Provided by: grass-doc_7.0.3-1build1_all bug

NAME

       r.horizon  - Computes horizon angle height from a digital elevation model.
       The  module  has two different modes of operation: 1. Computes the entire horizon around a
       single point whose coordinates are given with the ’coord’ option. The horizon  height  (in
       radians). 2. Computes one or more raster maps of the horizon height in a single direction.
       The input for this is the angle (in degrees),  which  is  measured  counterclockwise  with
       east=0, north=90 etc. The output is the horizon height in radians.

KEYWORDS

       raster, solar, sun position

SYNOPSIS

       r.horizon
       r.horizon --help
       r.horizon   [-dc]   elevation=name    [direction=float]     [step=float]     [start=float]
       [end=float]    [bufferzone=float]     [e_buff=float]     [w_buff=float]     [n_buff=float]
       [s_buff=float]      [maxdistance=float]     [output=basename]     [coordinates=east,north]
       [distance=float]   [file=name]   [--overwrite]  [--help]  [--verbose]  [--quiet]  [--ui]

   Flags:
       -d
           Write output in degrees (default is radians)

       -c
           Write output in compass orientation (default is CCW, East=0)

       --overwrite
           Allow output files to overwrite existing files

       --help
           Print usage summary

       --verbose
           Verbose module output

       --quiet
           Quiet module output

       --ui
           Force launching GUI dialog

   Parameters:
       elevation=name [required]
           Name of input elevation raster map

       direction=float
           Direction in which you want to know the horizon height

       step=float
           Angle step size for multidirectional horizon [degrees]

       start=float
           Start angle for multidirectional horizon [degrees]
           Default: 0.0

       end=float
           End angle for multidirectional horizon [degrees]
           Default: 360.0

       bufferzone=float
           For horizon rasters, read from the DEM an extra buffer around the present region

       e_buff=float
           For horizon rasters, read from the DEM an extra buffer eastward the present region

       w_buff=float
           For horizon rasters, read from the DEM an extra buffer westward the present region

       n_buff=float
           For horizon rasters, read from the DEM an extra buffer northward the present region

       s_buff=float
           For horizon rasters, read from the DEM an extra buffer southward the present region

       maxdistance=float
           The maximum distance to consider when finding the horizon height

       output=basename
           Name for output basename raster map(s)

       coordinates=east,north
           Coordinate for which you want to calculate the horizon

       distance=float
           Sampling distance step coefficient (0.5-1.5)
           Default: 1.0

       file=name
           Name of file for output (use output=- for stdout)
           Default: -

DESCRIPTION

       r.horizon computes the angular height of terrain horizon in radians. It reads a raster  of
       elevation data and outputs the horizon outline in one of two modes:

           •   single  point: as a series of horizon heights in the specified directions from the
               given point. The results are written to the stdout.

           •   raster: in this case the output is one or more raster maps, with each point  in  a
               raster  giving  the  horizon height in a specific direction. One raster is created
               for each direction.

       The directions are given as azimuthal angles (in degrees), with the angle starting with  0
       towards  East  and moving counterclockwise (North is 90, etc.). The calculation takes into
       account the actual projection, so the  angles  are  corrected  for  direction  distortions
       imposed  by  it. The directions are thus aligned to those of the geographic projection and
       not the coordinate system given by the rows and columns of the raster map. This correction
       implies  that  the  resulting  cardinal  directions represent true orientation towards the
       East, North, West and South. The only exception of  this  feature  is  LOCATION  with  x,y
       coordinate system, where this correction is not applied.

       Using  the  -c flag, the azimuthal angles will be printed in compass orientation (North=0,
       clockwise).

   Input parameters:
       The elevation parameter is an input elevation raster map. If the buffer options  are  used
       (see  below),  this  raster  should  extend  over  the area that accommodate the presently
       defined region plus defined buffer zones.

       The step parameter  gives  the  angle  step  (in  degrees)  between  successive  azimuthal
       directions for the calculation of the horizon. Thus, a value of 5 for the step will give a
       total of 360/5=72 directions (72 raster maps if used in the raster map mode).

