##// END OF EJS Templates
schain-jc
RSS
Optimizacion de graficos con buffer, el buffer se crea en la clase Axes del modulo figure.py, se agrega el metodo pcolorbuffer....
Optimizacion de graficos con buffer, el buffer se crea en la clase Axes del modulo figure.py, se agrega el metodo pcolorbuffer. En mpldriver.py se agrega el metodo addpcolorbuffer donde se limpia el buffer de matplotlib que genera pcolormesh Estas modificaciones se aplican a los graficos RTI y Mapa de Coherencias.
Daniel Valdez - - Load All Authors

File last commit:

r318:2312df9eac7d
r318:2312df9eac7d
Show More
jroplot.py
1003 lines | 33.3 KiB | text/x-python | PythonLexer
/ schainpy / model / jroplot.py
History | Annotation | Raw |Copy content |Copy permalink
import numpy
import time, datetime, os
from graphics.figure import *
class CrossSpectraPlot(Figure):
__isConfig = None
__nsubplots = None
WIDTH = None
HEIGHT = None
WIDTHPROF = None
HEIGHTPROF = None
PREFIX = 'cspc'
def __init__(self):
self.__isConfig = False
self.__nsubplots = 4
self.WIDTH = 250
self.HEIGHT = 250
self.WIDTHPROF = 0
self.HEIGHTPROF = 0
def getSubplots(self):
ncol = 4
nrow = self.nplots
return nrow, ncol
def setup(self, idfigure, nplots, wintitle, showprofile=True):
self.__showprofile = showprofile
self.nplots = nplots
ncolspan = 1
colspan = 1
self.createFigure(idfigure = idfigure,
wintitle = wintitle,
widthplot = self.WIDTH + self.WIDTHPROF,
heightplot = self.HEIGHT + self.HEIGHTPROF)
nrow, ncol = self.getSubplots()
counter = 0
for y in range(nrow):
for x in range(ncol):
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan, colspan, 1)
counter += 1
def run(self, dataOut, idfigure, wintitle="", pairsList=None, showprofile='True',
xmin=None, xmax=None, ymin=None, ymax=None, zmin=None, zmax=None,
save=False, figpath='./', figfile=None,
power_cmap='jet', coherence_cmap='jet', phase_cmap='RdBu_r'):
"""
Input:
dataOut :
idfigure :
wintitle :
channelList :
showProfile :
xmin : None,
xmax : None,
ymin : None,
ymax : None,
zmin : None,
zmax : None
"""
if pairsList == None:
pairsIndexList = dataOut.pairsIndexList
else:
pairsIndexList = []
for pair in pairsList:
if pair not in dataOut.pairsList:
raise ValueError, "Pair %s is not in dataOut.pairsList" %(pair)
pairsIndexList.append(dataOut.pairsList.index(pair))
if pairsIndexList == []:
return
if len(pairsIndexList) > 4:
pairsIndexList = pairsIndexList[0:4]
factor = dataOut.normFactor
x = dataOut.getVelRange(1)
y = dataOut.getHeiRange()
z = dataOut.data_spc[:,:,:]/factor
# z = numpy.where(numpy.isfinite(z), z, numpy.NAN)
avg = numpy.abs(numpy.average(z, axis=1))
noise = dataOut.getNoise()/factor
zdB = 10*numpy.log10(z)
avgdB = 10*numpy.log10(avg)
noisedB = 10*numpy.log10(noise)
thisDatetime = dataOut.datatime
title = "Cross-Spectra: %s" %(thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
xlabel = "Velocity (m/s)"
ylabel = "Range (Km)"
if not self.__isConfig:
nplots = len(pairsIndexList)
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle,
showprofile=showprofile)
if xmin == None: xmin = numpy.nanmin(x)
if xmax == None: xmax = numpy.nanmax(x)
if ymin == None: ymin = numpy.nanmin(y)
if ymax == None: ymax = numpy.nanmax(y)
if zmin == None: zmin = numpy.nanmin(avgdB)*0.9
if zmax == None: zmax = numpy.nanmax(avgdB)*0.9
self.__isConfig = True
self.setWinTitle(title)
for i in range(self.nplots):
