Note: This document is for an older version of GRASS GIS that will be discontinued soon. You should upgrade, and read the current manual page.
NAME
i.segment - Identifies segments (objects) from imagery data.
KEYWORDS
imagery,
segmentation,
classification,
object recognition
SYNOPSIS
i.segment
i.segment --help
i.segment [-dwap] group=name[,name,...] output=name [band_suffix=name] threshold=float [radius=float] [hr=float] [method=string] [similarity=string] [minsize=integer] [memory=memory in MB] [iterations=integer] [seeds=name] [bounds=name] [goodness=name] [--overwrite] [--help] [--verbose] [--quiet] [--ui]
Flags:
- -d
- Use 8 neighbors (3x3 neighborhood) instead of the default 4 neighbors for each pixel
- -w
- Weighted input, do not perform the default scaling of input raster maps
- -a
- Use adaptive bandwidth for mean shift
- Range (spectral) bandwidth is adapted for each moving window
- -p
- Use progressive bandwidth for mean shift
- Spatial bandwidth is increased, range (spectral) bandwidth is decreased in each iteration
- --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:
- group=name[,name,...] [required]
- Name of input imagery group or raster maps
- output=name [required]
- Name for output raster map
- band_suffix=name
- Suffix for output bands with modified band values
- Name for output raster map
- threshold=float [required]
- Difference threshold between 0 and 1
- Threshold = 0 merges only identical segments; threshold = 1 merges all
- radius=float
- Spatial radius in number of cells
- Must be >= 1, only cells within spatial bandwidth are considered for mean shift
- Default: 1.5
- hr=float
- Range (spectral) bandwidth [0, 1]
- Only cells within range (spectral) bandwidth are considered for mean shift. Range bandwidth is used as conductance parameter for adaptive bandwidth
- method=string
- Segmentation method
- Options: region_growing, mean_shift
- Default: region_growing
- similarity=string
- Similarity calculation method
- Options: euclidean, manhattan
- Default: euclidean
- minsize=integer
- Minimum number of cells in a segment
- The final step will merge small segments with their best neighbor
- Options: 1-100000
- Default: 1
- memory=memory in MB
- Maximum memory to be used (in MB)
- Cache size for raster rows
- Default: 300
- iterations=integer
- Maximum number of iterations
- seeds=name
- Name for input raster map with starting seeds
- bounds=name
- Name of input bounding/constraining raster map
- Must be integer values, each area will be segmented independent of the others
- goodness=name
- Name for output goodness of fit estimate map
Image segmentation or object recognition is the process of grouping
similar pixels into unique segments, also referred to as objects.
Boundary and region based algorithms are described in the literature,
currently a region growing and merging algorithm is implemented. Each
object found during the segmentation process is given a unique ID and
is a collection of contiguous pixels meeting some criteria. Note the
contrast with image classification where all pixels similar to each
other are assigned to the same class and do not need to be contiguous.
The image segmentation results can be useful on their own, or used as a
preprocessing step for image classification. The segmentation
preprocessing step can reduce noise and speed up the classification.
This segmentation algorithm sequentially examines all current segments
in the raster map. The similarity between the current segment and each
of its neighbors is calculated according to the given distance
formula. Segments will be merged if they meet a number of criteria,
including:
- The pair is mutually most similar to each other (the similarity
distance will be smaller than to any other neighbor), and
- The similarity must be lower than the input threshold. The
process is repeated until no merges are made during a complete pass.
Similarity and Threshold
The similarity between segments and unmerged objects is used to
determine which objects are merged. Smaller distance values indicate a
closer match, with a similarity score of zero for identical pixels.
During normal processing, merges are only allowed when the
similarity between two segments is lower than the given
threshold value. During the final pass, however, if a minimum
segment size of 2 or larger is given with the minsize
parameter, segments with a smaller pixel count will be merged with
their most similar neighbor even if the similarity is greater than
the threshold.
The threshold must be larger than 0.0 and smaller than 1.0. A threshold
of 0 would allow only identical valued pixels to be merged, while a
threshold of 1 would allow everything to be merged. The threshold is scaled to
the data range of the entire input data, not the current computational region.
This allows the application of the same threshold to different computational
regions when working on the same dataset, ensuring that this threshold has the
same meaning in all subregions.
Initial empirical
tests indicate threshold values of 0.01 to 0.05 are reasonable values
to start. It is recommended to start with a low value, e.g. 0.01, and
then perform hierarchical segmentation by using the output of the last
run as seeds for the next run.
Calculation Formulas
Both Euclidean and Manhattan distances use the normal definition,
considering each raster in the image group as a dimension.
In future, the distance calculation will also take into account the
shape characteristics of the segments. The normal distances are then
multiplied by the input radiometric weight. Next an additional
contribution is added:
(1-radioweight) * {smoothness * smoothness
weight + compactness * (1-smoothness weight)},
where
compactness = Perimeter Length / sqrt( Area )
and
smoothness = Perimeter Length / Bounding Box. The
perimeter length is estimated as the number of pixel sides the segment
has.
Seeds
The seeds map can be used to provide either seed pixels (random or
selected points from which to start the segmentation process) or
seed segments. If the seeds are the results of a previous segmentation
with lower threshold, hierarchical segmentation can be performed. The
different approaches are automatically detected by the program: any
pixels that have identical seed values and are contiguous will be
assigned a unique segment ID.
