"""This module contains all the functions needed for extracting satellite-derived shorelines (SDS) Author: Kilian Vos, Water Research Laboratory, University of New South Wales """ # load modules import os import numpy as np import matplotlib.pyplot as plt import pdb # image processing modules import skimage.filters as filters import skimage.exposure as exposure import skimage.transform as transform import sklearn.decomposition as decomposition import skimage.measure as measure import skimage.morphology as morphology # machine learning modules from sklearn.externals import joblib from shapely.geometry import LineString # other modules from osgeo import gdal, ogr, osr import scipy.interpolate as interpolate from datetime import datetime, timedelta import matplotlib.patches as mpatches import matplotlib.lines as mlines import matplotlib.cm as cm from matplotlib import gridspec from pylab import ginput import pickle # own modules import SDS_tools, SDS_preprocess np.seterr(all='ignore') # raise/ignore divisions by 0 and nans def nd_index(im1, im2, cloud_mask): """ Computes normalised difference index on 2 images (2D), given a cloud mask (2D). KV WRL 2018 Arguments: ----------- im1, im2: np.array Images (2D) with which to calculate the ND index cloud_mask: np.array 2D cloud mask with True where cloud pixels are Returns: ----------- im_nd: np.array Image (2D) containing the ND index """ # reshape the cloud mask vec_mask = cloud_mask.reshape(im1.shape[0] * im1.shape[1]) # initialise with NaNs vec_nd = np.ones(len(vec_mask)) * np.nan # reshape the two images vec1 = im1.reshape(im1.shape[0] * im1.shape[1]) vec2 = im2.reshape(im2.shape[0] * im2.shape[1]) # compute the normalised difference index temp = np.divide(vec1[~vec_mask] - vec2[~vec_mask], vec1[~vec_mask] + vec2[~vec_mask]) vec_nd[~vec_mask] = temp # reshape into image im_nd = vec_nd.reshape(im1.shape[0], im1.shape[1]) return im_nd def calculate_features(im_ms, cloud_mask, im_bool): """ Calculates a range of features on the image that are used for the supervised classification. The features include spectral normalized-difference indices and standard deviation of the image. KV WRL 2018 Arguments: ----------- im_ms: np.array RGB + downsampled NIR and SWIR cloud_mask: np.array 2D cloud mask with True where cloud pixels are im_bool: np.array 2D array of boolean indicating where on the image to calculate the features Returns: ----------- features: np.array matrix containing each feature (columns) calculated for all the pixels (rows) indicated in im_bool """ # add all the multispectral bands features = np.expand_dims(im_ms[im_bool,0],axis=1) for k in range(1,im_ms.shape[2]): feature = np.expand_dims(im_ms[im_bool,k],axis=1) features = np.append(features, feature, axis=-1) # NIR-G im_NIRG = nd_index(im_ms[:,:,3], im_ms[:,:,1], cloud_mask) features = np.append(features, np.expand_dims(im_NIRG[im_bool],axis=1), axis=-1) # SWIR-G im_SWIRG = nd_index(im_ms[:,:,4], im_ms[:,:,1], cloud_mask) features = np.append(features, np.expand_dims(im_SWIRG[im_bool],axis=1), axis=-1) # NIR-R im_NIRR = nd_index(im_ms[:,:,3], im_ms[:,:,2], cloud_mask) features = np.append(features, np.expand_dims(im_NIRR[im_bool],axis=1), axis=-1) # SWIR-NIR im_SWIRNIR = nd_index(im_ms[:,:,4], im_ms[:,:,3], cloud_mask) features = np.append(features, np.expand_dims(im_SWIRNIR[im_bool],axis=1), axis=-1) # B-R im_BR = nd_index(im_ms[:,:,0], im_ms[:,:,2], cloud_mask) features = np.append(features, np.expand_dims(im_BR[im_bool],axis=1), axis=-1) # calculate standard