def test_geom_clone(): b = geometry.box(0, 0, 10, 20, epsg4326) assert b == b.clone() assert b.geom is not b.clone().geom assert b == geometry.Geometry(b) assert b.geom is not geometry.Geometry(b).geom
def from_vector(self, vector_data): """Get the geobox to use for the grid. Parameters ---------- vector_data: str or :obj:`geopandas.GeoDataFrame` A file path to an OGR supported source or GeoDataFrame containing the vector data. Returns ------- :obj:`datacube.utils.geometry.GeoBox` The geobox for the grid to be generated from the vector data. """ vector_data = load_vector_data(vector_data) if self.like is not None: assert (self.output_crs is None), "'like' and 'output_crs' are not supported together" assert (self.resolution is None), "'like' and 'resolution' are not supported together" assert self.align is None, "'like' and 'align' are not supported together" try: geobox = self.like.geobox except AttributeError: geobox = geobox_from_rio(self.like) return geobox if self.resolution is None: raise RuntimeError( "Must specify 'resolution' if 'like' not specified.") if self.output_crs: crs = geometry.CRS(self.output_crs) else: crs = geometry.CRS(crs_to_wkt(CRS.from_user_input( vector_data.crs))) if self.geom is None and self.output_crs: geopoly = geometry.Geometry( mapping( box(*vector_data.to_crs( crs._crs.ExportToProj4()).total_bounds)), crs=crs, ) elif self.geom is None: geopoly = geometry.Geometry(mapping( box(*vector_data.total_bounds)), crs=crs) else: geom_json = json.loads(self.geom) geom_crs = geometry.CRS( "+init={}".format(geom_json["crs"]["properties"]["name"].lower( ) if "crs" in geom_json else "epsg:4326")) geopoly = geometry.Geometry(geom_json, crs=geom_crs) return geometry.GeoBox.from_geopolygon(geopoly, self.resolution, crs, self.align)
def test_3d_point_converted_to_2d_point(): point = (-35.5029340, 145.9312455, 0.0) point_3d = {'coordinates': point, 'type': 'Point'} point_2d = {'coordinates': (point[0], point[1]), 'type': 'Point'} p_2d = geometry.Geometry(point_2d) p_3d = geometry.Geometry(point_3d) assert len(p_3d.coords[0]) == 2 assert p_2d == p_3d
def test_lonlat_bounds(): # example from landsat scene: spans lon=180 poly = geometry.box(618300, -1876800, 849000, -1642500, 'EPSG:32660') bb = geometry.lonlat_bounds(poly) assert bb.left < 180 < bb.right assert geometry.lonlat_bounds(poly) == geometry.lonlat_bounds(poly, resolution=1e+8) bb = geometry.lonlat_bounds(poly, mode='quick') assert bb.right - bb.left > 180 poly = geometry.box(1, -10, 2, 20, 'EPSG:4326') assert geometry.lonlat_bounds(poly) == poly.boundingbox with pytest.raises(ValueError): geometry.lonlat_bounds(geometry.box(0, 0, 1, 1, None)) multi = { "type": "MultiPolygon", "coordinates": [ [[[174, 52], [174, 53], [175, 53], [174, 52]]], [[[168, 54], [167, 55], [167, 54], [168, 54]]] ] } multi_geom = geometry.Geometry(multi, "epsg:4326") multi_geom_projected = multi_geom.to_crs('epsg:32659', math.inf) ll_bounds = geometry.lonlat_bounds(multi_geom) ll_bounds_projected = geometry.lonlat_bounds(multi_geom_projected) assert ll_bounds == approx(ll_bounds_projected)
def open_polygon_from_shapefile(shapefile, index_of_polygon_within_shapefile=0): '''This function takes a shapefile, selects a polygon as per your selection, uses the datacube geometry object, along with shapely.geometry and fiona to get the geom for the datacube query. It will also make sure you have the correct crs object for the DEA Last modified: May 2018 Author: Bex Dunn''' # open all the shapes within the shape file shapes = fiona.open(shapefile) i =index_of_polygon_within_shapefile #print('shapefile index is '+str(i)) if i > len(shapes): print('index not in the range for the shapefile'+str(i)+' not in '+str(len(shapes))) sys.exit(0) #copy attributes from shapefile and define shape_name geom_crs = geometry.CRS(shapes.crs_wkt) geo = shapes[i]['geometry'] geom = geometry.Geometry(geo, crs=geom_crs) geom_bs = shapely.geometry.shape(shapes[i]['geometry']) shape_name = shapefile.split('/')[-1].split('.')[0]+'_'+str(i) #print('the name of your shape is '+shape_name) #get your polygon out as a geom to go into the query, and the shape name for file names later return geom, shape_name
def extent(self) -> Optional[geometry.Geometry]: """ :returns: valid extent of the dataset or None """ def xytuple(obj): return obj['x'], obj['y'] # If no projection or crs, they have no extent. projection = self._gs if not projection: return None crs = self.crs if not crs: _LOG.debug("No CRS, assuming no extent (dataset %s)", self.id) return None valid_data = projection.get('valid_data') geo_ref_points = projection.get('geo_ref_points') if valid_data: return geometry.Geometry(valid_data, crs=crs) elif geo_ref_points: return geometry.polygon([ xytuple(geo_ref_points[key]) for key in ('ll', 'ul', 'ur', 'lr', 'll') ], crs=crs) return None
def test_3d_geometry_converted_to_2d_geometry(): coordinates = [(115.8929714190001, -28.577007674999948, 0.0), (115.90275429200005, -28.57698532699993, 0.0), (115.90412631000004, -28.577577566999935, 0.0), (115.90157040700001, -28.58521105999995, 0.0), (115.89382838900008, -28.585473711999953, 0.0), (115.8929714190001, -28.577007674999948, 0.0)] geom_3d = {'coordinates': [coordinates], 'type': 'Polygon'} geom_2d = {'coordinates': [[(x, y) for x, y, z in coordinates]], 'type': 'Polygon'} g_2d = geometry.Geometry(geom_2d) g_3d = geometry.Geometry(geom_3d) assert {2} == set(len(pt) for pt in g_3d.boundary.coords) # All coordinates are 2D assert g_2d == g_3d # 3D geometry has been converted to a 2D by dropping the Z axis
def create_long_SHP_arrays(shape_file, feature_id): feature = feature_from_shapefile(shape_file, feature_id) with fiona.open(shape_file) as shapes: crs = geometry.CRS(shapes.crs_wkt) geom = geometry.Geometry(feature['geometry'], crs=crs) dc = datacube.Datacube() query = { 'time': ('2013-01-01', '2118-12-31'), 'geopolygon': geom, 'output_crs': 'EPSG:3577', 'resampling': 'bilinear', 'group_by': 'solar_day', } sb_names = [ 'nbart_coastal_aerosol', 'nbart_blue', 'nbart_green', 'nbart_red', 'nbart_red_edge_1', 'nbart_red_edge_2', 'nbart_red_edge_3', 'nbart_nir_1', 'nbart_nir_2', 'nbart_swir_2', 'nbart_swir_3', 'fmask' ] s2a_array = dc.load(product='s2a_ard_granule', measurements=sb_names, resolution=(-10, 10), **query) s2b_array = dc.load(product='s2b_ard_granule', measurements=sb_names, resolution=(-10, 10), **query) ls8_array = dc.load(product='ls8_nbart_scene', resolution=(-30, 30), **query) ls8_array = ls8_array.rename({ '1': 'coastal_aerosol', '2': 'blue', '3': 'green', '4': 'red', '5': 'nir', '6': 'swir1', '7': 'swir2' }) lmask = geometry_mask([geom], ls8_array.geobox, invert=True) ls8_array = ls8_array.where(lmask) smask = geometry_mask([geom], s2a_array.geobox, invert=True) s2a_array = s2a_array.where(smask) s2b_array = s2b_array.where(smask) return ls8_array, s2a_array, s2b_array
def _getData(shape, product, crs): dc = datacube.Datacube() dc_crs = datacube.utils.geometry.CRS(crs) g = geometry.Geometry(shape, crs=dc_crs) query = {'geopolygon': g} data = dc.load(product=product, **query) # # mask if polygon # mask = geometry_mask([g], data.geobox, invert=True) # masked = data.where(mask) return data