pair = dataOut.pairsList[pairsIndexList[i]]
title = "Channel %d: %4.2fdB" %(pair[0], noisedB[pair[0]])
zdB = 10.*numpy.log10(dataOut.data_spc[pair[0],:,:]/factor)
axes0 = self.axesList[i*self.__nsubplots]
axes0.pcolor(x, y, zdB,
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax, zmin=zmin, zmax=zmax,
xlabel=xlabel, ylabel=ylabel, title=title,
ticksize=9, colormap=power_cmap, cblabel='')
title = "Channel %d: %4.2fdB" %(pair[1], noisedB[pair[1]])
zdB = 10.*numpy.log10(dataOut.data_spc[pair[1],:,:]/factor)
axes0 = self.axesList[i*self.__nsubplots+1]
axes0.pcolor(x, y, zdB,
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax, zmin=zmin, zmax=zmax,
xlabel=xlabel, ylabel=ylabel, title=title,
ticksize=9, colormap=power_cmap, cblabel='')
coherenceComplex = dataOut.data_cspc[pairsIndexList[i],:,:]/numpy.sqrt(dataOut.data_spc[pair[0],:,:]*dataOut.data_spc[pair[1],:,:])
coherence = numpy.abs(coherenceComplex)
# phase = numpy.arctan(-1*coherenceComplex.imag/coherenceComplex.real)*180/numpy.pi
phase = numpy.arctan2(coherenceComplex.imag, coherenceComplex.real)*180/numpy.pi
title = "Coherence %d%d" %(pair[0], pair[1])
axes0 = self.axesList[i*self.__nsubplots+2]
axes0.pcolor(x, y, coherence,
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax, zmin=0, zmax=1,
xlabel=xlabel, ylabel=ylabel, title=title,
ticksize=9, colormap=coherence_cmap, cblabel='')
title = "Phase %d%d" %(pair[0], pair[1])
axes0 = self.axesList[i*self.__nsubplots+3]
axes0.pcolor(x, y, phase,
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax, zmin=-180, zmax=180,
xlabel=xlabel, ylabel=ylabel, title=title,
ticksize=9, colormap=phase_cmap, cblabel='')
self.draw()
if save:
date = thisDatetime.strftime("%Y%m%d_%H%M%S")
if figfile == None:
figfile = self.getFilename(name = date)
self.saveFigure(figpath, figfile)
class RTIPlot(Figure):
__isConfig = None
__nsubplots = None
WIDTHPROF = None
HEIGHTPROF = None
PREFIX = 'rti'
def __init__(self):
self.timerange = 2*60*60
self.__isConfig = False
self.__nsubplots = 1
self.WIDTH = 800
self.HEIGHT = 150
self.WIDTHPROF = 120
self.HEIGHTPROF = 0
self.counterftp = 0
def getSubplots(self):
ncol = 1
nrow = self.nplots
return nrow, ncol
def setup(self, idfigure, nplots, wintitle, showprofile=True):
self.__showprofile = showprofile
self.nplots = nplots
ncolspan = 1
colspan = 1
if showprofile:
ncolspan = 7
colspan = 6
self.__nsubplots = 2
self.createFigure(idfigure = idfigure,
wintitle = wintitle,
widthplot = self.WIDTH + self.WIDTHPROF,
heightplot = self.HEIGHT + self.HEIGHTPROF)
nrow, ncol = self.getSubplots()
counter = 0
for y in range(nrow):
for x in range(ncol):
if counter >= self.nplots:
break
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan, colspan, 1)
if showprofile:
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan+colspan, 1, 1)
counter += 1
def run(self, dataOut, idfigure, wintitle="", channelList=None, showprofile='True',
xmin=None, xmax=None, ymin=None, ymax=None, zmin=None, zmax=None,
timerange=None,
save=False, figpath='./', figfile=None, ftp=False, ftpratio=1):
"""
Input:
dataOut :
idfigure :
wintitle :
channelList :
showProfile :
xmin : None,
xmax : None,
ymin : None,
ymax : None,
zmin : None,
zmax : None
"""
if channelList == None:
channelIndexList = dataOut.channelIndexList
else:
channelIndexList = []
for channel in channelList:
if channel not in dataOut.channelList:
