updated gitignore

.gitignore

@@ -3,4 +3,5 @@
 *.tif
 *.png
 *.mp4
-*.gif
+*.gif
+*.jpg

sl_comparison_NARRA.py

@@ -0,0 +1,382 @@
+# -*- coding: utf-8 -*-
+
+#==========================================================#
+# Compare Narrabeen SDS with 3D quadbike surveys
+#==========================================================#
+
+# Initial settings
+
+import os
+import numpy as np
+import matplotlib.pyplot as plt
+import pdb
+import ee
+
+import matplotlib.dates as mdates
+import matplotlib.cm as cm
+from datetime import datetime, timedelta
+import pickle
+import pytz
+import scipy.io as sio
+import scipy.interpolate as interpolate
+import statsmodels.api as sm
+import skimage.measure as measure
+
+# my functions
+import functions.utils as utils
+
+# some settings
+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
+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_new' + '.pkl'), 'rb') as f:
+    output = pickle.load(f)
+        
+dates_l8 = output['t']
+# convert to AEST
+dates_l8 = [_.astimezone(au_tz) for _ in dates_l8]
+# remove duplicates
+dates_l8_str = [_.strftime('%Y%m%d') for _ in dates_l8]
+dupl = utils.duplicates_dict(dates_l8_str)
+idx_remove = []
+for k,v in dupl.items():
+    
+    idx1 = v[0]
+    idx2 = v[1]
+    
+    c1 = output['cloud_cover'][idx1]
+    c2 = output['cloud_cover'][idx2]
+    g1 = output['acc_georef'][idx1]
+    g2 = output['acc_georef'][idx2]
+    
+    if c1 < c2 - 0.01:
+        idx_remove.append(idx2)
+    elif g1 < g2 - 0.1:
+        idx_remove.append(idx2)
+    else:
+        idx_remove.append(idx1)
+idx_remove = sorted(idx_remove)
+idx_all = np.linspace(0,70,71)
+idx_keep = list(np.where(~np.isin(idx_all,idx_remove))[0])
+output['t'] = [output['t'][k] for k in idx_keep]
+output['shorelines'] = [output['shorelines'][k] for k in idx_keep]
+output['cloud_cover'] = [output['cloud_cover'][k] for k in idx_keep]
+output['acc_georef'] = [output['acc_georef'][k] for k in idx_keep]
+# convert to AEST
+dates_l8 = output['t']
+dates_l8 = [_.astimezone(au_tz) for _ in dates_l8]
+
+# load wave data (already AEST)
+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]
+    
+# load tide data (already AEST)
+filename = 'SydTideData.mat'
+filepath = os.path.join(os.getcwd(), 'data', 'tide', filename)
+tide_data = sio.loadmat(filepath)
+idx = utils.find_indices(tide_data['dates'][:,0], lambda e: e >= dates_l8[0].year and e <= dates_l8[-1].year)
+tide = np.array([tide_data['tide'][i][0] for i in idx])
+dates_tide = [datetime(tide_data['dates'][i,0], tide_data['dates'][i,1],
+                       tide_data['dates'][i,2], tide_data['dates'][i,3],
+                       tide_data['dates'][i,4], tide_data['dates'][i,5],
+                       tzinfo=au_tz) for i in idx]
+
+#%% make a plot of all the dates with wave data
+orange = [255/255,140/255,0]
+blue = [0,191/255,255/255]
+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=orange, label='survey')
+                cbool = False
+            else:
+                plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=orange)
+    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=blue, label='landsat8')
+                cbool = False
+            else:
+                plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=blue)
+    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 difference between dates (quad and sat)
+diff_days = [ [(x - _).days for _ in dates_quad] for x in dates_l8]
+max_diff = 14
+idx_closest = [utils.find_indices(_, lambda e: abs(e) <= max_diff) for _ in diff_days]
+# store in dates_diff dictionnary
+dates_diff = []
+cloud_cover = []
+for i in range(len(idx_closest)):
+    if not idx_closest[i]:
+        continue
+    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]]
+                           }) 
+    # store cloud data
+    cloud_cover.append(output['cloud_cover'][i])
+
+# store wave data
+wave_hsig = []
+for i in range(len(dates_diff)):
