This is the main structure used to hold the internal data used in vcs_solve_TP(), and to solve TP systems. More...
#include <vcs_solve.h>
This is the main structure used to hold the internal data used in vcs_solve_TP(), and to solve TP systems.
The indices of information in this structure may change when the species basis changes or when phases pop in and out of existence. Both of these operations change the species ordering.
Definition at line 44 of file vcs_solve.h.
Public Member Functions | |
VCS_SOLVE (MultiPhase *mphase, int printLvl=0) | |
Initialize the sizes within the VCS_SOLVE object. | |
int | vcs (int ipr, int ip1, int maxit) |
Solve an equilibrium problem. | |
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. | |
void | vcs_reinsert_deleted (size_t kspec) |
We make decisions on the initial mole number, and major-minor status here. | |
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. | |
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. | |
int | vcs_species_type (const size_t kspec) const |
Evaluate the species category for the indicated species. | |
bool | vcs_evaluate_speciesType () |
This routine evaluates the species type for all species. | |
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, at a fixed temperature and pressure. | |
void | vcs_updateVP (const int stateCalc) |
This routine uploads the state of the system into all of the vcs_VolumePhase objects in the current problem. | |
bool | vcs_popPhasePossible (const size_t iphasePop) const |
Utility function that evaluates whether a phase can be popped into existence. | |
size_t | vcs_popPhaseID (vector< size_t > &phasePopPhaseIDs) |
Decision as to whether a phase pops back into existence. | |
int | vcs_popPhaseRxnStepSizes (const size_t iphasePop) |
Calculates the deltas of the reactions due to phases popping into existence. | |
size_t | vcs_RxnStepSizes (int &forceComponentCalc, size_t &kSpecial) |
Calculates formation reaction step sizes. | |
double | vcs_tmoles () |
Calculates the total number of moles of species in all phases. | |
void | check_tmoles () const |
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. | |
void | vcs_printDeltaG (const int stateCalc) |
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. | |
double | vcs_phaseStabilityTest (const size_t iph) |
Main program to test whether a deleted phase should be brought back into existence. | |
int | vcs_TP (int ipr, int ip1, int maxit, double T, double pres) |
Solve an equilibrium problem at a particular fixed temperature and pressure. | |
int | vcs_evalSS_TP (int ipr, int ip1, double Temp, double pres) |
Evaluate the standard state free energies at the current temperature and pressure. | |
void | vcs_fePrep_TP () |
Initialize the chemical potential of single species phases. | |
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_prep (int printLvl) |
This routine is mostly concerned with changing the private data to be consistent with what's needed for solution. | |
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 in the front. | |
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_Hessian_diag_adj (size_t irxn, double hessianDiag_Ideal) |
Calculates the diagonal contribution to the Hessian due to the dependence of the activity coefficients on the mole numbers. | |
double | vcs_Hessian_actCoeff_diag (size_t irxn) |
Calculates the diagonal contribution to the Hessian due to the dependence of the activity coefficients on the mole numbers. | |
void | vcs_CalcLnActCoeffJac (const double *const moleSpeciesVCS) |
Recalculate all of the activity coefficients in all of the phases based on input mole numbers. | |
int | vcs_report (int iconv) |
Print out a report on the state of the equilibrium problem to standard output. | |
void | vcs_elab () |
Computes the current elemental abundances vector. | |
bool | vcs_elabcheck (int ibound) |
Checks to see if the element abundances are in compliance. | |
void | vcs_elabPhase (size_t iphase, double *const elemAbundPhase) |
Computes the elemental abundances vector for a single phase, elemAbundPhase[], and returns it through the argument list. | |
int | vcs_elcorr (double aa[], double x[]) |
This subroutine corrects for element abundances. | |
int | vcs_inest_TP () |
Create an initial estimate of the solution to the thermodynamic equilibrium problem. | |
int | vcs_setMolesLinProg () |
Estimate the initial mole numbers by constrained linear programming. | |
double | vcs_Total_Gibbs (double *w, double *fe, double *tPhMoles) |
Calculate the total dimensionless Gibbs free energy. | |
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. | |
void | vcs_prob_update () |
Transfer the results of the equilibrium calculation back from VCS_SOLVE. | |
void | vcs_prob_specifyFully () |
Fully specify the problem to be solved. | |
void | prob_report (int print_lvl) |
Print out the problem specification in all generality as it currently exists in the VCS_SOLVE object. | |
