class CSolver3D:
def __init__(self, domain, bc, timeStepping, alphaF, mu_ref):
self.done = False
self.Uwall = 0.25
#grid info
self.Nx = domain.Nx
self.x = domain.x
self.Lx = domain.Lx
self.dx = domain.dx
self.Ny = domain.Ny
self.y = domain.y
self.Ly = domain.Ly
self.dy = domain.dy
self.Nz = domain.Nz
self.z = domain.z
self.Lz = domain.Lz
self.dz = domain.dz
self.X = domain.X
self.Y = domain.Y
self.Z = domain.Z
#gas properties
self.idealGas = IdealGas(mu_ref)
#BC info
self.bcXType = bc.bcXType
self.bcX0 = bc.bcX0
self.bcX1 = bc.bcX1
self.bcYType = bc.bcYType
self.bcY0 = bc.bcY0
self.bcY1 = bc.bcY1
self.bcZType = bc.bcZType
self.bcZ0 = bc.bcZ0
self.bcZ1 = bc.bcZ1
#initial conditions
self.U0 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.V0 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.W0 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rho0 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.p0 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
#non-conserved data
self.U = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.V = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.W = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.T = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.p = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.mu = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.k = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.sos = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
#Derivatives of Data
self.Ux = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uxx = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uyy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uzz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uxy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uxz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Uyz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vx = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vxx = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vyy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vzz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vxy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vxz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Vyz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Tx = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Ty = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Tz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Txx = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Tyy = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.Tzz = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.MuX = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.MuY = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.MuZ = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
#conserved data
self.rho1 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoU1 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoV1 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoW1 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoE1 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhok = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoUk = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoVk = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoWk = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoEk = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhok2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoUk2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoVk2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoWk2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoEk2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rho2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoU2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoV2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoW2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
self.rhoE2 = np.zeros((self.Nx, self.Ny, self.Nz),dtype=np.double)
#time data
self.timeStep = 0
self.time = 0.0
self.maxTimeStep = timeStepping.maxTimeStep
self.maxTime = timeStepping.maxTime
self.plotStep = timeStepping.plotStep
self.CFL = timeStepping.CFL
#filter data
self.filterStep = timeStepping.filterStep
self.numberOfFilterStep = 0
self.alphaF = alphaF
if self.bcX0 == "SPONGE" or self.bcX1 == "SPONGE" or self.bcY0 == "SPONGE" or self.bcY1 == "SPONGE" or self.bcZ0 == "SPONGE" or self.bcZ1 == "SPONGE" :
self.spongeFlag = True
self.spongeBC = SpongeBC3D(domain, self.idealGas, bc)
else:
self.spongeFlag = False
#Generate our derivatives and our filters
self.derivX = CollocatedDeriv(self.Nx, self.dx, domain, self.bcXType, "X")
self.derivY = CollocatedDeriv(self.Ny, self.dy, domain, self.bcYType, "Y")
self.derivZ = CollocatedDeriv(self.Nz, self.dz, domain, self.bcZType, "Z")
self.filtX = CompactFilter(self.Nx, self.alphaF, domain, self.bcXType, "X")
self.filtY = CompactFilter(self.Ny, self.alphaF, domain, self.bcYType, "Y")
self.filtZ = CompactFilter(self.Nz, self.alphaF, domain, self.bcZType, "Z")
def setInitialConditions(self, rho0, U0, V0, W0, p0):
self.rho0 = rho0
self.U0 = U0
self.V0 = V0
self.W0 = W0
self.p0 = p0
self.U = U0
self.V = V0
self.W = W0
self.rho1 = rho0
self.p = p0
self.rhoU1 = rho0*U0
self.rhoV1 = rho0*V0
self.rhoW1 = rho0*W0
self.rhoE1 = self.idealGas.solveRhoE(rho0,U0,V0,W0,p0)
self.T = self.idealGas.solveT(rho0, p0)
self.mu = self.idealGas.solveMu(self.T)
self.Amu = self.idealGas.solveAMu(self.T)
self.k = self.idealGas.solveK(self.mu)
self.sos = self.idealGas.solveSOS(self.rho1, self.p)
if self.bcX0 == "ADIABATIC_WALL":
for jp in range(self.Ny):
for kp in range(self.Nz):
self.T[0,jp,kp] = self.derivX.calcNeumann0(self.T[:,jp,kp])
self.U[0,:,:] = 0.0
self.V[0,:,:] = 0.0
self.W[0,:,:] = 0.0
self.rhoU1[0,:,:] = 0.0
self.rhoV1[0,:,:] = 0.0
self.rhoW1[0,:,:] = 0.0
if self.bcX1 == "ADIABATIC_WALL":
for jp in range(self.Ny):
for kp in range(self.Nz):
self.T[-1,jp,kp] = self.derivX.calcNeumannEnd(self.T[:,jp,kp])
self.U[-1,:,:] = 0.0
self.V[-1,:,:] = 0.0
self.W[-1,:,:] = 0.0
self.rhoU1[-1,:,:] = 0.0
self.rhoV1[-1,:,:] = 0.0
self.rhoW1[-1,:,:] = 0.0
if self.bcY0 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for kp in range(self.Nz):
self.T[ip,0,kp] = self.derivY.calcNeumann0(self.T[ip,:,kp])
self.U[:,0,:] = 0.0
self.V[:,0,:] = 0.0
self.W[:,0,:] = 0.0
self.rhoU1[:,0,:] = 0.0
self.rhoV1[:,0,:] = 0.0
self.rhoW1[:,0,:] = 0.0
if self.bcY1 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for kp in range(self.Nz):
self.T[ip,-1,kp] = self.derivY.calcNeumannEnd(self.T[ip,:,kp])
self.U[:,-1,:] = 0.0
self.V[:,-1,:] = 0.0
self.W[:,-1,:] = 0.0
self.rhoU1[:,-1,:] = 0.0
self.rhoV1[:,-1,:] = 0.0
self.rhoW1[:,-1,:] = 0.0
if self.bcZ0 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for jp in range(self.Ny):
self.T[ip,jp,0] = self.derivZ.calcNeumann0(self.T[ip,jp,:])
self.U[:,:,0] = 0.0
self.V[:,:,0] = 0.0
self.W[:,:,0] = 0.0
self.rhoU1[:,:,0] = 0.0
self.rhoV1[:,:,0] = 0.0
self.rhoW1[:,:,0] = 0.0
if self.bcZ1 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for jp in range(self.Ny):
self.T[ip,jp,-1] = self.derivZ.calcNeumannEnd(self.T[ip,jp,:])
self.U[:,:,-1] = 0.0
self.V[:,:,-1] = 0.0
self.W[:,:,-1] = 0.0
self.rhoU1[:,:,-1] = 0.0
self.rhoV1[:,:,-1] = 0.0
self.rhoW1[:,:,-1] = 0.0
if self.bcY1 == "ADIABATIC_MOVINGWALL":
for ip in range(self.Nx):
for kp in range(self.Nz):
self.T[ip,-1,kp] = self.derivY.calcNeumannEnd(self.T[ip,:,kp])
self.U[:,-1,:] = self.Uwall
self.V[:,-1,:] = 0.0
self.W[:,-1,:] = 0.0
self.rhoU1[:,-1,:] = self.rho1[:,-1,:]*self.Uwall
self.rhoV1[:,-1,:] = 0.0
self.rhoW1[:,-1,:] = 0.0
if ( self.bcX0 == "ADIABATIC_WALL"
or self.bcX1 == "ADIABATIC_WALL"
or self.bcY0 == "ADIABATIC_WALL"
or self.bcY1 == "ADIABATIC_WALL"
or self.bcZ0 == "ADIABATIC_WALL"
or self.bcZ1 == "ADIABATIC_WALL"
or self.bcY1 == "ADIABATIC_MOVINGWALL"):
self.p = self.idealGas.solvePIdealGas(self.rho1, self.T)
self.sos = self.idealGas.solveSOS(self.rho1, self.p)
self.rhoE1 = self.idealGas.solveRhoE(self.rho1, self.U, self.V, self.W, self.p)
