qgis · May 24, 2017
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@@ -1,7 +1,7 @@
 <root>
   <key>CompareImages</key>
   <exec>otbcli_CompareImages</exec>
-  <longname>Images comparaison</longname>
+  <longname>Image comparison</longname>
   <group>Miscellaneous</group>
   <description>Estimator between 2 images.</description>
   <parameter>
 
@@ -95,7 +95,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -78,7 +78,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -87,7 +87,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -103,7 +103,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -70,7 +70,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -80,7 +80,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -90,7 +90,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -78,7 +78,7 @@
     <parameter_type source_parameter_type="ParameterType_Radius">ParameterNumber</parameter_type>
     <key>interpolator.bco.radius</key>
     <name>Radius for bicubic interpolation</name>
-    <description>This parameter allows controling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.</description>
+    <description>This parameter allows controling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.</description>
     <minValue />
     <maxValue />
     <default>2</default>
 
@@ -2,4 +2,4 @@
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 dl { border: 3px double #ccc; padding: 0.5em; } dt { float: left; clear: left; text-align: left; font-weight: bold; color: green; } dt:after { content: ":"; } dd { margin: 0 0 0 220px; padding: 0 0 0.5em 0; }
 </style>
-</head><body><h1>GridBasedImageResampling</h1><h2>Brief Description</h2>Resamples an image according to a resampling grid<h2>Tags</h2>Geometry<h2>Long Description</h2>This application allows performing image resampling from an input resampling grid.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -grid</b> &lt;string&gt; . Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -out</b> &lt;string&gt; Parameters of the output image. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; Available memory for processing (in MB). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>otbStereorecificationGridGeneration<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: ROI_IKO_PAN_LesHalles_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: ROI_IKO_PAN_LesHalles_sub_resampled.tif uint8</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">grid.in: ROI_IKO_PAN_LesHalles_sub_deformation_field.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out.sizex: 256</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out.sizey: 256</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">grid.type: def</p></li></ul></body></html>
+</head><body><h1>GridBasedImageResampling</h1><h2>Brief Description</h2>Resamples an image according to a resampling grid<h2>Tags</h2>Geometry<h2>Long Description</h2>This application allows performing image resampling from an input resampling grid.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -grid</b> &lt;string&gt; . Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -out</b> &lt;string&gt; Parameters of the output image. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; Available memory for processing (in MB). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>otbStereorecificationGridGeneration<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: ROI_IKO_PAN_LesHalles_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: ROI_IKO_PAN_LesHalles_sub_resampled.tif uint8</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">grid.in: ROI_IKO_PAN_LesHalles_sub_deformation_field.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out.sizex: 256</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out.sizey: 256</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">grid.type: def</p></li></ul></body></html>
@@ -2,4 +2,4 @@
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 </style>
-</head><body><h1>HomologousPointsExtraction</h1><h2>Brief Description</h2>Compute homologous points between images using keypoints<h2>Tags</h2>Feature Extraction<h2>Long Description</h2>This application allows computing homologous points between images using keypoints.  SIFT or SURF keypoints can be used and the band on which keypoints are computed can be set independantly for both images. The application offers two modes : the first is the full mode where keypoints are extracted from the full extent of both images (please note that in this mode large image file are not supported). The second mode, called geobins, allows one to set-up spatial binning to get fewer points spread across the entire image. In this mode, the corresponding spatial bin in the second image is estimated using geographical transform or sensor modelling, and is padded according to the user defined precision. Last, in both modes the application can filter matches whose colocalisation in first image exceed this precision. The elevation parameters are to deal more precisely with sensor modelling in case of sensor geometry data. The outvector option allows creating a vector file with segments corresponding to the localisation error between the matches. It can be useful to assess the precision of a registration for instance. The vector file is always reprojected to EPSG:4326 to allow display in a GIS. This is done via reprojection or by applying the image sensor models.