void | addPhaseElements (vcs_VolPhase *volPhase) |
Add elements to the local element list. | |
size_t | addOnePhaseSpecies (vcs_VolPhase *volPhase, size_t k, size_t kT) |
This routines adds entries for the formula matrix for one 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 end of the element list. | |
void | reportCSV (const string &reportFile) |
Static Public Member Functions | |
static void | disableTiming () |
Disable printing of timing information. | |
Public Attributes | |
int | m_printLvl |
Print level for print routines. | |
MultiPhase * | m_mix |
size_t | m_nsp |
Total number of species in the problems. | |
size_t | m_nelem = 0 |
Number of element constraints in the problem. | |
size_t | m_numComponents = 0 |
Number of components calculated for the problem. | |
size_t | m_numRxnTot = 0 |
Total number of non-component species in the problem. | |
size_t | m_numSpeciesRdc |
Current number of species in the problems. | |
size_t | m_numRxnRdc = 0 |
Current number of non-component species in the problem. | |
size_t | m_numRxnMinorZeroed = 0 |
Number of active species which are currently either treated as minor species. | |
size_t | m_numPhases |
Number of Phases in the problem. | |
Array2D | m_formulaMatrix |
Formula matrix for the problem. | |
Array2D | m_stoichCoeffRxnMatrix |
Stoichiometric coefficient matrix for the reaction mechanism expressed in Reduced Canonical Form. | |
vector< double > | m_scSize |
Absolute size of the stoichiometric coefficients. | |
vector< double > | m_spSize |
total size of the species | |
vector< double > | m_SSfeSpecies |
Standard state chemical potentials for species K at the current temperature and pressure. | |
vector< double > | m_feSpecies_old |
Free energy vector from the start of the current iteration. | |
vector< double > | m_feSpecies_new |
Dimensionless new free energy for all the species in the mechanism at the new tentative T, P, and mole numbers. | |
int | m_doEstimateEquil = -1 |
Setting for whether to do an initial estimate. | |
vector< double > | m_molNumSpecies_old |
Total moles of the species. | |
vector< int > | m_speciesUnknownType |
Specifies the species unknown type. | |
Array2D | m_deltaMolNumPhase |
Change in the number of moles of phase, iphase, due to the noncomponent formation reaction, irxn, for species, k: | |
Array2D | m_phaseParticipation |
This is 1 if the phase, iphase, participates in the formation reaction irxn, and zero otherwise. | |
vector< double > | m_phasePhi |
electric potential of the iph phase | |
vector< double > | m_molNumSpecies_new |
Tentative value of the mole number vector. | |
vector< double > | m_deltaGRxn_new |
Delta G(irxn) for the noncomponent species in the mechanism. | |
vector< double > | m_deltaGRxn_old |
Last deltag[irxn] from the previous step. | |
vector< double > | m_deltaGRxn_Deficient |
Last deltag[irxn] from the previous step with additions for possible births of zeroed phases. | |
vector< double > | m_deltaGRxn_tmp |
Temporary vector of Rxn DeltaG's. | |
vector< double > | m_deltaMolNumSpecies |
Reaction Adjustments for each species during the current step. | |
vector< double > | m_elemAbundances |
Element abundances vector. | |
vector< double > | m_elemAbundancesGoal |
Element abundances vector Goals. | |
double | m_totalMolNum = 0.0 |
Total number of kmoles in all phases. | |
vector< double > | m_tPhaseMoles_old |
Total kmols of species in each phase. | |
vector< double > | m_tPhaseMoles_new |
total kmols of species in each phase in the tentative soln vector | |
vector< double > | m_TmpPhase |
Temporary vector of length NPhase. | |
vector< double > | m_TmpPhase2 |
Temporary vector of length NPhase. | |
vector< double > | m_deltaPhaseMoles |
Change in the total moles in each phase. | |
double | m_temperature |
Temperature (Kelvin) | |
double | m_pressurePA |
Pressure. | |
vector< double > | TPhInertMoles |
Total kmoles of inert to add to each phase. | |
double | m_tolmaj = 1e-8 |
Tolerance requirement for major species. | |
double | m_tolmin = 1e-6 |
Tolerance requirements for minor species. | |
double | m_tolmaj2 = 1e-10 |
Below this, major species aren't refined any more. | |
double | m_tolmin2 = 1e-8 |
Below this, minor species aren't refined any more. | |
vector< size_t > | m_speciesMapIndex |
Index vector that keeps track of the species vector rearrangement. | |
vector< size_t > | m_speciesLocalPhaseIndex |
Index that keeps track of the index of the species within the local phase. | |
vector< size_t > | m_elementMapIndex |
Index vector that keeps track of the rearrangement of the elements. | |
vector< size_t > | m_indexRxnToSpecies |
Mapping between the species index for noncomponent species and the full species index. | |
vector< int > | m_speciesStatus |
Major -Minor status vector for the species in the problem. | |
vector< size_t > | m_phaseID |
Mapping from the species number to the phase number. | |
vector< char > | m_SSPhase |
Boolean indicating whether a species belongs to a single-species phase. | |