if self.spongeFlag == True:
self.spongeBC.spongeRhoAvg = self.rho1
self.spongeBC.spongeRhoUAvg = self.rhoU1
self.spongeBC.spongeRhoVAvg = self.rhoV1
self.spongeBC.spongeRhoWAvg = self.rhoW1
self.spongeBC.spongeRhoEAvg = self.rhoE1
def calcDtFromCFL(self):
UChar_dx = ((np.fabs(self.U) + self.sos)/self.dx +
(np.fabs(self.V) + self.sos)/self.dy +
(np.fabs(self.W) + self.sos)/self.dz)
self.dt = np.min(self.CFL/UChar_dx)
#Increment timestep
self.timeStep += 1
self.time += self.dt
def calcSpongeSource(self,f,eqn):
if self.spongeFlag == True:
if eqn == "CONT":
source = self.spongeBC.spongeSigma*(self.spongeBC.spongeRhoAvg-f)
elif eqn == "XMOM":
source = self.spongeBC.spongeSigma*(self.spongeBC.spongeRhoUAvg-f)
elif eqn == "YMOM":
source = self.spongeBC.spongeSigma*(self.spongeBC.spongeRhoVAvg-f)
elif eqn == "ZMOM":
source = self.spongeBC.spongeSigma*(self.spongeBC.spongeRhoWAvg-f)
elif eqn == "ENGY":
source = self.spongeBC.spongeSigma*(self.spongeBC.spongeRhoEAvg-f)
else:
source = 0
else:
source = 0
return source
def preStepBCHandling(self, rho, rhoU, rhoV, rhoW, rhoE):
if self.bcX0 == "ADIABATIC_WALL":
self.U[0,:,:] = 0.0
self.V[0,:,:] = 0.0
self.W[0,:,:] = 0.0
rhoU[0,:,:] = 0.0
rhoV[0,:,:] = 0.0
rhoW[0,:,:] = 0.0
for jp in range(self.Ny):
for kp in range(self.Nz):
self.T[0,jp,kp] = self.derivX.calcNeumann0(self.T[:,jp,kp])
self.p[0,:,:] = self.idealGas.solvePIdealGas(rho[0,:,:],self.T[0,:,:])
if self.bcX1 == "ADIABATIC_WALL":
self.U[-1,:,:] = 0.0
self.V[-1,:,:] = 0.0
self.W[-1,:,:] = 0.0
rhoU[-1,:,:] = 0.0
rhoV[-1,:,:] = 0.0
rhoW[-1,:,:] = 0.0
for jp in range(self.Ny):
for kp in range(self.Nz):
self.T[-1,jp,kp] = self.derivX.calcNeumannEnd(self.T[:,jp,kp])
self.p[-1,:,:] = self.idealGas.solvePIdealGas(rho[-1,:,:],self.T[-1,:,:])
if self.bcY0 == "ADIABATIC_WALL":
self.U[:,0,:] = 0.0
self.V[:,0,:] = 0.0
self.W[:,0,:] = 0.0
rhoU[:,0,:] = 0.0
rhoV[:,0,:] = 0.0
rhoW[:,0,:] = 0.0
for ip in range(self.Nx):
for kp in range(self.Nz):
self.T[ip,0,kp] = self.derivY.calcNeumann0(self.T[ip,:,kp])
self.p[:,0,:] = self.idealGas.solvePIdealGas(rho[:,0,:],self.T[:,0,:])
if self.bcY1 == "ADIABATIC_WALL":
self.U[:,-1,:] = 0.0
self.V[:,-1,:] = 0.0
self.W[:,-1,:] = 0.0
rhoU[:,-1,:] = 0.0
rhoV[:,-1,:] = 0.0
rhoW[:,-1,:] = 0.0
for ip in range(self.Nx):
for kp in range(self.Nz):
self.T[ip,-1,kp] = self.derivY.calcNeumannEnd(self.T[ip,:,kp])
self.p[:,-1,:] = self.idealGas.solvePIdealGas(rho[:,-1,:],self.T[:,-1,:])
if self.bcZ0 == "ADIABATIC_WALL":
self.U[:,:,0] = 0.0
self.V[:,:,0] = 0.0
self.W[:,:,0] = 0.0
rhoU[:,:,0] = 0.0
rhoV[:,:,0] = 0.0
rhoW[:,:,0] = 0.0
for ip in range(self.Nx):
for jp in range(self.Ny):
self.T[ip,jp,0] = self.derivZ.calcNeumann0(self.T[ip,jp,:])
self.p[:,:,0] = self.idealGas.solvePIdealGas(rho[:,:,0],self.T[:,:,0])
if self.bcZ1 == "ADIABATIC_WALL":
self.U[:,:,-1] = 0.0
self.V[:,:,-1] = 0.0
self.W[:,:,-1] = 0.0
rhoU[:,:,-1] = 0.0
rhoV[:,:,-1] = 0.0
rhoW[:,:,-1] = 0.0
for ip in range(self.Nx):
for jp in range(self.Ny):
self.T[ip,jp,-1] = self.derivZ.calcNeumannEnd(self.T[ip,jp,:])
self.p[:,:,-1] = self.idealGas.solvePIdealGas(rho[:,:,-1],self.T[:,:,-1])
if self.bcY1 == "ADIABATIC_MOVINGWALL":
for ip in range(self.Nx):
for kp in range(self.Nz):
self.T[ip,-1,kp] = self.derivY.calcNeumannEnd(self.T[ip,:,kp])
self.U[:,-1,:] = self.Uwall
self.V[:,-1,:] = 0.0
self.W[:,-1,:] = 0.0
self.rhoU1[:,-1,:] = self.rho1[:,-1,:]*self.Uwall
self.rhoV1[:,-1,:] = 0.0
self.rhoW1[:,-1,:] = 0.0
self.p[:,-1,:] = self.idealGas.solvePIdealGas(rho[:,-1,:],self.T[:,-1,:])
def preStepDerivatives(self):
#First Derivatives
self.Ux = self.derivX.df_3D(self.U)
self.Vx = self.derivX.df_3D(self.V)
self.Wx = self.derivX.df_3D(self.W)
self.Uy = self.derivY.df_3D(self.U)
self.Vy = self.derivY.df_3D(self.V)
self.Wy = self.derivY.df_3D(self.W)
self.Uz = self.derivZ.df_3D(self.U)
self.Vz = self.derivZ.df_3D(self.V)
self.Wz = self.derivZ.df_3D(self.W)
self.Tx = self.derivX.df_3D(self.T)
self.Ty = self.derivY.df_3D(self.T)
self.Tz = self.derivZ.df_3D(self.T)
#Second Derivatives
self.Uxx = self.derivX.d2f_3D(self.U)
self.Vxx = self.derivX.d2f_3D(self.V)
self.Wxx = self.derivX.d2f_3D(self.W)
self.Uyy = self.derivY.d2f_3D(self.U)
self.Vyy = self.derivY.d2f_3D(self.V)
self.Wyy = self.derivY.d2f_3D(self.W)
self.Uzz = self.derivZ.d2f_3D(self.U)
self.Vzz = self.derivZ.d2f_3D(self.V)
self.Wzz = self.derivZ.d2f_3D(self.W)
self.Txx = self.derivX.d2f_3D(self.T)
self.Tyy = self.derivY.d2f_3D(self.T)
self.Tzz = self.derivZ.d2f_3D(self.T)
self.MuX = self.Amu*self.Tx
self.MuY = self.Amu*self.Ty
self.MuZ = self.Amu*self.Tz
#Cross Derivatives
if self.timeStep%2 == 0:
self.Uxy = self.derivX.df_3D(self.Uy)
self.Vxy = self.derivX.df_3D(self.Vy)
self.Wxy = self.derivX.df_3D(self.Wy)
else:
self.Uxy = self.derivY.df_3D(self.Ux)
self.Vxy = self.derivY.df_3D(self.Vx)
self.Wxy = self.derivY.df_3D(self.Wx)
if self.timeStep%2 == 0:
self.Uyz = self.derivY.df_3D(self.Uz)
self.Vyz = self.derivY.df_3D(self.Vz)
self.Wyz = self.derivY.df_3D(self.Wz)
else:
self.Uyz = self.derivZ.df_3D(self.Uy)
self.Vyz = self.derivZ.df_3D(self.Vy)
self.Wyz = self.derivZ.df_3D(self.Wy)
if self.timeStep%2 == 0:
self.Uxz = self.derivX.df_3D(self.Uz)
self.Vxz = self.derivX.df_3D(self.Vz)
self.Wxz = self.derivX.df_3D(self.Wz)
else:
self.Uxz = self.derivZ.df_3D(self.Ux)
self.Vxz = self.derivZ.df_3D(self.Vx)
self.Wxz = self.derivZ.df_3D(self.Wx)
#Actually solving the equations...
def solveXMomentum_Euler(self, rhoU):
return (-self.derivX.df_3D(rhoU*self.U + self.p) - self.derivY.df_3D(rhoU*self.V)
-self.derivZ.df_3D(rhoU*self.W))
def solveYMomentum_Euler(self, rhoV):
return (-self.derivX.df_3D(rhoV*self.U) -self.derivY.df_3D(rhoV*self.V + self.p)
-self.derivZ.df_3D(rhoV*self.W))
def solveZMomentum_Euler(self, rhoW):
return (-self.derivX.df_3D(rhoW*self.U) -self.derivY.df_3D(rhoW*self.V)
-self.derivZ.df_3D(rhoW*self.W + self.p))
def solveEnergy_Euler(self, rhoE):
return (-self.derivX.df_3D(rhoE*self.U + self.U*self.p)
- self.derivY.df_3D(rhoE*self.V + self.V*self.p)
- self.derivZ.df_3D(rhoE*self.W + self.W*self.p))
##Need to write these out!
def solveXMomentum_Viscous(self):
temp = (4/3)*self.Uxx + self.Uyy + self.Uzz
temp += (1/3)*self.Vxy + (1/3)*self.Wxz
temp *= self.mu
temp += (4/3)*self.MuX*(self.Ux - (1/2)*self.Vy - (1/2)*self.Wz)
temp += self.MuY*(self.Uy + self.Vx)
temp += self.MuZ*(self.Wx + self.Uz)
return temp
def solveYMomentum_Viscous(self):
temp = self.Vxx + (4/3)*self.Vyy + self.Vzz
temp += (1/3)*self.Uxy + (1/3)*self.Wyz
temp *= self.mu
temp += (4/3)*self.MuY*(self.Vy - (1/2)*self.Ux - (1/2)*self.Wz)
temp += self.MuX*(self.Uy + self.Vx)
temp += self.MuZ*(self.Wy + self.Vz)
return temp
def solveZMomentum_Viscous(self):
temp = self.Wxx + self.Wyy + (4/3)*self.Wzz
temp += (1/3)*self.Uxz + (1/3)*self.Vyz
temp *= self.mu
temp += (4/3)*self.MuZ*(self.Wz - (1/2)*self.Ux - (1/2)*self.Vy)
temp += self.MuX*(self.Wx + self.Uz)
temp += self.MuY*(self.Wy + self.Vz)
return temp
def solveEnergy_Viscous(self):
#heat transfer terms
qtemp = self.MuX*self.Tx
qtemp += self.MuY*self.Ty
qtemp += self.MuZ*self.Tz
qtemp += self.mu*self.Txx
qtemp += self.mu*self.Tyy
qtemp += self.mu*self.Tzz
qtemp *= (self.idealGas.cp/self.idealGas.Pr)
#terms w/o viscosity derivatives
temp1 = self.U*((4/3)*self.Uxx + self.Uyy + self.Uzz)
temp1 += self.V*( self.Vxx +(4/3)*self.Vyy + self.Vzz)
temp1 += self.W*( self.Wxx + self.Wyy +(4/3)*self.Wzz)
temp1 += (4/3)*(self.Ux**2 + self.Vy**2 + self.Wz**2)
temp1 += (self.Uy**2 + self.Uz**2)
temp1 += (self.Vx**2 + self.Vz**2)
temp1 += (self.Wx**2 + self.Wy**2)
temp1 += -(4/3)*(self.Ux*self.Vy + self.Ux*self.Wz + self.Vy*self.Wz)
temp1 += 2*(self.Uy*self.Vx + self.Uz*self.Wx + self.Vz*self.Wy)
temp1 += (1/3)*(self.U*self.Vxy + self.U*self.Wxz + self.V*self.Uxy)
temp1 += (1/3)*(self.V*self.Wyz + self.W*self.Uxz + self.W*self.Vyz)
temp1 *= self.mu
#terms w/ viscosity derivatives
temp2 = (4/3)*(self.U*self.MuX*self.Ux + self.V*self.MuY*self.Vy + self.W*self.MuZ*self.Wz)
temp2 += -(2/3)*self.U*self.MuX*(self.Vy + self.Wz)
temp2 += -(2/3)*self.V*self.MuY*(self.Ux + self.Wz)
