# # Author: Heresh Fattahi # Copyright 2017 # import logging import isceobj from contrib.splitSpectrum import SplitRangeSpectrum as splitSpectrum import numpy as np import os from isceobj.Constants import SPEED_OF_LIGHT import time logger = logging.getLogger('isce.insar.runSplitSpectrum') def split(fullBandSlc, lowBandSlc, highBandSlc, fs, bL, bH, fL, fH): ss = splitSpectrum() ss.blocksize = 100 ss.memsize = 512 ss.inputDS = fullBandSlc + ".vrt" ss.lbDS = lowBandSlc ss.hbDS = highBandSlc ss.rangeSamplingRate = fs ss.lowBandWidth = bL ss.highBandWidth = bH ss.lowCenterFrequency = fL ss.highCenterFrequency = fH ss.split() def createSlcImage(slcName, width): slc = isceobj.createSlcImage() slc.setWidth(width) slc.filename = slcName slc.setAccessMode('write') slc.renderHdr() def adjustCenterFrequency(B, N, dc): # because of quantization, there may not be an index representing dc. We # therefore adjust dc to make sure that there is an index to represent it. # We find the index that is closest to nominal dc and then adjust dc to the # frequency of that index. # B = full band-width # N = length of signal # dc = center frequency of the sub-band df = B/N if (dc < 0): ind = N + np.round(dc/df) else: ind = np.round(dc/df); dc = frequency (B, N, ind) return dc def frequency (B, N, n): # calculates frequency at a given index. # Assumption: for indices 0 to (N-1)/2, frequency is positive # and for indices larger than (N-1)/2 frequency is negative #frequency interval given B as the total bandwidth df = B/N middleIndex = int((N-1)/2) if (n > middleIndex): f = (n-N)*df else: f = n*df return f def runSplitSpectrum(self): ''' Generate split spectrum SLCs. ''' if not self.doSplitSpectrum: print('Split spectrum processing not requested. Skipping ....') return referenceFrame = self._insar.loadProduct( self._insar.referenceSlcCropProduct) secondaryFrame = self._insar.loadProduct( self._insar.secondarySlcCropProduct) referenceSlc = referenceFrame.getImage().filename secondarySlc = secondaryFrame.getImage().filename width1 = referenceFrame.getImage().getWidth() width2 = secondaryFrame.getImage().getWidth() fs_reference = referenceFrame.rangeSamplingRate pulseLength_reference = referenceFrame.instrument.pulseLength chirpSlope_reference = referenceFrame.instrument.chirpSlope #Bandwidth B_reference = np.abs(chirpSlope_reference)*pulseLength_reference fs_secondary = secondaryFrame.rangeSamplingRate pulseLength_secondary = secondaryFrame.instrument.pulseLength chirpSlope_secondary = secondaryFrame.instrument.chirpSlope #Bandwidth B_secondary = np.abs(chirpSlope_secondary)*pulseLength_secondary print("reference image range sampling rate: {0} MHz".format(fs_reference/(1.0e6))) print("secondary image range sampling rate: {0} MHz".format(fs_secondary/(1.0e6))) print("reference image total range bandwidth: {0} MHz".format(B_reference/(1.0e6))) print("secondary image total range bandwidth: {0} MHz".format(B_secondary/(1.0e6))) # If the bandwidth of reference and secondary are different, choose the smaller bandwidth # for range split spectrum B = np.min([B_secondary, B_reference]) print("Bandwidth used for split spectrum: {0} MHz".format(B/(1.e6))) # Dividing the total bandwidth of B to three bands and consider the sub bands on # the most left and right hand side as the spectrum of low band and high band SLCs # band width of the low-band bL = B/3.0 # band width of the high-band bH = B/3.0 # center frequency of the low-band fL = -1.0*B/3.0 # center frequency of the high-band fH = B/3.0 lowBandDir = os.path.join(self.insar.splitSpectrumDirname, self.insar.lowBandSlcDirname) highBandDir = os.path.join(self.insar.splitSpectrumDirname, self.insar.highBandSlcDirname) os.makedirs(lowBandDir, exist_ok=True) os.makedirs(highBandDir, exist_ok=True) referenceLowBandSlc = os.path.join(lowBandDir, os.path.basename(referenceSlc)) referenceHighBandSlc = os.path.join(highBandDir, os.path.basename(referenceSlc)) secondaryLowBandSlc = os.path.join(lowBandDir, os.path.basename(secondarySlc)) secondaryHighBandSlc = os.path.join(highBandDir, os.path.basename(secondarySlc)) radarWavelength = referenceFrame.radarWavelegth print("deviation of low-band's center frequency from full-band's center frequency: {0} MHz".format(fL/1.0e6)) print("deviation of high-band's center frequency from full-band's center frequency: {0} MHz".format(fH/1.0e6)) print("%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%") print("splitting the range-spectrum of reference SLC") split(referenceSlc, referenceLowBandSlc, referenceHighBandSlc, fs_reference, bL, bH, fL, fH) print("%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%") print("splitting the range-spectrum of secondary SLC") split(secondarySlc, secondaryLowBandSlc, secondaryHighBandSlc, fs_secondary, bL, bH, fL, fH) ######################## createSlcImage(referenceLowBandSlc, width1) createSlcImage(referenceHighBandSlc, width1) createSlcImage(secondaryLowBandSlc, width2) createSlcImage(secondaryHighBandSlc, width2) ######################## f0 = SPEED_OF_LIGHT/radarWavelength fH = f0 + fH fL = f0 + fL wavelengthL = SPEED_OF_LIGHT/fL wavelengthH = SPEED_OF_LIGHT/fH self.insar.lowBandRadarWavelength = wavelengthL self.insar.highBandRadarWavelength = wavelengthH self.insar.lowBandSlc1 = referenceLowBandSlc self.insar.lowBandSlc2 = secondaryLowBandSlc self.insar.highBandSlc1 = referenceHighBandSlc self.insar.highBandSlc2 = secondaryHighBandSlc ########################