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Dataset Title:	Zooplankton collected aboard Palmer Station LTER annual cruises off the western antarctic peninsula, 1993, 2008.
Institution:	National Science Foundation   (Dataset ID: ZooplanktonDensityHistorical)
Information:	Summary | License | FGDC | ISO 19115 | Metadata | Background | Subset | Files | Make a graph

 

Variable	Optional Constraint #1		Optional Constraint #2		Minimum    or a List of Values	Maximum
time (Start Time, UTC)	!= =~ <= >= = < >		!= =~ <= >= = < >		1993-01-09T08:29:00Z	2008-02-02T08:32:00Z
depth (m)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	3709.0
latitude (degrees_north)	!= =~ <= >= = < >		!= =~ <= >= = < >		-68.752	-63.5731
longitude (degrees_east)	!= =~ <= >= = < >		!= =~ <= >= = < >		-73.9195	-63.7008
end_time (UTC)	!= =~ <= >= = < >		!= =~ <= >= = < >		1993-01-09T00:00:00Z	2008-02-02T09:09:00Z
lat_end (Latitude, degrees_north)	!= =~ <= >= = < >		!= =~ <= >= = < >		-68.751	-63.5731
lon_end (Longitude, degrees_east)	!= =~ <= >= = < >		!= =~ <= >= = < >		-73.9468	-57.9869
cruise_tow_number	!= =~ <= >= = < >		!= =~ <= >= = < >		10006	160255
cruise_name	!= =~ <= >= = < >		!= =~ <= >= = < >		"LMG00-01" "LMG01-01" "LMG02-01" "LMG03-01" "LMG04-01" "LMG05-01" "LMG06-01" "LMG07-01" "LMG08-01" "LMG98-01" "LMG99-01" "PD93-01" "PD94-01" "PD95-01" "PD96-01" "PD97-01"
event	!= =~ <= >= = < >		!= =~ <= >= = < >		8.0	1313.0
tow_number	!= =~ <= >= = < >		!= =~ <= >= = < >		1	255
grid_line	!= =~ <= >= = < >		!= =~ <= >= = < >		100	626
grid_station	!= =~ <= >= = < >		!= =~ <= >= = < >		-82	260
tow_duration (minutes)	!= =~ <= >= = < >		!= =~ <= >= = < >		0	85
heading (degrees)	!= =~ <= >= = < >		!= =~ <= >= = < >		0	359
speed_over_ground	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	4.5
wind_speed_start (Wind Speed)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	57.0
wind_direction (Wind From Direction, degrees)	!= =~ <= >= = < >		!= =~ <= >= = < >		0	359
net_id	!= =~ <= >= = < >		!= =~ <= >= = < >		2	2
tow_type	!= =~ <= >= = < >		!= =~ <= >= = < >		"Shallow"	"Standard"
target_depth (Depth)	!= =~ <= >= = < >		!= =~ <= >= = < >		0	0
depth_max (Depth, meters)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	690.0
volume_filtered (m3)	!= =~ <= >= = < >		!= =~ <= >= = < >		2458.0	28538.0
siphon_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	7.577
siphon_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2.66
ctenoph_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	8.176
ctenoph_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	33.024
clio_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	5.969
clio_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.208
limacina_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	932.167
limacina_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	34.844
clion_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	24.831
clion_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	1.865
pteropod_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	48.14
pteropod_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	1.747
cephalop_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.411
cephalop_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.13
tomopter_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	18.746
tomopter_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2.261
polychae_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	8.82
polychae_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	1.8
pseudosa_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	27.379
pseudosa_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	5.157
chaetogn_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	11.384
chaetogn_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2.637
copepoda_desnity (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.245
copepoda_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	7.646
ostracod_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.703
ostracod_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.0
mysida_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2.256
mysida_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.0
themisto_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	309.615
themisto_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	28.42
amphipod_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	86.999
amphipod_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	6.448
esuperba_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	9900.87
esuperba_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	4714.7
ecrystal_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	1067.947
ecrystal_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	129.371
efrigida_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	6.712
efrigida_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.25
etriacan_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	17.049
etriacan_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.266
thysanoe_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	8445.935
thysanoe_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	305.387
euphaus_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	129.541
euphaus_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2.783
salp_emb_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	113.533
salp_emb_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	24.282
salp_agg_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2551.778
salp_agg_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	6529.877
salp_sol_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	38.485
salp_sol_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	10.526
pantarct_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	219.093
pantarct_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.0
teleoste_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	80.164
teleoste_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	3.161
cnidaria_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	114.092
cnidaria_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	277.894
decopoda_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	24.9
decopoda_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	0.058
other_density (1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	3.835
other_biomass (ml 1000m-3)	!= =~ <= >= = < >		!= =~ <= >= = < >		0.0	2.756

 

Server-side Functions

distinct()

