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PDAC2024 / exercises /block_modelling.py

Hamza Salhi

Update exercises/block_modelling.py

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	import numpy as np
	import pandas as pd
	import streamlit as st
	import plotly.express as px
	import matplotlib.pyplot as plt
	import scipy.spatial as spatial
	from sklearn.neighbors import KDTree
	import warnings
	from multiprocessing.pool import ThreadPool as Pool
	from matplotlib.patches import Ellipse
	warnings.simplefilter("ignore")
	from scipy.interpolate import Rbf
	import matplotlib as mpl
	import plotly.graph_objects as go
	from plotly.subplots import make_subplots

	color_seq = np.array(['grey', 'blue', 'green', 'yellow', 'orange', 'red', 'purple', 'purple'])
	cog = np.array([-99, 0., 1.0, 1.5, 2.0, 2.5, 3.0, 3.0001])
	cmap = mpl.colors.ListedColormap(color_seq)
	norm = mpl.colors.BoundaryNorm(cog, cmap.N)

	#@st.cache

	def get_text_block(fname):
	# this is how to read a block of text:
	path = ""
	f = open(fname, "r")
	# and then write it to the app
	return f.read();


	def pad_matrix(mat, dim=2):
	mat = np.array(mat)
	if dim == 2:
	mat = np.pad(mat, (0, 1), 'constant', constant_values=(1))
	mat[-1, -1] = 0.
	else:
	mat = np.pad(mat, (0, 1), 'constant', constant_values=(1, 1))
	return mat;


	def variogram(h, var, nugget):
	gamma = nugget
	for i in range(2):
	gam = (var[i, 0]) * ((3 * h) / (2 * var[i, 1]) - (h ** 3) / (2 * var[i, 1] ** 3))
	gam[h > var[i, 1]] = var[i, 0]
	gamma += gam
	gamma[h == 0] = 0.
	return gamma;


	def OK(x, y, var, nugget):
	# x is samples
	# y in blocks
	x = np.array(x)
	y = np.array(y)
	xx = spatial.distance_matrix(x, x)
	xx_gamma = variogram(xx, var, nugget)
	xx_gamma = pad_matrix(xx_gamma)
	xy_gamma = variogram(y, var, nugget)
	xy_gamma = pad_matrix(xy_gamma, dim=1)
	xx_inv = np.linalg.inv(xx_gamma)
	return np.dot(xy_gamma, xx_inv)[:-1];


	def rotate(pts, rot):
	c = np.cos(np.radians(rot))
	s = np.sin(np.radians(rot))
	rotmat = np.array([[c, -s], [s, c]])
	pts = np.dot(pts, rotmat)
	return pts;

	def plot_samps(df):
	aniso = (300.) / (750.)
	fig, ax = plt.subplots(figsize=(15, 15 * aniso))
	xx, yy = dgrid(1.)
	rbfi = Rbf(df.YPT, df.ZPT, df.AU_G_T, function='cubic')
	zz = rbfi(xx, yy)
	ax.contour(xx, yy, zz, cog, colors=color_seq, alpha=0.5)
	ax.imshow(zz, origin='lower', extent=(0., 750, 0., 300.), alpha=0.2, cmap=cmap, norm=norm)
	scat = ax.scatter(df.YPT, df.ZPT, c=df.AU_G_T, cmap=cmap, norm=norm, edgecolor="black", s=40)
	cbar = fig.colorbar(scat, ticks=cog)
	cbar.set_label('Au g/t', rotation=0)
	plt.xlim((0,750))
	plt.ylim((0, 300))
	plt.xlabel('X')
	plt.ylabel('Y')
	return fig, ax;

	def plot_blocks(block_size, grades, df):
	aniso = (300. + block_size) / (750. + block_size)
	fig, ax = plt.subplots(figsize=(15, 15 * aniso))
	xx, yy = dgrid(block_size)
	extents = (0., 750 + block_size, 0., 300. + block_size)
	ax.imshow(np.reshape(grades, xx.shape), origin='lower', extent=extents, alpha=0.8, cmap=cmap, norm=norm)
	scat = ax.scatter(df.YPT, df.ZPT, c=df.AU_G_T, cmap=cmap, norm=norm, edgecolor="black", s=40)
	cbar = fig.colorbar(scat, ticks=cog)
	cbar.set_label('Au g/t', rotation=0)
	plt.xlim((0, 750))
	plt.ylim((0, 300))
	plt.xlabel('X')
	plt.ylabel('Y')
	return fig, ax;


	def dgrid(block_size=5.):
	x = np.arange(0., 750. + block_size, block_size)
	y = np.arange(0., 300. + block_size, block_size)
	return np.meshgrid(x, y);

	def gtcurve(grades, block_size):

