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@ -17,15 +17,9 @@ from datetime import datetime, timedelta
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import pickle
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import pytz
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import scipy.io as sio
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import scipy.interpolate as interpolate
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import statsmodels.api as sm
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# image processing modules
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import skimage.filters as filters
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import skimage.exposure as exposure
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import skimage.transform as transform
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import skimage.morphology as morphology
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import skimage.measure as measure
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import sklearn.decomposition as decomposition
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from scipy import spatial
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# my functions
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import functions.utils as utils
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import functions.sds as sds
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@ -65,6 +59,8 @@ dates_wave = [datetime(wave_data['dates'][i,0], wave_data['dates'][i,1],
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wave_data['dates'][i,4], wave_data['dates'][i,5],
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tzinfo=au_tz) for i in idx]
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#%% make a plot of all the dates
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orange = [255/255,140/255,0]
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blue = [0,191/255,255/255]
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f = plt.figure()
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months = mdates.MonthLocator()
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month_fmt = mdates.DateFormatter('%b %Y')
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@ -80,18 +76,18 @@ for k in range(len(years)):
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for j in range(len(dates_quad)):
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if dates_quad[j].year == sel_year:
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if cbool:
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plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=[255/255,140/255,0], label='survey')
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plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=orange, label='survey')
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cbool = False
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else:
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plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=[255/255,140/255,0])
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plt.plot([dates_quad[j], dates_quad[j]], [0, hsigmax], color=orange)
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cbool = True
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for j in range(len(dates_l8)):
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if dates_l8[j].year == sel_year:
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if cbool:
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plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=[0,191/255,255/255], label='landsat8')
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plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=blue, label='landsat8')
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cbool = False
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else:
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plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=[0,191/255,255/255])
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plt.plot([dates_l8[j], dates_l8[j]], [0, hsigmax], color=blue)
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if k == 3:
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plt.legend()
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plt.xlim((datetime(sel_year,1,1), datetime(sel_year,12,31, tzinfo=au_tz)))
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@ -101,9 +97,7 @@ for k in range(len(years)):
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ax.xaxis.set_major_formatter(month_fmt)
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f.subplots_adjust(hspace=0.2)
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plt.draw()
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#%%
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# calculate days difference
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#%% calculate days difference
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diff_days = [ [(x - _).days for _ in dates_quad] for x in dates_l8]
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max_diff = 5
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idx_closest = [utils.find_indices(_, lambda e: abs(e) <= max_diff) for _ in diff_days]
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@ -126,7 +120,11 @@ for i in range(len(idx_closest)):
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np.mean([ np.abs(_['days diff']) for _ in dates_diff])
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#%%
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#%% compare shorelines
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dist_thresh = 200 # maximum distance between an sds point and a narrabeen point
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frac_smooth = 1./12 # fraction of the data used for smoothing (the bigger the smoother)
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dist_buffer = 50 # buffer of points selected for interpolation
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# load quadbike .mat files
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foldername = 'data\quadbike\surveys3D'
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@ -136,43 +134,88 @@ filenames = os.listdir(folderpath)
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# load the satellite shorelines
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sl = output['shorelines']
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# load narrabeen beach points (manually digitized)
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with open(os.path.join(os.getcwd(), 'olddata', 'narra_beach' + '.pkl'), 'rb') as f:
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narrabeach = pickle.load(f)
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dates_quad = [datetime(int(_[6:10]), int(_[11:13]), int(_[14:16]), tzinfo= au_tz) for _ in filenames]
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# for each satellite shoreline, load the corresponding 3D survey
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zav = []
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for i in range(len(dates_diff)):
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# select closest 3D survey
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idx_closest = np.argmin(np.abs(np.array([(dates_diff[i]['date sat'] - _).days for _ in dates_quad])))
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survey3d = sio.loadmat(os.path.join(folderpath, filenames[idx_closest]))
