ucar.nc2.constants.CF Maven / Gradle / Ivy
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package ucar.nc2.constants;
import ucar.nc2.NetcdfFile;
/**
* Constants used in CF Conventions.
*
* @author caron
* @since Jan 21, 2009
*/
public interface CF {
// attribute names
public static final String AXIS = "axis";
public static final String BOUNDS = "bounds";
public static final String CALENDAR = "calendar";
public static final String CELL_METHODS = "cell_methods";
public static final String CF_ROLE = "cf_role";
public final static String COORDINATES = "coordinates";
public static final String FEATURE_TYPE = "featureType";
public static final String POSITIVE = "positive";
public static final String STANDARD_NAME = "standard_name";
public static final String FORMULA_TERMS = "formula_terms";
// positive values
public final static String POSITIVE_UP = "up";
public final static String POSITIVE_DOWN = "down";
// grid mapping names
public final static String ALBERS_CONICAL_EQUAL_AREA = "albers_conical_equal_area";
public final static String AZIMUTHAL_EQUIDISTANT = "azimuthal_equidistant";
public final static String LAMBERT_AZIMUTHAL_EQUAL_AREA = "lambert_azimuthal_equal_area";
public final static String LAMBERT_CONFORMAL_CONIC = "lambert_conformal_conic";
public final static String LAMBERT_CYLINDRICAL_EQUAL_AREA = "lambert_cylindrical_equal_area";
public final static String LATITUDE_LONGITUDE = "latitude_longitude";
public final static String MERCATOR = "mercator";
public final static String ORTHOGRAPHIC = "orthographic";
public final static String POLAR_STEREOGRAPHIC = "polar_stereographic";
public final static String ROTATED_LATITUDE_LONGITUDE = "rotated_latitude_longitude";
public final static String STEREOGRAPHIC = "stereographic";
public final static String SINUSOIDAL = "sinusoidal"; // NOY
public final static String TRANSVERSE_MERCATOR = "transverse_mercator";
public final static String VERTICAL_PERSPECTIVE = "vertical_perspective";
// for grid_mappings
public final static String EARTH_RADIUS = "earth_radius";
public static final String FALSE_EASTING = "false_easting";
public static final String FALSE_NORTHING = "false_northing";
public static final String GRID_MAPPING = "grid_mapping";
public static final String FIXED_ANGLE_AXIS = "fixed_angle_axis"; // geostationary
public static final String GRID_MAPPING_NAME = "grid_mapping_name";
public static final String GRID_NORTH_POLE_LATITUDE = "grid_north_pole_latitude";
public static final String GRID_NORTH_POLE_LONGITUDE = "grid_north_pole_longitude";
public static final String INVERSE_FLATTENING = "inverse_flattening";
public static final String LATITUDE_OF_PROJECTION_ORIGIN = "latitude_of_projection_origin";
public static final String LONGITUDE_OF_PROJECTION_ORIGIN = "longitude_of_projection_origin";
public static final String LATITUDE_OF_PRIME_MERIDIAN = "latitude_of_prime_meridian";
public static final String LONGITUDE_OF_PRIME_MERIDIAN = "longitude_of_prime_meridian";
public static final String LONGITUDE_OF_CENTRAL_MERIDIAN = "longitude_of_central_meridian";
public static final String NORTH_POLE_GRID_LONGITUDE = "north_pole_grid_longitude";
public static final String PERSPECTIVE_POINT_HEIGHT = "perspective_point_height"; // geostationary
public static final String SCALE_FACTOR_AT_CENTRAL_MERIDIAN = "scale_factor_at_central_meridian";
public static final String SCALE_FACTOR_AT_PROJECTION_ORIGIN = "scale_factor_at_projection_origin";
public static final String SEMI_MAJOR_AXIS = "semi_major_axis";
public static final String SEMI_MINOR_AXIS = "semi_minor_axis";
public static final String SWEEP_ANGLE_AXIS = "sweep_angle_axis"; // geostationary
public static final String STANDARD_PARALLEL = "standard_parallel";
public static final String STRAIGHT_VERTICAL_LONGITUDE_FROM_POLE = "straight_vertical_longitude_from_pole";
// standard_names
public static final String TIME = "time"; // valid; time, obs time
public static final String TIME_REFERENCE = "forecast_reference_time"; // the "data time", the time of the analysis from which the forecast was made.
public static final String PROJECTION_X_COORDINATE = "projection_x_coordinate";
public static final String PROJECTION_Y_COORDINATE = "projection_y_coordinate";
// cf_role
public static final String PROFILE_ID = "profile_id";
public static final String TIMESERIES_ID = "timeseries_id"; // alias STATION_ID
public static final String TRAJECTORY_ID = "trajectory_id";
// DSG
public static final String SAMPLE_DIMENSION = "sample_dimension";
public static final String INSTANCE_DIMENSION = "instance_dimension";
public static final String PLATFORM_NAME = "platform_name"; // instead of STATION_DESC
public static final String SURFACE_ALTITUDE = "surface_altitude"; // alias STATION_ALTITUDE
public static final String PLATFORM_ID = "platform_id"; // alias STATION_WMOID
///////////////////////////////////////////////////////////////////
// DSG proposed - not adopted; here for backwards compatibility
public static final String RAGGED_ROWSIZE = "CF:ragged_row_count";
public static final String RAGGED_PARENTINDEX = "CF:ragged_parent_index";
// proposed standard_names
public static final String STATION_ID = "station_id";
public static final String STATION_DESC = "station_description";
public static final String STATION_ALTITUDE = "station_altitude";
public static final String STATION_WMOID = "station_WMO_id";
public static final String featureTypeAtt2 = "CF:featureType";
public static final String featureTypeAtt3 = "CF:feature_type"; // GRIB was using this form (!)
