not needed as global variable
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@ -64,10 +64,6 @@ module constitutive
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real(pReal), dimension(:,:,:,:,:), allocatable, public :: &
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crystallite_partitionedF !< def grad to be reached at end of homog inc
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logical, dimension(:,:,:), allocatable :: &
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crystallite_converged !< convergence flag
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type :: tTensorContainer
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real(pReal), dimension(:,:,:), allocatable :: data
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end type
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@ -185,10 +181,10 @@ module constitutive
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! == cleaned:end ===================================================================================
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module function crystallite_stress(dt,co,ip,el)
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module function crystallite_stress(dt,co,ip,el) result(converged_)
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real(pReal), intent(in) :: dt
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integer, intent(in) :: co, ip, el
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logical :: crystallite_stress
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logical :: converged_
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end function crystallite_stress
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module function constitutive_homogenizedC(co,ip,el) result(C)
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@ -872,10 +868,8 @@ subroutine crystallite_init
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source = crystallite_partitionedF)
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allocate(crystallite_subdt(cMax,iMax,eMax),source=0.0_pReal)
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allocate(crystallite_orientation(cMax,iMax,eMax))
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allocate(crystallite_converged(cMax,iMax,eMax), source=.true.)
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num_crystallite => config_numerics%get('crystallite',defaultVal=emptyDict)
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@ -1253,7 +1247,7 @@ end function crystallite_push33ToRef
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!> @brief integrate stress, state with adaptive 1st order explicit Euler method
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!> using Fixed Point Iteration to adapt the stepsize
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!--------------------------------------------------------------------------------------------------
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subroutine integrateSourceState(co,ip,el)
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function integrateSourceState(co,ip,el) result(broken)
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integer, intent(in) :: &
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el, & !< element index in element loop
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@ -1273,12 +1267,13 @@ subroutine integrateSourceState(co,ip,el)
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r ! state residuum
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real(pReal), dimension(constitutive_source_maxSizeDotState,2,maxval(phase_Nsources)) :: source_dotState
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logical :: &
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broken
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broken, converged_
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ph = material_phaseAt(co,el)
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me = material_phaseMemberAt(co,ip,el)
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converged_ = .true.
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broken = constitutive_thermal_collectDotState(ph,me)
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broken = broken .or. constitutive_damage_collectDotState(crystallite_S(1:3,1:3,co,ip,el), co,ip,el,ph,me)
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if(broken) return
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@ -1313,19 +1308,20 @@ subroutine integrateSourceState(co,ip,el)
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- sourceState(ph)%p(so)%dotState (1:size_so(so),me) * crystallite_subdt(co,ip,el)
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sourceState(ph)%p(so)%state(1:size_so(so),me) = sourceState(ph)%p(so)%state(1:size_so(so),me) &
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- r(1:size_so(so))
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crystallite_converged(co,ip,el) = &
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crystallite_converged(co,ip,el) .and. converged(r(1:size_so(so)), &
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converged_ = converged_ .and. converged(r(1:size_so(so)), &
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sourceState(ph)%p(so)%state(1:size_so(so),me), &
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sourceState(ph)%p(so)%atol(1:size_so(so)))
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enddo
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if(crystallite_converged(co,ip,el)) then
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if(converged_) then
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broken = constitutive_damage_deltaState(crystallite_Fe(1:3,1:3,co,ip,el),co,ip,el,ph,me)
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exit iteration
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endif
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enddo iteration
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broken = broken .or. .not. converged_
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contains
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@ -1349,7 +1345,7 @@ subroutine integrateSourceState(co,ip,el)
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end function damper
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end subroutine integrateSourceState
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end function integrateSourceState
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!--------------------------------------------------------------------------------------------------
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@ -951,7 +951,7 @@ end function integrateStress
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!> @brief integrate stress, state with adaptive 1st order explicit Euler method
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!> using Fixed Point Iteration to adapt the stepsize
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!--------------------------------------------------------------------------------------------------
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subroutine integrateStateFPI(F_0,F,Delta_t,co,ip,el)
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function integrateStateFPI(F_0,F,Delta_t,co,ip,el) result(broken)
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real(pReal), intent(in),dimension(3,3) :: F_0,F
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real(pReal), intent(in) :: Delta_t
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@ -1004,11 +1004,7 @@ subroutine integrateStateFPI(F_0,F,Delta_t,co,ip,el)
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- plasticState(ph)%dotState (1:size_pl,me) * Delta_t
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plasticState(ph)%state(1:size_pl,me) = plasticState(ph)%state(1:size_pl,me) &
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- r(1:size_pl)
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crystallite_converged(co,ip,el) = converged(r(1:size_pl), &
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plasticState(ph)%state(1:size_pl,me), &
