!-------------------------------------------------------------------------------------------------- !> @author Martin Diehl, Max-Planck-Institut für Eisenforschung GmbH !> @author Pratheek Shanthraj, Max-Planck-Institut für Eisenforschung GmbH !> @author Franz Roters, Max-Planck-Institut für Eisenforschung GmbH !> @author Philip Eisenlohr, Max-Planck-Institut für Eisenforschung GmbH !> @author Christoph Kords, Max-Planck-Institut für Eisenforschung GmbH !> @author Chen Zhang, Michigan State University !> @brief crystallite state integration functions and reporting of results !-------------------------------------------------------------------------------------------------- module crystallite use prec use IO use config use debug use numerics use rotations use math use FEsolving use material use constitutive use discretization use lattice use results implicit none private real(pReal), dimension(:,:,:), allocatable, public :: & crystallite_dt !< requested time increment of each grain real(pReal), dimension(:,:,:), allocatable :: & crystallite_subdt, & !< substepped time increment of each grain crystallite_subFrac, & !< already calculated fraction of increment crystallite_subStep !< size of next integration step type(rotation), dimension(:,:,:), allocatable :: & crystallite_orientation !< current orientation real(pReal), dimension(:,:,:,:,:), allocatable, public, protected :: & crystallite_Fe, & !< current "elastic" def grad (end of converged time step) crystallite_P !< 1st Piola-Kirchhoff stress per grain real(pReal), dimension(:,:,:,:,:), allocatable, public :: & crystallite_S, & !< current 2nd Piola-Kirchhoff stress vector (end of converged time step) crystallite_S0, & !< 2nd Piola-Kirchhoff stress vector at start of FE inc crystallite_partionedS0, & !< 2nd Piola-Kirchhoff stress vector at start of homog inc crystallite_Fp, & !< current plastic def grad (end of converged time step) crystallite_Fp0, & !< plastic def grad at start of FE inc crystallite_partionedFp0,& !< plastic def grad at start of homog inc crystallite_Fi, & !< current intermediate def grad (end of converged time step) crystallite_Fi0, & !< intermediate def grad at start of FE inc crystallite_partionedFi0,& !< intermediate def grad at start of homog inc crystallite_F0, & !< def grad at start of FE inc crystallite_partionedF, & !< def grad to be reached at end of homog inc crystallite_partionedF0, & !< def grad at start of homog inc crystallite_Lp, & !< current plastic velocitiy grad (end of converged time step) crystallite_Lp0, & !< plastic velocitiy grad at start of FE inc crystallite_partionedLp0, & !< plastic velocity grad at start of homog inc crystallite_Li, & !< current intermediate velocitiy grad (end of converged time step) crystallite_Li0, & !< intermediate velocitiy grad at start of FE inc crystallite_partionedLi0 !< intermediate velocity grad at start of homog inc real(pReal), dimension(:,:,:,:,:), allocatable :: & crystallite_subS0, & !< 2nd Piola-Kirchhoff stress vector at start of crystallite inc crystallite_invFp, & !< inverse of current plastic def grad (end of converged time step) crystallite_subFp0,& !< plastic def grad at start of crystallite inc crystallite_invFi, & !< inverse of current intermediate def grad (end of converged time step) crystallite_subFi0,& !< intermediate def grad at start of crystallite inc crystallite_subF, & !< def grad to be reached at end of crystallite inc crystallite_subF0, & !< def grad at start of crystallite inc crystallite_subLp0,& !< plastic velocity grad at start of crystallite inc crystallite_subLi0 !< intermediate velocity grad at start of crystallite inc real(pReal), dimension(:,:,:,:,:,:,:), allocatable, public :: & crystallite_dPdF !< current individual dPdF per grain (end of converged time step) logical, dimension(:,:,:), allocatable, public :: & crystallite_requested !< used by upper level (homogenization) to request crystallite calculation logical, dimension(:,:,:), allocatable :: & crystallite_converged, & !< convergence flag crystallite_todo, & !< flag to indicate need for further computation crystallite_localPlasticity !< indicates this grain to have purely local constitutive law type :: tOutput !< new requested output (per phase) character(len=pStringLen), allocatable, dimension(:) :: & label end type tOutput type(tOutput), allocatable, dimension(:) :: output_constituent type :: tNumerics integer :: & iJacoLpresiduum, & !< frequency of Jacobian update of residuum in Lp nState, & !< state loop limit nStress !< stress loop limit real(pReal) :: & subStepMinCryst, & !< minimum (relative) size of sub-step allowed during cutback subStepSizeCryst, & !< size of first substep when cutback subStepSizeLp, & !< size of first substep when cutback in Lp calculation subStepSizeLi, & !< size of first substep when cutback in Li calculation stepIncreaseCryst, & !< increase of next substep size when previous substep converged rTol_crystalliteState, & !< relative tolerance in state loop rTol_crystalliteStress, & !< relative tolerance in stress loop aTol_crystalliteStress !< absolute tolerance in stress loop end type tNumerics type(tNumerics) :: num ! numerics parameters. Better name? procedure(), pointer :: integrateState public :: & crystallite_init, & crystallite_stress, & crystallite_stressTangent, & crystallite_orientations, & crystallite_push33ToRef, & crystallite_results contains !-------------------------------------------------------------------------------------------------- !> @brief allocates and initialize per grain variables !-------------------------------------------------------------------------------------------------- subroutine crystallite_init logical, dimension(discretization_nIP,discretization_nElem) :: devNull integer :: & c, & !< counter in integration point component loop i, & !< counter in integration point loop e, & !< counter in element loop cMax, & !< maximum number of integration point components iMax, & !< maximum number of integration points eMax, & !< maximum number of elements myNcomponents !< number of components at current IP write(6,'(/,a)') ' <<<+- crystallite init -+>>>' cMax = homogenization_maxNgrains iMax = discretization_nIP eMax = discretization_nElem allocate(crystallite_S0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedS0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_S(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subS0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_P(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_F0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedF0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedF(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subF0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subF(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Fp0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedFp0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subFp0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Fp(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_invFp(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Fi0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedFi0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subFi0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Fi(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_invFi(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Fe(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Lp0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedLp0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subLp0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Lp(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Li0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_partionedLi0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subLi0(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_Li(3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_dPdF(3,3,3,3,cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_dt(cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subdt(cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subFrac(cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_subStep(cMax,iMax,eMax), source=0.0_pReal) allocate(crystallite_orientation(cMax,iMax,eMax)) allocate(crystallite_localPlasticity(cMax,iMax,eMax), source=.true.) allocate(crystallite_requested(cMax,iMax,eMax), source=.false.) allocate(crystallite_todo(cMax,iMax,eMax), source=.false.) allocate(crystallite_converged(cMax,iMax,eMax), source=.true.) num%subStepMinCryst = config_numerics%getFloat('substepmincryst', defaultVal=1.0e-3_pReal) num%subStepSizeCryst = config_numerics%getFloat('substepsizecryst', defaultVal=0.25_pReal) num%stepIncreaseCryst = config_numerics%getFloat('stepincreasecryst', defaultVal=1.5_pReal) num%subStepSizeLp = config_numerics%getFloat('substepsizelp', defaultVal=0.5_pReal) num%subStepSizeLi = config_numerics%getFloat('substepsizeli', defaultVal=0.5_pReal) num%rTol_crystalliteState = config_numerics%getFloat('rtol_crystallitestate', defaultVal=1.0e-6_pReal) num%rTol_crystalliteStress = config_numerics%getFloat('rtol_crystallitestress',defaultVal=1.0e-6_pReal) num%aTol_crystalliteStress = config_numerics%getFloat('atol_crystallitestress',defaultVal=1.0e-8_pReal) num%iJacoLpresiduum = config_numerics%getInt ('ijacolpresiduum', defaultVal=1) num%nState = config_numerics%getInt ('nstate', defaultVal=20) num%nStress = config_numerics%getInt ('nstress', defaultVal=40) if(num%subStepMinCryst <= 0.0_pReal) call IO_error(301,ext_msg='subStepMinCryst') if(num%subStepSizeCryst <= 0.0_pReal) call IO_error(301,ext_msg='subStepSizeCryst') if(num%stepIncreaseCryst <= 0.0_pReal) call IO_error(301,ext_msg='stepIncreaseCryst') if(num%subStepSizeLp <= 0.0_pReal) call IO_error(301,ext_msg='subStepSizeLp') if(num%subStepSizeLi <= 0.0_pReal) call IO_error(301,ext_msg='subStepSizeLi') if(num%rTol_crystalliteState <= 0.0_pReal) call IO_error(301,ext_msg='rTol_crystalliteState') if(num%rTol_crystalliteStress <= 0.0_pReal) call IO_error(301,ext_msg='rTol_crystalliteStress') if(num%aTol_crystalliteStress <= 0.0_pReal) call IO_error(301,ext_msg='aTol_crystalliteStress') if(num%iJacoLpresiduum < 1) call IO_error(301,ext_msg='iJacoLpresiduum') if(num%nState < 1) call IO_error(301,ext_msg='nState') if(num%nStress< 1) call IO_error(301,ext_msg='nStress') select case(numerics_integrator) case(1) integrateState => integrateStateFPI case(2) integrateState => integrateStateEuler case(3) integrateState => integrateStateAdaptiveEuler case(4) integrateState => integrateStateRK4 case(5) integrateState => integrateStateRKCK45 end select allocate(output_constituent(size(config_phase))) do c = 1, size(config_phase) #if defined(__GFORTRAN__) allocate(output_constituent(c)%label(1)) output_constituent(c)%label(1)= 'GfortranBug86277' output_constituent(c)%label = config_phase(c)%getStrings('(output)',defaultVal=output_constituent(c)%label ) if (output_constituent(c)%label (1) == 'GfortranBug86277') output_constituent(c)%label = [character(len=pStringLen)::] #else output_constituent(c)%label = config_phase(c)%getStrings('(output)',defaultVal=[character(len=pStringLen)::]) #endif enddo call config_deallocate('material.config/phase') !-------------------------------------------------------------------------------------------------- ! initialize !$OMP PARALLEL DO PRIVATE(myNcomponents,i,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) myNcomponents = homogenization_Ngrains(material_homogenizationAt(e)) do i = FEsolving_execIP(1), FEsolving_execIP(2); do c = 1, myNcomponents crystallite_Fp0(1:3,1:3,c,i,e) = material_orientation0(c,i,e)%asMatrix() ! plastic def gradient reflects init orientation crystallite_Fp0(1:3,1:3,c,i,e) = crystallite_Fp0(1:3,1:3,c,i,e) & / math_det33(crystallite_Fp0(1:3,1:3,c,i,e))**(1.0_pReal/3.0_pReal) crystallite_Fi0(1:3,1:3,c,i,e) = constitutive_initialFi(c,i,e) crystallite_F0(1:3,1:3,c,i,e) = math_I3 crystallite_localPlasticity(c,i,e) = phase_localPlasticity(material_phaseAt(c,e)) crystallite_Fe(1:3,1:3,c,i,e) = math_inv33(matmul(crystallite_Fi0(1:3,1:3,c,i,e), & crystallite_Fp0(1:3,1:3,c,i,e))) ! assuming that euler angles are given in internal strain free configuration crystallite_Fp(1:3,1:3,c,i,e) = crystallite_Fp0(1:3,1:3,c,i,e) crystallite_Fi(1:3,1:3,c,i,e) = crystallite_Fi0(1:3,1:3,c,i,e) crystallite_requested(c,i,e) = .true. enddo; enddo enddo !$OMP END PARALLEL DO if(any(.not. crystallite_localPlasticity) .and. .not. usePingPong) call IO_error(601) ! exit if nonlocal but no ping-pong ToDo: Why not check earlier? or in nonlocal? crystallite_partionedFp0 = crystallite_Fp0 crystallite_partionedFi0 = crystallite_Fi0 crystallite_partionedF0 = crystallite_F0 crystallite_partionedF = crystallite_F0 call crystallite_orientations() !$OMP PARALLEL DO do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do c = 1,homogenization_Ngrains(material_homogenizationAt(e)) call constitutive_dependentState(crystallite_partionedF0(1:3,1:3,c,i,e), & crystallite_partionedFp0(1:3,1:3,c,i,e), & c,i,e) ! update dependent state variables to be consistent with basic states enddo enddo enddo !$OMP END PARALLEL DO devNull = crystallite_stress() call crystallite_stressTangent #ifdef DEBUG if (iand(debug_level(debug_crystallite), debug_levelBasic) /= 0) then write(6,'(a42,1x,i10)') ' # of elements: ', eMax write(6,'(a42,1x,i10)') 'max # of integration points/element: ', iMax write(6,'(a42,1x,i10)') 'max # of constituents/integration point: ', cMax write(6,'(a42,1x,i10)') ' # of nonlocal constituents: ',count(.not. crystallite_localPlasticity) flush(6) endif call debug_info call debug_reset #endif end subroutine crystallite_init !-------------------------------------------------------------------------------------------------- !> @brief calculate stress (P) !-------------------------------------------------------------------------------------------------- function crystallite_stress(dummyArgumentToPreventInternalCompilerErrorWithGCC) logical, dimension(discretization_nIP,discretization_nElem) :: crystallite_stress real(pReal), intent(in), optional :: & dummyArgumentToPreventInternalCompilerErrorWithGCC real(pReal) :: & formerSubStep integer :: & NiterationCrystallite, & ! number of iterations in crystallite loop c, & !< counter in integration point component loop i, & !< counter in integration point loop e, & !< counter in element loop startIP, endIP, & s #ifdef DEBUG if (iand(debug_level(debug_crystallite),debug_levelSelective) /= 0 & .and. FEsolving_execElem(1) <= debug_e & .and. debug_e <= FEsolving_execElem(2)) then write(6,'(/,a,i8,1x,i2,1x,i3)') '<< CRYST stress >> boundary and initial values at el ip ipc ', & debug_e,debug_i, debug_g write(6,'(a,/,3(12x,3(f14.9,1x)/))') '<< CRYST stress >> F ', & transpose(crystallite_partionedF(1:3,1:3,debug_g,debug_i,debug_e)) write(6,'(a,/,3(12x,3(f14.9,1x)/))') '<< CRYST stress >> F0 ', & transpose(crystallite_partionedF0(1:3,1:3,debug_g,debug_i,debug_e)) write(6,'(a,/,3(12x,3(f14.9,1x)/))') '<< CRYST stress >> Fp0', & transpose(crystallite_partionedFp0(1:3,1:3,debug_g,debug_i,debug_e)) write(6,'(a,/,3(12x,3(f14.9,1x)/))') '<< CRYST stress >> Fi0', & transpose(crystallite_partionedFi0(1:3,1:3,debug_g,debug_i,debug_e)) write(6,'(a,/,3(12x,3(f14.9,1x)/))') '<< CRYST stress >> Lp0', & transpose(crystallite_partionedLp0(1:3,1:3,debug_g,debug_i,debug_e)) write(6,'(a,/,3(12x,3(f14.9,1x)/))') '<< CRYST stress >> Li0', & transpose(crystallite_partionedLi0(1:3,1:3,debug_g,debug_i,debug_e)) endif #endif !-------------------------------------------------------------------------------------------------- ! initialize to starting condition crystallite_subStep = 0.0_pReal !$OMP PARALLEL DO elementLooping1: do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2); do c = 1,homogenization_Ngrains(material_homogenizationAt(e)) homogenizationRequestsCalculation: if (crystallite_requested(c,i,e)) then plasticState (material_phaseAt(c,e))%subState0( :,material_phaseMemberAt(c,i,e)) = & plasticState (material_phaseAt(c,e))%partionedState0(:,material_phaseMemberAt(c,i,e)) do s = 1, phase_Nsources(material_phaseAt(c,e)) sourceState(material_phaseAt(c,e))%p(s)%subState0( :,material_phaseMemberAt(c,i,e)) = & sourceState(material_phaseAt(c,e))%p(s)%partionedState0(:,material_phaseMemberAt(c,i,e)) enddo crystallite_subFp0(1:3,1:3,c,i,e) = crystallite_partionedFp0(1:3,1:3,c,i,e) crystallite_subLp0(1:3,1:3,c,i,e) = crystallite_partionedLp0(1:3,1:3,c,i,e) crystallite_subFi0(1:3,1:3,c,i,e) = crystallite_partionedFi0(1:3,1:3,c,i,e) crystallite_subLi0(1:3,1:3,c,i,e) = crystallite_partionedLi0(1:3,1:3,c,i,e) crystallite_subF0(1:3,1:3,c,i,e) = crystallite_partionedF0(1:3,1:3,c,i,e) crystallite_subS0(1:3,1:3,c,i,e) = crystallite_partionedS0(1:3,1:3,c,i,e) crystallite_subFrac(c,i,e) = 0.0_pReal crystallite_subStep(c,i,e) = 1.0_pReal/num%subStepSizeCryst crystallite_todo(c,i,e) = .true. crystallite_converged(c,i,e) = .false. ! pretend failed step of 1/subStepSizeCryst endif homogenizationRequestsCalculation enddo; enddo enddo elementLooping1 !$OMP END PARALLEL DO singleRun: if (FEsolving_execELem(1) == FEsolving_execElem(2) .and. & FEsolving_execIP (1) == FEsolving_execIP (2)) then startIP = FEsolving_execIP(1) endIP = startIP else singleRun startIP = 1 endIP = discretization_nIP endif singleRun NiterationCrystallite = 0 cutbackLooping: do while (any(crystallite_todo(:,startIP:endIP,FEsolving_execELem(1):FEsolving_execElem(2)))) NiterationCrystallite = NiterationCrystallite + 1 #ifdef DEBUG if (iand(debug_level(debug_crystallite),debug_levelExtensive) /= 0) & write(6,'(a,i6)') '<< CRYST stress >> crystallite iteration ',NiterationCrystallite #endif !