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plot_utils.py
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plot_utils.py
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from .metrics import slope, sspb, mdsa
from .meta import get_sensor_label
from .utils import closest_wavelength, ignore_warnings
from collections import defaultdict as dd
from pathlib import Path
import numpy as np
def add_identity(ax, *line_args, **line_kwargs):
'''
Add 1 to 1 diagonal line to a plot.
https://stackoverflow.com/questions/22104256/does-matplotlib-have-a-function-for-drawing-diagonal-lines-in-axis-coordinates
Usage: add_identity(plt.gca(), color='k', ls='--')
'''
line_kwargs['label'] = line_kwargs.get('label', '_nolegend_')
identity, = ax.plot([], [], *line_args, **line_kwargs)
def callback(axes):
low_x, high_x = ax.get_xlim()
low_y, high_y = ax.get_ylim()
lo = max(low_x, low_y)
hi = min(high_x, high_y)
identity.set_data([lo, hi], [lo, hi])
callback(ax)
ax.callbacks.connect('xlim_changed', callback)
ax.callbacks.connect('ylim_changed', callback)
ann_kwargs = {
'transform' : ax.transAxes,
'textcoords' : 'offset points',
'xycoords' : 'axes fraction',
'fontname' : 'monospace',
'xytext' : (0,0),
'zorder' : 25,
'va' : 'top',
'ha' : 'left',
}
ax.annotate(r'$\mathbf{1:1}$', xy=(0.87,0.99), size=11, **ann_kwargs)
def _create_metric(metric, y_true, y_est, longest=None, label=None):
''' Create a position-aligned string which shows the performance via a single metric '''
# if label == None: label = metric.__name__.replace('SSPB', '\\beta').replace('MdSA', '\\varepsilon\\thinspace').replace('Slope','S\\thinspace')
if label == None: label = metric.__name__.replace('SSPB', 'Bias').replace('MdSA', 'Error')
if longest == None: longest = len(label)
ispct = metric.__qualname__ in ['mape', 'sspb', 'mdsa'] # metrics which are percentages
diff = longest-len(label.replace('^',''))
space = r''.join([r'\ ']*diff + [r'\thinspace']*diff)
prec = (1 if abs(metric(y_true, y_est)) < 100 and metric.__name__ not in ['N'] else 0) if ispct or metric.__name__ in ['N'] else 3
# prec = 1 if abs(metric(y_true, y_est)) < 100 else 0
stat = f'{metric(y_true, y_est):.{prec}f}'
perc = r'$\small{\mathsf{\%}}$' if ispct else ''
return rf'$\mathtt{{{label}}}{space}:$ {stat}{perc}'
def _create_stats(y_true, y_est, metrics, title=None):
''' Create stat box strings for all metrics, assuming there is only a single target feature '''
longest = max([len(metric.__name__.replace('SSPB', 'Bias').replace('MdSA', 'Error').replace('^','')) for metric in metrics])
statbox = [_create_metric(m, y_true, y_est, longest=longest) for m in metrics]
if title is not None:
statbox = [rf'$\mathbf{{\underline{{{title}}}}}$'] + statbox
return statbox
def _create_multi_feature_stats(y_true, y_est, metrics, labels=None):
''' Create stat box strings for a single metric, assuming there are multiple target features '''
if labels == None:
labels = [f'Feature {i}' for i in range(y_true.shape[1])]
assert(len(labels) == y_true.shape[1] == y_est.shape[1]), f'Number of labels does not match number of features: {labels} - {y_true.shape}'
title = metrics[0].__name__.replace('SSPB', 'Bias').replace('MdSA', 'Error')
longest = max([len(label.replace('^','')) for label in labels])