<h2>Parameters</h2><ul><li><b>[param] -in1</b> &lt;string&gt;  First input image. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -band1</b> &lt;int32&gt; Index of the band from input image 1 to use for keypoints extraction. Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -in2</b> &lt;string&gt;  Second input image. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -band2</b> &lt;int32&gt; Index of the band from input image 1 to use for keypoints extraction. Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -threshold</b> &lt;float&gt; The distance threshold for matching.. Mandatory: True. Default Value: &quot;0.6&quot;</li><li><b>[param] -backmatching</b> &lt;boolean&gt; If set to true, matches should be consistent in both ways.. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -precision</b> &lt;float&gt; Estimated precision of the colocalisation function in pixels. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -mfilter</b> &lt;boolean&gt; If enabled, this option allows one to filter matches according to colocalisation from sensor or geographical information, using the given tolerancy expressed in pixels. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -2wgs84</b> &lt;boolean&gt; . Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -out</b> &lt;string&gt; File containing the list of tie points. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -outvector</b> &lt;string&gt; File containing segments representing matches . Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -algorithm</b> Choice of the detection algorithm to use surf,sift. Mandatory: True. Default Value: &quot;surf&quot;<ul><li><b>[group] -surf</b></li><ul></ul><li><b>[group] -sift</b></li><ul></ul></ul><b>[choice] -mode</b>  full,geobins. Mandatory: True. Default Value: &quot;full&quot;<ul><li><b>[group] -full</b></li><ul></ul><li><b>[group] -geobins</b></li><ul><li><b>[param] -mode.geobins.binsize</b> &lt;int32&gt; Radius of the spatial bin in pixels. Mandatory: True. Default Value: &quot;256&quot;</li><li><b>[param] -mode.geobins.binsizey</b> &lt;int32&gt; Radius of the spatial bin in pixels (y direction). If not set, the mode.geobins.binsize value is used.. Mandatory: False. Default Value: &quot;0&quot;</li><li><b>[param] -mode.geobins.binstep</b> &lt;int32&gt; Steps between bins in pixels. Mandatory: True. Default Value: &quot;256&quot;</li><li><b>[param] -mode.geobins.binstepy</b> &lt;int32&gt; Steps between bins in pixels (y direction). If not set, the mode.geobins.binstep value is used.. Mandatory: False. Default Value: &quot;0&quot;</li><li><b>[param] -mode.geobins.margin</b> &lt;int32&gt; Margin from image border to start/end bins (in pixels). Mandatory: True. Default Value: &quot;10&quot;</li></ul></ul></ul><h2>Limitations</h2>Full mode does not handle large images.<h2>Authors</h2>OTB-Team<h2>See Also</h2>RefineSensorModel<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in1: sensor_stereo_left.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in2: sensor_stereo_right.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode: full</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: homologous.txt</p></li></ul></body></html>
+</head><body><h1>HomologousPointsExtraction</h1><h2>Brief Description</h2>Compute homologous points between images using keypoints<h2>Tags</h2>Feature Extraction<h2>Long Description</h2>This application allows computing homologous points between images using keypoints.  SIFT or SURF keypoints can be used and the band on which keypoints are computed can be set independently for both images. The application offers two modes : the first is the full mode where keypoints are extracted from the full extent of both images (please note that in this mode large image file are not supported). The second mode, called geobins, allows one to set-up spatial binning to get fewer points spread across the entire image. In this mode, the corresponding spatial bin in the second image is estimated using geographical transform or sensor modelling, and is padded according to the user defined precision. Last, in both modes the application can filter matches whose colocalisation in first image exceed this precision. The elevation parameters are to deal more precisely with sensor modelling in case of sensor geometry data. The outvector option allows creating a vector file with segments corresponding to the localisation error between the matches. It can be useful to assess the precision of a registration for instance. The vector file is always reprojected to EPSG:4326 to allow display in a GIS. This is done via reprojection or by applying the image sensor models.<h2>Parameters</h2><ul><li><b>[param] -in1</b> &lt;string&gt;  First input image. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -band1</b> &lt;int32&gt; Index of the band from input image 1 to use for keypoints extraction. Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -in2</b> &lt;string&gt;  Second input image. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -band2</b> &lt;int32&gt; Index of the band from input image 1 to use for keypoints extraction. Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -threshold</b> &lt;float&gt; The distance threshold for matching.. Mandatory: True. Default Value: &quot;0.6&quot;</li><li><b>[param] -backmatching</b> &lt;boolean&gt; If set to true, matches should be consistent in both ways.. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -precision</b> &lt;float&gt; Estimated precision of the colocalisation function in pixels. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -mfilter</b> &lt;boolean&gt; If enabled, this option allows one to filter matches according to colocalisation from sensor or geographical information, using the given tolerancy expressed in pixels. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -2wgs84</b> &lt;boolean&gt; . Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -out</b> &lt;string&gt; File containing the list of tie points. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -outvector</b> &lt;string&gt; File containing segments representing matches . Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -algorithm</b> Choice of the detection algorithm to use surf,sift. Mandatory: True. Default Value: &quot;surf&quot;<ul><li><b>[group] -surf</b></li><ul></ul><li><b>[group] -sift</b></li><ul></ul></ul><b>[choice] -mode</b>  full,geobins. Mandatory: True. Default Value: &quot;full&quot;<ul><li><b>[group] -full</b></li><ul></ul><li><b>[group] -geobins</b></li><ul><li><b>[param] -mode.geobins.binsize</b> &lt;int32&gt; Radius of the spatial bin in pixels. Mandatory: True. Default Value: &quot;256&quot;</li><li><b>[param] -mode.geobins.binsizey</b> &lt;int32&gt; Radius of the spatial bin in pixels (y direction). If not set, the mode.geobins.binsize value is used.. Mandatory: False. Default Value: &quot;0&quot;</li><li><b>[param] -mode.geobins.binstep</b> &lt;int32&gt; Steps between bins in pixels. Mandatory: True. Default Value: &quot;256&quot;</li><li><b>[param] -mode.geobins.binstepy</b> &lt;int32&gt; Steps between bins in pixels (y direction). If not set, the mode.geobins.binstep value is used.. Mandatory: False. Default Value: &quot;0&quot;</li><li><b>[param] -mode.geobins.margin</b> &lt;int32&gt; Margin from image border to start/end bins (in pixels). Mandatory: True. Default Value: &quot;10&quot;</li></ul></ul></ul><h2>Limitations</h2>Full mode does not handle large images.<h2>Authors</h2>OTB-Team<h2>See Also</h2>RefineSensorModel<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in1: sensor_stereo_left.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in2: sensor_stereo_right.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode: full</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: homologous.txt</p></li></ul></body></html>
@@ -56,5 +56,5 @@
 # Each value must be separated with colons (:), with eventual spaces. Blank lines not allowed.
 1540.494123 : 1826.087443 : 1982.671954 : 1094.747446
 
-Finally, the 'Logs' tab provides usefull messages that can help the user in knowing the process different status.<h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; Input image filename (values in DN). Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; Output calibrated image filename. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; Available memory for processing (in MB). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -milli</b> &lt;boolean&gt; Flag to use milli-reflectance instead of reflectance.
-This allows saving the image with integer pixel type (in the range [0, 1000]  instead of floating point in the range [0, 1]. In order to do that, use this option and set the output pixel type (-out filename double for example). Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -clamp</b> &lt;boolean&gt; Clamping in the range [0, 100]. It can be useful to preserve area with specular reflectance.. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -acqui</b> &lt;string&gt; This group allows setting the parameters related to the acquisition conditions.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -atmo</b> &lt;string&gt; This group allows setting the atmospheric parameters.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -level</b>  toa,toatoim,toc. Mandatory: True. Default Value: &quot;toa&quot;<ul><li><b>[group] -toa</b></li><ul></ul><li><b>[group] -toatoim</b></li><ul></ul><li><b>[group] -toc</b></li><ul></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>The OTB CookBook<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: QB_1_ortho.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">level: toa</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: OpticalCalibration.tif</p></li></ul></body></html>
+Finally, the 'Logs' tab provides useful messages that can help the user in knowing the process different status.<h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; Input image filename (values in DN). Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; Output calibrated image filename. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; Available memory for processing (in MB). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -milli</b> &lt;boolean&gt; Flag to use milli-reflectance instead of reflectance.