orderBy orderByDescending orderByClosest orderByCount orderByLimit orderByMax orderByMin orderByMinMax orderByMean orderBySum (" time depth latitude longitude end_time lat_end lon_end cruise_tow_number cruise_name event tow_number grid_line grid_station tow_duration heading speed_over_ground wind_speed_start wind_direction net_id tow_type target_depth depth_max volume_filtered siphon_density siphon_biomass ctenoph_density ctenoph_biomass clio_density clio_biomass limacina_density limacina_biomass clion_density clion_biomass pteropod_density pteropod_biomass cephalop_density cephalop_biomass tomopter_density tomopter_biomass polychae_density polychae_biomass pseudosa_density pseudosa_biomass chaetogn_density chaetogn_biomass copepoda_desnity copepoda_biomass ostracod_density ostracod_biomass mysida_density mysida_biomass themisto_density themisto_biomass amphipod_density amphipod_biomass esuperba_density esuperba_biomass ecrystal_density ecrystal_biomass efrigida_density efrigida_biomass etriacan_density etriacan_biomass thysanoe_density thysanoe_biomass euphaus_density euphaus_biomass salp_emb_density salp_emb_biomass salp_agg_density salp_agg_biomass salp_sol_density salp_sol_biomass pantarct_density pantarct_biomass teleoste_density teleoste_biomass cnidaria_density cnidaria_biomass decopoda_density decopoda_biomass other_density other_biomass time depth latitude longitude end_time lat_end lon_end cruise_tow_number cruise_name event tow_number grid_line grid_station tow_duration heading speed_over_ground wind_speed_start wind_direction net_id tow_type target_depth depth_max volume_filtered siphon_density siphon_biomass ctenoph_density ctenoph_biomass clio_density clio_biomass limacina_density limacina_biomass clion_density clion_biomass pteropod_density pteropod_biomass cephalop_density cephalop_biomass tomopter_density tomopter_biomass polychae_density polychae_biomass pseudosa_density pseudosa_biomass chaetogn_density chaetogn_biomass copepoda_desnity copepoda_biomass ostracod_density ostracod_biomass mysida_density mysida_biomass themisto_density themisto_biomass amphipod_density amphipod_biomass esuperba_density esuperba_biomass ecrystal_density ecrystal_biomass efrigida_density efrigida_biomass etriacan_density etriacan_biomass thysanoe_density thysanoe_biomass euphaus_density euphaus_biomass salp_emb_density salp_emb_biomass salp_agg_density salp_agg_biomass salp_sol_density salp_sol_biomass pantarct_density pantarct_biomass teleoste_density teleoste_biomass cnidaria_density cnidaria_biomass decopoda_density decopoda_biomass other_density other_biomass time depth latitude longitude end_time lat_end lon_end cruise_tow_number cruise_name event tow_number grid_line grid_station tow_duration heading speed_over_ground wind_speed_start wind_direction net_id tow_type target_depth depth_max volume_filtered siphon_density siphon_biomass ctenoph_density ctenoph_biomass clio_density clio_biomass limacina_density limacina_biomass clion_density clion_biomass pteropod_density pteropod_biomass cephalop_density cephalop_biomass tomopter_density tomopter_biomass polychae_density polychae_biomass pseudosa_density pseudosa_biomass chaetogn_density chaetogn_biomass copepoda_desnity copepoda_biomass ostracod_density ostracod_biomass mysida_density mysida_biomass themisto_density themisto_biomass amphipod_density amphipod_biomass esuperba_density esuperba_biomass ecrystal_density ecrystal_biomass efrigida_density efrigida_biomass etriacan_density etriacan_biomass thysanoe_density thysanoe_biomass euphaus_density euphaus_biomass salp_emb_density salp_emb_biomass salp_agg_density salp_agg_biomass salp_sol_density salp_sol_biomass pantarct_density pantarct_biomass teleoste_density teleoste_biomass cnidaria_density cnidaria_biomass decopoda_density decopoda_biomass other_density other_biomass time depth latitude longitude end_time lat_end lon_end cruise_tow_number cruise_name event tow_number grid_line grid_station tow_duration heading speed_over_ground wind_speed_start wind_direction net_id tow_type target_depth depth_max volume_filtered siphon_density siphon_biomass ctenoph_density ctenoph_biomass clio_density clio_biomass limacina_density limacina_biomass clion_density clion_biomass pteropod_density pteropod_biomass cephalop_density cephalop_biomass tomopter_density tomopter_biomass polychae_density polychae_biomass pseudosa_density pseudosa_biomass chaetogn_density chaetogn_biomass copepoda_desnity copepoda_biomass ostracod_density ostracod_biomass mysida_density mysida_biomass themisto_density themisto_biomass amphipod_density amphipod_biomass esuperba_density esuperba_biomass ecrystal_density ecrystal_biomass efrigida_density efrigida_biomass etriacan_density etriacan_biomass thysanoe_density thysanoe_biomass euphaus_density euphaus_biomass salp_emb_density salp_emb_biomass salp_agg_density salp_agg_biomass salp_sol_density salp_sol_biomass pantarct_density pantarct_biomass teleoste_density teleoste_biomass cnidaria_density cnidaria_biomass decopoda_density decopoda_biomass other_density other_biomass time depth latitude longitude end_time lat_end lon_end cruise_tow_number cruise_name event tow_number grid_line grid_station tow_duration heading speed_over_ground wind_speed_start wind_direction net_id tow_type target_depth depth_max volume_filtered siphon_density siphon_biomass ctenoph_density ctenoph_biomass clio_density clio_biomass limacina_density limacina_biomass clion_density clion_biomass pteropod_density pteropod_biomass cephalop_density cephalop_biomass tomopter_density tomopter_biomass polychae_density polychae_biomass pseudosa_density pseudosa_biomass chaetogn_density chaetogn_biomass copepoda_desnity copepoda_biomass ostracod_density ostracod_biomass mysida_density mysida_biomass themisto_density themisto_biomass amphipod_density amphipod_biomass esuperba_density esuperba_biomass ecrystal_density ecrystal_biomass efrigida_density efrigida_biomass etriacan_density etriacan_biomass thysanoe_density thysanoe_biomass euphaus_density euphaus_biomass salp_emb_density salp_emb_biomass salp_agg_density salp_agg_biomass salp_sol_density salp_sol_biomass pantarct_density pantarct_biomass teleoste_density teleoste_biomass cnidaria_density cnidaria_biomass decopoda_density decopoda_biomass other_density other_biomass ")

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The Dataset Attribute Structure (.das) for this Dataset

