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Piero Toffanin 2025-11-25 14:28:13 -05:00
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// Auto-generated with extract_odm_strings.py, do not edit!
_("Do not attempt to merge partial reconstructions. This can happen when images do not have sufficient overlap or are isolated. Default: %(default)s");
_("Set this parameter if you want to generate a Google Earth (KMZ) rendering of the orthophoto. Default: %(default)s");
_("URL to a ClusterODM instance for distributing a split-merge workflow on multiple nodes in parallel. Default: %(default)s");
_("Average number of images per submodel. When splitting a large dataset into smaller submodels, images are grouped into clusters. This value regulates the number of images that each cluster should have on average. Default: %(default)s");
_("When processing multispectral datasets, you can specify the name of the primary band that will be used for reconstruction. It's recommended to choose a band which has sharp details and is in focus. Default: %(default)s");
_("Build orthophoto overviews for faster display in programs such as QGIS. Default: %(default)s");
_("During the orthophoto merging, skip expensive blending operation: %(default)s");
_("Automatically compute image masks using AI to remove the background. Experimental. Default: %(default)s");
_("Use this tag to build a DSM (Digital Surface Model, ground + objects) using a progressive morphological filter. Check the --dem* parameters for finer tuning. Default: %(default)s");
_("Number of steps used to fill areas with gaps. Set to 0 to disable gap filling. Starting with a radius equal to the output resolution, N different DEMs are generated with progressively bigger radius using the inverse distance weighted (IDW) algorithm and merged together. Remaining gaps are then merged using nearest neighbor interpolation. Default: %(default)s");
_("Simple Morphological Filter slope parameter (rise over run). Default: %(default)s");
_("Use the camera parameters computed from another dataset instead of calculating them. Can be specified either as path to a cameras.json file or as a JSON string representing the contents of a cameras.json file. Default: %(default)s");
_("Set the compression to use for orthophotos. Can be one of: %(choices)s. Default: %(default)s");
_("The maximum vertex count of the output mesh. Default: %(default)s");
_("Export the georeferenced point cloud in CSV format. Default: %(default)s");
_("Use this tag if you have a GCP File but want to use the EXIF information for georeferencing instead. Default: %(default)s");
_("Rerun processing from this stage. Can be one of: %(choices)s. Default: %(default)s");
_("Choose the structure from motion algorithm. For aerial datasets, if camera GPS positions and angles are available, triangulation can generate better results. For planar scenes captured at fixed altitude with nadir-only images, planar can be much faster. Can be one of: %(choices)s. Default: %(default)s");
_("GeoJSON polygon limiting the area of the reconstruction. Can be specified either as path to a GeoJSON file or as a JSON string representing the contents of a GeoJSON file. Default: %(default)s");
_("Export the georeferenced point cloud in Entwine Point Tile (EPT) format. Default: %(default)s");
_("Skip normalization of colors across all images. Useful when processing radiometric data. Default: %(default)s");
_("Export the georeferenced point cloud in LAS format. Default: %(default)s");
_("Skip generation of the orthophoto. This can save time if you only need 3D results or DEMs. Default: %(default)s");
_("Set a GPS offset in meters for the vertical axis (Z) by adding it to the altitude value of the GPS EXIF data. This does not change the value of any GCPs. This can be useful for example when adjusting from ellipsoidal to orthometric height. Default: %(default)s");
_("Set a value in meters for the GPS Dilution of Precision (DOP) information for all images. If your images are tagged with high precision GPS information (RTK), this value will be automatically set accordingly. You can use this option to manually set it in case the reconstruction fails. Lowering this option can sometimes help control bowling-effects over large areas. Default: %(default)s");
_("Delete heavy intermediate files to optimize disk space usage. This affects the ability to restart the pipeline from an intermediate stage, but allows datasets to be processed on machines that don't have sufficient disk space available. Default: %(default)s");
_("Orthophoto resolution in cm / pixel. Note that this value is capped by a ground sampling distance (GSD) estimate.Default: %(default)s");
_("Path to a GeoTIFF DEM or a LAS/LAZ point cloud that the reconstruction outputs should be automatically aligned to. Experimental. Default: %(default)s");
_("Name of dataset (i.e subfolder name within project folder). Default: %(default)s");
_("Run local bundle adjustment for every image added to the reconstruction and a global adjustment every 100 images. Speeds up reconstruction for very large datasets. Default: %(default)s");
