33class VCS_SPECIES_THERMO;
69 int vcs(
int ipr,
int ip1,
int maxit);
95 int vcs_solve_TP(
int print_lvl,
int printDetails,
int maxit);
159 int vcs_basopt(
const bool doJustComponents,
double aw[],
double sa[],
double sm[],
160 double ss[],
double test,
bool*
const usedZeroedSpecies);
173 size_t vcs_basisOptMax(
const double*
const molNum,
const size_t j,
const size_t n);
304 void vcs_dfe(
const int stateCalc,
const int ll,
const size_t lbot,
const size_t ltop);
386 void check_tmoles()
const;
417 void vcs_deltag(
const int L,
const bool doDeleted,
const int vcsState,
418 const bool alterZeroedPhases =
true);
420 void vcs_printDeltaG(
const int stateCalc);
434 void vcs_switch_pos(
const bool ifunc,
const size_t k1,
const size_t k2);
468 int vcs_TP(
int ipr,
int ip1,
int maxit,
double T,
double pres);
480 int vcs_evalSS_TP(
int ipr,
int ip1,
double Temp,
double pres);
504 double vcs_VolTotal(
const double tkelvin,
const double pres,
505 const double w[],
double volPM[]);
574 double*
const sm,
double*
const ss);
660 void vcs_elabPhase(
size_t iphase,
double*
const elemAbundPhase);
737 const double*
const fe);
804 int delta_species(
const size_t kspec,
double*
const delta_ptr);
872 char* ANOTE=0)
const;
904 void checkDelta1(
double*
const ds,
double*
const delTPhMoles,
size_t kspec);
918 void vcs_inest(
double*
const aw,
double*
const sa,
double*
const sm,
919 double*
const ss,
double test);
948 void vcs_setFlagsVolPhases(
const bool upToDate,
const int stateCalc);
950 void vcs_setFlagsVolPhase(
const size_t iph,
const bool upToDate,
const int stateCalc);
963 int solve_tp_component_calc(
bool& allMinorZeroedSpecies);
964 void solve_tp_inner(
size_t& iti,
size_t& it1,
bool& uptodate_minors,
965 bool& allMinorZeroedSpecies,
int& forceComponentCalc,
966 int& stage,
bool printDetails,
char* ANOTE);
967 void solve_tp_equilib_check(
bool& allMinorZeroedSpecies,
bool& uptodate_minors,
968 bool& giveUpOnElemAbund,
int& solveFail,
969 size_t& iti,
size_t& it1,
int maxit,
970 int& stage,
bool& lec);
971 void solve_tp_elem_abund_check(
size_t& iti,
int& stage,
bool& lec,
972 bool& giveUpOnElemAbund,
973 int& finalElemAbundAttempts,
974 int& rangeErrorFound);
1040 size_t addElement(
const char* elNameNew,
int elType,
int elactive);
1042 void reportCSV(
const string& reportFile);
1454 vector<vector<size_t>> phasePopProblemLists_;
1512 friend class vcs_phaseStabilitySolve;
Header file for class Cantera::Array2D.
A class for 2D arrays stored in column-major (Fortran-compatible) form.
A class for multiphase mixtures.
Class to keep track of time and iterations.
This is the main structure used to hold the internal data used in vcs_solve_TP(), and to solve TP sys...
size_t vcs_popPhaseID(vector< size_t > &phasePopPhaseIDs)
Decision as to whether a phase pops back into existence.
vector< double > m_deltaPhaseMoles
Change in the total moles in each phase.
size_t m_numPhases
Number of Phases in the problem.
int m_doEstimateEquil
Setting for whether to do an initial estimate.
vector< double > m_deltaMolNumSpecies
Reaction Adjustments for each species during the current step.
vector< double > m_spSize
total size of the species
vector< double > m_scSize
Absolute size of the stoichiometric coefficients.
int vcs_evalSS_TP(int ipr, int ip1, double Temp, double pres)
Evaluate the standard state free energies at the current temperature and pressure.
vector< double > m_wtSpecies
Molecular weight of each species.