temp2 += -(2/3)*self.W*self.MuZ*(self.Ux + self.Vy)
temp2 += self.U*self.MuY*(self.Uy + self.Vx)
temp2 += self.U*self.MuZ*(self.Uz + self.Wx)
temp2 += self.V*self.MuX*(self.Uy + self.Vx)
temp2 += self.V*self.MuZ*(self.Vz + self.Wy)
temp2 += self.W*self.MuX*(self.Uz + self.Wx)
temp2 += self.W*self.MuY*(self.Vz + self.Wy)
return qtemp + temp1 + temp2
#Using methods that don't maximize the resolution capabilities of the compact differences
def solveContinuity(self, rho, rhoU, rhoV, rhoW, rhoE):
drho = (-self.derivX.df_3D(rhoU) - self.derivY.df_3D(rhoV) - self.derivZ.df_3D(rhoW))
self.rhok2 = self.dt*(drho + self.calcSpongeSource(rho,"CONT"))
# def solveXMomentum(self, rho, rhoU, rhoV, rhoE):
# drhoU = (-self.derivX.df_2D(rhoU*self.U + self.p +
# -2*self.mu*self.Ux + (2/3)*self.mu*(self.Ux + self.Vy)) +
# -self.derivY.df_2D(rhoU*self.V -
# self.mu*(self.Vx + self.Uy)))
#
# self.rhoUk2 = self.dt*(drhoU + self.calcSpongeSource(rhoU,"XMOM"))
#
# def solveYMomentum(self, rho, rhoU, rhoV, rhoE):
#
# drhoV = (-self.derivY.df_2D(rhoV*self.V + self.p +
# -2*self.mu*self.Vy + (2/3)*self.mu*(self.Ux + self.Vy))
# -self.derivX.df_2D(rhoV*self.U -
# self.mu*(self.Vx + self.Uy)) )
#
# self.rhoVk2 = self.dt*(drhoV + self.calcSpongeSource(rhoV,"YMOM"))
#
# def solveEnergy(self, rho, rhoU, rhoV, rhoE):
# drhoE = (-self.derivX.df_2D(rhoE*self.U + self.U*self.p
# - (self.mu/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivX.df_2D(self.T) +
# - self.U*(2*self.mu*self.Ux - (2/3)*self.mu*(self.Ux + self.Vy))
# - self.V*(self.mu*(self.Vx + self.Uy)))
# - self.derivY.df_2D(rhoE*self.V + self.V*self.p
# - (self.mu/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivY.df_2D(self.T) +
# - self.V*(2*self.mu*self.Vy - (2/3)*self.mu*(self.Ux + self.Vy))
# - self.U*(self.mu*(self.Vx + self.Uy))));
#
#
# self.rhoEk2 = self.dt*(drhoE + self.calcSpongeSource(rhoE,"ENGY"))
#Using methods that do take advantage of the the spectral benefits of the compact diff's
def solveXMomentum_PV(self, rho, rhoU, rhoV, rhoW, rhoE):
self.rhoUk2 = self.dt*(self.solveXMomentum_Euler(rhoU) +
self.solveXMomentum_Viscous() +
self.calcSpongeSource(rhoU,"XMOM"))
def solveYMomentum_PV(self, rho, rhoU, rhoV, rhoW, rhoE):
self.rhoVk2 = self.dt*(self.solveYMomentum_Euler(rhoV) +
self.solveYMomentum_Viscous() +
self.calcSpongeSource(rhoV,"YMOM"))
def solveZMomentum_PV(self, rho, rhoU, rhoV, rhoW, rhoE):
self.rhoWk2 = self.dt*(self.solveZMomentum_Euler(rhoW) +
self.solveZMomentum_Viscous() +
self.calcSpongeSource(rhoW,"ZMOM"))
def solveEnergy_PV(self, rho, rhoU, rhoV, rhoW, rhoE):
self.rhoEk2 = self.dt*(self.solveEnergy_Euler(rhoE) +
self.solveEnergy_Viscous() +
self.calcSpongeSource(rhoE,"ENGY"))
#Left off here
def postStepBCHandling(self, rho, rhoU, rhoV, rhoW, rhoE):
if self.bcXType == "DIRICHLET":
if self.bcX0 == "ADIABATIC_WALL":
for jp in range(self.Ny):
for kp in range(self.Nz):
self.rhok2[0,jp,kp] = -self.dt*self.derivX.compact1stDeriv_Fast(rhoU[:,jp,kp])[0]
self.rhoUk2[0,jp,kp] = 0
self.rhoVk2[0,jp,kp] = 0
self.rhoWk2[0,jp,kp] = 0
self.rhoEk2[0,jp,kp] = (-self.dt*(self.derivX.compact1stDeriv_Fast(rhoE[:,jp,kp]*self.U[:,jp,kp] + self.U[:,jp,kp]*self.p[:,jp,kp]) -
(self.mu[:,jp,kp]/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivX.compact2ndDeriv_Fast(self.T[:,jp,kp]) +
(4/3)*self.mu[:,jp,kp]*self.U[:,jp,kp]*self.derivX.compact2ndDeriv_Fast(self.U[:,jp,kp])))[0]
else:
self.rhok2[0,:,:] = 0
self.rhoUk2[0,:,:] = 0
self.rhoVk2[0,:,:] = 0
self.rhoWk2[0,:,:] = 0
self.rhoEk2[0,:,:] = 0
if self.bcX1 == "ADIABATIC_WALL":
for jp in range(self.Ny):
for kp in range(self.Nz):
self.rhok2[-1,jp,kp] = -self.dt*self.derivX.compact1stDeriv_Fast(rhoU[:,jp,kp])[-1]
self.rhoUk2[-1,jp,kp] = 0
self.rhoVk2[-1,jp,kp] = 0
self.rhoWk2[-1,jp,kp] = 0
self.rhoEk2[-1,jp,kp] = (-self.dt*(self.derivX.compact1stDeriv_Fast(rhoE[:,jp,kp]*self.U[:,jp,kp] + self.U[:,jp,kp]*self.p[:,jp,kp]) -
(self.mu[:,jp,kp]/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivX.compact2ndDeriv_Fast(self.T[:,jp,kp]) +
(4/3)*self.mu[:,jp,kp]*self.U[:,jp,kp]*self.derivX.compact2ndDeriv_Fast(self.U[:,jp,kp])))[-1]
else:
self.rhok2[-1,:,:] = 0
self.rhoUk2[-1,:,:] = 0
self.rhoVk2[-1,:,:] = 0
self.rhoWk2[-1,:,:] = 0
self.rhoEk2[-1,:,:] = 0
if self.bcYType == "DIRICHLET":
if self.bcY0 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for kp in range(self.Nz):
self.rhok2[ip,0,kp] = -self.dt*self.derivY.compact1stDeriv_Fast(rhoV[ip,:,kp])[0]
self.rhoUk2[ip,0,kp] = 0
self.rhoVk2[ip,0,kp] = 0
self.rhoWk2[ip,0,kp] = 0
self.rhoEk2[ip,0,kp] = (-self.dt*(self.derivY.compact1stDeriv_Fast(rhoE[ip,:,kp]*self.V[ip,:,kp] + self.V[ip,:,kp]*self.p[ip,:,kp]) -
(self.mu[ip,:,kp]/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivY.compact2ndDeriv_Fast(self.T[ip,:,kp]) +
(4/3)*self.mu[ip,:,kp]*self.V[ip,:,kp]*self.derivY.compact2ndDeriv_Fast(self.V[ip,:,kp])))[0]
else:
self.rhok2[:,0,:] = 0
self.rhoUk2[:,0,:] = 0
self.rhoVk2[:,0,:] = 0
self.rhoWk2[:,0,:] = 0
self.rhoEk2[:,0,:] = 0
if self.bcY1 == "ADIABATIC_WALL" or self.bcY1 == "ADIABATIC_MOVINGWALL":
for ip in range(self.Nx):
for kp in range(self.Nz):
self.rhok2[ip,-1,kp] = -self.dt*self.derivY.compact1stDeriv_Fast(rhoV[ip,:,kp])[-1]
self.rhoUk2[ip,-1,kp] = 0
self.rhoVk2[ip,-1,kp] = 0
self.rhoWk2[ip,-1,kp] = 0
self.rhoEk2[ip,-1,kp] = (-self.dt*(self.derivY.compact1stDeriv_Fast(rhoE[ip,:,kp]*self.V[ip,:,kp] + self.V[ip,:,kp]*self.p[ip,:,kp]) -
(self.mu[ip,:,kp]/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivY.compact2ndDeriv_Fast(self.T[ip,:,kp]) +
(4/3)*self.mu[ip,:,kp]*self.V[ip,:,kp]*self.derivY.compact2ndDeriv_Fast(self.V[ip,:,kp])))[-1]
else:
self.rhok2[:,-1,:] = 0
self.rhoUk2[:,-1,:] = 0
self.rhoVk2[:,-1,:] = 0
self.rhoWk2[:,-1,:] = 0
self.rhoEk2[:,-1,:] = 0
if self.bcZType == "DIRICHLET":
if self.bcZ0 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for jp in range(self.Ny):
self.rhok2[ip,jp,0] = -self.dt*self.derivZ.compact1stDeriv_Fast(rhoW[ip,jp,:])[0]
self.rhoUk2[ip,jp,0] = 0
self.rhoVk2[ip,jp,0] = 0
self.rhoWk2[ip,jp,0] = 0
self.rhoEk2[ip,jp,0] = (-self.dt*(self.derivZ.compact1stDeriv_Fast(rhoE[ip,jp,:]*self.W[ip,jp,:] + self.W[ip,jp,:]*self.p[ip,jp,:]) -
(self.mu[ip,jp,:]/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivZ.compact2ndDeriv_Fast(self.T[ip,jp,:]) +
(4/3)*self.mu[ip,jp,:]*self.W[ip,jp,:]*self.derivZ.compact2ndDeriv_Fast(self.W[ip,jp,:])))[0]
else:
self.rhok2[:,:,0] = 0
self.rhoUk2[:,:,0] = 0
self.rhoVk2[:,:,0] = 0
self.rhoWk2[:,:,0] = 0
self.rhoEk2[:,:,0] = 0
if self.bcZ1 == "ADIABATIC_WALL":
for ip in range(self.Nx):
for jp in range(self.Ny):
self.rhok2[ip,jp,-1] = -self.dt*self.derivZ.compact1stDeriv_Fast(rhoW[ip,jp,:])[-1]
self.rhoUk2[ip,jp,-1] = 0
self.rhoVk2[ip,jp,-1] = 0
self.rhoWk2[ip,jp,-1] = 0
self.rhoEk2[ip,jp,-1] = (-self.dt*(self.derivZ.compact1stDeriv_Fast(rhoE[ip,jp,:]*self.W[ip,jp,:] + self.W[ip,jp,:]*self.p[ip,jp,:]) -
(self.mu[ip,jp,:]/self.idealGas.Pr/(self.idealGas.gamma-1))*self.derivZ.compact2ndDeriv_Fast(self.T[ip,jp,:]) +
(4/3)*self.mu[ip,jp,:]*self.W[ip,jp,:]*self.derivZ.compact2ndDeriv_Fast(self.W[ip,jp,:])))[-1]
else:
self.rhok2[:,:,-1] = 0
self.rhoUk2[:,:,-1] = 0
self.rhoVk2[:,:,-1] = 0
self.rhoWk2[:,:,-1] = 0
self.rhoEk2[:,:,-1] = 0
def updateConservedData(self,rkStep):
if rkStep == 1:
self.rho2 = self.rho1 + self.rhok2/6
self.rhoU2 = self.rhoU1 + self.rhoUk2/6
self.rhoV2 = self.rhoV1 + self.rhoVk2/6
self.rhoW2 = self.rhoW1 + self.rhoWk2/6
self.rhoE2 = self.rhoE1 + self.rhoEk2/6
elif rkStep == 2:
self.rho2 += self.rhok2/3
self.rhoU2 += self.rhoUk2/3
self.rhoV2 += self.rhoVk2/3
self.rhoW2 += self.rhoWk2/3
self.rhoE2 += self.rhoEk2/3
elif rkStep == 3:
self.rho2 += self.rhok2/3
self.rhoU2 += self.rhoUk2/3
self.rhoV2 += self.rhoVk2/3
self.rhoW2 += self.rhoWk2/3
self.rhoE2 += self.rhoEk2/3
elif rkStep == 4:
self.rho2 += self.rhok2/6
self.rhoU2 += self.rhoUk2/6
self.rhoV2 += self.rhoVk2/6
self.rhoW2 += self.rhoWk2/6
self.rhoE2 += self.rhoEk2/6
if rkStep == 1:
self.rhok = self.rho1 + self.rhok2/2
self.rhoUk = self.rhoU1 + self.rhoUk2/2
self.rhoVk = self.rhoV1 + self.rhoVk2/2