Attributes {
 s {
  time {
    String _CoordinateAxisType "Time";
    Float64 actual_range 7.2656814e+8, 1.20194112e+9;
    String axis "T";
    String calendar "proleptic_gregorian";
    Float64 column_id 4111;
    String column_name "col_4111";
    String comment "Date and time of the start of the net tow";
    String ioos_category "Time";
    String long_name "Start Time";
    String lter_column_description "Greenwich Mean Time, a.k.a UTC";
    String lter_column_name "TimeStart GMT";
    String lter_mscale "dateTime";
    String source_name "start_time";
    String standard_name "time";
    String time_origin "01-JAN-1970 00:00:00";
    String units "seconds since 1970-01-01T00:00:00Z";
  }
  depth {
    String _CoordinateAxisType "Height";
    String _CoordinateZisPositive "down";
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 3709.0;
    String axis "Z";
    Float64 colorBarMaximum 8000.0;
    Float64 colorBarMinimum -8000.0;
    String colorBarPalette "TopographyDepth";
    Float64 column_id 4121;
    String column_name "col_4121";
    String ioos_category "Location";
    String long_name "Depth";
    String lter_column_description "measurement or sample collection distance from water column surface";
    String lter_column_name "WaterDepth";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "m";
    String lter_units_string "meter";
    String positive "down";
    String standard_name "depth";
    String units "m";
    String units_conventions "AND-LTER,BNZ-LTER,CDR-LTER,EML-2.0.1,EML-2.1.0,EML-LTER,LUQ-LTER,SGS-LTER";
  }
  latitude {
    String _CoordinateAxisType "Lat";
    Float64 _FillValue NaN;
    Float64 actual_range -68.752, -63.5731;
    String axis "Y";
    Float64 colorBarMaximum 90.0;
    Float64 colorBarMinimum -90.0;
    Float64 column_id 4113;
    String column_name "col_4113";
    String comment "Latitude at the start of the tow";
    String ioos_category "Location";
    String long_name "Latitude";
    String lter_column_description "latitude measured from the equator in decimal degrees, South is negative";
    String lter_column_name "LatitudeStart";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "º";
    String lter_units_string "degree";
    String source_name "lat_start";
    String standard_name "latitude";
    String units "degrees_north";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  longitude {
    String _CoordinateAxisType "Lon";
    Float64 _FillValue NaN;
    Float64 actual_range -73.9195, -63.7008;
    String axis "X";
    Float64 colorBarMaximum 180.0;
    Float64 colorBarMinimum -180.0;
    Float64 column_id 4114;
    String column_name "col_4114";
    String comment "Longitude at the start of the tow";
    String ioos_category "Location";
    String long_name "Longitude";
    String lter_column_description "longitude measured from the Prime Meridian in decimal degrees, West is negative";
    String lter_column_name "LongitudeStart";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "º";
    String lter_units_string "degree";
    String source_name "lon_start";
    String standard_name "longitude";
    String units "degrees_east";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  end_time {
    Float64 actual_range 7.265376e+8, 1.20194334e+9;
    String calendar "proleptic_gregorian";
    Float64 column_id 4115;
    String column_name "col_4115";
    String ioos_category "Time";
    String long_name "End Time";
    String lter_column_description "Greenwich Mean Time, a.k.a UTC";
    String lter_column_name "TimeEnd GMT";
    String lter_mscale "dateTime";
    String standard_name "time";
    String time_origin "01-JAN-1970 00:00:00";
    String units "seconds since 1970-01-01T00:00:00Z";
  }
  lat_end {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range -68.751, -63.5731;
    Float64 colorBarMaximum 90.0;
    Float64 colorBarMinimum -90.0;
    Float64 column_id 4116;
    String column_name "col_4116";
    String comment "Latitude at the end of the tow";
    String ioos_category "Location";
    String long_name "Latitude";
    String lter_column_description "latitude measured from the equator in decimal degrees, South is negative";
    String lter_column_name "LatitudeEnd";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "º";
    String lter_units_string "degree";
    String standard_name "latitude";
    String units "degrees_north";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  lon_end {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range -73.9468, -57.9869;
    Float64 colorBarMaximum 180.0;
    Float64 colorBarMinimum -180.0;
    Float64 column_id 4117;
    String column_name "col_4117";
    String comment "Longitude at the end of the tow";
    String ioos_category "Location";
    String long_name "Longitude";
    String lter_column_description "longitude measured from the Prime Meridian in decimal degrees, West is negative";
    String lter_column_name "LongitudeEnd";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "º";
    String lter_units_string "degree";
    String standard_name "longitude";
    String units "degrees_east";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  cruise_tow_number {
    Int32 _FillValue 2147483647;
    Int32 actual_range 10006, 160255;
    Float64 colorBarMaximum 100.0;
    Float64 colorBarMinimum 0.0;
    Float64 column_id 4104;
    String column_name "col_4104";
    String ioos_category "Statistics";
    String long_name "Cruise Tow Number";
    String lter_column_description "index number";
    String lter_column_name "CruiseTow";
    String lter_mscale "interval";
    String lter_num_type "integer";
    String lter_units_string "number";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  cruise_name {
    String cf_role "trajectory_id";
    Float64 column_id 4105;
    String column_name "col_4105";
    String ioos_category "Identifier";
    String long_name "Cruise Name";
    String lter_column_description "cruiseName";
    String lter_column_name "CruiseName";
    String lter_mscale "nominal";
  }
  event {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 8.0, 1313.0;
    Float64 column_id 4106;
    String column_name "col_4106";
    String ioos_category "Unknown";
    String long_name "Event";
    String lter_column_description "sequence of cruise happenings ordered by time";
    String lter_column_name "Event";
    String lter_mscale "interval";
    String lter_num_type "real";
    String lter_units_string "number";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  tow_number {
    Float64 _FillValue 9223372036854775807;
    Float64 actual_range 1, 255;
    Float64 colorBarMaximum 100.0;
    Float64 colorBarMinimum 0.0;
    Float64 column_id 4107;
    String column_name "col_4107";
    String ioos_category "Statistics";
    String long_name "Tow Number";
    String lter_column_description "index number";
    String lter_column_name "Tow";
    String lter_mscale "interval";
    String lter_num_type "integer";
    String lter_units_string "number";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  grid_line {
    Int16 _FillValue -32767;
    Int16 actual_range 100, 626;
    Float64 column_id 4108;
    String column_name "col_4108";
    String ioos_category "Unknown";
    String long_name "Grid Line";
    String lter_column_description "line on a pre-defined survey grid in the LTER Palmer study area";
    String lter_column_name "GridLine";
    String lter_mscale "nominal";
  }
  grid_station {
    Int16 _FillValue -32767;
    Int16 actual_range -82, 260;
    Float64 column_id 4109;
    String column_name "col_4109";
    String ioos_category "Unknown";
    String long_name "Grid Station";
    String lter_column_description "Palmer LTER grid station";
    String lter_column_name "Grid Station";
    String lter_mscale "nominal";
  }
  tow_duration {
    Byte _FillValue 127;
    String _Unsigned "false";
    Byte actual_range 0, 85;
    Float64 column_id 4118;
    String column_name "col_4118";
    String ioos_category "Time";
    String long_name "Tow Duration";
    String lter_column_description "Duration in minutes.";
    String lter_column_name "TowDuration";
    String lter_mscale "interval";
    String lter_num_type "real";
    String lter_units "min";
    String lter_units_string "minute";
    String units "minutes";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER,LUQ-LTER,SGS-LTER";
  }
  heading {
    Int16 _FillValue 32767;
    Int16 actual_range 0, 359;
    Float64 column_id 4119;
    String column_name "col_4119";
    String ioos_category "Unknown";
    String long_name "Heading";
    String lter_column_description "direction in degrees";
    String lter_column_name "Heading";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "º";