vector< string > | m_speciesName |
Species string name for the kth species. | |
vector< string > | m_elementName |
Vector of strings containing the element names. | |
vector< int > | m_elType |
Type of the element constraint. | |
vector< int > | m_elementActive |
Specifies whether an element constraint is active. | |
vector< unique_ptr< vcs_VolPhase > > | m_VolPhaseList |
Array of Phase Structures. Length = number of phases. | |
vector< int > | m_actConventionSpecies |
specifies the activity convention of the phase containing the species | |
vector< int > | m_phaseActConvention |
specifies the activity convention of the phase. | |
vector< double > | m_lnMnaughtSpecies |
specifies the ln(Mnaught) used to calculate the chemical potentials | |
vector< double > | m_actCoeffSpecies_new |
Molar-based Activity Coefficients for Species. | |
vector< double > | m_actCoeffSpecies_old |
Molar-based Activity Coefficients for Species based on old mole numbers. | |
Array2D | m_np_dLnActCoeffdMolNum |
Change in the log of the activity coefficient with respect to the mole number multiplied by the phase mole number. | |
vector< double > | m_wtSpecies |
Molecular weight of each species. | |
vector< double > | m_chargeSpecies |
Charge of each species. Length = number of species. | |
vector< vector< size_t > > | phasePopProblemLists_ |
vector< unique_ptr< VCS_SPECIES_THERMO > > | m_speciesThermoList |
Vector of pointers to thermo structures which identify the model and parameters for evaluating the thermodynamic functions for that particular species. | |
int | m_useActCoeffJac = 0 |
Choice of Hessians. | |
double | m_totalVol |
Total volume of all phases. Units are m^3. | |
vector< double > | m_PMVolumeSpecies |
Partial molar volumes of the species. | |
double | m_Faraday_dim |
dimensionless value of Faraday's constant, F / RT (1/volt) | |
VCS_COUNTERS * | m_VCount = nullptr |
Timing and iteration counters for the vcs object. | |
int | m_debug_print_lvl = 0 |
Debug printing lvl. | |
int | m_timing_print_lvl = 1 |
printing level of timing information | |
Private Member Functions | |
int | vcs_zero_species (const size_t kspec) |
Zero out the concentration of a species. | |
int | vcs_delete_species (const size_t kspec) |
Change a single species from active to inactive status. | |
bool | vcs_delete_multiphase (const size_t iph) |
This routine handles the bookkeeping involved with the deletion of multiphase phases from the problem. | |
int | delta_species (const size_t kspec, double *const delta_ptr) |
Change the concentration of a species by delta moles. | |
size_t | vcs_add_all_deleted () |
Provide an estimate for the deleted species in phases that are not zeroed out. | |
int | vcs_recheck_deleted () |
Recheck deleted species in multispecies phases. | |
double | vcs_minor_alt_calc (size_t kspec, size_t irxn, bool *do_delete, char *ANOTE=0) const |
Minor species alternative calculation. | |
bool | vcs_globStepDamp () |
This routine optimizes the minimization of the total Gibbs free energy by making sure the slope of the following functional stays negative: | |
double | l2normdg (double dg[]) const |
Calculate the norm of a deltaGibbs free energy vector. | |
void | checkDelta1 (double *const ds, double *const delTPhMoles, size_t kspec) |
void | vcs_inest (double *const aw, double *const sa, double *const sm, double *const ss, double test) |
Estimate equilibrium compositions. | |
void | vcs_SSPhase () |
Calculate the status of single species phases. | |
void | vcs_delete_memory () |
Delete memory that isn't just resizable STL containers. | |
void | vcs_counters_init (int ifunc) |
Initialize the internal counters. | |
void | vcs_TCounters_report (int timing_print_lvl=1) |
Create a report on the plog file containing timing and its information. | |
void | vcs_setFlagsVolPhases (const bool upToDate, const int stateCalc) |
void | vcs_setFlagsVolPhase (const size_t iph, const bool upToDate, const int stateCalc) |
void | vcs_updateMolNumVolPhases (const int stateCalc) |
Update all underlying vcs_VolPhase objects. | |
int | solve_tp_component_calc (bool &allMinorZeroedSpecies) |
void | solve_tp_inner (size_t &iti, size_t &it1, bool &uptodate_minors, bool &allMinorZeroedSpecies, int &forceComponentCalc, int &stage, bool printDetails, char *ANOTE) |
void | solve_tp_equilib_check (bool &allMinorZeroedSpecies, bool &uptodate_minors, bool &giveUpOnElemAbund, int &solveFail, size_t &iti, size_t &it1, int maxit, int &stage, bool &lec) |
void | solve_tp_elem_abund_check (size_t &iti, int &stage, bool &lec, bool &giveUpOnElemAbund, int &finalElemAbundAttempts, int &rangeErrorFound) |
Private Attributes | |
vector< double > | m_sm |
vector< double > | m_ss |
vector< double > | m_sa |
vector< double > | m_aw |
vector< double > | m_wx |
Friends | |
class | vcs_phaseStabilitySolve |
VCS_SOLVE | ( | MultiPhase * | mphase, |
int | printLvl = 0 |
||
) |
Initialize the sizes within the VCS_SOLVE object.
