reorganisation

.gitignore

@@ -1,2 +1,3 @@
 *.pyc
 *.mat
+*.tif

data/L7/NARRA/NARRA_epsgcode.pkl

@@ -0,0 +1 @@
+<EFBFBD>M<>.

data/L8/NARRA/NARRA_epsgcode.pkl

@@ -0,0 +1 @@
+<EFBFBD>M<>.

download_images.py

@@ -32,7 +32,7 @@ import skimage.measure as measure
 
 
 # import own modules
-from functions.utils import *
+import functions.utils as utils
 
 np.seterr(all='ignore') # raise/ignore divisions by 0 and nans
 ee.Initialize()
@@ -60,10 +60,10 @@ rect_narra = [[[151.301454, -33.700754],
                [151.301454, -33.700754]]];
                
 # dates
-start_date = '2016-01-01'
-end_date = '2016-12-31'
+#start_date = '2016-01-01'
+#end_date = '2016-12-31'
 # filter by location
-flt_col = input_col.filterBounds(ee.Geometry.Polygon(rect_narra)).filterDate(start_date, end_date)
+flt_col = input_col.filterBounds(ee.Geometry.Polygon(rect_narra))#.filterDate(start_date, end_date)
 
 n_img = flt_col.size().getInfo()
 print('Number of images covering Narrabeen:', n_img)
@@ -105,10 +105,10 @@ for i in range(n_img):
         filename_ms = satname + '_' + sitename + '_' + im_date + '_ms' + '_r' + suffix 
     all_names_pan.append(filename_pan)
     
-#    local_data_pan = download_tif(im, rect_narra, pan_band, filepath_pan)
-#    os.rename(local_data_pan, os.path.join(filepath_pan, filename_pan))
-#    local_data_ms = download_tif(im, rect_narra, ms_bands, filepath_ms)
-#    os.rename(local_data_ms, os.path.join(filepath_ms, filename_ms))
+    local_data_pan = download_tif(im, rect_narra, pan_band, filepath_pan)
+    os.rename(local_data_pan, os.path.join(filepath_pan, filename_pan))
+    local_data_ms = download_tif(im, rect_narra, ms_bands, filepath_ms)
+    os.rename(local_data_ms, os.path.join(filepath_ms, filename_ms))
     
     
 with open(os.path.join(filepath, sitename + '_timestamps' + '.pkl'), 'wb') as f:

download_images_L7.py

@@ -0,0 +1,118 @@
+# -*- coding: utf-8 -*-
+"""
+Created on Tue Mar 27 17:12:35 2018
+
+@author: Kilian
+"""
+
+# Initial settings
+import os
+import numpy as np
+import matplotlib.pyplot as plt
+import pdb
+import ee
+
+
+# other modules
+from osgeo import gdal, ogr, osr
+from urllib.request import urlretrieve
+import zipfile
+from datetime import datetime
+import pytz
+import pickle
+
+
+
+# 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 own modules
+import functions.utils as utils
+
+np.seterr(all='ignore') # raise/ignore divisions by 0 and nans
+ee.Initialize()
+
+def download_tif(image, polygon, bandsId, filepath):
+    """downloads tif image (region and bands) from the ee server and stores it in a temp file"""
+    url = ee.data.makeDownloadUrl(ee.data.getDownloadId({
+        'image': image.serialize(),
+        'region': polygon,
+        'bands': bandsId,
+        'filePerBand': 'false',
+        'name': 'data',
+        }))
+    local_zip, headers = urlretrieve(url)
+    with zipfile.ZipFile(local_zip) as local_zipfile:
+        return local_zipfile.extract('data.tif', filepath)
+    
+# select collection
+input_col = ee.ImageCollection('LANDSAT/LE07/C01/T1_RT_TOA')
+# location (Narrabeen-Collaroy beach)
+rect_narra = [[[151.301454, -33.700754],
+               [151.311453, -33.702075], 
+               [151.307237, -33.739761],
+               [151.294220, -33.736329],
+               [151.301454, -33.700754]]];
+               
+# dates
+#start_date = '2016-01-01'
+#end_date = '2016-12-31'
+# filter by location
+flt_col = input_col.filterBounds(ee.Geometry.Polygon(rect_narra))#.filterDate(start_date, end_date)
+
+n_img = flt_col.size().getInfo()
+print('Number of images covering Narrabeen:', n_img)
+im_all = flt_col.getInfo().get('features')
+
+satname = 'L7'
+sitename = 'NARRA'
+suffix = '.tif'
+filepath = os.path.join(os.getcwd(), 'data', satname, sitename)
+filepath_pan = os.path.join(filepath, 'pan')
+filepath_ms = os.path.join(filepath, 'ms')
+
+all_names_pan = []
+all_names_ms = []
+timestamps = []
+# loop through all images
+for i in range(n_img):
+    # find each image in ee database
+    im = ee.Image(im_all[i].get('id'))
+    im_dic = im.getInfo()
+    im_bands = im_dic.get('bands')
+    im_date = im_dic['properties']['DATE_ACQUIRED']
+    t = im_dic['properties']['system:time_start']
+    im_timestamp = datetime.fromtimestamp(t/1000, tz=pytz.utc)
+    timestamps.append(im_timestamp)
+    im_epsg = int(im_dic['bands'][0]['crs'][5:])
+    
+    # delete dimensions key from dictionnary, otherwise the entire image is extracted
+    for j in range(len(im_bands)): del im_bands[j]['dimensions']