def main(): with fiona.open('line.shp') as shapes: crs = geometry.CRS(shapes.crs_wkt) first_geometry = next(shapes)['geometry'] line = geometry.Geometry(first_geometry, crs=crs) query = {'time': ('1990-01-01', '1991-01-01'), 'geopolygon': line} dc = datacube.Datacube(app='line-trans-recipe') data = dc.load(product='ls5_nbar_albers', measurements=['red'], **query) trans = transect(data, line, abs(data.affine.a)) trans.red.plot(x='distance', y='time')
def main(): shape_file = 'my_shape_file.shp' with fiona.open(shape_file) as shapes: crs = geometry.CRS(shapes.crs_wkt) first_geometry = next(iter(shapes))['geometry'] geom = geometry.Geometry(first_geometry, crs=crs) query = {'time': ('1990-01-01', '1991-01-01'), 'geopolygon': geom} dc = datacube.Datacube(app='poly-drill-recipe') data = dc.load(product='ls5_nbar_albers', measurements=['red'], **query) mask = geometry_mask([geom], data.geobox, invert=True) data = data.where(mask) data.red.plot.imshow(col='time', col_wrap=5)
def extent(self): """ :rtype: geometry.Geometry """ def xytuple(obj): return obj['x'], obj['y'] projection = self.metadata.grid_spatial if 'valid_data' in projection: return geometry.Geometry(projection['valid_data'], crs=self.crs) else: geo_ref_points = projection['geo_ref_points'] return geometry.polygon([xytuple(geo_ref_points[key]) for key in ('ll', 'ul', 'ur', 'lr', 'll')], crs=self.crs)
def test_props(): crs = epsg4326 box1 = geometry.box(10, 10, 30, 30, crs=crs) assert box1 assert box1.is_valid assert not box1.is_empty assert box1.area == 400.0 assert box1.boundary.length == 80.0 assert box1.centroid == geometry.point(20, 20, crs) triangle = geometry.polygon([(10, 20), (20, 20), (20, 10), (10, 20)], crs=crs) assert triangle.boundingbox == geometry.BoundingBox(10, 10, 20, 20) assert triangle.envelope.contains(triangle) assert box1.length == 80.0 box1copy = geometry.box(10, 10, 30, 30, crs=crs) assert box1 == box1copy assert box1.convex_hull == box1copy # NOTE: this might fail because of point order box2 = geometry.box(20, 10, 40, 30, crs=crs) assert box1 != box2 bbox = geometry.BoundingBox(1, 0, 10, 13) assert bbox.width == 9 assert bbox.height == 13 assert bbox.points == [(1, 0), (1, 13), (10, 0), (10, 13)] assert bbox.transform(Affine.identity()) == bbox assert bbox.transform(Affine.translation(1, 2)) == geometry.BoundingBox( 2, 2, 11, 15) pt = geometry.point(3, 4, crs) assert pt.json['coordinates'] == (3.0, 4.0) assert 'Point' in str(pt) assert bool(pt) is True assert pt.__nonzero__() is True # check "CRS as string is converted to class automatically" assert isinstance(geometry.point(3, 4, 'epsg:3857').crs, geometry.CRS) # constructor with bad input should raise ValueError with pytest.raises(ValueError): geometry.Geometry(object())
def make_long_SHP_query(shape_file): with fiona.open(shape_file) as shapes: crs = geometry.CRS(shapes.crs_wkt) first_geometry = next(iter(shapes))['geometry'] geom = geometry.Geometry(first_geometry, crs=crs) dc = datacube.Datacube() query = { 'time': ('2013-01-01', '2118-12-31'), 'geopolygon': geom, 'output_crs': 'EPSG:3577', 'resampling': 'bilinear', 'group_by': 'solar_day', } return dc, query, geom
def get_data_opensource_shapefile(prod_info, acq_min, acq_max, shapefile, no_partial_scenes): datacube_config = prod_info[0] source_prod = prod_info[1] source_band_list = prod_info[2] mask_band = prod_info[3] if datacube_config != 'default': remotedc = Datacube(config=datacube_config) else: remotedc = Datacube() with warnings.catch_warnings(): warnings.simplefilter("ignore") with fiona.open(shapefile) as shapes: crs = geometry.CRS(shapes.crs_wkt) first_geometry = next(iter(shapes))['geometry'] geom = geometry.Geometry(first_geometry, crs=crs) return_data = {} data = xr.Dataset() if source_prod != '': # get a sample dataset to decide the target epsg fd_query = {'time': (acq_min, acq_max), 'geopolygon': geom} sample_fd_ds = remotedc.find_datasets(product=source_prod, group_by='solar_day', **fd_query) if (len(sample_fd_ds)) > 0: # decidce pixel size for output data pixel_x, pixel_y = get_pixel_size(sample_fd_ds[0], source_band_list) log.info( 'Output pixel size for product {}: x={}, y={}'.format( source_prod, pixel_x, pixel_y)) # get target epsg from metadata target_epsg = get_epsg(sample_fd_ds[0]) log.info('CRS for product {}: {}'.format( source_prod, target_epsg)) query = { 'time': (acq_min, acq_max), 'geopolygon': geom, 'output_crs': target_epsg, 'resolution': (-pixel_y, pixel_x), 'measurements': source_band_list } if 's2' in source_prod: data = remotedc.load(product=source_prod, group_by='solar_day', **query) else: data = remotedc.load(product=source_prod, align=(pixel_x / 2.0, pixel_y / 2.0), group_by='solar_day', **query) # remove cloud and nodta data = remove_cloud_nodata(source_prod, data, mask_band) if data.data_vars: mask = geometry_mask([geom], data.geobox, invert=True) data = data.where(mask) if no_partial_scenes: # calculate valid data percentage data = only_return_whole_scene(data) return_data = { source_prod: { 'data': data, 'mask_band': mask_band, 'find_list': sample_fd_ds } } return return_data
def test_ops(): box1 = geometry.box(10, 10, 30, 30, crs=epsg4326) box2 = geometry.box(20, 10, 40, 30, crs=epsg4326) box3 = geometry.box(20, 10, 40, 30, crs=epsg4326) box4 = geometry.box(40, 10, 60, 30, crs=epsg4326) no_box = None assert box1 != box2 assert box2 == box3 assert box3 != no_box union1 = box1.union(box2) assert union1.area == 600.0 with pytest.raises(geometry.CRSMismatchError): box1.union(box2.to_crs(epsg3857)) inter1 = box1.intersection(box2) assert bool(inter1) assert inter1.area == 200.0 inter2 = box1.intersection(box4) assert not bool(inter2) assert inter2.is_empty # assert not inter2.is_valid TODO: what's going on here? diff1 = box1.difference(box2) assert diff1.area == 200.0 symdiff1 = box1.symmetric_difference(box2) assert symdiff1.area == 400.0 # test segmented line = geometry.line([(0, 0), (0, 5), (10, 5)], epsg4326) line2 = line.segmented(2) assert line.crs is line2.crs assert line.length == line2.length assert len(line.coords) < len(line2.coords) poly = geometry.polygon([(0, 0), (0, 5), (10, 5)], epsg4326) poly2 = poly.segmented(2) assert poly.crs is poly2.crs assert poly.length == poly2.length assert poly.area == poly2.area assert len(poly.geom.exterior.coords) < len(poly2.geom.exterior.coords) poly2 = poly.exterior.segmented(2) assert poly.crs is poly2.crs assert poly.length == poly2.length assert len(poly.geom.exterior.coords) < len(poly2.geom.coords) # test interpolate pt = line.interpolate(1) assert pt.crs is line.crs assert pt.coords[0] == (0, 1) assert isinstance(pt.coords, list) with pytest.raises(TypeError): pt.interpolate(3) # test array interface assert line.__array_interface__ is not None assert np.array(line).shape == (3, 2) # test simplify poly = geometry.polygon([(0, 0), (0, 5), (10, 5)], epsg4326) assert poly.simplify(100) == poly # test iteration poly_2_parts = geometry.Geometry( { "type": "MultiPolygon", "coordinates": [[[[102.0, 2.0], [103.0, 2.0], [103.0, 3.0], [102.0, 3.0], [102.0, 2.0]]], [[[100.0, 0.0], [101.0, 0.0], [101.0, 1.0], [100.0, 1.0], [100.0, 0.0]], [[100.2, 0.2], [100.8, 0.2], [100.8, 0.8], [100.2, 0.8], [100.2, 0.2]]]] }, 'EPSG:4326') pp = list(poly_2_parts) assert len(pp) == 2 assert all(p.crs == poly_2_parts.crs for p in pp) # test transform assert geometry.point( 0, 0, epsg4326).transform(lambda x, y: (x + 1, y + 2)) == geometry.point( 1, 2, epsg4326) # test sides box = geometry.box(1, 2, 11, 22, epsg4326) ll = list(geometry.sides(box)) assert all(l.crs is epsg4326 for l in ll) assert len(ll) == 4 assert ll[0] == geometry.line([(1, 2), (1, 22)], epsg4326) assert ll[1] == geometry.line([(1, 22), (11, 22)], epsg4326) assert ll[2] == geometry.line([(11, 22), (11, 2)], epsg4326) assert ll[3] == geometry.line([(11, 2), (1, 2)], epsg4326)