$OMP PARALLEL DO PRIVATE(formerSubStep) elementLooping3: do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do c = 1,homogenization_Ngrains(material_homogenizationAt(e)) !-------------------------------------------------------------------------------------------------- ! wind forward if (crystallite_converged(c,i,e)) then formerSubStep = crystallite_subStep(c,i,e) crystallite_subFrac(c,i,e) = crystallite_subFrac(c,i,e) + crystallite_subStep(c,i,e) crystallite_subStep(c,i,e) = min(1.0_pReal - crystallite_subFrac(c,i,e), & num%stepIncreaseCryst * crystallite_subStep(c,i,e)) crystallite_todo(c,i,e) = crystallite_subStep(c,i,e) > 0.0_pReal ! still time left to integrate on? if (crystallite_todo(c,i,e)) then crystallite_subF0 (1:3,1:3,c,i,e) = crystallite_subF(1:3,1:3,c,i,e) crystallite_subLp0(1:3,1:3,c,i,e) = crystallite_Lp (1:3,1:3,c,i,e) crystallite_subLi0(1:3,1:3,c,i,e) = crystallite_Li (1:3,1:3,c,i,e) crystallite_subFp0(1:3,1:3,c,i,e) = crystallite_Fp (1:3,1:3,c,i,e) crystallite_subFi0(1:3,1:3,c,i,e) = crystallite_Fi (1:3,1:3,c,i,e) crystallite_subS0 (1:3,1:3,c,i,e) = crystallite_S (1:3,1:3,c,i,e) !if abbrevation, make c and p private in omp plasticState( material_phaseAt(c,e))%subState0(:,material_phaseMemberAt(c,i,e)) & = plasticState(material_phaseAt(c,e))%state( :,material_phaseMemberAt(c,i,e)) do s = 1, phase_Nsources(material_phaseAt(c,e)) sourceState( material_phaseAt(c,e))%p(s)%subState0(:,material_phaseMemberAt(c,i,e)) & = sourceState(material_phaseAt(c,e))%p(s)%state( :,material_phaseMemberAt(c,i,e)) enddo endif !-------------------------------------------------------------------------------------------------- ! cut back (reduced time and restore) else crystallite_subStep(c,i,e) = num%subStepSizeCryst * crystallite_subStep(c,i,e) crystallite_Fp (1:3,1:3,c,i,e) = crystallite_subFp0(1:3,1:3,c,i,e) crystallite_invFp(1:3,1:3,c,i,e) = math_inv33(crystallite_Fp (1:3,1:3,c,i,e)) crystallite_Fi (1:3,1:3,c,i,e) = crystallite_subFi0(1:3,1:3,c,i,e) crystallite_invFi(1:3,1:3,c,i,e) = math_inv33(crystallite_Fi (1:3,1:3,c,i,e)) crystallite_S (1:3,1:3,c,i,e) = crystallite_S0 (1:3,1:3,c,i,e) if (crystallite_subStep(c,i,e) < 1.0_pReal) then ! actual (not initial) cutback crystallite_Lp (1:3,1:3,c,i,e) = crystallite_subLp0(1:3,1:3,c,i,e) crystallite_Li (1:3,1:3,c,i,e) = crystallite_subLi0(1:3,1:3,c,i,e) endif plasticState (material_phaseAt(c,e))%state( :,material_phaseMemberAt(c,i,e)) & = plasticState(material_phaseAt(c,e))%subState0(:,material_phaseMemberAt(c,i,e)) do s = 1, phase_Nsources(material_phaseAt(c,e)) sourceState( material_phaseAt(c,e))%p(s)%state( :,material_phaseMemberAt(c,i,e)) & = sourceState(material_phaseAt(c,e))%p(s)%subState0(:,material_phaseMemberAt(c,i,e)) enddo ! cant restore dotState here, since not yet calculated in first cutback after initialization crystallite_todo(c,i,e) = crystallite_subStep(c,i,e) > num%subStepMinCryst ! still on track or already done (beyond repair) endif !-------------------------------------------------------------------------------------------------- ! prepare for integration if (crystallite_todo(c,i,e)) then crystallite_subF(1:3,1:3,c,i,e) = crystallite_subF0(1:3,1:3,c,i,e) & + crystallite_subStep(c,i,e) * (crystallite_partionedF (1:3,1:3,c,i,e) & - crystallite_partionedF0(1:3,1:3,c,i,e)) crystallite_Fe(1:3,1:3,c,i,e) = matmul(matmul(crystallite_subF (1:3,1:3,c,i,e), & crystallite_invFp(1:3,1:3,c,i,e)), & crystallite_invFi(1:3,1:3,c,i,e)) crystallite_subdt(c,i,e) = crystallite_subStep(c,i,e) * crystallite_dt(c,i,e) crystallite_converged(c,i,e) = .false. endif enddo enddo enddo elementLooping3 !$OMP END PARALLEL DO !-------------------------------------------------------------------------------------------------- ! integrate --- requires fully defined state array (basic + dependent state) if (any(crystallite_todo)) call integrateState ! TODO: unroll into proper elementloop to avoid N^2 for single point evaluation where(.not. crystallite_converged .and. crystallite_subStep > num%subStepMinCryst) & ! do not try non-converged but fully cutbacked any further crystallite_todo = .true. ! TODO: again unroll this into proper elementloop to avoid N^2 for single point evaluation enddo cutbackLooping ! return whether converged or not crystallite_stress = .false. elementLooping5: do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) crystallite_stress(i,e) = all(crystallite_converged(:,i,e)) enddo enddo elementLooping5 end function crystallite_stress !-------------------------------------------------------------------------------------------------- !> @brief calculate tangent (dPdF) !-------------------------------------------------------------------------------------------------- subroutine crystallite_stressTangent integer :: & c, & !< counter in integration point component loop i, & !< counter in integration point loop e, & !< counter in element loop o, & p real(pReal), dimension(3,3) :: temp_33_1, devNull,invSubFi0, temp_33_2, temp_33_3, temp_33_4 real(pReal), dimension(3,3,3,3) :: dSdFe, & dSdF, & dSdFi, & dLidS, & dLidFi, & dLpdS, & dLpdFi, & dFidS, & dFpinvdF, & rhs_3333, & lhs_3333, & temp_3333 real(pReal), dimension(9,9):: temp_99 logical :: error !$OMP PARALLEL DO PRIVATE(dSdF,dSdFe,dSdFi,dLpdS,dLpdFi,dFpinvdF,dLidS,dLidFi,dFidS,invSubFi0,o,p, & !$OMP rhs_3333,lhs_3333,temp_99,temp_33_1,temp_33_2,temp_33_3,temp_33_4,temp_3333,error) elementLooping: do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do c = 1,homogenization_Ngrains(material_homogenizationAt(e)) call constitutive_SandItsTangents(devNull,dSdFe,dSdFi, & crystallite_Fe(1:3,1:3,c,i,e), & crystallite_Fi(1:3,1:3,c,i,e),c,i,e) ! call constitutive law to calculate elastic stress tangent call constitutive_LiAndItsTangents(devNull,dLidS,dLidFi, & crystallite_S (1:3,1:3,c,i,e), & crystallite_Fi(1:3,1:3,c,i,e), & c,i,e) ! call constitutive law to calculate Li tangent in lattice configuration if (sum(abs(dLidS)) < tol_math_check) then dFidS = 0.0_pReal else invSubFi0 = math_inv33(crystallite_subFi0(1:3,1:3,c,i,e)) lhs_3333 = 0.0_pReal; rhs_3333 = 0.0_pReal do o=1,3; do p=1,3 lhs_3333(1:3,1:3,o,p) = lhs_3333(1:3,1:3,o,p) & + crystallite_subdt(c,i,e)*matmul(invSubFi0,dLidFi(1:3,1:3,o,p)) lhs_3333(1:3,o,1:3,p) = lhs_3333(1:3,o,1:3,p) & + crystallite_invFi(1:3,1:3,c,i,e)*crystallite_invFi(p,o,c,i,e) rhs_3333(1:3,1:3,o,p) = rhs_3333(1:3,1:3,o,p) & - crystallite_subdt(c,i,e)*matmul(invSubFi0,dLidS(1:3,1:3,o,p)) enddo; enddo call math_invert(temp_99,error,math_3333to99(lhs_3333)) if (error) then call IO_warning(warning_ID=600,el=e,ip=i,g=c, & ext_msg='inversion error in analytic tangent calculation') dFidS = 0.0_pReal else dFidS = math_mul3333xx3333(math_99to3333(temp_99),rhs_3333) endif dLidS = math_mul3333xx3333(dLidFi,dFidS) + dLidS endif call constitutive_LpAndItsTangents(devNull,dLpdS,dLpdFi, & crystallite_S (1:3,1:3,c,i,e), & crystallite_Fi(1:3,1:3,c,i,e),c,i,e) ! call constitutive law to calculate Lp tangent in lattice configuration dLpdS = math_mul3333xx3333(dLpdFi,dFidS) + dLpdS !-------------------------------------------------------------------------------------------------- ! calculate dSdF temp_33_1 = transpose(matmul(crystallite_invFp(1:3,1:3,c,i,e), & crystallite_invFi(1:3,1:3,c,i,e))) temp_33_2 = matmul( crystallite_subF (1:3,1:3,c,i,e), & math_inv33(crystallite_subFp0(1:3,1:3,c,i,e))) temp_33_3 = matmul(matmul(crystallite_subF (1:3,1:3,c,i,e), & crystallite_invFp (1:3,1:3,c,i,e)), & math_inv33(crystallite_subFi0(1:3,1:3,c,i,e))) do o=1,3; do p=1,3 rhs_3333(p,o,1:3,1:3) = matmul(dSdFe(p,o,1:3,1:3),temp_33_1) temp_3333(1:3,1:3,p,o) = matmul(matmul(temp_33_2,dLpdS(1:3,1:3,p,o)), & crystallite_invFi(1:3,1:3,c,i,e)) & + matmul(temp_33_3,dLidS(1:3,1:3,p,o)) enddo; enddo lhs_3333 = crystallite_subdt(c,i,e)*math_mul3333xx3333(dSdFe,temp_3333) & + math_mul3333xx3333(dSdFi,dFidS) call math_invert(temp_99,error,math_identity2nd(9)+math_3333to99(lhs_3333)) if (error) then call IO_warning(warning_ID=600,el=e,ip=i,g=c, & ext_msg='inversion error in analytic tangent calculation') dSdF = rhs_3333 else dSdF = math_mul3333xx3333(math_99to3333(temp_99),rhs_3333) endif !-------------------------------------------------------------------------------------------------- ! calculate dFpinvdF temp_3333 = math_mul3333xx3333(dLpdS,dSdF) do o=1,3; do p=1,3 dFpinvdF(1:3,1:3,p,o) & = -crystallite_subdt(c,i,e) & * matmul(math_inv33(crystallite_subFp0(1:3,1:3,c,i,e)), & matmul(temp_3333(1:3,1:3,p,o),crystallite_invFi(1:3,1:3,c,i,e))) enddo; enddo !