deviation of individual bands for k in range(im_ms.shape[2]): im_std = SDS_tools.image_std(im_ms[:,:,k], 1) features = np.append(features, np.expand_dims(im_std[im_bool],axis=1), axis=-1) # calculate standard deviation of the spectral indices im_std = SDS_tools.image_std(im_NIRG, 1) features = np.append(features, np.expand_dims(im_std[im_bool],axis=1), axis=-1) im_std = SDS_tools.image_std(im_SWIRG, 1) features = np.append(features, np.expand_dims(im_std[im_bool],axis=1), axis=-1) im_std = SDS_tools.image_std(im_NIRR, 1) features = np.append(features, np.expand_dims(im_std[im_bool],axis=1), axis=-1) im_std = SDS_tools.image_std(im_SWIRNIR, 1) features = np.append(features, np.expand_dims(im_std[im_bool],axis=1), axis=-1) im_std = SDS_tools.image_std(im_BR, 1) features = np.append(features, np.expand_dims(im_std[im_bool],axis=1), axis=-1) return features def classify_image_NN(im_ms, im_extra, cloud_mask, min_beach_size, satname): """ Classifies every pixel in the image in one of 4 classes: - sand --> label = 1 - whitewater (breaking waves and swash) --> label = 2 - water --> label = 3 - other (vegetation, buildings, rocks...) --> label = 0 The classifier is a Neural Network, trained on several sites in New South Wales, Australia. KV WRL 2018 Arguments: ----------- im_ms: np.array Pansharpened RGB + downsampled NIR and SWIR im_extra: only used for Landsat 7 and 8 where im_extra is the panchromatic band cloud_mask: np.array 2D cloud mask with True where cloud pixels are min_beach_size: int minimum number of pixels that have to be connected in the SAND class Returns: ----------- im_classif: np.array 2D image containing labels im_labels: np.array of booleans 3D image containing a boolean image for each class (im_classif == label) """ if satname == 'L5': # load classifier (without panchromatic band) clf = joblib.load(os.path.join(os.getcwd(), 'classifiers', 'NN_4classes_nopan.pkl')) # calculate features n_features = 9 im_features = np.zeros((im_ms.shape[0], im_ms.shape[1], n_features)) im_features[:,:,[0,1,2,3,4]] = im_ms im_features[:,:,5] = nd_index(im_ms[:,:,3], im_ms[:,:,1], cloud_mask) # (NIR-G) im_features[:,:,6] = nd_index(im_ms[:,:,3], im_ms[:,:,2], cloud_mask) # ND(NIR-R) im_features[:,:,7] = nd_index(im_ms[:,:,0], im_ms[:,:,2], cloud_mask) # ND(B-R) im_features[:,:,8] = nd_index(im_ms[:,:,4], im_ms[:,:,1], cloud_mask) # ND(SWIR-G) vec_features = im_features.reshape((im_ms.shape[0] * im_ms.shape[1], n_features)) elif satname in ['L7','L8']: # load classifier (with panchromatic band) clf = joblib.load(os.path.join(os.getcwd(), 'classifiers', 'NN_4classes_withpan.pkl')) # calculate features n_features = 10 im_features = np.zeros((im_ms.shape[0], im_ms.shape[1], n_features)) im_features[:,:,[0,1,2,3,4]] = im_ms im_features[:,:,5] = im_extra im_features[:,:,6] = nd_index(im_ms[:,:,3], im_ms[:,:,1], cloud_mask) # (NIR-G) im_features[:,:,7] = nd_index(im_ms[:,:,3], im_ms[:,:,2], cloud_mask) # ND(NIR-R) im_features[:,:,8] = nd_index(im_ms[:,:,0], im_ms[:,:,2], cloud_mask) # ND(B-R) im_features[:,:,9] = nd_index(im_ms[:,:,4], im_ms[:,:,1], cloud_mask) # ND(SWIR-G) vec_features = im_features.reshape((im_ms.shape[0] * im_ms.shape[1], n_features)) elif satname == 'S2': # load classifier (special classifier for Sentinel-2 images) clf = joblib.load(os.path.join(os.getcwd(), 'classifiers', 'NN_4classes_S2.pkl')) # calculate features vec_features = calculate_features(im_ms, cloud_mask, np.ones(cloud_mask.shape).astype(bool)) vec_features[np.isnan(vec_features)] = 1e-9 # NaN values are create when std is too close to 0 # remove NaNs and cloudy pixels vec_cloud = cloud_mask.reshape(cloud_mask.shape[0]*cloud_mask.shape[1]) vec_nan = np.any(np.isnan(vec_features), axis=1) vec_mask = np.logical_or(vec_cloud, vec_nan) vec_features = vec_features[~vec_mask, :] # classify pixels labels = clf.predict(vec_features) # recompose image vec_classif = np.nan*np.ones((cloud_mask.shape[0]*cloud_mask.shape[1])) vec_classif[~vec_mask] = labels im_classif = vec_classif.reshape((cloud_mask.shape[0], cloud_mask.shape[1])) # create a stack of boolean images for each label im_sand = im_classif == 1 im_swash = im_classif == 2 im_water = im_classif == 3 # remove small patches of sand or water that could be around the image (usually noise) im_sand = morphology.remove_small_objects(im_sand, min_size=min_beach_size, connectivity=2) im_water = morphology.remove_small_objects(im_water, min_size=min_beach_size, connectivity=2) im_labels = np.stack((im_sand,im_swash,im_water), axis=-1) return im_classif, im_labels def find_wl_contours1(im_ndwi, cloud_mask): """ Traditional method for shorelien detection. Finds the water line by thresholding the Normalized Difference Water Index and applying the Marching Squares Algorithm to contour the iso-value corresponding to the threshold. KV WRL 2018 Arguments: ----------- im_ndwi: np.ndarray Image (2D) with the NDWI (water index) cloud_mask: np.ndarray 2D cloud mask with True where cloud pixels are Returns: ----------- contours_wl: list of np.arrays contains the (row,column) coordinates of the contour lines """ # reshape image to vector vec_ndwi = im_ndwi.reshape(im_ndwi.shape[0] * im_ndwi.shape[1]) vec_mask = cloud_mask.reshape(cloud_mask.shape[0] * cloud_mask.shape[1]) vec = vec_ndwi[~vec_mask] # apply otsu's threshold vec = vec[~np.isnan(vec)] t_otsu = filters.threshold_otsu(vec) # use Marching Squares algorithm to detect contours on ndwi image contours = measure.find_contours(im_ndwi, t_otsu) # remove contours that contain NaNs (due to cloud pixels in the contour) contours_nonans = [] for k in range(len(contours)): if np.any(np.isnan(contours[k])): index_nan = np.where(np.isnan(contours[k]))[0] contours_temp = np.delete(contours[k], index_nan, axis=0) if len(contours_temp) > 1: contours_nonans.append(contours_temp) else: contours_nonans.append(contours[k]) contours = contours_nonans return contours def find_wl_contours2(im_ms, im_labels, cloud_mask, buffer_size): """ New robust method for extracting shorelines. Incorporates the classification component to refine the treshold and make it specific to the sand/water interface. KV WRL 2018 Arguments: ----------- im_ms: np.array RGB + downsampled NIR and SWIR im_labels: np.array 3D image containing a boolean image for each class in the order (sand, swash, water) cloud_mask: np.array 2D cloud mask with True where cloud pixels are buffer_size: int size of the buffer around the sandy beach over which the pixels are considered in the thresholding algorithm. Returns: ----------- contours_wi: list of np.arrays contains the (row,column) coordinates of the contour lines extracted from the NDWI (Normalized Difference Water Index) image contours_mwi: list of np.arrays contains the (row,column) coordinates of the contour lines extracted from the MNDWI (Modified Normalized Difference Water Index) image """ nrows = cloud_mask.shape[0] ncols = cloud_mask.shape[1] # calculate Normalized Difference Modified Water Index (SWIR - G) im_mwi = nd_index(im_ms[:,:,4], im_ms[:,:,1], cloud_mask) # calculate