def get_training_data_for_shp(gdf, index, row, out_arrs, out_vars, products, dc_query, custom_func=None, field=None, calc_indices=None, reduce_func=None, drop=True, zonal_stats=None): """ Function to extract data from the ODC for training a machine learning classifier using a geopandas geodataframe of labelled geometries. This function provides a number of pre-defined methods for producing training data, including calcuating band indices, reducing time series using several summary statistics, and/or generating zonal statistics across polygons. The 'custom_func' parameter provides a method for the user to supply a custom function for generating features rather than using the pre-defined methods. Parameters ---------- gdf : geopandas geodataframe geometry data in the form of a geopandas geodataframe products : list a list of products to load from the datacube. e.g. ['ls8_usgs_sr_scene', 'ls7_usgs_sr_scene'] dc_query : dictionary Datacube query object, should not contain lat and long (x or y) variables as these are supplied by the 'gdf' variable field : string A string containing the name of column with class labels. Field must contain numeric values. out_arrs : list An empty list into which the training data arrays are stored. out_vars : list An empty list into which the data varaible names are stored. custom_func : function, optional A custom function for generating feature layers. If this parameter is set, all other options (excluding 'zonal_stats'), will be ignored. The result of the 'custom_func' must be a single xarray dataset containing 2D coordinates (i.e x, y - no time dimension). The custom function has access to the datacube dataset extracted using the 'dc_query' params, along with access to the 'dc_query' dictionary itself, which could be used to load other products besides those specified under 'products'. calc_indices: list, optional If not using a custom func, then this parameter provides a method for calculating a number of remote sensing indices (e.g. `['NDWI', 'NDVI']`). reduce_func : string, optional Function to reduce the data from multiple time steps to a single timestep. Options are 'mean', 'median', 'std', 'max', 'min', 'geomedian'. Ignored if 'custom_func' is provided. drop : boolean, optional , If this variable is set to True, and 'calc_indices' are supplied, the spectral bands will be dropped from the dataset leaving only the band indices as data variables in the dataset. Default is True. zonal_stats : string, optional An optional string giving the names of zonal statistics to calculate for each polygon. Default is None (all pixel values are returned). Supported values are 'mean', 'median', 'max', 'min', and 'std'. Will work in conjuction with a 'custom_func'. Returns -------- Two lists, a list of numpy.arrays containing classes and extracted data for each pixel or polygon, and another containing the data variable names. """ # prevent function altering dictionary kwargs dc_query = deepcopy(dc_query) # remove dask chunks if supplied as using # mulitprocessing for parallization if 'dask_chunks' in dc_query.keys(): dc_query.pop('dask_chunks', None) # connect to datacube dc = datacube.Datacube(app='training_data') # set up query based on polygon (convert to WGS84) geom = geometry.Geometry(gdf.geometry.values[index].__geo_interface__, geometry.CRS('epsg:4326')) # print(geom) q = {"geopolygon": geom} # merge polygon query with user supplied query params dc_query.update(q) # Identify the most common projection system in the input query output_crs = mostcommon_crs(dc=dc, product=products, query=dc_query) # load_ard doesn't handle geomedians # TODO: Add support for other sensors if 'ga_ls8c_gm_2_annual' in products: ds = dc.load(product='ga_ls8c_gm_2_annual', **dc_query) ds = ds.where(ds != 0, np.nan) else: # load data with HiddenPrints(): ds = load_ard(dc=dc, products=products, output_crs=output_crs, **dc_query) # create polygon mask with HiddenPrints(): mask = xr_rasterize(gdf.iloc[[index]], ds) # mask dataset ds = ds.where(mask) # Use custom function for training data if it exists if custom_func is not None: with HiddenPrints(): data = custom_func(ds) else: # first check enough variables are set to run functions if (len(ds.time.values) > 1) and (reduce_func == None): raise ValueError( "You're dataset has " + str(len(ds.time.values)) + " time-steps, please provide a reduction function," + " e.g. reduce_func='mean'") if calc_indices is not None: # determine which collection is being loaded if 'level2' in products[0]: collection = 'c2' elif 'gm' in products[0]: collection = 'c2' elif 'sr' in products[0]: collection = 'c1' elif 's2' in products[0]: collection = 's2' if len(ds.time.values) > 1: if reduce_func in ['mean', 'median', 'std', 'max', 'min']: with HiddenPrints(): data = calculate_indices(ds, index=calc_indices, drop=drop, collection=collection) # getattr is equivalent to calling data.reduce_func method_to_call = getattr(data, reduce_func) data = method_to_call(dim='time') elif reduce_func == 'geomedian': data = GeoMedian().compute(ds) with HiddenPrints(): data = calculate_indices(data, index=calc_indices, drop=drop, collection=collection) else: raise Exception( reduce_func + " is not one of the supported" + " reduce functions ('mean','median','std','max','min', 'geomedian')" ) else: with HiddenPrints(): data = calculate_indices(ds, index=calc_indices, drop=drop, collection=collection) # when band indices are not required, reduce the # dataset to a 2d array through means or (geo)medians if calc_indices is None: if len(ds.time.values) > 1: if reduce_func == 'geomedian': data = GeoMedian().compute(ds) elif reduce_func in ['mean', 'median', 'std', 'max', 'min']: method_to_call = getattr(ds, reduce_func) data = method_to_call('time') else: data = ds.squeeze() if zonal_stats is None: # If no zonal stats were requested then extract all pixel values flat_train = sklearn_flatten(data) # Make a labelled array of identical size flat_val = np.repeat(row[field], flat_train.shape[0]) stacked = np.hstack((np.expand_dims(flat_val, axis=1), flat_train)) elif zonal_stats in ['mean', 'median', 'std', 'max', 'min']: method_to_call = getattr(data, zonal_stats) flat_train = method_to_call() flat_train = flat_train.to_array() stacked = np.hstack((row[field], flat_train)) else: raise Exception( zonal_stats + " is not one of the supported" + " reduce functions ('mean','median','std','max','min')") # Append training data and labels to list out_arrs.append(stacked) out_vars.append([field] + list(data.data_vars))
