schain-jc Files · schainpy/model/graphics/jroplot_data.py

Add ScopePlot to the new way of plotting data (jroplot_data)

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      '''

      New Plots Operations

      @author: juan.espinoza@jro.igp.gob.pe

      '''

      import time

      import datetime

      import numpy

      from schainpy.model.graphics.jroplot_base import Plot, plt

      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 SpectraPlot(Plot):

          '''

          Plot for Spectra data

          '''

          CODE = 'spc'

          colormap = 'jro'

          def setup(self):

              self.nplots = len(self.data.channels)

              self.ncols = int(numpy.sqrt(self.nplots) + 0.9)

              self.nrows = int((1.0 * self.nplots / self.ncols) + 0.9)

              self.width = 3.4 * self.ncols

              self.height = 3 * self.nrows

              self.cb_label = 'dB'

              if self.showprofile:

                  self.width += 0.8 * self.ncols

              self.ylabel = 'Range [km]'

          def plot(self):

              if self.xaxis == "frequency":

                  x = self.data.xrange[0]

                  self.xlabel = "Frequency (kHz)"

              elif self.xaxis == "time":

                  x = self.data.xrange[1]

                  self.xlabel = "Time (ms)"

              else:

                  x = self.data.xrange[2]

                  self.xlabel = "Velocity (m/s)"

              if self.CODE == 'spc_mean':

                  x = self.data.xrange[2]

                  self.xlabel = "Velocity (m/s)"

              self.titles = []

              y = self.data.heights

              self.y = y

              z = self.data['spc']

              for n, ax in enumerate(self.axes):

                  noise = self.data['noise'][n][-1]

                  if self.CODE == 'spc_mean':

                      mean = self.data['mean'][n][-1]

                  if ax.firsttime:

                      self.xmax = self.xmax if self.xmax else numpy.nanmax(x)

                      self.xmin = self.xmin if self.xmin else -self.xmax

                      self.zmin = self.zmin if self.zmin else numpy.nanmin(z)

                      self.zmax = self.zmax if self.zmax else numpy.nanmax(z)

                      ax.plt = ax.pcolormesh(x, y, z[n].T,

                                             vmin=self.zmin,

                                             vmax=self.zmax,

                                             cmap=plt.get_cmap(self.colormap)

                                             )

                      if self.showprofile:

                          ax.plt_profile = self.pf_axes[n].plot(

                              self.data['rti'][n][-1], y)[0]

                          ax.plt_noise = self.pf_axes[n].plot(numpy.repeat(noise, len(y)), y,

                                                              color="k", linestyle="dashed", lw=1)[0]

                      if self.CODE == 'spc_mean':

                          ax.plt_mean = ax.plot(mean, y, color='k')[0]

                  else:

                      ax.plt.set_array(z[n].T.ravel())

                      if self.showprofile:

                          ax.plt_profile.set_data(self.data['rti'][n][-1], y)

                          ax.plt_noise.set_data(numpy.repeat(noise, len(y)), y)

                      if self.CODE == 'spc_mean':

                          ax.plt_mean.set_data(mean, y)

                  self.titles.append('CH {}: {:3.2f}dB'.format(n, noise))

      class CrossSpectraPlot(Plot):

          CODE = 'cspc'

          colormap = 'jet'

          zmin_coh = None

          zmax_coh = None

          zmin_phase = None

          zmax_phase = None

          def setup(self):

              self.ncols = 4

              self.nrows = len(self.data.pairs)

              self.nplots = self.nrows * 4

              self.width = 3.4 * self.ncols

              self.height = 3 * self.nrows

              self.ylabel = 'Range [km]'

              self.showprofile = False

          def plot(self):

              if self.xaxis == "frequency":

                  x = self.data.xrange[0]

                  self.xlabel = "Frequency (kHz)"

              elif self.xaxis == "time":

                  x = self.data.xrange[1]

                  self.xlabel = "Time (ms)"

              else:

                  x = self.data.xrange[2]

                  self.xlabel = "Velocity (m/s)"

              self.titles = []

              y = self.data.heights

              self.y = y

              spc = self.data['spc']