       The start parameter gives the angle start (in degrees) for the calculation of the horizon.
       The default value is 0 (East with North being 90 etc.).

       The end parameter gives the angle end (in degrees) for the calculation of the horizon. The
       end point is omitted!  So for example if we  run  r.horizon  with  step=10,  start=30  and
       end=70 the raster maps generated by r.horizon will be only for angles: 30, 40, 50, 60. The
       default value is 360.

       The direction parameter gives the initial direction of the first  output.  This  parameter
       acts  as  an  direction  angle  offset. For example, if you want to get horizon angles for
       directions 45 and 225 degrees, the direction should be set to 45 and step to 180.  If  you
       only want one single direction, use this parameter to specify desired direction of horizon
       angle, and set the step size to 0 degrees. Otherwise  all  angles  for  a  given  starting
       direction with step of step are calculated.

       The distance controls the sampling distance step size for the search for horizon along the
       line of sight. The default value is 1.0 meaning that the step size will be taken from  the
       raster  resolution.   Setting  the  value  below  1.0  might  slightly improve results for
       directions apart from the cardinal ones, but increasing the processing load of the  search
       algorithm.

       The maxdistance value gives a maximum distance to move away from the origin along the line
       of sight in order to search for the horizon height.  The default maxdistance is  the  full
       map  extent.   The  smaller  this value the faster the calculation but the higher the risk
       that you may miss a terrain feature that  can  contribute  significantly  to  the  horizon
       outline. Note that a viewshed can be calculated with r.viewshed.

       The coordinate parameter takes a pair of easting-northing values in the current coordinate
       system and calculates the values of angular height of the horizon around  this  point.  To
       achieve the consistency of the results, the point coordinate is aligned to the midpoint of
       the closest elevation raster cell.

       If an analyzed point (or raster cell) lies close to the edge of the  defined  region,  the
       horizon  calculation  may  not be realistic, since it may not see some significant terrain
       features which could have contributed to the horizon, because these features  are  outside
       the  region.  There  are  to  options  how  to  set the size of the buffer that is used to
       increase the area of the horizon analysis. The bufferzone parameter allows you to  specify
       the  same  size  of  buffer for all cardinal directions and the parameters e_buff, n_buff,
       s_buff, and w_buff allow you to specify a buffer size individually for each  of  the  four
       directions. The buffer parameters influence only size of the read elevation map, while the
       analysis in the raster mode will be done only for the area specified by the current region
       definition.

       The  basename  parameter  gives the basename of the output horizon raster maps. The raster
       name of each horizon direction raster will be constructed as basename_ANGLE,  where  ANGLE
       is  the angle in degrees with the direction. If you use r.horizon in the single point mode
       this option will be ignored.

       The output parameter allows saving the resulting horizon angles in a comma separated ASCII
       file  (single  point  mode  only). If you use r.horizon in the raster map mode this option
       will be ignored.

       At the moment the elevation and maximum distance must be measured in meters, even  if  you
       use geographical coordinates (longitude/latitude). If your projection is based on distance
       (easting and northing), these too must be in meters. The buffer parameters must be in  the
       same  units  as the raster coordinates (e.g., for latitude-longitude locations buffers are
       measured in degree unit).

METHOD

       The calculation method is based on the method used  in  r.sun  to  calculate  shadows.  It
       starts  at  a  very  shallow angle and walks along the line of sight and asks at each step
       whether the line of sight "hits" the terrain. If so, the angle is increased to  allow  the
       line  of  sight to pass just above the terrain at that point.  This is continued until the
       line of sight reaches a height that is higher than any point in the  region  or  until  it
       reaches  the  border  of  the  region (see also the bufferzone,e_buff, n_buff, s_buff, and
       w_buff). The the number of lines of sight (azimuth  directions)  is  determined  from  the
       direction  and  step  parameters. The method takes into account the curvature of the Earth
       whereby remote features will seem to be lower than they actually are. It also accounts for
       the changes of angles towards cardinal directions caused by the projection (see above).