train_kfold = REFdata[REFdata['1ha']==1] train_kfold = train_kfold[train_kfold[countCluster]>= Nplots] train_kfold = train_kfold[train_kfold[DV] < maxValueplots] print(f'kfold dataset: {train_kfold.shape}'); ## Generacion de datos de entrenamiento a partir de los conglomerados salidas=[] training_labels_all=[] training_samples_all=np.array([], dtype=np.int64).reshape(0,7) for i in range(len(train_kfold.Cha_HD)): print(f'Running conglom {i+1}') try: a = json.loads(train_kfold.iloc[i]['.geo']) geom = geometry.Geometry(a,crs=CRS('EPSG:4326')) dc = datacube.Datacube(app="Cana") """ ALOS = dc.load( product='ALOS2_PALSAR_MOSAIC', geopolygon=geom, ) ALOS=ALOS.isel(time=0) ALOS """ #for i in range(30): xarr_0 = dc.load( product='LS7_ETM_LEDAPS_MOSAIC', time=("2016-01-01", "2016-12-31"),
def generate_wb_timeseries(shapes, config_dict): """ This is where the code processing is actually done. This code takes in a polygon, and the and a config dict which contains: shapefile's crs, output directory, id_field, time_span, and include_uncertainty which says whether to include all data as well as an invalid pixel count which can be used for measuring uncertainty performs a polygon drill into the wofs_albers product. The resulting xarray, which contains the water classified pixels for that polygon over every available timestep, is used to calculate the percentage of the water body that is wet at each time step. The outputs are written to a csv file named using the polygon UID, which is a geohash of the polygon's centre coords. Inputs: shapes - polygon to be interrogated config_dict - many config settings including crs, id_field, time_span, shapefile Outputs: Nothing is returned from the function, but a csv file is written out to disk """ output_dir = config_dict['output_dir'] crs = config_dict['crs'] id_field = config_dict['id_field'] time_span = config_dict['time_span'] include_uncertainty = config_dict['include_uncertainty'] if include_uncertainty: unknown_percent_threshold = 100 else: unknown_percent_threshold = 10 with Datacube(app='Polygon drill') as dc: first_geometry = shapes['geometry'] str_poly_name = shapes['properties'][id_field] try: fpath = os.path.join(output_dir, f'{str_poly_name[0:4]}/{str_poly_name}.csv') except TypeError: str_poly_name = str(int(str_poly_name)).zfill(6) fpath = os.path.join(output_dir, f'{str_poly_name[0:4]}/{str_poly_name}.csv') geom = geometry.Geometry(first_geometry, crs=crs) current_year = datetime.now().year if time_span == 'ALL': if shapely_geom.shape(first_geometry).envelope.area > 2000000: years = range(1986, current_year + 1, 5) time_periods = [(str(year), str(year + 4)) for year in years] else: time_periods = [('1986', str(current_year))] elif time_span == 'APPEND': start_date = get_last_date(fpath) if start_date is None: print(f'There is no csv for {str_poly_name}') return 1 time_periods = [(start_date, str(current_year))] elif time_span == 'CUSTOM': time_periods = [(config_dict['start_dt'], config_dict['end_date'])] valid_capacity_pc = [] valid_capacity_ct = [] invalid_capacity_ct = [] date_list = [] for time in time_periods: wb_capacity_pc = [] wb_capacity_ct = [] wb_invalid_ct = [] dry_observed = [] invalid_observations = [] # Set up the query, and load in all of the WOFS layers query = {'geopolygon': geom, 'time': time} wofl = dc.load(product='wofs_albers', group_by='solar_day', fuse_func=wofls_fuser, **query) if len(wofl.attrs) == 0: print(f'There is no new data for {str_poly_name}') return 2 # Make a mask based on the polygon (to remove extra data # outside of the polygon) mask = rasterio.features.geometry_mask( [geom.to_crs(wofl.geobox.crs) for geoms in [geom]], out_shape=wofl.geobox.shape, transform=wofl.geobox.affine, all_touched=False, invert=True) # mask the data to the shape of the polygon # the geometry width and height must both be larger than one pixel # to mask. if (geom.boundingbox.width > 25.3 and geom.boundingbox.height > 25.3): wofl_masked = wofl.water.where(mask) else: wofl_masked = wofl.water # Work out how full the waterbody is at every time step for ix, times in enumerate(wofl.time): # Grab the data for our timestep all_the_bit_flags = wofl_masked.isel(time=ix) # Find all the wet/dry pixels for that timestep lsa_wet = all_the_bit_flags.where( all_the_bit_flags == 136).count().item() lsa_dry = all_the_bit_flags.where( all_the_bit_flags == 8).count().item() sea_wet = all_the_bit_flags.where( all_the_bit_flags == 132).count().item() sea_dry = all_the_bit_flags.where( all_the_bit_flags == 4).count().item() sea_lsa_wet = all_the_bit_flags.where( all_the_bit_flags == 140).count().item() sea_lsa_dry = all_the_bit_flags.where( all_the_bit_flags == 12).count().item() wet_pixels = (all_the_bit_flags.where( all_the_bit_flags == 128).count().item() + lsa_wet + sea_wet + sea_lsa_wet) dry_pixels = (all_the_bit_flags.where( all_the_bit_flags == 0).count().item() + lsa_dry + sea_dry + sea_lsa_dry) # Count the number of masked observations masked_all = all_the_bit_flags.count().item() # Turn our counts into percents try: water_percent = round((wet_pixels / masked_all * 100), 1) dry_percent = round((dry_pixels / masked_all * 100), 1) missing_pixels = masked_all - (wet_pixels + dry_pixels) unknown_percent = missing_pixels / masked_all * 100 except ZeroDivisionError: water_percent = 0.0 dry_percent = 0.0 unknown_percent = 100.0 missing_pixels = masked_all print(f'{str_poly_name} has divide by zero error') # Append the percentages to a list for each timestep # Filter out timesteps with < 90% valid observations. Add # empty values for timesteps with < 90% valid. if you set # 'UNCERTAINTY = True' in your config file then you will # only filter out timesteps with 100% invalid pixels. # You will also record the number invalid pixels per timestep. if unknown_percent < unknown_percent_threshold: wb_capacity_pc.append(water_percent) invalid_observations.append(unknown_percent) wb_invalid_ct.append(missing_pixels) dry_observed.append(dry_percent) wb_capacity_ct.append(wet_pixels) else: wb_capacity_pc.append('') invalid_observations.append('') wb_invalid_ct.append('') dry_observed.append('') wb_capacity_ct.append('') valid_obs = wofl.time.dropna(dim='time') valid_obs = valid_obs.to_dataframe() if 'spatial_ref' in valid_obs.columns: valid_obs = valid_obs.drop(columns=['spatial_ref']) valid_capacity_pc += wb_capacity_pc valid_capacity_ct += wb_capacity_ct invalid_capacity_ct += wb_invalid_ct date_list += valid_obs.to_csv( None, header=False, index=False, date_format="%Y-%m-%dT%H:%M:%SZ").split('\n') date_list.pop() if date_list: if include_uncertainty: rows = zip(date_list, valid_capacity_pc, valid_capacity_ct, invalid_capacity_ct) else: rows = zip(date_list, valid_capacity_pc, valid_capacity_ct) os.makedirs(os.path.dirname(fpath), exist_ok=True) if time_span == 'APPEND': with open(fpath, 'a') as f: writer = csv.writer(f) for row in rows: writer.writerow(row) else: with open(fpath, 'w') as f: writer = csv.writer(f) headings = [ 'Observation Date', 'Wet pixel percentage', 'Wet pixel count (n = {0})'.format(masked_all) ] if include_uncertainty: headings.append('Invalid pixel count') writer.writerow(headings) for row in rows: writer.writerow(row) else: print(f'{str_poly_name} has no new good valid data') return True
