NAME

KEYWORDS

SYNOPSIS

DESCRIPTION

What is geomorphon:

Geomorphon is a new concept of presentation and analysis of terrain forms. This concept utilises 8-tuple pattern of the visibility neighbourhood and breaks well known limitation of standard calculus approach where all terrain forms cannot be detected in a single window size. The pattern arises from a comparison of a focus pixel with its eight neighbors starting from the one located to the east and continuing counterclockwise producing ternary operator. For example, a tuple {+,-,-,-,0,+,+,+} describes one possible pattern of relative measures {higher, lower, lower, lower, equal, higher, higher, higher} for pixels surrounding the focus pixel. It is important to stress that the visibility neighbors are not necessarily an immediate neighbors of the focus pixel in the grid, but the pixels determined from the line-of-sight principle along the eight principal directions. This principle relates surface relief and horizontal distance by means of so-called zenith and nadir angles along the eight principal compass directions. The ternary operator converts the information contained in all the pairs of zenith and nadir angles into the ternary pattern (8-tuple). The result depends on the values of two parameters: search radius (L) and relief threshold (d). The search radius is the maximum allowable distance for calculation of zenith and nadir angles. The relief threshold is a minimum value of difference between LOSs angle (zenith and nadir) that is considered significantly different from the horizon. Two lines-of-sight are necessary due to zenith LOS only, does not detect positive forms correctly.

There are 3**8 = 6561 possible ternary patterns (8-tuples). However by eliminating all patterns that are results of either rotation or reflection of other patterns wa set of 498 patterns remain referred as geomorphons. This is a comprehensive and exhaustive set of idealized landforms that are independent of the size, relief, and orientation of the actual landform.

Form recognition depends on two free parameters: Search radius and flatness threshold. Using larger values of L and is tantamount to terrain classification from a higher and wider perspective, whereas using smaller values of L and is tantamount to terrain classification from a local point of view. A character of the map depends on the value of L. Using small value of L results in the map that correctly identifies landforms if their size is smaller than L; landforms having larger sizes are broken down into components. Using larger values of L allows simultaneous identification of landforms on variety of sizes in expense of recognition smaller, second-order forms. There are two additional parameters: skip radius used to eliminate impact of small irregularities. On the contrary flatness distance eliminates the impact of very high distance (in meters) of search radius which may not detect elevation difference if this is at very far distance. Important especially with low resolution DEMS.

OPTIONS

-m

All distance parameters (search, skip, flat distances) are supplied as meters instead of cells (default). To avoid situation when supplied distances is smaller than one cell program first check if supplied distance is longer than one cell in both NS and WE directions. For LatLong projection only NS distance checked, because in latitude angular unit comprise always bigger or equal distance than longitude one. If distance is supplied in cells, For all projections is recalculated into meters according formula: number_of_cells*resolution_along_NS_direction. It is important if geomorphons are calculated for large areas in LatLong projection.

elevation

Digital elevation model. Data can be of any type and any projection. During calculation DEM is stored as floating point raster.

search

Determines length on the geodesic distances in all eight directions where line-of-sight is calculated. To speed up calculation is determines only these cells which centers falls into the distance.

skip

Determines length on the geodesic distances at the beginning of calculation all eight directions where line-of-sight is yet calculated. To speed up calculation this distance is always recalculated into number of cell which are skipped at the beginning of every line-of-sight and is equal in all direction. This parameter eliminates forms of very small extend, smaller than skip parameter.

flat

The difference (in degrees) between zenith and nadir line-of-sight which indicate flat direction. If higher threshold produce more flat maps. If resolution of the map is low (more than 1 km per cell) threshold should be very small (much smaller than 1 degree) because on such distance 1 degree of difference means several meters of high difference.

dist

>Flat distance. This is additional parameter defining the distance above which the threshold starts to decrease to avoid problems with pseudo-flat line-of-sights if real elevation difference appears on the distance where its value is higher (TO BE CORRECTED).

comparison

Comparison mode for zenith/nadir line-of-sight search. "anglev1" is the original r.geomorphon comparison mode. "anglev2" is an improved mode, which better handles angle thresholds and zenith/nadir angles that are exactly equal. "anglev2_distance" in addition to that takes the zenith/nadir distances into account when the angles are exactly equal.

forms

Returns geomorphic map with 10 most popular terrestrial forms. Legend for forms, its definition by the number of + and - and its idealized visualisation are presented at the image.

