-- Vlasov-Poisson solver in Poisson-Bracket formulation
----------------------------------
-- Problem dependent parameters --
----------------------------------
log = Lucee.logInfo
polyOrder = 2 -- polynomial order
epsilon0 = 1.0 -- permittivity of free space
Te_Ti = 9.0 -- ratio of electron to ion temperaute
machNum = 5.0 -- Mach number computed from ion thermal speed
n0 = 1.0 -- initial number density
elcTemp = 1.0 -- electron temperature
elcMass = 1.0 -- electron mass
elcCharge = -1.0 -- electron charge
ionTemp = elcTemp/Te_Ti -- ion temperature
ionMass = 1836.2 -- ion mass
ionCharge = 1.0 -- ion charge
-- thermal speeds
cs = math.sqrt(elcTemp/ionMass)
vtElc = math.sqrt(elcTemp/elcMass)
vtIon = math.sqrt(ionTemp/ionMass)
-- plasma frequency and Debye length
wpe = math.sqrt(elcCharge^2*n0/(epsilon0*elcMass))
lambdaD = vtElc/wpe
-- electron and ion drift speeds
elcDrift = machNum*cs
ionDrift = elcDrift -- no net current
-- domain size and simulation time
LX = 500*lambdaD
tStart = 0.0 -- start time
tEnd = 1000.0/wpe
nFrames = 100
-- Resolution, time-stepping etc.
NX = 512
NV = 32
polyOrder = 2
cfl = 0.5/(2*polyOrder+1)
-- compute max thermal speed to set velocity space extents
VL_ELC, VU_ELC = -6.0*vtElc, 6.0*vtElc
VL_ION, VU_ION = -10.0*vtIon-ionDrift, 10.0*vtIon+ionDrift
-- print some diagnostics
log(string.format("tEnd=%g, nFrames=%d", tEnd, nFrames))
log(string.format("Sound speed=%g", cs))
log(string.format("Mach number=%g", machNum))
log(string.format("Electron thermal speed=%g", vtElc))
log(string.format("Plasma frequency=%g", wpe))
log(string.format("Debye length=%g", lambdaD))
log(string.format("Cell size=%g", LX/NX))
log(string.format("Ion thermal speed=%g", vtIon))
log(string.format("Electron/Ion drift speed=%g", elcDrift))
log(string.format("Electron domain extents = [%g,%g]", VL_ELC, VU_ELC))
log(string.format("Ion domain extents = [%g,%g]", VL_ION, VU_ION))
------------------------------------------------
-- COMPUTATIONAL DOMAIN, DATA STRUCTURE, ETC. --
------------------------------------------------
-- decomposition object
phaseDecomp = DecompRegionCalc2D.CartProd { cuts = {8,4} }
confDecomp = DecompRegionCalc1D.SubCartProd2D {
decomposition = phaseDecomp,
collectDirections = {0},
}
-- phase space grid for electrons
phaseGridElc = Grid.RectCart2D {
lower = {0.0, VL_ELC},
upper = {LX, VU_ELC},
cells = {NX, NV},
decomposition = phaseDecomp,
}
-- phase space grid for ions
phaseGridIon = Grid.RectCart2D {
lower = {0.0, VL_ION},
upper = {LX, VU_ION},
cells = {NX, NV},
decomposition = phaseDecomp,
}
-- configuration space grid (same for electrons and ions)
confGrid = Grid.RectCart1D {
lower = {0.0},
upper = {LX},
cells = {NX},
decomposition = confDecomp,
}
-- phase-space basis functions for electrons and ions
phaseBasisElc = NodalFiniteElement2D.Serendipity {
onGrid = phaseGridElc,
polyOrder = polyOrder,
}
phaseBasisIon = NodalFiniteElement2D.Serendipity {
onGrid = phaseGridIon,
polyOrder = polyOrder,
}
-- configuration-space basis functions (shared by both species)
confBasis = NodalFiniteElement1D.Lobatto {
onGrid = confGrid,
polyOrder = polyOrder,
}
-- distribution function for electrons
distfElc = DataStruct.Field2D {
onGrid = phaseGridElc,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
-- distribution function for ions
distfIon = DataStruct.Field2D {
onGrid = phaseGridIon,
numComponents = phaseBasisIon:numNodes(),
ghost = {1, 1},
}
-- extra fields for performing RK update
distfNewElc = DataStruct.Field2D {