statbox = [_create_metric(metrics[0], y1, y2, longest=longest, label=lbl) for y1, y2, lbl in zip(y_true.T, y_est.T, labels)]
statbox = [rf'$\mathbf{{\underline{{{title}}}}}$'] + statbox
return statbox
def add_stats_box(ax, y_true, y_est, metrics=[mdsa, sspb, slope], bottom_right=False, bottom=False, right=False, x=0.025, y=0.97, fontsize=16, label=None):
''' Add a text box containing a variety of performance statistics, to the given axis '''
import matplotlib.pyplot as plt
plt.rc('text', usetex=True)
plt.rcParams['mathtext.default']='regular'
create_box = _create_stats if len(y_true.shape) == 1 or y_true.shape[1] == 1 else _create_multi_feature_stats
stats_box = '\n'.join( create_box(y_true, y_est, metrics, label) )
ann_kwargs = {
'transform' : ax.transAxes,
'textcoords' : 'offset points',
'xycoords' : 'axes fraction',
'fontname' : 'monospace',
'xytext' : (0,0),
'zorder' : 25,
'va' : 'top',
'ha' : 'left',
'bbox' : {
'facecolor' : 'white',
'edgecolor' : 'black',
'alpha' : 0.7,
}
}
ann = ax.annotate(stats_box, xy=(x,y), size=fontsize, **ann_kwargs)
bottom |= bottom_right
right |= bottom_right
# Switch location to (approximately) the bottom right corner
if bottom or right or bottom_right:
plt.gcf().canvas.draw()
bbox_orig = ann.get_tightbbox(plt.gcf().canvas.renderer).transformed(ax.transAxes.inverted())
new_x = bbox_orig.x0
new_y = bbox_orig.y1
if bottom:
new_y = bbox_orig.y1 - bbox_orig.y0 + (1 - y)
ann.set_y(new_y)
new_y += 0.06
if right:
new_x = 1 - (bbox_orig.x1 - bbox_orig.x0) + x
ann.set_x(new_x)
new_x -= 0.04
ann.xy = (new_x, new_y)
return ann
def draw_map(*lonlats, scale=0.2, world=False, us=True, eu=False, labels=[], ax=None, gray=False, res='i', **scatter_kws):
''' Helper function to plot locations on a global map '''
import matplotlib.pyplot as plt
from matplotlib.transforms import Bbox
from mpl_toolkits.axes_grid1.inset_locator import TransformedBbox, BboxPatch, BboxConnector
from mpl_toolkits.axes_grid1.inset_locator import zoomed_inset_axes, inset_axes
from mpl_toolkits.basemap import Basemap
from itertools import chain
PLOT_WIDTH = 8
PLOT_HEIGHT = 6
WORLD_MAP = {'cyl': [-90, 85, -180, 180]}
US_MAP = {
'cyl' : [24, 49, -126, -65],
'lcc' : [23, 48, -121, -64],
}
EU_MAP = {
'cyl' : [34, 65, -12, 40],
'lcc' : [30.5, 64, -10, 40],
}
def mark_inset(ax, ax2, m, m2, MAP, loc1=(1, 2), loc2=(3, 4), **kwargs):
"""
https://stackoverflow.com/questions/41610834/basemap-projection-geos-controlling-mark-inset-location
Patched mark_inset to work with Basemap.
Reason: Basemap converts Geographic (lon/lat) to Map Projection (x/y) coordinates
Additionally: set connector locations separately for both axes:
loc1 & loc2: tuple defining start and end-locations of connector 1 & 2
"""
axzoom_geoLims = (MAP['cyl'][2:], MAP['cyl'][:2])
rect = TransformedBbox(Bbox(np.array(m(*axzoom_geoLims)).T), ax.transData)
pp = BboxPatch(rect, fill=False, **kwargs)
ax.add_patch(pp)
p1 = BboxConnector(ax2.bbox, rect, loc1=loc1[0], loc2=loc1[1], **kwargs)
ax2.add_patch(p1)
p1.set_clip_on(False)
p2 = BboxConnector(ax2.bbox, rect, loc1=loc2[0], loc2=loc2[1], **kwargs)
ax2.add_patch(p2)
p2.set_clip_on(False)
return pp, p1, p2
if world:
MAP = WORLD_MAP
kwargs = {'projection': 'cyl', 'resolution': res}
elif us:
MAP = US_MAP
kwargs = {'projection': 'lcc', 'lat_0':30, 'lon_0':-98, 'resolution': res}#, 'epsg':4269}
elif eu:
MAP = EU_MAP