              cspc = self.data['cspc']

              for n in range(self.nrows):

                  noise = self.data['noise'][n][-1]

                  pair = self.data.pairs[n]

                  ax = self.axes[4 * n]

                  spc0 = 10.*numpy.log10(spc[pair[0]]/self.data.factor)          

                  if ax.firsttime:                                               

                      self.xmax = self.xmax if self.xmax else numpy.nanmax(x)    

                      self.xmin = self.xmin if self.xmin else -self.xmax         

                      self.zmin = self.zmin if self.zmin else numpy.nanmin(spc)  

                      self.zmax = self.zmax if self.zmax else numpy.nanmax(spc)  

                      ax.plt = ax.pcolormesh(x , y , spc0.T,

                                             vmin=self.zmin,

                                             vmax=self.zmax,

                                             cmap=plt.get_cmap(self.colormap)

                                             )                                   

                  else:                                                          

                      ax.plt.set_array(spc0.T.ravel())

                  self.titles.append('CH {}: {:3.2f}dB'.format(pair[0], noise))

                  ax = self.axes[4 * n + 1]

                  spc1 = 10.*numpy.log10(spc[pair[1]]/self.data.factor)

                  if ax.firsttime:

                      ax.plt = ax.pcolormesh(x , y, spc1.T,

                                             vmin=self.zmin,

                                             vmax=self.zmax,

                                             cmap=plt.get_cmap(self.colormap)

                                             )

                  else: 

                      ax.plt.set_array(spc1.T.ravel())

                  self.titles.append('CH {}: {:3.2f}dB'.format(pair[1], noise))

                  out = cspc[n] / numpy.sqrt(spc[pair[0]] * spc[pair[1]])

                  coh = numpy.abs(out)

                  phase = numpy.arctan2(out.imag, out.real) * 180 / numpy.pi

                  ax = self.axes[4 * n + 2]

                  if ax.firsttime:

                      ax.plt = ax.pcolormesh(x, y, coh.T,

                                             vmin=0,

                                             vmax=1,

                                             cmap=plt.get_cmap(self.colormap_coh)

                                             )

                  else:

                      ax.plt.set_array(coh.T.ravel())

                  self.titles.append(

                      'Coherence Ch{} * Ch{}'.format(pair[0], pair[1]))

                  ax = self.axes[4 * n + 3]

                  if ax.firsttime:

                      ax.plt = ax.pcolormesh(x, y, phase.T,

                                             vmin=-180,

                                             vmax=180,

                                             cmap=plt.get_cmap(self.colormap_phase) 

                                             )

                  else:

                      ax.plt.set_array(phase.T.ravel())

                  self.titles.append('Phase CH{} * CH{}'.format(pair[0], pair[1]))

      class SpectraMeanPlot(SpectraPlot):

          '''

          Plot for Spectra and Mean

          '''

          CODE = 'spc_mean'

          colormap = 'jro'

      class RTIPlot(Plot):

          '''

          Plot for RTI data

          '''

          CODE = 'rti'

          colormap = 'jro'

          def setup(self):

              self.xaxis = 'time'

              self.ncols = 1

              self.nrows = len(self.data.channels)

              self.nplots = len(self.data.channels)

              self.ylabel = 'Range [km]'

              self.cb_label = 'dB'

              self.titles = ['{} Channel {}'.format(

                  self.CODE.upper(), x) for x in range(self.nrows)]

          def plot(self):

              self.x = self.data.times

              self.y = self.data.heights

              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.zmin = self.zmin if self.zmin else numpy.min(self.z)

                  self.zmax = self.zmax if self.zmax else numpy.max(self.z)

                  if ax.firsttime:

                      ax.plt = ax.pcolormesh(x, y, z[n].T,

                                             vmin=self.zmin,

                                             vmax=self.zmax,

                                             cmap=plt.get_cmap(self.colormap)

                                             )

                      if self.showprofile:

                          ax.plot_profile = self.pf_axes[n].plot(

                              self.data['rti'][n][-1], self.y)[0]