+This allows saving the image with integer pixel type (in the range [0, 1000]  instead of floating point in the range [0, 1]. In order to do that, use this option and set the output pixel type (-out filename double for example). Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -clamp</b> &lt;boolean&gt; Clamping in the range [0, 100]. It can be useful to preserve area with specular reflectance.. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -acqui</b> &lt;string&gt; This group allows setting the parameters related to the acquisition conditions.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -atmo</b> &lt;string&gt; This group allows setting the atmospheric parameters.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -level</b>  toa,toatoim,toc. Mandatory: True. Default Value: &quot;toa&quot;<ul><li><b>[group] -toa</b></li><ul></ul><li><b>[group] -toatoim</b></li><ul></ul><li><b>[group] -toc</b></li><ul></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>The OTB CookBook<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: QB_1_ortho.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">level: toa</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: OpticalCalibration.tif</p></li></ul></body></html>
@@ -4,4 +4,4 @@
 </style>
 </head><body><h1>OrthoRectification</h1><h2>Brief Description</h2>This application allows ortho-rectification of optical images from supported sensors.
 <h2>Tags</h2>Geometry<h2>Long Description</h2>An inverse sensor model is built from the input image metadata to convert geographical to raw geometry coordinates. This inverse sensor model is then combined with the chosen map projection to build a global coordinate mapping grid. Last, this grid is used to resample using the chosen interpolation algorithm. A Digital Elevation Model can be specified to account for terrain deformations. 
-In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
+In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
@@ -4,4 +4,4 @@
 </style>
 </head><body><h1>OrthoRectification</h1><h2>Brief Description</h2>This application allows ortho-rectification of optical images from supported sensors.
 <h2>Tags</h2>Geometry<h2>Long Description</h2>An inverse sensor model is built from the input image metadata to convert geographical to raw geometry coordinates. This inverse sensor model is then combined with the chosen map projection to build a global coordinate mapping grid. Last, this grid is used to resample using the chosen interpolation algorithm. A Digital Elevation Model can be specified to account for terrain deformations. 
-In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
+In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
@@ -4,4 +4,4 @@
 </style>
 </head><body><h1>OrthoRectification</h1><h2>Brief Description</h2>This application allows ortho-rectification of optical images from supported sensors.
 <h2>Tags</h2>Geometry<h2>Long Description</h2>An inverse sensor model is built from the input image metadata to convert geographical to raw geometry coordinates. This inverse sensor model is then combined with the chosen map projection to build a global coordinate mapping grid. Last, this grid is used to resample using the chosen interpolation algorithm. A Digital Elevation Model can be specified to account for terrain deformations. 
-In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
+In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
@@ -4,4 +4,4 @@
 </style>
 </head><body><h1>OrthoRectification</h1><h2>Brief Description</h2>This application allows ortho-rectification of optical images from supported sensors.
 <h2>Tags</h2>Geometry<h2>Long Description</h2>An inverse sensor model is built from the input image metadata to convert geographical to raw geometry coordinates. This inverse sensor model is then combined with the chosen map projection to build a global coordinate mapping grid. Last, this grid is used to resample using the chosen interpolation algorithm. A Digital Elevation Model can be specified to account for terrain deformations. 
-In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
+In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
@@ -4,4 +4,4 @@
 </style>
 </head><body><h1>OrthoRectification</h1><h2>Brief Description</h2>This application allows ortho-rectification of optical images from supported sensors.
 <h2>Tags</h2>Geometry<h2>Long Description</h2>An inverse sensor model is built from the input image metadata to convert geographical to raw geometry coordinates. This inverse sensor model is then combined with the chosen map projection to build a global coordinate mapping grid. Last, this grid is used to resample using the chosen interpolation algorithm. A Digital Elevation Model can be specified to account for terrain deformations. 
