##// END OF EJS Templates
schain
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Rewrite controller, remove MPDecorator to units (keep for plots an writers) use of queues for interproc comm instead of zmq, self operations are no longer supported
Rewrite controller, remove MPDecorator to units (keep for plots an writers) use of queues for interproc comm instead of zmq, self operations are no longer supported
Juan C. Espinoza - - Load All Authors

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jroplot_parameters.py
341 lines | 10.8 KiB | text/x-python | PythonLexer
/ schainpy / model / graphics / jroplot_parameters.py
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import os
import datetime
import numpy
from schainpy.model.graphics.jroplot_base import Plot, plt
from schainpy.model.graphics.jroplot_spectra import SpectraPlot, RTIPlot, CoherencePlot
from schainpy.utils import log
EARTH_RADIUS = 6.3710e3
def ll2xy(lat1, lon1, lat2, lon2):
p = 0.017453292519943295
a = 0.5 - numpy.cos((lat2 - lat1) * p)/2 + numpy.cos(lat1 * p) * \
numpy.cos(lat2 * p) * (1 - numpy.cos((lon2 - lon1) * p)) / 2
r = 12742 * numpy.arcsin(numpy.sqrt(a))
theta = numpy.arctan2(numpy.sin((lon2-lon1)*p)*numpy.cos(lat2*p), numpy.cos(lat1*p)
* numpy.sin(lat2*p)-numpy.sin(lat1*p)*numpy.cos(lat2*p)*numpy.cos((lon2-lon1)*p))
theta = -theta + numpy.pi/2
return r*numpy.cos(theta), r*numpy.sin(theta)
def km2deg(km):
'''
Convert distance in km to degrees
'''
return numpy.rad2deg(km/EARTH_RADIUS)
class SpectralMomentsPlot(SpectraPlot):
'''
Plot for Spectral Moments
'''
CODE = 'spc_moments'
colormap = 'jet'
plot_name = 'SpectralMoments'
plot_type = 'pcolor'
class SnrPlot(RTIPlot):
'''
Plot for SNR Data
'''
CODE = 'snr'
colormap = 'jet'
plot_name = 'SNR'
class DopplerPlot(RTIPlot):
'''
Plot for DOPPLER Data (1st moment)
'''
CODE = 'dop'
colormap = 'jet'
plot_name = 'DopplerShift'
class PowerPlot(RTIPlot):
'''
Plot for Power Data (0 moment)
'''
CODE = 'pow'
colormap = 'jet'
plot_name = 'TotalPower'
class SpectralWidthPlot(RTIPlot):
'''
Plot for Spectral Width Data (2nd moment)
'''
CODE = 'width'
colormap = 'jet'
plot_name = 'SpectralWidth'
class SkyMapPlot(Plot):
'''
Plot for meteors detection data
'''
CODE = 'param'
def setup(self):
self.ncols = 1
self.nrows = 1
self.width = 7.2
self.height = 7.2
self.nplots = 1
self.xlabel = 'Zonal Zenith Angle (deg)'
self.ylabel = 'Meridional Zenith Angle (deg)'
self.polar = True
self.ymin = -180
self.ymax = 180
self.colorbar = False
def plot(self):
arrayParameters = numpy.concatenate(self.data['param'])
error = arrayParameters[:, -1]
indValid = numpy.where(error == 0)[0]
finalMeteor = arrayParameters[indValid, :]
finalAzimuth = finalMeteor[:, 3]
finalZenith = finalMeteor[:, 4]
x = finalAzimuth * numpy.pi / 180
y = finalZenith
ax = self.axes[0]
if ax.firsttime:
ax.plot = ax.plot(x, y, 'bo', markersize=5)[0]
else:
ax.plot.set_data(x, y)
dt1 = self.getDateTime(self.data.min_time).strftime('%y/%m/%d %H:%M:%S')
dt2 = self.getDateTime(self.data.max_time).strftime('%y/%m/%d %H:%M:%S')
title = 'Meteor Detection Sky Map\n %s - %s \n Number of events: %5.0f\n' % (dt1,
dt2,
len(x))
self.titles[0] = title
class ParametersPlot(RTIPlot):
'''
Plot for data_param object
'''
CODE = 'param'
colormap = 'seismic'
plot_name = 'Parameters'
def setup(self):
self.xaxis = 'time'
self.ncols = 1
self.nrows = self.data.shape(self.CODE)[0]
self.nplots = self.nrows
if self.showSNR:
self.nrows += 1
self.nplots += 1
self.ylabel = 'Height [km]'
if not self.titles:
self.titles = self.data.parameters \
if self.data.parameters else ['Param {}'.format(x) for x in range(self.nrows)]
if self.showSNR:
self.titles.append('SNR')
def plot(self):
self.data.normalize_heights()
self.x = self.data.times
self.y = self.data.heights
if self.showSNR:
self.z = numpy.concatenate(
(self.data[self.CODE], self.data['snr'])
)
else:
self.z = self.data[self.CODE]
self.z = numpy.ma.masked_invalid(self.z)
if self.decimation is None:
x, y, z = self.fill_gaps(self.x, self.y, self.z)
else:
x, y, z = self.fill_gaps(*self.decimate())
for n, ax in enumerate(self.axes):
self.zmax = self.zmax if self.zmax is not None else numpy.max(
self.z[n])
self.zmin = self.zmin if self.zmin is not None else numpy.min(
self.z[n])
if ax.firsttime:
if self.zlimits is not None:
self.zmin, self.zmax = self.zlimits[n]