_("Keep faces in the mesh that are not seen in any camera. Default: %(default)s");
_("Skips dense reconstruction and 3D model generation. It generates an orthophoto directly from the sparse reconstruction. If you just need an orthophoto and do not need a full 3D model, turn on this option. Default: %(default)s");
_("Automatically crop image outputs by creating a smooth buffer around the dataset boundaries, shrunk by N meters. Use 0 to disable cropping. Default: %(default)s");
_("The maximum output resolution of extracted video frames in pixels. Default: %(default)s");
_("Skip alignment of submodels in split-merge. Useful if GPS is good enough on very large datasets. Default: %(default)s");
_("Use a full 3D mesh to compute the orthophoto instead of a 2.5D mesh. This option is a bit faster and provides similar results in planar areas. Default: %(default)s");
_("Create Cloud-Optimized GeoTIFFs instead of normal GeoTIFFs. Default: %(default)s");
_("Computes an euclidean raster map for each DEM. The map reports the distance from each cell to the nearest NODATA value (before any hole filling takes place). This can be useful to isolate the areas that have been filled. Default: %(default)s");
_("Geometric estimates improve the accuracy of the point cloud by computing geometrically consistent depthmaps but may not be usable in larger datasets. This flag disables geometric estimates. Default: %(default)s");
_("Override the rolling shutter readout time for your camera sensor (in milliseconds), instead of using the rolling shutter readout database. Note that not all cameras are present in the database. Set to 0 to use the database value. Default: %(default)s");
_("Run local bundle adjustment for every image added to the reconstruction and a global adjustment every 100 images. Speeds up reconstruction for very large datasets. Default: %(default)s");
_("Skip generation of the orthophoto. This can save time if you only need 3D results or DEMs. Default: %(default)s");
_("Set the compression to use for orthophotos. Can be one of: %(choices)s. Default: %(default)s");
_("Turn on rolling shutter correction. If the camera has a rolling shutter and the images were taken in motion, you can turn on this option to improve the accuracy of the results. See also --rolling-shutter-readout. Default: %(default)s");
_("Maximum number of frames to extract from video files for processing. Set to 0 for no limit. Default: %(default)s");
_("Skip generation of PDF report. This can save time if you don't need a report. Default: %(default)s");
_("Computes an euclidean raster map for each DEM. The map reports the distance from each cell to the nearest NODATA value (before any hole filling takes place). This can be useful to isolate the areas that have been filled. Default: %(default)s");
_("Use this tag to build a DTM (Digital Terrain Model, ground only) using a simple morphological filter. Check the --dem* and --smrf* parameters for finer tuning. Default: %(default)s");
_("Automatically crop image outputs by creating a smooth buffer around the dataset boundaries, shrunk by N meters. Use 0 to disable cropping. Default: %(default)s");
_("Turn off camera parameter optimization during bundle adjustment. This can be sometimes useful for improving results that exhibit doming/bowling or when images are taken with a rolling shutter camera. Default: %(default)s");
_("Name of dataset (i.e subfolder name within project folder). Default: %(default)s");
_("Classify the point cloud outputs. You can control the behavior of this option by tweaking the --dem-* parameters. Default: %(default)s");
_("Do not use GPU acceleration, even if it's available. Default: %(default)s");
_("Choose the algorithm for extracting keypoints and computing descriptors. Can be one of: %(choices)s. Default: %(default)s");
_("Simple Morphological Filter elevation threshold parameter (meters). Default: %(default)s");
_("Copy output results to this folder after processing.");
_("Export the georeferenced point cloud in CSV format. Default: %(default)s");
_("Specify the distance between camera shot locations and the outer edge of the boundary when computing the boundary with --auto-boundary. Set to 0 to automatically choose a value. Default: %(default)s");
_("Permanently delete all previous results and rerun the processing pipeline.");
_("Set a camera projection type. Manually setting a value can help improve geometric undistortion. By default the application tries to determine a lens type from the images metadata. Can be one of: %(choices)s. Default: %(default)s");
_("Automatically compute image masks using AI to remove the sky. Experimental. Default: %(default)s");
_("Number of steps used to fill areas with gaps. Set to 0 to disable gap filling. Starting with a radius equal to the output resolution, N different DEMs are generated with progressively bigger radius using the inverse distance weighted (IDW) algorithm and merged together. Remaining gaps are then merged using nearest neighbor interpolation. Default: %(default)s");