    String lter_units_string "degree";
    String units "degrees";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  speed_over_ground {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 4.5;
    Float64 column_id 4120;
    String column_name "col_4120";
    String ioos_category "Currents";
    String long_name "Speed Over Ground";
    String lter_column_description "distance travelled per unit of time";
    String lter_column_name "SOG";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units_string "knot";
    String units_conventions "EML-LTER";
  }
  wind_speed_start {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 57.0;
    Float64 colorBarMaximum 15.0;
    Float64 colorBarMinimum 0.0;
    Float64 column_id 4122;
    String column_name "col_4122";
    String ioos_category "Wind";
    String long_name "Wind Speed";
    String lter_column_description "distance travelled per unit of time";
    String lter_column_name "WindSpeed";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units_string "knot";
    String standard_name "wind_speed";
    String units_conventions "EML-LTER";
  }
  wind_direction {
    Int16 _FillValue 32767;
    Int16 actual_range 0, 359;
    Float64 colorBarMaximum 360.0;
    Float64 colorBarMinimum 0.0;
    Float64 column_id 4123;
    String column_name "col_4123";
    String ioos_category "Wind";
    String long_name "Wind From Direction";
    String lter_column_description "direction in degrees";
    String lter_column_name "WindDirection";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "º";
    String lter_units_string "degree";
    String standard_name "wind_from_direction";
    String units "degrees";
    String units_conventions "EML-2.0.1,EML-2.1.0,EML-LTER";
  }
  net_id {
    Byte _FillValue 127;
    String _Unsigned "false";
    Byte actual_range 2, 2;
    Float64 column_id 4124;
    String column_name "col_4124";
    String ioos_category "Identifier";
    String long_name "Net Id";
    String lter_column_description "trawl net size";
    String lter_column_name "NetID";
    String lter_mscale "nominal";
  }
  tow_type {
    Float64 column_id 4125;
    String column_name "col_4125";
    String ioos_category "Unknown";
    String long_name "Tow Type";
    String lter_column_description "Description of a tow that may describe a single characteristic (ie oblique versus vertical tow) or a suite of characteristics represented by a code describing net tow type, depth, size, mesh, etc.";
    String lter_column_name "TowType";
    String lter_mscale "nominal";
  }
  target_depth {
    Float64 _FillValue 9223372036854775807;
    Float64 actual_range 0, 0;
    Float64 colorBarMaximum 8000.0;
    Float64 colorBarMinimum -8000.0;
    String colorBarPalette "TopographyDepth";
    Float64 column_id 4126;
    String column_name "col_4126";
    String ioos_category "Location";
    String long_name "Depth";
    String lter_column_description "depth range of sample collection";
    String lter_column_name "DepthTarget";
    String lter_mscale "nominal";
    String standard_name "depth";
  }
  depth_max {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 690.0;
    Float64 colorBarMaximum 8000.0;
    Float64 colorBarMinimum -8000.0;
    String colorBarPalette "TopographyDepth";
    Float64 column_id 4127;
    String column_name "col_4127";
    String ioos_category "Location";
    String long_name "Depth";
    String lter_column_description "measurement or sample collection distance from water column surface";
    String lter_column_name "DepthMaximum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "m";
    String lter_units_string "meter";
    String standard_name "depth";
    String units "meters";
    String units_conventions "AND-LTER,BNZ-LTER,CDR-LTER,EML-2.0.1,EML-2.1.0,EML-LTER,LUQ-LTER,SGS-LTER";
  }
  volume_filtered {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 2458.0, 28538.0;
    Float64 column_id 4128;
    String column_name "col_4128";
    String ioos_category "Unknown";
    String long_name "Volume Filtered";
    String lter_column_description "seawater";
    String lter_column_name "VolumeFilteredM3";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "m³";
    String lter_units_string "meterCubed";
    String units "m3";
    String units_conventions "EML-LTER";
  }
  siphon_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 7.577;
    Float64 column_id 4129;
    String column_name "col_4129";
    String ioos_category "Physical Oceanography";
    String long_name "Siphon Density";
    String lter_column_description "density";
    String lter_column_name "SiphonNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  siphon_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2.66;
    Float64 column_id 4130;
    String column_name "col_4130";
    String ioos_category "Unknown";
    String long_name "Siphon Biomass";
    String lter_column_description "biomass";
    String lter_column_name "SiphonVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  ctenoph_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 8.176;
    Float64 column_id 4133;
    String column_name "col_4133";
    String ioos_category "Physical Oceanography";
    String long_name "Ctenoph Density";
    String lter_column_description "density";
    String lter_column_name "CtenophNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  ctenoph_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 33.024;
    Float64 column_id 4134;
    String column_name "col_4134";
    String ioos_category "Unknown";
    String long_name "Ctenoph Biomass";
    String lter_column_description "biomass";
    String lter_column_name "CtenophVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  clio_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 5.969;
    Float64 column_id 4135;
    String column_name "col_4135";
    String ioos_category "Physical Oceanography";
    String long_name "Clio Density";
    String lter_column_description "density";
    String lter_column_name "ClioNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  clio_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.208;
    Float64 column_id 4136;
    String column_name "col_4136";
    String ioos_category "Unknown";
    String long_name "Clio Biomass";
    String lter_column_description "biomass";
    String lter_column_name "ClioVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  limacina_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 932.167;
    Float64 column_id 4137;
    String column_name "col_4137";
    String ioos_category "Physical Oceanography";
    String long_name "Limacina Density";
    String lter_column_description "density";
    String lter_column_name "LimacinaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  limacina_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 34.844;
    Float64 column_id 4138;
    String column_name "col_4138";
    String ioos_category "Unknown";
    String long_name "Limacina Biomass";
    String lter_column_description "biomass";
    String lter_column_name "LimacinaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  clion_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 24.831;
    Float64 column_id 4139;
    String column_name "col_4139";
    String ioos_category "Physical Oceanography";
    String long_name "Clion Density";
    String lter_column_description "density";
    String lter_column_name "ClioneNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  clion_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 1.865;
    Float64 column_id 4140;
    String column_name "col_4140";
    String ioos_category "Unknown";
    String long_name "Clion Biomass";
    String lter_column_description "biomass";
    String lter_column_name "ClioneVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  pteropod_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 48.14;
    Float64 column_id 4141;
    String column_name "col_4141";
    String ioos_category "Physical Oceanography";
    String long_name "Pteropod Density";
    String lter_column_description "density";
    String lter_column_name "Pteropod_oNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  pteropod_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 1.747;
    Float64 column_id 4142;
    String column_name "col_4142";
    String ioos_category "Unknown";
    String long_name "Pteropod Biomass";
    String lter_column_description "biomass";
    String lter_column_name "Pteropod_oVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  cephalop_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.411;
    Float64 column_id 4143;
    String column_name "col_4143";
    String ioos_category "Physical Oceanography";
    String long_name "Cephalop Density";