	cogs = [0., 0.25, 0.5, 0.75, 1.0, 1.25, 1.5, 1.75, 2.0]
	grades[grades<0.] = 0.
	grades[np.isnan(grades)]=-99.
	bt = block_size*2.7

	g = []
	t = []
	c = []

	for cog in cogs:
	filt = grades>cog
	if np.sum(filt) > 0:
	g.append(np.average(grades[filt]))
	t.append(np.sum(filt)*bt)
	c.append(cog)

	return pd.DataFrame({'COG':c, 'Tonnes':t, 'Grade':g});

	def block_modelling():

	st.title("Block Modelling Exercise")
	st.markdown("The figure below is an orthogonal projection of full width intercepts within a narrow vein.")
	st.markdown("## Visual Trend Analysis")
	df = pd.read_csv("data//sim_pts.csv")
	df = df[df.use==1].copy().reset_index(drop=True)
	fig, ax = plot_samps(df)
	st.pyplot(fig)
	xx = spatial.distance_matrix(df[['YPT', 'ZPT']], df[['YPT', 'ZPT']])
	xx = np.array(xx)

	#-----------------------------------------------------------------------------------------------------------------#
	# Variogram
	# ----------------------------------------------------------------------------------------------------------------#

	st.markdown("## Variogram")
	st.markdown("The omni-directional variogram is given in the chart that follows." +
	" Keep in mind that no direction has been chosen and that the range shown will be shorter than" +
	" the longest direction and longer than the shortest direction. Your job is to estimate the range" +
	" in the longest direction given your observations from the plot above.")

	g1, g2 = np.meshgrid(df.AU_G_T, df.AU_G_T)
	col1, col2, col3 = st.beta_columns((1,1,1))

	with col1:
	st.markdown('#### Experimental Variogram')
	lag_dist = st.slider('Lag Distance', min_value=5., max_value=50., value=10., step=5.,key='var_lag')
	vartype = st.selectbox('Select Experimental Variogram Type',
	options=['Traditional Variogram', 'Correlogram'],
	index=0)
	with col2:
	st.markdown('#### Variogram Model (Variances)')
	nugget = st.slider('Nugget Effect',min_value=0.0, max_value=1.0, value=0.1, step=0.05)
	c1 = st.slider('C1', min_value=0.0, max_value=1.0-nugget, value=0.0, step=0.05)
	c2 = 1.0 - (c1 + nugget)
	with col3:
	st.markdown('#### Variogram Model (Ranges)')
	r1 = st.slider('Range s1', min_value=0.0, max_value=200.0, value=10., step=5., key='k1')
	r2 = st.slider('Range s2', min_value=0.0, max_value=200.0, value=10., step=5., key='k2')

	var = np.array([[c1, r1], [c2, r2]])
	h = np.arange(0.,200., 1.)
	vmod = variogram(h, var, nugget)
	lags = np.arange(lag_dist, 200., lag_dist)
	gammas = np.zeros(len(lags))
	numpairs = np.zeros(len(lags))
	fig, ax = plt.subplots()

	for i, lag in enumerate(lags):
	filt = (xx>=lag-lag_dist0.75)&(xx<lag+lag_dist0.75)
	sq_dif = np.sum((g1[filt]-g2[filt])**2)
	m = np.average(g1[filt])
	s = np.std(g1[filt])
	ns = np.sum(filt)
	numpairs[i] = ns

	if vartype == 'Traditional Variogram':
	gammas[i] = sq_dif/(2*float(np.sum(filt))) / np.var(df.AU_G_T)
	else:
	gammas[i] = (np.sum(g1[filt]g2[filt]) - nsm*2)/(nss**2)
	gammas[i] = 1.0 - gammas[i]
	ax.annotate(str(ns), (lag, gammas[i]+0.05), size=5)

	ax.bar(lags, numpairs/np.max(numpairs), width=lag_dist/2)
	ax.plot(lags, gammas, '-or', markeredgecolor='k', markersize=4, markeredgewidth=0.5)
	ax.plot(h, vmod, '-g', markeredgecolor='k', markersize=4, markeredgewidth=0.5)

	plt.xlim((0, 200))
	plt.ylim((0, 1.5))
	ax.plot([0., 200], [1.0, 1.0], '--k')
	plt.xlabel("Separation Distance/Lag Distance")
	plt.ylabel("Gamma")
	st.pyplot(fig)

