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Nueva version para graficos Scope, RTI, Spectra. Se hicieron pruebas con los experimentos EwDRIFTS, MST, IMAGING
Nueva version para graficos Scope, RTI, Spectra. Se hicieron pruebas con los experimentos EwDRIFTS, MST, IMAGING
Daniel Valdez - - Load All Authors

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SpectraProcessor.py
370 lines | 11.8 KiB | text/x-python | PythonLexer
/ schainpy2 / Processing / SpectraProcessor.py
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'''
$Author$
$Id$
'''
import os, sys
import numpy
import time
import datetime
path = os.path.split(os.getcwd())[0]
sys.path.append(path)
from Data.JROData import Spectra
from IO.SpectraIO import SpectraWriter
from Graphics.schainPlotTypes import SpcFigure
#from JRONoise import Noise
class SpectraProcessor:
'''
classdocs
'''
dataInObj = None
dataOutObj = None
noiseObj = None
integratorObjList = []
writerObjList = []
integratorObjIndex = None
writerObjIndex = None
profIndex = 0 # Se emplea cuando el objeto de entrada es un Voltage
def __init__(self):
'''
Constructor
'''
self.integratorObjIndex = None
self.writerObjIndex = None
self.plotObjIndex = None
self.integratorObjList = []
self.writerObjList = []
self.plotObjList = []
self.noiseObj = None
self.buffer = None
self.profIndex = 0
def setup(self, dataInObj=None, dataOutObj=None, nFFTPoints=None, pairList=None):
if dataInObj == None:
raise ValueError, "This SpectraProcessor.setup() function needs dataInObj input variable"
if dataInObj.type == "Voltage":
if nFFTPoints == None:
raise ValueError, "This SpectraProcessor.setup() function needs nFFTPoints input variable"
else:
nFFTPoints = dataInObj.nFFTPoints
self.dataInObj = dataInObj
if dataOutObj == None:
dataOutObj = Spectra()
self.dataOutObj = dataOutObj
return self.dataOutObj
def init(self):
self.integratorObjIndex = 0
self.writerObjIndex = 0
self.plotObjIndex = 0
if self.dataInObj.type == "Voltage":
if self.buffer == None:
self.buffer = numpy.zeros((self.nChannels,
self.nFFTPoints,
self.dataInObj.nHeights),
dtype='complex')
self.buffer[:,self.profIndex,:] = self.dataInObj.data
self.profIndex += 1
if self.profIndex == self.nFFTPoints:
self.__getFft()
self.dataOutObj.flagNoData = False
self.buffer = None
self.profIndex = 0
return
self.dataOutObj.flagNoData = True
return
#Other kind of data
if self.dataInObj.type == "Spectra":
self.dataOutObj.copy(self.dataInObj)
self.dataOutObj.flagNoData = False
return
raise ValueError, "The datatype is not valid"
def __getFft(self):
"""
Convierte valores de Voltaje a Spectra
Affected:
self.dataOutObj.data_spc
self.dataOutObj.data_cspc
self.dataOutObj.data_dc
self.dataOutObj.heightList
self.dataOutObj.m_BasicHeader
self.dataOutObj.m_ProcessingHeader
self.dataOutObj.m_RadarControllerHeader
self.dataOutObj.m_SystemHeader
self.profIndex
self.buffer
self.dataOutObj.flagNoData
self.dataOutObj.dataType
self.dataOutObj.nPairs
self.dataOutObj.nChannels
self.dataOutObj.nProfiles
self.dataOutObj.m_SystemHeader.numChannels
self.dataOutObj.m_ProcessingHeader.totalSpectra
self.dataOutObj.m_ProcessingHeader.profilesPerBlock
self.dataOutObj.m_ProcessingHeader.numHeights
self.dataOutObj.m_ProcessingHeader.spectraComb
self.dataOutObj.m_ProcessingHeader.shif_fft
"""
if self.dataInObj.flagNoData:
return 0
fft_volt = numpy.fft.fft(self.buffer,axis=1)
dc = fft_volt[:,0,:]
#calculo de self-spectra
fft_volt = numpy.fft.fftshift(fft_volt,axes=(1,))
spc = fft_volt * numpy.conjugate(fft_volt)
spc = spc.real
blocksize = 0
blocksize += dc.size
blocksize += spc.size
cspc = None
pairIndex = 0
if self.pairList != None:
#calculo de cross-spectra
cspc = numpy.zeros((self.nPairs, self.nFFTPoints, self.nHeights), dtype='complex')
for pair in self.pairList:
cspc[pairIndex,:,:] = numpy.abs(fft_volt[pair[0],:,:] * numpy.conjugate(fft_volt[pair[1],:,:]))
pairIndex += 1
blocksize += cspc.size
self.dataOutObj.data_spc = spc
self.dataOutObj.data_cspc = cspc
self.dataOutObj.data_dc = dc
self.dataOutObj.m_ProcessingHeader.blockSize = blocksize
self.dataOutObj.m_BasicHeader.utc = self.dataInObj.m_BasicHeader.utc
# self.getNoise()
def addWriter(self, wrpath, blocksPerFile):