-In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
+In case of SPOT5 images, the sensor model can be approximated by an RPC model in order to speed-up computation.<h2>Parameters</h2><ul><li><b>[param] -io</b> &lt;string&gt; This group of parameters allows setting the input and output images.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -outputs</b> &lt;string&gt; This group of parameters allows one to define the grid on which the input image will be resampled.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -elev</b> &lt;string&gt; This group of parameters allows managing elevation values. Supported formats are SRTM, DTED or any geotiff. DownloadSRTMTiles application could be a useful tool to list/download tiles related to a product.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -opt</b> &lt;string&gt; This group of parameters allows optimization of processing time.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -map</b> Parameters of the output map projection to be used. utm,lambert2,lambert93,wgs,epsg. Mandatory: True. Default Value: &quot;utm&quot;<ul><li><b>[group] -utm</b></li><ul><li><b>[param] -map.utm.zone</b> &lt;int32&gt; The zone number ranges from 1 to 60 and allows defining the transverse mercator projection (along with the hemisphere). Mandatory: True. Default Value: &quot;31&quot;</li><li><b>[param] -map.utm.northhem</b> &lt;boolean&gt; The transverse mercator projections are defined by their zone number as well as the hemisphere. Activate this parameter if your image is in the northern hemisphere.. Mandatory: False. Default Value: &quot;True&quot;</li></ul><li><b>[group] -lambert2</b></li><ul></ul><li><b>[group] -lambert93</b></li><ul></ul><li><b>[group] -wgs</b></li><ul></ul><li><b>[group] -epsg</b></li><ul><li><b>[param] -map.epsg.code</b> &lt;int32&gt; See www.spatialreference.org to find which EPSG code is associated to your projection. Mandatory: True. Default Value: &quot;4326&quot;</li></ul></ul><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. bco,nn,linear. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows one to control the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul></ul></ul><h2>Limitations</h2>Supported sensors are Pleiades, SPOT5 (TIF format), Ikonos, Quickbird, Worldview2, GeoEye.<h2>Authors</h2>OTB-Team<h2>See Also</h2>Ortho-rectification chapter from the OTB Software Guide<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.in: QB_TOULOUSE_MUL_Extract_500_500.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">io.out: QB_Toulouse_ortho.tif</p></li></ul></body></html>
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-</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
+</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
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-</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
+</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
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-</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
+</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
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-</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artefacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
+</head><body><h1>RigidTransformResample</h1><h2>Brief Description</h2>Resample an image with a rigid transform<h2>Tags</h2>Conversion,Geometry<h2>Long Description</h2>This application performs a parametric transform on the input image. Scaling, translation and rotation with scaling factor are handled. Parameters of the transform is expressed in physical units, thus particular attention must be paid on pixel size (value, and sign). Moreover transform is expressed from input space to output space (on the contrary ITK Transforms are expressed form output space to input space). <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to translate.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -out</b> &lt;string&gt; The transformed output image.. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -transform</b> &lt;string&gt; This group of parameters allows setting the transformation to apply.. Mandatory: True. Default Value: &quot;0&quot;</li><li><b>[param] -ram</b> &lt;int32&gt; This allows setting the maximum amount of RAM available for processing. As the writing task is time consuming, it is better to write large pieces of data, which can be achieved by increasing this parameter (pay attention to your system capabilities). Mandatory: False. Default Value: &quot;128&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -interpolator</b> This group of parameters allows one to define how the input image will be interpolated during resampling. nn,linear,bco. Mandatory: True. Default Value: &quot;bco&quot;<ul><li><b>[group] -nn</b></li><ul></ul><li><b>[group] -linear</b></li><ul></ul><li><b>[group] -bco</b></li><ul><li><b>[param] -interpolator.bco.radius</b> &lt;int32&gt; This parameter allows controlling the size of the bicubic interpolation filter. If the target pixel size is higher than the input pixel size, increasing this parameter will reduce aliasing artifacts.. Mandatory: True. Default Value: &quot;2&quot;</li></ul></ul></ul><h2>Limitations</h2>None<h2>Authors</h2>OTB-Team<h2>See Also</h2>Translation<h2>Example of use</h2><ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: qb_toulouse_sub.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">out: rigitTransformImage.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type: rotation</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.angle: 20</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scalex: 2.</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">transform.type.rotation.scaley: 2.</p></li></ul></body></html>
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 </head><body><h1>Segmentation</h1><h2>Brief Description</h2>Performs segmentation of an image, and output either a raster or a vector file. In vector mode, large input datasets are supported.<h2>Tags</h2>Segmentation<h2>Long Description</h2>This application allows one to perform various segmentation algorithms on a multispectral image.Available segmentation algorithms are two different versions of Mean-Shift segmentation algorithm (one being multi-threaded), simple pixel based connected components according to a user-defined criterion, and watershed from the gradient of the intensity (norm of spectral bands vector). The application has two different modes that affects the nature of its output.
 
-In raster mode, the output of the application is a classical image of unique labels identifying the segmented regions. The labeled output can be passed to the ColorMapping application to render regions with contrasted colours. Please note that this mode loads the whole input image into memory, and as such can not handle large images. 