This resizes all of the internal arrays within the object.
Definition at line 44 of file vcs_solve.cpp.
~VCS_SOLVE | ( | ) |
Definition at line 471 of file vcs_solve.cpp.
int vcs | ( | int | ipr, |
int | ip1, | ||
int | maxit | ||
) |
Solve an equilibrium problem.
This is the main interface routine to the equilibrium solver
ipr | Printing of results ipr = 1 -> Print problem statement and final results to standard output 0 -> don't report on anything |
ip1 | Printing of intermediate results IP1 = 1 -> Print intermediate results. |
maxit | Maximum number of iterations for the algorithm |
Definition at line 476 of file vcs_solve.cpp.
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.
This is the main routine that solves for equilibrium at constant T and P using a variant of the VCS method. Nonideal phases can be accommodated as well.
Any number of single-species phases and multi-species phases can be handled by the present version.
print_lvl | 1 -> Print results to standard output; 0 -> don't report on anything |
printDetails | 1 -> Print intermediate results. |
maxit | Maximum number of iterations for the algorithm |
Definition at line 49 of file vcs_solve_TP.cpp.
void vcs_reinsert_deleted | ( | size_t | kspec | ) |
We make decisions on the initial mole number, and major-minor status here.
We also fix up the total moles in a phase.
irxn = id of the noncomponent species formation reaction for the species to be added in.
The algorithm proceeds to implement these decisions in the previous position of the species. Then, vcs_switch_pos is called to move the species into the last active species slot, incrementing the number of active species at the same time.
This routine is responsible for the global data manipulation only.
Definition at line 1572 of file vcs_solve_TP.cpp.
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.
This is done by choosing the species with the largest mole fraction not currently a linear combination of the previous components. Then, calculate the stoichiometric coefficient matrix for that basis.
Rearranges the solution data to put the component data at the front of the species list.
Then, calculates m_stoichCoeffRxnMatrix(jcomp,irxn)
the formation reactions for all noncomponent species in the mechanism. Also calculates DNG(I) and DNL(I), the net mole change for each formation reaction. Also, initializes IR(I) to the default state.
[in] | doJustComponents | If true, the m_stoichCoeffRxnMatrix and m_deltaMolNumPhase are not calculated. |
[in] | aw | Vector of mole fractions which will be used to construct an optimal basis from. |
[in] | sa | Gram-Schmidt orthog work space (nc in length) sa[j] |
[in] | ss | Gram-Schmidt orthog work space (nc in length) ss[j] |
[in] | sm | QR matrix work space (nc*ne in length) sm[i+j*ne] |
[in] | test | This is a small negative number dependent upon whether an estimate is supplied or not. |
[out] | usedZeroedSpecies | If true, then a species with a zero concentration was used as a component. The problem may be converged. Or, the problem may have a range space error and may not have a proper solution. |
m_stoichCoeffRxnMatrix(jcomp,irxn)
Stoichiometric coefficient matrix for the reaction mechanism expressed in Reduced Canonical Form. jcomp refers to the component number, and irxn refers to the irxn_th non-component species.m_deltaMolNumPhase(iphase,irxn)
: Change in the number of moles in phase, iphase, due to the noncomponent formation reaction, irxn.m_phaseParticipation(iphase,irxn)
: This is 1 if the phase, iphase, participates in the formation reaction, irxn, and zero otherwise. Definition at line 2015 of file vcs_solve_TP.cpp.
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.
We make the choice based on testing (molNum[i] * spSize[i]) for its maximum value. Preference for single species phases is also made.
molNum | Mole number vector |
j | index into molNum[] that indicates where the search will start from Previous successful components are swapped into the front of molNum[]. |
n | Length of molNum[] |
Definition at line 2499 of file vcs_solve_TP.cpp.
int vcs_species_type | ( | const size_t | kspec | ) | const |
Evaluate the species category for the indicated species.
All evaluations are done using the "old" version of the solution.
kspec | Species to be evaluated |
Definition at line 2550 of file vcs_solve_TP.cpp.
bool vcs_evaluate_speciesType | ( | ) |
This routine evaluates the species type for all species.
Definition at line 3007 of file vcs_solve_TP.cpp.
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, at a fixed temperature and pressure.
We calculate the dimensionless chemical potentials of all species or certain groups of species here, at a fixed temperature and pressure, for the input mole vector z[] in the parameter list. Nondimensionalization is achieved by division by RT.
Note, for multispecies phases which are currently zeroed out, the chemical potential is filled out with the standard chemical potential.
For species in multispecies phases whose concentration is zero, we need to set the mole fraction to a very low value. Its chemical potential is then calculated using the VCS_DELETE_MINORSPECIES_CUTOFF concentration to keep numbers positive.
For formulas, see vcs_chemPotPhase().
