CoastSat_WRL/coastsat/SDS_transects.py

"""
This module contains functions to analyze the 2D shorelines along shore-normal
transects
    
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

# other modules
import skimage.transform as transform
from pylab import ginput
import geopandas as gpd

# CoastSat modules
from coastsat import SDS_tools

def create_transect(origin, orientation, length):
    """
    Create a transect given an origin, orientation and length.
    Points are spaced at 1m intervals.
    
    KV WRL 2018
    
    Arguments:
    -----------
    origin: np.array
        contains the X and Y coordinates of the origin of the transect
    orientation: int
        angle of the transect (anti-clockwise from North) in degrees
    length: int
        length of the transect in metres
        
    Returns:    
    -----------
    transect: np.array
        contains the X and Y coordinates of the transect
        
    """   
    
    # origin of the transect
    x0 = origin[0]
    y0 = origin[1]
    # orientation of the transect
    phi = (90 - orientation)*np.pi/180 
    # create a vector with points at 1 m intervals
    x = np.linspace(0,length,length+1)
    y = np.zeros(len(x))
    coords = np.zeros((len(x),2))
    coords[:,0] = x
    coords[:,1] = y 
    # translate and rotate the vector using the origin and orientation
    tf = transform.EuclideanTransform(rotation=phi, translation=(x0,y0))
    transect = tf(coords)
                
    return transect

def draw_transects(output, settings):
    """
    Draw shore-normal transects interactively on top of the mapped shorelines
    
    Arguments:
    -----------
    output: dict
        contains the extracted shorelines and corresponding metadata
    settings: dict with the following keys
        'inputs': dict
            input parameters (sitename, filepath, polygon, dates, sat_list)
            
    Returns:    
    -----------
    transects: dict
        contains the X and Y coordinates of all the transects drawn.
        Also saves the coordinates as a .geojson as well as a .jpg figure 
        showing the location of the transects.
        
    """   
    
    sitename = settings['inputs']['sitename']
    filepath = os.path.join(settings['inputs']['filepath'], sitename)

    # plot the mapped shorelines
    fig1 = plt.figure()
    ax1 = fig1.add_subplot(111)
    ax1.axis('equal')
    ax1.set_xlabel('Eastings [m]')
    ax1.set_ylabel('Northings [m]')
    ax1.grid(linestyle=':', color='0.5')
    for i in range(len(output['shorelines'])):
        sl = output['shorelines'][i]
        date = output['dates'][i]
        ax1.plot(sl[:, 0], sl[:, 1], '.', markersize=3, label=date.strftime('%d-%m-%Y'))
#    ax1.legend()
    fig1.set_tight_layout(True)
    mng = plt.get_current_fig_manager()                                         
    mng.window.showMaximized()
    ax1.set_title('Click two points to define each transect (first point is the origin of the transect).\n'+
              'When all transects have been defined, click on <ENTER>', fontsize=16)
    
    # initialise transects dict
    transects = dict([])
    counter = 0
    # loop until user breaks it by click <enter>
    while 1:
        # let user click two points
        pts = ginput(n=2, timeout=1e9)
        if len(pts) > 0:
            origin = pts[0]
        # if user presses <enter>, no points are selected
        else:
            # save figure as .jpg
            fig1.gca().set_title('Transect locations', fontsize=16)
            fig1.savefig(os.path.join(filepath, 'jpg_files', sitename + '_transect_locations.jpg'), dpi=200)
            plt.title('Transect coordinates saved as ' + sitename + '_transects.geojson')
            plt.draw()
            # wait 3 seconds for user to visualise the transects that are saved
            ginput(n=1, timeout=3, show_clicks=True)
            plt.close(fig1)
            # break the loop
            break
        
        # add selectect points to the transect dict
        counter = counter + 1
        transect = np.array([pts[0], pts[1]])
        
        # alternative of making the transect the origin, orientation and length
#        temp = np.array(pts[1]) - np.array(origin)
#        phi = np.arctan2(temp[1], temp[0])
#        orientation = -(phi*180/np.pi - 90)
#        length = np.linalg.norm(temp)
#        transect = create_transect(origin, orientation, length)
        
        transects[str(counter)] = transect
        
        # plot the transects on the figure
        ax1.plot(transect[:,0], transect[:,1], 'b-', lw=2.5)
        ax1.plot(transect[0,0], transect[0,1], 'rx', markersize=10)
        ax1.text(transect[-1,0], transect[-1,1], str(counter), size=16,
                 bbox=dict(boxstyle="square", ec='k',fc='w'))
        plt.draw()
        