kwargs = {'projection': 'lcc', 'lat_0':48, 'lon_0':27, 'resolution': res}
else:
raise Exception('Must plot world, US, or EU')
kwargs.update(dict(zip(['llcrnrlat', 'urcrnrlat', 'llcrnrlon', 'urcrnrlon'], MAP['lcc' if 'lcc' in MAP else 'cyl'])))
if ax is None: f = plt.figure(figsize=(PLOT_WIDTH, PLOT_HEIGHT), edgecolor='w')
m = Basemap(ax=ax, **kwargs)
ax = m.ax if m.ax is not None else plt.gca()
if not world:
m.readshapefile(Path(__file__).parent.joinpath('map_files', 'st99_d00').as_posix(), name='states', drawbounds=True, color='k', linewidth=0.5, zorder=11)
m.fillcontinents(color=(0,0,0,0), lake_color='#9abee0', zorder=9)
if not gray:
m.drawrivers(linewidth=0.2, color='blue', zorder=9)
m.drawcountries(color='k', linewidth=0.5)
else:
m.drawcountries(color='w')
# m.bluemarble()
if not gray:
if us or eu: m.shadedrelief(scale=0.3 if world else 1)
else:
# m.arcgisimage(service='ESRI_Imagery_World_2D', xpixels = 2000, verbose= True)
m.arcgisimage(service='World_Imagery', xpixels = 2000, verbose= True)
else:
pass
# lats = m.drawparallels(np.linspace(MAP[0], MAP[1], 13))
# lons = m.drawmeridians(np.linspace(MAP[2], MAP[3], 13))
# lat_lines = chain(*(tup[1][0] for tup in lats.items()))
# lon_lines = chain(*(tup[1][0] for tup in lons.items()))
# all_lines = chain(lat_lines, lon_lines)
# for line in all_lines:
# line.set(linestyle='-', alpha=0.0, color='w')
if labels:
colors = ['aqua', 'orangered', 'xkcd:tangerine', 'xkcd:fresh green', 'xkcd:clay', 'magenta', 'xkcd:sky blue', 'xkcd:greyish blue', 'xkcd:goldenrod', ]
markers = ['o', '^', 's', '*', 'v', 'X', '.', 'x',]
mod_cr = False
assert(len(labels) == len(lonlats)), [len(labels), len(lonlats)]
for i, (label, lonlat) in enumerate(zip(labels, lonlats)):
lonlat = np.atleast_2d(lonlat)
if 'color' not in scatter_kws or mod_cr:
scatter_kws['color'] = colors[i]
scatter_kws['marker'] = markers[i]
mod_cr = True
ax.scatter(*m(lonlat[:,0], lonlat[:,1]), label=label, zorder=12, **scatter_kws)
ax.legend(loc='lower left', prop={'weight':'bold', 'size':8}).set_zorder(20)
else:
for lonlat in lonlats:
if len(lonlat):
lonlat = np.atleast_2d(lonlat)
s = ax.scatter(*m(lonlat[:,0], lonlat[:,1]), zorder=12, **scatter_kws)
# plt.colorbar(s, ax=ax)
hide_kwargs = {'axis':'both', 'which':'both'}
hide_kwargs.update(dict([(k, False) for k in ['bottom', 'top', 'left', 'right', 'labelleft', 'labelbottom']]))
ax.tick_params(**hide_kwargs)
for axis in ['top','bottom','left','right']:
ax.spines[axis].set_linewidth(1.5)
ax.spines[axis].set_zorder(50)
# plt.axis('off')
if world:
size = 0.35
if us:
loc = (0.25, -0.1) if eu else (0.35, -0.01)
ax_ins = inset_axes(ax, width=PLOT_WIDTH*size, height=PLOT_HEIGHT*size, loc='center', bbox_to_anchor=loc, bbox_transform=ax.transAxes, axes_kwargs={'zorder': 5})
scatter_kws.update({'s': 6})
m2 = draw_map(*lonlats, labels=labels, ax=ax_ins, **scatter_kws)
mark_inset(ax, ax_ins, m, m2, US_MAP, loc1=(1,1), loc2=(2,2), edgecolor='grey', zorder=3)
mark_inset(ax, ax_ins, m, m2, US_MAP, loc1=[3,3], loc2=[4,4], edgecolor='grey', zorder=0)
if eu:
ax_ins = inset_axes(ax, width=PLOT_WIDTH*size, height=PLOT_HEIGHT*size, loc='center', bbox_to_anchor=(0.75, -0.05), bbox_transform=ax.transAxes, axes_kwargs={'zorder': 5})
scatter_kws.update({'s': 6})
m2 = draw_map(*lonlats, us=False, eu=True, labels=labels, ax=ax_ins, **scatter_kws)