As per the discussion above, for small species where the mole fraction
z(i) < VCS_DELETE_MINORSPECIES_CUTOFF
The chemical potential is calculated as:
m_feSpecies(I)(I) = m_SSfeSpecies(I) + ln(ActCoeff[i](VCS_DELETE_MINORSPECIES_CUTOFF))
Species in the following categories are treated as "small species"
For species in multispecies phases which are currently not active, the treatment is different. These species are in the following species categories:
For these species, the ln( ActCoeff[I] X[I])
term is dropped altogether. The following equation is used:
m_feSpecies(I) = m_SSfeSpecies(I) + Charge[I] * Faraday_dim * phasePhi[iphase];
These species have species types of VCS_SPECIES_TYPE_INTERFACIALVOLTAGE The chemical potentials for these "species" refer to electrons in metal electrodes. They have the following formula
m_feSpecies(I) = m_SSfeSpecies(I) - F z[I] / RT
F
is Faraday's constant.R
= gas constantT
= temperatureV
= potential of the interface = phi_electrode - phi_solutionFor these species, the solution vector unknown, z[I], is V, the phase voltage, in volts.
ll | Determine which group of species gets updated
|
lbot | Restricts the calculation of the chemical potential to the species between LBOT <= i < LTOP. Usually LBOT and LTOP will be equal to 0 and MR, respectively. |
ltop | Top value of the loops |
stateCalc | Determines whether z is old or new or tentative:
|
Also needed: ff : standard state chemical potentials. These are the chemical potentials of the standard states at the same T and P as the solution. tg : Total Number of moles in the phase.
Definition at line 2703 of file vcs_solve_TP.cpp.
void vcs_updateVP | ( | const int | stateCalc | ) |
This routine uploads the state of the system into all of the vcs_VolumePhase objects in the current problem.
stateCalc | Determines where to get the mole numbers from.
|
Definition at line 2988 of file vcs_solve_TP.cpp.
bool vcs_popPhasePossible | ( | const size_t | iphasePop | ) | const |
Utility function that evaluates whether a phase can be popped into existence.
A phase can be popped iff the stoichiometric coefficients for the component species, whose concentrations will be lowered during the process, are positive by at least a small degree.
If one of the phase species is a zeroed component, then the phase can be popped if the component increases in mole number as the phase moles are increased.
iphasePop | id of the phase, which is currently zeroed, |
Definition at line 528 of file vcs_solve.cpp.
size_t vcs_popPhaseID | ( | vector< size_t > & | phasePopPhaseIDs | ) |
Decision as to whether a phase pops back into existence.
phasePopPhaseIDs | Vector containing the phase ids of the phases that will be popped this step. |
Definition at line 617 of file vcs_solve.cpp.
int vcs_popPhaseRxnStepSizes | ( | const size_t | iphasePop | ) |
Calculates the deltas of the reactions due to phases popping into existence.
Updates m_deltaMolNumSpecies[irxn] : reaction adjustments, where irxn refers to the irxn'th species formation reaction. This adjustment is for species irxn + M, where M is the number of components.
iphasePop | Phase id of the phase that will come into existence |
Definition at line 708 of file vcs_solve.cpp.
size_t vcs_RxnStepSizes | ( | int & | forceComponentCalc, |
size_t & | kSpecial | ||
) |
Calculates formation reaction step sizes.
This is equation 6.4-16, p. 143 in Smith and Missen [40].
m_deltaMolNumSpecies(irxn) : reaction adjustments, where irxn refers to the irxn'th species formation reaction. This adjustment is for species irxn + M, where M is the number of components.
Special branching occurs sometimes. This causes the component basis to be reevaluated
forceComponentCalc | integer flagging whether a component recalculation needs to be carried out. |
kSpecial | species number of phase being zeroed. |
Definition at line 857 of file vcs_solve.cpp.
double vcs_tmoles | ( | ) |
Calculates the total number of moles of species in all phases.
Also updates the variable m_totalMolNum and Reconciles Phase existence flags with total moles in each phase.
Definition at line 2945 of file vcs_solve_TP.cpp.
void check_tmoles | ( | ) | const |
Definition at line 2969 of file vcs_solve_TP.cpp.
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.
Formation reactions are reactions which create each noncomponent species from the component species. m_stoichCoeffRxnMatrix(jcomp,irxn)
are the stoichiometric coefficients for these reactions. A stoichiometric coefficient of one is assumed for species irxn in this reaction.
L |
|
doDeleted | Do deleted species |
vcsState | Calculate deltaG corresponding to either old or new free energies |
alterZeroedPhases | boolean indicating whether we should add in a special section for zeroed phases. |
Note we special case one important issue. If the component has zero moles, then we do not allow deltaG < 0.0 for formation reactions which would lead to the loss of more of that same component. This dG < 0.0 condition feeds back into the algorithm in several places, and leads to a infinite loop in at least one case.
Definition at line 3073 of file vcs_solve_TP.cpp.
void vcs_printDeltaG | ( | const int | stateCalc | ) |
Definition at line 3255 of file vcs_solve_TP.cpp.