                          ax.plot_noise = self.pf_axes[n].plot(numpy.repeat(self.data['noise'][n][-1], len(self.y)), self.y,

                                                               color="k", linestyle="dashed", lw=1)[0]

                  else:

                      ax.collections.remove(ax.collections[0])

                      ax.plt = ax.pcolormesh(x, y, z[n].T,

                                             vmin=self.zmin,

                                             vmax=self.zmax,

                                             cmap=plt.get_cmap(self.colormap)

                                             )

                      if self.showprofile:

                          ax.plot_profile.set_data(self.data['rti'][n][-1], self.y)

                          ax.plot_noise.set_data(numpy.repeat(

                              self.data['noise'][n][-1], len(self.y)), self.y)

      class CoherencePlot(RTIPlot):

          '''

          Plot for Coherence data

          '''

          CODE = 'coh'

          def setup(self):

              self.xaxis = 'time'

              self.ncols = 1

              self.nrows = len(self.data.pairs)

              self.nplots = len(self.data.pairs)

              self.ylabel = 'Range [km]'

              if self.CODE == 'coh':

                  self.cb_label = ''

                  self.titles = [

                      'Coherence Map Ch{} * Ch{}'.format(x[0], x[1]) for x in self.data.pairs]

              else:

                  self.cb_label = 'Degrees'

                  self.titles = [

                      'Phase Map Ch{} * Ch{}'.format(x[0], x[1]) for x in self.data.pairs]

      class PhasePlot(CoherencePlot):

          '''

          Plot for Phase map data

          '''

          CODE = 'phase'

          colormap = 'seismic'

      class NoisePlot(Plot):

          '''

          Plot for noise 

          '''

          CODE = 'noise'

          def setup(self):

              self.xaxis = 'time'

              self.ncols = 1

              self.nrows = 1

              self.nplots = 1

              self.ylabel = 'Intensity [dB]'

              self.titles = ['Noise']

              self.colorbar = False

          def plot(self):

              x = self.data.times

              xmin = self.data.min_time

              xmax = xmin + self.xrange * 60 * 60

              Y = self.data[self.CODE]

              if self.axes[0].firsttime:

                  for ch in self.data.channels:

                      y = Y[ch]

                      self.axes[0].plot(x, y, lw=1, label='Ch{}'.format(ch))

                  plt.legend()

              else:

                  for ch in self.data.channels:

                      y = Y[ch]

                      self.axes[0].lines[ch].set_data(x, y)

              self.ymin = numpy.nanmin(Y) - 5

              self.ymax = numpy.nanmax(Y) + 5

      class SnrPlot(RTIPlot):

          '''

          Plot for SNR Data

          '''

          CODE = 'snr'

          colormap = 'jet'

      class DopplerPlot(RTIPlot):

          '''

          Plot for DOPPLER Data

          '''

          CODE = 'dop'

          colormap = 'jet'

      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'

          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'

      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]

      class ScopePlot(Plot):

          '''

             Plot for Scope

          '''  

          CODE = 'scope'

          def setup(self):

              self.xaxis = 'Range (Km)'

              self.ncols = 1

              self.nrows = 1

              self.nplots = 1

              self.ylabel = 'Intensity [dB]'

              self.titles = ['Scope']

              self.colorbar = False

              colspan = 3

              rowspan = 1

          def plot_iq(self, x, y, channelIndexList, thisDatetime, wintitle):

              yreal = y[channelIndexList,:].real

              yimag = y[channelIndexList,:].imag

              title = wintitle + " Scope: %s" %(thisDatetime.strftime("%d-%b-%Y"))

              self.xlabel = "Range (Km)"

              self.ylabel = "Intensity - IQ"

              self.y = yreal

              self.x = x

              self.xmin = min(x)

              self.xmax = max(x)

              self.titles[0] = title        

              for i,ax in enumerate(self.axes):

                  title = "Channel %d" %(i)

                  if ax.firsttime:

                      ax.plt_r = ax.plot(x, yreal[i,:], color='b')[0]

                      ax.plt_i = ax.plot(x, yimag[i,:], color='r')[0]

                  else:

                      #pass

                      ax.plt_r.set_data(x, yreal[i,:])

                      ax.plt_i.set_data(x, yimag[i,:])

          def plot_power(self, x, y, channelIndexList, thisDatetime, wintitle):

              y = y[channelIndexList,:] * numpy.conjugate(y[channelIndexList,:])

              yreal = y.real

              self.y = yreal

              title = wintitle + " Scope: %s" %(thisDatetime.strftime("%d-%b-%Y"))

              self.xlabel = "Range (Km)"

              self.ylabel = "Intensity"

              self.xmin = min(x)

              self.xmax = max(x)

              self.titles[0] = title

              for i,ax in enumerate(self.axes):

                  title = "Channel %d" %(i)

                  ychannel = yreal[i,:]

                  if ax.firsttime:    

                      ax.plt_r = ax.plot(x, ychannel)[0]

                  else:

                      #pass

                      ax.plt_r.set_data(x, ychannel)

          def plot(self):

              if self.channels:

                  channels = self.channels

              else:

                  channels = self.data.channels

              thisDatetime = datetime.datetime.utcfromtimestamp(self.data.times[-1])

              scope = self.data['scope']

              if self.data.flagDataAsBlock:

                  for i in range(self.data.nProfiles):

                      wintitle1 = " [Profile = %d] " %i

                      if self.type == "power":

                          self.plot_power(self.data.heights, 

                                          scope[:,i,:],                                

                                          channels,

                                          thisDatetime, 

                                          wintitle1

                                          )

                      if self.type == "iq":

                          self.plot_iq(self.data.heights, 

                                       scope[:,i,:],

                                       channels,

                                       thisDatetime, 

                                       wintitle1 

                                      )

              else:

                  wintitle = " [Profile = %d] " %self.data.profileIndex

                  if self.type == "power":

                       self.plot_power(self.data.heights, 

                                  scope,

                                  channels,

                                  thisDatetime,

                                  wintitle

                                  )

                  if self.type == "iq":

                      self.plot_iq(self.data.heights, 

                                  scope,

                                  channels,

                                  thisDatetime,

                                  wintitle

                                  )

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				'''
				New Plots Operations

				@author: juan.espinoza@jro.igp.gob.pe
				'''


				import time
				import datetime
				import numpy

				from schainpy.model.graphics.jroplot_base import Plot, plt
				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(lat2p), numpy.cos(lat1p)
				* numpy.sin(lat2p)-numpy.sin(lat1p)numpy.cos(lat2p)numpy.cos((lon2-lon1)p))
				theta = -theta + numpy.pi/2
				return rnumpy.cos(theta), rnumpy.sin(theta)


				def km2deg(km):
				'''
				Convert distance in km to degrees
				'''

				return numpy.rad2deg(km/EARTH_RADIUS)


				class SpectraPlot(Plot):
				'''
				Plot for Spectra data
				'''

				CODE = 'spc'
				colormap = 'jro'

				def setup(self):
				self.nplots = len(self.data.channels)
				self.ncols = int(numpy.sqrt(self.nplots) + 0.9)
				self.nrows = int((1.0 * self.nplots / self.ncols) + 0.9)
				self.width = 3.4 * self.ncols
				self.height = 3 * self.nrows
				self.cb_label = 'dB'
				if self.showprofile:
				self.width += 0.8 * self.ncols

				self.ylabel = 'Range [km]'

				def plot(self):
				if self.xaxis == "frequency":
				x = self.data.xrange[0]
				self.xlabel = "Frequency (kHz)"
				elif self.xaxis == "time":
				x = self.data.xrange[1]
				self.xlabel = "Time (ms)"
				else:
				x = self.data.xrange[2]
				self.xlabel = "Velocity (m/s)"

				if self.CODE == 'spc_mean':
				x = self.data.xrange[2]
				self.xlabel = "Velocity (m/s)"

				self.titles = []

				y = self.data.heights
				self.y = y
				z = self.data['spc']

