# lasheight This tool computes the height of each LAS point above the ground. This assumes that grounds points have already been classified (classification == 2) so they can be identified and used to construct a ground TIN. The ground points can also be in an separate file '-ground_points ground.las' or '-ground_points dtm.csv -parse ssxyz'. Should the input coordinates be in some representation where the z-axis does not correspond to elevation, such as in an earth-centered representation, then the file needs converted to, for example, a UTM projection first. The tool reads LIDAR in LAS/LAZ/ASCII format, triangulates the ground points into a TIN (or whatever point class(es) were selected with '-class 8' or '-classification 2 8'), and calculates the elevation of each point with respect to this TIN. By default the resulting heights are scaled with a factor of 10.0, quantized & clamped into an unsigned char between 0 and 255, and stored in the "user data" field of each point. Change the default scale factor of 10.0 with '-scale_u 20.0' or disable the storage in the "user data" field with option '-do_not_store_in_user_data' or by storing the height above the ground as "extra bytes" with '-store_as_extra_bytes' as an 0.01 scaled signed two-byte short [cm resolution] or with '-store_precise_as_extra_bytes' as an 0.001 scaled signed four-byte integer [mm resolution]. Alternatively - to avoid quantizing and clamping - you can '-replace_z' the elevation value of each point with the computed height. That means that afterwards all ground points will have an elevation of zero and all other points will have an elevation that equals their relative height above (or below) the ground TIN at their x and y location. In a sense this will "normalize" the elevations of points in respect to their surrounding ground truth. If you add the '-replace_z' option the resulting heights are *not* scaled with a factor of 10.0, quantized & clamped into an unsigned char between 0 and 255, and stored in the "user data" field of each point ... unless you add the explicit '-store_in_user_data' option. You can also use the height to change the point classification with '-classify_below -1.0 7' or '-classify_above 100.0 10' and also '-classify_between 0.5 2.0 3 -classify_between 2.0 5.0 4'. Another alternative is to use the computed height to eliminate points with a particular ground height above or below a threshold with the options '-drop_below 1.5' or '-drop_above 6.8'. You can ignore certain point classes from being dropped and/or classified with '-ignore_class 6 7'. If there are too few ground points to construct a ground TIN or the ground points form a degenerate triangulation no heights can be computed. By default the files are simply copied (and in case of '-replace_z' all elevations are zeroed). Alternatively these files can be skipped with the command-line option '-skip_files'. This tool can also be used to convert from Geoid to Ellipoidal heights. For this we need the Geoid model as a grid of points "geoid.txt", "geoid.las" or "geoid.xyz" whose elevations express the difference between the ellipsoid and the geoid. Simply run: lasheight64 -i lidar.las -ground_points geoid.txt -replace_z -odix _geoid When using external ground points with '-ground_points geoid.laz' lasheight will *not* use all points in the file but cut out a "generous portion" surrounding the bounding box of the points whose height is to be computed. That "generous cutting" may fail when the 'geoid.laz' file has sparsely spaced points. Using the '-all_ground_points' option forces lasheight to use all points. ## Examples lasheight64 -i *.las computes heights for all LAS files that match '*.las' and stores them quantized and clamped into the "user data" field (an 8-bit unsigned char) of each point record. lasheight64 -i *.las -class 3 the same as above but uses points with classification 3 instead of the default 2 to create the TIN that serves as the reference elevation against which the heights are computed. lasheight64 -i *.laz -olaz the same as above for LASzip-compressed input and output. lasheight64 -i *.las -replace_z replaces the z coordinate of each point with the computed height to avoid quantizing and clamping their value at the expense of losing the original z elevation values. lasheight64 -i lidar.las -o brush.las -drop_below 1.0 -drop_above 3.0 kepps only those points who are between 1 and 3 units above the ground. lasheight64 -i lidar.las -o heights.txt -oparse u stores the heights to a file called 'heights.txt' as quantized and clamped "unsigned chars". lasheight64 -i lidar.las -replace_z -o heights.txt -oparse z stores the heights to a file called 'heights.txt' as floating- point values of the same precision as the original elevations. lasheight64 -h lasheight64 -i *.las -v lasheight64 -i *.laz -olaz -quiet lasheight64 -i *.las -classification 2 8 -replace_z lasheight64 -i *.las -ground_points ground.las -replace_z lasheight64 -i *.las -ground_points geoid.xyz -replace_z lasheight64 -i in.las -o out.las -drop_below 1.5 lasheight64 -i in.las -o out.txt -drop_above 6.5 -oparse xyzu lasheight64 -i in.las -o out.las -drop_between 0.5 2.5 lasheight64 -i in.laz -o out.laz -classify_below -1 7 lasheight64 -i in.laz -o out.laz -classify_above 100 10 lasheight64 -i in.laz -o out.laz -classify_between 0.5 2 3 -classify_between 2 5 4 -ignore_class 6 lasheight64 -i in.laz -o out.laz -replace_z lasheight64 -i in.las -o out.txt -replace_z -oparse z lasheight64 -i tiles_ground\*.laz -store_as_extra_bytes -odir tiles_height -olaz -cores 4 lasheight64 -i tiles_ground\*.laz -store_precise_as_extra_bytes -odir tiles_height -olaz -cores 4 ## lasheight specific arguments -all_ground_points : use all external ground points instead of generously clipping them to bounding box of current file -class [m] [n] [o] ... : use points classes [m] [n] [o] ... as ground points -classification [m] [n] [o] ... : use points classes [m] [n] [o] ... as ground points -classify_above [z] [c] : classify points that are [z] units vertically above Delaunay TIN of ground points as [c] -classify_below [z] [c] : classify points that are [z] units vertically below Delaunay TIN of ground points as [c] -classify_between [z1] [z2] [c] : classify points that are between [z1] and [z2] units vertically above TIN of ground points as [c] -cores [n] : process multiple inputs on [n] cores in parallel -do_not_store_in_user_data : do not modify the user_data field at all -dont_remove_empty_files : do not remove files that have zero points remaining from disk -drop_above [z] : drop points that are [z] units vertically above Delaunay TIN of ground points -drop_below [z] : drop points that are [z] units vertically below Delaunay TIN of ground points -drop_between [z1] [z2] : drop points that are between [z1] and [z2] units vertically above TIN of ground points -ground_points [fnp] : use points from external file [fnp] as ground points -ignore_class [m] [n] [o] ... : ignores points with classification codes [m] [n] [o] ... -ilay [n] : apply [n] or all LASlayers found in corresponding *.lay file on read -ilaydir [n] : look for corresponding *.lay file in directory [n] -olay : write or append classification changes to a LASlayers *.lay file -olaydir [dir] : write the output *.lay file in directory [dir] -parse [xyz] : in case the input file is ascii use parse string [xyz] to access point values -remain_buffered : write buffer points to output when using '-buffered 25' on-the-fly buffering -replace_z : store heights to z coordinate (instead of in dm in user_data field). original elevations are lost. -scale_u [n] : scale height quantized to [n] increments in user_data field (default=10 cm) -skip_files : skip (instead of the default copy) files that have an insufficient number of ground points -store_as_extra_bytes : store height with cm precision as short in "extra bytes" (instead of in dm in user_data field) -store_in_user_data : store also in user_data field (even when storing to z coordinate or as extra bytes) -store_precise_as_extra_bytes : store height with mm precision as int in "extra bytes" (instead of in dm in user_data field) -switch_G_B : switch green and blue value -week_to_adjusted [n] : converts time stamps from GPS week [n] to Adjusted Standard GPS ### Basics -cpu64 : start 64 bit executable (instead of default 32 bit executable) -fail : fail if license expired or invalid -gui : start with files loaded into GUI -h : print help output -help : print help output -license : show license information -quiet : nothing reported in console -v : verbose output (print extra information) -verbose : verbose output (print extra information) -version : reports this tool's version number -vv : very verbose output (print even more information) -wait : wait for in the console at end of process ## Module arguments ### General -buffered [n] : define read or write buffer of size [n]{default=262144} -chunk_size [n] : set chunk size [n] in number of bytes -comma_not_point : use comma instead of point as decimal separator -neighbors [n] : set neighbors filename or wildcard [n] -neighbors_lof [n] : set neighbors list of files [fnf] -stored : use in memory reader -unique : remove duplicate points ### Color -clamp_RGB_to_8bit : limit RGB values to 8 bit (otherwise: 16 bit) -copy_B_into_NIR : copy blue color value into NearInfraRed value -copy_B_into_intensity : copy blue color value to intensity -copy_B_into_register [n] : copy blue color value into register [n] -copy_G_into_NIR : copy green color value into NearInfraRed value -copy_G_into_intensity : copy green color value to intensity -copy_G_into_register [n] : copy green color value into register [n] -copy_NIR_into_intensity : copy NIR into intensity -copy_NIR_into_register [n] : copy NearInfraRed value into register [n] -copy_RGB_into_intensity : copy weighted RGB value to intensity -copy_R_into_NIR : copy red color value into NearInfraRed value -copy_R_into_intensity : copy red color value to intensity -copy_R_into_register [n] : copy red color value into register [n] -copy_attribute_into_B [n] : copy attribute [n] value into blue -copy_attribute_into_G [n] : copy attribute [n] value into green -copy_attribute_into_NIR [n] : copy attribute [n] value into NIR (NearInfraRed) -copy_attribute_into_R [n] : copy attribute [n] value into red -copy_intensity_into_NIR : copy intensity into NIR (NearInfraRed) value -copy_register_into_B [n] : copy register [n] into blue color value -copy_register_into_G [n] : copy register [n] into green color value -copy_register_into_I [n] : copy register [n] into NearInfraRed value -copy_register_into_NIR [n] : copy register [n] into NearInfraRed value -copy_register_into_R [n] : copy register [n] into red color value -drop_RGB_green [min] [max] : drop points with green color value between [min] and [max] -drop_RGB_red [min] [max] : drop points with red color value between [min] and [max] -force_RGB : force the use of the RGB value even if the point format does not support RGB -keep_NDVI_from_CIR [min] [max] : keep NDVI (Normalized Difference Vegetation Index) from CIR between [min] [max] -keep_NDVI_green_is_NIR [min] [max] : keep NDVI (Normalized Difference Vegetation Index) where green is NIR between [min] [max] -keep_NDVI_intensity_is_NIR [min] [max]: keep NDVI (Normalized Difference Vegetation Index) where intensity is NIR between [min] [max] -keep_RGB_blue [m] [n] : keep points with RGB blue color values between [min] [max] -keep_RGB_green [min] [max] : keep points with green color value between [min] and [max] -keep_RGB_greenness [m] [n] : keep points with RGB greenness values between [min] [max] -keep_RGB_nir [m] [n] : keep points with RGB NIR values between [min] [max] -keep_RGB_red [min] [max] : keep points with red color value between [min] and [max] -map_attribute_into_RGB [a] [fnm] : map attribute [a] by table in file [fnm] to RGB values -oscale_rgb [n] : scale output RGB by [n] -scale_NIR [n] : scale NearInfraRed value by factor [n] -scale_NIR_down : scale NearInfraRed value down by 256 -scale_NIR_to_16bit : scale 8 bit NearInfraRed value to 16 bit -scale_NIR_to_8bit : scale 16 bit NearInfraRed value downto 8 bit -scale_NIR_up : scale NearInfraRed value up by 256 -scale_RGB [r] [g] [b] : scale RGB values by factors in [r][g][b] -scale_RGB_down : scale RGB color values down by 256 -scale_RGB_to_16bit : scale 8 bit color values to 16 bit -scale_RGB_to_8bit : scale 16 bit color values downto 8 bit -scale_RGB_up : scale RGB values from 8 bit up to 16 bit (multiply with 256) -scale_rgb_down : divides all RGB values by 256 (to go from 16 bit to 8 bit numbers) -scale_rgb_up : multiplies all RGB values by 256 (to go from 8 bit to 16 bit numbers) -set_NIR [n] : set NearInfraRed value to [n] -set_RGB [r] [g] [b] : set color to [r] [g] [b] -set_RGB_of_class [c] [r] [g] [b] : set RGB values of class [c] to [r][g][b] (8 or 16 bit) -switch_RGBI_into_CIR : set R to NIR; G to R; B to G -switch_RGB_intensity_into_CIR : set R to intensity; G to R; B to G -switch_R_B : switch red and blue color value -switch_R_G : switch red and green color value ### Coordinates -add_attribute_to_z [n] : add value of attribute [n] to z value -add_scaled_attribute_to_z [m] [n] : scale attribute [m] value by [n] and add to z value -auto_reoffset : puts a reasonable offset in the header and translates the points accordingly -bin_Z_into_point_source [n] : set point source to z/[n] -clamp_raw_z [min] [max] : limit raw z values to [min] and [max] -clamp_z [min] [max] : limit z values to [min] and [max] -clamp_z_above [n] : limit z values to maximal [n] -clamp_z_below [n] : limit z values to minimal [n] -classify_z_above_as [m] [n] : for z value above [m] set class to [n] -classify_z_below_as [m] [n] : for z value below [m] set class to [n] -classify_z_between_as [m] [n] [o] : for z value between [m] and [n] set class to [o] -copy_attribute_into_x [n] : copy attribute [n] value into x -copy_attribute_into_y [n] : copy attribute [n] value into y -copy_attribute_into_z [n] : copy attribute [n] value into z -copy_intensity_into_z : copy intensity to z value -copy_register_into_x [n] : copy register [n] to x value -copy_register_into_y [n] : copy register [n] to y value -copy_register_into_z [n] : copy register [n] to z value -copy_user_data_into_z : copy user data into z -copy_z_into_attribute [n] : copy z value into attribute [n] value -drop_x [m] [n] : drop points with x value between [m] and [n] -drop_x_above [n] : drop points with x value above [n] -drop_x_below [n] : drop points with x value below [n] -drop_xy [x1] [y1] [x2] [y2] : drop points within the [x1] [y1] [x2] [y2] rectangle -drop_xyz [x1] [y1] [z1] [x2] [y2] [z2]: drop points within the given cube dimensions -drop_y [m] [n] : drop points with y value between [m] and [n] -drop_y_above [n] : drop points with y value above [n] -drop_y_below [n] : drop points with y value below [n] -drop_z [m] [n] : drop points with z value between [m] and [n] -drop_z_above [n] : drop points with z value above [n] -drop_z_below [n] : drop points with z value below [n] -inside [x1] [y1] [x2] [y2] : use only points within the [x1] [y1] [x2] [y2] rectangle -inside_circle [x] [y] [r] : keep circle at pos [x] [y] with radius [r] -inside_rectangle [x1] [y1] [x2] [y2]: use only points within the [x1] [y1] [x2] [y2] rectangle -inside_tile [m] [n] [o] : use only points inside tile at lower-left [x] [y] with size [s] -keep_circle [x] [y] [r] : keep circle at pos [x] [y] with radius [r] -keep_profile [x1] [y1] [x2] [y2] [w]: keep profile with [x1] [y1] [x2] [y2] [w] -keep_tile [x] [y] [size] : keep tile at lower-left [x] [y] with size [s] -keep_x [m] [n] : keep points with x value between [m] and [n] -keep_xy [x1] [y1] [x2] [y2] : keep points within the [x1] [y1] [x2] [y2] rectangle -keep_xyz [x1] [y1] [z1] [x2] [y2] [z2]: keep points within the given cube dimensions -keep_y [m] [n] : keep points with y value between [m] and [n] -keep_z [m] [n] : keep points with z value between [m] and [n] -keep_z_above [n] : keep points with z value above [n] -keep_z_below [n] : keep points with z value below [n] -reoffset [x] [y] [z] : puts a new offset [x] [y] [z] into the header and translates the points accordingly -rescale [x] [y] [z] : puts a new scale [x] [y] [z] into the header and rescales the points accordingly -rescale_xy [x] [y] : rescale x y by [x] [y] -rescale_z [z] : rescale z by [z] -rotate_xy [a] [x] [y] : rotate points by [a] degrees, center at [x] [y] -rotate_xz [a] [x] [z] : rotate points by [a] degrees, center at [x] [z] -rotate_yz [a] [y] [z] : rotate points by [a] degrees, center at [y] [z] -scale_x [n] : scale x value by [n] -scale_xyz [m] [n] [o] : scale xyz values by [m] [n] [o] -scale_y [n] : scale y value by [n] -scale_z [n] : scale z value by [n] -switch_x_y : exchange x and y value -switch_x_z : exchange x and z value -switch_y_z : exchange z and x value -transform_affine [a],[b],[c],[d] : transform input using affine transformation with [a],[b],[c],[d] -transform_helmert [m] [n] [o] : do a helmert transformation with 3 or 7 comma separated parameters [n] ... -transform_matrix [r11,r12,r13] [r21,r22,r23] [r31,r32,r33] [tr1,tr2,tr3]: transform input using matrix [r11,r12,r13] [r21,r22,r23] [r31,r32,r33] [tr1,tr2,tr3] -translate_raw_x [n] : translate raw x value by [n] -translate_raw_xy_at_random [x] [y] : translate raw xy values by random and max offset of [x] [y] -translate_raw_xyz [x] [y] [z] : translate raw coordinates by [x] [y] [z] -translate_raw_y [n] : translate raw y value by [n] -translate_raw_z [n] : translate raw z value by [n] -translate_then_scale_x [m] [n] : translate x value by [m] and scale by [n] -translate_then_scale_y [m] [n] : translate y value by [m] and scale by [n] -translate_then_scale_z [m] [n] : translate z value by [m] and scale by [n] -translate_x [n] : translate y value by [n] -translate_xyz [x] [y] [z] : translate point coordinates by [x] [y] [z] -translate_y [n] : translate y value by [n] -translate_z [n] : translate z value by [n] ### Simple thinning -drop_every_nth [n] : drop every [n]th point -keep_every_nth [n] : keep every [n]th point -keep_random_fraction [m] [n] : keep points by random fraction [m]{0-1}, optional seed [n] -thin_points_with_time [n] : thin points with time, [n] = timespacing -thin_pulses_with_time [n] : thin pulses with time, [n] = timespacing -thin_with_grid [n] : thin points by min grid size of [n] -thin_with_time [n] : thin pulses with time, [n] = timespacing ### Return number -change_extended_number_of_returns_from_to [m] [n]: change extended number of returns from [m] to [n] -change_extended_return_number_from_to [m] [n]: change extended return number from [m] to [n] -change_number_of_returns_from_to [m] [n]: change number of returns from [m] to [n] -change_return_number_from_to [m] [n]: change return number from [m] to [n] -drop_double : drop double returns -drop_first : drop first return -drop_first_of_many : drop first of many returns -drop_last : drop last return -drop_last_of_many : drop last of many returns -drop_middle : drop middle returns -drop_number_of_returns [n] : drop points with [n] number of returns -drop_quadruple : drop quadruple returns -drop_quintuple : drop quintuple returns -drop_return [m] [n]... : drop points with return [m] [n]... -drop_return_mask [n] : drop points with return mask [n] -drop_second_last : drop points with second last return -drop_single : drop points with single return -drop_triple : drop points with triple return -first_only : use first return only -ignore_first : ignores first returns -ignore_first_of_many : ignores first returns (but only those of multi-returns) -ignore_intermediate : ignores intermediate returns -ignore_last : ignores last returns -ignore_last_of_many : ignores last returns (but only those of multi-returns) -ignore_single : ignores single returns -keep_double : keep double returns -keep_first : keep first return -keep_first_of_many : keep first of many returns -keep_last : keep last return -keep_last_of_many : keep last of many returns -keep_middle : keep mittle returns -keep_number_of_returns [n] : keep points with [n] number of returns -keep_quadruple : keep quadruple returns -keep_quintuple : keep quintuple returns -keep_return [m] [n]... : keep points with return [m] [n]... -keep_return_mask [n] : keep points with return mask [n] -keep_second_last : keep points with second last return -keep_single : keep points with single return -keep_triple : keep points with triple return -last_only : use last return only -repair_zero_returns : sets return counts and number of returns that are zero to one -set_extended_number_of_returns [n] : set extended number of returns to [n] -set_extended_return_number [n] : set extended return number to [n] -set_number_of_returns [n] : set number of returns to [n] -set_return_number [n] : set return number to [n] ### Scanline -drop_scan_direction [n] : drop points with scan direction [n] -faf : input files are flightlines. do ***NOT*** use this for tiled input -faf_index [n] : set files are flightlines index [n] -files_are_flightlines : input files are flightlines. do ***NOT*** use this for tiled input -keep_edge_of_flight_line : keep points with "Edge of Flight Line" flag set -keep_scan_direction_change : keep points with changed scan direction flag -set_edge_of_flight_line [0/1] : set "Edge of Flight Line" flag to [0/1] -set_scan_direction_flag [0/1] : set scan direction flag to [0/1] ### Scanner channel -copy_scanner_channel_into_point_source: copy scanner channel into point_source -copy_scanner_channel_into_user_data: copy scanner channel into user data -copy_user_data_into_scanner_channel: copy user data into scanner channel -drop_scanner_channel [n] : drop points with scanner channel [n] -keep_scanner_channel [n] : keep points with scanner channel [n] -merge_scanner_channel_into_point_source: merge scanner channel to point source -set_extended_scanner_channel [n] : set extended scanner channel to [n] -set_scanner_channel [n] : set scanner channel to [n] -split_scanner_channel_from_point_source: split scanner channel from point source and save as extended scanner channel ### Source ID -apply_file_source_ID : copy file source ID to target -bin_Z_into_point_source [n] : set point source to z/[n] -bin_abs_scan_angle_into_point_source [n]: set point source to scan_angle/[n] -bin_gps_time_into_point_source [n] : set point source to gps/[n] -change_point_source_from_to [m] [n]: change point source from [m] to [n] -copy_attribute_into_point_source [n]: copy attribute [n] value into point source -copy_classification_into_point_source: copy classification to point source -copy_point_source_into_register [n]: copy point source into register [n] -copy_register_into_point_source [n]: copy register [n] to point source -copy_scanner_channel_into_point_source: copy scanner channel into point_source -copy_user_data_into_point_source : copy user data into point source -drop_point_source [n] : drop points with point source [n] -drop_point_source_above [n] : drop points with with point source above [n] -drop_point_source_below [n] : drop points with with point source below [n] -drop_point_source_between [m] [n] : drop points with with point source between [n] and [m] -keep_point_source [n] : keep points with point source [n] -keep_point_source_between [m] [n] : keep points with with point source between [n] and [m] -map_point_source [fnm] : set the point source by map in file [fnm] -merge_scanner_channel_into_point_source: merge scanner channel to point source -set_point_source [n] : set point source to [n] -split_scanner_channel_from_point_source: split scanner channel from point source and save as extended scanner channel ### User data -add_scaled_attribute_to_user_data [m] [n]: scale attribute [m] value by [n] and add to user data -change_user_data_from_to [m] [n] : change user data from [m] to [n] -copy_attribute_into_user_data [n] : copy attribute [n] value into user data field -copy_classification_into_user_data : copy classification to user data -copy_register_into_user_data [n] : copy register [n] to user data -copy_scanner_channel_into_user_data: copy scanner channel into user data -copy_user_data_into_attribute [n] : copy user data into attribute [n] value -copy_user_data_into_classification : copy user data into classification -copy_user_data_into_point_source : copy user data into point source -copy_user_data_into_register [n] : copy user data to register [n] -copy_user_data_into_scanner_channel: copy user data into scanner channel -copy_user_data_into_z : copy user data into z -drop_user_data [n] : drop points with user data value of [n] -drop_user_data_above [n] : drop points with user data value above [n] -drop_user_data_below [n] : drop points with user data value below [n] -drop_user_data_between [m] [n] : drop points with user data between [m] and [n] -keep_user_data [n] : keep points with user data value of [n] -keep_user_data_above [n] : keep points with user data value above [n] -keep_user_data_below [n] : keep points with user data value below [n] -keep_user_data_between [m] [n] : keep points with user data between [m] and [n] -map_user_data [fnm] : set the user data by map in file [fnm] -scale_user_data [n] : scale user data by [n] -set_user_data [n] : sets all user_data fields to [n] ### Classification -change_class_from_to [m] [n] : change classification from [m] to [n] -change_classification_from_to [m] [n]: change classification from [m] to [n] -change_extended_class_from_to [m] [n]: change extended class from [m] to [n] -change_extended_classification_from_to [m] [n]: change extended class from [m] to [n] -classify_attribute_above_as [m] [n] [o]: for attribute [m] with value above [n] set class to [o] -classify_attribute_below_as [m] [n] [o]: for attribute [m] with value below [n] set class to [o] -classify_attribute_between_as [m] [n] [o] [p]: for attribute [m] with value between [n] and [o] set class to [p] -classify_intensity_above_as [m] [n]: for intensity value above [m] set class to [n] -classify_intensity_below_as [m] [n]: for intensity value below [m] set class to [n] -classify_intensity_between_as [m] [n] [o]: for intensity value between [m] and [n] set class to [o] -classify_z_above_as [m] [n] : for z value above [m] set class to [n] -classify_z_below_as [m] [n] : for z value below [m] set class to [n] -classify_z_between_as [m] [n] [o] : for z value between [m] and [n] set class to [o] -copy_classification_into_point_source: copy classification to point source -copy_classification_into_user_data : copy classification to user data -copy_intensity_into_classification : copy intensity to classification -copy_user_data_into_classification : copy user data into classification -drop_class [m] [n] [o]... : drop points with class in [m][n][o]... -drop_classification [m] [n] [o]... : drop points with class in [m][n][o]... -drop_classification_mask [n] : drop points with classification mask matches [n] -drop_extended_class [m] [n]... : drop extended class [m] [n]... -drop_extended_classification [n] : drop points with extended classification [n] -drop_extended_classification_mask [a] [b] [c] [d] [e] [f] [g] [h]: drop points with extended classification mask matches [a] [b] [c] [d] [e] [f] [g] [h] -ignore_class_mask [n] : ignores points with DWORD class mask [n] -ignore_extended_class [m] [n] [o] ...: ignores points with specified extended classification codes [m] [n] [o] ... -keep_class [m] [n] [o]... : keep points with class in [m][n][o]... -keep_classification [m] [n] [o]... : keep points with class in [m][n][o]... -keep_classification_mask [n] : keep points with classification mask matches [n] -keep_extended_class [m] [n]... : keep extended class [m] [n]... -keep_extended_classification [n] : keep points with extended class [n] -move_ancient_to_extended_classification: move old data to extended classification -set_RGB_of_class [c] [r] [g] [b] : set RGB values of class [c] to [r][g][b] (8 or 16 bit) -set_classification [n] : set classification to [n] -set_extended_classification [n] : set extended classification to [n] ### Extra byte -add_attribute_to_z [n] : add value of attribute [n] to z value -add_scaled_attribute_to_user_data [m] [n]: scale attribute [m] value by [n] and add to user data -add_scaled_attribute_to_z [m] [n] : scale attribute [m] value by [n] and add to z value -classify_attribute_above_as [m] [n] [o]: for attribute [m] with value above [n] set class to [o] -classify_attribute_below_as [m] [n] [o]: for attribute [m] with value below [n] set class to [o] -classify_attribute_between_as [m] [n] [o] [p]: for attribute [m] with value between [n] and [o] set class to [p] -copy_attribute_into_B [n] : copy attribute [n] value into blue -copy_attribute_into_G [n] : copy attribute [n] value into green -copy_attribute_into_I [n] : copy attribute [n] value into intensity -copy_attribute_into_NIR [n] : copy attribute [n] value into NIR (NearInfraRed) -copy_attribute_into_R [n] : copy attribute [n] value into red -copy_attribute_into_intensity [n] : copy attribute [n] value into intensity -copy_attribute_into_point_source [n]: copy attribute [n] value into point source -copy_attribute_into_register [m] [n]: copy attribute [m] value into register [m] -copy_attribute_into_user_data [n] : copy attribute [n] value into user data field -copy_attribute_into_x [n] : copy attribute [n] value into x -copy_attribute_into_y [n] : copy attribute [n] value into y -copy_attribute_into_z [n] : copy attribute [n] value into z -copy_intensity_into_attribute [n] : copy intensity to attribute [n] value -copy_register_into_attribute [m] [n]: copy register [m] to attribute [n] value -copy_user_data_into_attribute [n] : copy user data into attribute [n] value -copy_z_into_attribute [n] : copy z value into attribute [n] value -drop_attribute_above [m] [n] : drop points with attribute [m] value > [n] -drop_attribute_below [m] [n] : drop points with attribute [m] value < [n] -drop_attribute_between [m] [n] [o] : drop points with attribute [m] in range [n]...