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.
ifunc | If true, switch the species data and the noncomponent reaction data. This must be called for a non-component species only. If false, switch the species data only. Typically, we use this option when determining the component species and at the end of the calculation, when we want to return unscrambled results. All rxn data will be out-of-date. |
k1 | First species index |
k2 | Second species index |
Definition at line 3381 of file vcs_solve_TP.cpp.
double vcs_phaseStabilityTest | ( | const size_t | iph | ) |
Main program to test whether a deleted phase should be brought back into existence.
iph | Phase id of the deleted phase |
Definition at line 1136 of file vcs_solve.cpp.
int vcs_TP | ( | int | ipr, |
int | ip1, | ||
int | maxit, | ||
double | T, | ||
double | pres | ||
) |
Solve an equilibrium problem at a particular fixed temperature and pressure.
The actual problem statement is assumed to be in the structure already. This is a wrapper around the solve_TP() function. In this wrapper, we calculate the standard state Gibbs free energies of the species and we decide whether to we need to use the initial guess algorithm.
ipr | = 1 -> Print results to standard output; 0 -> don't report on anything |
ip1 | = 1 -> Print intermediate results; 0 -> Dont print any intermediate results |
maxit | Maximum number of iterations for the algorithm |
T | Value of the Temperature (Kelvin) |
pres | Value of the Pressure |
Definition at line 1399 of file vcs_solve.cpp.
int vcs_evalSS_TP | ( | int | ipr, |
int | ip1, | ||
double | Temp, | ||
double | pres | ||
) |
Evaluate the standard state free energies at the current temperature and pressure.
Ideal gas pressure contribution is added in here.
ipr | 1 -> Print results to standard output; 0 -> don't report on anything |
ip1 | 1 -> Print intermediate results; 0 -> don't. |
Temp | Temperature (Kelvin) |
pres | Pressure (Pascal) |
Definition at line 1431 of file vcs_solve.cpp.
void vcs_fePrep_TP | ( | ) |
Initialize the chemical potential of single species phases.
For single species phases, initialize the chemical potential with the value of the standard state chemical potential. This value doesn't change during the calculation
Definition at line 1445 of file vcs_solve.cpp.
double vcs_VolTotal | ( | const double | tkelvin, |
const double | pres, | ||
const double | w[], | ||
double | volPM[] | ||
) |
Calculation of the total volume and the partial molar volumes.
This function calculates the partial molar volume for all species, kspec, in the thermo problem at the temperature TKelvin and pressure, Pres, pres is in atm. And, it calculates the total volume of the combined system.
[in] | tkelvin | Temperature in kelvin() |
[in] | pres | Pressure in Pascal |
[in] | w | w[] is the vector containing the current mole numbers in units of kmol. |
[out] | volPM[] | For species in all phase, the entries are the partial molar volumes units of M**3 / kmol. |
Definition at line 1458 of file vcs_solve.cpp.
int vcs_prep | ( | int | printLvl | ) |
This routine is mostly concerned with changing the private data to be consistent with what's needed for solution.
It is called one time for each new problem structure definition.
The problem structure refers to:
Tasks:
printLvl | Print level of the routine |
Definition at line 1472 of file vcs_solve.cpp.
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 in the front.
This subroutine handles the rearrangement of the constraint equations represented by the Formula Matrix. Rearrangement is only necessary when the number of components is less than the number of elements. For this case, some constraints can never be satisfied exactly, because the range space represented by the Formula Matrix of the components can't span the extra space. These constraints, which are out of the range space of the component Formula matrix entries, are migrated to the back of the Formula matrix.
A prototypical example is an extra element column in FormulaMatrix[], which is identically zero. For example, let's say that argon is has an element column in FormulaMatrix[], but no species in the mechanism actually contains argon. Then, nc < ne. Also, without perturbation of FormulaMatrix[] vcs_basopt[] would produce a zero pivot because the matrix would be singular (unless the argon element column was already the last column of FormulaMatrix[].
This routine borrows heavily from vcs_basopt's algorithm. It finds nc constraints which span the range space of the Component Formula matrix, and assigns them as the first nc components in the formula matrix. This guarantees that vcs_basopt[] has a nonsingular matrix to invert.
Other Variables
aw | Mole fraction work space (ne in length) |
sa | Gram-Schmidt orthog work space (ne in length) |
sm | QR matrix work space (ne*ne in length) |
ss | Gram-Schmidt orthog work space (ne in length) |
Definition at line 1627 of file vcs_solve.cpp.
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.
This function knows all of the element information with VCS_SOLVE, and can therefore switch element positions
ipos | first global element index |
jpos | second global element index |
Definition at line 1743 of file vcs_solve.cpp.
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 coefficients on the mole numbers.
(See framemaker notes, Eqn. 20 - VCS Equations document)
We allow the diagonal to be increased positively to any degree. We allow the diagonal to be decreased to 1/3 of the ideal solution value, but no more -> it must remain positive.