onGrid = phaseGridElc,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
distf1Elc = DataStruct.Field2D {
onGrid = phaseGridElc,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
distfNewIon = DataStruct.Field2D {
onGrid = phaseGridIon,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
distf1Ion = DataStruct.Field2D {
onGrid = phaseGridIon,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
-- Electron number density
numDensityElc = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- Ion number density
numDensityIon = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- Electron momentum
momentumElc = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- Ion momentum
momentumIon = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- Electron particle energy
ptclEnergyElc = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- Ion particle energy
ptclEnergyIon = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- charge density
chargeDensity = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- field to store potential in 1D
phi1d = DataStruct.Field1D {
onGrid = confGrid,
numComponents = confBasis:numNodes(),
ghost = {1, 1},
}
-- Electron Hamiltonian
hamilElc = DataStruct.Field2D {
onGrid = phaseGridElc,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
-- Ion Hamiltonian
hamilIon = DataStruct.Field2D {
onGrid = phaseGridIon,
numComponents = phaseBasisIon:numNodes(),
ghost = {1, 1},
}
-- create field to store kinetic energy term in Hamiltonian
hamilKeElc = DataStruct.Field2D {
onGrid = phaseGridElc,
numComponents = phaseBasisElc:numNodes(),
ghost = {1, 1},
}
hamilKeIon = DataStruct.Field2D {
onGrid = phaseGridIon,
numComponents = phaseBasisIon:numNodes(),
ghost = {1, 1},
}
--------------------------------
-- INITIAL CONDITION UPDATERS --
--------------------------------
-- Maxwellian with number density 'n0', drift-speed 'vdrift' and
-- thermal speed 'vt' = \sqrt{T/m}, where T and m are species
-- temperature and mass respectively.
function maxwellian(n0, vdrift, vt, v)
return n0/math.sqrt(2*Lucee.Pi*vt^2)*math.exp(-(v-vdrift)^2/(2*vt^2))
end
-- updater to initialize distribution function
initDistfElc = Updater.ProjectOnNodalBasis2D {
onGrid = phaseGridElc,
basis = phaseBasisElc,
-- are common nodes shared?
shareCommonNodes = false, -- In DG, common nodes are not shared
-- function to use for initialization
evaluate = function(x,v,z,t)
local sloc = 0.5*LX
local fxv = maxwellian(n0, elcDrift, vtElc, v)
if x>sloc then
fxv = maxwellian(n0, -elcDrift, vtElc, v)
end
return fxv
end
}
-- updater to initialize distribution function
initDistfIon = Updater.ProjectOnNodalBasis2D {
onGrid = phaseGridIon,
basis = phaseBasisIon,
-- are common nodes shared?
shareCommonNodes = false, -- In DG, common nodes are not shared
-- function to use for initialization
evaluate = function(x,v,z,t)
local sloc = 0.5*LX
local fxv = maxwellian(n0, ionDrift, vtIon, v)
if x>sloc then
fxv = maxwellian(n0, -ionDrift, vtIon, v)
end
return fxv
end
}
-- updater to initialize electron kinetic energy term in Hamiltonian
initHamilKeElc = Updater.EvalOnNodes2D {
onGrid = phaseGridElc,
basis = phaseBasisElc,
-- are common nodes shared?
shareCommonNodes = false,
-- function to use for initialization
evaluate = function (x,y,z,t)
local v = y
return v^2/2
end
}
-- updater to initialize ion kinetic energy term in Hamiltonian
initHamilKeIon = Updater.EvalOnNodes2D {
onGrid = phaseGridIon,
basis = phaseBasisIon,
-- are common nodes shared?