def get_training_data_for_shp(polygons, out, products, dc_query, field=None, calc_indices=None, reduce_func='median', drop=True, zonal_stats=None, collection='c1'): """ Function to extract data for training a classifier using a shapefile of labelled polygons. Parameters ---------- polygons : geopandas geodataframe polygon data in the form of a geopandas geodataframe out : list Empty list to contain output data. products : list a list of products ot load from the datacube. e.g. ['ls8_usgs_sr_scene', 'ls7_usgs_sr_scene'] dc_query : dictionary Datacube query object, should not contain lat and long (x or y) variables as these are supplied by the 'polygons' variable field : string A string containing name of column with labels in shapefile attribute table. Field must contain numeric values. calc_indices: list, optional An optional list giving the names of any remote sensing indices to be calculated on the loaded data (e.g. `['NDWI', 'NDVI']`. reduce_func : string, optional Function to reduce the data from multiple time steps to a single timestep. Options are 'mean' drop : booleam, optional , 'median', or 'geomedian' If this variable is set to True, and 'calc_indices' are supplied, the spectral bands will be dropped from the dataset leaving only the band indices as data variables in the dataset. Default is False. zonal_stats: string, optional An optional string giving the names of zonal statistics to calculate for the polygon. Default is None (all pixel values). Supported values are 'mean' or 'median' collection: string, optional to calculate band indices, the satellite collection is required. Options include 'c1' for Landsat C1, 'c2' for Landsat C2, and 's2' for Sentinel 2. Returns -------- A list of numpy.arrays containing classes and extracted data for each pixel or polygon. """ #prevent function altering dictionary kwargs dc_query = deepcopy(dc_query) dc = datacube.Datacube(app='training_data') #set up some print statements i = 0 if calc_indices is not None: print("Calculating indices: " + str(calc_indices)) if reduce_func is not None: print("Reducing data using: " + reduce_func) if zonal_stats is not None: print("Taking zonal statistic: " + zonal_stats) # loop through polys and extract training data for index, row in polygons.iterrows(): print(" Feature {:04}/{:04}\r".format(i + 1, len(polygons)), end='') # set up query based on polygon (convert to WGS84) geom = geometry.Geometry(polygons.geometry.values[0].__geo_interface__, geometry.CRS('epsg:4326')) q = {"geopolygon": geom} # merge polygon query with user supplied query params dc_query.update(q) # Identify the most common projection system in the input query output_crs = mostcommon_crs(dc=dc, product=products, query=dc_query) #load_ard doesn't handle geomedians if 'ga_ls8c_gm_2_annual' in products: ds = dc.load(product='ga_ls8c_gm_2_annual', **dc_query) else: # load data with HiddenPrints(): ds = load_ard(dc=dc, products=products, output_crs=output_crs, **dc_query) # create polygon mask mask = rasterio.features.geometry_mask( [geom.to_crs(ds.geobox.crs) for geoms in [geom]], out_shape=ds.geobox.shape, transform=ds.geobox.affine, all_touched=False, invert=False) mask = xr.DataArray(mask, dims=("y", "x")) ds = ds.where(mask == False) # Check if band indices are wanted if calc_indices is not None: if len(ds.time.values) > 1: if reduce_func == 'geomedian': data = GeoMedian().compute(ds) with HiddenPrints(): data = calculate_indices(data, index=calc_indices, drop=drop, collection=collection) elif reduce_func == 'std': with HiddenPrints(): data = calculate_indices(ds, index=calc_indices, drop=drop, collection=collection) data = data.std('time') elif reduce_func == 'mean': with HiddenPrints(): data = calculate_indices(ds, index=calc_indices, drop=drop, collection=collection) data = data.mean('time') elif reduce_func == 'median': with HiddenPrints(): data = calculate_indices(ds, index=calc_indices, drop=drop, collection=collection) data = data.median('time') else: with HiddenPrints(): data = calculate_indices(ds, index=calc_indices, drop=drop, collection=collection) # when band indices are not required, reduce the # dataset to a 2d array through means or (geo)medians if calc_indices is None: if (len(ds.time.values) > 1) and (reduce_func == None): raise ValueError( "You're dataset has " + str(len(ds.time.values)) + "time-steps, please provide a reduction function, e.g. reduce_func='mean'" ) if len(ds.time.values) > 1: if reduce_func == 'geomedian': data = GeoMedian().compute(ds) if reduce_func == 'mean': data = ds.mean('time') if reduce_func == 'std': data = ds.std('time') if reduce_func == 'median': data = ds.median('time') else: data = ds.squeeze() # compute in case we have dask arrays data = data.compute() if zonal_stats is None: # If no summary stats were requested then extract all pixel values flat_train = sklearn_flatten(data) # Make a labelled array of identical size flat_val = np.repeat(row[field], flat_train.shape[0]) stacked = np.hstack((np.expand_dims(flat_val, axis=1), flat_train)) elif zonal_stats == 'mean': flat_train = data.mean(axis=None, skipna=True) flat_train = flat_train.to_array() stacked = np.hstack((row[field], flat_train)) elif zonal_stats == 'median': flat_train = data.median(axis=None, skipna=True) flat_train = flat_train.to_array() stacked = np.hstack((row[field], flat_train)) # Append training data and label to list out.append(stacked) i += 1 # Return a list of labels for columns in output array return [field] + list(data.data_vars)
def rasterize_points( config=None, emission_types={ "Fuel Consumption [kg]": "Fuel", "NOx [kg]": "NOX", "CO2 [kg]": "CO2" }, #resolution=(-0.03, 0.05), #bbox=[-4, 50, 25, 65], ): """ """ if config is None: with open("config.json") as file: config = json.load(file) resolution = config["resolution"] bbox = config["bounding_box"] datapath = os.path.join( os.path.expanduser("~"), config["intermediate_data"], "ship_emissions", ) filepaths = [os.path.join( datapath, i, ) for i in os.listdir(datapath)] filepaths.sort() # path to store data result_data = os.path.join(os.path.expanduser("~"), config["result_data"]) if not os.path.exists(result_data): os.makedirs(result_data) # reproject to geo dataframe right LCC crs = "epsg:4326" # LCC "+proj=lcc +lat_1=30 +lat_2=60 +lat_0=55 +lon_0=10 +y_0=1e+06 +x_0=1275000 +a=6370997 +b=6370997 +units=km +no_defs" bounding_box = box(bbox[0], bbox[1], bbox[2], bbox[3]) json_box = mapping(bounding_box) # minx miny maxx maxy json_box["crs"] = {"properties": {"name": crs}} geopoly = geometry.Geometry( json_box, crs=crs, ) geobox = geometry.GeoBox.from_geopolygon( geopoly, resolution, crs=crs, ) # resolution y,x # geobox.xr_coords() # also get coords as xarrays from geobox coords = affine_to_coords(geobox.affine, geobox.width, geobox.height) for emission_type in emission_types.keys(): emissions_per_day = {} dates = [] for file in filepaths: df = pd.read_csv(file, index_col=[0], parse_dates=True) # , nrows=1000000) geodf = gpd.GeoDataFrame( df, crs="epsg:4326", geometry=gpd.points_from_xy(df.lon, df.lat), ) if "lcc" in crs: geodf = geodf.to_crs(crs) arr = rasterize( zip( geodf.geometry.apply(mapping).values, geodf[emission_type], ), # colums 7 is co2 out_shape=( geobox.height, geobox.width, ), transform=geobox.affine, merge_alg=MergeAlg.add, all_touched=True, ) date = df.index[ 0].dayofyear # df.index.date[0].strftime("%Y-%m-%d") dates.append(date) emissions_per_day[date] = arr da = xr.DataArray( [i for i in emissions_per_day.values()], dims=[ "time", "lat", "lon", ], coords=[ np.array(dates), coords["y"], coords["x"], ], ) da = da.rename("sum") da = da.astype("float64") da.attrs = {"units": "kg d-1"} da.coords["time"].attrs = { "standard_name": "time", "calendar": "proleptic_gregorian", "units": "days since 2015-01-01", "axis": "T", } da.coords["lon"].attrs = { "standard_name": "longnitude", "long_name": "longnitude", "units": "degrees_east", "axis": "X", } da.coords["lat"].attrs = { "standard_name": "latitude", "long_name": "latitude", "units": "degrees_north", "axis": "Y", } da.to_netcdf( os.path.join(result_data, emission_types[emission_type] + ".nc"), # write to shorter file name encoding={ "lat": { "dtype": "float32" }, "lon": { "dtype": "float32" }, "sum": { "dtype": "float32" }, }, )
def WIT_drill(gdf_poly, time, min_gooddata=0.80, TCW_threshold=-6000, export_csv=None, dask_chunks=None): """ The Wetlands Insight Tool. This function loads FC, WOfS, Landsat-ARD, and calculate tasseled cap wetness, in order to determine the dominant land cover class within a polygon at each satellite observation. The output is a pandas dataframe containing a timeseries of the relative fractions of each class at each time-step. This forms the input to produce a stacked line-plot. Last modified: Feb 2020 Parameters ---------- gdf_poly : geopandas.GeoDataFrame The dataframe must only contain a single row, containing the polygon you wish to interrograte. time : tuple a tuple containing the time range over which to run the WIT. e.g. ('2015-01' , '2019-12') min_gooddata : Float, optional A number between 0 and 1 (e.g 0.8) indicating the minimum percentage of good quality pixels required for a satellite observation to be loaded and therefore included in the WIT plot. Defaults to 0.8, which should be considered a minimum percentage. TCW_threshold : Int, optional The tasseled cap wetness threshold, beyond which a pixel will be considered 'wet'. Defaults to -6000. Consider the surface reflectance scaling of the Landsat product when adjusting this (C2 = 1-65,535) export_csv : str, optional To export the returned pandas dataframe provide a location string (e.g. 'output/results.csv') dask_chunks : dict, optional To lazily load the datasets using dask, pass a dictionary containing the dimensions over which to chunk e.g. {'time':-1, 'x':250, 'y':250}. The function is not currently set up to handle dask arrays very well, so memory efficieny using dask will be of limited use here. Returns ------- PolyDrill_df : Pandas.Dataframe A pandas dataframe containing the timeseries of relative fractions of each land cover class (WOfs, FC, TCW) """ print("working on polygon: " + str(gdf_poly.drop('geometry', axis=1).values) + ". ") # make quaery from polygon geom = geometry.Geometry(gdf_poly.geometry.values[0].__geo_interface__, geometry.CRS("epsg:4326")) query = {"geopolygon": geom, "time": time} # set Sandbox configs to load COG's faster datacube.utils.rio.set_default_rio_config(aws="auto", cloud_defaults=True) # Create a datacube instance dc = datacube.Datacube(app="wetlands insight tool") # find UTM crs for location crs = deafrica_datahandling.mostcommon_crs(dc=dc, product="usgs_ls8c_level2_2", query=query) # load landsat 5,7,8 data ls578_ds = deafrica_datahandling.load_ard( dc=dc, products=["usgs_ls8c_level2_2"], output_crs=crs, min_gooddata=min_gooddata, measurements=["red", "green", "blue", "nir", "swir_1", "swir_2"], align=(15, 15), dask_chunks=dask_chunks, group_by='solar_day', resolution=(-30, 30), **query, ) # mask the data with our original polygon to remove extra data data = ls578_ds mask = rasterio.features.geometry_mask( [geom.to_crs(data.geobox.crs) for geoms in [geom]], out_shape=data.geobox.shape, transform=data.geobox.affine, all_touched=False, invert=False, ) # mask the data with the polygon mask_xr = xr.DataArray(mask, dims=("y", "x")) ls578_ds = data.where(mask_xr == False) print("size of wetlands array: " + str(ls578_ds.isel(time=1).red.values.shape)) ls578_ds = ls578_ds.compute() # calculate tasselled cap wetness within masked AOI print("calculating tasseled cap index ") tci = thresholded_tasseled_cap(ls578_ds, wetness_threshold=TCW_threshold, drop=True, drop_tc_bands=True) # select only finite values (over threshold values) tcw = xr.ufuncs.isfinite(tci.wetness_thresholded) # #reapply the polygon mask tcw = tcw.where(mask_xr == False) print("Loading WOfS layers ") wofls = dc.load( product="ga_ls8c_wofs_2", like=ls578_ds, fuse_func=wofs_fuser, dask_chunks=dask_chunks, ) wofls = wofls.where(wofls.time == tcw.time) # #reapply the polygon mask wofls = wofls.where(mask_xr == False) wofls = wofls.compute() wet_wofs = wofls.where(wofls.water == 128) # use bit values for wet (128) and terrain/low-angle (8) shadow_wofs = wofls.where(wofls.water == 136) # bit values for wet (128) and sea (4) sea_wofs = wofls.where(wofls.water == 132) # bit values for wet (128) and sea (4) and terrain/low-angle (8) sea_shadow_wofs = wofls.where(wofls.water == 140) # load Fractional cover print("Loading fractional Cover") # load fractional cover fc_ds = dc.load( product="ga_ls8c_fractional_cover_2", dask_chunks=dask_chunks, like=ls578_ds, measurements=["pv", "npv", "bs"], ) # use landsat data set to cloud mask FC fc_ds = fc_ds.where(ls578_ds.red) # mask with polygon fc_ds = fc_ds.where(mask_xr == False) fc_ds = fc_ds.compute() fc_ds_noTCW = fc_ds.where(tcw == False) print("Generating classification") # match timesteps fc_ds_noTCW = fc_ds_noTCW.where(fc_ds_noTCW.time == tcw.time) # following robbi's advice, cast the dataset to a dataarray maxFC = fc_ds_noTCW.to_array(dim="variable", name="maxFC") # turn FC array into integer only as nanargmax doesn't seem to handle floats the way we want it to FC_int = maxFC.astype("int8") # use numpy.nanargmax to get the index of the maximum value along the variable dimension # BSPVNPV=np.nanargmax(FC_int, axis=0) BSPVNPV = FC_int.argmax(dim="variable") FC_mask = xr.ufuncs.isfinite(maxFC).all(dim="variable") # #re-mask with nans to remove no-data BSPVNPV = BSPVNPV.where(FC_mask) # restack the Fractional cover dataset all together # CAUTION:ARGMAX DEPENDS ON ORDER OF VARIABALES IN # DATASET, THESE WILL BE DIFFERENT FOR DIFFERENT COLLECTIONS. # NEED TO ADJUST 0,1,2 BELOW DEPENDING ON ORDER OF FC VARIABLES # IN THE DATASET. FC_dominant = xr.Dataset({ "BS": (BSPVNPV == 2).where(FC_mask), "PV": (BSPVNPV == 0).where(FC_mask), "NPV": (BSPVNPV == 1).where(FC_mask), }) # count number of Fractional Cover pixels for each cover type in area of interest FC_count = FC_dominant.sum(dim=["x", "y"]) # number of pixels in area of interest pixels = (mask_xr == 0).sum(dim=["x", "y"]) # count number of tcw pixels