Definition at line 1776 of file vcs_solve.cpp.
double vcs_Hessian_actCoeff_diag | ( | size_t | irxn | ) |
Calculates the diagonal contribution to the Hessian due to the dependence of the activity coefficients on the mole numbers.
(See framemaker notes, Eqn. 20 - VCS Equations document)
Definition at line 1794 of file vcs_solve.cpp.
void vcs_CalcLnActCoeffJac | ( | const double *const | moleSpeciesVCS | ) |
Recalculate all of the activity coefficients in all of the phases based on input mole numbers.
moleSpeciesVCS | kmol of species to be used in the update. |
NOTE: This routine needs to be regulated.
Definition at line 1824 of file vcs_solve.cpp.
int vcs_report | ( | int | iconv | ) |
Print out a report on the state of the equilibrium problem to standard output.
iconv | Indicator of convergence, to be printed out in the report:
|
Definition at line 1842 of file vcs_solve.cpp.
void vcs_elab | ( | ) |
Computes the current elemental abundances vector.
Computes the elemental abundances vector, m_elemAbundances[], and stores it back into the global structure
Definition at line 2128 of file vcs_solve.cpp.
bool vcs_elabcheck | ( | int | ibound | ) |
Checks to see if the element abundances are in compliance.
If they are, then TRUE is returned. If not, FALSE is returned. Note the number of constraints checked is usually equal to the number of components in the problem. This routine can check satisfaction of all of the constraints in the problem, which is equal to ne. However, the solver can't fix breakage of constraints above nc, because that nc is the range space by definition. Satisfaction of extra constraints would have had to occur in the problem specification.
The constraints should be broken up into 2 sections. If a constraint involves a formula matrix with positive and negative signs, and eaSet = 0.0, then you can't expect that the sum will be zero. There may be roundoff that inhibits this. However, if the formula matrix is all of one sign, then this requires that all species with nonzero entries in the formula matrix be identically zero. We put this into the logic below.
ibound | 1: Checks constraints up to the number of elements; 0: Checks constraints up to the number of components. |
Definition at line 2140 of file vcs_solve.cpp.
void vcs_elabPhase | ( | size_t | iphase, |
double *const | elemAbundPhase | ||
) |
Computes the elemental abundances vector for a single phase, elemAbundPhase[], and returns it through the argument list.
The mole numbers of species are taken from the current value in m_molNumSpecies_old[].
Definition at line 2196 of file vcs_solve.cpp.
int vcs_elcorr | ( | double | aa[], |
double | x[] | ||
) |
This subroutine corrects for element abundances.
At the end of the subroutine, the total moles in all phases are recalculated again, because we have changed the number of moles in this routine.
aa | temporary work vector, length ne*ne |
x | temporary work vector, length ne |
3 = The solution changed significantly, The element abundances are still bad and a component species got zeroed out.
Internal data to be worked on::
NOTES: This routine is turning out to be very problematic. There are lots of special cases and problems with zeroing out species.
Still need to check out when we do loops over nc vs. ne.
Definition at line 2208 of file vcs_solve.cpp.
int vcs_inest_TP | ( | ) |
Create an initial estimate of the solution to the thermodynamic equilibrium problem.
Definition at line 2550 of file vcs_solve.cpp.
int vcs_setMolesLinProg | ( | ) |
Estimate the initial mole numbers by constrained linear programming.
This is done by running each reaction as far forward or backward as possible, subject to the constraint that all mole numbers remain non- negative. Reactions for which \( \Delta \mu^0 \) are positive are run in reverse, and ones for which it is negative are run in the forward direction. The end result is equivalent to solving the linear programming problem of minimizing the linear Gibbs function subject to the element and non-negativity constraints.
Definition at line 2647 of file vcs_solve.cpp.
double vcs_Total_Gibbs | ( | double * | w, |
double * | fe, | ||
double * | tPhMoles | ||
) |
Calculate the total dimensionless Gibbs free energy.
Inert species are handled as if they had a standard free energy of zero. Note, for this algorithm this function should be monotonically decreasing.
Definition at line 2784 of file vcs_solve.cpp.
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.
Inert species are handled as if they had a standard free energy of zero and if they obeyed ideal solution/gas theory.
iphase | ID of the phase |
w | Species mole number vector for all species |
fe | vector of partial molar free energies of all of the species |
Definition at line 2809 of file vcs_solve.cpp.
void vcs_prob_update | ( | ) |
Transfer the results of the equilibrium calculation back from VCS_SOLVE.
Definition at line 2833 of file vcs_solve.cpp.
void vcs_prob_specifyFully | ( | ) |
Fully specify the problem to be solved.
Definition at line 2846 of file vcs_solve.cpp.
|
private |
Zero out the concentration of a species.
Make sure to conserve elements and keep track of the total moles in all phases.
kspec | Species index |
Definition at line 1492 of file vcs_solve_TP.cpp.