///////////////////////////////////////////////////////////////////////
/**
* Map from CF feature type names to our FeatureType enums.
*/
public enum FeatureType {
point, timeSeries, profile, trajectory, timeSeriesProfile, trajectoryProfile;
public static FeatureType convert(ucar.nc2.constants.FeatureType ft) {
switch (ft) {
case POINT:
return CF.FeatureType.point;
case STATION:
return CF.FeatureType.timeSeries;
case PROFILE:
return CF.FeatureType.profile;
case TRAJECTORY:
return CF.FeatureType.trajectory;
case STATION_PROFILE:
return CF.FeatureType.timeSeriesProfile;
case SECTION:
return CF.FeatureType.trajectoryProfile;
}
return null;
}
public static ucar.nc2.constants.FeatureType convert(FeatureType cff) {
switch (cff) {
case point:
return ucar.nc2.constants.FeatureType.POINT;
case timeSeries:
return ucar.nc2.constants.FeatureType.STATION;
case profile:
return ucar.nc2.constants.FeatureType.PROFILE;
case trajectory:
return ucar.nc2.constants.FeatureType.TRAJECTORY;
case timeSeriesProfile:
return ucar.nc2.constants.FeatureType.STATION_PROFILE;
case trajectoryProfile:
return ucar.nc2.constants.FeatureType.SECTION;
}
return null;
}
/*
1) The CF discrete sampling proposal will be the recommended one for point data when thats finalized. Unfortunately, it will be
somewhat different from whats gone before. The CF: prefix is dropped until the namespace proposal can be completed.
So those feature types are now proposed to be:
* point: one or more parameters measured at a set of points in time and space
* timeSeries: a time-series of data points at the same location, with varying time
* trajectory: a connected set of data points along a 1D curve in time and space
* profile: a set of data points along a vertical line
* timeSeriesProfile: a time-series of profiles at a named location
* trajectoryProfile: a collection of profiles which originate along a trajectory
The CDM will be backwards compatible, including:
* accepting the CF: prefix
* being case insensitive
* "station" and "stationTimeSeries"as aliases for "timeSeries"
* "stationProfile" as alias for "timeSeriesProfile"
* "section" as alias for "trajectoryProfile"
I know that CF wants to standardize on other feature types also. Its hard to anticipate what they will come with, but its likely:
* grid
* swath
maybe:
* image
* radial
* unstructuredGrid
*/
public static FeatureType getFeatureType(String s) {
if (s.equalsIgnoreCase("point")) return FeatureType.point;
if (s.equalsIgnoreCase("timeSeries")) return FeatureType.timeSeries;
if (s.equalsIgnoreCase("stationTimeSeries")) return FeatureType.timeSeries;
if (s.equalsIgnoreCase("station")) return FeatureType.timeSeries;
if (s.equalsIgnoreCase("profile")) return FeatureType.profile;
if (s.equalsIgnoreCase("trajectory")) return FeatureType.trajectory;
if (s.equalsIgnoreCase("timeSeriesProfile")) return FeatureType.timeSeriesProfile;
if (s.equalsIgnoreCase("stationProfile")) return FeatureType.timeSeriesProfile;
if (s.equalsIgnoreCase("stationProfileTimeSeries")) return FeatureType.timeSeriesProfile;
if (s.equalsIgnoreCase("trajectoryProfile")) return FeatureType.trajectoryProfile;
if (s.equalsIgnoreCase("section")) return FeatureType.trajectoryProfile;
return null;
}
public static FeatureType getFeatureTypeFromGlobalAttribute(NetcdfFile ds) {
String ftypeS = ds.findAttValueIgnoreCase(null, CF.FEATURE_TYPE, null);
if (ftypeS == null)
ftypeS = ds.findAttValueIgnoreCase(null, CF.featureTypeAtt2, null);
if (ftypeS == null)
ftypeS = ds.findAttValueIgnoreCase(null, CF.featureTypeAtt3, null);
if (ftypeS == null)
return null;
return CF.FeatureType.getFeatureType(ftypeS);
}
}
// http://cf-pcmdi.llnl.gov/documents/cf-conventions/1.6/cf-conventions.html#appendix-cell-methods
public enum CellMethods {
point, sum, maximum, median, mid_range, minimum, mean, mode, standard_deviation, variance;
// deprecated
public static CellMethods convertGribCodeTable4_10(int code) {
switch (code) {
case 0:
return CellMethods.mean; // "Average";
case 1:
return CellMethods.sum; // "Accumulation";
case 2:
return CellMethods.maximum; // "Maximum";
case 3:
return CellMethods.minimum; // "Minimum";
//case 4: return "Difference"; // (Value at the end of time range minus value at the beginning)";
//case 5: return "RootMeanSquare";
case 6:
return CellMethods.standard_deviation; // "StandardDeviation";
case 7:
return CellMethods.variance; // "Covariance"; // (Temporal variance)";
//case 8: return "Difference"; // (Value at the start of time range minus value at the end)";
//case 9: return "Ratio";
default:
return null;
}
}
}
}
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