raise ValueError, "Channel %d is not in dataOut.channelList"
channelIndexList.append(dataOut.channelList.index(channel))
if timerange != None:
self.timerange = timerange
tmin = None
tmax = None
factor = dataOut.normFactor
x = dataOut.getTimeRange()
y = dataOut.getHeiRange()
z = dataOut.data_spc[channelIndexList,:,:]/factor
z = numpy.where(numpy.isfinite(z), z, numpy.NAN)
avg = numpy.average(z, axis=1)
avgdB = 10.*numpy.log10(avg)
thisDatetime = dataOut.datatime
title = "RTI: %s" %(thisDatetime.strftime("%d-%b-%Y"))
xlabel = ""
ylabel = "Range (Km)"
if not self.__isConfig:
nplots = len(channelIndexList)
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle,
showprofile=showprofile)
tmin, tmax = self.getTimeLim(x, xmin, xmax)
if ymin == None: ymin = numpy.nanmin(y)
if ymax == None: ymax = numpy.nanmax(y)
if zmin == None: zmin = numpy.nanmin(avgdB)*0.9
if zmax == None: zmax = numpy.nanmax(avgdB)*0.9
self.name = thisDatetime.strftime("%Y%m%d_%H%M%S")
self.__isConfig = True
self.setWinTitle(title)
for i in range(self.nplots):
title = "Channel %d: %s" %(dataOut.channelList[i], thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
axes = self.axesList[i*self.__nsubplots]
zdB = avgdB[i].reshape((1,-1))
axes.pcolorbuffer(x, y, zdB,
xmin=tmin, xmax=tmax, ymin=ymin, ymax=ymax, zmin=zmin, zmax=zmax,
xlabel=xlabel, ylabel=ylabel, title=title, rti=True, XAxisAsTime=True,
ticksize=9, cblabel='', cbsize="1%")
if self.__showprofile:
axes = self.axesList[i*self.__nsubplots +1]
axes.pline(avgdB[i], y,
xmin=zmin, xmax=zmax, ymin=ymin, ymax=ymax,
xlabel='dB', ylabel='', title='',
ytick_visible=False,
grid='x')
self.draw()
if save:
if figfile == None:
figfile = self.getFilename(name = self.name)
self.saveFigure(figpath, figfile)
self.counterftp += 1
if (ftp and (self.counterftp==ftpratio)):
figfilename = os.path.join(figpath,figfile)
self.sendByFTP(figfilename)
self.counterftp = 0
if x[1] + (x[1]-x[0]) >= self.axesList[0].xmax:
self.__isConfig = False
class SpectraPlot(Figure):
__isConfig = None
__nsubplots = None
WIDTHPROF = None
HEIGHTPROF = None
PREFIX = 'spc'
def __init__(self):
self.__isConfig = False
self.__nsubplots = 1
self.WIDTH = 230
self.HEIGHT = 250
self.WIDTHPROF = 120
self.HEIGHTPROF = 0
def getSubplots(self):
ncol = int(numpy.sqrt(self.nplots)+0.9)
nrow = int(self.nplots*1./ncol + 0.9)
return nrow, ncol
def setup(self, idfigure, nplots, wintitle, showprofile=True):
self.__showprofile = showprofile
self.nplots = nplots
ncolspan = 1
colspan = 1
if showprofile:
ncolspan = 3
colspan = 2
self.__nsubplots = 2
self.createFigure(idfigure = idfigure,
wintitle = wintitle,
widthplot = self.WIDTH + self.WIDTHPROF,
heightplot = self.HEIGHT + self.HEIGHTPROF)
nrow, ncol = self.getSubplots()
counter = 0
for y in range(nrow):
for x in range(ncol):
if counter >= self.nplots:
break
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan, colspan, 1)
if showprofile:
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan+colspan, 1, 1)
counter += 1
def run(self, dataOut, idfigure, wintitle="", channelList=None, showprofile='True',
xmin=None, xmax=None, ymin=None, ymax=None, zmin=None, zmax=None,
save=False, figpath='./', figfile=None):
"""
Input:
dataOut :
idfigure :
wintitle :
channelList :
showProfile :
xmin : None,
xmax : None,
ymin : None,
ymax : None,
zmin : None,
zmax : None
"""
if channelList == None:
channelIndexList = dataOut.channelIndexList
else:
channelIndexList = []
for channel in channelList:
if channel not in dataOut.channelList:
raise ValueError, "Channel %d is not in dataOut.channelList"
channelIndexList.append(dataOut.channelList.index(channel))
factor = dataOut.normFactor
x = dataOut.getVelRange(1)
y = dataOut.getHeiRange()
z = dataOut.data_spc[channelIndexList,:,:]/factor
z = numpy.where(numpy.isfinite(z), z, numpy.NAN)
avg = numpy.average(z, axis=1)
noise = dataOut.getNoise()/factor
zdB = 10*numpy.log10(z)
avgdB = 10*numpy.log10(avg)
noisedB = 10*numpy.log10(noise)
thisDatetime = dataOut.datatime
title = "Spectra: %s" %(thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
xlabel = "Velocity (m/s)"
ylabel = "Range (Km)"
if not self.__isConfig:
nplots = len(channelIndexList)
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle,
showprofile=showprofile)
if xmin == None: xmin = numpy.nanmin(x)
if xmax == None: xmax = numpy.nanmax(x)
if ymin == None: ymin = numpy.nanmin(y)
if ymax == None: ymax = numpy.nanmax(y)
if zmin == None: zmin = numpy.nanmin(avgdB)*0.9
if zmax == None: zmax = numpy.nanmax(avgdB)*0.9
self.__isConfig = True
self.setWinTitle(title)
for i in range(self.nplots):
title = "Channel %d: %4.2fdB" %(dataOut.channelList[i], noisedB[i])
axes = self.axesList[i*self.__nsubplots]
axes.pcolor(x, y, zdB[i,:,:],
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax, zmin=zmin, zmax=zmax,
xlabel=xlabel, ylabel=ylabel, title=title,
ticksize=9, cblabel='')
if self.__showprofile:
axes = self.axesList[i*self.__nsubplots +1]
axes.pline(avgdB[i], y,
xmin=zmin, xmax=zmax, ymin=ymin, ymax=ymax,
xlabel='dB', ylabel='', title='',
ytick_visible=False,
grid='x')
noiseline = numpy.repeat(noisedB[i], len(y))
axes.addpline(noiseline, y, idline=1, color="black", linestyle="dashed", lw=2)
self.draw()
if save:
date = thisDatetime.strftime("%Y%m%d_%H%M%S")
if figfile == None:
figfile = self.getFilename(name = date)
self.saveFigure(figpath, figfile)
class Scope(Figure):
__isConfig = None
def __init__(self):
self.__isConfig = False
self.WIDTH = 600
self.HEIGHT = 200
def getSubplots(self):
nrow = self.nplots
ncol = 3
return nrow, ncol
def setup(self, idfigure, nplots, wintitle):
self.nplots = nplots
self.createFigure(idfigure, wintitle)
nrow,ncol = self.getSubplots()
colspan = 3
rowspan = 1
for i in range(nplots):
self.addAxes(nrow, ncol, i, 0, colspan, rowspan)
def run(self, dataOut, idfigure, wintitle="", channelList=None,
xmin=None, xmax=None, ymin=None, ymax=None, save=False,
figpath='./', figfile=None):
"""
Input:
dataOut :
idfigure :
wintitle :
channelList :
xmin : None,
xmax : None,
ymin : None,
ymax : None,
"""
if channelList == None:
channelIndexList = dataOut.channelIndexList
else:
channelIndexList = []
for channel in channelList:
if channel not in dataOut.channelList:
raise ValueError, "Channel %d is not in dataOut.channelList"
channelIndexList.append(dataOut.channelList.index(channel))
x = dataOut.heightList
y = dataOut.data[channelIndexList,:] * numpy.conjugate(dataOut.data[channelIndexList,:])
y = y.real
thisDatetime = dataOut.datatime
title = "Scope: %s" %(thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
xlabel = "Range (Km)"
ylabel = "Intensity"
if not self.__isConfig:
nplots = len(channelIndexList)
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle)