	#-----------------------------------------------------------------------------------------------------------------#
	# Set up search ellipse
	# ----------------------------------------------------------------------------------------------------------------#
	st.markdown("## Search Ellipse")

	scol1, scol2 = st.beta_columns((1, 1))
	with scol1:
	st.markdown('#### Ellipse Shape')
	rot = st.number_input('Pick a Rotation (-360 to 360)', min_value=-360., max_value=360., value=0., step=5.)
	rot = (360. - rot)
	srange_major = st.number_input('Major Axis Range', min_value=10., max_value=500., value=100., step=5.)
	srange_minor = st.number_input('Minor Axis Range', min_value=10., max_value=500., value=100., step=5.)
	with scol2:
	st.markdown('#### Sample Selection')
	min_samps = st.number_input("Minimum Samples", min_value=1, max_value=40, value=2, step=1)
	max_samps = st.number_input("Maximum Samples", min_value=1, max_value=40, value=10, step=1)
	fig, ax = plot_samps(df)
	e = Ellipse(xy=[350, 150], width=srange_minor * 2, height=srange_major * 2, angle=rot, linewidth=2)
	ax.add_artist(e)
	e.set_facecolor('None')
	e.set_edgecolor('black')
	st.pyplot(fig)

	#-----------------------------------------------------------------------------------------------------------------#
	# Block modelling parameters
	# ----------------------------------------------------------------------------------------------------------------#

	st.markdown("## Additional Parameters")

	bcol1, bcol2 = st.beta_columns((1, 1))
	with bcol1:
	block_size = st.number_input('Block Size', min_value=5., max_value=100., value=10., step=5.)
	with bcol2:
	id_exponent = st.number_input('ID Exponent', min_value=0.0, max_value=10.0, value=2., step=1.)

	if st.button("Run Interpolation"):

	xx, yy = dgrid(block_size)
	grid = np.array([xx.flatten(), yy.flatten()]).transpose()
	points = np.array(df.loc[:, ['YPT', 'ZPT']])

	AUID = np.zeros(len(grid))
	AUNN = np.zeros(len(grid))
	AUOK = np.zeros(len(grid))
	NDIST = np.zeros(len(grid))

	AUID[:] = np.nan
	AUID[:] = np.nan
	AUNN[:] = np.nan
	AUOK[:] = np.nan
	NDIST[:] = np.nan

	# rotate
	# grid2 = grid.copy()
	grid = rotate(grid, rot)
	points = rotate(points, rot)
	# apply anisotropy
	grid[:, 0] *= srange_major / srange_minor
	points[:, 0] *= srange_major / srange_minor

	point_tree = KDTree(points)
	idx, dist = point_tree.query_radius(grid, r=srange_major, return_distance=True, sort_results=True)

	for i, ix in enumerate(idx):
	mx = max_samps
	if len(ix) <= mx:
	mx = len(ix)
	dists = dist[i][:mx]
	grades = np.array(df.loc[ix[:mx], 'AU_G_T'])
	if len(ix) >= min_samps:
	AUID[i] = (np.average(grades, weights=1.0 / dists ** id_exponent))
	AUNN[i] = (grades[0])
	NDIST[i] = (dists[0])
	OK_weights = OK(x=points[ix[:mx]], y=dists, var=var, nugget=nugget)
	AUOK[i] = (np.sum(OK_weights * grades))


	fig, ax = plot_blocks(block_size, AUNN, df)
	plt.title("Nearest Neighbour Interpolation")
	st.pyplot(fig)

	fig, ax = plot_blocks(block_size, AUID, df)
	plt.title("Inverse Distance Interpolation")
	st.pyplot(fig)

	fig, ax = plot_blocks(block_size, AUOK, df)
	plt.title("Ordinary Kriging Interpolation")
	st.pyplot(fig)

	st.write("Grade Tonnage Curve:")
	fig = make_subplots(specs=[[{"secondary_y": True}]])
	curve = gtcurve(AUNN, block_size)
	fig.add_trace(
	go.Scatter(x=curve.COG, y=curve.Tonnes, name="NN Tonnes"),
	secondary_y=False,
	)
	fig.add_trace(
	go.Scatter(x=curve.COG, y=curve.Grade, name="NN Grade"),
	secondary_y=True,
	)

	curve = gtcurve(AUID, block_size)
	fig.add_trace(
	go.Scatter(x=curve.COG, y=curve.Tonnes, name="ID Tonnes"),
	secondary_y=False,
	)
	fig.add_trace(
	go.Scatter(x=curve.COG, y=curve.Grade, name="ID Grade"),
	secondary_y=True,
	)

	curve = gtcurve(AUOK, block_size)
	fig.add_trace(
	go.Scatter(x=curve.COG, y=curve.Tonnes, name="OK Tonnes"),
	secondary_y=False,
	)
	fig.add_trace(
	go.Scatter(x=curve.COG, y=curve.Grade, name="OK Grade"),
	secondary_y=True,
	)

	fig.update_xaxes(title_text="Cut-off (Au g/t)")
	fig.update_yaxes(title_text="Tonnes", secondary_y=False)
	fig.update_yaxes(title_text="Grade (Au g/t)", secondary_y=True)

	st.plotly_chart(fig)