323 lines
13 KiB
Fortran
323 lines
13 KiB
Fortran
!* $Id$
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!********************************************************************
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! Material subroutine for MSC.Marc
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!
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! written by P. Eisenlohr,
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! F. Roters,
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! L. Hantcherli,
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! W.A. Counts
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! D.D. Tjahjanto
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! C. Kords
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!
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! MPI fuer Eisenforschung, Duesseldorf
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!
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!********************************************************************
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! Usage:
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! - choose material as hypela2
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! - set statevariable 2 to index of homogenization
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! - set statevariable 3 to index of microstructure
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! - make sure the file "material.config" exists in the working
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! directory
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! - make sure the file "numerics.config" exists in the working
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! directory
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! - use nonsymmetric option for solver (e.g. direct
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! profile or multifrontal sparse, the latter seems
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! to be faster!)
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! - in case of ddm (domain decomposition)a SYMMETRIC
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! solver has to be used, i.e uncheck "non-symmetric"
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!********************************************************************
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! Marc subroutines used:
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! - hypela2
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! - plotv
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! - quit
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!********************************************************************
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! Marc common blocks included:
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! - concom: lovl, ncycle, inc, incsub
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! - creeps: timinc
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!********************************************************************
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!
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MODULE cpfem_interface
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CONTAINS
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subroutine mpie_cpfem_init
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write(6,*)
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write(6,*) '<<<+- mpie_cpfem_marc init -+>>>'
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write(6,*) '$Id$'
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write(6,*)
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return
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end subroutine
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END MODULE
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include "prec.f90" ! uses nothing else
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include "IO.f90" ! uses prec
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include "numerics.f90" ! uses prec, IO
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include "math.f90" ! uses prec, numerics
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include "debug.f90" ! uses prec, numerics
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include "FEsolving.f90" ! uses prec, IO
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include "mesh.f90" ! uses prec, math, IO, FEsolving
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include "material.f90" ! uses prec, math, IO, mesh
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include "lattice.f90" ! uses prec, math, IO, material
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include "constitutive_phenopowerlaw.f90" ! uses prec, math, IO, lattice, material, debug
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include "constitutive_j2.f90" ! uses prec, math, IO, lattice, material, debug
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include "constitutive_dislobased.f90" ! uses prec, math, IO, lattice, material, debug
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include "constitutive_nonlocal.f90" ! uses prec, math, IO, lattice, material, debug
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include "constitutive.f90" ! uses prec, IO, math, lattice, mesh, debug
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include "crystallite.f90" ! uses prec, math, IO, numerics
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include "homogenization_isostrain.f90" ! uses prec, math, IO,
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include "homogenization_RGC.f90" ! uses prec, math, IO, numerics, mesh: added <<<updated 31.07.2009>>>
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include "homogenization.f90" ! uses prec, math, IO, numerics
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include "CPFEM.f90" ! uses prec, math, IO, numerics, debug, FEsolving, mesh, lattice, constitutive, crystallite
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!********************************************************************
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! This is the Marc material routine
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!********************************************************************
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!
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! ************* user subroutine for defining material behavior **************
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!
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!
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! CAUTION : Due to calculation of the Deformation gradients, Stretch Tensors and
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! Rotation tensors at previous and current states, the analysis can be
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! computationally expensive. Please use the user subroutine -> hypela
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! if these kinematic quantities are not needed in the constitutive model
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!
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!
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! IMPORTANT NOTES :
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!
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! (1) F,R,U are only available for continuum and membrane elements (not for
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! shells and beams).
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!
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! (2) For total Lagrangian formulation use the -> 'Elasticity,1' card(=
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! total Lagrange with large disp) in the parameter section of input deck.
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! For updated Lagrangian formulation use the -> 'Plasticity,3' card(=
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! update+finite+large disp+constant d) in the parameter section of
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! input deck.
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!
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! The following operation obtains U (stretch tensor) at t=n+1 :
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!
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! call scla(un1,0.d0,itel,itel,1)
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! do 3 k=1,3
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! do 2 i=1,3
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! do 1 j=1,3
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! un1(i,j)=un1(i,j)+dsqrt(strechn1(k))*eigvn1(i,k)*eigvn1(j,k)
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!1 continue
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!2 continue
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!3 continue
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!