if xmin == None: xmin = numpy.nanmin(x)
if xmax == None: xmax = numpy.nanmax(x)
if ymin == None: ymin = numpy.nanmin(y)
if ymax == None: ymax = numpy.nanmax(y)
self.__isConfig = True
self.setWinTitle(title)
for i in range(len(self.axesList)):
title = "Channel %d" %(i)
axes = self.axesList[i]
ychannel = y[i,:]
axes.pline(x, ychannel,
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax,
xlabel=xlabel, ylabel=ylabel, title=title)
self.draw()
if save:
date = thisDatetime.strftime("%Y%m%d_%H%M%S")
if figfile == None:
figfile = self.getFilename(name = date)
self.saveFigure(figpath, figfile)
class ProfilePlot(Figure):
__isConfig = None
__nsubplots = None
WIDTHPROF = None
HEIGHTPROF = None
PREFIX = 'spcprofile'
def __init__(self):
self.__isConfig = False
self.__nsubplots = 1
self.WIDTH = 300
self.HEIGHT = 500
def getSubplots(self):
ncol = 1
nrow = 1
return nrow, ncol
def setup(self, idfigure, nplots, wintitle):
self.nplots = nplots
ncolspan = 1
colspan = 1
self.createFigure(idfigure = idfigure,
wintitle = wintitle,
widthplot = self.WIDTH,
heightplot = self.HEIGHT)
nrow, ncol = self.getSubplots()
counter = 0
for y in range(nrow):
for x in range(ncol):
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan, colspan, 1)
def run(self, dataOut, idfigure, wintitle="", channelList=None,
xmin=None, xmax=None, ymin=None, ymax=None,
save=False, figpath='./', figfile=None):
if channelList == None:
channelIndexList = dataOut.channelIndexList
channelList = dataOut.channelList
else:
channelIndexList = []
for channel in channelList:
if channel not in dataOut.channelList:
raise ValueError, "Channel %d is not in dataOut.channelList"
channelIndexList.append(dataOut.channelList.index(channel))
factor = dataOut.normFactor
y = dataOut.getHeiRange()
x = dataOut.data_spc[channelIndexList,:,:]/factor
x = numpy.where(numpy.isfinite(x), x, numpy.NAN)
avg = numpy.average(x, axis=1)
avgdB = 10*numpy.log10(avg)
thisDatetime = dataOut.datatime
title = "Power Profile"
xlabel = "dB"
ylabel = "Range (Km)"
if not self.__isConfig:
nplots = 1
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle)
if ymin == None: ymin = numpy.nanmin(y)
if ymax == None: ymax = numpy.nanmax(y)
if xmin == None: xmin = numpy.nanmin(avgdB)*0.9
if xmax == None: xmax = numpy.nanmax(avgdB)*0.9
self.__isConfig = True
self.setWinTitle(title)
title = "Power Profile: %s" %(thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
axes = self.axesList[0]
legendlabels = ["channel %d"%x for x in channelList]
axes.pmultiline(avgdB, y,
xmin=xmin, xmax=xmax, ymin=ymin, ymax=ymax,
xlabel=xlabel, ylabel=ylabel, title=title, legendlabels=legendlabels,
ytick_visible=True, nxticks=5,
grid='x')
self.draw()
if save:
date = thisDatetime.strftime("%Y%m%d")
if figfile == None:
figfile = self.getFilename(name = date)
self.saveFigure(figpath, figfile)
class CoherenceMap(Figure):
__isConfig = None
__nsubplots = None
WIDTHPROF = None
HEIGHTPROF = None
PREFIX = 'cmap'
def __init__(self):
self.timerange = 2*60*60
self.__isConfig = False
self.__nsubplots = 1
self.WIDTH = 800
self.HEIGHT = 150
self.WIDTHPROF = 120
self.HEIGHTPROF = 0
self.counterftp = 0
def getSubplots(self):
ncol = 1
nrow = self.nplots*2
return nrow, ncol
def setup(self, idfigure, nplots, wintitle, showprofile=True):
self.__showprofile = showprofile
self.nplots = nplots
ncolspan = 1
colspan = 1
if showprofile:
ncolspan = 7