self.rhoWk = self.rhoW1 + self.rhoWk2/2
self.rhoEk = self.rhoE1 + self.rhoEk2/2
elif rkStep == 2:
self.rhok = self.rho1 + self.rhok2/2
self.rhoUk = self.rhoU1 + self.rhoUk2/2
self.rhoVk = self.rhoV1 + self.rhoVk2/2
self.rhoWk = self.rhoW1 + self.rhoWk2/2
self.rhoEk = self.rhoE1 + self.rhoEk2/2
elif rkStep == 3:
self.rhok = self.rho1 + self.rhok2
self.rhoUk = self.rhoU1 + self.rhoUk2
self.rhoVk = self.rhoV1 + self.rhoVk2
self.rhoWk = self.rhoW1 + self.rhoWk2
self.rhoEk = self.rhoE1 + self.rhoEk2
def updateNonConservedData(self,rkStep):
if rkStep == 1 or rkStep == 2 or rkStep == 3:
self.U = self.rhoUk/self.rhok
self.V = self.rhoVk/self.rhok
self.W = self.rhoWk/self.rhok
self.p = (self.idealGas.gamma-1)*(self.rhoEk -
0.5*(self.rhoUk*self.rhoUk + self.rhoVk*self.rhoVk + self.rhoWk*self.rhoWk)/self.rhok)
self.T = (self.p/(self.rhok*self.idealGas.R_gas))
self.mu = self.idealGas.mu_ref*(self.T/self.idealGas.T_ref)**0.76
self.k = self.idealGas.cp*self.mu/self.idealGas.Pr
self.sos = np.sqrt(self.idealGas.gamma*self.p/self.rhok)
self.Amu = self.idealGas.solveAMu(self.T)
elif rkStep == 4:
self.U = self.rhoU1/self.rho1
self.V = self.rhoV1/self.rho1
self.W = self.rhoW1/self.rho1
self.p = (self.idealGas.gamma-1)*(self.rhoE1 -
0.5*(self.rhoU1*self.rhoU1 + self.rhoV1*self.rhoV1 + self.rhoW1*self.rhoW1)/self.rho1)
self.T = (self.p/(self.rho1*self.idealGas.R_gas))
self.mu = self.idealGas.mu_ref*(self.T/self.idealGas.T_ref)**0.76
self.k = self.idealGas.cp*self.mu/self.idealGas.Pr
self.sos = np.sqrt(self.idealGas.gamma*self.p/self.rho1)
self.Amu = self.idealGas.solveAMu(self.T)
def filterConservedValues(self):
if(self.timeStep%self.filterStep == 0):
self.numberOfFilterStep += 1
#Need to flip the order of the filtering every other time
if self.numberOfFilterStep%3 == 1:
self.rho1 = self.filtX.filt_3D(self.rho2)
self.rhoU1 = self.filtX.filt_3D(self.rhoU2)
self.rhoV1 = self.filtX.filt_3D(self.rhoV2)
self.rhoW1 = self.filtX.filt_3D(self.rhoW2)
self.rhoE1 = self.filtX.filt_3D(self.rhoE2)
self.rho1 = self.filtY.filt_3D(self.rho1)
self.rhoU1 = self.filtY.filt_3D(self.rhoU1)
self.rhoV1 = self.filtY.filt_3D(self.rhoV1)
self.rhoW1 = self.filtY.filt_3D(self.rhoW1)
self.rhoE1 = self.filtY.filt_3D(self.rhoE1)
self.rho1 = self.filtZ.filt_3D(self.rho1)
self.rhoU1 = self.filtZ.filt_3D(self.rhoU1)
self.rhoV1 = self.filtZ.filt_3D(self.rhoV1)
self.rhoW1 = self.filtZ.filt_3D(self.rhoW1)
self.rhoE1 = self.filtZ.filt_3D(self.rhoE1)
elif self.numberOfFilterStep%3 == 2:
self.rho1 = self.filtY.filt_3D(self.rho2)
self.rhoU1 = self.filtY.filt_3D(self.rhoU2)
self.rhoV1 = self.filtY.filt_3D(self.rhoV2)
self.rhoW1 = self.filtY.filt_3D(self.rhoW2)
self.rhoE1 = self.filtY.filt_3D(self.rhoE2)
self.rho1 = self.filtZ.filt_3D(self.rho1)
self.rhoU1 = self.filtZ.filt_3D(self.rhoU1)
self.rhoV1 = self.filtZ.filt_3D(self.rhoV1)
self.rhoW1 = self.filtZ.filt_3D(self.rhoW1)
self.rhoE1 = self.filtZ.filt_3D(self.rhoE1)
self.rho1 = self.filtX.filt_3D(self.rho1)
self.rhoU1 = self.filtX.filt_3D(self.rhoU1)
self.rhoV1 = self.filtX.filt_3D(self.rhoV1)
self.rhoW1 = self.filtX.filt_3D(self.rhoW1)
self.rhoE1 = self.filtX.filt_3D(self.rhoE1)
else:
self.rho1 = self.filtZ.filt_3D(self.rho2)
self.rhoU1 = self.filtZ.filt_3D(self.rhoU2)
self.rhoV1 = self.filtZ.filt_3D(self.rhoV2)
self.rhoW1 = self.filtZ.filt_3D(self.rhoW2)
self.rhoE1 = self.filtZ.filt_3D(self.rhoE2)
self.rho1 = self.filtX.filt_3D(self.rho1)
self.rhoU1 = self.filtX.filt_3D(self.rhoU1)
self.rhoV1 = self.filtX.filt_3D(self.rhoV1)
self.rhoW1 = self.filtX.filt_3D(self.rhoW1)
self.rhoE1 = self.filtX.filt_3D(self.rhoE1)
self.rho1 = self.filtY.filt_3D(self.rho1)
self.rhoU1 = self.filtY.filt_3D(self.rhoU1)
self.rhoV1 = self.filtY.filt_3D(self.rhoV1)
self.rhoW1 = self.filtY.filt_3D(self.rhoW1)
self.rhoE1 = self.filtY.filt_3D(self.rhoE1)
print("Filtering...")
#Is there something here that needs to be done about corners for
#DIRICHLET/DIRICHLET, PERIODIC/DIRICHLET?
if self.bcXType == "DIRICHLET":
self.rho1[0,:,:] = self.rho2[0,:,:]
self.rho1[-1,:,:] = self.rho2[-1,:,:]
self.rhoU1[0,:,:] = self.rhoU2[0,:,:]
self.rhoU1[-1,:,:] = self.rhoU2[-1,:,:]
self.rhoV1[0,:,:] = self.rhoV2[0,:,:]
self.rhoV1[-1,:,:] = self.rhoV2[-1,:,:]
self.rhoW1[0,:,:] = self.rhoW2[0,:,:]
self.rhoW1[-1,:,:] = self.rhoW2[-1,:,:]
self.rhoE1[0,:,:] = self.rhoE2[0,:,:]
self.rhoE1[-1,:,:] = self.rhoE2[-1,:,:]
if self.bcYType == "DIRICHLET":
self.rho1[:,0,:] = self.rho2[:,0,:]
self.rho1[:,-1,:] = self.rho2[:,-1,:]
self.rhoU1[:,0,:] = self.rhoU2[:,0,:]
self.rhoU1[:,-1,:] = self.rhoU2[:,-1,:]
self.rhoV1[:,0,:] = self.rhoV2[:,0,:]
self.rhoV1[:,-1,:] = self.rhoV2[:,-1,:]
self.rhoW1[:,0,:] = self.rhoW2[:,0,:]
self.rhoW1[:,-1,:] = self.rhoW2[:,-1,:]
self.rhoE1[:,0,:] = self.rhoE2[:,0,:]
self.rhoE1[:,-1,:] = self.rhoE2[:,-1,:]
if self.bcZType == "DIRICHLET":
self.rho1[:,:,0] = self.rho2[:,:,0]
self.rho1[:,:,-1] = self.rho2[:,:,-1]
self.rhoU1[:,:,0] = self.rhoU2[:,:,0]
self.rhoU1[:,:,-1] = self.rhoU2[:,:,-1]
self.rhoV1[:,:,0] = self.rhoV2[:,:,0]
self.rhoV1[:,:,-1] = self.rhoV2[:,:,-1]
self.rhoW1[:,:,0] = self.rhoW2[:,:,0]
self.rhoW1[:,:,-1] = self.rhoW2[:,:,-1]
self.rhoE1[:,:,0] = self.rhoE2[:,:,0]
self.rhoE1[:,:,-1] = self.rhoE2[:,:,-1]
else:
self.rho1 = self.rho2
self.rhoU1 = self.rhoU2
self.rhoV1 = self.rhoV2
self.rhoW1 = self.rhoW2
self.rhoE1 = self.rhoE2
def updateSponge(self):
if self.spongeFlag == True:
eps = 1.0/(self.spongeBC.spongeAvgT/self.dt+1.0)
self.spongeBC.spongeRhoAvg += eps*(self.rho1 - self.spongeBC.spongeRhoAvg)
self.spongeBC.spongeRhoUAvg += eps*(self.rhoU1 - self.spongeBC.spongeRhoUAvg)
self.spongeBC.spongeRhoVAvg += eps*(self.rhoV1 - self.spongeBC.spongeRhoVAvg)
self.spongeBC.spongeRhoWAvg += eps*(self.rhoW1 - self.spongeBC.spongeRhoWAvg)
self.spongeBC.spongeRhoEAvg += eps*(self.rhoE1 - self.spongeBC.spongeRhoEAvg)
self.spongeBC.spongeRhoEAvg = (self.spongeBC.spongeEpsP*self.spongeBC.spongeRhoEAvg +
(1.0 - self.spongeBC.spongeEpsP)*(self.spongeBC.spongeP/(self.idealGas.gamma-1) +
0.5*(self.spongeBC.spongeRhoUAvg**2 + self.spongeBC.spongeRhoVAvg**2 + self.spongeBC.spongeRhoWAvg**2)/self.spongeBC.spongeRhoAvg))
if self.bcX0 == "SPONGE":
self.rho1[0,:,:] = self.spongeBC.spongeRhoAvg[0,:,:]
self.rhoU1[0,:,:] = self.spongeBC.spongeRhoUAvg[0,:,:]
self.rhoV1[0,:,:] = self.spongeBC.spongeRhoVAvg[0,:,:]
self.rhoW1[0,:,:] = self.spongeBC.spongeRhoWAvg[0,:,:]
self.rhoE1[0,:,:] = self.spongeBC.spongeRhoEAvg[0,:,:]
if self.bcX1 == "SPONGE":
self.rho1[-1,:,:] = self.spongeBC.spongeRhoAvg[-1,:,:]
self.rhoU1[-1,:,:] = self.spongeBC.spongeRhoUAvg[-1,:,:]
self.rhoV1[-1,:,:] = self.spongeBC.spongeRhoVAvg[-1,:,:]
self.rhoW1[-1,:,:] = self.spongeBC.spongeRhoWAvg[-1,:,:]
self.rhoE1[-1,:,:] = self.spongeBC.spongeRhoEAvg[-1,:,:]
if self.bcY0 == "SPONGE":
self.rho1[:,0,:] = self.spongeBC.spongeRhoAvg[:,0,:]
self.rhoU1[:,0,:] = self.spongeBC.spongeRhoUAvg[:,0,:]
self.rhoV1[:,0,:] = self.spongeBC.spongeRhoVAvg[:,0,:]
self.rhoW1[:,0,:] = self.spongeBC.spongeRhoWAvg[:,0,:]
self.rhoE1[:,0,:] = self.spongeBC.spongeRhoEAvg[:,0,:]
if self.bcY1 == "SPONGE":
self.rho1[:,-1,:] = self.spongeBC.spongeRhoAvg[:,-1,:]
self.rhoU1[:,-1,:] = self.spongeBC.spongeRhoUAvg[:,-1,:]
self.rhoV1[:,-1,:] = self.spongeBC.spongeRhoVAvg[:,-1,:]
self.rhoW1[:,-1,:] = self.spongeBC.spongeRhoWAvg[:,-1,:]
self.rhoE1[:,-1,:] = self.spongeBC.spongeRhoEAvg[:,-1,:]
if self.bcZ0 == "SPONGE":
self.rho1[:,:,0] = self.spongeBC.spongeRhoAvg[:,:,0]
self.rhoU1[:,:,0] = self.spongeBC.spongeRhoUAvg[:,:,0]
self.rhoV1[:,:,0] = self.spongeBC.spongeRhoVAvg[:,:,0]
self.rhoW1[:,:,0] = self.spongeBC.spongeRhoWAvg[:,:,0]
self.rhoE1[:,:,0] = self.spongeBC.spongeRhoEAvg[:,:,0]
if self.bcZ1 == "SPONGE":
self.rho1[:,:,-1] = self.spongeBC.spongeRhoAvg[:,:,-1]
self.rhoU1[:,:,-1] = self.spongeBC.spongeRhoUAvg[:,:,-1]
self.rhoV1[:,:,-1] = self.spongeBC.spongeRhoVAvg[:,:,-1]
self.rhoW1[:,:,-1] = self.spongeBC.spongeRhoWAvg[:,:,-1]
self.rhoE1[:,:,-1] = self.spongeBC.spongeRhoEAvg[:,:,-1]
def plotFigure(self):
