#!/usr/bin/env python3 import matplotlib.pyplot as plt import numpy as np import bisect import ast import math import argparse import sys #TODO: use YAML/ruamel.yaml for configuration file. def read_definition(filename): ddict = {} with open(filename, "r") as f: for line in f: items = line.split(': ', 1) if len(items) == 2: ddict[items[0]] = ast.literal_eval(items[1]) return ddict def conveyance(numH, n_co, xregion, zregion, zmin, zmax): p_i = [] # wetted perimeter A_i = [] # area r_h = [] # hydraulic radius h_i = [] # list of heights K_i = [] # conveyance Q_i = [] # discharge x_sub = [[] for i in range(numH)] # list of x values in subregion z_sub = [[] for i in range(numH)] # list of z values in subregion for i in range(numH): h_i.append(zmin + (i+1)*(zmax-zmin)/numH) #print(zregion[zregion < h_i[i]]) booleanArray = zregion < h_i[i] #print(booleanArray[i]) x_sub[i] += list(xregion[booleanArray]) z_sub[i] += list(zregion[booleanArray]) for interval in range(len(xregion)-1): if booleanArray[interval+1] != booleanArray[interval]: x_extra = xregion[interval] \ + (h_i[i] - zregion[interval])\ *(xregion[interval+1] - xregion[interval])\ /(zregion[interval+1] - zregion[interval]) bisect.insort(x_sub[i], x_extra) # add intercept value ind_x = x_sub[i].index(x_extra) z_sub[i].insert(ind_x, h_i[i]) # add height value #print(z_sub[i]) dp = 0 dA = 0 eps = 1e-06 for j in range(len(x_sub[i])-1): if (abs(z_sub[i][j+1] - h_i[i]) > eps or abs(z_sub[i][j] - h_i[i]) > eps): dp += np.hypot(x_sub[i][j+1] - x_sub[i][j], abs(z_sub[i][j+1] - z_sub[i][j])) #print(dp) # calculate area using trapezium rule dA += (h_i[i] - (z_sub[i][j+1] + z_sub[i][j])/2)\ *(x_sub[i][j+1] - x_sub[i][j]) #print('Area =', dA) p_i.append(dp) A_i.append(dA) r_h.append(A_i[i]/p_i[i]) # ratio of area and wetted perimeter #print('hydraulic radius =', r_h[i]) K_i.append(A_i[i]*(1/n_co)*r_h[i]**(2/3)) # conveyance Q_i.append(K_i[i]*abs(slope)**0.5) # discharge return p_i, A_i, r_h, h_i, K_i, Q_i def plot_region(ydata, labely, xdata1, labelx1, xdata2, labelx2, xdata3, labelx3, titlep): plt.xlabel(labelx1) plt.ylabel(labely) plt.title(titlep) plt.plot(xdata1, ydata) plt.show() plt.xlabel(labelx2) plt.ylabel(labely) plt.title(titlep) plt.plot(xdata2, ydata) plt.show() plt.xlabel(labelx3) plt.ylabel(labely) plt.title(titlep) plt.plot(xdata3, ydata) plt.show() def save_bc(outputfile): with open(outputfile, 'w') as f: f.write('{:6} {:>2} {:>2} {:>10}\n'.format('#x', 'c', 'q', 'h')) for ind_z, (xitem, zitem) in enumerate(zip(xin, zin)): panel_x = bisect.bisect(markers, xitem) if csa[ind_z] == 0: # wall boundary condition f.write('{:6.2f} {:>2}\n'.format(xitem, 2)) elif panel_x == panel[ind_p]: # imposed discharge within part-filled panel f.write('{:6.2f} {:>2} {:10.6f} {:9.6f}\n'.format( xitem, btype, -csa[ind_z]*panel_target_flow/csa_p[panel_x], h_extra-zitem)) else: # imposed discharge within filled panels f.write('{:6.2f} {:>2} {:10.6f} {:9.6f}\n'.format( xitem, btype, -csa[ind_z]*Q_i[panel_x][-1]/csa_p[panel_x], zmax-zitem)) def interp(extra2, max1, min1, max2, min2): # use similar triangles to perform linear interpolation extra1 = min1 + (max1 - min1)*(extra2 - min2)/(max2 - min2) return extra1 # read command line argument: parser = argparse.ArgumentParser( description="generate FullSWOF boundary files") parser.add_argument("location", help="boundary location") args = parser.parse_args() if args.location == 'top': inputFilename = "boundaryTop.txt" outputFilename = "BCTop.txt" elif args.location == 'bottom': inputFilename = "boundaryBottom.txt" outputFilename = "BCBottom.txt" elif args.location == 'left': inputFilename = "boundaryLeft.txt" outputFilename = "BCLeft.txt" elif args.location == 'right': inputFilename = "boundaryRight.txt" outputFilename = "BCRight.txt" # read boundary definition file: definition_dict = read_definition(inputFilename) #for dd in definition_dict: # print(definition_dict[dd]) btype = definition_dict["type"] # boundary type (1--5) slope = definition_dict["slope"] # slope at top boundary target_flow = definition_dict["target_flow"] # imposed discharge plotting = definition_dict["plotting"] # enable or disable plotting printing = definition_dict["printing"] # enable or disable printing n_co = definition_dict["n_co"] # Manning's 'n' coefficients # TODO: use weighted mean 'n' values. See http://help.floodmodeller.com/\ # floodmodeller/Technical/1D_nodes/River_section/River_Section.htm. Note: # weighted mean calculation requires roughness map. markers = definition_dict["markers"] # distances from corner point panel = definition_dict["panel"] # panel fill order ztol = definition_dict["ztol"] # tolerance in overtopping height numH = definition_dict["numH"] # number of height intervals # print(len(markers)) # with open('./1D_top.txt', "r") as data: # xch, ych, zch = np.loadtxt(data, delimiter=' ', unpack=True) # Fit with polyfit # m, c = np.polyfit(ych, zch, 1) # print('gradient =', m, 'intercept =', c) # read topography: with open("./topography.txt", "r") as topo: xtp, ytp, ztp = np.loadtxt(topo, delimiter=' ', unpack=True) xmax = (xtp[0]+xtp[-1]) # domain extent in x-direction ymax = (ytp[0]+ytp[-1]) # domain extent in y-direction ncols = int(math.sqrt(len(xtp)*xmax/ymax)) # number of cells in x-direction nrows = int(len(xtp)/ncols) # number of cells in y-direction dX = xmax/ncols # cell size print('cell size, dX (/m) =', dX) #print(ncols, nrows) # extract slices from height data array. Note: xyz format uses ncols # blocks, with nrows lines per block. if args.location == 'top': xin = xtp[nrows-1:len(xtp):nrows] yin = 2*ytp[nrows-1:len(xtp):nrows] - ytp[nrows-2:len(xtp):nrows] zin = 2*ztp[nrows-1:len(xtp):nrows] - ztp[nrows-2:len(xtp):nrows] elif args.location == 'bottom': xin = xtp[0:len(xtp):nrows] yin = 2*ytp[0:len(xtp):nrows] - ytp[1:len(xtp):nrows] zin = 2*ztp[0:len(xtp):nrows] - ztp[1:len(xtp):nrows] elif args.location == 'left': xin = 2*xtp[:nrows] - xtp[nrows:2*nrows] yin = ytp[:nrows] zin = 2*ztp[:nrows] - ztp[nrows:2*nrows] elif args.location == 'right': xin = 2*xtp[nrows*(ncols-1):] - xtp[nrows*(ncols-2):nrows*(ncols-1)] yin = ytp[nrows*(ncols-1):] zin = 2*ztp[nrows*(ncols-1):] - ztp[nrows*(ncols-2):nrows*(ncols-1)] # print(xin) num_panels = len(panel) # number of panels across boundary # convert marker co-ordinates to array indices: marker_ind = [0] for i in range(len(markers)): marker_ind.append(int(markers[i]/dX)) if args.location == 'left' or args.location == 'right': marker_ind.append(nrows) elif args.location == 'top' or args.location == 'bottom': marker_ind.append(ncols) # print(marker_ind) xregion = [] zregion = [] zmin = [] for p in range(num_panels): # identify regions: xregion.append(xin[marker_ind[p]:marker_ind[p+1]]) zregion.append(zin[marker_ind[p]:marker_ind[p+1]]) # identify minimum heights within each panel: zmin.append(zregion[p].min()) # xregion_west = xin[100:281] # zregion_west = zin[100:281] # xregion_east = xin[300:408] # zregion_east = zin[300:408] # print(zregion) # print(xin[12:20]) for i in range(len(zmin)): print('zmin[{0}] (/m) = {1:.3f}'.format(i, zmin[i])) # channel overtopping height (minimum of left bank and right bank heights): zmax = min(zregion[panel[0]][0], zregion[panel[0]][-1]) - ztol print('maximum water elevation in channel, zmax (/m) =', zmax) #print(h_i) p_i = [[] for _ in range(num_panels)] A_i = [[] for _ in range(num_panels)] r_h = [[] for _ in range(num_panels)] h_i = [[] for _ in range(num_panels)] K_i = [[] for _ in range(num_panels)] Q_i = [[] for _ in range(num_panels)] for p in range(num_panels): if p == panel[0]-1 and zregion[p][-1] < zmax: # ensure end node in region to the left of channel is dry: xregion[p] = np.append(xregion[p], xin[marker_ind[p]]) zregion[p] = np.append(zregion[p], zin[marker_ind[p]]) if p == panel[0]+1 and zregion[p][0] < zmax: # ensure start node in region to the right of channel is dry: xregion[p] = np.insert(xregion[p], 0, xin[marker_ind[p]-1]) zregion[p] = np.insert(zregion[p], 0, zin[marker_ind[p]-1]) if zmax > zmin[p]: p_i[p], A_i[p], r_h[p], h_i[p], K_i[p], Q_i[p] = conveyance( numH, n_co[p], xregion[p], zregion[p], zmin[p], zmax) if plotting: plot_region( h_i[p]-zmin[p], 'water level / m', r_h[p], 'hydraulic radius / m', K_i[p], r'conveyance / $m^3/s$', Q_i[p], r'discharge / $m^3/s$', 'Panel {}'.format(p)) if printing: ratingCurveFileName = 'panel{}_{}.dat'.format(p,args.location) with open(ratingCurveFileName, 'w') as f: f.write('{:14} {:18} {:12} {:10}\n'.format( '#water level', 'hydraulic radius', 'conveyance', 'discharge')) f.write('{:14} {:18} {:12} {:10}\n'.format( '#/ m', '/ m', '/ m^3/s', '/ m^3/s')) for h in range(numH): f.write('{:7.6f} {:16.6f} {:19.6f} {:11.6f}\n'.format( h_i[p][h]-zmin[p],r_h[p][h],K_i[p][h],Q_i[p][h])) else: p_i[p], A_i[p], r_h[p], h_i[p], K_i[p], Q_i[p] = [ [0] * numH for _ in range(6)] # sort list of discharge lists according to panel fill order: sortedQ = [Q_i[i] for i in panel] # create cumulative discharge list: total_flow = np.cumsum([item[-1] for item in sortedQ]) print('total_flow = ', total_flow) # target_flow_west = target_flow - Q_i[-1] - Q_i_east[-1] # calculate velocity: note dependence on hydraulic radius velocity_channel = Q_i[panel[0]][-1]/A_i[panel[0]][-1] # velocity_east = Q_i_east[-1]/A_i_east[-1] # print(target_flow_west) # find part-filled panel: if total_flow[-1] > target_flow: ind_p = bisect.bisect(total_flow, target_flow) else: print('Error: imposed discharge is higher than total capacity of panels.') sys.exit() print('index of part-filled panel:', ind_p) # calculate target flow in part-filled panel: if ind_p == 0: panel_target_flow = target_flow else: panel_target_flow = target_flow - total_flow[ind_p-1] # find insertion point for target flow value: ind_q = bisect.bisect(Q_i[panel[ind_p]], panel_target_flow) print('insertion point =', ind_q) # find height at target flow by linear interpolation h_extra = interp( panel_target_flow, h_i[panel[ind_p]][ind_q], h_i[panel[ind_p]][ind_q-1], Q_i[panel[ind_p]][ind_q], Q_i[panel[ind_p]][ind_q-1]) print('heights:', h_i[panel[ind_p]][ind_q-1], h_extra, h_i[panel[ind_p]][ind_q]) # find area at target flow by linear interpolation A_extra = interp( h_extra, A_i[panel[ind_p]][ind_q], A_i[panel[ind_p]][ind_q-1], h_i[panel[ind_p]][ind_q], h_i[panel[ind_p]][ind_q-1]) print('hydraulic radii:', r_h[panel[ind_p]][ind_q-1], r_h[panel[ind_p]][ind_q]) velocity_panel = panel_target_flow/A_extra print('velocities:', velocity_channel, velocity_panel) csa = np.zeros(len(xin)) # cross-sectional area of element csa_p = np.zeros(num_panels) # cross-sectional area of panel for i, p in enumerate(panel): if i < ind_p: # panels are filled area_sum = 0 for m in range(marker_ind[p], marker_ind[p+1]): csa[m] = max(0, (zmax - zin[m])*dX) area_sum += csa[m] csa_p[p] = area_sum elif i == ind_p: # panel is part-filled area_sum = 0 for m in range(marker_ind[p], marker_ind[p+1]): csa[m] = max(0, (h_extra - zin[m])*dX) area_sum += csa[m] csa_p[p] = area_sum else: # panel is empty for m in range(marker_ind[p], marker_ind[p+1]): csa[m] = 0 csa_p[p] = 0 #print('csa_p[0] = {} csa_p[1] = {}'.format(csa_p[0], csa_p[1])) #print('A_i_west = {} A_i = {} A_i_east = {}'.format(A_extra, A_i[-1], A_i_east[-1])) save_bc(outputFilename)