+    pan_band = [im_bands[7]]
+    ms_bands = [im_bands[0], im_bands[1], im_bands[2], im_bands[3], im_bands[4], im_bands[9]]
+
+    filename_pan = satname + '_' + sitename + '_' + im_date + '_pan' + suffix
+    filename_ms = satname + '_' + sitename + '_' + im_date +  '_ms' + suffix
+
+    print(i)
+    if any(filename_pan in _ for _ in all_names_pan):
+        filename_pan = satname + '_' + sitename + '_' + im_date + '_pan' + '_r' + suffix 
+        filename_ms = satname + '_' + sitename + '_' + im_date + '_ms' + '_r' + suffix 
+    all_names_pan.append(filename_pan)
+    
+    local_data_pan = download_tif(im, rect_narra, pan_band, filepath_pan)
+    os.rename(local_data_pan, os.path.join(filepath_pan, filename_pan))
+    local_data_ms = download_tif(im, rect_narra, ms_bands, filepath_ms)
+    os.rename(local_data_ms, os.path.join(filepath_ms, filename_ms))
+    
+    
+with open(os.path.join(filepath, sitename + '_timestamps' + '.pkl'), 'wb') as f:
+    pickle.dump(timestamps, f)  
+with open(os.path.join(filepath, sitename + '_epsgcode' + '.pkl'), 'wb') as f:
+    pickle.dump(im_epsg, f)      
+    

functions/sds.py

@@ -25,6 +25,7 @@ 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
 
 
 # import own modules
@@ -79,7 +80,7 @@ def load_image(image, polygon, bandsId):
     bands = [dataset.GetRasterBand(i + 1).ReadAsArray() for i in range(dataset.RasterCount)]
     return np.stack(bands, 2), georef
 
-def create_cloud_mask(im_qa):
+def create_cloud_mask(im_qa, satname, plot_bool):
     """
     Creates a cloud mask from the image containing the QA band information
     
@@ -89,6 +90,10 @@ def create_cloud_mask(im_qa):
     -----------
         im_qa: np.ndarray
             Image containing the QA band
+        satname: string
+            short name for the satellite (L8, L7, S2)
+        plot_bool: boolean
+            True if plot is wanted
             
     Returns:
     -----------
@@ -97,8 +102,20 @@ def create_cloud_mask(im_qa):
     """
     
     # convert QA bits
-    cloud_values = [2800, 2804, 2808, 2812, 6896, 6900, 6904, 6908]
+    if satname == 'L8':
+        cloud_values = [2800, 2804, 2808, 2812, 6896, 6900, 6904, 6908]
+    elif satname == 'L7':
+        cloud_values = [752, 756, 760, 764]
+        
     cloud_mask = np.isin(im_qa, cloud_values)
+    # remove isolated cloud pixels (there are some in the swash and they cause problems)
+    if sum(sum(cloud_mask)) > 0:
+        morphology.remove_small_objects(cloud_mask, min_size=5, connectivity=8, in_place=True)
+    
+    if plot_bool:
+        plt.figure()
+        plt.imshow(cloud_mask, cmap='gray')
+        plt.draw()
     