mark_inset(ax, ax_ins, m, m2, EU_MAP, loc1=(1,1), loc2=(2,2), edgecolor='grey', zorder=3)
mark_inset(ax, ax_ins, m, m2, EU_MAP, loc1=[3,3], loc2=[4,4], edgecolor='grey', zorder=0)
return m
def default_dd(d={}, f=lambda k: k):
''' Helper function to allow defaultdicts whose default value returned is the queried key '''
class key_dd(dd):
''' DefaultDict which allows the key as the default value '''
def __missing__(self, key):
if self.default_factory is None:
raise KeyError(key)
val = self[key] = self.default_factory(key)
return val
return key_dd(f, d)
@ignore_warnings
def plot_scatter(y_test, benchmarks, bands, labels, products, sensor, title=None, methods=None, n_col=3, img_outlbl=''):
import matplotlib.patheffects as pe
import matplotlib.ticker as ticker
import matplotlib.pyplot as plt
import seaborn as sns
folder = Path('scatter_plots')
folder.mkdir(exist_ok=True, parents=True)
product_labels = default_dd({
'chl' : 'Chl\\textit{a}',
'aph' : '\\textit{a}_{ph}',
'tss' : 'TSS',
'cdom': '\\textit{a}_{CDOM}',
})
product_units = default_dd({
'chl' : '[mg m^{-3}]',
'tss' : '[g m^{-3}]',
'aph' : '[m^{-1}]',
'cdom': '[m^{-1}]',
}, lambda k: '')
model_labels = default_dd({
'MDN' : 'MDN_{A}',
})
products = [p for i,p in enumerate(np.atleast_1d(products)) if i < y_test.shape[-1]]
plt.rc('text', usetex=True)
plt.rcParams['mathtext.default']='regular'
# plt.rcParams['mathtext.fontset'] = 'stix'
# plt.rcParams['font.family'] = 'cm'
# Only plot certain bands
if len(labels) > 3 and 'chl' not in products:
product_bands = {
'default' : [443, 482, 561, 655],
# 'aph' : [443, 530],
}
target = [closest_wavelength(w, bands) for w in product_bands.get(products[0], product_bands['default'])]
plot_label = [w in target for w in bands]
plot_order = ['MDN', 'QAA', 'GIOP']
plot_bands = True
else:
plot_label = [True] * len(labels)
plot_order = methods
plot_bands = False
if plot_order is None:
if 'chl' in products and len(products) == 1:
benchmarks = benchmarks['chl']
if 'MLP' in benchmarks:
plot_order = ['MDN', 'MLP', 'SVM', 'XGB', 'KNN', 'OC3']
else:
plot_order = ['MDN', 'Smith_Blend', 'OC6', 'Mishra_NDCI', 'Gons_2band', 'Gilerson_2band']
elif len(products) == 3 and all(k in products for k in ['chl', 'tss', 'cdom']):
n_col = 3
plot_order = {
'chl' : ['MDN', 'OC3','Smith_Blend'],
'tss' : ['MDN', 'SOLID', 'Novoa'],
'cdom' : ['MDN', 'Ficek', 'Mannino'],
}
plot_label = [True] * 3
plot_bands = True
labels = [(p,label) for label in labels for p in products if p in label]
print('Plotting labels:', [l for i,l in enumerate(labels) if plot_label[i]])
assert(len(labels) == y_test.shape[-1]), [len(labels), y_test.shape]
# plot_order = [p for p in plot_order if p in benchmarks]
fig_size = 5
n_col = max(n_col, sum(plot_label))
n_row = max(1,int(not plot_bands) + int(0.5 + len(plot_order) / (1 if plot_bands else n_col)) -1)
if isinstance(plot_order, dict): n_row = 3
if plot_bands:
n_col, n_row = n_row, n_col
fig, axes = plt.subplots(n_row, n_col, figsize=(fig_size*n_col, fig_size*n_row+1))
axes = [ax for axs in np.atleast_1d(axes) for ax in np.atleast_1d(axs)]
colors = ['xkcd:sky blue', 'xkcd:tangerine', 'xkcd:fresh green', 'xkcd:greyish blue', 'xkcd:goldenrod', 'xkcd:clay', 'xkcd:bluish purple', 'xkcd:reddish']
print('Order:', plot_order)
print(f'Plot size: {n_row} x {n_col}')