vector< size_t > m_indexRxnToSpecies
Mapping between the species index for noncomponent species and the full species index.
int vcs_inest_TP()
Create an initial estimate of the solution to the thermodynamic equilibrium problem.
vector< size_t > m_phaseID
Mapping from the species number to the phase number.
vector< string > m_speciesName
Species string name for the kth species.
void vcs_deltag(const int L, const bool doDeleted, const int vcsState, const bool alterZeroedPhases=true)
This subroutine calculates reaction free energy changes for all noncomponent formation reactions.
double m_tolmaj2
Below this, major species aren't refined any more.
double vcs_VolTotal(const double tkelvin, const double pres, const double w[], double volPM[])
Calculation of the total volume and the partial molar volumes.
int vcs_elem_rearrange(double *const aw, double *const sa, double *const sm, double *const ss)
Rearrange the constraint equations represented by the Formula Matrix so that the operational ones are...
vector< double > m_deltaGRxn_new
Delta G(irxn) for the noncomponent species in the mechanism.
Array2D m_np_dLnActCoeffdMolNum
Change in the log of the activity coefficient with respect to the mole number multiplied by the phase...
void vcs_updateMolNumVolPhases(const int stateCalc)
Update all underlying vcs_VolPhase objects.
size_t m_nelem
Number of element constraints in the problem.
vector< double > m_PMVolumeSpecies
Partial molar volumes of the species.
vector< int > m_elementActive
Specifies whether an element constraint is active.
int m_useActCoeffJac
Choice of Hessians.
vector< size_t > m_speciesLocalPhaseIndex
Index that keeps track of the index of the species within the local phase.
void vcs_updateVP(const int stateCalc)
This routine uploads the state of the system into all of the vcs_VolumePhase objects in the current p...
double m_totalVol
Total volume of all phases. Units are m^3.
size_t vcs_add_all_deleted()
Provide an estimate for the deleted species in phases that are not zeroed out.
bool vcs_globStepDamp()
This routine optimizes the minimization of the total Gibbs free energy by making sure the slope of th...
int vcs_basopt(const bool doJustComponents, double aw[], double sa[], double sm[], double ss[], double test, bool *const usedZeroedSpecies)
Choose the optimum species basis for the calculations.
int vcs_prep(int printLvl)
This routine is mostly concerned with changing the private data to be consistent with what's needed f...
vector< string > m_elementName
Vector of strings containing the element names.
vector< int > m_speciesUnknownType
Specifies the species unknown type.
int vcs_elcorr(double aa[], double x[])
This subroutine corrects for element abundances.
vector< double > m_TmpPhase
Temporary vector of length NPhase.
size_t vcs_basisOptMax(const double *const molNum, const size_t j, const size_t n)
Choose a species to test for the next component.
vector< size_t > m_speciesMapIndex
Index vector that keeps track of the species vector rearrangement.
void vcs_TCounters_report(int timing_print_lvl=1)
Create a report on the plog file containing timing and its information.
Array2D m_phaseParticipation
This is 1 if the phase, iphase, participates in the formation reaction irxn, and zero otherwise.
static void disableTiming()
Disable printing of timing information.
vector< int > m_actConventionSpecies
specifies the activity convention of the phase containing the species
double vcs_phaseStabilityTest(const size_t iph)
Main program to test whether a deleted phase should be brought back into existence.
vector< double > m_elemAbundances
Element abundances vector.
vector< double > m_tPhaseMoles_new
total kmols of species in each phase in the tentative soln vector
void vcs_inest(double *const aw, double *const sa, double *const sm, double *const ss, double test)
Estimate equilibrium compositions.
vector< double > m_actCoeffSpecies_old
Molar-based Activity Coefficients for Species based on old mole numbers.
vector< double > m_SSfeSpecies
Standard state chemical potentials for species K at the current temperature and pressure.
bool vcs_popPhasePossible(const size_t iphasePop) const
Utility function that evaluates whether a phase can be popped into existence.