_("Rerun processing from this stage. Can be one of: %(choices)s. Default: %(default)s");
_("Orthophoto resolution in cm / pixel. Note that this value is capped by a ground sampling distance (GSD) estimate.Default: %(default)s");
_("Radius of the overlap between submodels in meters. After grouping images into clusters, images that are closer than this radius to a cluster are added to the cluster. This is done to ensure that neighboring submodels overlap. All imagesneed GPS information. Default: %(default)s");
_("DSM/DTM resolution in cm / pixel. Note that this value is capped by a ground sampling distance (GSD) estimate. Default: %(default)s");
_("Use images' GPS exif data for reconstruction, even if there are GCPs present.This flag is useful if you have high precision GPS measurements. If there are no GCPs, this flag does nothing. Default: %(default)s");
_("Generate OBJs that have a single material and a single texture file instead of multiple ones. Default: %(default)s");
_("Simple Morphological Filter elevation scalar parameter. Default: %(default)s");
_("Set a value in meters for the GPS Dilution of Precision (DOP) information for all images. If your images are tagged with high precision GPS information (RTK), this value will be automatically set accordingly. You can use this option to manually set it in case the reconstruction fails. Lowering this option can sometimes help control bowling-effects over large areas. Default: %(default)s");
_("GeoJSON polygon limiting the area of the reconstruction. Can be specified either as path to a GeoJSON file or as a JSON string representing the contents of a GeoJSON file. Default: %(default)s");
_("Create Cloud-Optimized GeoTIFFs instead of normal GeoTIFFs. Default: %(default)s");
_("Set this parameter if you want to generate a Google Earth (KMZ) rendering of the orthophoto. Default: %(default)s");
_("Skip normalization of colors across all images. Useful when processing radiometric data. Default: %(default)s");
_("Keep faces in the mesh that are not seen in any camera. Default: %(default)s");
_("Choose the structure from motion algorithm. For aerial datasets, if camera GPS positions and angles are available, triangulation can generate better results. For planar scenes captured at fixed altitude with nadir-only images, planar can be much faster. Can be one of: %(choices)s. Default: %(default)s");
_("Set feature extraction quality. Higher quality generates better features, but requires more memory and takes longer. Can be one of: %(choices)s. Default: %(default)s");
_("Generates a polygon around the cropping area that cuts the orthophoto around the edges of features. This polygon can be useful for stitching seamless mosaics with multiple overlapping orthophotos. Default: %(default)s");
_("Set the radiometric calibration to perform on images. When processing multispectral and thermal images you should set this option to obtain reflectance/temperature values (otherwise you will get digital number values). [camera] applies black level, vignetting, row gradient gain/exposure compensation (if appropriate EXIF tags are found) and computes absolute temperature values. [camera+sun] is experimental, applies all the corrections of [camera], plus compensates for spectral radiance registered via a downwelling light sensor (DLS) taking in consideration the angle of the sun. Can be one of: %(choices)s. Default: %(default)s");
_("Do not attempt to merge partial reconstructions. This can happen when images do not have sufficient overlap or are isolated. Default: %(default)s");
_("Path to the file containing the ground control points used for georeferencing. The file needs to use the following format: EPSG:<code> or <+proj definition>geo_x geo_y geo_z im_x im_y image_name [gcp_name] [extra1] [extra2]Default: %(default)s");
_("Set point cloud quality. Higher quality generates better, denser point clouds, but requires more memory and takes longer. Each step up in quality increases processing time roughly by a factor of 4x.Can be one of: %(choices)s. Default: %(default)s");
_("Generate static tiles for orthophotos and DEMs that are suitable for viewers like Leaflet or OpenLayers. Default: %(default)s");
_("Geometric estimates improve the accuracy of the point cloud by computing geometrically consistent depthmaps but may not be usable in larger datasets. This flag disables geometric estimates. Default: %(default)s");
_("Simple Morphological Filter elevation scalar parameter. Default: %(default)s");
_("Skip generation of PDF report. This can save time if you don't need a report. Default: %(default)s");
_("Classify the point cloud outputs. You can control the behavior of this option by tweaking the --dem-* parameters. Default: %(default)s");
_("show this help message and exit");
_("Choose what to merge in the merge step in a split dataset. By default all available outputs are merged. Options: %(choices)s. Default: %(default)s");
_("Automatically compute image masks using AI to remove the sky. Experimental. Default: %(default)s");