print(labels)
curr_idx = 0
full_ax = fig.add_subplot(111, frameon=False)
full_ax.tick_params(labelcolor='none', top=False, bottom=False, left=False, right=False, pad=10)
estimate_label = 'Estimated' #'Satellite-derived'
x_pre = 'Measured'
y_pre = estimate_label.replace('-', '\\textbf{-}')
plabel = f'{product_labels[products[0]]} {product_units[products[0]]}'
xlabel = fr'$\mathbf{{{x_pre} {plabel}}}$'
ylabel = fr'$\mathbf{{{y_pre}}}$'+'' +fr'$\mathbf{{ {plabel}}}$'
if not isinstance(plot_order, dict):
full_ax.set_xlabel(xlabel.replace(' ', '\ '), fontsize=20, labelpad=10)
full_ax.set_ylabel(ylabel.replace(' ', '\ '), fontsize=20, labelpad=10)
else:
full_ax.set_xlabel(fr'$\mathbf{{{x_pre} Product}}$'.replace(' ', '\ '), fontsize=20, labelpad=10)
s_lbl = title or get_sensor_label(sensor).replace('-',' ')
n_pts = len(y_test)
title = fr'$\mathbf{{\underline{{\large{{{s_lbl}}}}}}}$' + '\n' + fr'$\small{{\mathit{{N\small{{=}}}}{n_pts}}}$'
# full_ax.set_title(title.replace(' ', '\ '), fontsize=24, y=1.06)
if isinstance(plot_order, dict):
full_ax.set_title(fr'$\mathbf{{\underline{{\large{{{s_lbl}}}}}}}$'.replace(' ', '\ '), fontsize=24, y=1.03)
for plt_idx, (label, y_true) in enumerate(zip(labels, y_test.T)):
if not plot_label[plt_idx]: continue
product, title = label
plabel = f'{product_labels[product]} {product_units[product]}'
for est_idx, est_lbl in enumerate(plot_order[product] if isinstance(plot_order, dict) else plot_order):
if plt_idx >= (len(plot_order[product]) if isinstance(plot_order, dict) else benchmarks[est_lbl].shape[1]): continue
if isinstance(plot_order, dict) and est_lbl not in benchmarks[product]:
axes[curr_idx].tick_params(labelcolor='none', top=False, bottom=False, left=False, right=False)
axes[curr_idx].axis('off')
curr_idx += 1
continue
y_est = benchmarks[product][est_lbl] if isinstance(plot_order, dict) else benchmarks[est_lbl][..., plt_idx]
ax = axes[curr_idx]
cidx = (curr_idx % n_col) if plot_bands else curr_idx
color = colors[cidx]
first_row = curr_idx < n_col #(curr_idx % n_row) == 0
last_row = curr_idx >= ((n_row-1)*n_col) #((curr_idx+1) % n_row) == 0
first_col = (curr_idx % n_col) == 0
last_col = ((curr_idx+1) % n_col) == 0
print(curr_idx, first_row, last_row, first_col, last_col, est_lbl, product, plabel)
y_est_log = np.log10(y_est).flatten()
y_true_log = np.log10(y_true).flatten()
curr_idx += 1
l_kws = {'color': color, 'path_effects': [pe.Stroke(linewidth=4, foreground='k'), pe.Normal()], 'zorder': 22, 'lw': 1}
s_kws = {'alpha': 0.4, 'color': color}#, 'edgecolor': 'grey'}
if est_lbl == 'MDN':
[i.set_linewidth(5) for i in ax.spines.values()]
est_lbl = 'MDN_{A}'
# est_lbl = 'MDN-I'
else:
est_lbl = est_lbl.replace('Mishra_','').replace('Gons_2band', 'Gons').replace('Gilerson_2band', 'GI2B').replace('Smith_','').replace('Cao_XGB','BST')#.replace('Cao_', 'Cao\ ')
if product not in ['chl', 'tss', 'cdom'] and last_col:
ax2 = ax.twinx()
ax2.tick_params(labelcolor='none', top=False, bottom=False, left=False, right=False, pad=0)
ax2.grid(False)
ax2.set_yticklabels([])
ax2.set_ylabel(fr'$\mathbf{{{bands[plt_idx]:.0f}nm}}$', fontsize=20)
minv = -2 if product == 'cdom' else -1 # int(np.nanmin(y_true_log)) - 1 if product != 'aph' else -4
maxv = 3 if product == 'tss' else 3 if product == 'chl' else 1 #int(np.nanmax(y_true_log)) + 1 if product != 'aph' else 1