# plt.plot(self.y,self.U[0,:,0],self.y,self.Uy[0,:,0])
# plt.imshow(np.rot90(self.Vx[1:-2,1:-2] - self.Uy[1:-2,1:-2]), cmap="RdBu",interpolation='bicubic')
# plt.imshow(np.rot90(self.Ux[1:-2,1:-2] + self.Ux[1:-2,1:-2]), cmap="RdBu",interpolation='bicubic')
plt.imshow(np.rot90(self.U[:,:,5]), cmap="RdBu",interpolation='bicubic')
plt.colorbar()
plt.axis("equal")
def checkSolution(self):
print(self.timeStep)
#Check if we've hit the end of the timestep condition
if self.timeStep >= self.maxTimeStep:
self.done = True
#Check if we've hit the end of the max time condition
if self.time >= self.maxTime:
self.done = True
if(self.timeStep%self.plotStep == 0):
drawnow(self.plotFigure)
if((np.isnan(self.rhoE1)).any() == True or (np.isnan(self.rho1)).any() == True or (np.isnan(self.rhoU1)).any() == True or (np.isnan(self.rhoV1)).any() == True or (np.isnan(self.rhoW1)).any() == True):
self.done = True
print(-1)
rho1 = rho0
p1 = p0
rhoU1 = rho0 * U0
rhoE1 = p0 / (gamma - 1) + (1 / 2) * rho0 * U0 * U0
T1 = p0 / (rho0 * R_gas)
mu = mu_ref * (T1 / T_ref)**0.76
k = cp * mu / Pr
sos = np.sqrt(gamma * p0 / rho0)
if bcX0 == "ADIABATIC_WALL":
T1[0] = deriv.calcNeumann0(T1)
U1[0] = 0.0
rhoU1[0] = 0.0
if bcX1 == "ADIABATIC_WALL":
T1[-1] = deriv.calcNeumannEnd(T1)
U1[-1] = 0.0
rhoU1[-1] = 0.0
if bcX0 == "ADIABATIC_WALL" or bcX1 == "ADIABATIC_WALL":
p1 = T1 * rho1 * R_gas
sos = np.sqrt(gamma * p1 / rho1)
rhoE1 = p1 / (gamma - 1) + (1 / 2) * rho1 * U1 * U1
if bcX0 == "SPONGE" or bcX1 == "SPONGE":
spongeRhoAvg = rho1
spongeRhoUAvg = rhoU1
spongeRhoEAvg = rhoE1
#Calculate the time step from constant CFL
UChar = np.fabs(U1) + sos
class CSolver:
def __init__(self, domain, bc, timeStepping, alphaF, mu_ref):
self.done = False
#grid info
self.N = domain.N
self.x = domain.x
self.L = domain.L
self.dx = domain.dx
#gas properties
self.idealGas = IdealGas(mu_ref)
#BC info
self.bcType = bc.bcType
self.bcX0 = bc.bcX0
self.bcX1 = bc.bcX1
#initial conditions
self.U0 = np.zeros(self.N)
self.rho0 = np.zeros(self.N)
self.p0 = np.zeros(self.N)
#non-primative data
self.U = np.zeros(self.N)
self.T = np.zeros(self.N)
self.p = np.zeros(self.N)
self.mu = np.zeros(self.N)
self.k = np.zeros(self.N)
self.sos = np.zeros(self.N)
#primative data
self.rho1 = np.zeros(self.N)
self.rhoU1 = np.zeros(self.N)
self.rhoE1 = np.zeros(self.N)
self.rhok = np.zeros(self.N)
self.rhoUk = np.zeros(self.N)
self.rhoEk = np.zeros(self.N)
self.rhok2 = np.zeros(self.N)
self.rhoUk2 = np.zeros(self.N)
self.rhoEk2 = np.zeros(self.N)
self.rho2 = np.zeros(self.N)
self.rhoU2 = np.zeros(self.N)
self.rhoE2 = np.zeros(self.N)
#time data
self.timeStep = 0
self.time = 0.0
self.maxTimeStep = timeStepping.maxTimeStep
self.maxTime = timeStepping.maxTime
self.plotStep = timeStepping.plotStep
self.CFL = timeStepping.CFL
#filter data
self.filterStep = timeStepping.filterStep
self.alphaF = alphaF
if self.bcX0 == "SPONGE" or self.bcX1 == "SPONGE":
self.spongeFlag = 1
self.spongeBC = SpongeBC(self.N, self.x, self.L, self.idealGas,
self.bcX0, self.bcX1)
else:
self.spongeFlag = 0
#Generate our derivatives and our filter
self.deriv = CollocatedDeriv(self.N, self.dx, self.bcType)
self.filt = CompactFilter(self.N, self.alphaF, self.bcType)
def setInitialConditions(self, rho0, U0, p0):
self.rho0 = rho0
self.U0 = U0
self.p0 = p0
self.U = U0
self.rho1 = rho0
self.p = p0
self.rhoU1 = rho0 * U0
self.rhoE1 = self.idealGas.solveRhoE(rho0, U0, p0)
self.T = self.idealGas.solveT(rho0, p0)
self.mu = self.idealGas.solveMu(self.T)
self.k = self.idealGas.solveK(self.mu)
self.sos = self.idealGas.solveSOS(self.rho1, self.p)
if self.bcX0 == "ADIABATIC_WALL":
self.T[0] = self.deriv.calcNeumann0(self.T)
self.U[0] = 0.0
self.rhoU1[0] = 0.0
if self.bcX1 == "ADIABATIC_WALL":
self.T[-1] = self.deriv.calcNeumannEnd(self.T)
self.U[-1] = 0.0
self.rhoU1[-1] = 0.0
if self.bcX0 == "ADIABATIC_WALL" or self.bcX1 == "ADIABATIC_WALL":
self.p = self.idealGas.solvePIdealGas(self.rho1, self.T)
self.sos = self.idealGas.solveSOS(self.rho1, self.p)
self.rhoE1 = self.idealGas.solveRhoE(self.rho1, self.U, self.p)
if self.bcX0 == "SPONGE" or self.bcX1 == "SPONGE":
self.spongeBC.spongeRhoAvg = self.rho1
self.spongeBC.spongeRhoUAvg = self.rhoU1
self.spongeBC.spongeRhoEAvg = self.rhoE1
def calcDtFromCFL(self):
UChar = np.fabs(self.U) + self.sos
self.dt = np.min(self.CFL * self.dx / UChar)
#Increment timestep
self.timeStep += 1
self.time += self.dt
def calcSpongeSource(self, f, eqn):
if self.spongeFlag == 1:
if eqn == "CONT":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoAvg - f)
elif eqn == "XMOM":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoUAvg - f)
elif eqn == "ENGY":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoEAvg - f)
else:
source = 0
else:
source = 0
return source
def preStepBCHandling(self, rho, rhoU, rhoE):
if self.bcX0 == "ADIABATIC_WALL":
self.U[0] = 0.0
rhoU[0] = 0.0
self.T[0] = self.deriv.calcNeumann0(self.T)
self.p[0] = self.idealGas.solvePIdealGas(rho[0], self.T[0])
if self.bcX1 == "ADIABATIC_WALL":
self.U[-1] = 0.0
rhoU[-1] = 0.0
self.T[-1] = self.deriv.calcNeumannEnd(self.T)
self.p[-1] = self.idealGas.solvePIdealGas(rho[-1], self.T[-1])
def solveContinuity(self, rho, rhoU, rhoE):
self.rhok2 = (-self.dt * self.deriv.compact1stDeriv(rhoU) +
self.calcSpongeSource(rho, "CONT"))
def solveXMomentum(self, rho, rhoU, rhoE):
self.rhoUk2 = (
-self.dt *
(self.deriv.compact1stDeriv(rhoU * self.U + self.p) -
(4 / 3) * self.mu * self.deriv.compact2ndDeriv(self.U)) +
self.calcSpongeSource(rhoU, "XMOM"))
def solveEnergy(self, rho, rhoU, rhoE):
self.rhoEk2 = (
-self.dt *
(self.deriv.compact1stDeriv(rhoE * self.U + self.U * self.p) -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) * self.deriv.compact2ndDeriv(self.T) +
(4 / 3) * self.mu * self.U * self.deriv.compact2ndDeriv(self.U)) +
self.calcSpongeSource(rhoE, "ENGY"))
def postStepBCHandling(self, rho, rhoU, rhoE):
if self.bcType == "DIRICHLET":
if self.bcX0 == "ADIABATIC_WALL":
rho[0] = rho[0]
rhoU[0] = 0
rhoE[0] = rhoE[0]
else:
rho[0] = 0
rhoU[0] = 0
rhoE[0] = 0
if self.bcX1 == "ADIABATIC_WALL":
rho[-1] = rho[-1]
rhoU[-1] = 0
rhoE[-1] = rhoE[-1]
else:
rho[-1] = 0
rhoU[-1] = 0
rhoE[-1] = 0
def updateConservedData(self, rkStep):
if rkStep == 1:
self.rho2 = self.rho1 + self.rhok2 / 6
self.rhoU2 = self.rhoU1 + self.rhoUk2 / 6
self.rhoE2 = self.rhoE1 + self.rhoEk2 / 6
elif rkStep == 2:
self.rho2 += self.rhok2 / 3
self.rhoU2 += self.rhoUk2 / 3
self.rhoE2 += self.rhoEk2 / 3
elif rkStep == 3:
self.rho2 += self.rhok2 / 3
self.rhoU2 += self.rhoUk2 / 3
self.rhoE2 += self.rhoEk2 / 3
elif rkStep == 4:
self.rho2 += self.rhok2 / 6
self.rhoU2 += self.rhoUk2 / 6
self.rhoE2 += self.rhoEk2 / 6
if rkStep == 1:
self.rhok = self.rho1 + self.rhok2 / 2
self.rhoUk = self.rhoU1 + self.rhoUk2 / 2
self.rhoEk = self.rhoE1 + self.rhoEk2 / 2
elif rkStep == 2:
self.rhok = self.rho1 + self.rhok2 / 2
self.rhoUk = self.rhoU1 + self.rhoUk2 / 2
self.rhoEk = self.rhoE1 + self.rhoEk2 / 2
elif rkStep == 3:
self.rhok = self.rho1 + self.rhok2
self.rhoUk = self.rhoU1 + self.rhoUk2
self.rhoEk = self.rhoE1 + self.rhoEk2
def updateNonConservedData(self, rkStep):
if rkStep == 1 or rkStep == 2 or rkStep == 3:
self.U = self.rhoUk / self.rhok
self.p = (self.idealGas.gamma - 1) * (
self.rhoEk - 0.5 * self.rhoUk * self.rhoUk / self.rhok)
self.T = (self.p / (self.rhok * self.idealGas.R_gas))
self.mu = self.idealGas.mu_ref * (self.T /
self.idealGas.T_ref)**0.76
self.k = self.idealGas.cp * self.mu / self.idealGas.Pr
self.sos = np.sqrt(self.idealGas.gamma * self.p / self.rhok)
elif rkStep == 4:
self.U = self.rhoU1 / self.rho1
self.p = (self.idealGas.gamma - 1) * (
self.rhoE1 - 0.5 * self.rhoU1 * self.rhoU1 / self.rho1)
self.T = (self.p / (self.rho1 * self.idealGas.R_gas))
self.mu = self.idealGas.mu_ref * (self.T /
self.idealGas.T_ref)**0.76
self.k = self.idealGas.cp * self.mu / self.idealGas.Pr
self.sos = np.sqrt(self.idealGas.gamma * self.p / self.rho1)
def filterPrimativeValues(self):
if (self.timeStep % self.filterStep == 0):
self.rho1 = self.filt.compactFilter(self.rho2)
self.rhoU1 = self.filt.compactFilter(self.rhoU2)
self.rhoE1 = self.filt.compactFilter(self.rhoE2)
print("Filtering...")
