def IntegratorNL1D(V, P, C_V, C_P, probeReadFinishBe, probeReadStartAf):
i = 1
V.tempVarPol, V.tempTempVarE, V.tempVarE, V.tempTempVarPol, V.polarisationCurr, V.Ex, V.Dx, V.Hy = BaseFDTD11.FieldInit(
V, P) #Not necessary?
V.UpHyMat, V.UpExMat = BaseFDTD11.EmptySpaceCalc(V, P)
# move these into bc manager, call bc manager from here
C_V = BaseFDTD11.CPML_FieldInit(V, P, C_V, C_P)
C_V = boundCondManager(V, P, C_V, C_P)
lamCont, lamDisc, diff, V.plasmaFreqE, fix = gStab.spatialStab(
P.timeSteps, P.Nz, P.dz, P.freq_in, P.delT, V.plasmaFreqE, V.omega_0E,
V.gammaE)
Exs, Hys = SourceManager(V, P, C_V, C_P)
#Exs = Sig_Mod(V,P, Exs)
#Hys = Sig_Mod(V,P, Hys, AmpMod = 1/P.CharImp)
for counts in range(0, P.timeSteps):
#if i == 1:
#V.tempTempVarPol, V.tempVarPol, V.tempVarE, V.tempTempVarE, V.tempTempVarHy, V.tempVarHy, V.tempTempVarJx, V.tempVarJx, C_V.tempTempVarPsiEx, C_V.tempVarPsiEx, C_V.tempTempVarPsiHy, C_V.tempVarPsiHy = BaseFDTD11.ADE_TempPolCurr(V,P, C_V, C_P)
#V.polarisationCurr = BaseFDTD11.ADE_PolarisationCurrent_Ex(V, P, C_V, C_P, counts)
V.Ex = BaseFDTD11.ADE_ExUpdate(V, P, C_V, C_P, counts)
# V.Jx = BaseFDTD11.ADE_JxUpdate(V,P, C_V, C_P)
if P.CPMLXp == True or P.CPMLXm == True: # Go into cpml field updates to choose x+ and x-
C_V.psi_Ex, V.Ex = BaseFDTD11.CPML_Psi_e_Update(V, P, C_V, C_P)
V.Ex[P.nzsrc] += Exs[counts] / P.courantNo
if P.TFSF == True:
V.Hy[P.nzsrc - 1] -= Hys[counts] / P.courantNo
V.Dx = BaseFDTD11.ADE_DxUpdate(V, P, C_V, C_P) # Linear bit
# V.Ex =BaseFDTD11.ADE_ExCreate(V, P, C_V, C_P)
V.Acubic = BaseFDTD11.AcubicFinder(V, P)
if not counts % 50:
print(counts)
V.Ex = BaseFDTD11.NonLinExUpdate(V, P)
V.Hy = BaseFDTD11.ADE_HyUpdate(V, P, C_V, C_P)
if P.CPMLXp == True or P.CPMLXm == True:
C_V.psi_Hy, V.Hy = BaseFDTD11.CPML_Psi_m_Update(V, P, C_V, C_P)
if counts > 0:
if counts % P.vidInterval == 0:
if i == 1:
V.Ex_History = vidMake(V,
P,
C_V,
C_P,
counts,
V.Ex,
whichField="Ex")
V.Port1, V.Port2 = probeSim(V, P, C_V, C_P, counts, nonlinear=True)
return V.Ex, V.Hy, Exs, Hys, C_V.psi_Ex, C_V.psi_Hy, V.x1ColBe, V.x1ColAf
def IntegratorLinLor1D(V, P, C_V, C_P, probeReadFinishBe, probeReadStartAf):
for i in range(0, 2):
V.tempVarPol, V.tempTempVarE, V.tempVarE, V.tempTempVarPol, V.polarisationCurr, V.Ex, V.Dx, V.Hy = BaseFDTD11.FieldInit(
V, P)
V.UpHyMat, V.UpExMat = BaseFDTD11.EmptySpaceCalc(V, P)
# move these into bc manager, call bc manager from here
C_V = BaseFDTD11.CPML_FieldInit(V, P, C_V, C_P)
C_V = boundCondManager(V, P, C_V, C_P)
lamCont, lamDisc, diff, V.plasmaFreqE, fix = gStab.spatialStab(
P.timeSteps, P.Nz, P.dz, P.freq_in, P.delT, V.plasmaFreqE,
V.omega_0E, V.gammaE)
Exs, Hys = SourceManager(V, P, C_V, C_P)
tauIn = 1 / (P.freq_in / 5)
#Exs = Sig_Mod(V,P, Exs,tau =tauIn)