    String lter_column_description "density";
    String lter_column_name "CephalopNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  cephalop_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.13;
    Float64 column_id 4144;
    String column_name "col_4144";
    String ioos_category "Unknown";
    String long_name "Cephalop Biomass";
    String lter_column_description "biomass";
    String lter_column_name "CephalopVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  tomopter_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 18.746;
    Float64 column_id 4145;
    String column_name "col_4145";
    String ioos_category "Physical Oceanography";
    String long_name "Tomopter Density";
    String lter_column_description "density";
    String lter_column_name "TomopterNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  tomopter_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2.261;
    Float64 column_id 4146;
    String column_name "col_4146";
    String ioos_category "Unknown";
    String long_name "Tomopter Biomass";
    String lter_column_description "biomass";
    String lter_column_name "TomopterVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  polychae_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 8.82;
    Float64 column_id 4147;
    String column_name "col_4147";
    String ioos_category "Physical Oceanography";
    String long_name "Polychae Density";
    String lter_column_description "density";
    String lter_column_name "Polychae_oNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  polychae_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 1.8;
    Float64 column_id 4148;
    String column_name "col_4148";
    String ioos_category "Unknown";
    String long_name "Polychae Biomass";
    String lter_column_description "biomass";
    String lter_column_name "Polychae_oVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  pseudosa_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 27.379;
    Float64 column_id 4149;
    String column_name "col_4149";
    String ioos_category "Physical Oceanography";
    String long_name "Pseudosa Density";
    String lter_column_description "density";
    String lter_column_name "PseudosaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  pseudosa_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 5.157;
    Float64 column_id 4150;
    String column_name "col_4150";
    String ioos_category "Unknown";
    String long_name "Pseudosa Biomass";
    String lter_column_description "biomass";
    String lter_column_name "PseudosaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  chaetogn_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 11.384;
    Float64 column_id 4151;
    String column_name "col_4151";
    String ioos_category "Physical Oceanography";
    String long_name "Chaetogn Density";
    String lter_column_description "density";
    String lter_column_name "Chaetogn_oNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  chaetogn_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2.637;
    Float64 column_id 4152;
    String column_name "col_4152";
    String ioos_category "Unknown";
    String long_name "Chaetogn Biomass";
    String lter_column_description "biomass";
    String lter_column_name "Chaetogn_oVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  copepoda_desnity {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.245;
    Float64 column_id 4153;
    String column_name "col_4153";
    String ioos_category "Unknown";
    String long_name "Copepoda Desnity";
    String lter_column_description "density";
    String lter_column_name "CopepodaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  copepoda_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 7.646;
    Float64 column_id 4154;
    String column_name "col_4154";
    String ioos_category "Unknown";
    String long_name "Copepoda Biomass";
    String lter_column_description "biomass";
    String lter_column_name "CopepodaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  ostracod_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.703;
    Float64 column_id 4155;
    String column_name "col_4155";
    String ioos_category "Physical Oceanography";
    String long_name "Ostracod Density";
    String lter_column_description "density";
    String lter_column_name "OstracodNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  ostracod_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.0;
    Float64 column_id 4156;
    String column_name "col_4156";
    String ioos_category "Unknown";
    String long_name "Ostracod Biomass";
    String lter_column_description "biomass";
    String lter_column_name "OstracodVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  mysida_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2.256;
    Float64 column_id 4157;
    String column_name "col_4157";
    String ioos_category "Physical Oceanography";
    String long_name "Mysida Density";
    String lter_column_description "density";
    String lter_column_name "MysidaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  mysida_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.0;
    Float64 column_id 4158;
    String column_name "col_4158";
    String ioos_category "Unknown";
    String long_name "Mysida Biomass";
    String lter_column_description "biomass";
    String lter_column_name "MysidaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  themisto_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 309.615;
    Float64 column_id 4159;
    String column_name "col_4159";
    String ioos_category "Physical Oceanography";
    String long_name "Themisto Density";
    String lter_column_description "density";
    String lter_column_name "ThemistoNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  themisto_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 28.42;
    Float64 column_id 4160;
    String column_name "col_4160";
    String ioos_category "Unknown";
    String long_name "Themisto Biomass";
    String lter_column_description "biomass";
    String lter_column_name "ThemistoVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  amphipod_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 86.999;
    Float64 column_id 4161;
    String column_name "col_4161";
    String ioos_category "Physical Oceanography";
    String long_name "Amphipod Density";
    String lter_column_description "density";
    String lter_column_name "Amphipod_oNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  amphipod_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 6.448;
    Float64 column_id 4162;
    String column_name "col_4162";
    String ioos_category "Unknown";
    String long_name "Amphipod Biomass";
    String lter_column_description "biomass";
    String lter_column_name "Amphipod_oVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  esuperba_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 9900.87;
    Float64 column_id 4163;
    String column_name "col_4163";
    String ioos_category "Physical Oceanography";
    String long_name "Esuperba Density";
    String lter_column_description "density";
    String lter_column_name "EsuperbaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  esuperba_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 4714.7;
    Float64 column_id 4164;
    String column_name "col_4164";
    String ioos_category "Unknown";
    String long_name "Esuperba Biomass";
    String lter_column_description "biomass";
    String lter_column_name "EsuperbaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  ecrystal_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 1067.947;
    Float64 column_id 4165;
    String column_name "col_4165";
    String ioos_category "Physical Oceanography";
    String long_name "Ecrystal Density";
    String lter_column_description "density";
    String lter_column_name "EcrystalNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  ecrystal_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 129.371;
    Float64 column_id 4166;
    String column_name "col_4166";
    String ioos_category "Unknown";
    String long_name "Ecrystal Biomass";
    String lter_column_description "biomass";
    String lter_column_name "EcrystalVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  efrigida_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 6.712;
    Float64 column_id 4167;
    String column_name "col_4167";
    String ioos_category "Physical Oceanography";
    String long_name "Efrigida Density";
    String lter_column_description "density";
    String lter_column_name "EfrigidaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  efrigida_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.25;
    Float64 column_id 4168;