EXAMPLES

       The examples are intended for the North Carolina sample dataset.

   Single point mode
       Example  1:  determine horizon angle in 225 degree direction (output of horizon angles CCW
       from East):
       g.region raster=elevation -p
       r.horizon elevation=elevation direction=215 step=0 bufferzone=200 \
           coordinates=638871.6,223384.4 maxdistance=5000

       Example 2: determine horizon values starting at 90 deg (North), step size of 5 deg, saving
       result as CSV file:
       r.horizon elevation=elevation direction=90 step=5 bufferzone=200 \
           coordinates=638871.6,223384.4 maxdistance=5000 file=horizon.csv

       Example  3:  test  point near highway intersection, saving result as CSV file for plotting
       the horizon around the highway intersection:
       g.region n=223540 s=220820 w=634650 e=638780 res=10 -p
       r.horizon elevation=elevation direction=0 step=5 bufferzone=200 \
           coordinates=636483.54,222176.25 maxdistance=5000 -d file=horizon.csv
       Test point near high way intersection (North Carolina sample dataset)

       Horizon angles for test point (CCW from East)

       We can plot horizon in polar coordinates using Matplotlib in Python:
       import numpy as np
       import matplotlib.pyplot as plt
       horizon = np.genfromtxt(’horizon.csv’, delimiter=’,’)
       horizon = horizon[1:, :]
       ax = plt.subplot(111, polar=True)
       bars = ax.plot(horizon[:, 0] / 180 * np.pi,
                      (90 - horizon[:, 1]) / 180 * np.pi)
       # uncomment the 2 following lines when using -c flag
       # ax.set_theta_direction(-1)
       # ax.set_theta_zero_location(’N’)
       plt.show()
       Horizon plot in polar coordinates.

   Raster map mode
       Raster map mode (output maps "horangle*" become input for r.sun):
       # we put a bufferzone of 10% of maxdistance around the study area
       # compute only direction between 90 and 270 degrees
       r.horizon elevation=elevation step=30 start=90 end=300 \
           bufferzone=200 output=horangle maxdistance=5000

REFERENCES

       Hofierka J., 1997. Direct solar  radiation  modelling  within  an  open  GIS  environment.
       Proceedings of JEC-GI’97 conference in Vienna, Austria, IOS Press Amsterdam, 575-584

       Hofierka  J.,  Huld T., Cebecauer T., Suri M., 2007. Open Source Solar Radiation Tools for
       Environmental and Renewable Energy Applications, International Symposium on  Environmental
       Software Systems, Prague, 2007

       Neteler  M., Mitasova H., 2004. Open Source GIS: A GRASS GIS Approach, Springer, New York.
       ISBN: 1-4020-8064-6, 2nd Edition 2004 (reprinted 2005), 424 pages

       Project PVGIS, European Commission, DG Joint Research Centre 2001-2007

       Suri M., Hofierka J., 2004.  A New GIS-based Solar Radiation Model and Its Application for
       Photovoltaic Assessments. Transactions in GIS, 8(2), 175-190

SEE ALSO

        r.sun, r.sunmask, r.viewshed

AUTHORS

       Thomas Huld, Joint Research Centre of the European Commission, Ispra, Italy

       Tomas Cebecauer, Joint Research Centre of the European Commission, Ispra, Italy

       Jaroslav Hofierka, GeoModel s.r.o., Bratislava, Slovakia
       Marcel Suri, Joint Research Centre of the European Commission, Ispra, Italy

       ©  2007,  Thomas  Huld, Tomas Cebecauer, Jaroslav Hofierka, Marcel Suri Thomas.Huld@jrc.it
       Tomas.Cebecauer@jrc.it hofierka@geomodel.sk Marcel.Suri@jrc.it

       Last changed: $Date: 2016-01-19 23:08:44 +0100 (Tue, 19 Jan 2016) $

       Main index | Raster index | Topics index | Keywords index | Full index

       © 2003-2016 GRASS Development Team, GRASS GIS 7.0.3 Reference Manual