def writeData(self, outFileName='1Dfeout.h5'): """ Write solution state to hdf5 file. - keff (if applicable) - mesh - elements (nodes in element) - node positions - flux field """ # write [[nodeID, nodeX, nodeY, nodeZ],...] vector (this is gmshMesh.nodes) # write [[nodeID, fluxValue]...] vector (this is the totFluxField) # write eigenvalue h5data = {'nodes': self.nodes, 'ordFluxes': self.superMesh.totFluxField, 'keff': self.keff, 'fluxNorm': self.norm} h5d.writeToHdf5(h5data, outFileName)
def writeData(self, outFileName='1Dfeout.h5'): """ Write solution state to hdf5 file. - keff (if applicable) - mesh - elements (nodes in element) - node positions - flux field """ # write [[nodeID, nodeX, nodeY, nodeZ],...] vector (this is gmshMesh.nodes) # write [[nodeID, fluxValue]...] vector (this is the totFluxField) # write eigenvalue h5data = { 'nodes': self.nodes, 'ordFluxes': self.superMesh.totFluxField, 'keff': self.keff, 'fluxNorm': self.norm } h5d.writeToHdf5(h5data, outFileName)
def testSlab(widths, modMat, borMat): print("\n========= INITIATING MULT REGION TEST ==========") ngrps = 10 sNord = 8 srcStrength = 1.e10 # [n / cm**3-s] # ## REGION WIDTHS width1, dx1 = widths[0], 0.1 end1 = 0 + width1 - dx1 # width2, dx2 = widths[1], 0.02 start2 = end1 + dx1 / 2 + dx2 / 2 end2 = start2 + width2 - dx2 # width3, dx3 = widths[2], 0.1 start3 = end2 + dx2 / 2 + dx3 / 2 end3 = start3 + width3 - dx3 # width4, dx4 = widths[3], 0.02 start4 = end3 + dx3 / 2 + dx4 / 2 #start4 = end3 + dx3 / 1. + dx4 / 1. + 0.04 end4 = start4 + width4 - dx4 # width5, dx5 = widths[4], 0.1 start5 = end4 + dx4 / 2 + dx5 / 2 end5 = start5 + width5 - dx5 # width6, dx6 = widths[5], 0.02 start6 = end5 + dx5 / 2 + dx6 / 2 end6 = start6 + width6 - dx6 # width7, dx7 = widths[6], 0.1 start7 = end6 + dx6 / 2 + dx7 / 2 end7 = start7 + width7 - dx7 # # ## REGIONS Defs ### region1mesh1D = sn.Mesh1Dsn([0, end1 + dx1], dx1, modMat, sN=sNord) src = np.zeros((10, 3, sNord)) src[0, 0, :] = srcStrength bcs1 = {0: {'vac': (1, 0)}} region1mesh1D.setBCs(bcs1) region2mesh1D = sn.Mesh1Dsn([start2, end2], dx2, borMat, sN=sNord, source=src) region3mesh1D = sn.Mesh1Dsn([start3, end3], dx3, modMat, sN=sNord) region4mesh1D = sn.Mesh1Dsn([start4, end4], dx4, borMat, sN=sNord, source=src) region5mesh1D = sn.Mesh1Dsn([start5, end5], dx5, modMat, sN=sNord) region6mesh1D = sn.Mesh1Dsn([start6, end6], dx6, borMat, sN=sNord, source=src) region7mesh1D = sn.Mesh1Dsn([start7, end7 + dx7], dx7, modMat, sN=sNord) bcs2 = {-1: {'vac': (2, 0)}} region7mesh1D.setBCs(bcs2) # ## BUILD DOMAIN ### domain = sn.SubDomain() domain.addRegion(region1mesh1D) domain.addRegion(region2mesh1D) domain.addRegion(region3mesh1D) domain.addRegion(region4mesh1D) domain.addRegion(region5mesh1D) domain.addRegion(region6mesh1D) domain.addRegion(region7mesh1D) domain.buildSweepTree() # # ## SWEEP DOMAIN ### for si in range(180): resid = domain.sweepSubDomain(1) if resid < 1e-6: pass #break scalarFlux = domain.getScalarFlux() #flxPlt.plotFluxE(scalarFlux[-1][::-1]) # flux vs E at left edge centroids = domain.getCentroids() # plot all grp fluxes vs space for g in range(ngrps): sfp.plot1DScalarFlux(scalarFlux[:][:, g], centroids, label='Group ' + str(g + 1), legend=True, enableYlog=False) pass # plot ord fluxes at center of first absorber strip ordFlux = domain.getOrdFlux() angles = np.arccos(domain.regions[0].cells[0].sNmu) print("ord flux plots at " + str(centroids[92]) + "[cm]") for g in range(10): mag = ordFlux[92][g, 0, :] / sum(ordFlux[92][g, 0, :]) #pof.compass(angles, mag, figName='hw3_polar_grp' + str(g + 1)) # plot absorption rate absRate = domain.getAbsRate() #sfp.plot1DScalarFlux(absRate, centroids, label='absRate', legend=True, fnameOut='absRate', figNum=20) # Rate of leakage out of left and right faces leftGrpCurrent, rightGrpCurrent = 0, 0 for g in range(ngrps): leftGrpCurrent += 0.5 * np.sum((domain.regions[0].cells[0].wN[:] * np.abs(domain.regions[0].cells[0].sNmu[:]) * domain.regions[0].cells[0].totOrdFlux[g, 1, :])[sNord/2:]) rightGrpCurrent += 0.5 * np.sum((domain.regions[6].cells[-1].wN[:] * np.abs(domain.regions[6].cells[-1].sNmu[:]) * domain.regions[6].cells[-1].totOrdFlux[g, 2, :])[:sNord/2]) # total neutron production rate (3x abs pins of width 2cm) totProd = 1e10 * 2 * 3 # (n/s-cm^3) * (cm) -> n/s-cm^2 # fraction out left and right face lfl = leftGrpCurrent / totProd rfl = rightGrpCurrent / totProd print("Fraction of source neutrons leaking left= " + str(lfl)) print("Fraction of source neutrons leaking right= " + str(rfl)) # non leakage prob nlp = 1 - (leftGrpCurrent + rightGrpCurrent) / totProd print("Non Leakage Probability= " + str(nlp)) # compute dimensionless parameter: pi1 totXS = domain.regions[1].totalXs weightedXS = np.max(totXS) #weightedXS = np.sum(totXS * domain.getScalarFlux([0, 6]), axis=1) totFlux = np.sum(domain.getScalarFlux([0, 6]), axis=1) #flux = np.sum(domain.getScalarFlux([1, 3, 5])) #pi1 = 6.0 * np.average(weightedXS / totFlux) pi1 = 6.0 * weightedXS # dump ord fluxes and source to h5 file h5data = {'mesh': domain.getCentroids(), 'ordFluxes': domain.getOrdFlux(), 'source': domain.getSource(), 'scalarFluxes': scalarFlux[:]} h5d.writeToHdf5(h5data, '1d_7region.h5') return nlp, pi1