    # save transects.geojson
    gdf = SDS_tools.transects_to_gdf(transects)
    # set projection
    gdf.crs = {'init':'epsg:'+str(settings['output_epsg'])}
    # save as geojson    
    gdf.to_file(os.path.join(filepath, sitename + '_transects.geojson'), driver='GeoJSON', encoding='utf-8')
    # print the location of the files
    print('Transect locations saved in ' + filepath)
        
    return transects

def compute_intersection(output, transects, settings):
    """
    Computes the intersection between the 2D shorelines and the shore-normal.
    transects. It returns time-series of cross-shore distance along each transect.
    
    Arguments:
    -----------
    output: dict
        contains the extracted shorelines and corresponding metadata
    transects: dict
        contains the X and Y coordinates of each transect
    settings: dict with the following keys
        'along_dist': int
            alongshore distance considered caluclate the intersection
              
    Returns:    
    -----------
    cross_dist: dict
        time-series of cross-shore distance along each of the transects. 
        Not tidally corrected.
        
    """    
    
    shorelines = output['shorelines']
    along_dist = settings['along_dist']
    
    # initialise variables
    chainage_mtx = np.zeros((len(shorelines),len(transects),6))
    idx_points = []
    
    for i in range(len(shorelines)):

        sl = shorelines[i]
        idx_points_all = []
        
        for j,key in enumerate(list(transects.keys())): 
            
            # compute rotation matrix
            X0 = transects[key][0,0]
            Y0 = transects[key][0,1]
            temp = np.array(transects[key][-1,:]) - np.array(transects[key][0,:])
            phi = np.arctan2(temp[1], temp[0])
            Mrot = np.array([[np.cos(phi), np.sin(phi)],[-np.sin(phi), np.cos(phi)]])
    
            # calculate point to line distance between shoreline points and the transect
            p1 = np.array([X0,Y0])
            p2 = transects[key][-1,:]
            d_line = np.abs(np.cross(p2-p1,sl-p1)/np.linalg.norm(p2-p1))
            # calculate the distance between shoreline points and the origin of the transect
            d_origin = np.array([np.linalg.norm(sl[k,:] - p1) for k in range(len(sl))])
            # find the shoreline points that are close to the transects and to the origin
            # the distance to the origin is hard-coded here to 1 km 
            idx_dist = np.logical_and(d_line <= along_dist, d_origin <= 1000)
            # find the shoreline points that are in the direction of the transect (within 90 degrees)
            temp_sl = sl - np.array(transects[key][0,:])
            phi_sl = np.array([np.arctan2(temp_sl[k,1], temp_sl[k,0]) for k in range(len(temp_sl))])
            diff_angle = (phi - phi_sl)
            idx_angle = np.abs(diff_angle) < np.pi/2
            # combine the transects that are close in distance and close in orientation
            idx_close = np.where(np.logical_and(idx_dist,idx_angle))[0]
            idx_points_all.append(idx_close)        
            
            # in case there are no shoreline points close to the transect 
            if len(idx_close) == 0:
                chainage_mtx[i,j,:] = np.tile(np.nan,(1,6))
            else:
                # change of base to shore-normal coordinate system
                xy_close = np.array([sl[idx_close,0],sl[idx_close,1]]) - np.tile(np.array([[X0],
                                   [Y0]]), (1,len(sl[idx_close])))
                xy_rot = np.matmul(Mrot, xy_close)
                    
                # compute mean, median, max, min and std of chainage position
                n_points = len(xy_rot[0,:])
                mean_cross = np.nanmean(xy_rot[0,:])
                median_cross = np.nanmedian(xy_rot[0,:])
                max_cross = np.nanmax(xy_rot[0,:])
                min_cross = np.nanmin(xy_rot[0,:])
                std_cross = np.nanstd(xy_rot[0,:])
                # store all statistics
                chainage_mtx[i,j,:] = np.array([mean_cross, median_cross, max_cross,
                            min_cross, n_points, std_cross])
    