# Hys = Sig_Mod(V,P, Hys, AmpMod = 1/P.CharImp, tau = tauIn)
#gStab.vonNeumannAnalysis(V,P,C_V,C_P)
V.test = 0
for counts in range(0, P.timeSteps):
if i == 1:
V.tempTempVarPol, V.tempVarPol, V.tempVarE, V.tempTempVarE, V.tempTempVarHy, V.tempVarHy, V.tempTempVarJx, V.tempVarJx, C_V.tempTempVarPsiEx, C_V.tempVarPsiEx, C_V.tempTempVarPsiHy, C_V.tempVarPsiHy = BaseFDTD11.ADE_TempPolCurr(
V, P, C_V, C_P)
V.polarisationCurr = BaseFDTD11.ADE_PolarisationCurrent_Ex(
V, P, C_V, C_P, counts)
V.Ex = BaseFDTD11.ADE_ExUpdate(V, P, C_V, C_P, counts)
# V.Jx = BaseFDTD11.ADE_JxUpdate(V,P, C_V, C_P)
if P.CPMLXp == True or P.CPMLXm == True: # Go into cpml field updates to choose x+ and x-
C_V.psi_Ex, V.Ex = BaseFDTD11.CPML_Psi_e_Update(V, P, C_V, C_P)
V.Ex[P.nzsrc] += Exs[counts] / P.courantNo
if P.TFSF == True:
V.Hy[P.nzsrc - 1] -= Hys[counts] / P.courantNo
V.Dx = BaseFDTD11.ADE_DxUpdate(V, P, C_V, C_P)
V.Ex = BaseFDTD11.ADE_ExCreate(V, P, C_V, C_P)
V.Hy = BaseFDTD11.ADE_HyUpdate(V, P, C_V, C_P)
if P.CPMLXp == True or P.CPMLXm == True:
C_V.psi_Hy, V.Hy = BaseFDTD11.CPML_Psi_m_Update(V, P, C_V, C_P)
#V.Ex = BaseFDTD11.MUR1DEx(V, P, C_V, C_P)
#C_V.psi_Ex, V.Ex = BaseFDTD11.CPML_Psi_e_Update(V,P, C_V, C_P)
# V.Ex = BaseFDTD11.MUR1DEx(V, P, C_V, C_P)
"""
Re write probes to not require Ex_History.
Re write History to be optional and be taken in interval steps
Re write probes into a different function
Create transmission probes and attenuation probes.
Spatial dispersion plot alongside looping parameters
Function which plots epsilon, mu, refractive index etc with loop
Rigorous reflection and transmission probe timings.
Beer's law vs attenuation plot
clean up redundant code, split big functions into smaller ones,
split scripts into multiple scripts.
Prepare for nonlinear ade (Harmonics, then resonance tuning
Manley-Rowe verification, resonance tuning verification?)
Prepare for 2D, (Extra update fields, plots, dispersion checks,
2D checks angles stuff, geometry designer)
Simple charged particle distribution evolution. 25th Jan?
should free space pre-reflection be running Dx? Maybe just call
free space integrator once?
"""
if counts > 0: # MOVE TO FUNCTION
if counts % P.vidInterval == 0:
if i == 1:
V.Ex_History = vidMake(V,
P,
C_V,
C_P,
counts,
V.Ex,
whichField="Ex")
# option to not store history, and even when storing, only store in
#intervals
if i == 0:
if counts <= P.timeSteps - 1:
if counts <= probeReadFinishBe:
V.x1ColBe = probeSim(V, P, C_V, C_P, counts,
V.Ex[P.x1Loc])
#change this from Ex history
elif i == 1:
if counts <= P.timeSteps - 1:
if counts >= probeReadStartAf:
V.x1ColAf = probeSim(V,
P,
C_V,
C_P,
counts,
V.Ex[P.x2Loc],
af=True)
if P.atten == True:
V.x1Atten = probeSim(V,
P,
C_V,
C_P,
counts,
V.Ex[P.x2Loc],
attenRead=True)
return V.Ex, V.Hy, Exs, Hys, C_V.psi_Ex, C_V.psi_Hy, V.x1ColBe, V.x1ColAf