shareCommonNodes = false,
-- function to use for initialization
evaluate = function (x,y,z,t)
local v = y
return v^2/2
end
}
----------------------
-- EQUATION SOLVERS --
----------------------
-- Updater for electron Vlasov equation
vlasovSolverElc = Updater.PoissonBracket {
onGrid = phaseGridElc,
basis = phaseBasisElc,
cfl = cfl,
-- flux type: one of "upwind" (default) or "central"
fluxType = "upwind",
hamilNodesShared = false, -- Hamiltonian is not continuous
zeroFluxDirections = {1},
}
vlasovSolverIon = Updater.PoissonBracket {
onGrid = phaseGridIon,
basis = phaseBasisIon,
cfl = cfl,
-- flux type: one of "upwind" (default) or "central"
fluxType = "upwind",
hamilNodesShared = false, -- Hamiltonian is not continuous
zeroFluxDirections = {1},
}
-- Updater to compute electron number density
numDensityCalcElc = Updater.DistFuncMomentCalc1D {
onGrid = phaseGridElc,
basis2d = phaseBasisElc,
basis1d = confBasis,
moment = 0, -- moment to compute
}
numDensityCalcIon = Updater.DistFuncMomentCalc1D {
onGrid = phaseGridIon,
basis2d = phaseBasisIon,
basis1d = confBasis,
moment = 0, --moment to compute
}
-- updater to compute phi from charge density
phiFromChargeDensityCalc = Updater.FemPoisson1D {
onGrid = confGrid,
basis = confBasis,
sourceNodesShared = false, -- charge density is discontinous
solutionNodesShared = false, -- solution is discontinous
-- left boundary is wall, so fix potential to ground
bcLeft = { T = "D", V = 0.0 },
-- right boundary is wall, so fix potential to ground
bcRight = { T = "D", V = 0.0 },
}
-- Updater to compute electron momentum
momentumCalcElc = Updater.DistFuncMomentCalc1D {
onGrid = phaseGridElc,
basis2d = phaseBasisElc,
basis1d = confBasis,
moment = 1,
}
momentumCalcIon = Updater.DistFuncMomentCalc1D {
onGrid = phaseGridIon,
basis2d = phaseBasisIon,
basis1d = confBasis,
moment = 1,
}
-- Updater to compute electron momentum
ptclEnergyCalcElc = Updater.DistFuncMomentCalc1D {
onGrid = phaseGridElc,
basis2d = phaseBasisElc,
basis1d = confBasis,
moment = 2,
}
ptclEnergyCalcIon = Updater.DistFuncMomentCalc1D {
onGrid = phaseGridIon,
basis2d = phaseBasisIon,
basis1d = confBasis,
moment = 2,
}
-- updater to copy potential (1D field) to Hamiltonian (2D) field
-- (used in constructing full Hamiltonian, which also includes the KE
-- part)
copyTo2DElc = Updater.CopyNodalFields1D_2D {
onGrid = phaseGridElc,
sourceBasis = confBasis,
targetBasis = phaseBasisElc
}
copyTo2DIon = Updater.CopyNodalFields1D_2D {
onGrid = phaseGridIon,
sourceBasis = confBasis,
targetBasis = phaseBasisIon
}
-------------------------
-- Boundary Conditions --
-------------------------
-- boundary applicator objects for fluids and fields
-- apply boundary conditions
function applyBc(curr, dt, fldElc, fldIon)
for i,bc in ipairs({}) do
runUpdater(bc, curr, dt, {}, {fldElc})
end
for i,bc in ipairs({}) do
runUpdater(bc, curr, dt, {}, {fldIon})
end
for i,fld in ipairs({fldElc, fldIon}) do
fld:applyCopyBc(0, "lower")
fld:applyCopyBc(0, "upper")
end
-- sync the distribution function across processors
fldElc:sync()
fldIon:sync()
end
----------------------------