if self.bcType == "DIRICHLET":
self.rho1[0] = self.rho2[0]
self.rho1[-1] = self.rho2[-1]
self.rhoU1[0] = self.rhoU2[0]
self.rhoU1[-1] = self.rhoU2[-1]
self.rhoE1[0] = self.rhoE2[0]
self.rhoE1[-1] = self.rhoE2[-1]
else:
self.rho1 = self.rho2
self.rhoU1 = self.rhoU2
self.rhoE1 = self.rhoE2
def updateSponge(self):
if self.spongeFlag == 1:
eps = 1.0 / (self.spongeBC.spongeAvgT / self.dt + 1.0)
self.spongeBC.spongeRhoAvg += eps * (self.rho1 -
self.spongeBC.spongeRhoAvg)
self.spongeBC.spongeRhoUAvg += eps * (self.rhoU1 -
self.spongeBC.spongeRhoUAvg)
self.spongeBC.spongeRhoEAvg += eps * (self.rhoE1 -
self.spongeBC.spongeRhoEAvg)
self.spongeBC.spongeRhoEAvg = (
self.spongeBC.spongeEpsP * self.spongeBC.spongeRhoEAvg +
(1.0 - self.spongeBC.spongeEpsP) *
(self.spongeBC.spongeP / (self.idealGas.gamma - 1) + 0.5 *
(self.spongeBC.spongeRhoUAvg**2) / self.spongeBC.spongeRhoAvg)
)
if self.bcX0 == "SPONGE":
self.rho1[0] = self.spongeBC.spongeRhoAvg[0]
self.rhoU1[0] = self.spongeBC.spongeRhoUAvg[0]
self.rhoE1[0] = self.spongeBC.spongeRhoEAvg[0]
if self.bcX1 == "SPONGE":
self.rho1[-1] = self.spongeBC.spongeRhoAvg[-1]
self.rhoU1[-1] = self.spongeBC.spongeRhoUAvg[-1]
self.rhoE1[-1] = self.spongeBC.spongeRhoEAvg[-1]
def plotFigure(self):
plt.plot(self.x, self.rho1)
plt.axis([0, self.L, 0.95, 1.05])
def checkSolution(self):
print(self.timeStep)
#Check if we've hit the end of the timestep condition
if self.timeStep >= self.maxTimeStep:
self.done = True
#Check if we've hit the end of the max time condition
if self.time >= self.maxTime:
self.done = True
if (self.timeStep % self.plotStep == 0):
drawnow(self.plotFigure)
print(self.timeStep)
if ((np.isnan(self.rhoE1)).any() == True
or (np.isnan(self.rho1)).any() == True
or (np.isnan(self.rhoU1)).any() == True):
self.done = True
print(-1)
class CSolver2D:
def __init__(self, domain, bc, timeStepping, alphaF, mu_ref):
self.done = False
self.Uwall = 0.1
#grid info
self.Nx = domain.Nx
self.x = domain.x
self.Lx = domain.Lx
self.dx = domain.dx
self.Ny = domain.Ny
self.y = domain.y
self.Ly = domain.Ly
self.dy = domain.dy
self.X = domain.X
self.Y = domain.Y
#gas properties
self.idealGas = IdealGas(mu_ref)
#BC info
self.bcXType = bc.bcXType
self.bcX0 = bc.bcX0
self.bcX1 = bc.bcX1
self.bcYType = bc.bcYType
self.bcY0 = bc.bcY0
self.bcY1 = bc.bcY1
#initial conditions
self.U0 = np.zeros((self.Nx, self.Ny))
self.V0 = np.zeros((self.Nx, self.Ny))
self.rho0 = np.zeros((self.Nx, self.Ny))
self.p0 = np.zeros((self.Nx, self.Ny))
#non-conserved data
self.U = np.zeros((self.Nx, self.Ny))
self.V = np.zeros((self.Nx, self.Ny))
self.T = np.zeros((self.Nx, self.Ny))
self.p = np.zeros((self.Nx, self.Ny))
self.mu = np.zeros((self.Nx, self.Ny))
self.k = np.zeros((self.Nx, self.Ny))
self.sos = np.zeros((self.Nx, self.Ny))
#Derivatives of Data
self.Ux = np.zeros((self.Nx, self.Ny))
self.Uy = np.zeros((self.Nx, self.Ny))
self.Uxx = np.zeros((self.Nx, self.Ny))
self.Uyy = np.zeros((self.Nx, self.Ny))
self.Uxy = np.zeros((self.Nx, self.Ny))
self.Vx = np.zeros((self.Nx, self.Ny))
self.Vy = np.zeros((self.Nx, self.Ny))
self.Vxx = np.zeros((self.Nx, self.Ny))
self.Vyy = np.zeros((self.Nx, self.Ny))
self.Vxy = np.zeros((self.Nx, self.Ny))
self.Tx = np.zeros((self.Nx, self.Ny))
self.Ty = np.zeros((self.Nx, self.Ny))
self.Txx = np.zeros((self.Nx, self.Ny))
self.Tyy = np.zeros((self.Nx, self.Ny))
#conserved data
self.rho1 = np.zeros((self.Nx, self.Ny))
self.rhoU1 = np.zeros((self.Nx, self.Ny))
self.rhoV1 = np.zeros((self.Nx, self.Ny))
self.rhoE1 = np.zeros((self.Nx, self.Ny))
self.rhok = np.zeros((self.Nx, self.Ny))
self.rhoUk = np.zeros((self.Nx, self.Ny))
self.rhoVk = np.zeros((self.Nx, self.Ny))
self.rhoEk = np.zeros((self.Nx, self.Ny))
self.rhok2 = np.zeros((self.Nx, self.Ny))
self.rhoUk2 = np.zeros((self.Nx, self.Ny))
self.rhoVk2 = np.zeros((self.Nx, self.Ny))
self.rhoEk2 = np.zeros((self.Nx, self.Ny))
self.rho2 = np.zeros((self.Nx, self.Ny))
self.rhoU2 = np.zeros((self.Nx, self.Ny))
self.rhoV2 = np.zeros((self.Nx, self.Ny))
self.rhoE2 = np.zeros((self.Nx, self.Ny))
#time data
self.timeStep = 0
self.time = 0.0
self.maxTimeStep = timeStepping.maxTimeStep
self.maxTime = timeStepping.maxTime
self.plotStep = timeStepping.plotStep
self.CFL = timeStepping.CFL
#filter data
self.filterStep = timeStepping.filterStep
self.numberOfFilterStep = 0
self.alphaF = alphaF
if self.bcX0 == "SPONGE" or self.bcX1 == "SPONGE" or self.bcY0 == "SPONGE" or self.bcY1 == "SPONGE":
self.spongeFlag = True
self.spongeBC = SpongeBC2D(domain, self.idealGas, bc)
else:
self.spongeFlag = False
#Generate our derivatives and our filters
self.derivX = CollocatedDeriv(self.Nx, self.dx, self.bcXType, "X")
self.derivY = CollocatedDeriv(self.Ny, self.dy, self.bcYType, "Y")
self.filtX = CompactFilter(self.Nx, self.alphaF, self.bcXType, "X")
self.filtY = CompactFilter(self.Ny, self.alphaF, self.bcYType, "Y")
def setInitialConditions(self, rho0, U0, V0, p0):
self.rho0 = rho0
self.U0 = U0
self.V0 = V0
self.p0 = p0
self.U = U0
self.V = V0
self.rho1 = rho0
self.p = p0
self.rhoU1 = rho0 * U0
self.rhoV1 = rho0 * V0
self.rhoE1 = self.idealGas.solveRhoE(rho0, U0, V0, p0)
self.T = self.idealGas.solveT(rho0, p0)
self.mu = self.idealGas.solveMu(self.T)
self.Amu = self.idealGas.solveAMu(self.T)
self.k = self.idealGas.solveK(self.mu)
self.sos = self.idealGas.solveSOS(self.rho1, self.p)
if self.bcX0 == "ADIABATIC_WALL":
self.T[0, :] = self.derivX.calcNeumann0(self.T)
self.U[0, :] = 0.0
self.rhoU1[0, :] = 0.0
self.V[0, :] = 0.0
self.rhoV1[0, :] = 0.0
if self.bcX1 == "ADIABATIC_WALL":
self.T[-1, :] = self.derivX.calcNeumannEnd(self.T)
self.U[-1, :] = 0.0
self.rhoU1[-1, :] = 0.0
self.V[-1, :] = 0.0
self.rhoV1[-1, :] = 0.0
if self.bcY0 == "ADIABATIC_WALL":
self.T[:, 0] = self.derivY.calcNeumann0(self.T)
self.U[:, 0] = 0.0
self.rhoU1[:, 0] = 0.0
self.V[:, 0] = 0.0
self.rhoV1[:, 0] = 0.0
if self.bcY1 == "ADIABATIC_WALL":
self.T[:, -1] = self.derivY.calcNeumannEnd(self.T)
self.U[:, -1] = 0.0
self.rhoU1[:, -1] = 0.0
self.V[:, -1] = 0.0
self.rhoV1[:, -1] = 0.0
if self.bcY1 == "ADIABATIC_MOVINGWALL":
self.T[:, -1] = self.derivY.calcNeumannEnd(self.T)
self.U[:, -1] = self.Uwall
self.rhoU1[:, -1] = self.rho1[:, -1] * self.Uwall
self.V[:, -1] = 0.0
self.rhoV1[:, -1] = 0.0
if self.bcX0 == "ADIABATIC_WALL" or self.bcX1 == "ADIABATIC_WALL" or self.bcY0 == "ADIABATIC_WALL" or self.bcY1 == "ADIABATIC_WALL" or self.bcY1 == "ADIABATIC_MOVINGWALL":
self.p = self.idealGas.solvePIdealGas(self.rho1, self.T)
self.sos = self.idealGas.solveSOS(self.rho1, self.p)
self.rhoE1 = self.idealGas.solveRhoE(self.rho1, self.U, self.V,
self.p)
if self.spongeFlag == True:
self.spongeBC.spongeRhoAvg = self.rho1
self.spongeBC.spongeRhoUAvg = self.rhoU1
self.spongeBC.spongeRhoVAvg = self.rhoV1
self.spongeBC.spongeRhoEAvg = self.rhoE1
self.Ux = self.derivX.df_2D(self.U)
self.Vx = self.derivX.df_2D(self.V)
self.Uy = self.derivY.df_2D(self.U)
self.Vy = self.derivY.df_2D(self.V)
def calcDtFromCFL(self):
UChar_dx = (np.fabs(self.U) + self.sos) / self.dx + (
np.fabs(self.V) + self.sos) / self.dy
self.dt = np.min(self.CFL / UChar_dx)
#Increment timestep
self.timeStep += 1
self.time += self.dt
def calcSpongeSource(self, f, eqn):
if self.spongeFlag == True:
if eqn == "CONT":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoAvg - f)
elif eqn == "XMOM":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoUAvg - f)