     #cloud_shadow_values = [2976, 2980, 2984, 2988, 3008, 3012, 3016, 3020]
     #cloud_shadow_mask = np.isin(im_qa, cloud_shadow_values)

oldcodes/time_coverage.py

@@ -0,0 +1,136 @@
+# -*- coding: utf-8 -*-
+"""
+Created on Tue Mar 20 16:15:51 2018
+
+@author: z5030440
+"""
+
+import scipy.io as sio
+import os
+import ee
+import matplotlib.pyplot as plt
+import matplotlib.dates as mdates
+import numpy as np
+import pandas as pd
+from datetime import datetime, timedelta
+import pickle
+import pdb
+import pytz
+
+
+# image processing modules
+import skimage.filters as filters 
+import skimage.exposure as exposure
+import skimage.transform as transform
+import skimage.morphology as morphology
+import skimage.measure as measure
+import sklearn.decomposition as decomposition
+from scipy import spatial
+# my functions
+import functions.utils as utils
+import functions.sds as sds
+#plt.rcParams['axes.grid'] = True
+au_tz = pytz.timezone('Australia/Sydney')
+
+# load quadbike dates and convert from datenum to datetime
+suffix = '.mat'
+dir_name = os.getcwd()
+file_name = 'data\quadbike_dates'
+file_path = os.path.join(dir_name, file_name + suffix)
+quad_dates = sio.loadmat(file_path)['dates']
+dt_quad = []
+for i in range(quad_dates.shape[0]): 
+    dt_quad.append(datetime(quad_dates[i,0], quad_dates[i,1], quad_dates[i,2], tzinfo=au_tz))
+    
+# load satellite datetimes (in UTC) and convert to AEST time
+input_col = ee.ImageCollection('LANDSAT/LC08/C01/T1_RT_TOA')
+# location (Narrabeen-Collaroy beach)
+rect_narra = [[[151.3473129272461,-33.69035274454718],
+              [151.2820816040039,-33.68206818063878], 
+              [151.27281188964844,-33.74775138989556],
+              [151.3425064086914,-33.75231878701767],
+              [151.3473129272461,-33.69035274454718]]];
+flt_col = input_col.filterBounds(ee.Geometry.Polygon(rect_narra))               
+n_img = flt_col.size().getInfo()
+print('Number of images covering Narrabeen:', n_img)
+im_all = flt_col.getInfo().get('features')
+
+# extract datetimes from image metadata
+dt_sat = [_['properties']['system:time_start'] for _ in im_all]
+dt_sat = [datetime.fromtimestamp(_/1000, tz=pytz.utc) for _ in dt_sat]
+dt_sat = [_.astimezone(au_tz) for _ in dt_sat]
+# calculate days difference
+diff_days = [ [(x - _).days for _ in dt_quad] for x in dt_sat]
+day_thresh = 15
+idx = [utils.find_indices(_, lambda e: abs(e) < day_thresh) for _ in diff_days]
+
+dt_diff = []
+idx_nogt = []
+for i in range(n_img):
+    if not idx[i]:
+        idx_nogt.append(i)
+        continue
+    dt_diff.append({"sat dt": dt_sat[i],
+               "quad dt": [dt_quad[_] for _ in idx[i]],
+               "days diff": [diff_days[i][_] for _ in idx[i]] })
+
+with open('idx_nogt.pkl', 'wb') as f:
+    pickle.dump(idx_nogt, f)     
+
+    
+#%%  
+dates_sat = mdates.date2num(dt_sat)
+dates_quad = mdates.date2num(dt_quad)
+plt.figure()
+plt.plot_date(dates_sat, np.zeros((n_img,1)))
+plt.plot_date(dates_quad, np.ones((len(dates_quad),1)))
+plt.show()
+
+data = pd.read_pickle('data_2016.pkl')
+
+dt_sat = [_.astimezone(au_tz) for _ in data['dt']]
+
+[ (_ - dt_sat[0]).days for _ in dt_quad]
+
+
+
+dn_sat = []
+for i in range(len(dt_sat)): dn_sat.append(dt_sat[i].toordinal())
+dn_sat = np.array(dn_sat)
+dn_sur = []
+for i in range(len(dt_survey)): dn_sur.append(dt_survey[i].toordinal())
+dn_sur = np.array(dn_sur)
+
+distances = np.zeros((len(dn_sat),4)).astype('int32')
+indexes = np.zeros((len(dn_sat),2)).astype('int32')
+for i in range(len(dn_sat)):
+    distances[i,0] = np.sort(abs(dn_sat[i] - dn_sur))[0]
+    distances[i,1] = np.sort(abs(dn_sat[i] - dn_sur))[1]
+    distances[i,2] = dt_sat[i].year
+    distances[i,3] = dt_sat[i].month
+    indexes[i,0] = np.where(abs(dn_sat[i] - dn_sur) == np.sort(abs(dn_sat[i] - dn_sur))[0])[0][0]
+    indexes[i,1] = np.where(abs(dn_sat[i] - dn_sur) == np.sort(abs(dn_sat[i] - dn_sur))[1])[0][0]
+
+
+years = [2013, 2014, 2015, 2016]
+months = mdates.MonthLocator()
+days = mdates.DayLocator()
+month_fmt = mdates.DateFormatter('%b')
+f, ax = plt.subplots(4, 1)
+for i, ca in enumerate(ax):
+    ca.xaxis.set_major_locator(months)
+    ca.xaxis.set_major_formatter(month_fmt)
+    ca.xaxis.set_minor_locator(days)
+    ca.set_ylabel(str(years[i]))
+    for j in range(len(dt_sat)):
+        if dt_sat[j].year == years[i]:
+            ca.plot(dt_sat[j],0, 'bo', markerfacecolor='b')
+#f.subplots_adjust(hspace=0)
+#plt.setp([a.get_xticklabels() for a in f.axes[:-1]], visible=False)            
+ 
+    
+plt.plot(dt_survey, np.zeros([len(dt_survey),1]), 'bo')
+plt.plot(dt_sat, np.ones([len(dt_sat),1]), 'ro')
+plt.yticks([])
+plt.show()
+