colspan = 6
self.__nsubplots = 2
self.createFigure(idfigure = idfigure,
wintitle = wintitle,
widthplot = self.WIDTH + self.WIDTHPROF,
heightplot = self.HEIGHT + self.HEIGHTPROF)
nrow, ncol = self.getSubplots()
for y in range(nrow):
for x in range(ncol):
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan, colspan, 1)
if showprofile:
self.addAxes(nrow, ncol*ncolspan, y, x*ncolspan+colspan, 1, 1)
def run(self, dataOut, idfigure, wintitle="", pairsList=None, showprofile='True',
xmin=None, xmax=None, ymin=None, ymax=None, zmin=None, zmax=None,
timerange=None,
save=False, figpath='./', figfile=None, ftp=False, ftpratio=1,
coherence_cmap='jet', phase_cmap='RdBu_r'):
if pairsList == None:
pairsIndexList = dataOut.pairsIndexList
else:
pairsIndexList = []
for pair in pairsList:
if pair not in dataOut.pairsList:
raise ValueError, "Pair %s is not in dataOut.pairsList" %(pair)
pairsIndexList.append(dataOut.pairsList.index(pair))
if timerange != None:
self.timerange = timerange
if pairsIndexList == []:
return
if len(pairsIndexList) > 4:
pairsIndexList = pairsIndexList[0:4]
tmin = None
tmax = None
x = dataOut.getTimeRange()
y = dataOut.getHeiRange()
thisDatetime = dataOut.datatime
title = "CoherenceMap: %s" %(thisDatetime.strftime("%d-%b-%Y"))
xlabel = ""
ylabel = "Range (Km)"
if not self.__isConfig:
nplots = len(pairsIndexList)
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle,
showprofile=showprofile)
tmin, tmax = self.getTimeLim(x, xmin, xmax)
if ymin == None: ymin = numpy.nanmin(y)
if ymax == None: ymax = numpy.nanmax(y)
self.name = thisDatetime.strftime("%Y%m%d_%H%M%S")
self.__isConfig = True
self.setWinTitle(title)
for i in range(self.nplots):
pair = dataOut.pairsList[pairsIndexList[i]]
coherenceComplex = dataOut.data_cspc[pairsIndexList[i],:,:]/numpy.sqrt(dataOut.data_spc[pair[0],:,:]*dataOut.data_spc[pair[1],:,:])
avgcoherenceComplex = numpy.average(coherenceComplex, axis=0)
coherence = numpy.abs(avgcoherenceComplex)
# coherence = numpy.abs(coherenceComplex)
# avg = numpy.average(coherence, axis=0)
z = coherence.reshape((1,-1))
counter = 0
title = "Coherence %d%d: %s" %(pair[0], pair[1], thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
axes = self.axesList[i*self.__nsubplots*2]
axes.pcolorbuffer(x, y, z,
xmin=tmin, xmax=tmax, ymin=ymin, ymax=ymax, zmin=0, zmax=1,
xlabel=xlabel, ylabel=ylabel, title=title, rti=True, XAxisAsTime=True,
ticksize=9, cblabel='', colormap=coherence_cmap, cbsize="1%")
if self.__showprofile:
counter += 1
axes = self.axesList[i*self.__nsubplots*2 + counter]
axes.pline(coherence, y,
xmin=0, xmax=1, ymin=ymin, ymax=ymax,
xlabel='', ylabel='', title='', ticksize=7,
ytick_visible=False, nxticks=5,
grid='x')
counter += 1
# phase = numpy.arctan(-1*coherenceComplex.imag/coherenceComplex.real)*180/numpy.pi
phase = numpy.arctan2(avgcoherenceComplex.imag, avgcoherenceComplex.real)*180/numpy.pi
# avg = numpy.average(phase, axis=0)
z = phase.reshape((1,-1))
title = "Phase %d%d: %s" %(pair[0], pair[1], thisDatetime.strftime("%d-%b-%Y %H:%M:%S"))
axes = self.axesList[i*self.__nsubplots*2 + counter]
axes.pcolorbuffer(x, y, z,
xmin=tmin, xmax=tmax, ymin=ymin, ymax=ymax, zmin=-180, zmax=180,
xlabel=xlabel, ylabel=ylabel, title=title, rti=True, XAxisAsTime=True,
ticksize=9, cblabel='', colormap=phase_cmap, cbsize="1%")
if self.__showprofile:
counter += 1