-------------------------------------------------------------------------------------------------- ! assemble dPdF temp_33_1 = matmul(crystallite_S(1:3,1:3,c,i,e),transpose(crystallite_invFp(1:3,1:3,c,i,e))) temp_33_2 = matmul(crystallite_invFp(1:3,1:3,c,i,e),temp_33_1) temp_33_3 = matmul(crystallite_subF(1:3,1:3,c,i,e),crystallite_invFp(1:3,1:3,c,i,e)) temp_33_4 = matmul(temp_33_3,crystallite_S(1:3,1:3,c,i,e)) crystallite_dPdF(1:3,1:3,1:3,1:3,c,i,e) = 0.0_pReal do p=1,3 crystallite_dPdF(p,1:3,p,1:3,c,i,e) = transpose(temp_33_2) enddo do o=1,3; do p=1,3 crystallite_dPdF(1:3,1:3,p,o,c,i,e) = crystallite_dPdF(1:3,1:3,p,o,c,i,e) + & matmul(matmul(crystallite_subF(1:3,1:3,c,i,e),dFpinvdF(1:3,1:3,p,o)),temp_33_1) + & matmul(matmul(temp_33_3,dSdF(1:3,1:3,p,o)),transpose(crystallite_invFp(1:3,1:3,c,i,e))) + & matmul(temp_33_4,transpose(dFpinvdF(1:3,1:3,p,o))) enddo; enddo enddo; enddo enddo elementLooping !$OMP END PARALLEL DO end subroutine crystallite_stressTangent !-------------------------------------------------------------------------------------------------- !> @brief calculates orientations !-------------------------------------------------------------------------------------------------- subroutine crystallite_orientations integer & c, & !< counter in integration point component loop i, & !< counter in integration point loop e !< counter in element loop !$OMP PARALLEL DO do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do c = 1,homogenization_Ngrains(material_homogenizationAt(e)) call crystallite_orientation(c,i,e)%fromMatrix(transpose(math_rotationalPart33(crystallite_Fe(1:3,1:3,c,i,e)))) enddo; enddo; enddo !$OMP END PARALLEL DO nonlocalPresent: if (any(plasticState%nonLocal)) then !$OMP PARALLEL DO do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) if (plasticState(material_phaseAt(1,e))%nonLocal) & ! if nonlocal model call plastic_nonlocal_updateCompatibility(crystallite_orientation,i,e) enddo; enddo !$OMP END PARALLEL DO endif nonlocalPresent end subroutine crystallite_orientations !-------------------------------------------------------------------------------------------------- !> @brief Map 2nd order tensor to reference config !-------------------------------------------------------------------------------------------------- function crystallite_push33ToRef(ipc,ip,el, tensor33) real(pReal), dimension(3,3) :: crystallite_push33ToRef real(pReal), dimension(3,3), intent(in) :: tensor33 real(pReal), dimension(3,3) :: T integer, intent(in):: & el, & ip, & ipc T = matmul(material_orientation0(ipc,ip,el)%asMatrix(), & ! ToDo: initial orientation correct? transpose(math_inv33(crystallite_subF(1:3,1:3,ipc,ip,el)))) crystallite_push33ToRef = matmul(transpose(T),matmul(tensor33,T)) end function crystallite_push33ToRef !-------------------------------------------------------------------------------------------------- !> @brief writes crystallite results to HDF5 output file !-------------------------------------------------------------------------------------------------- subroutine crystallite_results integer :: p,o real(pReal), allocatable, dimension(:,:,:) :: selected_tensors type(rotation), allocatable, dimension(:) :: selected_rotations character(len=pStringLen) :: group,lattice_label do p=1,size(config_name_phase) group = trim('current/constituent')//'/'//trim(config_name_phase(p))//'/generic' call results_closeGroup(results_addGroup(group)) do o = 1, size(output_constituent(p)%label) select case (output_constituent(p)%label(o)) case('f') selected_tensors = select_tensors(crystallite_partionedF,p) call results_writeDataset(group,selected_tensors,'F',& 'deformation gradient','1') case('fe') selected_tensors = select_tensors(crystallite_Fe,p) call results_writeDataset(group,selected_tensors,'Fe',& 'elastic deformation gradient','1') case('fp') selected_tensors = select_tensors(crystallite_Fp,p) call results_writeDataset(group,selected_tensors,'Fp',& 'plastic deformation gradient','1') case('fi') selected_tensors = select_tensors(crystallite_Fi,p) call results_writeDataset(group,selected_tensors,'Fi',& 'inelastic deformation gradient','1') case('lp') selected_tensors = select_tensors(crystallite_Lp,p) call results_writeDataset(group,selected_tensors,'Lp',& 'plastic velocity gradient','1/s') case('li') selected_tensors = select_tensors(crystallite_Li,p) call results_writeDataset(group,selected_tensors,'Li',& 'inelastic velocity gradient','1/s') case('p') selected_tensors = select_tensors(crystallite_P,p) call results_writeDataset(group,selected_tensors,'P',& '1st Piola-Kirchoff stress','Pa') case('s') selected_tensors = select_tensors(crystallite_S,p) call results_writeDataset(group,selected_tensors,'S',& '2nd Piola-Kirchoff stress','Pa') case('orientation') select case(lattice_structure(p)) case(LATTICE_iso_ID) lattice_label = 'iso' case(LATTICE_fcc_ID) lattice_label = 'fcc' case(LATTICE_bcc_ID) lattice_label = 'bcc' case(LATTICE_bct_ID) lattice_label = 'bct' case(LATTICE_hex_ID) lattice_label = 'hex' case(LATTICE_ort_ID) lattice_label = 'ort' end select selected_rotations = select_rotations(crystallite_orientation,p) call results_writeDataset(group,selected_rotations,'orientation',& 'crystal orientation as quaternion',lattice_label) end select enddo enddo contains !------------------------------------------------------------------------------------------------ !> @brief select tensors for output !------------------------------------------------------------------------------------------------ function select_tensors(dataset,instance) integer, intent(in) :: instance real(pReal), dimension(:,:,:,:,:), intent(in) :: dataset real(pReal), allocatable, dimension(:,:,:) :: select_tensors integer :: e,i,c,j allocate(select_tensors(3,3,count(material_phaseAt==instance)*homogenization_maxNgrains*discretization_nIP)) j=0 do e = 1, size(material_phaseAt,2) do i = 1, discretization_nIP do c = 1, size(material_phaseAt,1) !ToDo: this needs to be changed for varying Ngrains if (material_phaseAt(c,e) == instance) then j = j + 1 select_tensors(1:3,1:3,j) = dataset(1:3,1:3,c,i,e) endif enddo enddo enddo end function select_tensors !-------------------------------------------------------------------------------------------------- !> @brief select rotations for output !-------------------------------------------------------------------------------------------------- function select_rotations(dataset,instance) integer, intent(in) :: instance type(rotation), dimension(:,:,:), intent(in) :: dataset type(rotation), allocatable, dimension(:) :: select_rotations integer :: e,i,c,j allocate(select_rotations(count(material_phaseAt==instance)*homogenization_maxNgrains*discretization_nIP)) j=0 do e = 1, size(material_phaseAt,2) do i = 1, discretization_nIP do c = 1, size(material_phaseAt,1) !ToDo: this needs to be changed for varying Ngrains if (material_phaseAt(c,e) == instance) then j = j + 1 select_rotations(j) = dataset(c,i,e) endif enddo enddo enddo end function select_rotations end subroutine crystallite_results !-------------------------------------------------------------------------------------------------- !> @brief calculation of stress (P) with time integration based on a residuum in Lp and !> intermediate acceleration of the Newton-Raphson correction !-------------------------------------------------------------------------------------------------- logical function integrateStress(ipc,ip,el,timeFraction) integer, intent(in):: el, & ! element index ip, & ! integration point index ipc ! grain index real(pReal), optional, intent(in) :: timeFraction ! fraction of timestep real(pReal), dimension(3,3):: F, & ! deformation gradient at end of timestep Fp_new, & ! plastic deformation gradient at end of timestep Fe_new, & ! elastic deformation gradient at end of timestep invFp_new, & ! inverse of Fp_new Fi_new, & ! gradient of intermediate deformation stages invFi_new, & invFp_current, & ! inverse of Fp_current invFi_current, & ! inverse of Fp_current Lpguess, & ! current guess for plastic velocity gradient Lpguess_old, & ! known last good guess for plastic velocity gradient Lp_constitutive, & ! plastic velocity gradient resulting from constitutive law residuumLp, & ! current residuum of plastic velocity gradient residuumLp_old, & ! last residuum of plastic velocity gradient deltaLp, & ! direction of next guess Liguess, & ! current guess for intermediate velocity gradient Liguess_old, & ! known last good guess for intermediate velocity gradient Li_constitutive, & ! intermediate velocity gradient resulting from constitutive law residuumLi, & ! current residuum of intermediate velocity gradient residuumLi_old, & ! last residuum of intermediate velocity gradient deltaLi, & ! direction of next guess S, & ! 