read_images.py

@@ -31,6 +31,8 @@ import functions.utils as utils
 import functions.sds as sds
 
 np.seterr(all='ignore') # raise/ignore divisions by 0 and nans
+plt.rcParams['axes.grid'] = True
+plt.rcParams['figure.max_open_warning'] = 100
 ee.Initialize()
 
 # initial settings
@@ -73,7 +75,7 @@ for i in range(N):
     im_ms = np.stack(bands, 2)
     # cloud mask
     im_qa = im_ms[:,:,5]
-    cloud_mask = sds.create_cloud_mask(im_qa)
+    cloud_mask = sds.create_cloud_mask(im_qa, satname, plot_bool)
     cloud_mask = transform.resize(cloud_mask, (im_pan.shape[0], im_pan.shape[1]),
                                 order=0, preserve_range=True, 
                                 mode='constant').astype('bool_')    
@@ -105,16 +107,19 @@ for i in range(N):
     # convert to output epsg spatial reference
     wl = sds.convert_epsg(wl_coords, input_epsg, output_epsg)
     
-#    plt.figure()
-#    plt.imshow(im_ms_ps[:,:,[2,1,0]])
-#    for i,contour in enumerate(wl_pix): plt.plot(contour[:, 1], contour[:, 0], linewidth=2)
-#    plt.axis('image')
-#    plt.title(file_names_pan[i])
-#    plt.show() 
-    
     plt.figure()
-    centroids = []
     cmap = cm.get_cmap('jet')
+
+    plt.subplot(121)
+    plt.imshow(im_ms_ps[:,:,[2,1,0]])
+    for j,contour in enumerate(wl_pix):
+        colours = cmap(np.linspace(0, 1, num=len(wl)))
+        plt.plot(contour[:, 1], contour[:, 0], linewidth=2, color=colours[j,:])
+    plt.axis('image')
+    plt.title(file_names_pan[i])
+    
+    plt.subplot(122)
+    centroids = []
     for j,contour in enumerate(wl):
         colours = cmap(np.linspace(0, 1, num=len(wl)))
         centroids.append([np.mean(contour[:, 0]),np.mean(contour[:, 1])])
@@ -122,8 +127,18 @@ for i in range(N):
         plt.plot(np.mean(contour[:, 0]), np.mean(contour[:, 1]), 'o', color=colours[j,:])
     plt.axis('equal')
     plt.title(file_names_pan[i])
+    mng = plt.get_current_fig_manager()                                         
+    mng.window.showMaximized()
+    plt.tight_layout()   
     plt.draw()
+    
     pt_in = np.array(ginput(1))
+    
+    if pt_in[0][0] < 10000:
+        print('skipped m ' + str(i))
+        idx_high_cloud.append(i)
+        continue
+
     dist_centroid = [np.linalg.norm(_ - pt_in) for _ in centroids]
     shorelines.append(wl[np.argmin(dist_centroid)])
     t.append(timestamps_sorted[i])
@@ -138,3 +153,5 @@ output = {'t':t, 'shorelines':shorelines}
 
 with open(os.path.join(filepath, sitename + '_output' + '.pkl'), 'wb') as f:
     pickle.dump(output, f)
+    
+

test_L7image.py

@@ -0,0 +1,75 @@
+# -*- coding: utf-8 -*-
+"""
+Created on Tue Mar 27 17:12:35 2018
+
+@author: Kilian
+"""
+
+# Initial settings
+import os
+import numpy as np
+import matplotlib.pyplot as plt
+import ee
+import pdb
+
+# other modules
+from osgeo import gdal, ogr, osr
+import pickle
+import matplotlib.cm as cm
+from pylab import ginput
+
+# 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 own modules
+import functions.utils as utils
+import functions.sds as sds
+
+np.seterr(all='ignore') # raise/ignore divisions by 0 and nans
+plt.rcParams['axes.grid'] = True
+plt.rcParams['figure.max_open_warning'] = 100
+ee.Initialize()
+
+# initial settings
+cloud_thresh = 0.5      # threshold for cloud cover
+plot_bool = False       # if you want the plots
+prob_high = 99.9        # upper probability to clip and rescale pixel intensity
+min_contour_points = 100# minimum number of points contained in each water line
+output_epsg = 28356     # GDA94 / MGA Zone 56
+
+satname = 'L7'
+sitename = 'NARRA'
+filepath = os.path.join(os.getcwd(), 'data', satname, sitename)
+with open(os.path.join(filepath, sitename + '_timestamps' + '.pkl'), 'rb') as f:
+    timestamps = pickle.load(f)
+timestamps_sorted = sorted(timestamps)
+with open(os.path.join(filepath, sitename + '_epsgcode' + '.pkl'), 'rb') as f:
+    input_epsg = pickle.load(f)
+    
+file_path_pan = os.path.join(filepath, 'pan')
+file_path_ms = os.path.join(filepath, 'ms')
+file_names_pan = os.listdir(file_path_pan)
+file_names_ms = os.listdir(file_path_ms)
+N = len(file_names_pan)
+idx_high_cloud = []
+t = []
+shorelines = []
+
+for i in range(N):
+    # read pan image
+    fn_pan = os.path.join(file_path_pan, file_names_pan[i])
+    data = gdal.Open(fn_pan, gdal.GA_ReadOnly)
+    georef = np.array(data.GetGeoTransform())
+    bands = [data.GetRasterBand(i + 1).ReadAsArray() for i in range(data.RasterCount)]
+    im_pan = np.stack(bands, 2)[:,:,0]
+    # read ms image
+    fn_ms = os.path.join(file_path_ms, file_names_ms[i])
+    data = gdal.Open(fn_ms, gdal.GA_ReadOnly)
+    bands = [data.GetRasterBand(i + 1).ReadAsArray() for i in range(data.RasterCount)]
+    im_ms = np.stack(bands, 2)
+    

time_coverage.py

@@ -5,18 +5,18 @@ Created on Tue Mar 20 16:15:51 2018
 @author: z5030440
 """
 