axes = self.axesList[i*self.__nsubplots*2 + counter]
axes.pline(phase, y,
xmin=-180, xmax=180, ymin=ymin, ymax=ymax,
xlabel='', ylabel='', title='', ticksize=7,
ytick_visible=False, nxticks=4,
grid='x')
self.draw()
if save:
if figfile == None:
figfile = self.getFilename(name = self.name)
self.saveFigure(figpath, figfile)
self.counterftp += 1
if (ftp and (self.counterftp==ftpratio)):
figfilename = os.path.join(figpath,figfile)
self.sendByFTP(figfilename)
self.counterftp = 0
if x[1] + (x[1]-x[0]) >= self.axesList[0].xmax:
self.__isConfig = False
class RTIfromNoise(Figure):
__isConfig = None
__nsubplots = None
PREFIX = 'rtinoise'
def __init__(self):
self.timerange = 24*60*60
self.__isConfig = False
self.__nsubplots = 1
self.WIDTH = 820
self.HEIGHT = 200
self.WIDTHPROF = 120
self.HEIGHTPROF = 0
self.xdata = None
self.ydata = None
def getSubplots(self):
ncol = 1
nrow = 1
return nrow, ncol
def setup(self, idfigure, nplots, wintitle, showprofile=True):
self.__showprofile = showprofile
self.nplots = nplots
ncolspan = 7
colspan = 6
self.__nsubplots = 2
self.createFigure(idfigure = idfigure,
wintitle = wintitle,
widthplot = self.WIDTH+self.WIDTHPROF,
heightplot = self.HEIGHT+self.HEIGHTPROF)
nrow, ncol = self.getSubplots()
self.addAxes(nrow, ncol*ncolspan, 0, 0, colspan, 1)
def run(self, dataOut, idfigure, wintitle="", channelList=None, showprofile='True',
xmin=None, xmax=None, ymin=None, ymax=None,
timerange=None,
save=False, figpath='./', figfile=None):
if channelList == None:
channelIndexList = dataOut.channelIndexList
channelList = dataOut.channelList
else:
channelIndexList = []
for channel in channelList:
if channel not in dataOut.channelList:
raise ValueError, "Channel %d is not in dataOut.channelList"
channelIndexList.append(dataOut.channelList.index(channel))
if timerange != None:
self.timerange = timerange
tmin = None
tmax = None
x = dataOut.getTimeRange()
y = dataOut.getHeiRange()
factor = dataOut.normFactor
noise = dataOut.getNoise()/factor
noisedB = 10*numpy.log10(noise)
thisDatetime = dataOut.datatime
title = "RTI Noise: %s" %(thisDatetime.strftime("%d-%b-%Y"))
xlabel = ""
ylabel = "Range (Km)"
if not self.__isConfig:
nplots = 1
self.setup(idfigure=idfigure,
nplots=nplots,
wintitle=wintitle,
showprofile=showprofile)
tmin, tmax = self.getTimeLim(x, xmin, xmax)
if ymin == None: ymin = numpy.nanmin(noisedB)
if ymax == None: ymax = numpy.nanmax(noisedB)
self.name = thisDatetime.strftime("%Y%m%d_%H%M%S")
self.__isConfig = True
self.xdata = numpy.array([])
self.ydata = numpy.array([])
self.setWinTitle(title)
title = "RTI Noise %s" %(thisDatetime.strftime("%d-%b-%Y"))
legendlabels = ["channel %d"%idchannel for idchannel in channelList]
axes = self.axesList[0]
self.xdata = numpy.hstack((self.xdata, x[0:1]))
if len(self.ydata)==0:
self.ydata = noisedB[channelIndexList].reshape(-1,1)
else:
self.ydata = numpy.hstack((self.ydata, noisedB[channelIndexList].reshape(-1,1)))
axes.pmultilineyaxis(x=self.xdata, y=self.ydata,
xmin=tmin, xmax=tmax, ymin=ymin, ymax=ymax,
xlabel=xlabel, ylabel=ylabel, title=title, legendlabels=legendlabels, marker='x', markersize=8, linestyle="solid",
XAxisAsTime=True
)
self.draw()
if save:
if figfile == None:
figfile = self.getFilename(name = self.name)
self.saveFigure(figpath, figfile)
if x[1] + (x[1]-x[0]) >= self.axesList[0].xmax:
self.__isConfig = False
del self.xdata
del self.ydata