double l2normdg(double dg[]) const
Calculate the norm of a deltaGibbs free energy vector.
int delta_species(const size_t kspec, double *const delta_ptr)
Change the concentration of a species by delta moles.
int vcs_TP(int ipr, int ip1, int maxit, double T, double pres)
Solve an equilibrium problem at a particular fixed temperature and pressure.
double m_tolmin2
Below this, minor species aren't refined any more.
vector< double > m_lnMnaughtSpecies
specifies the ln(Mnaught) used to calculate the chemical potentials
vector< int > m_elType
Type of the element constraint.
void vcs_elab()
Computes the current elemental abundances vector.
void prob_report(int print_lvl)
Print out the problem specification in all generality as it currently exists in the VCS_SOLVE object.
int m_timing_print_lvl
printing level of timing information
int vcs_setMolesLinProg()
Estimate the initial mole numbers by constrained linear programming.
vector< double > m_molNumSpecies_old
Total moles of the species.
vector< double > TPhInertMoles
Total kmoles of inert to add to each phase.
double vcs_Total_Gibbs(double *w, double *fe, double *tPhMoles)
Calculate the total dimensionless Gibbs free energy.
void vcs_CalcLnActCoeffJac(const double *const moleSpeciesVCS)
Recalculate all of the activity coefficients in all of the phases based on input mole numbers.
size_t m_numRxnMinorZeroed
Number of active species which are currently either treated as minor species.
vector< size_t > m_elementMapIndex
Index vector that keeps track of the rearrangement of the elements.
void vcs_elabPhase(size_t iphase, double *const elemAbundPhase)
Computes the elemental abundances vector for a single phase, elemAbundPhase[], and returns it through...
size_t m_numSpeciesRdc
Current number of species in the problems.
int vcs_delete_species(const size_t kspec)
Change a single species from active to inactive status.
vector< double > m_feSpecies_old
Free energy vector from the start of the current iteration.
int m_debug_print_lvl
Debug printing lvl.
void vcs_counters_init(int ifunc)
Initialize the internal counters.
void vcs_reinsert_deleted(size_t kspec)
We make decisions on the initial mole number, and major-minor status here.
vector< double > m_chargeSpecies
Charge of each species. Length = number of species.
Array2D m_formulaMatrix
Formula matrix for the problem.
void addPhaseElements(vcs_VolPhase *volPhase)
Add elements to the local element list.
int vcs_solve_TP(int print_lvl, int printDetails, int maxit)
Main routine that solves for equilibrium at constant T and P using a variant of the VCS method.
size_t addOnePhaseSpecies(vcs_VolPhase *volPhase, size_t k, size_t kT)
This routines adds entries for the formula matrix for one species.
Array2D m_stoichCoeffRxnMatrix
Stoichiometric coefficient matrix for the reaction mechanism expressed in Reduced Canonical Form.
size_t m_numRxnRdc
Current number of non-component species in the problem.
VCS_COUNTERS * m_VCount
Timing and iteration counters for the vcs object.
int vcs(int ipr, int ip1, int maxit)
Solve an equilibrium problem.
vector< double > m_deltaGRxn_Deficient
Last deltag[irxn] from the previous step with additions for possible births of zeroed phases.
vector< unique_ptr< vcs_VolPhase > > m_VolPhaseList
Array of Phase Structures. Length = number of phases.
double vcs_Hessian_diag_adj(size_t irxn, double hessianDiag_Ideal)
Calculates the diagonal contribution to the Hessian due to the dependence of the activity coefficient...
double vcs_GibbsPhase(size_t iphase, const double *const w, const double *const fe)
Calculate the total dimensionless Gibbs free energy of a single phase.
size_t m_numComponents
Number of components calculated for the problem.
void vcs_prob_specifyFully()
Fully specify the problem to be solved.
int vcs_species_type(const size_t kspec) const
Evaluate the species category for the indicated species.
double m_pressurePA
Pressure.
void vcs_SSPhase()
Calculate the status of single species phases.
int vcs_report(int iconv)
Print out a report on the state of the equilibrium problem to standard output.
