.. index:: ! backtracker .. include:: ../module_supplements_purpose.rst_ *********** backtracker *********** |backtracker_purpose| Synopsis -------- .. include:: ../../common_SYN_OPTs.rst_ **gmt backtracker** [ *table* ] |-E|\ *rot_file*\|\ *ID1-ID2*\|\ *lon*/*lat*/*angle*\ [**+i**] [ |-A|\ [*young*/*old*] ] [ |-D|\ **f**\|\ **b** ] [ |-F|\ *driftfile* ] [ |-L|\ **f**\|\ **b**\ **F**\|\ **B**\ [*step*] ] [ |-M|\ [*factor*] ] [ |-N|\ *upper_age* ] [ |-Q|\ *fixed_age* ] [ |-S|\ *filestem* ] [ |-T|\ *zero_age* ] [ |SYN_OPT-V| ] [ |-W|\ [**a**\|\ **t**] ] [ |SYN_OPT-b| ] [ |SYN_OPT-d| ] [ |SYN_OPT-e| ] [ |SYN_OPT-f| ] [ |SYN_OPT-h| ] [ |SYN_OPT-i| ] [ |SYN_OPT-o| ] [ |SYN_OPT-q| ] [ |SYN_OPT-s| ] [ |SYN_OPT-:| ] [ |SYN_OPT--| ] |No-spaces| Description ----------- **backtracker** reads (*longitude, latitude, age*) positions from *infiles* [or standard input] and computes rotated (*x, y, t*) coordinates using the specified rotation parameters. It can either calculate final positions [Default] or create a sampled track (flowline or hotspot track) between the initial and final positions [*Wessel*, 1999]. The former mode allows additional data fields after the first 3 columns which must have (longitude,latitude,age). See option **-:** on how to read (latitude,longitude,age) files. Required Arguments ------------------ .. |Add_intables| unicode:: 0x20 .. just an invisible code .. include:: ../../explain_intables.rst_ .. include:: explain_rots.rst_ Optional Arguments ------------------ .. _-A: **-A**\ [*young*/*old*] Used in conjunction with **-Lb**\|\ **f** to limit the track output to those sections whose predicted ages lie between the specified *young* and *old* limits. If **-LB**\|\ **F** is used instead then the limits apply to the stage ids (id 1 is the youngest stage). If no limits are specified then individual limits for each record are expected in columns 4 and 5 of the input file. .. _-D: **-Df**\|\ **b** Set the direction to go: **-Df** will go backward in time (from younger to older positions), while **-Db** will go forward in time (from older to younger positions) [Default]. **Note**: For **-Db** you are specifying the age at the given location, whereas for **-Df** you are not; instead you specify the age at the reconstructed point. .. _-F: **-F**\ *driftfile* Supply a file with (*lon, lat, age*) records that describe the history of hotspot motion for the current hotspot. The reconstructions will use the 3rd data input column (i.e., the age) to obtain the location of the hotspot at that time, via an interpolation of the hotspot motion history. Input data locations are then adjusted by the change in hotspot location when reconstructing the point or path [No drift]. **Note**: (1) When |-F| is used the |-L| *step* values will be in time (Myr). (2) Drift is only considered when backtracking a point (**-Db**) or predicting seamount trails (**-Df** **-Lb**). (3) Cannot be used with |-M|. .. _-L: **-Lf**\|\ **b**\|\ **F**\|\ **B**\ [*step*] Specify a sampled path between initial and final position: **-Lf** will draw particle flowlines, while **-Lb** will draw backtrack (hotspot track) paths. Append sampling interval in km. If *step* < 0 or not provided then only the rotation times will be returned. When **-LF** or **-LB** is used, the third output column will contain the stage id (1 is youngest) [Default is along-track predicted ages]. You can control the direction of the paths by using |-D|. .. _-M: **-M**\ [*factor*] Scale opening angles by *factor* on output [0.5]. Typically used to get half-spreading rates needed to compute flowlines. .. _-N: **-N**\ *upper_age* Set the maximum age to extend the oldest stage rotation back in time [Default is no extension]. .. _-Q: **-Q**\ *fixed_age* Assign a fixed age to all positions. Only (*lon, lat*) input is expected [Default expects longitude, latitude, age]. Useful when the input are points defining isochrons. .. _-S: **-S**\ *filestem* When |-L| is set, the tracks are normally written to standard output as a multisegment file. Specify a *filestem* to have each track written to *filestem.