-import scipy.io as sio
 import os
-import ee
+import numpy as np
 import matplotlib.pyplot as plt
+import pdb
+import ee
+
 import matplotlib.dates as mdates
-import numpy as np
-import pandas as pd
+import matplotlib.cm as cm
 from datetime import datetime, timedelta
 import pickle
-import pdb
 import pytz
-
+import scipy.io as sio
 
 # image processing modules
 import skimage.filters as filters 
@@ -29,108 +29,150 @@ from scipy import spatial
 # my functions
 import functions.utils as utils
 import functions.sds as sds
-#plt.rcParams['axes.grid'] = True
+
+np.seterr(all='ignore') # raise/ignore divisions by 0 and nans
+plt.rcParams['axes.grid'] = True
+plt.rcParams['figure.max_open_warning'] = 100
+
 au_tz = pytz.timezone('Australia/Sydney')
 
 # load quadbike dates and convert from datenum to datetime
-suffix = '.mat'
-dir_name = os.getcwd()
-file_name = 'data\quadbike_dates'
-file_path = os.path.join(dir_name, file_name + suffix)
-quad_dates = sio.loadmat(file_path)['dates']
-dt_quad = []
-for i in range(quad_dates.shape[0]): 
-    dt_quad.append(datetime(quad_dates[i,0], quad_dates[i,1], quad_dates[i,2], tzinfo=au_tz))
-    
-# load satellite datetimes (in UTC) and convert to AEST time
-input_col = ee.ImageCollection('LANDSAT/LC08/C01/T1_RT_TOA')
-# location (Narrabeen-Collaroy beach)
-rect_narra = [[[151.3473129272461,-33.69035274454718],
-              [151.2820816040039,-33.68206818063878], 
-              [151.27281188964844,-33.74775138989556],
-              [151.3425064086914,-33.75231878701767],
-              [151.3473129272461,-33.69035274454718]]];
-flt_col = input_col.filterBounds(ee.Geometry.Polygon(rect_narra))               
-n_img = flt_col.size().getInfo()
-print('Number of images covering Narrabeen:', n_img)
-im_all = flt_col.getInfo().get('features')
-
-# extract datetimes from image metadata
-dt_sat = [_['properties']['system:time_start'] for _ in im_all]
-dt_sat = [datetime.fromtimestamp(_/1000, tz=pytz.utc) for _ in dt_sat]
-dt_sat = [_.astimezone(au_tz) for _ in dt_sat]
+filename = 'data\quadbike\survey_dates.mat'
+filepath = os.path.join(os.getcwd(), filename)
+dates_quad = sio.loadmat(filepath)['dates'] # matrix containing year, month, day
+dates_quad = [datetime(dates_quad[i,0], dates_quad[i,1], dates_quad[i,2],
+                       tzinfo=au_tz) for i in range(dates_quad.shape[0])]
+
+# load timestamps from satellite images
+satname = 'L8'
+sitename = 'NARRA'
+filepath = os.path.join(os.getcwd(), 'data', satname, sitename)
+with open(os.path.join(filepath, sitename + '_output' + '.pkl'), 'rb') as f:
+    output = pickle.load(f)
+dates_l8 = output['t']
+# convert to AEST
+dates_l8 = [_.astimezone(au_tz) for _ in dates_l8]
+
+# load wave data
+filename = 'data\wave\SydneyProcessed.mat'
+filepath = os.path.join(os.getcwd(), filename)
+wave_data = sio.loadmat(filepath)
+idx = utils.find_indices(wave_data['dates'][:,0], lambda e: e >= dates_l8[0].year and e <= dates_l8[-1].year)
+hsig = np.array([wave_data['Hsig'][i][0] for i in idx])
+wdir = np.array([wave_data['Wdir'][i][0] for i in idx])
+dates_wave = [datetime(wave_data['dates'][i,0], wave_data['dates'][i,1],
+                       wave_data['dates'][i,2], wave_data['dates'][i,3],
+                       wave_data['dates'][i,4], wave_data['dates'][i,5],
+                       tzinfo=au_tz) for i in idx]
+#%% make a plot of all the dates
+f = plt.figure()
+months = mdates.MonthLocator()
+month_fmt = mdates.DateFormatter('%b %Y')