				for n, ax in enumerate(self.axes):
				noise = self.data['noise'][n][-1]
				if self.CODE == 'spc_mean':
				mean = self.data['mean'][n][-1]
				if ax.firsttime:
				self.xmax = self.xmax if self.xmax else numpy.nanmax(x)
				self.xmin = self.xmin if self.xmin else -self.xmax
				self.zmin = self.zmin if self.zmin else numpy.nanmin(z)
				self.zmax = self.zmax if self.zmax else numpy.nanmax(z)
				ax.plt = ax.pcolormesh(x, y, z[n].T,
				vmin=self.zmin,
				vmax=self.zmax,
				cmap=plt.get_cmap(self.colormap)
				)

				if self.showprofile:
				ax.plt_profile = self.pf_axes[n].plot(
				self.data['rti'][n][-1], y)[0]
				ax.plt_noise = self.pf_axes[n].plot(numpy.repeat(noise, len(y)), y,
				color="k", linestyle="dashed", lw=1)[0]
				if self.CODE == 'spc_mean':
				ax.plt_mean = ax.plot(mean, y, color='k')[0]
				else:
				ax.plt.set_array(z[n].T.ravel())
				if self.showprofile:
				ax.plt_profile.set_data(self.data['rti'][n][-1], y)
				ax.plt_noise.set_data(numpy.repeat(noise, len(y)), y)
				if self.CODE == 'spc_mean':
				ax.plt_mean.set_data(mean, y)

				self.titles.append('CH {}: {:3.2f}dB'.format(n, noise))


				class CrossSpectraPlot(Plot):

				CODE = 'cspc'
				colormap = 'jet'
				zmin_coh = None
				zmax_coh = None
				zmin_phase = None
				zmax_phase = None

				def setup(self):

				self.ncols = 4
				self.nrows = len(self.data.pairs)
				self.nplots = self.nrows * 4
				self.width = 3.4 * self.ncols
				self.height = 3 * self.nrows
				self.ylabel = 'Range [km]'
				self.showprofile = False

				def plot(self):

				if self.xaxis == "frequency":
				x = self.data.xrange[0]
				self.xlabel = "Frequency (kHz)"
				elif self.xaxis == "time":
				x = self.data.xrange[1]
				self.xlabel = "Time (ms)"
				else:
				x = self.data.xrange[2]
				self.xlabel = "Velocity (m/s)"

				self.titles = []

				y = self.data.heights
				self.y = y
				spc = self.data['spc']
				cspc = self.data['cspc']

				for n in range(self.nrows):
				noise = self.data['noise'][n][-1]
				pair = self.data.pairs[n]
				ax = self.axes[4 * n]
				spc0 = 10.*numpy.log10(spc[pair[0]]/self.data.factor)
				if ax.firsttime:
				self.xmax = self.xmax if self.xmax else numpy.nanmax(x)
				self.xmin = self.xmin if self.xmin else -self.xmax
				self.zmin = self.zmin if self.zmin else numpy.nanmin(spc)
				self.zmax = self.zmax if self.zmax else numpy.nanmax(spc)
				ax.plt = ax.pcolormesh(x , y , spc0.T,
				vmin=self.zmin,
				vmax=self.zmax,
				cmap=plt.get_cmap(self.colormap)
				)
				else:
				ax.plt.set_array(spc0.T.ravel())
				self.titles.append('CH {}: {:3.2f}dB'.format(pair[0], noise))

				ax = self.axes[4 * n + 1]
				spc1 = 10.*numpy.log10(spc[pair[1]]/self.data.factor)
				if ax.firsttime:
				ax.plt = ax.pcolormesh(x , y, spc1.T,
				vmin=self.zmin,
				vmax=self.zmax,
				cmap=plt.get_cmap(self.colormap)
				)
				else:
				ax.plt.set_array(spc1.T.ravel())
				self.titles.append('CH {}: {:3.2f}dB'.format(pair[1], noise))

				out = cspc[n] / numpy.sqrt(spc[pair[0]] * spc[pair[1]])
				coh = numpy.abs(out)
				phase = numpy.arctan2(out.imag, out.real) * 180 / numpy.pi