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plasticState(ph)%atol(1:size_pl))
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if(crystallite_converged(co,ip,el)) then
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if (converged(r(1:size_pl),plasticState(ph)%state(1:size_pl,me),plasticState(ph)%atol(1:size_pl))) then
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broken = constitutive_deltaState(crystallite_S(1:3,1:3,co,ip,el), &
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constitutive_mech_Fi(ph)%data(1:3,1:3,me),co,ip,el,ph,me)
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exit iteration
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@ -1016,7 +1012,6 @@ subroutine integrateStateFPI(F_0,F,Delta_t,co,ip,el)
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enddo iteration
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contains
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!--------------------------------------------------------------------------------------------------
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@ -1039,13 +1034,13 @@ subroutine integrateStateFPI(F_0,F,Delta_t,co,ip,el)
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end function damper
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end subroutine integrateStateFPI
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end function integrateStateFPI
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!--------------------------------------------------------------------------------------------------
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!> @brief integrate state with 1st order explicit Euler method
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!--------------------------------------------------------------------------------------------------
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subroutine integrateStateEuler(F_0,F,Delta_t,co,ip,el)
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function integrateStateEuler(F_0,F,Delta_t,co,ip,el) result(broken)
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real(pReal), intent(in),dimension(3,3) :: F_0,F
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real(pReal), intent(in) :: Delta_t
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@ -1075,15 +1070,14 @@ subroutine integrateStateEuler(F_0,F,Delta_t,co,ip,el)
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if(broken) return
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broken = integrateStress(F,Delta_t,co,ip,el)
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crystallite_converged(co,ip,el) = .not. broken
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end subroutine integrateStateEuler
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end function integrateStateEuler
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!--------------------------------------------------------------------------------------------------
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!> @brief integrate stress, state with 1st order Euler method with adaptive step size
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!--------------------------------------------------------------------------------------------------
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subroutine integrateStateAdaptiveEuler(F_0,F,Delta_t,co,ip,el)
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function integrateStateAdaptiveEuler(F_0,F,Delta_t,co,ip,el) result(broken)
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real(pReal), intent(in),dimension(3,3) :: F_0,F
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real(pReal), intent(in) :: Delta_t
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@ -1123,24 +1117,22 @@ subroutine integrateStateAdaptiveEuler(F_0,F,Delta_t,co,ip,el)
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broken = mech_collectDotState(Delta_t, co,ip,el,ph,me)
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if(broken) return
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sizeDotState = plasticState(ph)%sizeDotState
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crystallite_converged(co,ip,el) = converged(residuum_plastic(1:sizeDotState) &
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+ 0.5_pReal * plasticState(ph)%dotState(:,me) * Delta_t, &
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broken = .not. converged(residuum_plastic(1:sizeDotState) + 0.5_pReal * plasticState(ph)%dotState(:,me) * Delta_t, &
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plasticState(ph)%state(1:sizeDotState,me), &
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plasticState(ph)%atol(1:sizeDotState))
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end subroutine integrateStateAdaptiveEuler
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end function integrateStateAdaptiveEuler
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!---------------------------------------------------------------------------------------------------
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!> @brief Integrate state (including stress integration) with the classic Runge Kutta method
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!---------------------------------------------------------------------------------------------------
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subroutine integrateStateRK4(F_0,F,Delta_t,co,ip,el)
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function integrateStateRK4(F_0,F,Delta_t,co,ip,el) result(broken)
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real(pReal), intent(in),dimension(3,3) :: F_0,F
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real(pReal), intent(in) :: Delta_t
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integer, intent(in) :: co,ip,el
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logical :: broken
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real(pReal), dimension(3,3), parameter :: &
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A = reshape([&
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@ -1153,19 +1145,20 @@ subroutine integrateStateRK4(F_0,F,Delta_t,co,ip,el)
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real(pReal), dimension(4), parameter :: &
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B = [1.0_pReal/6.0_pReal, 1.0_pReal/3.0_pReal, 1.0_pReal/3.0_pReal, 1.0_pReal/6.0_pReal]
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call integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C)
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broken = integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C)
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end subroutine integrateStateRK4
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end function integrateStateRK4
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!---------------------------------------------------------------------------------------------------
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!> @brief Integrate state (including stress integration) with the Cash-Carp method
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!---------------------------------------------------------------------------------------------------
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subroutine integrateStateRKCK45(F_0,F,Delta_t,co,ip,el)
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function integrateStateRKCK45(F_0,F,Delta_t,co,ip,el) result(broken)
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real(pReal), intent(in),dimension(3,3) :: F_0,F
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real(pReal), intent(in) :: Delta_t
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integer, intent(in) :: co,ip,el
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logical :: broken
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real(pReal), dimension(5,5), parameter :: &
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A = reshape([&
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@ -1185,16 +1178,16 @@ subroutine integrateStateRKCK45(F_0,F,Delta_t,co,ip,el)