-- DIAGNOSIS AND DATA I/O --
----------------------------
totalPtclElc = DataStruct.DynVector { numComponents = 1, }
totalPtclIon = DataStruct.DynVector { numComponents = 1, }
-- updater compute total number of electrons in domain
totalPtclCalcElc = Updater.IntegrateNodalField1D {
onGrid = confGrid,
basis = confBasis,
shareCommonNodes = false, -- for DG fields common nodes not shared
}
-- updater compute total number of ions in domain
totalPtclCalcIon = Updater.IntegrateNodalField1D {
onGrid = confGrid,
basis = confBasis,
shareCommonNodes = false, -- for DG fields common nodes not shared
}
----------------------
-- SOLVER UTILITIES --
----------------------
-- generic function to run an updater
function runUpdater(updater, currTime, timeStep, inpFlds, outFlds)
updater:setCurrTime(currTime)
if inpFlds then
updater:setIn(inpFlds)
end
if outFlds then
updater:setOut(outFlds)
end
return updater:advance(currTime+timeStep)
end
-- function to calculate number density
function calcNumDensity(calculator, curr, dt, distfIn, numDensOut)
return runUpdater(calculator, curr, dt, {distfIn}, {numDensOut})
end
-- function to calculate momentum density
function calcMomentum(calculator, curr, dt, distfIn, momentumOut)
return runUpdater(calculator, curr, dt, {distfIn}, {momentumOut})
end
-- function to calculate energy density
function calcPtclEnergy(calculator, curr, dt, distfIn, energyOut)
return runUpdater(calculator, curr, dt, {distfIn}, {energyOut})
end
-- function to compute moments from distribution function
function calcMoments(curr, dt, distfElcIn, distfIonIn)
-- number density
calcNumDensity(numDensityCalcElc, curr, dt, distfElcIn, numDensityElc)
calcNumDensity(numDensityCalcIon, curr, dt, distfIonIn, numDensityIon)
-- momentum
calcMomentum(momentumCalcElc, curr, dt, distfElcIn, momentumElc)
calcMomentum(momentumCalcIon, curr, dt, distfIonIn, momentumIon)
-- energy
calcPtclEnergy(ptclEnergyCalcElc, curr, dt, distfElcIn, ptclEnergyElc)
calcPtclEnergy(ptclEnergyCalcIon, curr, dt, distfIonIn, ptclEnergyIon)
end
-- function to copy 1D field to 2D field
function copyPhi(copier, curr, dt, phi1, phi2)
runUpdater(copier, curr, dt, {phi1}, {phi2})
phi2:sync()
end
-- function to update Vlasov equation
function updateVlasovEqn(pbSlvr, curr, dt, distfIn, hamilIn, distfOut)
return runUpdater(pbSlvr, curr, dt, {distfIn, hamilIn}, {distfOut})
end
-- function to compute phi from number density
function calcPhiFromChargeDensity(curr, dt, distElcIn, distIonIn, phiOut)
calcMoments(curr, dt, distElcIn, distIonIn)
-- charge density: -rhoc/epsilon0
chargeDensity:combine(-ionCharge/epsilon0, numDensityIon, -elcCharge/epsilon0, numDensityElc)
return runUpdater(phiFromChargeDensityCalc, curr, dt, {chargeDensity}, {phiOut})
end
-- compute hamiltonian for electrons
function calcHamiltonianElc(curr, dt, phiIn, hamilOut)
hamilOut:clear(0.0)
copyPhi(copyTo2DElc, curr, dt, phiIn, hamilOut)
hamilOut:scale(elcCharge/elcMass)
hamilOut:accumulate(1.0, hamilKeElc)
end
-- compute hamiltonian for ions
function calcHamiltonianIon(curr, dt, phiIn, hamilOut)
hamilOut:clear(0.0)