2nd Piola-Kirchhoff Stress in plastic (lattice) configuration A, & B, & Fe, & ! elastic deformation gradient temp_33 real(pReal), dimension(9) :: temp_9 ! needed for matrix inversion by LAPACK integer, dimension(9) :: devNull_9 ! needed for matrix inversion by LAPACK real(pReal), dimension(9,9) :: dRLp_dLp, & ! partial derivative of residuum (Jacobian for Newton-Raphson scheme) dRLi_dLi ! partial derivative of residuumI (Jacobian for Newton-Raphson scheme) real(pReal), dimension(3,3,3,3):: dS_dFe, & ! partial derivative of 2nd Piola-Kirchhoff stress dS_dFi, & dFe_dLp, & ! partial derivative of elastic deformation gradient dFe_dLi, & dFi_dLi, & dLp_dFi, & dLi_dFi, & dLp_dS, & dLi_dS real(pReal) steplengthLp, & steplengthLi, & dt, & ! time increment aTolLp, & aTolLi, & devNull integer NiterationStressLp, & ! number of stress integrations NiterationStressLi, & ! number of inner stress integrations ierr, & ! error indicator for LAPACK o, & p, & jacoCounterLp, & jacoCounterLi ! counters to check for Jacobian update logical :: error external :: & dgesv integrateStress = .false. if (present(timeFraction)) then dt = crystallite_subdt(ipc,ip,el) * timeFraction F = crystallite_subF0(1:3,1:3,ipc,ip,el) & + (crystallite_subF(1:3,1:3,ipc,ip,el) - crystallite_subF0(1:3,1:3,ipc,ip,el)) * timeFraction else dt = crystallite_subdt(ipc,ip,el) F = crystallite_subF(1:3,1:3,ipc,ip,el) endif Lpguess = crystallite_Lp(1:3,1:3,ipc,ip,el) ! take as first guess Liguess = crystallite_Li(1:3,1:3,ipc,ip,el) ! take as first guess call math_invert33(invFp_current,devNull,error,crystallite_subFp0(1:3,1:3,ipc,ip,el)) if (error) return ! error call math_invert33(invFi_current,devNull,error,crystallite_subFi0(1:3,1:3,ipc,ip,el)) if (error) return ! error A = matmul(F,invFp_current) ! intermediate tensor needed later to calculate dFe_dLp jacoCounterLi = 0 steplengthLi = 1.0_pReal residuumLi_old = 0.0_pReal Liguess_old = Liguess NiterationStressLi = 0 LiLoop: do NiterationStressLi = NiterationStressLi + 1 if (NiterationStressLi>num%nStress) return ! error invFi_new = matmul(invFi_current,math_I3 - dt*Liguess) Fi_new = math_inv33(invFi_new) jacoCounterLp = 0 steplengthLp = 1.0_pReal residuumLp_old = 0.0_pReal Lpguess_old = Lpguess NiterationStressLp = 0 LpLoop: do NiterationStressLp = NiterationStressLp + 1 if (NiterationStressLp>num%nStress) return ! error B = math_I3 - dt*Lpguess Fe = matmul(matmul(A,B), invFi_new) call constitutive_SandItsTangents(S, dS_dFe, dS_dFi, & Fe, Fi_new, ipc, ip, el) call constitutive_LpAndItsTangents(Lp_constitutive, dLp_dS, dLp_dFi, & S, Fi_new, ipc, ip, el) !* update current residuum and check for convergence of loop aTolLp = max(num%rTol_crystalliteStress * max(norm2(Lpguess),norm2(Lp_constitutive)), & ! absolute tolerance from largest acceptable relative error num%aTol_crystalliteStress) ! minimum lower cutoff residuumLp = Lpguess - Lp_constitutive if (any(IEEE_is_NaN(residuumLp))) then return ! error elseif (norm2(residuumLp) < aTolLp) then ! converged if below absolute tolerance exit LpLoop elseif (NiterationStressLp == 1 .or. norm2(residuumLp) < norm2(residuumLp_old)) then ! not converged, but improved norm of residuum (always proceed in first iteration)... residuumLp_old = residuumLp ! ...remember old values and... Lpguess_old = Lpguess steplengthLp = 1.0_pReal ! ...proceed with normal step length (calculate new search direction) else ! not converged and residuum not improved... steplengthLp = num%subStepSizeLp * steplengthLp ! ...try with smaller step length in same direction Lpguess = Lpguess_old & + deltaLp * stepLengthLp cycle LpLoop endif !* calculate Jacobian for correction term if (mod(jacoCounterLp, num%iJacoLpresiduum) == 0) then jacoCounterLp = jacoCounterLp + 1 do o=1,3; do p=1,3 dFe_dLp(o,1:3,p,1:3) = A(o,p)*transpose(invFi_new) ! dFe_dLp(i,j,k,l) = -dt * A(i,k) invFi(l,j) enddo; enddo dFe_dLp = - dt * dFe_dLp dRLp_dLp = math_identity2nd(9) & - math_3333to99(math_mul3333xx3333(math_mul3333xx3333(dLp_dS,dS_dFe),dFe_dLp)) temp_9 = math_33to9(residuumLp) call dgesv(9,1,dRLp_dLp,9,devNull_9,temp_9,9,ierr) ! solve dRLp/dLp * delta Lp = -res for delta Lp if (ierr /= 0) return ! error deltaLp = - math_9to33(temp_9) endif Lpguess = Lpguess & + deltaLp * steplengthLp enddo LpLoop call constitutive_LiAndItsTangents(Li_constitutive, dLi_dS, dLi_dFi, & S, Fi_new, ipc, ip, el) !* update current residuum and check for convergence of loop aTolLi = max(num%rTol_crystalliteStress * max(norm2(Liguess),norm2(Li_constitutive)), & ! absolute tolerance from largest acceptable relative error num%aTol_crystalliteStress) ! minimum lower cutoff residuumLi = Liguess - Li_constitutive if (any(IEEE_is_NaN(residuumLi))) then return ! error elseif (norm2(residuumLi) < aTolLi) then ! converged if below absolute tolerance exit LiLoop elseif (NiterationStressLi == 1 .or. norm2(residuumLi) < norm2(residuumLi_old)) then ! not converged, but improved norm of residuum (always proceed in first iteration)... residuumLi_old = residuumLi ! ...remember old values and... Liguess_old = Liguess steplengthLi = 1.0_pReal ! ...proceed with normal step length (calculate new search direction) else ! not converged and residuum not improved... steplengthLi = num%subStepSizeLi * steplengthLi ! ...try with smaller step length in same direction Liguess = Liguess_old & + deltaLi * steplengthLi cycle LiLoop endif !* calculate Jacobian for correction term if (mod(jacoCounterLi, num%iJacoLpresiduum) == 0) then jacoCounterLi = jacoCounterLi + 1 temp_33 = matmul(matmul(A,B),invFi_current) do o=1,3; do p=1,3 dFe_dLi(1:3,o,1:3,p) = -dt*math_I3(o,p)*temp_33 ! dFe_dLp(i,j,k,l) = -dt * A(i,k) invFi(l,j) dFi_dLi(1:3,o,1:3,p) = -dt*math_I3(o,p)*invFi_current enddo; enddo do o=1,3; do p=1,3 dFi_dLi(1:3,1:3,o,p) = matmul(matmul(Fi_new,dFi_dLi(1:3,1:3,o,p)),Fi_new) enddo; enddo dRLi_dLi = math_identity2nd(9) & - math_3333to99(math_mul3333xx3333(dLi_dS, math_mul3333xx3333(dS_dFe, dFe_dLi) & + math_mul3333xx3333(dS_dFi, dFi_dLi))) & - math_3333to99(math_mul3333xx3333(dLi_dFi, dFi_dLi)) temp_9 = math_33to9(residuumLi) call dgesv(9,1,dRLi_dLi,9,devNull_9,temp_9,9,ierr) ! solve dRLi/dLp * delta Li = -res for delta Li if (ierr /= 0) return ! error deltaLi = - math_9to33(temp_9) endif Liguess = Liguess & + deltaLi * steplengthLi enddo LiLoop invFp_new = matmul(invFp_current,B) call math_invert33(Fp_new,devNull,error,invFp_new) if (error) return ! error Fp_new = Fp_new / math_det33(Fp_new)**(1.0_pReal/3.0_pReal) ! regularize Fe_new = matmul(matmul(F,invFp_new),invFi_new) integrateStress = .true. crystallite_P (1:3,1:3,ipc,ip,el) = matmul(matmul(F,invFp_new),matmul(S,transpose(invFp_new))) ! ToDo: We propably do not need to store P! crystallite_S (1:3,1:3,ipc,ip,el) = S crystallite_Lp (1:3,1:3,ipc,ip,el) = Lpguess crystallite_Li (1:3,1:3,ipc,ip,el) = Liguess crystallite_Fp (1:3,1:3,ipc,ip,el) = Fp_new crystallite_Fi (1:3,1:3,ipc,ip,el) = Fi_new crystallite_Fe (1:3,1:3,ipc,ip,el) = Fe_new crystallite_invFp(1:3,1:3,ipc,ip,el) = invFp_new crystallite_invFi(1:3,1:3,ipc,ip,el) = invFi_new end function integrateStress !-------------------------------------------------------------------------------------------------- !> @brief integrate stress, state with adaptive 1st order explicit Euler method !> using Fixed Point Iteration to adapt the stepsize !-------------------------------------------------------------------------------------------------- subroutine integrateStateFPI integer :: & NiterationState, & !< number of iterations in state loop e, & !< element index in element loop i, & !< integration point index in ip loop g, & !< grain index in grain loop p, & c, & s, & sizeDotState real(pReal) :: & zeta real(pReal), dimension(constitutive_plasticity_maxSizeDotState) :: & residuum_plastic ! residuum for plastic state real(pReal), dimension(constitutive_source_maxSizeDotState) :: & residuum_source ! residuum for source state logical :: & doneWithIntegration ! --+>> PREGUESS FOR STATE <<+-- call update_dotState(1.0_pReal) call update_state(1.0_pReal) NiterationState = 0 doneWithIntegration = .false. crystalliteLooping: do while (.not. doneWithIntegration .and. NiterationState < num%nState) NiterationState = NiterationState + 1 #ifdef DEBUG if (iand(debug_level(debug_crystallite), debug_levelExtensive) /= 0) & write(6,'(a,i6)') '<< CRYST stateFPI >> state iteration ',NiterationState #endif ! store previousDotState and previousDotState2 !$OMP PARALLEL DO PRIVATE(p,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) then p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) plasticState(p)%previousDotState2(:,c) = merge(plasticState(p)%previousDotState(:,c),& 0.0_pReal,& NiterationState > 1) plasticState(p)%previousDotState (:,c) = plasticState(p)%dotState(:,c) do s = 1, phase_Nsources(p) sourceState(p)%p(s)%previousDotState2(:,c) = merge(sourceState(p)%p(s)%previousDotState(:,c),& 0.0_pReal, & NiterationState > 1) sourceState(p)%p(s)%previousDotState (:,c) = sourceState(p)%p(s)%dotState(:,c) enddo endif enddo enddo enddo !