loc = ticker.LinearLocator(numticks=int(round(maxv-minv+1.5)))
fmt = ticker.FuncFormatter(lambda i, _: r'$10$\textsuperscript{%i}'%i)
ax.set_ylim((minv, maxv))
ax.set_xlim((minv, maxv))
ax.xaxis.set_major_locator(loc)
ax.yaxis.set_major_locator(loc)
ax.xaxis.set_major_formatter(fmt)
ax.yaxis.set_major_formatter(fmt)
# if not last_row: ax.set_xticklabels([])
# elif isinstance(plot_order, dict): ax.set_xlabel(fr'$\mathbf{{{x_pre}}}$'+'' +fr'$\mathbf{{ {plabel}}}$'.replace(' ', '\ '), fontsize=18)
if not first_col: ax.set_yticklabels([])
elif isinstance(plot_order, dict):
ylabel = fr'$\mathbf{{{y_pre}}}$'+'' +fr'$\mathbf{{ {plabel}}}$' + '\n' + fr'$\small{{\mathit{{N\small{{=}}}}{np.isfinite(y_true_log).sum()}}}$'
ax.set_ylabel(ylabel.replace(' ', '\ '), fontsize=18)
valid = np.logical_and(np.isfinite(y_true_log), np.isfinite(y_est_log))
if valid.sum():
sns.regplot(y_true_log[valid], y_est_log[valid], ax=ax, scatter_kws=s_kws, line_kws=l_kws, fit_reg=True, truncate=False, robust=True, ci=None)
kde = sns.kdeplot(y_true_log[valid], y_est_log[valid], shade=False, ax=ax, bw='scott', n_levels=4, legend=False, gridsize=100, color=color)
# kde.collections[2].set_alpha(0)
invalid = np.logical_and(np.isfinite(y_true_log), ~np.isfinite(y_est_log))
if invalid.sum():
ax.scatter(y_true_log[invalid], [minv]*(invalid).sum(), color='r', alpha=0.4, label=r'$\mathbf{%s\ invalid}$' % (invalid).sum())
ax.legend(loc='lower right', prop={'weight':'bold', 'size': 16})
add_identity(ax, ls='--', color='k', zorder=20)
if valid.sum():
add_stats_box(ax, y_true[valid], y_est[valid])
if first_row or not plot_bands or (isinstance(plot_order, dict) and plot_order[product][est_idx] != 'MDN'):
if est_lbl == 'BST':
# ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$'+'\n'+r'$\small{\textit{(Cao\ et\ al.\ 2020)}}$', fontsize=18)
ax.set_title(r'$\small{\textit{(Cao\ et\ al.\ 2020)}}$' + '\n' + fr'$\mathbf{{\large{{{est_lbl}}}}}$', fontsize=18, linespacing=0.95)
elif est_lbl == 'Ficek':
# ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$'+'\n'+r'$\small{\textit{(Cao\ et\ al.\ 2020)}}$', fontsize=18)
ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$' + r'$\small{\textit{\ (et\ al.\ 2011)}}$', fontsize=18, linespacing=0.95)
elif est_lbl == 'Mannino':
# ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$'+'\n'+r'$\small{\textit{(Cao\ et\ al.\ 2020)}}$', fontsize=18)
ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$' + r'$\small{\textit{\ (et\ al.\ 2008)}}$', fontsize=18, linespacing=0.95)
elif est_lbl == 'Novoa':
# ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$'+'\n'+r'$\small{\textit{(Cao\ et\ al.\ 2020)}}$', fontsize=18)
ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$' + r'$\small{\textit{\ (et\ al.\ 2017)}}$', fontsize=18, linespacing=0.95)
else: ax.set_title(fr'$\mathbf{{\large{{{est_lbl}}}}}$', fontsize=18)
ax.tick_params(labelsize=18)
ax.grid('on', alpha=0.3)
u_label = ",".join([o.split('_')[0] for o in plot_order]) if len(plot_order) < 10 else f'{n_row}x{n_col}'
filename = folder.joinpath(f'{img_outlbl}{",".join(products)}_{sensor}_{n_pts}test_{u_label}.png')
plt.tight_layout()
# plt.subplots_adjust(wspace=0.35)
plt.savefig(filename.as_posix(), dpi=100, bbox_inches='tight', pad_inches=0.1,)
plt.show()