[o] -iadd_attribute [m] [n] [o] [p] [q] [r] [s] [t]: adds a new "extra_byte" attribute of data_type [m] name [n] description [o]; optional: scale[p] offset [q] pre_scale [r] pre_offset [s] no_data_value [t] -iadd_extra [m] [n] [o] [p] [q] [r] [s] [t]: adds a new "extra_byte" attribute of data_type [m] name [n] description [o]; optional: scale[p] offset [q] pre_scale [r] pre_offset [s] no_data_value [t] -keep_attribute_above [m] [n] : keep points with attribute [m] value > [n] -keep_attribute_below [m] [n] : keep points with attribute [m] value < [n] -keep_attribute_between [m] [n] [o] : keep points with attribute [m] in range [n]...[o] -load_attribute_from_text [m] [fnt] : load attribute [m] from file [fnt] -map_attribute_into_RGB [a] [fnm] : map attribute [a] by table in file [fnm] to RGB values -scale_attribute [m] [n] : scale attribute [m] by [n] -set_attribute [m] [n] : set attribute [m] with value [n] -translate_attribute [m] [n] : translate attribute [n] by [n] ### Flags -drop_keypoint : drop points flaged as keypoint -drop_overlap : drop points flaged as overlap -drop_scan_direction [n] : drop points with scan direction [n] -drop_synthetic : drop points flaged as synthetic -drop_withheld : drop points flaged as withheld -ignore_keypoint : ignore points with keypoint flag set -ignore_overlap : ignores points flagged overlap (new LAS 1.4 point types only) -ignore_synthetic : ignore points with synthetic flag set -ignore_withheld : ignores points flagged withheld -keep_edge_of_flight_line : keep points with "Edge of Flight Line" flag set -keep_keypoint : keep points flaged as keypoint -keep_overlap : keep points flaged as overlap -keep_scan_direction_change : keep points with changed scan direction flag -keep_synthetic : keep points flaged as synthetic -keep_withheld : keep points flaged as withheld -set_edge_of_flight_line [0/1] : set "Edge of Flight Line" flag to [0/1] -set_extended_overlap_flag [0/1] : set extended overlap flag to [0/1] -set_keypoint_flag [0/1] : set keypoint flag to [0/1] -set_overlap_flag [0/1] : set overlap flag to [0/1] -set_scan_direction_flag [0/1] : set scan direction flag to [0/1] -set_synthetic_flag [0/1] : set synthetic flag to [0/1] -set_withheld_flag [0/1] : set withheld flag to [0/1] ### GPS time -adjusted_to_week : converts time stamps from Adjusted Standard GPS to GPS week -bin_gps_time_into_intensity [n] : set intensity time to gps/[n] -bin_gps_time_into_point_source [n] : set point source to gps/[n] -drop_gps_time_above [n] : drop points with GPS time above [n] -drop_gps_time_below [n] : drop points with GPS time below [n] -drop_gps_time_between [m] [n] : drop points with GPS time between [m] and [n] -drop_gpstime_above [n] : drop points with GPS time above [n] -drop_gpstime_below [n] : drop points with GPS time below [n] -drop_gpstime_between [m] [n] : drop points with GPS time between [m] and [n] -keep_gps_time [m] [n] : keep points with GPS time between [m] and [n] -keep_gps_time_above [n] : keep points with GPS time above [n] -keep_gps_time_below [n] : keep points with GPS time below [n] -keep_gps_time_between [m] [n] : keep points with GPS time between [m] and [n] -keep_gpstime [m] [n] : keep points with GPS time between [m] and [n] -keep_gpstime_above [n] : keep points with GPS time above [n] -keep_gpstime_below [n] : keep points with GPS time below [n] -keep_gpstime_between [m] [n] : keep points with GPS time between [m] and [n] -set_gps_time [n] : set gps time to [n] -translate_gps_time [n] : translate GPS time by [n] ### Intensity -bin_gps_time_into_intensity [n] : set intensity time to gps/[n] -clamp_intensity [min] [max] : limit intensity values to [min] and [max] -clamp_intensity_above [max] : limit intensity values to maximal [max] -clamp_intensity_below [max] : limit intensity values to minimal [min] -classify_intensity_above_as [m] [n]: for intensity value above [m] set class to [n] -classify_intensity_below_as [m] [n]: for intensity value below [m] set class to [n] -classify_intensity_between_as [m] [n] [o]: for intensity value between [m] and [n] set class to [o] -copy_B_into_intensity : copy blue color value to intensity -copy_G_into_intensity : copy green color value to intensity -copy_NIR_into_intensity : copy NIR into intensity -copy_RGB_into_intensity : copy weighted RGB value to intensity -copy_R_into_intensity : copy red color value to intensity -copy_attribute_into_I [n] : copy attribute [n] value into intensity -copy_attribute_into_intensity [n] : copy attribute [n] value into intensity -copy_intensity_into_NIR : copy intensity into NIR (NearInfraRed) value -copy_intensity_into_attribute [n] : copy intensity to attribute [n] value -copy_intensity_into_classification : copy intensity to classification -copy_intensity_into_register [n] : copy color intensitiy value into register [n] -copy_intensity_into_z : copy intensity to z value -copy_register_into_intensity [n] : copy register [n] into point intensitiy value -drop_intensity_above [n] : drop points with intensity value above [n] -drop_intensity_below [n] : drop points with intensity value below [n] -drop_intensity_between [m] [n] : drop points with intensity value between [m] and [n] -iscale_intensity [n] : scale intensity value by [n] -itranslate_intensity [n] : translate input intensity by [n] -keep_NDVI_intensity_is_NIR [min] [max]: keep NDVI (Normalized Difference Vegetation Index) where intensity is NIR between [min] [max] -keep_intensity [m] [n] : keep points with intensity between [m] and [n] -keep_intensity_above [n] : keep points with intensity value above [n] -keep_intensity_below [n] : keep points with intensity value below [n] -map_intensity [fnm] : set the intensity by map in file [fnm] -scale_intensity [n] : multiply intensity by [n] -set_intensity [n] : set intensity to [n] -switch_RGB_intensity_into_CIR : set R to intensity; G to R; B to G -translate_intensity [n] : translate intensity by [n] -translate_then_scale_intensity [m] [n]: translate intensity by [m] and scale by [n] ### Raw point values -clamp_raw_z [min] [max] : limit raw z values to [min] and [max] -translate_raw_x [n] : translate raw x value by [n] -translate_raw_xy_at_random [x] [y] : translate raw xy values by random and max offset of [x] [y] -translate_raw_xyz [x] [y] [z] : translate raw coordinates by [x] [y] [z] -translate_raw_y [n] : translate raw y value by [n] -translate_raw_z [n] : translate raw z value by [n] ### Registers -add_registers [m] [n] [o] : add register [m] and [n] and store result in register [o] -copy_B_into_register [n] : copy blue color value into register [n] -copy_G_into_register [n] : copy green color value into register [n] -copy_NIR_into_register [n] : copy NearInfraRed value into register [n] -copy_R_into_register [n] : copy red color value into register [n] -copy_attribute_into_register [m] [n]: copy attribute [m] value into register [m] -copy_intensity_into_register [n] : copy color intensitiy value into register [n] -copy_point_source_into_register [n]: copy point source into register [n] -copy_register_into_B [n] : copy register [n] into blue color value -copy_register_into_G [n] : copy register [n] into green color value -copy_register_into_I [n] : copy register [n] into NearInfraRed value -copy_register_into_NIR [n] : copy register [n] into NearInfraRed value -copy_register_into_R [n] : copy register [n] into red color value -copy_register_into_attribute [m] [n]: copy register [m] to attribute [n] value -copy_register_into_intensity [n] : copy register [n] into point intensitiy value -copy_register_into_point_source [n]: copy register [n] to point source -copy_register_into_user_data [n] : copy register [n] to user data -copy_register_into_x [n] : copy register [n] to x value -copy_register_into_y [n] : copy register [n] to y value -copy_register_into_z [n] : copy register [n] to z value -copy_user_data_into_register [n] : copy user data to register [n] -divide_registers [m] [n] [o] : divide register [m] by register [n] and store result in register [o] -multiply_registers [m] [n] [o] : Multiply register [m] with [n] and store result in register [o] -scale_register [m] [n] : scale register index [m] with factor [n] -set_register [m] [n] : set register [m] with value [n] -subtract_registers [m] [n] [o] : subtract register [m] by register [n] and store result in register [o] -translate_register [m] [n] : translate register index [m] value by [n] ### Scan angle -bin_abs_scan_angle_into_point_source [n]: set point source to scan_angle/[n] -drop_abs_scan_angle_above [max] : drop points with absolute scan angle above [max] -drop_abs_scan_angle_below [min] : drop points with absolute scan angle below [min] -drop_scan_angle_above [n] : drop points with scan angle above [n] -drop_scan_angle_below [n] : drop points with scan angle below [n] -drop_scan_angle_between [m] [n] : drop points with scan angle between [m] and [n] -iscale_scan_angle [n] : scale scan angle by [n] -itranslate_scan_angle [n] : translate input scan angle by [n] -keep_scan_angle [m] [n] : keep points with scan angle between [m] and [n] -keep_scan_angle_between [m] [n] : keep points with scan angle between [m] and [n] -scale_scan_angle [n] : scale scan angle by [n] -set_scan_angle [n] : set scan angle to [n] -translate_scan_angle [n] : translate scan angle by [n] -translate_then_scale_scan_angle [m] [n]: translate scan angle by [m] and scale by [n] ### Tiles -keep_tile [x] [y] [size] : keep tile at lower-left [x] [y] with size [s] ### Waveform packet -drop_wavepacket [n] : drop points with wavepacket value of [n] -flip_waveform_direction : flip the waveform direction in the waveform VLR -keep_wavepacket [n] : keep points with wavepacket value of [n] ### CRS -aeac [m] [n] [meter/survey_feet/feet] [o] [p] [q] [r]: Albers Equal Area Conic Projection: False Easting [m] False Northing[n] [meter/survey_feet/feet] Central Meridian [o] Standard Parallel 1 [p] Standard Parallel 2 [q] Latitude of origin [r] -ecef : input is geocentric (Earth-centered Earth-fixed) -elevation_feet : use feet for elevation -elevation_meter : use meter for elevation -elevation_survey_feet : set vertical units from meters to US survey feet -elevation_surveyfeet : use survey feet for elevation -ellipsoid [n] : use the WGS-84 ellipsoid [n]{do -ellipsoid -1 for a list of ellipsoids} -epsg [n] : set datum to EPSG [n] -etrs89 : use datum ETRS89 -feet : use feet -gda2020 : use datum GDA2020 -gda94 : use datum GDA94 -grs80 : use datum GRS1980 -latlong : geometric coordinates in latitude/longitude order -lcc 609601.22 0.0 meter 33.75 -79 34.33333 36.16666: specifies a lambertian conic confomal projection -longlat : geometric coordinates in longitude/latitude order -meter : use meter -nad27 : use the NAD27 ellipsoid -nad83 : use the NAD83 ellipsoid -nad83_2011 : use datum NAD83_2011 -nad83_csrs : use datum NAD83_CSRS -nad83_harn : use datum NAD83_HARN -nad83_pa11 : set horizontal datum to NAD83 PA11 -osgb1936 : use datum OSGB 1936 -sp27 SC_N : use the NAD27 South Carolina North state plane -sp83 CO_S : use the NAD83 Colorado South state plane for georeferencing -survey_feet : use survey feet -surveyfeet : use survey feet as unit of measurement -target_aeac [m] [n] [meter/survey_feet/feet] [o] [p] [q] [r]: Albers Equal Area Conic Projection for target: False Easting [m] False Northing[n] [meter/survey_feet/feet] Central Meridian [o] Standard Parallel 1 [p] Standard Parallel 2 [q] Latitude of origin [r] -target_ecef : output is geocentric (Earth-centered Earth-fixed) -target_elevation_feet : output uses feet for elevation -target_elevation_meter : output uses meter for elevation -target_elevation_precision [n] : output uses [n] (meter/feet) resolution for z -target_elevation_survey_feet : use elevation survey feet as target unit -target_elevation_surveyfeet : output uses survey feet for elevation -target_epsg [n] : output is EPSG code [n] (e.g. 2193=NZGD2000) -target_feet : output uses feet -target_latlong : output is geometric coordinates in latitude/longitude -target_lcc 609601.22 0.0 meter 33.75 -79 34.33333 36.16666: specifies a lambertian conic confomal projection at target -target_longlat : output is geometric coordinates in longitude/latitude -target_meter : output uses meter -target_precision [n] : output uses [n] (meter/feet) resolution for x and y -target_sp27 SC_N : output is state plane NAD27 South Carolina North -target_sp83 CO_S : output is state plane NAD83 Colorado South -target_survey_feet : output uses survey feet -target_surveyfeet : use survey feet as target unit -target_tm : use transverse mercator projection for target -target_utm 12T : output is UTM zone 12T -tm 609601.22 0.0 meter 33.75 -79 0.99996: specifies a transverse mercator projection -transverse_mercator : use transverse mercator projection -utm 12T : use UTM zone 12T -vertical_cgvd2013 : set vertical datum to CGVD2013 -vertical_cgvd28 : set vertical datum to CGVD28 -vertical_dhhn2016 : set vertical datum to DHHN2016 -vertical_dhhn92 : set vertical datum to DHHN92 -vertical_dvr90 : set vertical datum to DVR90 -vertical_epsg [n] : set vertical datum to EPSG [n] -vertical_evrf2007 : set vertical datum to EVRF2007 -vertical_navd29 : set vertical datum to NAVD29 -vertical_navd88 : set vertical datum to NAVD88 -vertical_ngvd29 : set vertical datum to NGVD29 -vertical_nn2000 : set vertical datum to NN2000 -vertical_nn54 : set vertical datum to NN54 -vertical_nzvd2016 : set vertical datum to NZVD2016 -vertical_wgs84 : set vertical datum to WGS84 -wgs72 : use the WGS-72 ellipsoid -wgs84 : use the WGS-84 ellipsoid ### Logical -filter_and : boolean AND combination of last 2 filters -filter_or : boolean OR combination of last 2 filters -filtered_transform : do the transformation only on points of the current filter ### Input -i [fnp] : input file or input file mask [fnp] (e.g. *.laz;fo?.la?;esri.shp,...) -io_ibuffer [n] : use read-input-buffer of size [n] bytes -iparse [xyz] : define fields [xyz] for text input parser -ipts : input as PTS (plain text lidar source), store header in VLR -iptx : input as PTX (plain text extended lidar data), store header in VLR -iptx_transform : use PTX file header to transform point data -iskip [n] : skip [n] lines at the beginning of the text input -itxt : expect input as text file -lof [fnf] : use input out of a list of files [fnf] -merged : merge input files -stdin : pipe from stdin ### Output -compatible : write LAS/LAZ output in compatibility mode -do_not_populate : do not populate header on output -io_obuffer [n] : use write-out-buffer of size [n] bytes -native : write LAS/LAZ output in native/actual mode -nil : pipe output to NULL (suppress output) -o [n] : use [n] as output file -obin : output as BIN (terrasolid binary) -ocut [n] : cut the last [n] characters from name -odir [n] : set output directory to [n] -odix [n] : set output file name suffix to [n] -oforce : force output creation also on errors or warnings -olas : output as LAS file -olaz : output as LAZ (compressed LAS) -oparse [xyz] : parse on-the-fly to ASCII using fields [xyz] -opts : output as PTS (plain text lidar data) -optx : output as PTX (plain text with header) -oqi : output in QFIT format (.qi)(ATM project, NASA) -oscale_rgb [n] : scale output RGB by [n] -osep [sep] : set text output separator as [sep](see table below) -otxt : output as textfile -owrl : output as VRLM (Virtual Reality Modeling Language) text -pipe_on : write output to command pipe, see also -std_in -populate : populate header on output -stdout : pipe to stdout -target_ecef : output is geocentric (Earth-centered Earth-fixed) -temp_files [n] : set base file name [n] for temp files (example: E:\tmp) ### parse The '-parse [xyz]' flag specifies how to interpret each line of the ASCII file. For example, 'tsxyzssa' means that the first number is the gpstime, the next number should be skipped, the next three numbers are the x, y, and z coordinate, the next two should be skipped, and the next number is the scan angle. The other supported entries are: x : [x] coordinate y : [y] coordinate z : [z] coordinate t : gps [t]ime R : RGB [R]ed channel G : RGB [G]reen channel B : RGB [B]lue channel I : N[I]R channel of LAS 1.4 point type 8 s : [s]kip a string or a number that we don't care about i : [i]ntensity a : scan [a]ngle n : [n]umber of returns of that given pulse r : number of [r]eturn h : with[h]eld flag k : [k]eypoint flag g : synthetic fla[g] o : [o]verlap flag of LAS 1.4 point types 6, 7, 8 l : scanner channe[l] of LAS 1.4 point types 6, 7, 8 E : terrasolid [E]hco Encoding c : [c]lassification u : [u]ser data p : [p]oint source ID e : [e]dge of flight line flag d : [d]irection of scan flag 0-9 : additional attributes described as extra bytes (0 through 9) (13) : additional attributes described as extra bytes (10 and up) H : a hexadecimal string encoding the RGB color J : a hexadecimal string encoding the intensity ### output separator The '-osep [sep]' argument specifies the output format of a text(xyz or csv) output. Supported [sep] values: comma tab dot colon semicolon hyphen space ## License Please license from info@rapidlasso.de to use the tool commercially. You may use the tool to do tests with up to 3 mio points. Please note that the unlicensed version may will adjust some data and add a bit of white noise to the coordinates. ## Support To get more information about a tool just goto the [LAStools Google Group](http://groups.google.com/group/lastools/) and enter the tool name in the search function. You will get plenty of samples to this tool. To get further support see our [rapidlasso service page](https://rapidlasso.de/service/) Check for latest updates at https://rapidlasso.de/category/blog/releases/ If you have any suggestions please let us (info@rapidlasso.de) know.