copyPhi(copyTo2DIon, curr, dt, phiIn, hamilOut)
hamilOut:scale(ionCharge/ionMass)
hamilOut:accumulate(1.0, hamilKeIon)
end
-- function to compute diagnostics
function calcDiagnostics(curr, dt)
runUpdater(totalPtclCalcElc, curr, dt, {numDensityElc}, {totalPtclElc})
runUpdater(totalPtclCalcIon, curr, dt, {numDensityIon}, {totalPtclIon})
end
----------------------------
-- Time-stepping routines --
----------------------------
function rk3(tCurr, myDt)
local statusElc, dtSuggestedElc
local statusIon, dtSuggestedIon
-- RK stage 1
statusElc, dtSuggestedElc = updateVlasovEqn(vlasovSolverElc, tCurr, myDt, distfElc, hamilElc, distf1Elc)
statusIon, dtSuggestedIon = updateVlasovEqn(vlasovSolverIon, tCurr, myDt, distfIon, hamilIon, distf1Ion)
if (statusElc == false) or (statusIon == false) then
return false, math.min(dtSuggestedElc, dtSuggestedIon)
end
applyBc(tCurr, myDt, distf1Elc, distf1Ion)
calcPhiFromChargeDensity(tCurr, myDt, distf1Elc, distf1Ion, phi1d)
calcHamiltonianElc(tCurr, myDt, phi1d, hamilElc)
calcHamiltonianIon(tCurr, myDt, phi1d, hamilIon)
-- RK stage 2
statusElc, dtSuggestedElc = updateVlasovEqn(vlasovSolverElc, tCurr, myDt, distf1Elc, hamilElc, distfNewElc)
statusIon, dtSuggestedIon = updateVlasovEqn(vlasovSolverIon, tCurr, myDt, distf1Ion, hamilIon, distfNewIon)
if (statusElc == false) or (statusIon == false) then
return false, math.min(dtSuggestedElc, dtSuggestedIon)
end
distf1Elc:combine(3.0/4.0, distfElc, 1.0/4.0, distfNewElc)
distf1Ion:combine(3.0/4.0, distfIon, 1.0/4.0, distfNewIon)
applyBc(tCurr, myDt, distf1Elc, distf1Ion)
calcPhiFromChargeDensity(tCurr, myDt, distf1Elc, distf1Ion, phi1d)
calcHamiltonianElc(tCurr, myDt, phi1d, hamilElc)
calcHamiltonianIon(tCurr, myDt, phi1d, hamilIon)
-- RK stage 3
statusElc, dtSuggestedElc = updateVlasovEqn(vlasovSolverElc, tCurr, myDt, distf1Elc, hamilElc, distfNewElc)
statusIon, dtSuggestedIon = updateVlasovEqn(vlasovSolverIon, tCurr, myDt, distf1Ion, hamilIon, distfNewIon)
if (statusElc == false) or (statusIon == false) then
return false, math.min(dtSuggestedElc, dtSuggestedIon)
end
distf1Elc:combine(1.0/3.0, distfElc, 2.0/3.0, distfNewElc)
distf1Ion:combine(1.0/3.0, distfIon, 2.0/3.0, distfNewIon)
applyBc(tCurr, myDt, distf1Elc, distf1Ion)
distfElc:copy(distf1Elc)
distfIon:copy(distf1Ion)
calcPhiFromChargeDensity(tCurr, myDt, distfElc, distfIon, phi1d)
calcHamiltonianElc(tCurr, myDt, phi1d, hamilElc)
calcHamiltonianIon(tCurr, myDt, phi1d, hamilIon)
return true, math.min(dtSuggestedElc, dtSuggestedIon)
end
-- make a duplicate in case we need it
distfDupElc = distfElc:duplicate()
distfDupIon = distfIon:duplicate()
-- function to advance solution from tStart to tEnd
function runSimulation(tStart, tEnd, nFrames, initDt)
local frame = 1
local tFrame = (tEnd-tStart)/nFrames
local nextIOt = tFrame
local step = 1
local tCurr = tStart
local myDt = initDt
local status, dtSuggested
-- the grand loop
while true do
distfDupElc:copy(distfElc)
distfDupIon:copy(distfIon)
-- if needed adjust dt to hit tEnd exactly
if (tCurr+myDt > tEnd) then
myDt = tEnd-tCurr
end
-- advance particles and fields