$OMP END PARALLEL DO call update_dependentState call update_stress(1.0_pReal) call update_dotState(1.0_pReal) !$OMP PARALLEL !$OMP DO PRIVATE(sizeDotState,residuum_plastic,residuum_source,zeta,p,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) then p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) sizeDotState = plasticState(p)%sizeDotState zeta = damper(plasticState(p)%dotState (:,c), & plasticState(p)%previousDotState (:,c), & plasticState(p)%previousDotState2(:,c)) residuum_plastic(1:SizeDotState) = plasticState(p)%state (1:sizeDotState,c) & - plasticState(p)%subState0(1:sizeDotState,c) & - ( plasticState(p)%dotState (:,c) * zeta & + plasticState(p)%previousDotState(:,c) * (1.0_pReal-zeta) & ) * crystallite_subdt(g,i,e) plasticState(p)%state(1:sizeDotState,c) = plasticState(p)%state(1:sizeDotState,c) & - residuum_plastic(1:sizeDotState) plasticState(p)%dotState(:,c) = plasticState(p)%dotState(:,c) * zeta & + plasticState(p)%previousDotState(:,c) * (1.0_pReal - zeta) crystallite_converged(g,i,e) = converged(residuum_plastic(1:sizeDotState), & plasticState(p)%state(1:sizeDotState,c), & plasticState(p)%aTolState(1:sizeDotState)) do s = 1, phase_Nsources(p) sizeDotState = sourceState(p)%p(s)%sizeDotState zeta = damper(sourceState(p)%p(s)%dotState (:,c), & sourceState(p)%p(s)%previousDotState (:,c), & sourceState(p)%p(s)%previousDotState2(:,c)) residuum_source(1:sizeDotState) = sourceState(p)%p(s)%state (1:sizeDotState,c) & - sourceState(p)%p(s)%subState0(1:sizeDotState,c) & - ( sourceState(p)%p(s)%dotState (:,c) * zeta & + sourceState(p)%p(s)%previousDotState(:,c) * (1.0_pReal - zeta) & ) * crystallite_subdt(g,i,e) sourceState(p)%p(s)%state(1:sizeDotState,c) = sourceState(p)%p(s)%state(1:sizeDotState,c) & - residuum_source(1:sizeDotState) sourceState(p)%p(s)%dotState(:,c) = sourceState(p)%p(s)%dotState(:,c) * zeta & + sourceState(p)%p(s)%previousDotState(:,c)* (1.0_pReal - zeta) crystallite_converged(g,i,e) = & crystallite_converged(g,i,e) .and. converged(residuum_source(1:sizeDotState), & sourceState(p)%p(s)%state(1:sizeDotState,c), & sourceState(p)%p(s)%aTolState(1:sizeDotState)) enddo endif enddo; enddo; enddo !$OMP ENDDO !$OMP DO do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) !$OMP FLUSH(crystallite_todo) if (crystallite_todo(g,i,e) .and. crystallite_converged(g,i,e)) then ! converged and still alive... crystallite_todo(g,i,e) = stateJump(g,i,e) !$OMP FLUSH(crystallite_todo) if (.not. crystallite_todo(g,i,e)) then ! if state jump fails, then convergence is broken crystallite_converged(g,i,e) = .false. if (.not. crystallite_localPlasticity(g,i,e)) then ! if broken non-local... !$OMP CRITICAL (checkTodo) crystallite_todo = crystallite_todo .and. crystallite_localPlasticity ! ...all non-locals skipped !$OMP END CRITICAL (checkTodo) endif endif endif enddo; enddo; enddo !$OMP ENDDO !$OMP END PARALLEL if (any(plasticState(:)%nonlocal)) call nonlocalConvergenceCheck ! --- CHECK IF DONE WITH INTEGRATION --- doneWithIntegration = .true. do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) then doneWithIntegration = .false. exit endif enddo; enddo enddo enddo crystalliteLooping contains !-------------------------------------------------------------------------------------------------- !> @brief calculate the damping for correction of state and dot state !-------------------------------------------------------------------------------------------------- real(pReal) pure function damper(current,previous,previous2) real(pReal), dimension(:), intent(in) ::& current, previous, previous2 real(pReal) :: dot_prod12, dot_prod22 dot_prod12 = dot_product(current - previous, previous - previous2) dot_prod22 = dot_product(previous - previous2, previous - previous2) if ((dot_product(current,previous) < 0.0_pReal .or. dot_prod12 < 0.0_pReal) .and. dot_prod22 > 0.0_pReal) then damper = 0.75_pReal + 0.25_pReal * tanh(2.0_pReal + 4.0_pReal * dot_prod12 / dot_prod22) else damper = 1.0_pReal endif end function damper end subroutine integrateStateFPI !-------------------------------------------------------------------------------------------------- !> @brief integrate state with 1st order explicit Euler method !-------------------------------------------------------------------------------------------------- subroutine integrateStateEuler call update_dotState(1.0_pReal) call update_state(1.0_pReal) call update_deltaState call update_dependentState call update_stress(1.0_pReal) call setConvergenceFlag if (any(plasticState(:)%nonlocal)) call nonlocalConvergenceCheck end subroutine integrateStateEuler !-------------------------------------------------------------------------------------------------- !> @brief integrate stress, state with 1st order Euler method with adaptive step size !-------------------------------------------------------------------------------------------------- subroutine integrateStateAdaptiveEuler integer :: & e, & ! element index in element loop i, & ! integration point index in ip loop g, & ! grain index in grain loop p, & c, & s, & sizeDotState ! ToDo: MD: once all constitutives use allocate state, attach residuum arrays to the state in case of adaptive Euler real(pReal), dimension(constitutive_plasticity_maxSizeDotState, & homogenization_maxNgrains,discretization_nIP,discretization_nElem) :: & residuum_plastic real(pReal), dimension(constitutive_source_maxSizeDotState,& maxval(phase_Nsources), & homogenization_maxNgrains,discretization_nIP,discretization_nElem) :: & residuum_source !-------------------------------------------------------------------------------------------------- ! contribution to state and relative residui and from Euler integration call update_dotState(1.0_pReal) !$OMP PARALLEL DO PRIVATE(sizeDotState,p,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e)) then p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) sizeDotState = plasticState(p)%sizeDotState residuum_plastic(1:sizeDotState,g,i,e) = plasticState(p)%dotstate(1:sizeDotState,c) & * (- 0.5_pReal * crystallite_subdt(g,i,e)) plasticState(p)%state(1:sizeDotState,c) = & plasticState(p)%state(1:sizeDotState,c) + plasticState(p)%dotstate(1:sizeDotState,c) * crystallite_subdt(g,i,e) !ToDo: state, partitioned state? do s = 1, phase_Nsources(p) sizeDotState = sourceState(p)%p(s)%sizeDotState residuum_source(1:sizeDotState,s,g,i,e) = sourceState(p)%p(s)%dotstate(1:sizeDotState,c) & * (- 0.5_pReal * crystallite_subdt(g,i,e)) sourceState(p)%p(s)%state(1:sizeDotState,c) = & sourceState(p)%p(s)%state(1:sizeDotState,c) + sourceState(p)%p(s)%dotstate(1:sizeDotState,c) * crystallite_subdt(g,i,e) !ToDo: state, partitioned state? enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO call update_deltaState call update_dependentState call update_stress(1.0_pReal) call update_dotState(1.0_pReal) !$OMP PARALLEL DO PRIVATE(sizeDotState,p,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e)) then p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) sizeDotState = plasticState(p)%sizeDotState residuum_plastic(1:sizeDotState,g,i,e) = residuum_plastic(1:sizeDotState,g,i,e) & + 0.5_pReal * plasticState(p)%dotState(:,c) * crystallite_subdt(g,i,e) crystallite_converged(g,i,e) = converged(residuum_plastic(1:sizeDotState,g,i,e), & plasticState(p)%state(1:sizeDotState,c), & plasticState(p)%aTolState(1:sizeDotState)) do s = 1, phase_Nsources(p) sizeDotState = sourceState(p)%p(s)%sizeDotState residuum_source(1:sizeDotState,s,g,i,e) = & residuum_source(1:sizeDotState,s,g,i,e) + 0.5_pReal * sourceState(p)%p(s)%dotState(:,c) * crystallite_subdt(g,i,e) crystallite_converged(g,i,e) = & crystallite_converged(g,i,e) .and. converged(residuum_source(1:sizeDotState,s,g,i,e), & sourceState(p)%p(s)%state(1:sizeDotState,c), & sourceState(p)%p(s)%aTolState(1:sizeDotState)) enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO if (any(plasticState(:)%nonlocal)) call nonlocalConvergenceCheck end subroutine integrateStateAdaptiveEuler !-------------------------------------------------------------------------------------------------- !> @brief integrate stress, state with 4th order explicit Runge Kutta method ! ToDo: This is totally BROKEN: RK4dotState is never used!!! !-------------------------------------------------------------------------------------------------- subroutine integrateStateRK4 real(pReal), dimension(4), parameter :: & TIMESTEPFRACTION = [0.5_pReal, 0.5_pReal, 1.0_pReal, 1.0_pReal] ! factor giving the fraction of the original timestep used for Runge Kutta Integration real(pReal), dimension(4), parameter :: & WEIGHT = [1.0_pReal, 2.0_pReal, 2.0_pReal, 1.0_pReal/6.0_pReal] ! weight of slope used for Runge Kutta integration (final weight divided by 6) integer :: e, & ! element index in element loop i, & ! integration point index in ip loop g, & ! grain index in grain loop p, & ! phase loop c, & n, & s call update_dotState(1.0_pReal) do n = 1,4 !