        # store the indices of the shoreline points that were used
        idx_points.append(idx_points_all)
     
    # format into dictionnary
    chainage = dict([])
    chainage['mean'] = chainage_mtx[:,:,0]
    chainage['median'] = chainage_mtx[:,:,1]
    chainage['max'] = chainage_mtx[:,:,2]
    chainage['min'] = chainage_mtx[:,:,3]
    chainage['npoints'] = chainage_mtx[:,:,4]
    chainage['std'] = chainage_mtx[:,:,5]
    chainage['idx_points'] = idx_points
        
    # only return the median
    cross_dist = dict([])
    for j,key in enumerate(list(transects.keys())): 
        cross_dist[key] = chainage['median'][:,j]    
    
    return cross_dist
update from Github version of CoastSat 5 years ago			`"""`
			`This module contains functions to analyze the 2D shorelines along shore-normal`
			`transects`
update 6 years ago
update from Github version of CoastSat 5 years ago			`Author: Kilian Vos, Water Research Laboratory, University of New South Wales`
update 6 years ago			`"""`

			`# load modules`
			`import os`
			`import numpy as np`
			`import matplotlib.pyplot as plt`
			`import pdb`

			`# other modules`
			`import skimage.transform as transform`
			`from pylab import ginput`
update from GitHub.com 6 years ago			`import geopandas as gpd`
update 6 years ago
update from Github version of CoastSat 5 years ago			`# CoastSat modules`
update from GitHub.com 6 years ago			`from coastsat import SDS_tools`
update 6 years ago
			`def create_transect(origin, orientation, length):`
			`"""`
update from Github version of CoastSat 5 years ago			`Create a transect given an origin, orientation and length.`
			`Points are spaced at 1m intervals.`

			`KV WRL 2018`
update 6 years ago
			`Arguments:`
			`-----------`
update from Github version of CoastSat 5 years ago			`origin: np.array`
			`contains the X and Y coordinates of the origin of the transect`
			`orientation: int`
			`angle of the transect (anti-clockwise from North) in degrees`
			`length: int`
			`length of the transect in metres`
update 6 years ago
			`Returns:`
			`-----------`
update from Github version of CoastSat 5 years ago			`transect: np.array`
			`contains the X and Y coordinates of the transect`
update 6 years ago
update from Github version of CoastSat 5 years ago			`"""`

			`# origin of the transect`
update 6 years ago			`x0 = origin[0]`
			`y0 = origin[1]`
			`# orientation of the transect`
			`phi = (90 - orientation)*np.pi/180`
			`# create a vector with points at 1 m intervals`
			`x = np.linspace(0,length,length+1)`
			`y = np.zeros(len(x))`
			`coords = np.zeros((len(x),2))`
			`coords[:,0] = x`
			`coords[:,1] = y`
			`# translate and rotate the vector using the origin and orientation`
			`tf = transform.EuclideanTransform(rotation=phi, translation=(x0,y0))`
			`transect = tf(coords)`

			`return transect`

			`def draw_transects(output, settings):`
			`"""`
update from Github version of CoastSat 5 years ago			`Draw shore-normal transects interactively on top of the mapped shorelines`
update 6 years ago
			`Arguments:`
			`-----------`
update from Github version of CoastSat 5 years ago			`output: dict`
			`contains the extracted shorelines and corresponding metadata`
			`settings: dict with the following keys`
			`'inputs': dict`
			`input parameters (sitename, filepath, polygon, dates, sat_list)`

update 6 years ago			`Returns:`
			`-----------`
update from Github version of CoastSat 5 years ago			`transects: dict`
			`contains the X and Y coordinates of all the transects drawn.`
			`Also saves the coordinates as a .geojson as well as a .jpg figure`
			`showing the location of the transects.`
update 6 years ago
update from Github version of CoastSat 5 years ago			`"""`

update 6 years ago			`sitename = settings['inputs']['sitename']`
update from GitHub.com 6 years ago			`filepath = os.path.join(settings['inputs']['filepath'], sitename)`
update 6 years ago
update from Github version of CoastSat 5 years ago			`# plot the mapped shorelines`
update 6 years ago			`fig1 = plt.figure()`
			`ax1 = fig1.add_subplot(111)`
			`ax1.axis('equal')`
			`ax1.set_xlabel('Eastings [m]')`
			`ax1.set_ylabel('Northings [m]')`
			`ax1.grid(linestyle=':', color='0.5')`
			`for i in range(len(output['shorelines'])):`
			`sl = output['shorelines'][i]`
			`date = output['dates'][i]`
			`ax1.plot(sl[:, 0], sl[:, 1], '.', markersize=3, label=date.strftime('%d-%m-%Y'))`
			`# ax1.legend()`
			`fig1.set_tight_layout(True)`
			`mng = plt.get_current_fig_manager()`
			`mng.window.showMaximized()`
			`ax1.set_title('Click two points to define each transect (first point is the origin of the transect).\n'+`
			`'When all transects have been defined, click on <ENTER>', fontsize=16)`