ax.plt = ax.pcolormesh(x, y, z[n].T * self.factors[n],
vmin=self.zmin,
vmax=self.zmax,
cmap=self.cmaps[n]
)
else:
if self.zlimits is not None:
self.zmin, self.zmax = self.zlimits[n]
ax.collections.remove(ax.collections[0])
ax.plt = ax.pcolormesh(x, y, z[n].T * self.factors[n],
vmin=self.zmin,
vmax=self.zmax,
cmap=self.cmaps[n]
)
class OutputPlot(ParametersPlot):
'''
Plot data_output object
'''
CODE = 'output'
colormap = 'seismic'
plot_name = 'Output'
class PolarMapPlot(Plot):
'''
Plot for weather radar
'''
CODE = 'param'
colormap = 'seismic'
def setup(self):
self.ncols = 1
self.nrows = 1
self.width = 9
self.height = 8
self.mode = self.data.meta['mode']
if self.channels is not None:
self.nplots = len(self.channels)
self.nrows = len(self.channels)
else:
self.nplots = self.data.shape(self.CODE)[0]
self.nrows = self.nplots
self.channels = list(range(self.nplots))
if self.mode == 'E':
self.xlabel = 'Longitude'
self.ylabel = 'Latitude'
else:
self.xlabel = 'Range (km)'
self.ylabel = 'Height (km)'
self.bgcolor = 'white'
self.cb_labels = self.data.meta['units']
self.lat = self.data.meta['latitude']
self.lon = self.data.meta['longitude']
self.xmin, self.xmax = float(
km2deg(self.xmin) + self.lon), float(km2deg(self.xmax) + self.lon)
self.ymin, self.ymax = float(
km2deg(self.ymin) + self.lat), float(km2deg(self.ymax) + self.lat)
# self.polar = True
def plot(self):
for n, ax in enumerate(self.axes):
data = self.data['param'][self.channels[n]]
zeniths = numpy.linspace(
0, self.data.meta['max_range'], data.shape[1])
if self.mode == 'E':
azimuths = -numpy.radians(self.data.heights)+numpy.pi/2
r, theta = numpy.meshgrid(zeniths, azimuths)
x, y = r*numpy.cos(theta)*numpy.cos(numpy.radians(self.data.meta['elevation'])), r*numpy.sin(
theta)*numpy.cos(numpy.radians(self.data.meta['elevation']))
x = km2deg(x) + self.lon
y = km2deg(y) + self.lat
else:
azimuths = numpy.radians(self.data.heights)
r, theta = numpy.meshgrid(zeniths, azimuths)
x, y = r*numpy.cos(theta), r*numpy.sin(theta)
self.y = zeniths
if ax.firsttime:
if self.zlimits is not None:
self.zmin, self.zmax = self.zlimits[n]
ax.plt = ax.pcolormesh( # r, theta, numpy.ma.array(data, mask=numpy.isnan(data)),
x, y, numpy.ma.array(data, mask=numpy.isnan(data)),
vmin=self.zmin,
vmax=self.zmax,
cmap=self.cmaps[n])
else:
if self.zlimits is not None:
self.zmin, self.zmax = self.zlimits[n]
ax.collections.remove(ax.collections[0])
ax.plt = ax.pcolormesh( # r, theta, numpy.ma.array(data, mask=numpy.isnan(data)),
x, y, numpy.ma.array(data, mask=numpy.isnan(data)),
vmin=self.zmin,
vmax=self.zmax,
cmap=self.cmaps[n])
if self.mode == 'A':
continue
# plot district names
f = open('/data/workspace/schain_scripts/distrito.csv')
for line in f:
label, lon, lat = [s.strip() for s in line.split(',') if s]
lat = float(lat)
lon = float(lon)
# ax.plot(lon, lat, '.b', ms=2)
ax.text(lon, lat, label.decode('utf8'), ha='center',
va='bottom', size='8', color='black')
# plot limites
limites = []
tmp = []
for line in open('/data/workspace/schain_scripts/lima.csv'):
if '#' in line:
if tmp:
limites.append(tmp)
tmp = []
continue
values = line.strip().split(',')
tmp.append((float(values[0]), float(values[1])))
for points in limites:
ax.add_patch(
Polygon(points, ec='k', fc='none', ls='--', lw=0.5))
# plot Cuencas
for cuenca in ('rimac', 'lurin', 'mala', 'chillon', 'chilca', 'chancay-huaral'):
f = open('/data/workspace/schain_scripts/{}.csv'.format(cuenca))
values = [line.strip().split(',') for line in f]
points = [(float(s[0]), float(s[1])) for s in values]
ax.add_patch(Polygon(points, ec='b', fc='none'))
# plot grid
for r in (15, 30, 45, 60):
ax.add_artist(plt.Circle((self.lon, self.lat),
km2deg(r), color='0.6', fill=False, lw=0.2))
ax.text(
self.lon + (km2deg(r))*numpy.cos(60*numpy.pi/180),
self.lat + (km2deg(r))*numpy.sin(60*numpy.pi/180),
'{}km'.format(r),
ha='center', va='bottom', size='8', color='0.6', weight='heavy')
if self.mode == 'E':
title = 'El={}$^\circ$'.format(self.data.meta['elevation'])
label = 'E{:02d}'.format(int(self.data.meta['elevation']))
else:
title = 'Az={}$^\circ$'.format(self.data.meta['azimuth'])
label = 'A{:02d}'.format(int(self.data.meta['azimuth']))
self.save_labels = ['{}-{}'.format(lbl, label) for lbl in self.labels]
self.titles = ['{} {}'.format(
self.data.parameters[x], title) for x in self.channels]