tcw_pixel_count = tcw.sum(dim=["x", "y"]) # return FC_dominant, FC_mask, BSPVNPV, fc_ds, ls578_ds # number of pixels in area of interest pixels = (mask_xr == 0).sum(dim=["x", "y"]) wofs_pixels = (wet_wofs.water.count(dim=["x", "y"]) + shadow_wofs.water.count(dim=["x", "y"]) + sea_wofs.water.count(dim=["x", "y"]) + sea_shadow_wofs.water.count(dim=["x", "y"])) # count percentage of area of wofs wofs_area_percent = (wofs_pixels / pixels) * 100 # count number of tcw pixels tcw_pixel_count = tcw.sum(dim=["x", "y"]) # calculate percentage area wet tcw_area_percent = (tcw_pixel_count / pixels) * 100 # calculate wet not wofs tcw_less_wofs = tcw_area_percent - wofs_area_percent # Fractional cover pixel count method # Get number of FC pixels, divide by total number of pixels per polygon # Work out the number of nodata pixels in the data, so that we can graph the variables by number of observed pixels. Bare_soil_percent = (FC_count.BS / pixels) * 100 Photosynthetic_veg_percent = (FC_count.PV / pixels) * 100 NonPhotosynthetic_veg_percent = (FC_count.NPV / pixels) * 100 NoData = (100 - wofs_area_percent - tcw_less_wofs - Photosynthetic_veg_percent - NonPhotosynthetic_veg_percent - Bare_soil_percent) NoDataPixels = (NoData / 100) * pixels # Fractional cover pixel count method # Get number of FC pixels, divide by total number of pixels per polygon Bare_soil_percent2 = (FC_count.BS / (pixels - NoDataPixels)) * 100 Photosynthetic_veg_percent2 = (FC_count.PV / (pixels - NoDataPixels)) * 100 NonPhotosynthetic_veg_percent2 = (FC_count.NPV / (pixels - NoDataPixels)) * 100 # count percentage of area of wofs wofs_area_percent2 = (wofs_pixels / (pixels - NoDataPixels)) * 100 # wofs_area_percent wofs_area_percent = (wofs_pixels / pixels) * 100 # count number of tcw pixels tcw_pixel_count2 = tcw.sum(dim=["x", "y"]) # calculate percentage area wet tcw_area_percent2 = (tcw_pixel_count2 / (pixels - NoDataPixels)) * 100 # calculate wet not wofs tcw_less_wofs2 = tcw_area_percent2 - wofs_area_percent2 # last check for timestep matching before we plot wofs_area_percent2 = wofs_area_percent2.where( wofs_area_percent2.time == Bare_soil_percent2.time) Bare_soil_percent2 = Bare_soil_percent2.where( Bare_soil_percent2.time == wofs_area_percent2.time) Photosynthetic_veg_percent2 = Photosynthetic_veg_percent2.where( Photosynthetic_veg_percent2.time == wofs_area_percent2.time) NonPhotosynthetic_veg_percent2 = NonPhotosynthetic_veg_percent2.where( NonPhotosynthetic_veg_percent2.time == wofs_area_percent2.time) # start setup of dataframe by adding only one dataset WOFS_df = pd.DataFrame( data=wofs_area_percent2.data, index=wofs_area_percent2.time.values, columns=["wofs_area_percent"], ) # add data into pandas dataframe for export WOFS_df["wet_percent"] = tcw_less_wofs2.data WOFS_df["green_veg_percent"] = Photosynthetic_veg_percent2.data WOFS_df["dry_veg_percent"] = NonPhotosynthetic_veg_percent2.data WOFS_df["bare_soil_percent"] = Bare_soil_percent2.data # call the composite dataframe something sensible, like PolyDrill PolyDrill_df = WOFS_df.round(2) # save the csv of the output data used to create the stacked plot for the polygon drill if export_csv: print('exporting csv: ' + export_csv) PolyDrill_df.to_csv(export_csv, index_label="Datetime") ls578_ds = None data = None fc_ds = None wofls = None tci = None return PolyDrill_df
def FindOutHowFullTheDamIs(shapes, crs): """ This is where the code processing is actually done. This code takes in a polygon, and the shapefile's crs and performs a polygon drill into the wofs_albers product. The resulting xarray, which contains the water classified pixels for that polygon over every available timestep, is used to calculate the percentage of the water body that is wet at each time step. The outputs are written to a csv file named using the polygon ID. Inputs: shapes - polygon to be interrogated crs - crs of the shapefile Outputs: True or False - False if something unexpected happened, so the function can be run again. a csv file on disk is appended for every valid polygon. """ dc = Datacube(app='Polygon drill') first_geometry = shapes['geometry'] if 'ID' in shapes['properties'].keys(): polyName = shapes['properties']['ID'] else: polyName = shapes['properties']['FID'] strPolyName = str(polyName).zfill(6) fpath = os.path.join(output_dir, f'{strPolyName[0:4]}/{strPolyName}.csv') # start_date = get_last_date(fpath) start_date = '2021-05-01' if start_date is None: time_period = ('2021-03-01', current_time.strftime('%Y-%m-%d')) # print(f'There is no csv for {strPolyName}') # return 1 else: time_period = ('2021-03-01', current_time.strftime('%Y-%m-%d')) geom = geometry.Geometry(first_geometry, crs=crs) ## Set up the query, and load in all of the WOFS layers query = {'geopolygon': geom, 'time': time_period} # WOFL = dc.load(product='wofs_albers', **query) WOFL = dc.load(product='wofs_albers', group_by='solar_day', fuse_func=wofls_fuser, **query) if len(WOFL.attrs) == 0: print(f'There is no new data for {strPolyName}') return 2 # Make a mask based on the polygon (to remove extra data outside of the polygon) mask = rasterio.features.geometry_mask( [geom.to_crs(WOFL.geobox.crs) for geoms in [geom]], out_shape=WOFL.geobox.shape, transform=WOFL.geobox.affine, all_touched=False, invert=True) wofl_masked = WOFL.water.where(mask) ## Work out how full the dam is at every time step DamCapacityPc = [] DamCapacityCt = [] LSA_WetPc = [] DryObserved = [] InvalidObservations = [] for ix, times in enumerate(WOFL.time): # Grab the data for our timestep AllTheBitFlags = wofl_masked.isel(time=ix) # Find all the wet/dry pixels for that timestep LSA_Wet = AllTheBitFlags.where( AllTheBitFlags == 136).count().item() LSA_Dry = AllTheBitFlags.where(AllTheBitFlags == 8).count().item() WetPixels = AllTheBitFlags.where( AllTheBitFlags == 128).count().item() + LSA_Wet DryPixels = AllTheBitFlags.where( AllTheBitFlags == 0).count().item() + LSA_Dry # Apply the mask and count the number of observations MaskedAll = AllTheBitFlags.count().item() # Turn our counts into percents try: WaterPercent = WetPixels / MaskedAll * 100 DryPercent = DryPixels / MaskedAll * 100 UnknownPercent = (MaskedAll - (WetPixels + DryPixels)) / MaskedAll * 100 LSA_WetPercent = LSA_Wet / MaskedAll * 100 except ZeroDivisionError: WaterPercent = 0.0 DryPercent = 0.0 UnknownPercent = 100.0 LSA_WetPercent = 0.0 # Append the percentages to a list for each timestep DamCapacityPc.append(WaterPercent) InvalidObservations.append(UnknownPercent) DryObserved.append(DryPercent) DamCapacityCt.append(WetPixels) LSA_WetPc.append(LSA_WetPercent) ## Filter out timesteps with less than 90% valid observations try: ValidMask = [ i for i, x in enumerate(InvalidObservations) if x < 10 ] if len(ValidMask) > 0: ValidObs = WOFL.time[ValidMask].dropna(dim='time') ValidCapacityPc = [DamCapacityPc[i] for i in ValidMask] ValidCapacityCt = [DamCapacityCt[i] for i in ValidMask] ValidLSApc = [LSA_WetPc[i] for i in ValidMask] ValidObs = ValidObs.to_dataframe() if 'spatial_ref' in ValidObs.columns: ValidObs = ValidObs.drop(columns=['spatial_ref']) DateList = ValidObs.to_csv( None, header=False, index=False, date_format="%Y-%m-%dT%H:%M:%SZ").split('\n') rows = zip(DateList, ValidCapacityPc, ValidCapacityCt, ValidLSApc) if DateList: strPolyName = str(polyName).zfill(6) fpath = os.path.join( output_dir, f'{strPolyName[0:4]}/{strPolyName}.csv') os.makedirs(os.path.dirname(fpath), exist_ok=True) with open(fpath, 'w') as f: writer = csv.writer(f) Headings = [ 'Observation Date', 'Wet pixel percentage', 'Wet pixel count (n = {0})'.format(MaskedAll), 'LSA Wet Pixel Pct' ] writer.writerow(Headings) for row in rows: writer.writerow(row) else: print(f'{polyName} has no new good (90percent) valid data') return 1 except: print(f'This polygon isn\'t working...: {polyName}') return 3