update from Github version of CoastSat 5 years ago			`# initialise transects dict`
update 6 years ago			`transects = dict([])`
			`counter = 0`
			`# loop until user breaks it by click <enter>`
			`while 1:`
update from GitHub.com 6 years ago			`# let user click two points`
			`pts = ginput(n=2, timeout=1e9)`
			`if len(pts) > 0:`
update 6 years ago			`origin = pts[0]`
update from Github version of CoastSat 5 years ago			`# if user presses <enter>, no points are selected`
update from GitHub.com 6 years ago			`else:`
update from Github version of CoastSat 5 years ago			`# save figure as .jpg`
update 6 years ago			`fig1.gca().set_title('Transect locations', fontsize=16)`
update from GitHub.com 6 years ago			`fig1.savefig(os.path.join(filepath, 'jpg_files', sitename + '_transect_locations.jpg'), dpi=200)`
update from GitHub.com 6 years ago			`plt.title('Transect coordinates saved as ' + sitename + '_transects.geojson')`
update from GitHub.com 6 years ago			`plt.draw()`
update from Github version of CoastSat 5 years ago			`# wait 3 seconds for user to visualise the transects that are saved`
update from GitHub.com 6 years ago			`ginput(n=1, timeout=3, show_clicks=True)`
update from GitHub.com 6 years ago			`plt.close(fig1)`
update from Github version of CoastSat 5 years ago			`# break the loop`
update 6 years ago			`break`
update from Github version of CoastSat 5 years ago
			`# add selectect points to the transect dict`
update 6 years ago			`counter = counter + 1`
update from GitHub.com 6 years ago			`transect = np.array([pts[0], pts[1]])`

			`# alternative of making the transect the origin, orientation and length`
			`# temp = np.array(pts[1]) - np.array(origin)`
			`# phi = np.arctan2(temp[1], temp[0])`
			`# orientation = -(phi*180/np.pi - 90)`
			`# length = np.linalg.norm(temp)`
			`# transect = create_transect(origin, orientation, length)`

update 6 years ago			`transects[str(counter)] = transect`

			`# plot the transects on the figure`
update from GitHub.com 6 years ago			`ax1.plot(transect[:,0], transect[:,1], 'b-', lw=2.5)`
update 6 years ago			`ax1.plot(transect[0,0], transect[0,1], 'rx', markersize=10)`
			`ax1.text(transect[-1,0], transect[-1,1], str(counter), size=16,`
			`bbox=dict(boxstyle="square", ec='k',fc='w'))`
			`plt.draw()`

update from Github version of CoastSat 5 years ago			`# save transects.geojson`
update from GitHub.com 6 years ago			`gdf = SDS_tools.transects_to_gdf(transects)`
			`# set projection`
			`gdf.crs = {'init':'epsg:'+str(settings['output_epsg'])}`
			`# save as geojson`
			`gdf.to_file(os.path.join(filepath, sitename + '_transects.geojson'), driver='GeoJSON', encoding='utf-8')`
update from Github version of CoastSat 5 years ago			`# print the location of the files`
update from GitHub.com 6 years ago			`print('Transect locations saved in ' + filepath)`
update 6 years ago
			`return transects`

			`def compute_intersection(output, transects, settings):`
			`"""`
update from Github version of CoastSat 5 years ago			`Computes the intersection between the 2D shorelines and the shore-normal.`
			`transects. It returns time-series of cross-shore distance along each transect.`
update 6 years ago
			`Arguments:`
			`-----------`
update from Github version of CoastSat 5 years ago			`output: dict`
			`contains the extracted shorelines and corresponding metadata`
			`transects: dict`
			`contains the X and Y coordinates of each transect`
			`settings: dict with the following keys`
			`'along_dist': int`
			`alongshore distance considered caluclate the intersection`

update 6 years ago			`Returns:`
			`-----------`
update from Github version of CoastSat 5 years ago			`cross_dist: dict`
			`time-series of cross-shore distance along each of the transects.`
			`Not tidally corrected.`
update 6 years ago
update from Github version of CoastSat 5 years ago			`"""`

update 6 years ago			`shorelines = output['shorelines']`
			`along_dist = settings['along_dist']`

