SYN_OPT--| ] |No-spaces| Description ----------- **talwani2d** will read the multi-segment *table* from file (or standard input). This file contains cross-sections of one or more 2-D bodies, with one polygon per segment. The segment header must contain the parameter *density*, which states the density of this body (individual body densities may be overridden by a fixed constant density contrast given via an optional |-D|). We can compute anomalies on an equidistant lattice (by specifying a lattice with **-T**) or provide arbitrary output points specified in a file via |-N|. Choose between free-air anomalies, vertical gravity gradient anomalies, or geoid anomalies. Options are available to control axes units and direction. For theory, see references at the end. Required Arguments ------------------ *table* One or more ASCII files describing cross-sectional polygons of one or more bodies. Polygons will be automatically closed if not already closed, and repeated vertices will be eliminated. The segment header for each body will be examined for a density parameter in :math:`\mbox{kg/m}^3` or :math:`\mbox{g/cm}^3`; see |-D| for overriding this value. If no *table* is given then we read standard input. Optional Arguments ------------------ .. _-A: **-A** The *z*-axis should be positive upwards [Default is down]. .. _-D: **-D**\ *density* Sets a fixed density contrast that overrides any per-body settings in the model file, in :math:`\mbox{kg/m}^3` or :math:`\mbox{g/cm}^3`. .. _-F: **-F**\ **f**\|\ **n**\ [*lat*]\|\ **v** Specify desired gravitational field component. Choose between **f** (free-air anomaly) [Default], **n** (geoid; optionally append average latitude for normal gravity reference value [45]) or **v** (vertical gravity gradient). .. _-M: **-M**\ [**h**]\ [**v**] Sets distance units used. Append **h** to indicate horizontal distances are in km [m], and append **z** to indicate vertical distances are in km [m]. .. _-N: **-N**\ *trackfile* Specifies locations where we wish to compute the predicted value. When this option is used you cannot use |-T| to set an equidistant lattice. The output data records are written to standard output (see **-bo** for binary output). .. _-T: **-T**\ *min*\ /*max*\ /\ *inc*\ [**+i**\|\ **n**]\ \|\ *file*\|\ *list* Specify an equidistant output lattice. For details on array creation, see `Generate 1-D Array`_. .. |Add_-V| replace:: |Add_-V_links| .. include:: /explain_-V.rst_ :start-after: **Syntax** :end-before: **Description** .. _-Z: **-Z**\ *level*\ [/*ymin*\ /*ymax*] Set a constant observation level [0]. Optionally, and for gravity anomalies only (**-Ff**), append the finite extent limits of a 2.5-D body. .. |Add_-bi| replace:: [Default is 2 input columns]. .. include:: ../../explain_-bi.rst_ .. |Add_-d| unicode:: 0x20 .. just an invisible code .. include:: ../../explain_-d.rst_ .. |Add_-e| unicode:: 0x20 .. just an invisible code .. include:: ../../explain_-e.rst_ .. |Add_-h| replace:: Not used with binary data. .. include:: ../../explain_-h.rst_ .. include:: ../../explain_-icols.rst_ .. include:: ../../explain_-ocols.rst_ .. include:: ../../explain_core.rst_ .. include:: ../../explain_colon.rst_ .. include:: ../../explain_help.rst_ .. include:: ../../explain_distunits.rst_ .. include:: ../../explain_array.rst_ Examples -------- To compute the free-air anomalies on an equidistant profile over a 2-D body that has been contoured and saved to body2d.txt, using 1700 :math:`\mbox{kg/m}^3` as a constant density contrast, with all distances in meters, try :: gmt talwani2d -T-200/200/2 body2d.txt -D1700 -Ff > 2dgrav.txt To obtain the vertical gravity gradient anomaly along the track given by the file crossing.txt for the same model, try :: gmt talwani2d -Ncrossing.txt body2d.txt -D1700 -Fv > vgg_crossing.txt The geoid anomaly for the same setup, evaluated at 60N, is given by :: gmt talwani2d -Ncrossing.txt body2d.txt -D1700 -Fn60 > n_crossing.txt Notes ----- #. The 2-D geoid anomaly is a logarithmic potential and thus has no natural reference level. We simply remove the most negative (if density contrast is positive) or positive (if density contrast is negative) computed value from all values, rendering the entire anomaly positive (or negative). You can use :doc:`gmtmath ` to change the zero level to suit your needs. References ---------- Rasmussen, R., and L. B. Pedersen (1979), End corrections in potential field modeling, *Geophys. Prospect., 27*, 749-760. Chapman, M. E., 1979, Techniques for interpretation of geoid anomalies, *J. Geophys. Res., 84(B8)*, 3793-3801. Kim, S.-S., and P. Wessel, 2016, New analytic solutions for modeling vertical gravity gradient anomalies, *Geochem. Geophys. Geosyst., 17*, `https://doi.org/10.1002/2016GC006263 `_. Talwani, M., J. L. Worzel, and M. Landisman, 1959, Rapid gravity computations for two-dimensional bodies with application to the Mendocino submarine fracture zone, *J. Geophys. Res., 64*, 49-59. See Also -------- :doc:`gmt.conf `, :doc:`gmt `, :doc:`grdmath `, :doc:`gmtmath `, :doc:`gravfft `, :doc:`gmtgravmag3d `, :doc:`grdgravmag3d `, :doc:`talwani3d `