_("Displays version number and exits. ");
_("Perform image matching with the nearest images based on GPS exif data. Set to 0 to match by triangulation. Default: %(default)s");
_("Rerun this stage only and stop. Can be one of: %(choices)s. Default: %(default)s");
_("Simple Morphological Filter window radius parameter (meters). Default: %(default)s");
_("End processing at this stage. Can be one of: %(choices)s. Default: %(default)s");
_("Perform image matching with the nearest N images based on image filename order. Can speed up processing of sequential images, such as those extracted from video. It is applied only on non-georeferenced datasets. Set to 0 to disable. Default: %(default)s");
_("Choose the algorithm for extracting keypoints and computing descriptors. Can be one of: %(choices)s. Default: %(default)s");
_("Set this parameter if you want to generate a PNG rendering of the orthophoto. Default: %(default)s");
_("Maximum number of frames to extract from video files for processing. Set to 0 for no limit. Default: %(default)s");
_("Specify the distance between camera shot locations and the outer edge of the boundary when computing the boundary with --auto-boundary. Set to 0 to automatically choose a value. Default: %(default)s");
_("Path to the image groups file that controls how images should be split into groups. The file needs to use the following format: image_name group_nameDefault: %(default)s");
_("Path to the project folder. Your project folder should contain subfolders for each dataset. Each dataset should have an \"images\" folder.");
_("Simple Morphological Filter elevation threshold parameter (meters). Default: %(default)s");
_("Do not use GPU acceleration, even if it's available. Default: %(default)s");
_("Override the rolling shutter readout time for your camera sensor (in milliseconds), instead of using the rolling shutter readout database. Note that not all cameras are present in the database. Set to 0 to use the database value. Default: %(default)s");
_("Radius of the overlap between submodels in meters. After grouping images into clusters, images that are closer than this radius to a cluster are added to the cluster. This is done to ensure that neighboring submodels overlap. All imagesneed GPS information. Default: %(default)s");
_("Skip alignment of submodels in split-merge. Useful if GPS is good enough on very large datasets. Default: %(default)s");
_("The maximum number of processes to use in various processes. Peak memory requirement is ~1GB per thread and 2 megapixel image resolution. Default: %(default)s");
_("Set this parameter if you want a striped GeoTIFF. Default: %(default)s");
_("Set feature extraction quality. Higher quality generates better features, but requires more memory and takes longer. Can be one of: %(choices)s. Default: %(default)s");
_("Decimate the points before generating the DEM. 1 is no decimation (full quality). 100 decimates ~99%% of the points. Useful for speeding up generation of DEM results in very large datasets. Default: %(default)s");
_("Use this tag to build a DTM (Digital Terrain Model, ground only) using a simple morphological filter. Check the --dem* and --smrf* parameters for finer tuning. Default: %(default)s");
_("Generate OGC 3D Tiles outputs. Default: %(default)s");
_("Generate OBJs that have a single material and a single texture file instead of multiple ones. Default: %(default)s");
_("Generate single file Binary glTF (GLB) textured models. Default: %(default)s");
_("Set a camera projection type. Manually setting a value can help improve geometric undistortion. By default the application tries to determine a lens type from the images metadata. Can be one of: %(choices)s. Default: %(default)s");
_("Save the georeferenced point cloud in Cloud Optimized Point Cloud (COPC) format. Default: %(default)s");
_("Ignore Ground Sampling Distance (GSD).A memory and processor hungry change relative to the default behavior if set to true. Ordinarily, GSD estimates are used to cap the maximum resolution of image outputs and resizes images when necessary, resulting in faster processing and lower memory usage. Since GSD is an estimate, sometimes ignoring it can result in slightly better image output quality. Never set --ignore-gsd to true unless you are positive you need it, and even then: do not use it. Default: %(default)s");
_("Matcher algorithm, Fast Library for Approximate Nearest Neighbors or Bag of Words. FLANN is slower, but more stable. BOW is faster, but can sometimes miss valid matches. BRUTEFORCE is very slow but robust.Can be one of: %(choices)s. Default: %(default)s");
_("Skip generation of a full 3D model. This can save time if you only need 2D results such as orthophotos and DEMs. Default: %(default)s");
_("Path to the file containing the ground control points used for georeferencing. The file needs to use the following format: EPSG:<code> or <+proj definition>geo_x geo_y geo_z im_x im_y image_name [gcp_name] [extra1] [extra2]Default: %(default)s");
_("Octree depth used in the mesh reconstruction, increase to get more vertices, recommended values are 8-12. Default: %(default)s");