Normalized Difference Modified Water Index (NIR - G) im_wi = nd_index(im_ms[:,:,3], im_ms[:,:,1], cloud_mask) # stack indices together im_ind = np.stack((im_wi, im_mwi), axis=-1) vec_ind = im_ind.reshape(nrows*ncols,2) # reshape labels into vectors vec_sand = im_labels[:,:,0].reshape(ncols*nrows) vec_water = im_labels[:,:,2].reshape(ncols*nrows) # create a buffer around the sandy beach se = morphology.disk(buffer_size) im_buffer = morphology.binary_dilation(im_labels[:,:,0], se) vec_buffer = im_buffer.reshape(nrows*ncols) # select water/sand/swash pixels that are within the buffer int_water = vec_ind[np.logical_and(vec_buffer,vec_water),:] int_sand = vec_ind[np.logical_and(vec_buffer,vec_sand),:] # make sure both classes have the same number of pixels before thresholding if len(int_water) > 0 and len(int_sand) > 0: if np.argmin([int_sand.shape[0],int_water.shape[0]]) == 1: int_sand = int_sand[np.random.choice(int_sand.shape[0],int_water.shape[0], replace=False),:] else: int_water = int_water[np.random.choice(int_water.shape[0],int_sand.shape[0], replace=False),:] # threshold the sand/water intensities int_all = np.append(int_water,int_sand, axis=0) t_mwi = filters.threshold_otsu(int_all[:,0]) t_wi = filters.threshold_otsu(int_all[:,1]) # find contour with MS algorithm im_wi_buffer = np.copy(im_wi) im_wi_buffer[~im_buffer] = np.nan im_mwi_buffer = np.copy(im_mwi) im_mwi_buffer[~im_buffer] = np.nan contours_wi = measure.find_contours(im_wi_buffer, t_wi) contours_mwi = measure.find_contours(im_mwi, t_mwi) # remove contour points that are NaNs (around clouds) contours = contours_wi contours_nonans = [] for k in range(len(contours)): if np.any(np.isnan(contours[k])): index_nan = np.where(np.isnan(contours[k]))[0] contours_temp = np.delete(contours[k], index_nan, axis=0) if len(contours_temp) > 1: contours_nonans.append(contours_temp) else: contours_nonans.append(contours[k]) contours_wi = contours_nonans # repeat for MNDWI contours contours = contours_mwi contours_nonans = [] for k in range(len(contours)): if np.any(np.isnan(contours[k])): index_nan = np.where(np.isnan(contours[k]))[0] contours_temp = np.delete(contours[k], index_nan, axis=0) if len(contours_temp) > 1: contours_nonans.append(contours_temp) else: contours_nonans.append(contours[k]) contours_mwi = contours_nonans return contours_wi, contours_mwi def process_shoreline(contours, georef, image_epsg, settings): """ Converts the contours from image coordinates to world coordinates. This function also removes the contours that are too small to be a shoreline (based on the parameter settings['min_length_sl']) KV WRL 2018 Arguments: ----------- contours: np.array or list of np.array image contours as detected by the function find_contours georef: np.array vector of 6 elements [Xtr, Xscale, Xshear, Ytr, Yshear, Yscale] image_epsg: int spatial reference system of the image from which the contours were extracted settings: dict contains important parameters for processing the shoreline: output_epsg: output spatial reference system min_length_sl: minimum length of shoreline perimeter to be kept (in meters) reference_sl: [optional] reference shoreline coordinates max_dist_ref: max distance (in meters) allowed from a reference shoreline Returns: ----------- shoreline: np.array array of points with the X and Y coordinates of the shoreline """ # convert pixel coordinates to world coordinates contours_world = SDS_tools.convert_pix2world(contours, georef) # convert world coordinates to desired spatial