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[2825.0_pReal/27648.0_pReal, .0_pReal, 18575.0_pReal/48384.0_pReal,&
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13525.0_pReal/55296.0_pReal, 277.0_pReal/14336.0_pReal, 1._pReal/4._pReal]
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call integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB)
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broken = integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB)
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end subroutine integrateStateRKCK45
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end function integrateStateRKCK45
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!--------------------------------------------------------------------------------------------------
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!> @brief Integrate state (including stress integration) with an explicit Runge-Kutta method or an
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!! embedded explicit Runge-Kutta method
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!--------------------------------------------------------------------------------------------------
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subroutine integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB)
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function integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB) result(broken)
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real(pReal), intent(in),dimension(3,3) :: F_0,F
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real(pReal), intent(in) :: Delta_t
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@ -1205,6 +1198,7 @@ subroutine integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB)
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el, & !< element index in element loop
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ip, & !< integration point index in ip loop
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co !< grain index in grain loop
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logical :: broken
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integer :: &
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stage, & ! stage index in integration stage loop
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@ -1212,8 +1206,6 @@ subroutine integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB)
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ph, &
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me, &
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sizeDotState
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logical :: &
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broken
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real(pReal), dimension(constitutive_plasticity_maxSizeDotState,size(B)) :: plastic_RKdotState
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@ -1266,10 +1258,8 @@ subroutine integrateStateRK(F_0,F,Delta_t,co,ip,el,A,B,C,DB)
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if(broken) return
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broken = integrateStress(F,Delta_t,co,ip,el)
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crystallite_converged(co,ip,el) = .not. broken
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end subroutine integrateStateRK
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end function integrateStateRK
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!--------------------------------------------------------------------------------------------------
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@ -1479,15 +1469,14 @@ end function constitutive_homogenizedC
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!--------------------------------------------------------------------------------------------------
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!> @brief calculate stress (P)
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!--------------------------------------------------------------------------------------------------
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module function crystallite_stress(dt,co,ip,el)
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module function crystallite_stress(dt,co,ip,el) result(converged_)
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real(pReal), intent(in) :: dt
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integer, intent(in) :: &
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co, &
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ip, &
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el
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logical :: crystallite_stress
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logical :: converged_
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real(pReal) :: &
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formerSubStep
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@ -1519,7 +1508,7 @@ module function crystallite_stress(dt,co,ip,el)
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subFrac = 0.0_pReal
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subStep = 1.0_pReal/num%subStepSizeCryst
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todo = .true.
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crystallite_converged(co,ip,el) = .false. ! pretend failed step of 1/subStepSizeCryst
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converged_ = .false. ! pretend failed step of 1/subStepSizeCryst
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todo = .true.
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NiterationCrystallite = 0
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@ -1528,7 +1517,7 @@ module function crystallite_stress(dt,co,ip,el)
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!--------------------------------------------------------------------------------------------------
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! wind forward
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if (crystallite_converged(co,ip,el)) then
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if (converged_) then
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formerSubStep = subStep
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subFrac = subFrac + subStep
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subStep = min(1.0_pReal - subFrac, num%stepIncreaseCryst * subStep)
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@ -1579,17 +1568,13 @@ module function crystallite_stress(dt,co,ip,el)
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math_inv33(matmul(constitutive_mech_Fi(ph)%data(1:3,1:3,me), &
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constitutive_mech_Fp(ph)%data(1:3,1:3,me))))
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crystallite_subdt(co,ip,el) = subStep * dt
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crystallite_converged(co,ip,el) = .false.
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call integrateState(subF0,crystallite_subF(1:3,1:3,co,ip,el),&
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converged_ = .not. integrateState(subF0,crystallite_subF(1:3,1:3,co,ip,el),&
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crystallite_subdt(co,ip,el),co,ip,el)
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call integrateSourceState(co,ip,el)
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converged_ = converged_ .and. .not. integrateSourceState(co,ip,el)
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endif
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enddo cutbackLooping
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! return whether converged or not
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crystallite_stress = crystallite_converged(co,ip,el)
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end function crystallite_stress
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end submodule constitutive_mech
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