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!********************************************************************
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subroutine hypela2(&
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d,& ! stress strain law to be formed
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g,& ! change in stress due to temperature effects
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e,& ! total elastic strain
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de,& ! increment of strain
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s,& ! stress - should be updated by user
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t,& ! state variables (comes in at t=n, must be updated to have state variables at t=n+1)
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dt,& ! increment of state variables
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ngens,& ! size of stress - strain law
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n,& ! element number
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nn,& ! integration point number
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kcus,& ! (1) layer number, (2) internal layer number
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matus,& ! (1) user material identification number, (2) internal material identification number
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ndi,& ! number of direct components
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nshear,& ! number of shear components
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disp,& ! incremental displacements
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dispt,& ! displacements at t=n (at assembly, lovl=4) and displacements at t=n+1 (at stress recovery, lovl=6)
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coord,& ! coordinates
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ffn,& ! deformation gradient
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frotn,& ! rotation tensor
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strechn,& ! square of principal stretch ratios, lambda(i)
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eigvn,& ! i principal direction components for j eigenvalues
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ffn1,& ! deformation gradient
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frotn1,& ! rotation tensor
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strechn1,& ! square of principal stretch ratios, lambda(i)
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eigvn1,& ! i principal direction components for j eigenvalues
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ncrd,& ! number of coordinates
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itel,& ! dimension of F and R, either 2 or 3
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ndeg,& ! number of degrees of freedom ==> is this at correct list position ?!?
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ndm,& !
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nnode,& ! number of nodes per element
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jtype,& ! element type
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lclass,& ! element class
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ifr,& ! set to 1 if R has been calculated
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ifu & ! set to 1 if stretch has been calculated
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)
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use prec, only: pReal, &
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pInt
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use FEsolving, only: cycleCounter, &
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theInc, &
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theCycle, &
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theLovl, &
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theTime, &
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lastIncConverged, &
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outdatedByNewInc, &
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outdatedFFN1, &
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terminallyIll, &
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symmetricSolver
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use CPFEM, only: CPFEM_general
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use math, only: invnrmMandel
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use debug, only: debug_info, &
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debug_reset
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implicit none
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! ** Start of generated type statements **
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real(pReal) coord, d, de, disp, dispt, dt, e, eigvn, eigvn1, ffn, ffn1
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real(pReal) frotn, frotn1, g
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integer(pInt) ifr, ifu, itel, jtype, kcus, lclass, matus, n, ncrd, ndeg
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integer(pInt) ndi, ndm, ngens, nn, nnode, nshear
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real(pReal) s, strechn, strechn1, t
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! ** End of generated type statements **
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dimension e(*),de(*),t(*),dt(*),g(*),d(ngens,*),s(*), n(2),coord(ncrd,*),disp(ndeg,*),matus(2),dispt(ndeg,*),ffn(itel,*),&
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frotn(itel,*),strechn(itel),eigvn(itel,*),ffn1(itel,*),frotn1(itel,*),strechn1(itel),eigvn1(itel,*),kcus(2), lclass(2)
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! Marc common blocks are in fixed format so they have to be reformated to free format (f90)
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! Beware of changes in newer Marc versions
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include "concom%%MARCVERSION%%" ! concom is needed for inc, subinc, ncycle, lovl
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include "creeps%%MARCVERSION%%" ! creeps is needed for timinc (time increment)
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integer(pInt) computationMode, i
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if (inc == 0) then
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cycleCounter = 4
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else
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if (theCycle > ncycle .or. theInc /= inc) then
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cycleCounter = 0 ! reset counter for each cutback or new inc
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terminallyIll = .false.
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endif
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if (theCycle /= ncycle .or. theLovl /= lovl) then
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cycleCounter = cycleCounter+1 ! ping pong
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outdatedFFN1 = .false.
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write (6,*) n(1),nn,'cycleCounter',cycleCounter
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call debug_info() ! output of debugging/performance statistics of former
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call debug_reset()
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endif
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endif
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if (cptim > theTime .or. theInc /= inc) then ! reached convergence
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lastIncConverged = .true.
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outdatedByNewInc = .true.
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write (6,*) n(1),nn,'lastIncConverged + outdated'
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endif
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if (mod(cycleCounter,2) /= 0) computationMode = 4 ! recycle in odd cycles
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if (mod(cycleCounter,4) == 2) computationMode = 3 ! collect in 2,6,10,...
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if (mod(cycleCounter,4) == 0) computationMode = 2 ! compute in 0,4,8,...