    String column_name "col_4168";
    String ioos_category "Unknown";
    String long_name "Efrigida Biomass";
    String lter_column_description "biomass";
    String lter_column_name "EfrigidaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  etriacan_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 17.049;
    Float64 column_id 4169;
    String column_name "col_4169";
    String ioos_category "Physical Oceanography";
    String long_name "Etriacan Density";
    String lter_column_description "density";
    String lter_column_name "EtriacanNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  etriacan_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.266;
    Float64 column_id 4170;
    String column_name "col_4170";
    String ioos_category "Unknown";
    String long_name "Etriacan Biomass";
    String lter_column_description "biomass";
    String lter_column_name "EtriacanVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  thysanoe_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 8445.935;
    Float64 column_id 4171;
    String column_name "col_4171";
    String ioos_category "Physical Oceanography";
    String long_name "Thysanoe Density";
    String lter_column_description "density";
    String lter_column_name "ThysanoeNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  thysanoe_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 305.387;
    Float64 column_id 4172;
    String column_name "col_4172";
    String ioos_category "Unknown";
    String long_name "Thysanoe Biomass";
    String lter_column_description "biomass";
    String lter_column_name "ThysanoeVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  euphaus_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 129.541;
    Float64 column_id 4173;
    String column_name "col_4173";
    String ioos_category "Physical Oceanography";
    String long_name "Euphaus Density";
    String lter_column_description "density";
    String lter_column_name "Euphaus_oNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  euphaus_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2.783;
    Float64 column_id 4174;
    String column_name "col_4174";
    String ioos_category "Unknown";
    String long_name "Euphaus Biomass";
    String lter_column_description "biomass";
    String lter_column_name "Euphaus_oVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  salp_emb_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 113.533;
    Float64 column_id 4175;
    String column_name "col_4175";
    String ioos_category "Physical Oceanography";
    String long_name "Salp Emb Density";
    String lter_column_description "density";
    String lter_column_name "SalpEmbNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  salp_emb_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 24.282;
    Float64 column_id 4176;
    String column_name "col_4176";
    String ioos_category "Unknown";
    String long_name "Salp Emb Biomass";
    String lter_column_description "biomass";
    String lter_column_name "SalpEmbVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  salp_agg_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2551.778;
    Float64 column_id 4177;
    String column_name "col_4177";
    String ioos_category "Physical Oceanography";
    String long_name "Salp Agg Density";
    String lter_column_description "density";
    String lter_column_name "SalpAggNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  salp_agg_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 6529.877;
    Float64 column_id 4178;
    String column_name "col_4178";
    String ioos_category "Unknown";
    String long_name "Salp Agg Biomass";
    String lter_column_description "biomass";
    String lter_column_name "SalpAggVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  salp_sol_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 38.485;
    Float64 column_id 6263;
    String column_name "col_6263";
    String ioos_category "Physical Oceanography";
    String long_name "Salp Sol Density";
    String lter_column_description "density";
    String lter_column_name "SalpSolNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  salp_sol_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 10.526;
    Float64 column_id 6264;
    String column_name "col_6264";
    String ioos_category "Unknown";
    String long_name "Salp Sol Biomass";
    String lter_column_description "biomass";
    String lter_column_name "SalpSolVol";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  pantarct_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 219.093;
    Float64 column_id 4179;
    String column_name "col_4179";
    String ioos_category "Physical Oceanography";
    String long_name "Pantarct Density";
    String lter_column_description "density";
    String lter_column_name "PantarctNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  pantarct_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.0;
    Float64 column_id 4180;
    String column_name "col_4180";
    String ioos_category "Unknown";
    String long_name "Pantarct Biomass";
    String lter_column_description "biomass";
    String lter_column_name "PantarctVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  teleoste_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 80.164;
    Float64 column_id 4181;
    String column_name "col_4181";
    String ioos_category "Physical Oceanography";
    String long_name "Teleoste Density";
    String lter_column_description "density";
    String lter_column_name "TeleosteNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  teleoste_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 3.161;
    Float64 column_id 4182;
    String column_name "col_4182";
    String ioos_category "Unknown";
    String long_name "Teleoste Biomass";
    String lter_column_description "biomass";
    String lter_column_name "TeleosteVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  cnidaria_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 114.092;
    Float64 column_id 4564;
    String column_name "col_4564";
    String ioos_category "Physical Oceanography";
    String long_name "Cnidaria Density";
    String lter_column_description "density";
    String lter_column_name "Cnidaria_oNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  cnidaria_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 277.894;
    Float64 column_id 4565;
    String column_name "col_4565";
    String ioos_category "Unknown";
    String long_name "Cnidaria Biomass";
    String lter_column_description "biomass";
    String lter_column_name "Cnidaria_oVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  decopoda_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 24.9;
    Float64 column_id 4568;
    String column_name "col_4568";
    String ioos_category "Physical Oceanography";
    String long_name "Decopoda Density";
    String lter_column_description "density";
    String lter_column_name "DecapodaNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  decopoda_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 0.058;
    Float64 column_id 4569;
    String column_name "col_4569";
    String ioos_category "Unknown";
    String long_name "Decopoda Biomass";
    String lter_column_description "biomass";
    String lter_column_name "DecapodaVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
  other_density {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 3.835;
    Float64 column_id 4570;
    String column_name "col_4570";
    String ioos_category "Physical Oceanography";
    String long_name "Other Density";
    String lter_column_description "density";
    String lter_column_name "OtherNum";
    String lter_mscale "ratio";
    String lter_num_type "real";
    String lter_units "num/1000m³";
    String lter_units_string "numberPerThousandMetersCubed";
    String units "1000m-3";
    String units_conventions "CCE-LTER";
  }
  other_biomass {
    Float64 _FillValue 9.969209968386869e+36;
    Float64 actual_range 0.0, 2.756;
    Float64 column_id 4571;
    String column_name "col_4571";
    String ioos_category "Unknown";
    String long_name "Other Biomass";
    String lter_column_description "biomass";
    String lter_column_name "OtherVol";
    String lter_mscale "ratio";
    String lter_num_type "natural";
    String lter_units "ml/1000m3";
    String lter_units_string "milliliterPerThousandCubicMeter";
    String units "ml 1000m-3";
    String units_conventions "CCE-LTER";
  }
 }
  NC_GLOBAL {
    String acknowledgement "Funding and support provided by the National Science Foundation";
    String cdm_data_type "Trajectory";
    String cdm_trajectory_variables "cruise_name";