#*, where *#* is the track number. The track number is also copied to the 4th output column. .. _-T: **-T**\ *zero_age* Set the current time [Default is 0 Ma]. .. |Add_-V| replace:: |Add_-V_links| .. include:: /explain_-V.rst_ :start-after: **Syntax** :end-before: **Description** .. _-W: **-W**\ [**a**\|\ **t**] Rotates the given input (*lon, lat, time*) and calculates the confidence ellipse for the projected point. The input point *must* have a time coordinate that exactly matches a particular total reconstruction rotation time, otherwise the point will be skipped. Append **t** or **a** to output time or angle, respectively, after the projected (*lon, lat*). After these 2-3 items, we write azimuth, major, minor (in km) for the 95% confidence ellipse. See |-D| for the direction of rotation. .. |Add_-bi| replace:: [Default is 3 input columns]. .. include:: ../../explain_-bi.rst_ .. |Add_-bo| replace:: [Default is same as input]. .. include:: ../../explain_-bo.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_-f| unicode:: 0x20 .. just an invisible code .. include:: ../../explain_-f.rst_ .. |Add_-h| unicode:: 0x20 .. just an invisible code .. include:: ../../explain_-h.rst_ .. include:: ../../explain_-icols.rst_ .. include:: ../../explain_-ocols.rst_ .. include:: ../../explain_-q.rst_ .. include:: ../../explain_-s.rst_ .. include:: ../../explain_colon.rst_ .. include:: ../../explain_help.rst_ .. include:: explain_geodetic.rst_ Examples -------- To backtrack the (*x, y, t*) points in the file seamounts.txt to their origin (presumably the hotspot), using the DC85.txt Euler poles, run :: gmt backtracker seamounts.txt -Db -EDC85.txt > newpos.txt To project flowlines forward from the (*x, y, t*) points stored in several 3-column, binary, double precision files, run :: gmt backtracker points.* -Df -EDC85.txt -Lf25 -bo -bi3 > lines.b This file can then be plotted with :doc:`plot `. To compute the predicted Hawaiian hotspot track from 0 to 80 Ma every 1 Ma, given a history of hotspot motion file (HIdrift.txt) and a set of total reconstruction rotations for the plate (PAC_APM.txt), try :: echo 204 19 80 | gmt backtracker -Df -EPAC_APM.txt -Lb1 > path.txt To predict Hawaiian-Emperor seamount trail using the Pacific absolute plate and plume motion from *Doubrovine et al.* [2012], use :: echo -155.2872 19.3972 80 | gmt backtracker -Df -Lb1 -ED2012.txt -FD2012_HI_drift.txt > traildrift.txt To predict the Hawaiian-Emperor seamount trail that would have resulted if no plume drift had been in effect, using the Pacific absolute plate motion model from *Doubrovine et al.* [2012], use :: echo -155.2872 19.3972 80 | gmt backtracker -Df -Lb1 -ED2012.txt > trail.txt Notes ----- GMT distributes the EarthByte rotation model Global_EarthByte_230-0Ma_GK07_AREPS.rot. To use an alternate rotation file, create an environmental parameters named **GPLATES_ROTATIONS** that points to an alternate rotation file. See Also -------- :doc:`gmt ` , :doc:`gmtpmodeler`, :doc:`grdpmodeler`, :doc:`grdrotater`, :doc:`grdspotter`, :doc:`hotspotter`, :doc:`mapproject `, :doc:`originater`, :doc:`project `, :doc:`plot ` References ---------- Wessel, P., 1999, "Hotspotting" tools released, EOS Trans. AGU, 80 (29), p. 319. Doubrovine, P. V., B. Steinberger, and T. H. Torsvik, 2012, Absolute plate motions in a reference frame defined by moving hot spots in the Pacific, Atlantic, and Indian oceans, *J. Geophys. Res.*, **117**\ (B09101), https://doi.org/10.1029/2011jb009072.