				ax = self.axes[4 * n + 2]
				if ax.firsttime:
				ax.plt = ax.pcolormesh(x, y, coh.T,
				vmin=0,
				vmax=1,
				cmap=plt.get_cmap(self.colormap_coh)
				)
				else:
				ax.plt.set_array(coh.T.ravel())
				self.titles.append(
				'Coherence Ch{} * Ch{}'.format(pair[0], pair[1]))

				ax = self.axes[4 * n + 3]
				if ax.firsttime:
				ax.plt = ax.pcolormesh(x, y, phase.T,
				vmin=-180,
				vmax=180,
				cmap=plt.get_cmap(self.colormap_phase)
				)
				else:
				ax.plt.set_array(phase.T.ravel())
				self.titles.append('Phase CH{} * CH{}'.format(pair[0], pair[1]))


				class SpectraMeanPlot(SpectraPlot):
				'''
				Plot for Spectra and Mean
				'''
				CODE = 'spc_mean'
				colormap = 'jro'


				class RTIPlot(Plot):
				'''
				Plot for RTI data
				'''

				CODE = 'rti'
				colormap = 'jro'

				def setup(self):
				self.xaxis = 'time'
				self.ncols = 1
				self.nrows = len(self.data.channels)
				self.nplots = len(self.data.channels)
				self.ylabel = 'Range [km]'
				self.cb_label = 'dB'
				self.titles = ['{} Channel {}'.format(
				self.CODE.upper(), x) for x in range(self.nrows)]

				def plot(self):
				self.x = self.data.times
				self.y = self.data.heights
				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.zmin = self.zmin if self.zmin else numpy.min(self.z)
				self.zmax = self.zmax if self.zmax else numpy.max(self.z)
				if ax.firsttime:
				ax.plt = ax.pcolormesh(x, y, z[n].T,
				vmin=self.zmin,
				vmax=self.zmax,
				cmap=plt.get_cmap(self.colormap)
				)
				if self.showprofile:
				ax.plot_profile = self.pf_axes[n].plot(
				self.data['rti'][n][-1], self.y)[0]
				ax.plot_noise = self.pf_axes[n].plot(numpy.repeat(self.data['noise'][n][-1], len(self.y)), self.y,
				color="k", linestyle="dashed", lw=1)[0]
				else:
				ax.collections.remove(ax.collections[0])
				ax.plt = ax.pcolormesh(x, y, z[n].T,
				vmin=self.zmin,
				vmax=self.zmax,
				cmap=plt.get_cmap(self.colormap)
				)
				if self.showprofile:
				ax.plot_profile.set_data(self.data['rti'][n][-1], self.y)
				ax.plot_noise.set_data(numpy.repeat(
				self.data['noise'][n][-1], len(self.y)), self.y)


				class CoherencePlot(RTIPlot):
				'''
				Plot for Coherence data
				'''

				CODE = 'coh'

				def setup(self):
				self.xaxis = 'time'
				self.ncols = 1
				self.nrows = len(self.data.pairs)
				self.nplots = len(self.data.pairs)
				self.ylabel = 'Range [km]'
				if self.CODE == 'coh':
				self.cb_label = ''
				self.titles = [
				'Coherence Map Ch{} * Ch{}'.format(x[0], x[1]) for x in self.data.pairs]
				else:
				self.cb_label = 'Degrees'
				self.titles = [
				'Phase Map Ch{} * Ch{}'.format(x[0], x[1]) for x in self.data.pairs]


				class PhasePlot(CoherencePlot):
				'''
				Plot for Phase map data
				'''

				CODE = 'phase'
				colormap = 'seismic'


				class NoisePlot(Plot):
				'''
				Plot for noise
				'''