vector< double > m_feSpecies_new
Dimensionless new free energy for all the species in the mechanism at the new tentative T,...
double m_Faraday_dim
dimensionless value of Faraday's constant, F / RT (1/volt)
int vcs_recheck_deleted()
Recheck deleted species in multispecies phases.
double m_tolmin
Tolerance requirements for minor species.
size_t m_nsp
Total number of species in the problems.
vector< double > m_actCoeffSpecies_new
Molar-based Activity Coefficients for Species.
bool vcs_elabcheck(int ibound)
Checks to see if the element abundances are in compliance.
vector< unique_ptr< VCS_SPECIES_THERMO > > m_speciesThermoList
Vector of pointers to thermo structures which identify the model and parameters for evaluating the th...
vector< char > m_SSPhase
Boolean indicating whether a species belongs to a single-species phase.
bool vcs_delete_multiphase(const size_t iph)
This routine handles the bookkeeping involved with the deletion of multiphase phases from the problem...
void vcs_delete_memory()
Delete memory that isn't just resizable STL containers.
vector< double > m_phasePhi
electric potential of the iph phase
double vcs_Hessian_actCoeff_diag(size_t irxn)
Calculates the diagonal contribution to the Hessian due to the dependence of the activity coefficient...
int vcs_zero_species(const size_t kspec)
Zero out the concentration of a species.
vector< double > m_elemAbundancesGoal
Element abundances vector Goals.
void vcs_prob_update()
Transfer the results of the equilibrium calculation back from VCS_SOLVE.
size_t vcs_RxnStepSizes(int &forceComponentCalc, size_t &kSpecial)
Calculates formation reaction step sizes.
Array2D m_deltaMolNumPhase
Change in the number of moles of phase, iphase, due to the noncomponent formation reaction,...
vector< int > m_phaseActConvention
specifies the activity convention of the phase.
vector< int > m_speciesStatus
Major -Minor status vector for the species in the problem.
vector< double > m_deltaGRxn_tmp
Temporary vector of Rxn DeltaG's.
vector< double > m_TmpPhase2
Temporary vector of length NPhase.
void vcs_switch_elem_pos(size_t ipos, size_t jpos)
Swaps the indices for all of the global data for two elements, ipos and jpos.
double vcs_minor_alt_calc(size_t kspec, size_t irxn, bool *do_delete, char *ANOTE=0) const
Minor species alternative calculation.
double vcs_tmoles()
Calculates the total number of moles of species in all phases.
void vcs_switch_pos(const bool ifunc, const size_t k1, const size_t k2)
Swaps the indices for all of the global data for two species, k1 and k2.
int m_printLvl
Print level for print routines.
void vcs_dfe(const int stateCalc, const int ll, const size_t lbot, const size_t ltop)
Calculate the dimensionless chemical potentials of all species or of certain groups of species,...
vector< double > m_tPhaseMoles_old
Total kmols of species in each phase.
int vcs_popPhaseRxnStepSizes(const size_t iphasePop)
Calculates the deltas of the reactions due to phases popping into existence.
size_t m_numRxnTot
Total number of non-component species in the problem.
vector< double > m_molNumSpecies_new
Tentative value of the mole number vector.
void vcs_fePrep_TP()
Initialize the chemical potential of single species phases.
double m_temperature
Temperature (Kelvin)
double m_tolmaj
Tolerance requirement for major species.
vector< double > m_deltaGRxn_old
Last deltag[irxn] from the previous step.
bool vcs_evaluate_speciesType()
This routine evaluates the species type for all species.
size_t addElement(const char *elNameNew, int elType, int elactive)
This routine resizes the number of elements in the VCS_SOLVE object by adding a new element to the en...
double m_totalMolNum
Total number of kmoles in all phases.
Phase information and Phase calculations for vcs.
This file contains definitions of constants, types and terms that are used in internal routines and a...
Namespace for the Cantera kernel.
Defines and definitions within the vcs package.
Internal declarations for the VCSnonideal package.