objWriter = SpectraWriter(self.dataOutObj)
objWriter.setup(wrpath, blocksPerFile)
self.writerObjList.append(objWriter)
def addIntegrator(self,N,timeInterval):
objIncohInt = IncoherentIntegration(N,timeInterval)
self.integratorObjList.append(objIncohInt)
def addSpc(self, idfigure, nframes, wintitle, driver, colormap, colorbar, showprofile):
spcObj = SpcFigure(idfigure, nframes, wintitle, driver, colormap, colorbar, showprofile)
self.plotObjList.append(spcObj)
def plotSpc(self, idfigure=None,
xmin=None,
xmax=None,
ymin=None,
ymax=None,
minvalue=None,
maxvalue=None,
wintitle='',
driver='plplot',
colormap='br_greeen',
colorbar=True,
showprofile=False,
save=False,
gpath=None):
if self.dataOutObj.flagNoData:
return 0
nframes = len(self.dataOutObj.channelList)
if len(self.plotObjList) <= self.plotObjIndex:
self.addSpc(idfigure, nframes, wintitle, driver, colormap, colorbar, showprofile)
x = numpy.arange(self.dataOutObj.nFFTPoints)
y = self.dataOutObj.heightList
channelList = self.dataOutObj.channelList
data = 10.*numpy.log10(self.dataOutObj.data_spc[channelList,:,:])
# noisedB = 10.*numpy.log10(noise)
noisedB = numpy.arange(len(channelList)+1)
noisedB = noisedB *1.2
titleList = []
for i in range(len(noisedB)):
title = "%.2f"%noisedB[i]
titleList.append(title)
thisdatetime = datetime.datetime.fromtimestamp(self.dataOutObj.dataUtcTime)
dateTime = "%s"%(thisdatetime.strftime("%d-%b-%Y %H:%M:%S"))
figuretitle = "Spc Radar Data: %s"%dateTime
cleardata = True
plotObj = self.plotObjList[self.plotObjIndex]
plotObj.plotPcolor(data,
x,
y,
channelList,
xmin,
xmax,
ymin,
ymax,
minvalue,
maxvalue,
figuretitle,
None,
save,
gpath,
cleardata,
titleList)
self.plotObjIndex += 1
def writeData(self, wrpath, blocksPerFile):
if self.dataOutObj.flagNoData:
return 0
if len(self.writerObjList) <= self.writerObjIndex:
self.addWriter(wrpath, blocksPerFile)
self.writerObjList[self.writerObjIndex].putData()
self.writerObjIndex += 1
def integrator(self, N=None, timeInterval=None):
if self.dataOutObj.flagNoData:
return 0
if len(self.integratorObjList) <= self.integratorObjIndex:
self.addIntegrator(N,timeInterval)
myIncohIntObj = self.integratorObjList[self.integratorObjIndex]
myIncohIntObj.exe(data=self.dataOutObj.data_spc,timeOfData=self.dataOutObj.m_BasicHeader.utc)
if myIncohIntObj.isReady:
self.dataOutObj.data_spc = myIncohIntObj.data
self.dataOutObj.nAvg = myIncohIntObj.navg
self.dataOutObj.m_ProcessingHeader.incoherentInt = self.dataInObj.m_ProcessingHeader.incoherentInt*myIncohIntObj.navg
self.dataOutObj.flagNoData = False
"""Calcular el ruido"""
self.getNoise()
else:
self.dataOutObj.flagNoData = True
self.integratorObjIndex += 1
class IncoherentIntegration:
integ_counter = None
data = None
navg = None
buffer = None
nIncohInt = None
def __init__(self, N = None, timeInterval = None):
"""
N
timeInterval - interval time [min], integer value
"""
self.data = None
self.navg = None
self.buffer = None
self.timeOut = None
self.exitCondition = False
self.isReady = False
self.nIncohInt = N
self.integ_counter = 0
if timeInterval!=None:
self.timeIntervalInSeconds = timeInterval * 60. #if (type(timeInterval)!=integer) -> change this line
if ((timeInterval==None) and (N==None)):
print 'N = None ; timeInterval = None'
sys.exit(0)
elif timeInterval == None:
self.timeFlag = False
else:
self.timeFlag = True
def exe(self,data,timeOfData):
"""
data
timeOfData [seconds]
"""
if self.timeFlag:
if self.timeOut == None:
self.timeOut = timeOfData + self.timeIntervalInSeconds
if timeOfData < self.timeOut:
if self.buffer == None:
self.buffer = data
else:
self.buffer = self.buffer + data
self.integ_counter += 1
else:
self.exitCondition = True
else:
if self.integ_counter < self.nIncohInt:
if self.buffer == None:
self.buffer = data
else:
self.buffer = self.buffer + data
self.integ_counter += 1
if self.integ_counter == self.nIncohInt:
self.exitCondition = True
if self.exitCondition:
self.data = self.buffer
self.navg = self.integ_counter
self.isReady = True
self.buffer = None
self.timeOut = None
self.integ_counter = 0
self.exitCondition = False
if self.timeFlag:
self.buffer = data
self.timeOut = timeOfData + self.timeIntervalInSeconds
else:
self.isReady = False