def __init__(self,nodalObject):
self.name='incompressible3d'
self.dependent=['ALL']
self.nonLinear=False
flowx=ad.Differentiate(ad.Multiply([nodalObject.material[0].properties['density'],nodalObject.variableCal['U']]),{'x':1})
flowy=ad.Differentiate(ad.Multiply([nodalObject.material[0].properties['density'],nodalObject.variableCal['V']]),{'y':1})
flowz=ad.Differentiate(ad.Multiply([nodalObject.material[0].properties['density'],nodalObject.variableCal['W']]),{'z':1})
self.result=ad.Addition([flowx,flowy,flowz])
def __init__(self,nodalObject):
self.name='incompressible4d'
self.dependent=['ALL']
self.nonLinear=False
desityChange=ad.Differentiate(nodalObject.material[0].properties['density'],{'t':1})
flowx=ad.Differentiate(nodalObject.material[0].properties['density']*nodalObject.variableCal['U'],{'x':1})
flowy=ad.Differentiate(nodalObject.material[0].properties['density']*nodalObject.variableCal['V'],{'y':1})
flowz=ad.Differentiate(nodalObject.material[0].properties['density']*nodalObject.variableCal['W'],{'z':1})
self.result=desityChange+flowx+flowy+flowz
def __init__(self,nodalObject,variableList,coordList):
self.name='incompressible4d'
self.dependent=['ALL']
self.nonLinear=False
desityChange=ad.Differentiate(nodalObject.material[0].properties['density'],{'t':1})
flow=[]
for n in range(len(coordList)):
flow.append(ad.Differentiate(nodalObject.material[0].properties['density']*nodalObject.variableCal[variableList[n]],{coordList[n]:1}))
flow.append(desityChange)
self.result=ad.Addition(flow)
def __init__(self,eqnName,nodalObject,solvingVariableIdentifier,diffusivityIdentifier,internalSourceEquation=None,externalSourceEquation=None):
self.name=eqnName
self.dependent=['ALL']
self.nonLinear=False
variation=ad.Differentiate(nodalObject.variableCal[solvingVariableIdentifier],{'t':1})
diffusion=ad.Multiply([ad.Addition([ad.Differentiate(nodalObject.variableCal[solvingVariableIdentifier],{'x':2}),
ad.Differentiate(nodalObject.variableCal[solvingVariableIdentifier],{'y':2}),
ad.Differentiate(nodalObject.variableCal[solvingVariableIdentifier],{'z':2})]),
-1.,
nodalObject.material[0].properties[diffusivityIdentifier]])
if internalSourceEquation!=None:
internalSource=internalSourceEquation(nodalObject)
else:
internalSource=0.
if externalSourceEquation!=None:
externalSource=ad.Multiply([-1.,externalSourceEquation(nodalObject)])
else:
externalSource=0.
self.result=ad.Addition([variation,diffusion,internalSource,externalSource])
def __init__(self,eqnName,nodalObject,convectionVariableIdentifier):
convectionU=ad.Multiply([nodalObject.variableCal['U'],ad.Conjugate(ad.Differentiate(nodalObject.variableCal[convectionVariableIdentifier],{'x':1}))])
convectionV=ad.Multiply([nodalObject.variableCal['V'],ad.Conjugate(ad.Differentiate(nodalObject.variableCal[convectionVariableIdentifier],{'y':1}))])
convectionW=ad.Multiply([nodalObject.variableCal['W'],ad.Conjugate(ad.Differentiate(nodalObject.variableCal[convectionVariableIdentifier],{'z':1}))])
convection=ad.Addition([convectionU,convectionV,convectionW])
def __init__(self,eqnName,nodalObject,variableIdentifier,add_dOrder):
self.name=eqnName
self.dependent=['ALL']
self.nonLinear=False
self.result=ad.Differentiate(nodalObject.variableCal[variableIdentifier],add_dOrder)