    String comment "The Palmer, Antarctica, Long-Term Ecological Research project is a member site of the Long-Term Ecological Research program, a network of sites investigating diverse biomes.  A team of researchers seeks to understand the structure and function of the Western Antarctic Peninsula's marine and terrestrial ecosystems in the context of seasonal-to-interannual atmospheric and sea ice dynamics, as well as long-term climate change. The PAL measurement system (or grid) is designed to study marine and terrestrial food webs consisting principally of diatom primary producers, the dominant herbivore Antarctic krill, and the apex predator Adelie penguin. An attenuated microbial food web is also a focus. PAL studies these ecosystems annually over a regional scale grid of oceanographic stations and seasonally at Palmer Station. \\n\\nPalmer Station is located on Anvers Island west of the Antarctic Peninula. The peninsula runs perpendicular to a strong climatic gradient between the cold, dry continental regime to the south, characteristic of the Antarctic interior, and the warm, moist, maritime regime to the north. North-south shifts in the gradient give rise to large environmental variability to climate change. Sea ice extent and variability affects ecosystem changes at all trophic levels.  In addition to the long-term field and research activities, information management, graduate student training,  education and outreach are an integral part of the program.";
    String contributor_email "debbies@vims.edu,robin@icess.ucsb.edu,langdon@icess.ucsb.edu";
    String contributor_name "Debbie Steinberg,Robin Ross,Langdon Quetin";
    String contributor_role "PrincipalInvestigator,PrincipalInvestigator,PrincipalInvestigator";
    String contributor_role_vocabulary "https://vocab.nerc.ac.uk/collection/G04/current/";
    String Conventions "CF-1.8, ACDD-1.3, COARDS";
    String creator_country "USA";
    String creator_email "kerfoot@marine.rutgers.edu";
    String creator_institution "Rutgers University";
    String creator_name "John Kerfoot";
    String creator_sector "academic";
    String creator_type "person";
    String creator_url "https://rucool.marine.rutgers.edu";
    String datazoo_dataset_id "212";
    String datazoo_datatable_id "212";
    String datazoo_datatable_label "Zooplankton Density - Historical";
    String datazoo_datatable_name "ZooplanktonDensityHistorical";
    String date_created "2022-03-03T16:18:30Z";
    String date_issued "2022-03-03T16:18:30Z";
    String defaultDataQuery "null";
    String defaultGraphQuery "longitude%2Clatitude%2Ctime&.draw=markers&.marker=6%7C5&.color=0x000000&.colorBar=%7C%7C%7C%7C%7C&.bgColor=0xffccccff";
    String doi "https://doi.org/10.6073/pasta/03e6d72a78bc2512ef5bb327e686f8fa";
    Float64 Easternmost_Easting -63.7008;
    String featureType "Trajectory";
    String geospatial_bounds_crs "EPSG:4326";
    String geospatial_bounds_vertical_crs "EPSG:5831";
    Float64 geospatial_lat_max -63.5731;
    Float64 geospatial_lat_min -68.752;
    String geospatial_lat_resolution "0.00001 degree";
    String geospatial_lat_units "degrees_north";
    Float64 geospatial_lon_max -63.7008;
    Float64 geospatial_lon_min -73.9195;
    String geospatial_lon_resolution "0.00001 degree";
    String geospatial_lon_units "degrees_east";
    Float64 geospatial_vertical_max 3709.0;
    Float64 geospatial_vertical_min 0.0;
    String geospatial_vertical_positive "down";
    String geospatial_vertical_units "m";
    String history 
"/Users/kerfoot/data/lter/data/tsv/dat_212/dat_212_PD97-01.tsv
2025-05-04T11:01:48Z (local files)
2025-05-04T11:01:48Z http://pallter-data.marine.rutgers.edu/erddap/tabledap/ZooplanktonDensityHistorical.html";
    String infoUrl "https://pal.lternet.edu/";
    String institution "National Science Foundation";
    String keywords "abundance, biomass, density, marine, oceans, Population Studies, Signature, zooplankton";
    String keywords_vocabulary "LTER Controlled Vocabulary,LTER Core Areas";
    String license "All data contained herein is licensed under the LTER Network Data Access Policy (https://lternet.edu/data-access-policy/). In accordance with scientific publishing conventions and professional etiquette, the consumer of these data (the \"Data User\") is expected to appropriately cite these data in any publication that results from their use. The Data User should realize that these data may be actively used by others for ongoing research and that coordination may be necessary to prevent duplicate publication. The Data User is urged to contact the authors of these data if any questions about methodology or results occur and should realize that misinterpretation of data may occur if used out of context of the original study. Where appropriate, the Data User is encouraged to consider collaboration or co-authorship with the data authors. While substantial efforts are made to ensure the accuracy of data and associated documentation, complete accuracy of data sets cannot be guaranteed. All data are made available \"as is.\" The Data User should be aware that data are updated periodically and it is the responsibility of the Data User to check for new versions of the data. The data authors and the repository where these data were obtained shall not be liable for damages resulting from any use or misinterpretation of the data.";
    String license_link "https://lternet.edu/data-access-policy/";
    String methods "General Methods: Zooplankton net tows were conducted at Palmer LTER grid stations.  Tows were double oblique with a 2x2-m square mouth (700-um stretch mesh) Metro net to 120 m.  Abundance (#/1000 m3) and biomass (i.e., biovolume, mL/1000 m3) were determined for dominant macrozooplankton taxa.  Data includes tow location, time, depth, and volume of water filtered by the net.  Samples were preserved in 4% buffered formaldehyde.  Density prefixes:  Siphon = Siphonophorae; Hydrozoa_o = Hydrozoa (other hydrozoa, excluding Siphonophorae); Ctenoph = Ctenophora; Clio = Clio spp. pteropods; Limacina = Limacina helicina; Clione = Clione spp. pteropods; Pteropod_o = Pteropoda (other pteropods, excluding defined taxa); Cephalop = Cephalopoda; Tomopter = Tomopteris spp. polychaetes; Polychae_o = Polychaeta (other polychaetes, excluding Tomopteris); Pseudosa = Pseudosagitta spp. chaetognaths; Chaetogn_o = Sagittoidea (other chaetognaths, excluding Pseudosagitta); Copepoda = Copepoda; Ostracod = Ostracoda; Mysida = Mysida; Themisto = Themisto gaudichaudii;  Amphipod_o = Amphipoda (other amphipods, excluding defined taxa); Esuperba = Euphausia superba; Ecrystal = Euphausia crystallorophias; Efrigida = Euphausia frigida; Etriacan = Euphausia triacantha; Thysanoe = Thysanoessa macrura; Euphaus_o = Euphausiacea (other euphausiids, excluding defined taxa) (mostly immature stages); SalpEmb = Salpa thompsoni embryo stage; SalpAgg = Salpa thompsoni aggregate stage; Pantarct = Pleuragramma antarcticum; Teleoste = Teleostei.  A blank abundance or biovolume value means that the sample was not analyzed for that taxonomic group; a value of -1 means that the taxonomic group was present but not quantified.";
    String naming_authority "edu.rutgers.rucool";
    Float64 Northernmost_Northing -63.5731;
    String product_version "1.0";
    String program "LTER";
    String project "Palmer LTER";
    String publisher_country "USA";
    String publisher_email "kerfoot@marine.rutgers.edu";
    String publisher_institution "Rutgers University";
    String publisher_name "John Kerfoot";
    String publisher_type "person";
    String publisher_url "https://rucool.marine.rutgers.edu";
    String references "https://pal.lternet.edu/";
    String sea_name "Southern Ocean";
    String source "/Users/kerfoot/data/lter/data/tsv/dat_212/dat_212_LMG04-01.tsv";
    String sourceUrl "(local files)";
    Float64 Southernmost_Northing -68.752;
    String standard_name_vocabulary "CF Standard Name Table v77";
    String subsetVariables "cruise_name";
    String summary "Zooplankton collected aboard Palmer Station LTER annual cruises off the western antarctic peninsula, 1993 - 2008. Samples were collected with a 2-m, 700-um net towed from surface to 120 m. This dataset is the historical (1993 - 2008) counterpart to dataset #199, Zooplankton Density - Current. Together these two data sets comprise the full Palmer LTER zooplankton density time series. Please refer to the methods of each dataset for differences between the two.";
    String time_coverage_end "2008-02-02T08:32:00Z";
    String time_coverage_start "1993-01-09T08:29:00Z";
    String title "Zooplankton collected aboard Palmer Station LTER annual cruises off the western antarctic peninsula, 1993, 2008.";
    Float64 Westernmost_Easting -73.9195;
  }
}