reference system contours_epsg = SDS_tools.convert_epsg(contours_world, image_epsg, settings['output_epsg']) # remove contours that have a perimeter < min_length_wl (provided in settings dict) # this enable to remove the very small contours that do not correspond to the shoreline contours_long = [] for l, wl in enumerate(contours_epsg): coords = [(wl[k,0], wl[k,1]) for k in range(len(wl))] a = LineString(coords) # shapely LineString structure if a.length >= settings['min_length_sl']: contours_long.append(wl) # format points into np.array x_points = np.array([]) y_points = np.array([]) for k in range(len(contours_long)): x_points = np.append(x_points,contours_long[k][:,0]) y_points = np.append(y_points,contours_long[k][:,1]) contours_array = np.transpose(np.array([x_points,y_points])) # if reference shoreline has been manually digitised if 'refsl' in settings.keys(): # only keep the points that are at a certain distance (define in settings) from the # reference shoreline, enables to avoid false detections and remove obvious outliers temp = np.zeros((len(contours_array))).astype(bool) for k in range(len(settings['refsl'])): temp = np.logical_or(np.linalg.norm(contours_array - settings['refsl'][k,[0,1]], axis=1) < settings['max_dist_ref'], temp) shoreline = contours_array[temp] else: shoreline = contours_array return shoreline def show_detection(im_ms, cloud_mask, im_labels, shoreline,image_epsg, georef, settings, date, satname): """ Shows the detected shoreline to the user for visual quality control. The user can select "keep" if the shoreline detection is correct or "skip" if it is incorrect. KV WRL 2018 Arguments: ----------- im_ms: np.array RGB + downsampled NIR and SWIR cloud_mask: np.array 2D cloud mask with True where cloud pixels are im_labels: np.array 3D image containing a boolean image for each class in the order (sand, swash, water) shoreline: np.array array of points with the X and Y coordinates of the shoreline image_epsg: int spatial reference system of the image from which the contours were extracted georef: np.array vector of 6 elements [Xtr, Xscale, Xshear, Ytr, Yshear, Yscale] settings: dict contains important parameters for processing the shoreline date: string date at which the image was taken satname: string indicates the satname (L5,L7,L8 or S2) Returns: ----------- skip_image: boolean True if the user wants to skip the image, False otherwise. """ sitename = settings['inputs']['sitename'] # subfolder where the .jpg file is stored if the user accepts the shoreline detection filepath = os.path.join(os.getcwd(), 'data', sitename, 'jpg_files', 'detection') im_RGB = SDS_preprocess.rescale_image_intensity(im_ms[:,:,[2,1,0]], cloud_mask, 99.9) # compute classified image im_class = np.copy(im_RGB) cmap = cm.get_cmap('tab20c') colorpalette = cmap(np.arange(0,13,1)) colours = np.zeros((3,4)) colours[0,:] = colorpalette[5] colours[1,:] = np.array([204/255,1,1,1]) colours[2,:] = np.array([0,91/255,1,1]) for k in range(0,im_labels.shape[2]): im_class[im_labels[:,:,k],0] = colours[k,0] im_class[im_labels[:,:,k],1] = colours[k,1] im_class[im_labels[:,:,k],2] = colours[k,2] # compute MNDWI grayscale image im_mwi = nd_index(im_ms[:,:,4], im_ms[:,:,1], cloud_mask) # transform world coordinates of shoreline into pixel coordinates # use try/except in case there are no coordinates to be transformed (shoreline = []) try: sl_pix = SDS_tools.convert_world2pix(SDS_tools.convert_epsg(shoreline, settings['output_epsg'], image_epsg)[:,[0,1]], georef) except: # if try