				CODE = 'noise'

				def setup(self):
				self.xaxis = 'time'
				self.ncols = 1
				self.nrows = 1
				self.nplots = 1
				self.ylabel = 'Intensity [dB]'
				self.titles = ['Noise']
				self.colorbar = False

				def plot(self):

				x = self.data.times
				xmin = self.data.min_time
				xmax = xmin + self.xrange * 60 * 60
				Y = self.data[self.CODE]

				if self.axes[0].firsttime:
				for ch in self.data.channels:
				y = Y[ch]
				self.axes[0].plot(x, y, lw=1, label='Ch{}'.format(ch))
				plt.legend()
				else:
				for ch in self.data.channels:
				y = Y[ch]
				self.axes[0].lines[ch].set_data(x, y)

				self.ymin = numpy.nanmin(Y) - 5
				self.ymax = numpy.nanmax(Y) + 5


				class SnrPlot(RTIPlot):
				'''
				Plot for SNR Data
				'''

				CODE = 'snr'
				colormap = 'jet'


				class DopplerPlot(RTIPlot):
				'''
				Plot for DOPPLER Data
				'''

				CODE = 'dop'
				colormap = 'jet'


				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'

				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'


				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 = rnumpy.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 = rnumpy.cos(theta), rnumpy.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(60numpy.pi/180),
				self.lat + (km2deg(r))numpy.sin(60numpy.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]

				class ScopePlot(Plot):

				'''
				Plot for Scope
				'''

				CODE = 'scope'

				def setup(self):

				self.xaxis = 'Range (Km)'
				self.ncols = 1
				self.nrows = 1
				self.nplots = 1
				self.ylabel = 'Intensity [dB]'
				self.titles = ['Scope']
				self.colorbar = False
				colspan = 3
				rowspan = 1

				def plot_iq(self, x, y, channelIndexList, thisDatetime, wintitle):

				yreal = y[channelIndexList,:].real
				yimag = y[channelIndexList,:].imag
				title = wintitle + " Scope: %s" %(thisDatetime.strftime("%d-%b-%Y"))
				self.xlabel = "Range (Km)"
				self.ylabel = "Intensity - IQ"

				self.y = yreal
				self.x = x
				self.xmin = min(x)
				self.xmax = max(x)


				self.titles[0] = title

				for i,ax in enumerate(self.axes):
				title = "Channel %d" %(i)
				if ax.firsttime:
				ax.plt_r = ax.plot(x, yreal[i,:], color='b')[0]
				ax.plt_i = ax.plot(x, yimag[i,:], color='r')[0]
				else:
				#pass
				ax.plt_r.set_data(x, yreal[i,:])
				ax.plt_i.set_data(x, yimag[i,:])

				def plot_power(self, x, y, channelIndexList, thisDatetime, wintitle):
				y = y[channelIndexList,:] * numpy.conjugate(y[channelIndexList,:])
				yreal = y.real
				self.y = yreal
				title = wintitle + " Scope: %s" %(thisDatetime.strftime("%d-%b-%Y"))
				self.xlabel = "Range (Km)"
				self.ylabel = "Intensity"
				self.xmin = min(x)
				self.xmax = max(x)


				self.titles[0] = title

				for i,ax in enumerate(self.axes):
				title = "Channel %d" %(i)

				ychannel = yreal[i,:]

				if ax.firsttime:
				ax.plt_r = ax.plot(x, ychannel)[0]
				else:
				#pass
				ax.plt_r.set_data(x, ychannel)


				def plot(self):

				if self.channels:
				channels = self.channels
				else:
				channels = self.data.channels



				thisDatetime = datetime.datetime.utcfromtimestamp(self.data.times[-1])

				scope = self.data['scope']


				if self.data.flagDataAsBlock:

				for i in range(self.data.nProfiles):

				wintitle1 = " [Profile = %d] " %i

				if self.type == "power":
				self.plot_power(self.data.heights,
				scope[:,i,:],
				channels,
				thisDatetime,
				wintitle1
				)

				if self.type == "iq":
				self.plot_iq(self.data.heights,
				scope[:,i,:],
				channels,
				thisDatetime,
				wintitle1
				)





				else:
				wintitle = " [Profile = %d] " %self.data.profileIndex

				if self.type == "power":
				self.plot_power(self.data.heights,
				scope,
				channels,
				thisDatetime,
				wintitle
				)

				if self.type == "iq":
				self.plot_iq(self.data.heights,
				scope,
				channels,
				thisDatetime,
				wintitle
				)