 

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Using tabledap to Request Data and Graphs from Tabular Datasets

tabledap lets you request a data subset, a graph, or a map from a tabular dataset (for example, buoy data), via a specially formed URL. tabledap uses the OPeNDAP Data Access Protocol (DAP) and its selection constraints.

The URL specifies what you want: the dataset, a description of the graph or the subset of the data, and the file type for the response.

• (easy) You can get data by using the dataset's Data Access Form or Subset form. They make the URL for you.
• (easy) You can make a graph or map by using the dataset's Make A Graph form. It makes the URL for you.
• (not hard) You can bypass the forms and get the data or make a graph or map by generating the URL by hand or with a computer program or script.

Tabledap request URLs must be in the form
https://coastwatch.pfeg.noaa.gov/erddap/tabledap/datasetID.fileType{?query}
For example,
https://coastwatch.pfeg.noaa.gov/erddap/tabledap/pmelTaoDySst.htmlTable?longitude,latitude,time,station,wmo_platform_code,T_25&time>=2015-05-23T12:00:00Z&time<=2015-05-31T12:00:00Z
Thus, the query is often a comma-separated list of desired variable names, followed by a collection of constraints (e.g., variable<value), each preceded by '&' (which is interpreted as "AND").

For details, see the tabledap Documentation.

 

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