+days = mdates.DayLocator()
+years = [2013,2014,2015,2016]
+for k in range(len(years)):
+    sel_year = years[k]
+    ax = plt.subplot(4,1,k+1)
+    idx_year = utils.find_indices(dates_wave, lambda e : e.year >= sel_year and e.year <= sel_year)
+    plt.plot([dates_wave[i] for i in idx_year], [hsig[i] for i in idx_year], 'k-', linewidth=0.5)
+    hsigmax = np.nanmax([hsig[i] for i in idx_year])
+    cbool = True
+    for j in range(len(dates_quad)):
+        if dates_quad[j].year == sel_year:
+            if cbool:
+                plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=[255/255,140/255,0], label='survey')
+                cbool = False
+            else:
+                plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=[255/255,140/255,0])
+    cbool = True
+    for j in range(len(dates_l8)):
+        if dates_l8[j].year == sel_year:
+            if cbool:
+                plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=[0,191/255,255/255], label='landsat8')
+                cbool = False
+            else:
+                plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=[0,191/255,255/255])
+    if k == 3:
+        plt.legend()
+    plt.xlim((datetime(sel_year,1,1), datetime(sel_year,12,31, tzinfo=au_tz)))
+    plt.ylim((0, hsigmax))
+    plt.ylabel('Hs [m]')
+    ax.xaxis.set_major_locator = months
+    ax.xaxis.set_major_formatter(month_fmt)
+f.subplots_adjust(hspace=0.2)
+plt.draw()
+#%%
+
 # calculate days difference
-diff_days = [ [(x - _).days for _ in dt_quad] for x in dt_sat]
-day_thresh = 15
-idx = [utils.find_indices(_, lambda e: abs(e) < day_thresh) for _ in diff_days]
-
-dt_diff = []
-idx_nogt = []
-for i in range(n_img):
-    if not idx[i]:
-        idx_nogt.append(i)
+diff_days = [ [(x - _).days for _ in dates_quad] for x in dates_l8]
+max_diff = 5
+idx_closest = [utils.find_indices(_, lambda e: abs(e) <= max_diff) for _ in diff_days]
+dates_diff = []
+for i in range(len(idx_closest)):
+    if not idx_closest[i]:
         continue
-    dt_diff.append({"sat dt": dt_sat[i],
-               "quad dt": [dt_quad[_] for _ in idx[i]],
-               "days diff": [diff_days[i][_] for _ in idx[i]] })
-
-with open('idx_nogt.pkl', 'wb') as f:
-    pickle.dump(idx_nogt, f)     
-
+    elif len(idx_closest[i]) > 1:
+        idx_best = np.argmin(np.abs([diff_days[i][_] for _ in idx_closest[i]]))
+        dates_temp = [dates_quad[_] for _ in idx_closest[i]]
+        days_temp = [diff_days[i][_] for _ in idx_closest[i]]
+        dates_diff.append({"date sat": dates_l8[i],
+                           "date quad": dates_temp[idx_best],
+                           "days diff": days_temp[idx_best]})
+    else:
+        dates_diff.append({"date sat": dates_l8[i],
+                           "date quad": dates_quad[idx_closest[i][0]],
+                           "days diff": diff_days[i][idx_closest[i][0]]
+                           }) 
+
+np.mean([ np.abs(_['days diff']) for _ in dates_diff])
 
 #%%
-dates_sat = mdates.date2num(dt_sat)
-dates_quad = mdates.date2num(dt_quad)
-plt.figure()
-plt.plot_date(dates_sat, np.zeros((n_img,1)))
-plt.plot_date(dates_quad, np.ones((len(dates_quad),1)))
-plt.show()
-
-data = pd.read_pickle('data_2016.pkl')
 
-dt_sat = [_.astimezone(au_tz) for _ in data['dt']]
+# load quadbike .mat files 
+foldername = 'data\quadbike\surveys3D'
+folderpath = os.path.join(os.getcwd(), foldername)
+filenames = os.listdir(folderpath)
 