+    wave_hsig.append(hsig[np.argmin(np.abs(np.array([(dates_diff[i]['date sat'] - _).total_seconds() for _ in dates_wave])))])
+
+# make a plot
+plt.figure()
+counter = 0
+for i in range(len(dates_diff)):
+    counter = counter + 1
+    if dates_diff[i]['date quad'] > dates_diff[i]['date sat']:
+        date_min = dates_diff[i]['date sat']
+        date_max = dates_diff[i]['date quad']
+        color1 = orange
+        color2 = blue
+    else:
+        date_min = dates_diff[i]['date quad']
+        date_max = dates_diff[i]['date sat']
+        color1 = blue
+        color2 = orange
+    idx_t = utils.find_indices(dates_wave, lambda e : e >= date_min and e <= date_max)
+    hsigmax = np.nanmax([hsig[i] for i in idx_t])
+    hsigmin = np.nanmin([hsig[i] for i in idx_t])
+    if counter > 9:
+        counter = 1
+        plt.figure()
+    ax = plt.subplot(3,3,counter)
+    plt.plot([dates_wave[i] for i in idx_t], [hsig[i] for i in idx_t], 'k-', linewidth=1.5)
+    plt.plot([date_min, date_min], [0, 4.5], color=color2, label='survey')
+    plt.plot([date_max, date_max], [0, 4.5], color=color1, label='landsat8')
+    plt.ylabel('Hs [m]')
+    ax.xaxis.set_major_locator(mdates.DayLocator(tz=au_tz))
+    ax.xaxis.set_minor_locator(mdates.HourLocator(tz=au_tz))
+    ax.xaxis.set_major_formatter(mdates.DateFormatter('%d'))
+    ax.xaxis.set_minor_locator(months)
+    plt.title(dates_diff[i]['date sat'].strftime('%b %Y') + '   (' + str(abs(dates_diff[i]['days diff'])) + ' days)')
+    plt.draw()
+    plt.gcf().subplots_adjust(hspace=0.5)   
+
+# mean day difference
+np.mean([ np.abs(_['days diff']) for _ in dates_diff])
+
+#%% Compare shorelines in elevation
+
+dist_buffer = 50 # buffer of points selected for interpolation
+
+# load quadbike .mat files 
+foldername = 'data\quadbike\surveys3D'
+folderpath = os.path.join(os.getcwd(), foldername)
+filenames = os.listdir(folderpath)
+
+# get the satellite shorelines
+sl = output['shorelines']
+
+# get dates from filenames
+dates_quad = [datetime(int(_[6:10]), int(_[11:13]), int(_[14:16]), tzinfo= au_tz) for _ in filenames]
+
+zav = []
+ztide = []
+sl_gt = []
+for i in range(len(dates_diff)):
+    
+    sl_smooth = sl[i]
+    
+    # select closest 3D survey and load .mat file
+    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]))
+    # reshape to a vector
+    xs = survey3d['x'].reshape(survey3d['x'].shape[0] * survey3d['x'].shape[1])
+    ys = survey3d['y'].reshape(survey3d['y'].shape[0] * survey3d['y'].shape[1])
+    zs = survey3d['z'].reshape(survey3d['z'].shape[0] * survey3d['z'].shape[1])
+    # remove nan values
+    idx_nan = np.isnan(zs)
+    xs = xs[~idx_nan]
+    ys = ys[~idx_nan]
+    zs = zs[~idx_nan]
+    
+    # find water level at the time the image was acquired
+    idx_closest = np.argmin(np.abs(np.array([(dates_diff[i]['date sat'] - _).total_seconds() for _ in dates_tide])))
+    tide_level = tide[idx_closest]
+    ztide.append(tide_level)
+    
+    # find contour corresponding to the water level on 3D surface (if below minimum, add 0.05m increments)
+    if tide_level < np.nanmin(survey3d['z']):
+        tide_level = np.nanmin(survey3d['z'])
+        sl_tide = measure.find_contours(survey3d['z'], tide_level)
+        sl_tide = sl_tide[np.argmax(np.array([len(_) for _ in sl_tide]))]
+        count = 0
+        while len(sl_tide) < 900:
+            count = count + 1
+            tide_level = tide_level + 0.05*count
+            sl_tide = measure.find_contours(survey3d['z'], tide_level)
+            sl_tide = sl_tide[np.argmax(np.array([len(_) for _ in sl_tide]))]
+        print('added ' + str(0.05*count) + ' cm   -  contour with ' + str(len(sl_tide)) + ' points')    
+    else:
+        sl_tide = measure.find_contours(survey3d['z'], tide_level)
+        sl_tide = sl_tide[np.argmax(np.array([len(_) for _ in sl_tide]))]
+    # remove nans
+    if np.any(np.isnan(sl_tide)):
+        index_nan = np.where(np.isnan(sl_tide))[0]