elif eqn == "YMOM":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoVAvg - f)
elif eqn == "ENGY":
source = self.spongeBC.spongeSigma * (
self.spongeBC.spongeRhoEAvg - f)
else:
source = 0
else:
source = 0
return source
def preStepBCHandling(self, rho, rhoU, rhoV, rhoE):
if self.bcX0 == "ADIABATIC_WALL":
self.U[0, :] = 0.0
rhoU[0, :] = 0.0
self.V[0, :] = 0.0
rhoV[0, :] = 0.0
self.T[0, :] = self.derivX.calcNeumann0(self.T)
self.p[0, :] = self.idealGas.solvePIdealGas(
rho[0, :], self.T[0, :])
if self.bcX1 == "ADIABATIC_WALL":
self.U[-1, :] = 0.0
rhoU[-1, :] = 0.0
self.V[-1, :] = 0.0
rhoV[-1, :] = 0.0
self.T[-1, :] = self.derivX.calcNeumannEnd(self.T)
self.p[-1, :] = self.idealGas.solvePIdealGas(
rho[-1, :], self.T[-1, :])
if self.bcY0 == "ADIABATIC_WALL":
self.U[:, 0] = 0.0
rhoU[:, 0] = 0.0
self.V[:, 0] = 0.0
rhoV[:, 0] = 0.0
self.T[:, 0] = self.derivY.calcNeumann0(self.T)
self.p[:,
0] = self.idealGas.solvePIdealGas(rho[:, 0], self.T[:, 0])
if self.bcY1 == "ADIABATIC_WALL":
self.U[:, -1] = 0.0
rhoU[:, -1] = 0.0
self.V[:, -1] = 0.0
rhoV[:, -1] = 0.0
self.T[:, -1] = self.derivY.calcNeumannEnd(self.T)
self.p[:,
-1] = self.idealGas.solvePIdealGas(rho[:, -1], self.T[:,
-1])
if self.bcY1 == "ADIABATIC_MOVINGWALL":
self.U[:, -1] = self.Uwall
rhoU[:, -1] = rho[:, -1] * self.Uwall
self.V[:, -1] = 0.0
rhoV[:, -1] = 0.0
self.T[:, -1] = self.derivY.calcNeumannEnd(self.T[:, :])
self.p[:,
-1] = self.idealGas.solvePIdealGas(rho[:, -1], self.T[:,
-1])
def preStepDerivatives(self):
#First Derivatives
self.Ux = self.derivX.df_2D(self.U)
self.Vx = self.derivX.df_2D(self.V)
self.Uy = self.derivY.df_2D(self.U)
self.Vy = self.derivY.df_2D(self.V)
self.Tx = self.derivX.df_2D(self.T)
self.Ty = self.derivY.df_2D(self.T)
#Second Derivatives
self.Uxx = self.derivX.d2f_2D(self.U)
self.Uyy = self.derivY.d2f_2D(self.U)
self.Vxx = self.derivX.d2f_2D(self.V)
self.Vyy = self.derivY.d2f_2D(self.V)
self.Txx = self.derivX.d2f_2D(self.T)
self.Tyy = self.derivY.d2f_2D(self.T)
#Cross Derivatives
if self.timeStep % 2 == 0:
self.Uxy = self.derivX.df_2D(self.derivY.df_2D(self.U))
self.Vxy = self.derivX.df_2D(self.derivY.df_2D(self.V))
else:
self.Uxy = self.derivY.df_2D(self.derivX.df_2D(self.U))
self.Vxy = self.derivY.df_2D(self.derivX.df_2D(self.V))
#Actually solving the equations...
def solveXMomentum_Euler(self, rhoU):
return -self.derivX.df_2D(rhoU * self.U + self.p) - self.derivY.df_2D(
rhoU * self.V)
def solveYMomentum_Euler(self, rhoV):
return -self.derivX.df_2D(
rhoV * self.U) - self.derivY.df_2D(rhoV * self.V + self.p)
def solveEnergy_Euler(self, rhoE):
return -self.derivX.df_2D(rhoE * self.U + self.U *
self.p) - self.derivY.df_2D(rhoE * self.V +
self.V * self.p)
def solveXMomentum_Viscous(self):
return ((4 / 3) * self.Amu * self.Tx * self.Ux +
(4 / 3) * self.mu * self.Uxx -
(2 / 3) * self.Amu * self.Tx * self.Vy +
(1 / 3) * self.mu * self.Vxy + self.Amu * self.Ty * self.Vx +
self.Amu * self.Ty * self.Uy + self.mu * self.Uyy)
def solveYMomentum_Viscous(self):
return ((4 / 3) * self.Amu * self.Ty * self.Vy +
(4 / 3) * self.mu * self.Vyy -
(2 / 3) * self.Amu * self.Ty * self.Ux +
(1 / 3) * self.mu * self.Uxy + self.Amu * self.Tx * self.Uy +
self.Amu * self.Tx * self.Vx + self.mu * self.Vxx)
def solveEnergy_Viscous(self):
return ((self.idealGas.cp / self.idealGas.Pr) * self.Amu *
(self.Tx**2 + self.Ty**2) +
(self.idealGas.cp / self.idealGas.Pr) * self.mu *
(self.Txx + self.Tyy) + (4 / 3) * self.mu *
(self.Ux**2 + self.Vy**2) + (4 / 3) * self.Amu *
(self.U * self.Tx * self.Ux + self.V * self.Ty * self.Vy) +
(4 / 3) * self.mu * (self.U * self.Uxx + self.V * self.Vyy) -
(4 / 3) * self.mu * self.Ux * self.Vy - (2 / 3) * self.Amu *
(self.U * self.Tx * self.Vy + self.V * self.Ty * self.Ux) +
(1 / 3) * self.mu * (self.U * self.Vxy + self.V * self.Uxy) +
self.mu * (self.Uy**2 + self.Vx**2) + 2. * self.mu *
(self.Uy * self.Vx) + self.mu *
(self.U * self.Uyy + self.V * self.Vxx) + self.Amu *
(self.V * self.Tx * self.Uy + self.V * self.Tx * self.Vx +
self.U * self.Ty * self.Uy + self.U * self.Ty * self.Vx))
#Using methods that don't maximize the resolution capabilities of the compact differences
def solveContinuity(self, rho, rhoU, rhoV, rhoE):
drho = (-self.derivX.df_2D(rhoU) - self.derivY.df_2D(rhoV))
self.rhok2 = self.dt * (drho + self.calcSpongeSource(rho, "CONT"))
def solveXMomentum(self, rho, rhoU, rhoV, rhoE):
drhoU = (-self.derivX.df_2D(rhoU * self.U + self.p +
-2 * self.mu * self.Ux +
(2 / 3) * self.mu * (self.Ux + self.Vy)) +
-self.derivY.df_2D(rhoU * self.V - self.mu *
(self.Vx + self.Uy)))
self.rhoUk2 = self.dt * (drhoU + self.calcSpongeSource(rhoU, "XMOM"))
def solveYMomentum(self, rho, rhoU, rhoV, rhoE):
drhoV = (-self.derivY.df_2D(rhoV * self.V + self.p +
-2 * self.mu * self.Vy +
(2 / 3) * self.mu * (self.Ux + self.Vy)) -
self.derivX.df_2D(rhoV * self.U - self.mu *
(self.Vx + self.Uy)))
self.rhoVk2 = self.dt * (drhoV + self.calcSpongeSource(rhoV, "YMOM"))
def solveEnergy(self, rho, rhoU, rhoV, rhoE):
drhoE = (-self.derivX.df_2D(rhoE * self.U + self.U * self.p -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) *
self.derivX.df_2D(self.T) + -self.U *
(2 * self.mu * self.Ux -
(2 / 3) * self.mu *
(self.Ux + self.Vy)) - self.V *
(self.mu * (self.Vx + self.Uy))) -
self.derivY.df_2D(rhoE * self.V + self.V * self.p -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) *
self.derivY.df_2D(self.T) + -self.V *
(2 * self.mu * self.Vy - (2 / 3) * self.mu *
(self.Ux + self.Vy)) - self.U *
(self.mu * (self.Vx + self.Uy))))
self.rhoEk2 = self.dt * (drhoE + self.calcSpongeSource(rhoE, "ENGY"))
#Using methods that do take advantage of the the spectral benefits of the compact diff's
def solveXMomentum_PV(self, rho, rhoU, rhoV, rhoE):
self.rhoUk2 = self.dt * (self.solveXMomentum_Euler(rhoU) +
self.solveXMomentum_Viscous() +
self.calcSpongeSource(rhoU, "XMOM"))
def solveYMomentum_PV(self, rho, rhoU, rhoV, rhoE):
self.rhoVk2 = self.dt * (self.solveYMomentum_Euler(rhoV) +
self.solveYMomentum_Viscous() +
self.calcSpongeSource(rhoV, "YMOM"))
def solveEnergy_PV(self, rho, rhoU, rhoV, rhoE):
self.rhoEk2 = self.dt * (self.solveEnergy_Euler(rhoE) +
self.solveEnergy_Viscous() +
self.calcSpongeSource(rhoE, "ENGY"))
def postStepBCHandling(self, rho, rhoU, rhoV, rhoE):
if self.bcXType == "DIRICHLET":
if self.bcX0 == "ADIABATIC_WALL":
self.rhok2[0, :] = -self.dt * self.derivX.df_2D(rhoU)[0, :]
self.rhoUk2[0, :] = 0
self.rhoVk2[0, :] = 0
self.rhoEk2[0, :] = (
-self.dt *
(self.derivX.df_2D(rhoE * self.U + self.U * self.p) -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) * self.derivX.d2f_2D(self.T) +
(4 / 3) * self.mu * self.U * self.derivX.d2f_2D(self.U))
)[0, :]
else:
self.rhok2[0, :] = 0
self.rhoUk2[0, :] = 0
self.rhoVk2[0, :] = 0
self.rhoEk2[0, :] = 0
if self.bcX1 == "ADIABATIC_WALL":
self.rhok2[-1, :] = -self.dt * self.derivX.df_2D(rhoU)[-1, :]
self.rhoUk2[-1, :] = 0
self.rhoVk2[-1, :] = 0
self.rhoEk2[-1, :] = (
-self.dt *
(self.derivX.df_2D(rhoE * self.U + self.U * self.p) -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) * self.derivX.d2f_2D(self.T) +
(4 / 3) * self.mu * self.U * self.derivX.d2f_2D(self.U))
)[-1, :]
else:
self.rhok2[-1, :] = 0
self.rhoUk2[-1, :] = 0
self.rhoVk2[-1, :] = 0
self.rhoEk2[-1, :] = 0
if self.bcYType == "DIRICHLET":
if self.bcY0 == "ADIABATIC_WALL":
self.rhok2[:, 0] = -self.dt * self.derivY.df_2D(rhoV)[:, 0]
self.rhoUk2[:, 0] = 0
self.rhoVk2[:, 0] = 0