-[ (_ - dt_sat[0]).days for _ in dt_quad]
+# load the satellite shorelines
+sl = output['shorelines']
 
+dates_quad = [datetime(int(_[6:10]), int(_[11:13]), int(_[14:16]), tzinfo= au_tz) for _ in filenames]
+# for each satellite shoreline, load the corresponding 3D survey
+for i in range(len(dates_diff)):
+    idx_closest = np.argmin(np.abs(np.array([(dates_diff[i]['date sat'] - _).days for _ in dates_quad])))
+    survey3d = sio.loadmat(os.path.join(folderpath, filenames[idx_closest]))
     
+    plt.figure()
+    plt.axis('equal')
+    plt.scatter(survey3d['x'], survey3d['y'], s=10, c=survey3d['z'], marker='o', cmap=cm.get_cmap('jet'),
+            label='quad data')
+    plt.plot(sl[i][:,0], sl[i][:,1], 'ko')
+    plt.draw()
     
-dn_sat = []
-for i in range(len(dt_sat)): dn_sat.append(dt_sat[i].toordinal())
-dn_sat = np.array(dn_sat)
-dn_sur = []
-for i in range(len(dt_survey)): dn_sur.append(dt_survey[i].toordinal())
-dn_sur = np.array(dn_sur)
+import statsmodels.api as sm
+lowess = sm.nonparametric.lowess
 
-distances = np.zeros((len(dn_sat),4)).astype('int32')
-indexes = np.zeros((len(dn_sat),2)).astype('int32')
-for i in range(len(dn_sat)):
-    distances[i,0] = np.sort(abs(dn_sat[i] - dn_sur))[0]
-    distances[i,1] = np.sort(abs(dn_sat[i] - dn_sur))[1]
-    distances[i,2] = dt_sat[i].year
-    distances[i,3] = dt_sat[i].month
-    indexes[i,0] = np.where(abs(dn_sat[i] - dn_sur) == np.sort(abs(dn_sat[i] - dn_sur))[0])[0][0]
-    indexes[i,1] = np.where(abs(dn_sat[i] - dn_sur) == np.sort(abs(dn_sat[i] - dn_sur))[1])[0][0]
 
 
-years = [2013, 2014, 2015, 2016]
-months = mdates.MonthLocator()
-days = mdates.DayLocator()
-month_fmt = mdates.DateFormatter('%b')
-f, ax = plt.subplots(4, 1)
-for i, ca in enumerate(ax):
-    ca.xaxis.set_major_locator(months)
-    ca.xaxis.set_major_formatter(month_fmt)
-    ca.xaxis.set_minor_locator(days)
-    ca.set_ylabel(str(years[i]))
-    for j in range(len(dt_sat)):
-        if dt_sat[j].year == years[i]:
-            ca.plot(dt_sat[j],0, 'bo', markerfacecolor='b')
-#f.subplots_adjust(hspace=0)
-#plt.setp([a.get_xticklabels() for a in f.axes[:-1]], visible=False)            
- 
-    
-plt.plot(dt_survey, np.zeros([len(dt_survey),1]), 'bo')
-plt.plot(dt_sat, np.ones([len(dt_sat),1]), 'ro')
-plt.yticks([])
+# For the 1D case:
+x = sl[i][:,0]
+y = sl[i][:,1]
+x0 = x
+f_hat = lo.lowess(x, y, x)
+fig,ax = plt.subplots(1)
+ax.scatter(x,y)
+ax.plot(x0,f_hat,'ro')
 plt.show()
 
+# 2D case (and more...)
+x = np.random.randn(2, 100)
+f = -1 * np.sin(x[0]) + 0.5 * np.cos(x[1]) + 0.2*np.random.randn(100)
+x0 = np.mgrid[-1:1:.1, -1:1:.1]
+x0 = np.vstack([x0[0].ravel(), x0[1].ravel()])
+f_hat = lo.lowess(x, f, x0, kernel=lo.tri_cube)
+from mpl_toolkits.mplot3d import Axes3D
+fig = plt.figure()
+ax = fig.add_subplot(111, projection='3d')
+ax.scatter(x[0], x[1], f)
+ax.scatter(x0[0], x0[1], f_hat, color='r')
+