From 116d4ba7946d7d7c37e567d62d1489103d8a2135 Mon Sep 17 00:00:00 2001 From: Paul Garlick Date: Mon, 13 Jul 2020 13:32:10 +0100 Subject: doc: Add Invoking slope.py section. * doc/fullswof-utils.texi (Usage): Add section. --- doc/fullswof-utils.texi | 66 +++++++++++++++++++++++++++++++++++++++++++++++-- 1 file changed, 64 insertions(+), 2 deletions(-) diff --git a/doc/fullswof-utils.texi b/doc/fullswof-utils.texi index d32d646..d2412c9 100644 --- a/doc/fullswof-utils.texi +++ b/doc/fullswof-utils.texi @@ -147,6 +147,7 @@ ln -s /path/to/installation/directory/python/makeBoundary @menu * Runtime Dependencies:: * Invoking makeBoundary:: +* Invoking slope.py:: @end menu @@ -299,11 +300,71 @@ Manning's n coefficients (comma-separated list, ordered by panel index) number of height intervals @end table - - Comment lines are allowed in the boundary definition file. Lines that start with the @samp{#} character are treated as comments. +@node Invoking slope.py, Demos, Boundary Definition File, Usage +@comment node-name, next, previous, up +@section Invoking slope.py + +@command{slope.py} is an interactive program that is able to derive +local gradient information from elevation data and user input. To start +the program the command is: + +@example +./slope.py +@end example + +The program responds with a request for user input: + +@example +Locate markers (m), plot channel profile (p), save profile (s) or exit (q): +@end example + +The derivation of the local gradient is a two-stage process. Firstly, a +series of markers are placed on opposite sides of the feature of +interest. For example, for a channel feature, markers are placed along +the channel on either side. Secondly, a best-fit curve is fitted to the +data. A plot is displayed and the gradient printed to standard output. +Optionally, the one-dimensional elevation data may be saved to an output +file. + +A detailed description of the options follows: + +@table @samp +@item m +Locate markers. @command{slope.py} opens a window that displays a +contour plot of the elevation data on the left hand side and a contour +plot of the derived slope on the right hand side. The axes are labeled +by cell index number. A legend to the side of each plot shows the range +of contour values. + +The user is required to identify marker locations by positioning the +mouse pointer within the elevation plot and pressing the @key{SPACE} +key. The markers are entered in pairs, one on either side of the +feature of interest. To finish the sequence of marker pairs, the user +is required to move the mouse pointer to a position outside the +elevation plot and press the @kbd{q} key. + +@item p +Plot channel profile. @command{slope.py} constructs a straight line +between each pair of markers and calculates the location of the minimum +elevation value along each line. These locations form a channel +``centre-line''. @command{slope.py} then uses a best-fit procedure to +plot a straight line through the centre-line elevation data. A new +window opens to show the centre-line data and the best-fit line. The +gradient and intercept of the best-fit line are printed to standard +output. + +@item s +Save profile. The channel centre-line data is written to the file +@file{1D.txt}. The file is formatted in the @emph{FullSWOF} @emph{xyz} +format. + +@item q +Quit @command{slope.py}. +@end table + @node Demos, GNU Free Documentation License, Boundary Definition File, Top @comment node-name, next, previous, up @chapter Demos @@ -335,5 +396,6 @@ already exists. Local Variables: mode: texinfo +eval: (outline-minor-mode) TeX-master: t End: -- cgit