Maximum number of segments
The current limit with CELL storage used for segment IDs is 2
billion starting segment IDs. Segment IDs are assigned whenever a yet
unprocessed pixel is merged with another segment. Integer overflow can
happen for computational regions with more than 2 billion cells and
very low threshold values, resulting in many segments. If integer
overflow occurs durin region growing, starting segments can be used
(created by initial classification or other methods).
Goodness of Fit
The
goodness of fit for each pixel is calculated as 1 - distance
of the pixel to the object it belongs to. The distance is calculated
with the selected
similarity method. A value of 1 means
identical values, perfect fit, and a value of 0 means maximum possible
distance, worst possible fit.
Mean shift image segmentation consists of 2 steps: anisotrophic
filtering and 2. clustering. For anisotrophic filtering new cell values
are calculated from all pixels not farther than
hs pixels away
from the current pixel and with a spectral difference not larger than
hr. That means that pixels that are too different from the current
pixel are not considered in the calculation of new pixel values.
hs and
hr are the spatial and spectral (range) bandwidths
for anisotrophic filtering. Cell values are iteratively recalculated
(shifted to the segment's mean) until the maximum number of iterations
is reached or until the largest shift is smaller than
threshold.
If input bands have been reprojected, they should not be reprojected
with bilinear resampling because that method causes smooth transitions
between objects. More appropriate methods are bicubic or lanczos
resampling.
Boundary constraints limit the adjacency of pixels and segments.
Each unique value present in the
bounds raster are
considered as a MASK. Thus no segments in the final segmentated map
will cross a boundary, even if their spectral data is very similar.
To reduce the salt and pepper effect, a
minsize greater
than 1 will add one additional pass to the processing. During the
final pass, the threshold is ignored for any segments smaller then
the set size, thus forcing very small segments to merge with their
most similar neighbor. A minimum segment size larger than 1 is
recommended when using adaptive bandwidth selected with the
-a
flag.
This example uses the ortho photograph included in the NC Sample
Dataset. Set up an imagery group:
i.group group=ortho_group input=ortho_2001_t792_1m@PERMANENT
Set the region to a smaller test region (resolution taken from
input ortho photograph).
g.region -p raster=ortho_2001_t792_1m n=220446 s=220075 e=639151 w=638592
Try out a low threshold and check the results.
i.segment group=ortho_group output=ortho_segs_l1 threshold=0.02
From a visual inspection, it seems this results in too many segments.
Increasing the threshold, using the previous results as seeds,
and setting a minimum size of 2:
i.segment group=ortho_group output=ortho_segs_l2 threshold=0.05 seeds=ortho_segs_l1 min=2
i.segment group=ortho_group output=ortho_segs_l3 threshold=0.1 seeds=ortho_segs_l2
i.segment group=ortho_group output=ortho_segs_l4 threshold=0.2 seeds=ortho_segs_l3
i.segment group=ortho_group output=ortho_segs_l5 threshold=0.3 seeds=ortho_segs_l4
The output ortho_segs_l4 with threshold=0.2 still has
too many segments, but the output with threshold=0.3 has too few
segments. A threshold value of 0.25 seems to be a good choice. There
is also some noise in the image, lets next force all segments smaller
than 10 pixels to be merged into their most similar neighbor (even if
they are less similar than required by our threshold):
Set the region to match the entire map(s) in the group.
g.region -p raster=ortho_2001_t792_1m@PERMANENT
Run i.segment on the full map:
i.segment group=ortho_group output=ortho_segs_final threshold=0.25 min=10
Processing the entire ortho image with nearly 10 million pixels took
about 450 times more then for the final run.
This example uses the panchromatic channel of the Landsat7 scene included
in the North Carolina sample dataset:
# create group with single channel
i.group group=singleband input=lsat7_2002_80
# set computational region to Landsat7 PAN band
g.region raster=lsat7_2002_80 -p
# perform segmentation with minsize=5
i.segment group=singleband threshold=0.05 minsize=5 \
output=lsat7_2002_80_segmented_min5 goodness=lsat7_2002_80_goodness_min5
# perform segmentation with minsize=100
i.segment group=singleband threshold=0.05 minsize=100
output=lsat7_2002_80_segmented_min100 goodness=lsat7_2002_80_goodness_min100
Original panchromatic channel of the Landsat7 scene
Segmented panchromatic channel, minsize=5
Segmented panchromatic channel, minsize=100
- Further testing of the shape characteristics (smoothness,
compactness), if it looks good it should be added.
(in progress)
- Malahanobis distance for the similarity calculation.
- Improve the optional output from this module, or better yet, add a
module for i.segment.metrics.
- Providing updates to i.maxlik
to ensure the segmentation output can be used as input for the
existing classification functionality.
- Integration/workflow for r.fuzzy (Addon).
This project was first developed during GSoC 2012. Project documentation,
Image Segmentation references, and other information is at the
project wiki.
Information about
classification in GRASS
is at available on the wiki.
g.gui.iclass,
i.group,
i.maxlik,
i.smap,
r.kappa
Eric Momsen - North Dakota State University
Markus Metz (GSoC Mentor)
SOURCE CODE
Available at:
i.segment source code
(history)
Latest change: Tuesday Jun 06 10:07:53 2023 in commit: aaa0827a278dad0f701e41ad4e60e0bd5f72a4a8
Note: This document is for an older version of GRASS GIS that will be discontinued soon. You should upgrade, and read the current manual page.
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© 2003-2023
GRASS Development Team,
GRASS GIS 8.2.2dev Reference Manual