fails, just add nan into the shoreline vector so the next parts can still run sl_pix = np.array([[np.nan, np.nan],[np.nan, np.nan]]) # according to the image shape, decide whether it is better to have the images in the subplot # in different rows or different columns fig = plt.figure() if im_RGB.shape[1] > 2*im_RGB.shape[0]: # vertical subplots gs = gridspec.GridSpec(3, 1) gs.update(bottom=0.03, top=0.97, left=0.03, right=0.97) ax1 = fig.add_subplot(gs[0,0]) ax2 = fig.add_subplot(gs[1,0]) ax3 = fig.add_subplot(gs[2,0]) else: # horizontal subplots gs = gridspec.GridSpec(1, 3) gs.update(bottom=0.05, top=0.95, left=0.05, right=0.95) ax1 = fig.add_subplot(gs[0,0]) ax2 = fig.add_subplot(gs[0,1]) ax3 = fig.add_subplot(gs[0,2]) # create image 1 (RGB) ax1.imshow(im_RGB) ax1.plot(sl_pix[:,0], sl_pix[:,1], 'k.', markersize=3) ax1.axis('off') btn_keep = plt.text(0, 0.9, 'keep', size=16, ha="left", va="top", transform=ax1.transAxes, bbox=dict(boxstyle="square", ec='k',fc='w')) btn_skip = plt.text(1, 0.9, 'skip', size=16, ha="right", va="top", transform=ax1.transAxes, bbox=dict(boxstyle="square", ec='k',fc='w')) ax1.set_title(sitename + ' ' + date + ' ' + satname, fontweight='bold', fontsize=16) # create image 2 (classification) ax2.imshow(im_class) ax2.plot(sl_pix[:,0], sl_pix[:,1], 'k.', markersize=3) ax2.axis('off') orange_patch = mpatches.Patch(color=colours[0,:], label='sand') white_patch = mpatches.Patch(color=colours[1,:], label='whitewater') blue_patch = mpatches.Patch(color=colours[2,:], label='water') black_line = mlines.Line2D([],[],color='k',linestyle='--', label='shoreline') ax2.legend(handles=[orange_patch,white_patch,blue_patch, black_line], bbox_to_anchor=(1, 0.5), fontsize=9) # create image 3 (MNDWI) ax3.imshow(im_mwi, cmap='bwr') ax3.plot(sl_pix[:,0], sl_pix[:,1], 'k.', markersize=3) ax3.axis('off') # additional options # ax1.set_anchor('W') # ax2.set_anchor('W') # cb = plt.colorbar() # cb.ax.tick_params(labelsize=10) # cb.set_label('MNDWI values') # ax3.set_anchor('W') fig.set_size_inches([12.53, 9.3]) mng = plt.get_current_fig_manager() mng.window.showMaximized() # wait for user's selection: or pt = ginput(n=1, timeout=100000, show_clicks=True) pt = np.array(pt) # if user clicks around the button, return skip_image = True if pt[0][0] > im_ms.shape[1]/2: skip_image = True plt.close() else: skip_image = False btn_skip.set_visible(False) btn_keep.set_visible(False) fig.savefig(os.path.join(filepath, date + '_' + satname + '.jpg'), dpi=150) plt.close() return skip_image def extract_shorelines(metadata, settings): """ Extracts shorelines from satellite images. KV WRL 2018 Arguments: ----------- metadata: dict contains all the information about the satellite images that were downloaded inputs: dict contains the following fields: sitename: str String containig the name of the site polygon: list polygon containing the lon/lat coordinates to be extracted longitudes in the first column and latitudes in the second column dates: list of str list that contains 2 strings with the initial and final dates in format 'yyyy-mm-dd' e.g. ['1987-01-01', '2018-01-01'] sat_list: list of str list that contains the names of the satellite missions to include e.g. ['L5', 'L7', 'L8', 'S2'] Returns: ----------- output: dict contains the extracted shorelines and corresponding dates. """ sitename = settings['inputs']['sitename'] # initialise output structure output = dict([]) # create a subfolder to store the .jpg images showing the detection filepath_jpg = os.path.join(os.getcwd(), 