			`# initialise variables`
			`chainage_mtx = np.zeros((len(shorelines),len(transects),6))`
			`idx_points = []`

			`for i in range(len(shorelines)):`

			`sl = shorelines[i]`
			`idx_points_all = []`

			`for j,key in enumerate(list(transects.keys())):`

			`# compute rotation matrix`
			`X0 = transects[key][0,0]`
			`Y0 = transects[key][0,1]`
			`temp = np.array(transects[key][-1,:]) - np.array(transects[key][0,:])`
			`phi = np.arctan2(temp[1], temp[0])`
			`Mrot = np.array([[np.cos(phi), np.sin(phi)],[-np.sin(phi), np.cos(phi)]])`

			`# calculate point to line distance between shoreline points and the transect`
			`p1 = np.array([X0,Y0])`
			`p2 = transects[key][-1,:]`
			`d_line = np.abs(np.cross(p2-p1,sl-p1)/np.linalg.norm(p2-p1))`
			`# calculate the distance between shoreline points and the origin of the transect`
			`d_origin = np.array([np.linalg.norm(sl[k,:] - p1) for k in range(len(sl))])`
			`# find the shoreline points that are close to the transects and to the origin`
			`# the distance to the origin is hard-coded here to 1 km`
update from GitHub.com 6 years ago			`idx_dist = np.logical_and(d_line <= along_dist, d_origin <= 1000)`
			`# find the shoreline points that are in the direction of the transect (within 90 degrees)`
			`temp_sl = sl - np.array(transects[key][0,:])`
			`phi_sl = np.array([np.arctan2(temp_sl[k,1], temp_sl[k,0]) for k in range(len(temp_sl))])`
			`diff_angle = (phi - phi_sl)`
			`idx_angle = np.abs(diff_angle) < np.pi/2`
			`# combine the transects that are close in distance and close in orientation`
			`idx_close = np.where(np.logical_and(idx_dist,idx_angle))[0]`
			`idx_points_all.append(idx_close)`
update 6 years ago
			`# in case there are no shoreline points close to the transect`
update from GitHub.com 6 years ago			`if len(idx_close) == 0:`
update 6 years ago			`chainage_mtx[i,j,:] = np.tile(np.nan,(1,6))`
			`else:`
			`# change of base to shore-normal coordinate system`
			`xy_close = np.array([sl[idx_close,0],sl[idx_close,1]]) - np.tile(np.array([[X0],`
			`[Y0]]), (1,len(sl[idx_close])))`
			`xy_rot = np.matmul(Mrot, xy_close)`

			`# compute mean, median, max, min and std of chainage position`
			`n_points = len(xy_rot[0,:])`
			`mean_cross = np.nanmean(xy_rot[0,:])`
			`median_cross = np.nanmedian(xy_rot[0,:])`
			`max_cross = np.nanmax(xy_rot[0,:])`
			`min_cross = np.nanmin(xy_rot[0,:])`
			`std_cross = np.nanstd(xy_rot[0,:])`
			`# store all statistics`
			`chainage_mtx[i,j,:] = np.array([mean_cross, median_cross, max_cross,`
			`min_cross, n_points, std_cross])`

			`# store the indices of the shoreline points that were used`
			`idx_points.append(idx_points_all)`

			`# format into dictionnary`
			`chainage = dict([])`
			`chainage['mean'] = chainage_mtx[:,:,0]`
			`chainage['median'] = chainage_mtx[:,:,1]`
			`chainage['max'] = chainage_mtx[:,:,2]`
			`chainage['min'] = chainage_mtx[:,:,3]`
			`chainage['npoints'] = chainage_mtx[:,:,4]`
			`chainage['std'] = chainage_mtx[:,:,5]`
			`chainage['idx_points'] = idx_points`

			`# only return the median`
			`cross_dist = dict([])`
			`for j,key in enumerate(list(transects.keys())):`
			`cross_dist[key] = chainage['median'][:,j]`

			`return cross_dist`