_("DSM/DTM resolution in cm / pixel. Note that this value is capped by a ground sampling distance (GSD) estimate. Default: %(default)s");
_("Perform ground rectification on the point cloud. This means that wrongly classified ground points will be re-classified and gaps will be filled. Useful for generating DTMs. Default: %(default)s");
_("Filters the point cloud by removing points that deviate more than N standard deviations from the local mean. Set to 0 to disable filtering. Default: %(default)s");
_("Turn off camera parameter optimization during bundle adjustment. This can be sometimes useful for improving results that exhibit doming/bowling or when images are taken with a rolling shutter camera. Default: %(default)s");
_("Filters the point cloud by keeping only a single point around a radius N (in meters). This can be useful to limit the output resolution of the point cloud and remove duplicate points. Set to 0 to disable sampling. Default: %(default)s");
_("Path to the image geolocation file containing the camera center coordinates used for georeferencing. If you don't have values for yaw/pitch/roll you can set them to 0. The file needs to use the following format: EPSG:<code> or <+proj definition>image_name geo_x geo_y geo_z [yaw (degrees)] [pitch (degrees)] [roll (degrees)] [horz accuracy (meters)] [vert accuracy (meters)]Default: %(default)s");
_("The maximum output resolution of extracted video frames in pixels. Default: %(default)s");
_("Permanently delete all previous results and rerun the processing pipeline.");
_("Use the camera parameters computed from another dataset instead of calculating them. Can be specified either as path to a cameras.json file or as a JSON string representing the contents of a cameras.json file. Default: %(default)s");
_("When processing multispectral datasets, ODM will automatically align the images for each band. If the images have been postprocessed and are already aligned, use this option. Default: %(default)s");
_("Automatically set a boundary using camera shot locations to limit the area of the reconstruction. This can help remove far away background artifacts (sky, background landscapes, etc.). See also --boundary. Default: %(default)s");
_("Use images' GPS exif data for reconstruction, even if there are GCPs present.This flag is useful if you have high precision GPS measurements. If there are no GCPs, this flag does nothing. Default: %(default)s");
_("The maximum number of processes to use in various processes. Peak memory requirement is ~1GB per thread and 2 megapixel image resolution. Default: %(default)s");
_("During the orthophoto merging, skip expensive blending operation: %(default)s");
_("When processing multispectral datasets, you can specify the name of the primary band that will be used for reconstruction. It's recommended to choose a band which has sharp details and is in focus. Default: %(default)s");
_("Filters the point cloud by keeping only a single point around a radius N (in meters). This can be useful to limit the output resolution of the point cloud and remove duplicate points. Set to 0 to disable sampling. Default: %(default)s");
_("Simple Morphological Filter slope parameter (rise over run). Default: %(default)s");
_("Perform image matching with the nearest images based on GPS exif data. Set to 0 to match by triangulation. Default: %(default)s");
_("End processing at this stage. Can be one of: %(choices)s. Default: %(default)s");
_("Generate OGC 3D Tiles outputs. Default: %(default)s");
_("Path to the image groups file that controls how images should be split into groups. The file needs to use the following format: image_name group_nameDefault: %(default)s");
_("Minimum number of features to extract per image. More features can be useful for finding more matches between images, potentially allowing the reconstruction of areas with little overlap or insufficient features. More features also slow down processing. Default: %(default)s");
_("Copy output results to this folder after processing.");
_("Export the georeferenced point cloud in Entwine Point Tile (EPT) format. Default: %(default)s");
_("Perform image matching with the nearest N images based on image filename order. Can speed up processing of sequential images, such as those extracted from video. It is applied only on non-georeferenced datasets. Set to 0 to disable. Default: %(default)s");
_("Octree depth used in the mesh reconstruction, increase to get more vertices, recommended values are 8-12. Default: %(default)s");
_("Simple Morphological Filter window radius parameter (meters). Default: %(default)s");
_("Generate single file Binary glTF (GLB) textured models. Default: %(default)s");
_("Set a GPS offset in meters for the vertical axis (Z) by adding it to the altitude value of the GPS EXIF data. This does not change the value of any GCPs. This can be useful for example when adjusting from ellipsoidal to orthometric height. Default: %(default)s");