$OMP PARALLEL DO PRIVATE(p,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e)) then p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) plasticState(p)%RK4dotState(:,c) = WEIGHT(n)*plasticState(p)%dotState(:,c) & + merge(plasticState(p)%RK4dotState(:,c),0.0_pReal,n>1) do s = 1, phase_Nsources(p) sourceState(p)%p(s)%RK4dotState(:,c) = WEIGHT(n)*sourceState(p)%p(s)%dotState(:,c) & + merge(sourceState(p)%p(s)%RK4dotState(:,c),0.0_pReal,n>1) enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO call update_state(TIMESTEPFRACTION(n)) call update_deltaState call update_dependentState call update_stress(TIMESTEPFRACTION(n)) ! --- dot state and RK dot state--- first3steps: if (n < 4) then call update_dotState(TIMESTEPFRACTION(n)) endif first3steps enddo call setConvergenceFlag if (any(plasticState(:)%nonlocal)) call nonlocalConvergenceCheck end subroutine integrateStateRK4 !-------------------------------------------------------------------------------------------------- !> @brief integrate stress, state with 5th order Runge-Kutta Cash-Karp method with !> adaptive step size (use 5th order solution to advance = "local extrapolation") !-------------------------------------------------------------------------------------------------- subroutine integrateStateRKCK45 real(pReal), dimension(5,5), parameter :: & A = reshape([& .2_pReal, .075_pReal, .3_pReal, -11.0_pReal/54.0_pReal, 1631.0_pReal/55296.0_pReal, & .0_pReal, .225_pReal, -.9_pReal, 2.5_pReal, 175.0_pReal/512.0_pReal, & .0_pReal, .0_pReal, 1.2_pReal, -70.0_pReal/27.0_pReal, 575.0_pReal/13824.0_pReal, & .0_pReal, .0_pReal, .0_pReal, 35.0_pReal/27.0_pReal, 44275.0_pReal/110592.0_pReal, & .0_pReal, .0_pReal, .0_pReal, .0_pReal, 253.0_pReal/4096.0_pReal], & [5,5], order=[2,1]) !< coefficients in Butcher tableau (used for preliminary integration in stages 2 to 6) real(pReal), dimension(6), parameter :: & B = & [37.0_pReal/378.0_pReal, .0_pReal, 250.0_pReal/621.0_pReal, & 125.0_pReal/594.0_pReal, .0_pReal, 512.0_pReal/1771.0_pReal], & !< coefficients in Butcher tableau (used for final integration and error estimate) DB = B - & [2825.0_pReal/27648.0_pReal, .0_pReal, 18575.0_pReal/48384.0_pReal,& 13525.0_pReal/55296.0_pReal, 277.0_pReal/14336.0_pReal, 0.25_pReal] !< coefficients in Butcher tableau (used for final integration and error estimate) real(pReal), dimension(5), parameter :: & C = [0.2_pReal, 0.3_pReal, 0.6_pReal, 1.0_pReal, 0.875_pReal] !< coefficients in Butcher tableau (fractions of original time step in stages 2 to 6) integer :: & e, & ! element index in element loop i, & ! integration point index in ip loop g, & ! grain index in grain loop stage, & ! stage index in integration stage loop n, & p, & cc, & s, & sizeDotState ! ToDo: MD: once all constitutives use allocate state, attach residuum arrays to the state in case of RKCK45 real(pReal), dimension(constitutive_plasticity_maxSizeDotState, & homogenization_maxNgrains,discretization_nIP,discretization_nElem) :: & residuum_plastic ! relative residuum from evolution in microstructure real(pReal), dimension(constitutive_source_maxSizeDotState, & maxval(phase_Nsources), & homogenization_maxNgrains,discretization_nIP,discretization_nElem) :: & residuum_source ! relative residuum from evolution in microstructure call update_dotState(1.0_pReal) ! --- SECOND TO SIXTH RUNGE KUTTA STEP --- do stage = 1,5 ! --- state update --- !$OMP PARALLEL DO PRIVATE(p,cc) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e)) then p = material_phaseAt(g,e); cc = material_phaseMemberAt(g,i,e) plasticState(p)%RKCK45dotState(stage,:,cc) = plasticState(p)%dotState(:,cc) plasticState(p)%dotState(:,cc) = A(1,stage) * plasticState(p)%RKCK45dotState(1,:,cc) do s = 1, phase_Nsources(p) sourceState(p)%p(s)%RKCK45dotState(stage,:,cc) = sourceState(p)%p(s)%dotState(:,cc) sourceState(p)%p(s)%dotState(:,cc) = A(1,stage) * sourceState(p)%p(s)%RKCK45dotState(1,:,cc) enddo do n = 2, stage plasticState(p)%dotState(:,cc) = plasticState(p)%dotState(:,cc) & + A(n,stage) * plasticState(p)%RKCK45dotState(n,:,cc) do s = 1, phase_Nsources(p) sourceState(p)%p(s)%dotState(:,cc) = sourceState(p)%p(s)%dotState(:,cc) & + A(n,stage) * sourceState(p)%p(s)%RKCK45dotState(n,:,cc) enddo enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO call update_state(1.0_pReal) !MD: 1.0 correct? call update_deltaState call update_dependentState call update_stress(C(stage)) call update_dotState(C(stage)) enddo !-------------------------------------------------------------------------------------------------- ! --- STATE UPDATE WITH ERROR ESTIMATE FOR STATE --- !$OMP PARALLEL DO PRIVATE(sizeDotState,p,cc) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e)) then p = material_phaseAt(g,e); cc = material_phaseMemberAt(g,i,e) sizeDotState = plasticState(p)%sizeDotState plasticState(p)%RKCK45dotState(6,:,cc) = plasticState (p)%dotState(:,cc) residuum_plastic(1:sizeDotState,g,i,e) = & matmul(transpose(plasticState(p)%RKCK45dotState(1:6,1:sizeDotState,cc)),DB) & ! why transpose? Better to transpose constant DB * crystallite_subdt(g,i,e) plasticState(p)%dotState(:,cc) = & matmul(transpose(plasticState(p)%RKCK45dotState(1:6,1:sizeDotState,cc)), B) ! why transpose? Better to transpose constant B do s = 1, phase_Nsources(p) sizeDotState = sourceState(p)%p(s)%sizeDotState sourceState(p)%p(s)%RKCK45dotState(6,:,cc) = sourceState(p)%p(s)%dotState(:,cc) residuum_source(1:sizeDotState,s,g,i,e) = & matmul(transpose(sourceState(p)%p(s)%RKCK45dotState(1:6,1:sizeDotState,cc)),DB) & * crystallite_subdt(g,i,e) sourceState(p)%p(s)%dotState(:,cc) = & matmul(transpose(sourceState(p)%p(s)%RKCK45dotState(1:6,1:sizeDotState,cc)),B) enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO call update_state(1.0_pReal) ! --- relative residui and state convergence --- !$OMP PARALLEL DO PRIVATE(sizeDotState,p,cc) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e)) then p = material_phaseAt(g,e); cc = material_phaseMemberAt(g,i,e) sizeDotState = plasticState(p)%sizeDotState crystallite_todo(g,i,e) = converged(residuum_plastic(1:sizeDotState,g,i,e), & plasticState(p)%state(1:sizeDotState,cc), & plasticState(p)%aTolState(1:sizeDotState)) do s = 1, phase_Nsources(p) sizeDotState = sourceState(p)%p(s)%sizeDotState crystallite_todo(g,i,e) = & crystallite_todo(g,i,e) .and. converged(residuum_source(1:sizeDotState,s,g,i,e), & sourceState(p)%p(s)%state(1:sizeDotState,cc), & sourceState(p)%p(s)%aTolState(1:sizeDotState)) enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO call update_deltaState call update_dependentState call update_stress(1.0_pReal) call setConvergenceFlag if (any(plasticState(:)%nonlocal)) call nonlocalConvergenceCheck end subroutine integrateStateRKCK45 !-------------------------------------------------------------------------------------------------- !> @brief sets convergence flag for nonlocal calculations !> @detail one non-converged nonlocal sets all other nonlocals to non-converged to trigger cut back !-------------------------------------------------------------------------------------------------- subroutine nonlocalConvergenceCheck if (any(.not. crystallite_converged .and. .not. crystallite_localPlasticity)) & ! any non-local not yet converged (or broken)... where( .not. crystallite_localPlasticity) crystallite_converged = .false. end subroutine nonlocalConvergenceCheck !-------------------------------------------------------------------------------------------------- !> @brief Sets convergence flag based on "todo": every point that survived the integration (todo is ! still .true. is considered as converged !> @details: For explicitEuler, RK4 and RKCK45, adaptive Euler and FPI have their on criteria !-------------------------------------------------------------------------------------------------- subroutine setConvergenceFlag integer :: & e, & !< element index in element loop i, & !< integration point index in ip loop g !< grain index in grain loop !OMP DO PARALLEL PRIVATE do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) crystallite_converged(g,i,e) = crystallite_todo(g,i,e) .or. crystallite_converged(g,i,e) ! if still "to do" then converged per definition enddo; enddo; enddo !OMP END DO PARALLEL end subroutine setConvergenceFlag !-------------------------------------------------------------------------------------------------- !> @brief determines whether a point is converged !-------------------------------------------------------------------------------------------------- logical pure function converged(residuum,state,aTol) real(pReal), intent(in), dimension(:) ::& residuum, state, aTol real(pReal) :: & rTol rTol = num%rTol_crystalliteState converged = all(abs(residuum) <= max(aTol, rTol*abs(state))) end function converged !