self.rhoEk2[:, 0] = (
-self.dt *
(self.derivY.df_2D(rhoE * self.V + self.V * self.p) -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) * self.derivY.d2f_2D(self.T) +
(4 / 3) * self.mu * self.V * self.derivY.d2f_2D(self.V))
)[:, 0]
else:
self.rhok2[:, 0] = 0
self.rhoUk2[:, 0] = 0
self.rhoVk2[:, 0] = 0
self.rhoEk2[:, 0] = 0
if self.bcY1 == "ADIABATIC_WALL" or self.bcY1 == "ADIABATIC_MOVINGWALL":
self.rhok2[:, -1] = -self.dt * self.derivY.df_2D(rhoV)[:, -1]
self.rhoUk2[:, -1] = 0
self.rhoVk2[:, -1] = 0
self.rhoEk2[:, -1] = (
-self.dt *
(self.derivY.df_2D(rhoE * self.V + self.V * self.p) -
(self.mu / self.idealGas.Pr /
(self.idealGas.gamma - 1)) * self.derivY.d2f_2D(self.T) +
(4 / 3) * self.mu * self.V * self.derivY.d2f_2D(self.V))
)[:, -1]
else:
self.rhok2[:, -1] = 0
self.rhoUk2[:, -1] = 0
self.rhoVk2[:, -1] = 0
self.rhoEk2[:, -1] = 0
def updateConservedData(self, rkStep):
if rkStep == 1:
self.rho2 = self.rho1 + self.rhok2 / 6
self.rhoU2 = self.rhoU1 + self.rhoUk2 / 6
self.rhoV2 = self.rhoV1 + self.rhoVk2 / 6
self.rhoE2 = self.rhoE1 + self.rhoEk2 / 6
elif rkStep == 2:
self.rho2 += self.rhok2 / 3
self.rhoU2 += self.rhoUk2 / 3
self.rhoV2 += self.rhoVk2 / 3
self.rhoE2 += self.rhoEk2 / 3
elif rkStep == 3:
self.rho2 += self.rhok2 / 3
self.rhoU2 += self.rhoUk2 / 3
self.rhoV2 += self.rhoVk2 / 3
self.rhoE2 += self.rhoEk2 / 3
elif rkStep == 4:
self.rho2 += self.rhok2 / 6
self.rhoU2 += self.rhoUk2 / 6
self.rhoV2 += self.rhoVk2 / 6
self.rhoE2 += self.rhoEk2 / 6
if rkStep == 1:
self.rhok = self.rho1 + self.rhok2 / 2
self.rhoUk = self.rhoU1 + self.rhoUk2 / 2
self.rhoVk = self.rhoV1 + self.rhoVk2 / 2
self.rhoEk = self.rhoE1 + self.rhoEk2 / 2
elif rkStep == 2:
self.rhok = self.rho1 + self.rhok2 / 2
self.rhoUk = self.rhoU1 + self.rhoUk2 / 2
self.rhoVk = self.rhoV1 + self.rhoVk2 / 2
self.rhoEk = self.rhoE1 + self.rhoEk2 / 2
elif rkStep == 3:
self.rhok = self.rho1 + self.rhok2
self.rhoUk = self.rhoU1 + self.rhoUk2
self.rhoVk = self.rhoV1 + self.rhoVk2
self.rhoEk = self.rhoE1 + self.rhoEk2
def updateNonConservedData(self, rkStep):
if rkStep == 1 or rkStep == 2 or rkStep == 3:
self.U = self.rhoUk / self.rhok
self.V = self.rhoVk / self.rhok
self.p = (self.idealGas.gamma - 1) * (self.rhoEk - 0.5 * (
self.rhoUk * self.rhoUk + self.rhoVk * self.rhoVk) / self.rhok)
self.T = (self.p / (self.rhok * self.idealGas.R_gas))
self.mu = self.idealGas.mu_ref * (self.T /
self.idealGas.T_ref)**0.76
self.k = self.idealGas.cp * self.mu / self.idealGas.Pr
self.sos = np.sqrt(self.idealGas.gamma * self.p / self.rhok)
self.Amu = self.idealGas.solveAMu(self.T)
elif rkStep == 4:
self.U = self.rhoU1 / self.rho1
self.V = self.rhoV1 / self.rho1
self.p = (self.idealGas.gamma - 1) * (self.rhoE1 - 0.5 * (
self.rhoU1 * self.rhoU1 + self.rhoV1 * self.rhoV1) / self.rho1)
self.T = (self.p / (self.rho1 * self.idealGas.R_gas))
self.mu = self.idealGas.mu_ref * (self.T /
self.idealGas.T_ref)**0.76
self.k = self.idealGas.cp * self.mu / self.idealGas.Pr
self.sos = np.sqrt(self.idealGas.gamma * self.p / self.rho1)
self.Amu = self.idealGas.solveAMu(self.T)
def filterPrimativeValues(self):
if (self.timeStep % self.filterStep == 0):
self.numberOfFilterStep += 1
#Need to flip the order of the filtering every other time
if self.numberOfFilterStep % 2 == 0:
self.rho1 = self.filtX.filt_2D(self.rho2)
self.rhoU1 = self.filtX.filt_2D(self.rhoU2)
self.rhoV1 = self.filtX.filt_2D(self.rhoV2)
self.rhoE1 = self.filtX.filt_2D(self.rhoE2)
self.rho1 = self.filtY.filt_2D(self.rho1)
self.rhoU1 = self.filtY.filt_2D(self.rhoU1)
self.rhoV1 = self.filtY.filt_2D(self.rhoV1)
self.rhoE1 = self.filtY.filt_2D(self.rhoE1)
else:
self.rho1 = self.filtY.filt_2D(self.rho2)
self.rhoU1 = self.filtY.filt_2D(self.rhoU2)
self.rhoV1 = self.filtY.filt_2D(self.rhoV2)
self.rhoE1 = self.filtY.filt_2D(self.rhoE2)
self.rho1 = self.filtX.filt_2D(self.rho1)
self.rhoU1 = self.filtX.filt_2D(self.rhoU1)
self.rhoV1 = self.filtX.filt_2D(self.rhoV1)
self.rhoE1 = self.filtX.filt_2D(self.rhoE1)
print("Filtering...")
#Is there something here that needs to be done about corners for
#DIRICHLET/DIRICHLET, PERIODIC/DIRICHLET?
if self.bcXType == "DIRICHLET":
self.rho1[0, :] = self.rho2[0, :]
self.rho1[-1, :] = self.rho2[-1, :]
self.rhoU1[0, :] = self.rhoU2[0, :]
self.rhoU1[-1, :] = self.rhoU2[-1, :]
self.rhoV1[0, :] = self.rhoV2[0, :]
self.rhoV1[-1, :] = self.rhoV2[-1, :]
self.rhoE1[0, :] = self.rhoE2[0, :]
self.rhoE1[-1, :] = self.rhoE2[-1, :]
if self.bcYType == "DIRICHLET":
self.rho1[:, 0] = self.rho2[:, 0]
self.rho1[:, -1] = self.rho2[:, -1]
self.rhoU1[:, 0] = self.rhoU2[:, 0]
self.rhoU1[:, -1] = self.rhoU2[:, -1]
self.rhoV1[:, 0] = self.rhoV2[:, 0]
self.rhoV1[:, -1] = self.rhoV2[:, -1]
self.rhoE1[:, 0] = self.rhoE2[:, 0]
self.rhoE1[:, -1] = self.rhoE2[:, -1]
else:
self.rho1 = self.rho2
self.rhoU1 = self.rhoU2
self.rhoV1 = self.rhoV2
self.rhoE1 = self.rhoE2
def updateSponge(self):
if self.spongeFlag == True:
eps = 1.0 / (self.spongeBC.spongeAvgT / self.dt + 1.0)
self.spongeBC.spongeRhoAvg += eps * (self.rho1 -
self.spongeBC.spongeRhoAvg)
self.spongeBC.spongeRhoUAvg += eps * (self.rhoU1 -
self.spongeBC.spongeRhoUAvg)
self.spongeBC.spongeRhoVAvg += eps * (self.rhoV1 -
self.spongeBC.spongeRhoVAvg)
self.spongeBC.spongeRhoEAvg += eps * (self.rhoE1 -
self.spongeBC.spongeRhoEAvg)
self.spongeBC.spongeRhoEAvg = (
self.spongeBC.spongeEpsP * self.spongeBC.spongeRhoEAvg +
(1.0 - self.spongeBC.spongeEpsP) *
(self.spongeBC.spongeP / (self.idealGas.gamma - 1) + 0.5 *
(self.spongeBC.spongeRhoUAvg**2 + self.spongeBC.spongeRhoVAvg
**2) / self.spongeBC.spongeRhoAvg))
if self.bcX0 == "SPONGE":
self.rho1[0, :] = self.spongeBC.spongeRhoAvg[0, :]
self.rhoU1[0, :] = self.spongeBC.spongeRhoUAvg[0, :]
self.rhoV1[0, :] = self.spongeBC.spongeRhoVAvg[0, :]
self.rhoE1[0, :] = self.spongeBC.spongeRhoEAvg[0, :]
if self.bcX1 == "SPONGE":
self.rho1[-1, :] = self.spongeBC.spongeRhoAvg[-1, :]
self.rhoU1[-1, :] = self.spongeBC.spongeRhoUAvg[-1, :]
self.rhoV1[-1, :] = self.spongeBC.spongeRhoVAvg[-1, :]
self.rhoE1[-1, :] = self.spongeBC.spongeRhoEAvg[-1, :]
if self.bcY0 == "SPONGE":
self.rho1[:, 0] = self.spongeBC.spongeRhoAvg[:, 0]
self.rhoU1[:, 0] = self.spongeBC.spongeRhoUAvg[:, 0]
self.rhoV1[:, 0] = self.spongeBC.spongeRhoVAvg[:, 0]
self.rhoE1[:, 0] = self.spongeBC.spongeRhoEAvg[:, 0]
if self.bcY1 == "SPONGE":
self.rho1[:, -1] = self.spongeBC.spongeRhoAvg[:, -1]
self.rhoU1[:, -1] = self.spongeBC.spongeRhoUAvg[:, -1]
self.rhoV1[:, -1] = self.spongeBC.spongeRhoVAvg[:, -1]
self.rhoE1[:, -1] = self.spongeBC.spongeRhoEAvg[:, -1]
def plotFigure(self):
#plt.plot(self.x,self.rho1[:,0])
# plt.imshow(np.rot90(self.Vx[1:-2,1:-2] - self.Uy[1:-2,1:-2]), cmap="RdBu",interpolation='bicubic')
# plt.imshow(np.rot90(self.Ux[1:-2,1:-2] + self.Ux[1:-2,1:-2]), cmap="RdBu",interpolation='bicubic')
plt.imshow(np.rot90(self.V), cmap="RdBu", interpolation='bicubic')
plt.colorbar()
plt.axis("equal")
def checkSolution(self):
print(self.timeStep)
#Check if we've hit the end of the timestep condition
if self.timeStep >= self.maxTimeStep:
self.done = True
#Check if we've hit the end of the max time condition
if self.time >= self.maxTime:
self.done = True
if (self.timeStep % self.plotStep == 0):
drawnow(self.plotFigure)
print(self.timeStep)
if ((np.isnan(self.rhoE1)).any() == True
or (np.isnan(self.rho1)).any() == True
or (np.isnan(self.rhoU1)).any() == True):
self.done = True
print(-1)