Forms represented by geomorphons:

ternary

returns code of one of 498 unique ternary patterns for every cell. The code is a decimal representation of 8-tuple minimalised patterns written in ternary system. Full list of patterns is available in source code directory as patterns.txt. This map can be used to create alternative form classification using supervised approach.

positive and negative

returns codes binary patterns for zenith (positive) and nadir (negative) line of sights. The code is a decimal representation of 8-tuple minimalised patterns written in binary system. Full list of patterns is available in source code directory as patterns.txt.

coordinates

The central point of a single geomorphon to profile. The central point must be within the computational region, which should be large enough to accommodate the search radius. Setting the region larger than that will not produce more accurate data, but in the current implementation will slow the computation down. For the best results remember to align the region to the raster cells. Profiling is mutually exclusive with any raster outputs, but other parameters and flags (such as elevation, search, comparison, -m and -e) work as usual.

profiledata

The output file name for the complete profile data, "-" means to write to the standard output. The data is in a machine-readable format and it includes assorted values describing the computation context and parameters, as well as its intermediate and final results.

profileformat

Format of the profile data: "json", "yaml" or "xml".

NOTE: parameters below are experimental. The usefulness of these parameters are currently under investigation.

intensity

returns average difference between central cell of geomorphon and eight cells in visibility neighbourhood. This parameter shows local (as is visible) exposition/abasement of the form in the terrain.

range

returns difference between minimum and maximum values of visibility neighbourhood.

variance

returns variance (difference between particular values and mean value) of visibility neighbourhood.

extend

returns area of the polygon created by the 8 points where line-of-sight cuts the terrain (see image in description section).

azimuth

returns orientation of the polygon constituting geomorphon. This orientation is currently calculated as a orientation of least square fit line to the eight verticles of this polygon.

elongation

returns proportion between sides of the bounding box rectangle calculated for geomorphon rotated to fit least square line.

width

returns length of the shorter side of the bounding box rectangle calculated for geomorphon rotated to fit least square line.

NOTES

EXAMPLES

Geomorphon calculation: extraction of terrestrial landforms

g.region raster=eu_dem_25m -p
r.geomorphon elevation=eu_dem_25m forms=eu_dem_25m_geomorph

# verify terrestrial landforms found in DEM
r.category eu_dem_25m_geomorph
 1  flat
 2  peak
 3  ridge
 4  shoulder
 5  spur
 6  slope
 7  hollow
 8  footslope
 9  valley
 10 pit

Extraction of peaks

r.mapcalc expression="eu_dem_25m_peaks = if(eu_dem_25m_geomorph == 2, 1, null())"
r.thin input=eu_dem_25m_peaks output=eu_dem_25m_peaks_thinned
r.to.vect input=eu_dem_25m_peaks_thinned output=eu_dem_25m_peaks type=point
v.info input=eu_dem_25m_peaks

REFERENCES

• Stepinski, T., Jasiewicz, J., 2011, Geomorphons - a new approach to classification of landform, in : Eds: Hengl, T., Evans, I.S., Wilson, J.P., and Gould, M., Proceedings of Geomorphometry 2011, Redlands, 109-112 (PDF)
• Jasiewicz, J., Stepinski, T., 2013, Geomorphons - a pattern recognition approach to classification and mapping of landforms, Geomorphology, vol. 182, 147-156 (DOI: 10.1016/j.geomorph.2012.11.005)

SEE ALSO

AUTHORS

SOURCE CODE

Available at: r.geomorphon source code (history)

Latest change: Friday Oct 25 16:16:09 2024 in commit: 4ea983fff87951516b6e4578a0527e3b10f04643

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