_("Path to the image geolocation file containing the camera center coordinates used for georeferencing. If you don't have values for yaw/pitch/roll you can set them to 0. The file needs to use the following format: EPSG:<code> or <+proj definition>image_name geo_x geo_y geo_z [yaw (degrees)] [pitch (degrees)] [roll (degrees)] [horz accuracy (meters)] [vert accuracy (meters)]Default: %(default)s");
_("Skips dense reconstruction and 3D model generation. It generates an orthophoto directly from the sparse reconstruction. If you just need an orthophoto and do not need a full 3D model, turn on this option. Default: %(default)s");
_("Filters the point cloud by removing points that deviate more than N standard deviations from the local mean. Set to 0 to disable filtering. Default: %(default)s");
_("Delete heavy intermediate files to optimize disk space usage. This affects the ability to restart the pipeline from an intermediate stage, but allows datasets to be processed on machines that don't have sufficient disk space available. Default: %(default)s");
_("Choose what to merge in the merge step in a split dataset. By default all available outputs are merged. Options: %(choices)s. Default: %(default)s");
_("show this help message and exit");
_("Set this parameter if you want a striped GeoTIFF. Default: %(default)s");
_("Set the radiometric calibration to perform on images. When processing multispectral and thermal images you should set this option to obtain reflectance/temperature values (otherwise you will get digital number values). [camera] applies black level, vignetting, row gradient gain/exposure compensation (if appropriate EXIF tags are found) and computes absolute temperature values. [camera+sun] is experimental, applies all the corrections of [camera], plus compensates for spectral radiance registered via a downwelling light sensor (DLS) taking in consideration the angle of the sun. Can be one of: %(choices)s. Default: %(default)s");
_("Automatically compute image masks using AI to remove the background. Experimental. Default: %(default)s");
_("Skip generation of a full 3D model. This can save time if you only need 2D results such as orthophotos and DEMs. Default: %(default)s");
_("Displays version number and exits. ");
_("Average number of images per submodel. When splitting a large dataset into smaller submodels, images are grouped into clusters. This value regulates the number of images that each cluster should have on average. Default: %(default)s");
_("Path to a GeoTIFF DEM or a LAS/LAZ point cloud that the reconstruction outputs should be automatically aligned to. Experimental. Default: %(default)s");
_("Path to the project folder. Your project folder should contain subfolders for each dataset. Each dataset should have an \"images\" folder.");
_("The maximum vertex count of the output mesh. Default: %(default)s");
_("URL to a ClusterODM instance for distributing a split-merge workflow on multiple nodes in parallel. Default: %(default)s");
_("Save the georeferenced point cloud in Cloud Optimized Point Cloud (COPC) format. Default: %(default)s");
_("Automatically set a boundary using camera shot locations to limit the area of the reconstruction. This can help remove far away background artifacts (sky, background landscapes, etc.). See also --boundary. Default: %(default)s");
_("Build orthophoto overviews for faster display in programs such as QGIS. Default: %(default)s");
_("Use this tag to build a DSM (Digital Surface Model, ground + objects) using a progressive morphological filter. Check the --dem* parameters for finer tuning. Default: %(default)s");
_("Use this tag if you have a GCP File but want to use the EXIF information for georeferencing instead. Default: %(default)s");
_("Perform ground rectification on the point cloud. This means that wrongly classified ground points will be re-classified and gaps will be filled. Useful for generating DTMs. Default: %(default)s");
_("Export the georeferenced point cloud in LAS format. Default: %(default)s");
_("Rerun this stage only and stop. Can be one of: %(choices)s. Default: %(default)s");
_("Matcher algorithm, Fast Library for Approximate Nearest Neighbors or Bag of Words. FLANN is slower, but more stable. BOW is faster, but can sometimes miss valid matches. BRUTEFORCE is very slow but robust.Can be one of: %(choices)s. Default: %(default)s");
_("Ignore Ground Sampling Distance (GSD).A memory and processor hungry change relative to the default behavior if set to true. Ordinarily, GSD estimates are used to cap the maximum resolution of image outputs and resizes images when necessary, resulting in faster processing and lower memory usage. Since GSD is an estimate, sometimes ignoring it can result in slightly better image output quality. Never set --ignore-gsd to true unless you are positive you need it, and even then: do not use it. Default: %(default)s");
_("Set this parameter if you want to generate a PNG rendering of the orthophoto. Default: %(default)s");

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Subproject commit 1970d0375fd84f77b94888a0399eb90bc3de4756