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xs = survey3d['x'].reshape(survey3d['x'].shape[0] * survey3d['x'].shape[1])
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ys = survey3d['y'].reshape(survey3d['y'].shape[0] * survey3d['y'].shape[1])
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zs = survey3d['z'].reshape(survey3d['z'].shape[0] * survey3d['z'].shape[1])
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idx_nan = np.isnan(zs)
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xs = xs[~idx_nan]
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ys = ys[~idx_nan]
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zs = zs[~idx_nan]
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# smooth (LOWESS) satellite shoreline
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idx_beach = [np.min(np.linalg.norm(sl[i][k,:] - narrabeach, axis=1)) < dist_thresh for k in range(sl[i].shape[0])]
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sl_smooth = sm.nonparametric.lowess(sl[i][idx_beach,0],sl[i][idx_beach,1], frac=frac_smooth, it = 6)
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sl_smooth = sl_smooth[:,[1,0]]
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# make plot
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plt.figure()
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plt.axis('equal')
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plt.scatter(survey3d['x'], survey3d['y'], s=10, c=survey3d['z'], marker='o', cmap=cm.get_cmap('jet'),
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plt.scatter(xs, ys, s=10, c=zs, marker='o', cmap=cm.get_cmap('jet'),
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label='quad data')
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plt.plot(sl[i][:,0], sl[i][:,1], 'ko')
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plt.plot(sl[i][idx_beach,0], sl[i][idx_beach,1], 'ko-', markersize=3)
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plt.plot(sl_smooth[:,0], sl_smooth[:,1], 'ro-', markersize=3)
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plt.xlabel('Eastings [m]')
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plt.ylabel('Northings [m]')
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plt.title('Local weighted scatterplot smoothing (LOWESS)')
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plt.draw()
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import statsmodels.api as sm
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lowess = sm.nonparametric.lowess
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zq = np.zeros((sl_smooth.shape[0], 1))
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for j in range(sl_smooth.shape[0]):
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xq = sl_smooth[j,0]
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yq = sl_smooth[j,1]
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dist_q = np.linalg.norm(np.transpose(np.array([[xq - _ for _ in xs],[yq - _ for _ in ys]])), axis=1)
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idx_buffer = dist_q <= dist_buffer
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# plt.figure()
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# plt.axis('equal')
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# plt.scatter(xs, ys, s=10, c=zs, marker='o', cmap=cm.get_cmap('jet'),
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# label='quad data')
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# plt.plot(xs[idx_buffer], ys[idx_buffer], 'ko')
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# plt.plot(xq,yq,'ro')
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# plt.draw()
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tck = interpolate.bisplrep(xs[idx_buffer], ys[idx_buffer], zs[idx_buffer])
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zq[j] = interpolate.bisplev(xq, yq, tck)
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# For the 1D case:
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x = sl[i][:,0]
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y = sl[i][:,1]
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x0 = x
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f_hat = lo.lowess(x, y, x)
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fig,ax = plt.subplots(1)
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ax.scatter(x,y)
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ax.plot(x0,f_hat,'ro')
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plt.show()
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# 2D case (and more...)
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x = np.random.randn(2, 100)
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f = -1 * np.sin(x[0]) + 0.5 * np.cos(x[1]) + 0.2*np.random.randn(100)
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x0 = np.mgrid[-1:1:.1, -1:1:.1]
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x0 = np.vstack([x0[0].ravel(), x0[1].ravel()])
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f_hat = lo.lowess(x, f, x0, kernel=lo.tri_cube)
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from mpl_toolkits.mplot3d import Axes3D
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fig = plt.figure()
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ax = fig.add_subplot(111, projection='3d')
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ax.scatter(x[0], x[1], f)
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ax.scatter(x0[0], x0[1], f_hat, color='r')
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zav.append(np.median(zq))
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plt.figure()
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plt.plot(sl_smooth[:,1], zq, 'ko-', markersize=5)
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plt.plot([sl_smooth[0,1], sl_smooth[-1,1]], [zav[i], zav[i]], 'r--')
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plt.xlabel('Northings [m]')
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plt.ylabel('Elevation [mAHD]')
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plt.title('Interpolated SDS elevation')
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plt.draw()
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#%%
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i = 0
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lowess = sm.nonparametric.lowess
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x = sl[i][idx_beach,0]
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y = sl[i][idx_beach,1]
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sl_smooth = lowess(x,y, frac=1./15, it = 6)
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plt.figure()
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plt.axis('equal')
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plt.scatter
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plt.plot(x,y,'bo-', linewidth=2, marker='o',
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color='b', label='original')
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plt.plot(sl_smooth[:,1], sl_smooth[:,0], linewidth=2, marker='o',
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color='r', label='smooth')
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plt.legend()
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plt.xlabel('Eastings [m]')
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plt.ylabel('Northings [m]')
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plt.title('Local weighted scatterplot smoothing (LOWESS)')
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plt.draw()
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