def analyze_parcel(_id, uid, coords, bbox): print("Starting analysis for: " + _id) time_range = ('2020-08-17', '2020-08-31') products = ['s2_l2a'] measurements = ['red', 'green', 'blue', 'nir'] resolution = [-10, 10] output_crs = 'EPSG:31700' attribute_col = 'id' data = { "type": "FeatureCollection", "bbox": bbox, "features": [{ "type": "Feature", "geometry": { "type": "Polygon", "coordinates": [coords] } }] } filename = "/tmp/" + _id + ".geojson" with open(filename, "w") as tmpfile: json.dump(data, tmpfile, ensure_ascii=False, indent=4) gdf = gpd.read_file(filename) gdf['id'] = range(0, len(gdf)) query = { 'time': time_range, 'measurements': measurements, 'resolution': resolution, 'output_crs': output_crs } # Dictionary to save results results = {} # Progress indicator i = 0 # Loop through polygons in geodataframe and extract satellite data for index, row in gdf.iterrows(): print(" Feature {:02}/{:02}\r".format(i + 1, len(gdf)), end='') # Get the geometry geom = geometry.Geometry(row.geometry.__geo_interface__, geometry.CRS(f'EPSG:{gdf.crs.to_epsg()}')) # Update dc query with geometry query.update({'geopolygon': geom}) # Load landsat (hide print statements) ds = load_ard(dc=dc, products=products, group_by='solar_day', **query) # Generate a polygon mask to keep only data within the polygon: mask = xr_rasterize(gdf.iloc[[index]], ds) # Mask dataset to set pixels outside the polygon to `NaN` ds = ds.where(mask) # Append results to a dictionary using the attribute # column as an key results.update({str(row[attribute_col]): ds}) # Update counter i += 1 polygon_result = results['0'] ndvi = calculate_indices(results['0'], index='NDVI', collection='c1') ndwi = calculate_indices(results['0'], index='NDWI', collection='c1') savi = calculate_indices(results['0'], index='SAVI', collection='c1') ndvi_result = ndvi.NDVI.values ndwi_result = ndwi.NDWI.values savi_result = savi.SAVI.values t, h, w = ndvi_result.shape for timestep in range(0, t): ndvi_img = Image.fromarray( np.uint8(cm.get_cmap("YlGn")(ndvi_result[timestep]) * 255)) filename = _id + timestep.__str__() + ".ndvi.png" ndvi_img.save(filename) bucket = 'ceres-analyzed-data' upload_file(filename, bucket) link = 'https://ceres-analyzed-data.s3.eu-central-1.amazonaws.com/' + filename date = '2020-08-15' payload = {"date": date, "link": link} url = 'http://parcel-manager-server:8080/parcels/' + uid.__str__( ) + '/' + _id.__str__() requests.patch(url, json=payload)
def init_polygon(self): crs = self.crs crs = geometry.CRS(crs) first_geometry = {'type': 'Polygon', 'coordinates': eval(self.poly)} geom = geometry.Geometry(first_geometry, crs=crs) return geom
def interval_uncertainty(polygon_id, item_polygon_path, products=('ls5_pq_albers', 'ls7_pq_albers', 'ls8_pq_albers'), time_period=('1986-01-01', '2017-01-01')): """ This function uses the Digital Earth Australia archive to compute the standard deviation of tide heights for all Landsat observations that were used to generate the ITEM 2.0 composite layers and resulting tidal intervals. These standard deviations (one for each ITEM 2.0 interval) quantify the 'uncertainty' of each NIDEM elevation estimate: larger values indicate the ITEM interval was produced from a composite of images with a larger range of tide heights. Last modified: September 2018 Author: Robbi Bishop-Taylor :param polygon_id: An integer giving the polygon ID of the desired ITEM v2.0 polygon to analyse. :param item_polygon_path: A string giving the path to the ITEM v2.0 polygon shapefile. :param products: An optional tuple of DEA Landsat product names used to calculate tide heights of all observations used to generate ITEM v2.0 tidal intervals. Defaults to ('ls5_pq_albers', 'ls7_pq_albers', 'ls8_pq_albers'), which loads Landsat 5, Landsat 7 and Landsat 8. :param time_period: An optional tuple giving the start and end date to analyse. Defaults to ('1986-01-01', '2017-01-01'), which analyses all Landsat observations from the start of 1986 to the end of 2016. :return: An array of shape (9,) giving the standard deviation of tidal heights for all Landsat observations used to produce each ITEM interval. """ # Import tidal model data and extract geom and tide post item_gpd = gpd.read_file(item_polygon_path) lat, lon, poly = item_gpd[item_gpd.ID == int(polygon_id)][['lat', 'lon', 'geometry']].values[0] geom = geometry.Geometry(mapping(poly), crs=geometry.CRS(item_gpd.crs['init'])) all_times_obs = list() # For each product: for source in products: # Use entire time range unless LS7 time_range = ('1986-01-01', '2003-05-01') if source == 'ls7_pq_albers' else time_period # Determine matching datasets for geom area and group into solar day ds = dc.find_datasets(product=source, time=time_range, geopolygon=geom) group_by = query_group_by(group_by='solar_day') sources = dc.group_datasets(ds, group_by) # If data is found, add time to list then sort if len(ds) > 0: all_times_obs.extend(sources.time.data.astype('M8[s]').astype('O').tolist()) # Calculate tide data from X-Y-time location all_times_obs = sorted(all_times_obs) tp_obs = [TimePoint(float(lon), float(lat), dt) for dt in all_times_obs] tides_obs = [tide.tide_m for tide in predict_tide(tp_obs)] # Covert to dataframe of observed dates and tidal heights df1_obs = pd.DataFrame({'Tide_height': tides_obs}, index=pd.DatetimeIndex(all_times_obs)) ################## # ITEM intervals # ################## # Compute percentage tide height min_height = df1_obs.Tide_height.min() max_height = df1_obs.Tide_height.max() observed_range = max_height - min_height # Create dict of percentile values per10_dict = {perc + 1: min_height + observed_range * perc * 0.1 for perc in range(0, 10, 1)} # Bin each observation into an interval df1_obs['interval'] = pd.cut(df1_obs.Tide_height, bins=list(per10_dict.values()), labels=list(per10_dict.keys())[:-1]) return df1_obs.groupby('interval').std().values.flatten()
print("Loading data...") if(tile): grd_path = args.gridfile grd = gpd.read_file(grd_path) dc = datacube.Datacube() curr_poly = grd.where(grd.id == tile).dropna().iloc[0].geometry json_poly = json.loads(gpd.GeoSeries([curr_poly]).to_json()) dc_geom = geometry.Geometry(json_poly['features'][0]['geometry'], geometry.CRS("EPSG:{}".format(args.epsg))) ds = getDataset(('1988-01-01', '2020-12-31'), dc_geom, args.epsg) dc.close() else: ds = xr.open_dataset(args.infile) print("Setting up variables and output files...") bands = list(ds.data_vars) # Change threshold based on chi square distribution ch_thresh = chi2.ppf(0.99, df=len(bands))