log (string.format(" Taking step %5d at time %6g with dt %g", step, tCurr, myDt))
status, dtSuggested = rk3(tCurr, myDt)
if (status == false) then
-- time-step too large
log (string.format(" ** Time step %g too large! Will retake with dt %g", myDt, dtSuggested))
myDt = dtSuggested
distfElc:copy(distfDupElc)
distfIon:copy(distfDupIon)
else
-- compute diagnostics
calcDiagnostics(tCurr, myDt)
-- write out data
if (tCurr+myDt > nextIOt or tCurr+myDt >= tEnd) then
log (string.format(" Writing data at time %g (frame %d) ...\n", tCurr+myDt, frame))
writeFields(frame, tCurr+myDt)
frame = frame + 1
nextIOt = nextIOt + tFrame
step = 0
end
tCurr = tCurr + myDt
myDt = dtSuggested
step = step + 1
-- check if done
if (tCurr >= tEnd) then
break
end
end
end -- end of time-step loop
return dtSuggested
end
-- Write out data frame 'frameNum' with at specified time 'tCurr'
function writeFields(frameNum, tCurr)
-- distribution functions
distfElc:write(string.format("distfElc_%d.h5", frameNum), tCurr)
distfIon:write(string.format("distfIon_%d.h5", frameNum), tCurr)
-- potential
phi1d:write(string.format("phi_%d.h5", frameNum), tCurr)
-- moments
numDensityElc:write(string.format("numDensityElc_%d.h5", frameNum), tCurr)
numDensityIon:write(string.format("numDensityIon_%d.h5", frameNum), tCurr)
momentumElc:write(string.format("momentumElc_%d.h5", frameNum), tCurr)
momentumIon:write(string.format("momentumIon_%d.h5", frameNum), tCurr)
-- diagnostics
totalPtclElc:write(string.format("totalPtclElc_%d.h5", frameNum), tCurr)
totalPtclIon:write(string.format("totalPtclIon_%d.h5", frameNum), tCurr)
ptclEnergyElc:write(string.format("ptclEnergyElc_%d.h5", frameNum), tCurr)
ptclEnergyIon:write(string.format("ptclEnergyIon_%d.h5", frameNum), tCurr)
end
----------------------------
-- RUNNING THE SIMULATION --
----------------------------
-- -- apply initial conditions for electrons and ion
runUpdater(initDistfElc, 0.0, 0.0, {}, {distfElc})
runUpdater(initDistfIon, 0.0, 0.0, {}, {distfIon})
-- initialize KE parts of Hamiltonian
runUpdater(initHamilKeElc, 0.0, 0.0, {}, {hamilKeElc})
runUpdater(initHamilKeIon, 0.0, 0.0, {}, {hamilKeIon})
-- -- compute initial moments
calcMoments(0.0, 0.0, distfElc, distfIon)
-- -- calculate initial potential and Hamiltonians
applyBc(0.0, 0.0, distfElc, distfIon)
calcPhiFromChargeDensity(0.0, 0.0, distfElc, distfIon, phi1d)
calcHamiltonianElc(0.0, 0.0, phi1d, hamilElc)
calcHamiltonianIon(0.0, 0.0, phi1d, hamilIon)
--compute initial diagnostics
calcDiagnostics(0.0, 0.0)
-- write out initial fields
writeFields(0, 0.0)
-- run the whole thing
initDt = tEnd
runSimulation(tStart, tEnd, nFrames, initDt)
-- print some timing information
Lucee.logInfo(string.format("Total time in poisson solver = %g", phiFromChargeDensityCalc:totalAdvanceTime()) )
Lucee.logInfo(string.format(
"Total time in poisson bracket = %g", vlasovSolverElc:totalAdvanceTime()+vlasovSolverIon:totalAdvanceTime()))
Lucee.logInfo(string.format(
"Total time in number density calc = %g", numDensityCalcElc:totalAdvanceTime()+numDensityCalcIon:totalAdvanceTime()))