'data', sitename, 'jpg_files', 'detection') try: os.makedirs(filepath_jpg) except: print('') # loop through satellite list for satname in metadata.keys(): # get images filepath = SDS_tools.get_filepath(settings['inputs'],satname) filenames = metadata[satname]['filenames'] # initialise some variables output_timestamp = [] # datetime at which the image was acquired (UTC time) output_shoreline = [] # vector of shoreline points output_filename = [] # filename of the images from which the shorelines where derived output_cloudcover = [] # cloud cover of the images output_geoaccuracy = []# georeferencing accuracy of the images output_idxkeep = [] # index that were kept during the analysis (cloudy images are skipped) # loop through the images for i in range(len(filenames)): # get image filename fn = SDS_tools.get_filenames(filenames[i],filepath, satname) # preprocess image (cloud mask + pansharpening/downsampling) im_ms, georef, cloud_mask, im_extra, imQA = SDS_preprocess.preprocess_single(fn, satname) # get image spatial reference system (epsg code) from metadata dict image_epsg = metadata[satname]['epsg'][i] # calculate cloud cover cloud_cover = np.divide(sum(sum(cloud_mask.astype(int))), (cloud_mask.shape[0]*cloud_mask.shape[1])) # skip image if cloud cover is above threshold if cloud_cover > settings['cloud_thresh']: continue # classify image in 4 classes (sand, whitewater, water, other) with NN classifier im_classif, im_labels = classify_image_NN(im_ms, im_extra, cloud_mask, settings['min_beach_size'], satname) # extract water line contours # if there aren't any sandy pixels, use find_wl_contours1 (traditional method), # otherwise use find_wl_contours2 (enhanced method with classification) try: # use try/except structure for long runs if sum(sum(im_labels[:,:,0])) == 0 : # compute MNDWI (SWIR-Green normalized index) grayscale image im_mndwi = nd_index(im_ms[:,:,4], im_ms[:,:,1], cloud_mask) # find water contourson MNDWI grayscale image contours_mwi = find_wl_contours1(im_mndwi, cloud_mask) else: # use classification to refine threshold and extract sand/water interface contours_wi, contours_mwi = find_wl_contours2(im_ms, im_labels, cloud_mask, settings['buffer_size']) except: continue # process water contours into shorelines shoreline = process_shoreline(contours_mwi, georef, image_epsg, settings) if settings['check_detection']: date = filenames[i][:10] skip_image = show_detection(im_ms, cloud_mask, im_labels, shoreline, image_epsg, georef, settings, date, satname) if skip_image: continue # fill and save outputput structure output_timestamp.append(metadata[satname]['dates'][i]) output_shoreline.append(shoreline) output_filename.append(filenames[i]) output_cloudcover.append(cloud_cover) output_geoaccuracy.append(metadata[satname]['acc_georef'][i]) output_idxkeep.append(i) output[satname] = { 'timestamp': output_timestamp, 'shoreline': output_shoreline, 'filename': output_filename, 'cloudcover': output_cloudcover, 'geoaccuracy': output_geoaccuracy, 'idxkeep': output_idxkeep } # add some metadata output['meta'] = { 'timestamp': 'UTC time', 'shoreline': 'coordinate system epsg : ' + str(settings['output_epsg']), 'cloudcover': 'calculated on the cropped image', 'geoaccuracy': 'RMSE error based on GCPs', 'idxkeep': 'indices of the images that were kept to extract a shoreline' } # save outputput structure as output.pkl filepath = os.path.join(os.getcwd(), 'data', sitename) with open(os.path.join(filepath, sitename + '_output.pkl'), 'wb') as f: pickle.dump(output, f) return output