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if (computationMode == 4 .and. ncycle == 0 .and. .not. lastIncConverged) &
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computationMode = 6 ! recycle but restore known good consistent tangent
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if (computationMode == 4 .and. lastIncConverged) then
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computationMode = 5 ! recycle and record former consistent tangent
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lastIncConverged = .false.
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endif
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if (computationMode == 2 .and. outdatedByNewInc) then
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computationMode = 1 ! compute and age former results
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outdatedByNewInc = .false.
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endif
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theTime = cptim ! record current starting time
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theInc = inc ! record current increment number
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theCycle = ncycle ! record current cycle count
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theLovl = lovl ! record current lovl
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call CPFEM_general(computationMode,ffn,ffn1,t(1),timinc,n(1),nn,s,d,ngens)
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! Mandel: 11, 22, 33, SQRT(2)*12, SQRT(2)*23, SQRT(2)*13
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! Marc: 11, 22, 33, 12, 23, 13
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forall(i=1:ngens) d(1:ngens,i) = invnrmMandel(i)*d(1:ngens,i)*invnrmMandel(1:ngens)
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s(1:ngens) = s(1:ngens)*invnrmMandel(1:ngens)
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if(symmetricSolver) d(1:ngens,1:ngens) = 0.5_pReal*(d(1:ngens,1:ngens)+transpose(d(1:ngens,1:ngens)))
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return
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end subroutine
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!********************************************************************
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! This routine sets user defined output variables for Marc
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!********************************************************************
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!
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! select a variable contour plotting (user subroutine).
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!
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!********************************************************************
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subroutine plotv(&
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v,& ! variable
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s,& ! stress array
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sp,& ! stresses in preferred direction
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etot,& ! total strain (generalized)
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eplas,& ! total plastic strain
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ecreep,& ! total creep strain
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t,& ! current temperature
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m,& ! element number
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nn,& ! integration point number
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layer,& ! layer number
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ndi,& ! number of direct stress components
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nshear,& ! number of shear stress components
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jpltcd & ! user variable index
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)
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use prec, only: pReal,pInt
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use mesh, only: mesh_FEasCP
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use homogenization, only: materialpoint_results
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implicit none
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real(pReal) s(*),etot(*),eplas(*),ecreep(*),sp(*)
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real(pReal) v, t(*)
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integer(pInt) m, nn, layer, ndi, nshear, jpltcd
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v = materialpoint_results(jpltcd,nn,mesh_FEasCP('elem', m))
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return
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end subroutine
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! subroutine utimestep(timestep,timestepold,icall,time,timeloadcase)
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!********************************************************************
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! This routine modifies the addaptive time step of Marc
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!********************************************************************
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! use prec, only: pReal,pInt
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! use CPFEM, only : CPFEM_timefactor_max
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! implicit none
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!
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! real(pReal) timestep, timestepold, time,timeloadcase
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! integer(pInt) icall
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!
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! user subroutine for modifying the time step in auto step
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!
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! timestep : the current time step as suggested by marc
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! to be modified in this routine
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! timestepold : the current time step before it was modified by marc
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! icall : =1 for setting the initial time step
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! =2 if this routine is called during an increment
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! =3 if this routine is called at the beginning
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! of the increment
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! time : time at the start of the current increment
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! timeloadcase: time period of the current load case
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!
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! it is in general not recommended to increase the time step
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! during the increment.
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! this routine is called right after the time step has (possibly)
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! been updated by marc.
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!
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! user coding
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! reduce timestep during increment in case mpie_timefactor is too large
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! if(icall==2_pInt) then
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! if(mpie_timefactor_max>1.25_pReal) then
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! timestep=min(timestep,timestepold*0.8_pReal)
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! end if
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! return
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! modify timestep at beginning of new increment
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! else if(icall==3_pInt) then
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! if(mpie_timefactor_max<=0.8_pReal) then
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! timestep=min(timestep,timestepold*1.25_pReal)
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! else if (mpie_timefactor_max<=1.0_pReal) then
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! timestep=min(timestep,timestepold/mpie_timefactor_max)
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! else if (mpie_timefactor_max<=1.25_pReal) then
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! timestep=min(timestep,timestepold*1.01_pReal)
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! else
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! timestep=min(timestep,timestepold*0.8_pReal)
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! end if
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! end if
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! return
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! end |