-------------------------------------------------------------------------------------------------- !> @brief Standard forwarding of state as state = state0 + dotState * (delta t) comment seems wrong! !-------------------------------------------------------------------------------------------------- subroutine update_stress(timeFraction) real(pReal), intent(in) :: & timeFraction integer :: & e, & !< element index in element loop i, & !< integration point index in ip loop g !$OMP PARALLEL DO do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) !$OMP FLUSH(crystallite_todo) if (crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) then crystallite_todo(g,i,e) = integrateStress(g,i,e,timeFraction) !$OMP FLUSH(crystallite_todo) if (.not. crystallite_todo(g,i,e) .and. .not. crystallite_localPlasticity(g,i,e)) then ! if broken non-local... !$OMP CRITICAL (checkTodo) crystallite_todo = crystallite_todo .and. crystallite_localPlasticity ! ...all non-locals skipped !$OMP END CRITICAL (checkTodo) endif endif enddo; enddo; enddo !$OMP END PARALLEL DO end subroutine update_stress !-------------------------------------------------------------------------------------------------- !> @brief tbd !-------------------------------------------------------------------------------------------------- subroutine update_dependentState integer :: e, & ! element index in element loop i, & ! integration point index in ip loop g ! grain index in grain loop !$OMP PARALLEL DO do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) & call constitutive_dependentState(crystallite_Fe(1:3,1:3,g,i,e), & crystallite_Fp(1:3,1:3,g,i,e), & g, i, e) enddo; enddo; enddo !$OMP END PARALLEL DO end subroutine update_dependentState !-------------------------------------------------------------------------------------------------- !> @brief Standard forwarding of state as state = state0 + dotState * (delta t) !-------------------------------------------------------------------------------------------------- subroutine update_state(timeFraction) real(pReal), intent(in) :: & timeFraction integer :: & e, & !< element index in element loop i, & !< integration point index in ip loop g, & !< grain index in grain loop p, & c, & s, & mySize !$OMP PARALLEL DO PRIVATE(mySize,p,c) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) if (crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) then p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) mySize = plasticState(p)%sizeDotState plasticState(p)%state(1:mySize,c) = plasticState(p)%subState0(1:mySize,c) & + plasticState(p)%dotState (1:mySize,c) & * crystallite_subdt(g,i,e) * timeFraction do s = 1, phase_Nsources(p) mySize = sourceState(p)%p(s)%sizeDotState sourceState(p)%p(s)%state(1:mySize,c) = sourceState(p)%p(s)%subState0(1:mySize,c) & + sourceState(p)%p(s)%dotState (1:mySize,c) & * crystallite_subdt(g,i,e) * timeFraction enddo endif enddo; enddo; enddo !$OMP END PARALLEL DO end subroutine update_state !-------------------------------------------------------------------------------------------------- !> @brief triggers calculation of all new rates !> if NaN occurs, crystallite_todo is set to FALSE. Any NaN in a nonlocal propagates to all others !-------------------------------------------------------------------------------------------------- subroutine update_dotState(timeFraction) real(pReal), intent(in) :: & timeFraction integer :: & e, & !< element index in element loop i, & !< integration point index in ip loop g, & !< grain index in grain loop p, & c, & s logical :: & NaN, & nonlocalStop nonlocalStop = .false. !$OMP PARALLEL DO PRIVATE (p,c,NaN) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) !$OMP FLUSH(nonlocalStop) if ((crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) .and. .not. nonlocalStop) then call constitutive_collectDotState(crystallite_S(1:3,1:3,g,i,e), & crystallite_partionedF0, & crystallite_Fi(1:3,1:3,g,i,e), & crystallite_partionedFp0, & crystallite_subdt(g,i,e)*timeFraction, g,i,e) p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) NaN = any(IEEE_is_NaN(plasticState(p)%dotState(:,c))) do s = 1, phase_Nsources(p) NaN = NaN .or. any(IEEE_is_NaN(sourceState(p)%p(s)%dotState(:,c))) enddo if (NaN) then crystallite_todo(g,i,e) = .false. ! this one done (and broken) if (.not. crystallite_localPlasticity(g,i,e)) nonlocalStop = .True. endif endif enddo; enddo; enddo !$OMP END PARALLEL DO if (nonlocalStop) crystallite_todo = crystallite_todo .and. crystallite_localPlasticity end subroutine update_DotState subroutine update_deltaState integer :: & e, & !< element index in element loop i, & !< integration point index in ip loop g, & !< grain index in grain loop p, & mySize, & myOffset, & c, & s logical :: & NaN, & nonlocalStop nonlocalStop = .false. !$OMP PARALLEL DO PRIVATE(p,c,myOffset,mySize,NaN) do e = FEsolving_execElem(1),FEsolving_execElem(2) do i = FEsolving_execIP(1),FEsolving_execIP(2) do g = 1,homogenization_Ngrains(material_homogenizationAt(e)) !$OMP FLUSH(nonlocalStop) if ((crystallite_todo(g,i,e) .and. .not. crystallite_converged(g,i,e)) .and. .not. nonlocalStop) then call constitutive_collectDeltaState(crystallite_S(1:3,1:3,g,i,e), & crystallite_Fe(1:3,1:3,g,i,e), & crystallite_Fi(1:3,1:3,g,i,e), & g,i,e) p = material_phaseAt(g,e); c = material_phaseMemberAt(g,i,e) myOffset = plasticState(p)%offsetDeltaState mySize = plasticState(p)%sizeDeltaState NaN = any(IEEE_is_NaN(plasticState(p)%deltaState(1:mySize,c))) if (.not. NaN) then plasticState(p)%state(myOffset + 1: myOffset + mySize,c) = & plasticState(p)%state(myOffset + 1: myOffset + mySize,c) + plasticState(p)%deltaState(1:mySize,c) do s = 1, phase_Nsources(p) myOffset = sourceState(p)%p(s)%offsetDeltaState mySize = sourceState(p)%p(s)%sizeDeltaState NaN = NaN .or. any(IEEE_is_NaN(sourceState(p)%p(s)%deltaState(1:mySize,c))) if (.not. NaN) then sourceState(p)%p(s)%state(myOffset + 1:myOffset + mySize,c) = & sourceState(p)%p(s)%state(myOffset + 1:myOffset + mySize,c) + sourceState(p)%p(s)%deltaState(1:mySize,c) endif enddo endif crystallite_todo(g,i,e) = .not. NaN if (.not. crystallite_todo(g,i,e)) then ! if state jump fails, then convergence is broken crystallite_converged(g,i,e) = .false. if (.not. crystallite_localPlasticity(g,i,e)) nonlocalStop = .true. endif endif enddo; enddo; enddo !$OMP END PARALLEL DO if (nonlocalStop) crystallite_todo = crystallite_todo .and. crystallite_localPlasticity end subroutine update_deltaState !-------------------------------------------------------------------------------------------------- !> @brief calculates a jump in the state according to the current state and the current stress !> returns true, if state jump was successfull or not needed. false indicates NaN in delta state !-------------------------------------------------------------------------------------------------- logical function stateJump(ipc,ip,el) integer, intent(in):: & el, & ! element index ip, & ! integration point index ipc ! grain index integer :: & c, & p, & mySource, & myOffset, & mySize c = material_phaseMemberAt(ipc,ip,el) p = material_phaseAt(ipc,el) call constitutive_collectDeltaState(crystallite_S(1:3,1:3,ipc,ip,el), & crystallite_Fe(1:3,1:3,ipc,ip,el), & crystallite_Fi(1:3,1:3,ipc,ip,el), & ipc,ip,el) myOffset = plasticState(p)%offsetDeltaState mySize = plasticState(p)%sizeDeltaState if( any(IEEE_is_NaN(plasticState(p)%deltaState(1:mySize,c)))) then ! NaN occured in deltaState stateJump = .false. return endif plasticState(p)%state(myOffset + 1:myOffset + mySize,c) = & plasticState(p)%state(myOffset + 1:myOffset + mySize,c) + plasticState(p)%deltaState(1:mySize,c) do mySource = 1, phase_Nsources(p) myOffset = sourceState(p)%p(mySource)%offsetDeltaState mySize = sourceState(p)%p(mySource)%sizeDeltaState if (any(IEEE_is_NaN(sourceState(p)%p(mySource)%deltaState(1:mySize,c)))) then ! NaN occured in deltaState stateJump = .false. return endif sourceState(p)%p(mySource)%state(myOffset + 1: myOffset + mySize,c) = & sourceState(p)%p(mySource)%state(myOffset + 1: myOffset + mySize,c) + sourceState(p)%p(mySource)%deltaState(1:mySize,c) enddo #ifdef DEBUG if (any(dNeq0(plasticState(p)%deltaState(1:mySize,c))) & .and. iand(debug_level(debug_crystallite), debug_levelExtensive) /= 0 & .and. ((el == debug_e .and. ip == debug_i .and. ipc == debug_g) & .or. .not. iand(debug_level(debug_crystallite), debug_levelSelective) /= 0)) then write(6,'(a,i8,1x,i2,1x,i3, /)') '<< CRYST >> update state at el ip ipc ',el,ip,ipc write(6,'(a,/,(12x,12(e12.5,1x)),/)') '<< CRYST >> deltaState', plasticState(p)%deltaState(1:mySize,c) write(6,'(a,/,(12x,12(e12.5,1x)),/)') '<< CRYST >> new state', & plasticState(p)%state(myOffset + 1 : & myOffset + mySize,c) endif #endif stateJump = .true. end function stateJump end module crystallite