+        sl_tide = np.delete(sl_tide, index_nan, axis=0) 
+    # get x,y coordinates
+    xtide = [survey3d['x'][int(np.round(sl_tide[m,0])), int(np.round(sl_tide[m,1]))] for m in range(sl_tide.shape[0])]
+    ytide = [survey3d['y'][int(np.round(sl_tide[m,0])), int(np.round(sl_tide[m,1]))] for m in range(sl_tide.shape[0])]
+    sl_gt.append(np.transpose(np.array([np.array(xtide), np.array(ytide)])))
+    # interpolate SDS on 3D surface to get elevation (point by point)
+    zq = []
+    for j in range(sl_smooth.shape[0]):
+        xq = sl_smooth[j,0]
+        yq = sl_smooth[j,1]
+        dist_q = np.linalg.norm(np.transpose(np.array([[xq - _ for _ in xs],[yq - _ for _ in ys]])), axis=1)
+        idx_buffer = dist_q <= dist_buffer
+        if sum(idx_buffer) > 0:
+            tck = interpolate.bisplrep(xs[idx_buffer], ys[idx_buffer], zs[idx_buffer])
+            zq.append(interpolate.bisplev(xq, yq, tck))
+            
+    zq = np.array(zq)
+    plt.figure()
+    plt.hist(zq, bins=100)
+    plt.draw()
+#        plt.figure()
+#        plt.axis('equal')
+#        plt.scatter(xs, ys, s=10, c=zs, marker='o', cmap=cm.get_cmap('jet'),
+#                    label='quad data')
+#        plt.plot(xs[idx_buffer], ys[idx_buffer], 'ko')
+#        plt.plot(xq,yq,'ro')
+#        plt.draw()
+        
+    # store the alongshore median elevation
+    zav.append(np.median(utils.reject_outliers(zq, m=2)))
+    
+    # make plot
+    red = [255/255, 0, 0]
+    gray = [0.75, 0.75, 0.75]
+    plt.figure()
+    plt.subplot(121)
+    plt.axis('equal')
+    plt.scatter(xs, ys, s=10, c=zs, marker='o', cmap=cm.get_cmap('jet'),
+            label='3D survey')
+    plt.plot(xtide, ytide, '--', color=gray, linewidth=2.5, label='tide level contour')
+    plt.plot(sl_smooth[:,0], sl_smooth[:,1], '-', color=red, linewidth=2.5, label='SDS')
+#    plt.plot(sl[i][idx_beach,0], sl[i][idx_beach,1], 'w-', linewidth=2)
+    plt.xlabel('Eastings [m]')
+    plt.ylabel('Northings [m]')
+    plt.title('Shoreline comparison')
+    plt.colorbar(label='mAHD')
+    plt.legend()
+    plt.ylim((6266100, 6267000))
+    plt.subplot(122)
+    plt.plot(np.linspace(0,1,len(zq)), zq, 'ko-', markersize=5)
+    plt.plot([0, 1], [zav[i], zav[i]], 'r-', label='median')
+    plt.plot([0, 1], [ztide[i], ztide[i]], 'g--', label = 'measured tide')
+    plt.xlabel('Northings [m]')
+    plt.ylabel('Elevation [mAHD]')
+    plt.title('Alongshore SDS elevation')
+    plt.legend()
+    mng = plt.get_current_fig_manager()                                         
+    mng.window.showMaximized()
+    plt.tight_layout()   
+    plt.draw()
+    
+    print(i)
+
+#%% Calculate some error statistics
+zav = np.array(zav)
+ztide = np.array(ztide)
+
+f = plt.figure()
+plt.subplot(3,1,1)
+plt.bar(np.linspace(1,len(zav),len(zav)), zav-ztide)
+plt.ylabel('Error in z [m]')
+plt.title('Elevation error')
+plt.xticks([])
+plt.draw()
+
+plt.subplot(3,1,2)
+plt.bar(np.linspace(1,len(zav),len(zav)), wave_hsig, color=orange)
+plt.ylabel('Hsig [m]')
+plt.xticks([])
+plt.draw()
+
+plt.subplot(3,1,3)
+plt.bar(np.linspace(1,len(zav),len(zav)), np.array(cloud_cover)*100, color='g')
+plt.ylabel('Cloud cover %')
+plt.xlabel('comparison #')
+plt.grid(False)
+plt.grid(axis='y')
+f.subplots_adjust(hspace=0)
+plt.draw()
+
+np.sqrt(np.mean((zav - ztide)**2))
+
+
+
+#%% plot to show LOWESS smoothing
+#i = 0
+#idx_beach = [np.min(np.linalg.norm(sl[i][k,:] - narrabeach, axis=1)) < dist_thresh for k in range(sl[i].shape[0])]
+#x = sl[i][idx_beach,0]
+#y = sl[i][idx_beach,1]
+#sl_smooth = lowess(x,y, frac=1./10, it = 10)
+#
+#plt.figure()
+#plt.axis('equal')
+#plt.scatter
+#plt.plot(x,y,'bo', linewidth=2, label='original SDS')
+#plt.plot(sl_smooth[:,1], sl_smooth[:,0], 'ro', linewidth=2, label='smoothed SDS')
+#plt.legend()
+#plt.xlabel('Eastings [m]')
+#plt.ylabel('Northings [m]')
+#plt.title('Local weighted scatterplot smoothing (LOWESS)')
+#plt.draw()
+