+In raster mode, the output of the application is a classical image of unique labels identifying the segmented regions. The labeled output can be passed to the ColorMapping application to render regions with contrasted colors. Please note that this mode loads the whole input image into memory, and as such can not handle large images. 
 
 To segment large data, one can use the vector mode. In this case, the output of the application is a vector file or database. The input image is split into tiles (whose size can be set using the tilesize parameter), and each tile is loaded, segmented with the chosen algorithm, vectorized, and written into the output file or database. This piece-wise behavior ensure that memory will never get overloaded, and that images of any size can be processed. There are few more options in the vector mode. The simplify option allows simplifying the geometry (i.e. remove nodes in polygons) according to a user-defined tolerance. The stitch option tries to stitch together the polygons corresponding to segmented region that may have been split by the tiling scheme. <h2>Parameters</h2><ul><li><b>[param] -in</b> &lt;string&gt; The input image to segment. Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -inxml</b> &lt;string&gt; Load otb application from xml file. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -outxml</b> &lt;string&gt; Save otb application to xml file. Mandatory: False. Default Value: &quot;&quot;</li><b>[choice] -filter</b> Choice of segmentation algorithm (mean-shift by default) meanshift,cc,watershed,mprofiles. Mandatory: True. Default Value: &quot;meanshift&quot;<ul><li><b>[group] -meanshift</b></li><ul><li><b>[param] -filter.meanshift.spatialr</b> &lt;int32&gt; Spatial radius of the neighborhood.. Mandatory: True. Default Value: &quot;5&quot;</li><li><b>[param] -filter.meanshift.ranger</b> &lt;float&gt; Range radius defining the radius (expressed in radiometry unit) in the multispectral space.. Mandatory: True. Default Value: &quot;15&quot;</li><li><b>[param] -filter.meanshift.thres</b> &lt;float&gt; Algorithm iterative scheme will stop if mean-shift vector is below this threshold or if iteration number reached maximum number of iterations.. Mandatory: True. Default Value: &quot;0.1&quot;</li><li><b>[param] -filter.meanshift.maxiter</b> &lt;int32&gt; Algorithm iterative scheme will stop if convergence hasn't been reached after the maximum number of iterations.. Mandatory: True. Default Value: &quot;100&quot;</li><li><b>[param] -filter.meanshift.minsize</b> &lt;int32&gt; Minimum size of a region (in pixel unit) in segmentation. Smaller clusters will be merged to the neighboring cluster with the closest radiometry. If set to 0 no pruning is done.. Mandatory: True. Default Value: &quot;100&quot;</li></ul><li><b>[group] -cc</b></li><ul><li><b>[param] -filter.cc.expr</b> &lt;string&gt; User defined connection condition, written as a mathematical expression. Available variables are p(i)b(i), intensity_p(i) and distance (example of expression : distance < 10 ). Mandatory: True. Default Value: &quot;&quot;</li></ul><li><b>[group] -watershed</b></li><ul><li><b>[param] -filter.watershed.threshold</b> &lt;float&gt; Depth threshold Units in percentage of the maximum depth in the image.. Mandatory: True. Default Value: &quot;0.01&quot;</li><li><b>[param] -filter.watershed.level</b> &lt;float&gt; flood level for generating the merge tree from the initial segmentation (between 0 and 1). Mandatory: True. Default Value: &quot;0.1&quot;</li></ul><li><b>[group] -mprofiles</b></li><ul><li><b>[param] -filter.mprofiles.size</b> &lt;int32&gt; Size of the profiles. Mandatory: True. Default Value: &quot;5&quot;</li><li><b>[param] -filter.mprofiles.start</b> &lt;int32&gt; Initial radius of the structuring element (in pixels). Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -filter.mprofiles.step</b> &lt;int32&gt; Radius step along the profile (in pixels). Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -filter.mprofiles.sigma</b> &lt;float&gt; Profiles values under the threshold will be ignored.. Mandatory: True. Default Value: &quot;1&quot;</li></ul></ul><b>[choice] -mode</b> Choice of processing mode, either raster or large-scale. vector,raster. Mandatory: True. Default Value: &quot;vector&quot;<ul><li><b>[group] -vector</b></li><ul><li><b>[param] -mode.vector.out</b> &lt;string&gt; The output vector file or database (name can be anything understood by OGR). Mandatory: True. Default Value: &quot;&quot;</li><li><b>[param] -mode.vector.outmode</b> &lt;string&gt; This allows one to set the writing behaviour for the output vector file. Please note that the actual behaviour depends on the file format.. Mandatory: True. Default Value: &quot;ulco&quot;</li><li><b>[param] -mode.vector.inmask</b> &lt;string&gt; Only pixels whose mask value is strictly positive will be segmented.. Mandatory: False. Default Value: &quot;&quot;</li><li><b>[param] -mode.vector.neighbor</b> &lt;boolean&gt; Activate 8-Neighborhood connectivity (default is 4).. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -mode.vector.stitch</b> &lt;boolean&gt; Scan polygons on each side of tiles and stitch polygons which connect by more than one pixel.. Mandatory: False. Default Value: &quot;True&quot;</li><li><b>[param] -mode.vector.minsize</b> &lt;int32&gt; Objects whose size is below the minimum object size (area in pixels) will be ignored during vectorization.. Mandatory: False. Default Value: &quot;1&quot;</li><li><b>[param] -mode.vector.simplify</b> &lt;float&gt; Simplify polygons according to a given tolerance (in pixel). This option allows reducing the size of the output file or database.. Mandatory: False. Default Value: &quot;0.1&quot;</li><li><b>[param] -mode.vector.layername</b> &lt;string&gt; Name of the layer in the vector file or database (default is Layer).. Mandatory: True. Default Value: &quot;layer&quot;</li><li><b>[param] -mode.vector.fieldname</b> &lt;string&gt; Name of the field holding the geometry index in the output vector file or database.. Mandatory: True. Default Value: &quot;DN&quot;</li><li><b>[param] -mode.vector.tilesize</b> &lt;int32&gt; User defined tiles size for tile-based segmentation. Optimal tile size is selected according to available RAM if null.. Mandatory: True. Default Value: &quot;1024&quot;</li><li><b>[param] -mode.vector.startlabel</b> &lt;int32&gt; Starting value of the geometry index field. Mandatory: True. Default Value: &quot;1&quot;</li><li><b>[param] -mode.vector.ogroptions</b> &lt;string&gt; A list of layer creation options in the form KEY=VALUE that will be passed directly to OGR without any validity checking. Options may depend on the file format, and can be found in OGR documentation.. Mandatory: False. Default Value: &quot;&quot;</li></ul><li><b>[group] -raster</b></li><ul><li><b>[param] -mode.raster.out</b> &lt;string&gt; The output labeled image.. Mandatory: True. Default Value: &quot;&quot;</li></ul></ul></ul><h2>Limitations</h2>In raster mode, the application can not handle large input images. Stitching step of vector mode might become slow with very large input images. 
 MeanShift filter results depends on the number of threads used. 
-Watershed and multiscale geodesic morphology segmentation will be performed on the amplitude  of the input image.<h2>Authors</h2>OTB-Team<h2>See Also</h2>MeanShiftSegmentation<h2>Example of use</h2><ul><li>Example of use with vector mode and watershed segmentation<ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: QB_Toulouse_Ortho_PAN.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode: vector</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode.vector.out: SegmentationVector.sqlite</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">filter: watershed</p></li></ul></li><li>Example of use with raster mode and mean-shift segmentation<ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: QB_Toulouse_Ortho_PAN.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode: raster</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode.raster.out: SegmentationRaster.tif uint16</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">filter: meanshift</p></li></ul></li></ul></body></html>
+Watershed and multiscale geodesic morphology segmentation will be performed on the amplitude  of the input image.<h2>Authors</h2>OTB-Team<h2>See Also</h2>MeanShiftSegmentation<h2>Example of use</h2><ul><li>Example of use with vector mode and watershed segmentation<ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: QB_Toulouse_Ortho_PAN.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode: vector</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode.vector.out: SegmentationVector.sqlite</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">filter: watershed</p></li></ul></li><li>Example of use with raster mode and mean-shift segmentation<ul><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">in: QB_Toulouse_Ortho_PAN.tif</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode: raster</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">mode.raster.out: SegmentationRaster.tif uint16</p></li><li><p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">filter: meanshift</p></li></ul></li></ul></body></html>