Metafor

ULiege - Aerospace & Mechanical Engineering

User Tools

Site Tools


doc:user:integration:general:mim_tim

This is an old revision of the document!


Managing N.-R. Iterations

Mechanical iterations parameters are imposed by functions associated to metafor.getMechanicalIterationManager(), when thermal iterations parameters are imposed by functions associated to metafor.getThermalIterationManager().

  mim = metafor.getMechanicalIterationManager() 
  tim = metafor.getThermalIterationManager()
  
  mim/tim.setResidualComputationMethod(meth)    
  mim/tim.setVerbose()     
  mim/tim.setResidualTolerance(prec)
  mim/tim.setMaxNbOfIterations(itma)
  mim/tim.setNbOfIterationsForStiffUpdate(irea)
  mim/tim.setMaxNbOfLineSearchIterations(lsma)
  mim/tim.setLineSearchTolerance1(lsp1)
  mim/tim.setLineSearchTolerance2(lsp2)
  mim.setPredictorComputationMethod(predMeth)
  mim.setConstrainedDofsVAComputationMethod(VACMeth)
  mim/tim.setPreviousResidualsDecreaseCriterion()
  mim/tim.setCpuDependency(cpuDep)

where meth defines the method used to compute the $Residual$.

Method1RedisualComputation(limitNormFactor)

The residual is adimensionalized by the norm of external forces and internal reactions (default value). First :

$$Rmin = \frac{||FreeExternalForces|| + ||CstrInternalForces||+||CstrInertialForces||}{nreac} $$

If $$ Rmin < limitNormFactor $$

$Rmin$ is set to $$ Rmin = limitNormFactor $$

and the residual is adimensionalized :

$$Residual = \frac{||FreeResidual||}{ndofs*Rmin}$$

where

$ndofs$ : total number of degrees of freedom

$nreac$ : number of fixed degrees of freedom (having an associated reaction)

Method2ResidualComputation(limitNormFactor)

The residual is adimensionalized by the square of the norm of external forces and internal reactions. First:

$$Rmin = \frac{\sqrt{||FreeExternalForces||^2 + ||CstrInternalForces||^2+||CstrInertialForces||^2}}{nreac}$$

If $$ Rmin < limitNormFactor $$ then $$ Rmin = limitNormFactor $$

and the residual is adimensionalized :

$$Residual = \frac{||FreeResidual||}{ndofs*Rmin}$$

where

$ndofs$ : total number of degrees of freedom

$nreac$ : number of fixed degrees of freedom (having an associated reaction)

Method3ResidualComputation(limitNormFactor)

The residual is adimensionalized by the norm of external and inertial forces, and internal reactions (value to use preferentially for thermal simulations. Careful, the user must define it).

If $$ ||FreeExternalForces|| < limitNormFactor $$ then $$ Residual = max(|FreeResidual|) $$ Else, $$Rmin = ||FreeExternalForces|| + ||CstrInternalForces||+||CstrInertialForces|| $$ and $$Residual = \frac{||FreeResidual||}{ndofs*Rmin}$$

Method4ResidualComputation(limitNormFactor)

This method is the same as Method1ResidualComputation() but without dividing by the number of dofs, so

$$Rmin = ||FreeExternalForces|| + ||CstrInternalForces||+||CstrInertialForces|| $$

If $$ Rmin < limitNormFactor$$ then $$ Rmin = limitNormFactor $$

and the residual is adimensionalized :

$$Residual = \frac{||FreeResidual||}{Rmin}$$

Method5ResidualComputation(adimFactor)

The residual is adimensionalized by the factor adimFactor, given by the user, without dividing by the number of dofs.

$$Residual = \frac{||FreeResidual||}{adimFactor }$$

Method6ResidualComputation(adimFactor)

The residual is adimensionalized by the factor adimFactor, given by the user, and by the number of dofs. $$Residual = \frac{||FreeResidual||}{ndofs * adimFactor }$$

where

$ndofs$ : total number of dofs

Parameters

Parameter Default value Description
limitNormFactor 1.0 Value from which the residual is no longer divided by $$Rmin$$ (to adjust as a function of the loading using verbose output)
adimFactor - Fixed adimensionalization factor for methods #5 and 6 (no default value, the factor must be defined for these methods)
prec 1.0E-4 accuracy that the residual must reach
itma 7 maximal number of Newton-Raphson iterations (this number if corrected internally if the automatic criterion is used to update the matrix). Iterations are stopped if the residual does not decrease over 6 iterations
irea 1 = 1 : stiffness matrix updated for each iteration
> 1 : stiffness matrix is updated automatically if the iteration number is lower than irea. The criterion is based on a convergence speed and a CPU time ratio (requires MDE_ICPU=1)
lsma 0 maximal line-search iteration number
lsp1 1.0 accuracy that the line-search residual must reach
lsp2 1.E-8 stop criterion when the line search parameter is not updated enough
predMeth EXTRAPOLATION_DEFAULT EXTRAPOLATION_DEFAULT = Extrapolation of the scheme by default (for example method to compute the displacement predictor by Newmark formula in the case of alpha-generalized scheme)
EXTRAPOLATION_MRUA = method to compute the displacement predictor by MRUA formula (for now only possible for alpha-generalized algorithms)
EXTRAPOLATION_ZERO = New positions are equal to the old ones, speed (and acceleration for dynamic schemes) equal to zero (for now only possible for quasi-static algorithms and alpha-generalized algorithms) .
VACMeth VAC_SCHEMECONSISTANT VAC_SCHEMECONSISTANT : Calculation of speed and acceleration with Newmark formula
VAC_BACKWARDEULER : Calculation of speed and acceleration using Backward Euler (to stabilize Newmark with dofs with a non zero fixed displacement. See JPP's thesis pg VIII.28)
cpuDep “False” Specify if the criterion for updating the stiffness matrix (irea > 1) depends on the User CPU time. (Metafor Version > 2422)
doc/user/integration/general/mim_tim.1444400697.txt.gz · Last modified: 2016/03/30 15:22 (external edit)

Donate Powered by PHP Valid HTML5 Valid CSS Driven by DokuWiki