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private |
Change a single species from active to inactive status.
Rearrange data when species is added or removed. The Lth species is moved to the back of the species vector. The back of the species vector is indicated by the value of MR, the current number of active species in the mechanism.
kspec | Species Index |
Definition at line 1511 of file vcs_solve_TP.cpp.
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private |
This routine handles the bookkeeping involved with the deletion of multiphase phases from the problem.
When they are deleted, all of their species become active species, even though their mole numbers are set to zero. The routine does not make the decision to eliminate multiphases.
Note, species in phases with zero mole numbers are still considered active. Whether the phase pops back into existence or not is checked as part of the main iteration loop.
iph | Phase to be deleted |
Definition at line 1623 of file vcs_solve_TP.cpp.
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private |
Change the concentration of a species by delta moles.
Make sure to conserve elements and keep track of the total kmoles in all phases.
kspec | The species index |
delta_ptr | pointer to the delta for the species. This may change during the calculation |
Definition at line 1443 of file vcs_solve_TP.cpp.
|
private |
Provide an estimate for the deleted species in phases that are not zeroed out.
Try to add back in all deleted species. An estimate of the kmol numbers are obtained and the species is added back into the equation system, into the old state vector.
This routine is called at the end of the calculation, just before returning to the user.
Definition at line 1831 of file vcs_solve_TP.cpp.
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private |
Recheck deleted species in multispecies phases.
We are checking the equation:
sum_u = sum_j_comp [ sigma_i_j * u_j ] = u_i_O + \ln((AC_i * W_i)/m_tPhaseMoles_old)
by first evaluating:
DG_i_O = u_i_O - sum_u.
Then, if TL is zero, the phase pops into existence if DG_i_O < 0. Also, if the phase exists, then we check to see if the species can have a mole number larger than VCS_DELETE_SPECIES_CUTOFF (default value = 1.0E-32).
Definition at line 1757 of file vcs_solve_TP.cpp.
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private |
Minor species alternative calculation.
This is based upon the following approximation: The mole fraction changes due to these reactions don't affect the mole numbers of the component species. Therefore the following approximation is valid for a small component of an ideal phase:
0 = m_deltaGRxn_old(I) + log(molNum_new(I)/molNum_old(I))
m_deltaGRxn_old
contains the contribution from
m_feSpecies_old(I) = m_SSfeSpecies(I) + log(ActCoeff[i] * molNum_old(I) / m_tPhaseMoles_old(iph))
Thus,
molNum_new(I)= molNum_old(I) * EXP(-m_deltaGRxn_old(I))
Most of this section is mainly restricting the update to reasonable values. We restrict the update a factor of 1.0E10 up and 1.0E-10 down because we run into trouble with the addition operator due to roundoff if we go larger than ~1.0E15. Roundoff will then sometimes produce zero mole fractions.
Note: This routine was generalized to incorporate nonideal phases and phases on the molality basis
[in] | kspec | The current species and corresponding formation reaction number. |
[in] | irxn | The current species and corresponding formation reaction number. |
[out] | do_delete | BOOLEAN which if true on return, then we branch to the section that deletes a species from the current set of active species. |
[out] | ANOTE | Buffer used for debug annotations |
Definition at line 1360 of file vcs_solve_TP.cpp.
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private |
This routine optimizes the minimization of the total Gibbs free energy by making sure the slope of the following functional stays negative:
The slope of the following functional is equivalent to the slope of the total Gibbs free energy of the system:
d_Gibbs/ds = sum_k( m_deltaGRxn * m_deltaMolNumSpecies[k] )
along the current direction m_deltaMolNumSpecies[], by choosing a value, al: (0<al<1) such that the a parabola approximation to Gibbs(al) fit to the end points al = 0 and al = 1 is minimized.
Only if there has been an inflection point (that is, s1 < 0 and s2 > 0), does this code section kick in. It finds the point on the parabola where the slope is equal to zero.
Definition at line 1924 of file vcs_solve_TP.cpp.
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private |
Calculate the norm of a deltaGibbs free energy vector.
Positive DG for species which don't exist are ignored.
dg | Vector of local delta G's. |
Definition at line 2927 of file vcs_solve_TP.cpp.
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private |
Definition at line 30 of file vcs_solve_TP.cpp.
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private |
Estimate equilibrium compositions.
Algorithm covered in a section of Smith and Missen's Book [40].
Linear programming module is based on using dbolm.
aw | aw[i[ Mole fraction work space (ne in length) |
sa | sa[j] = Gram-Schmidt orthog work space (ne in length) |
sm | sm[i+j*ne] = QR matrix work space (ne*ne in length) |
ss | ss[j] = Gram-Schmidt orthog work space (ne in length) |
test | This is a small negative number. |
Definition at line 2935 of file vcs_solve.cpp.
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private |
Calculate the status of single species phases.
Definition at line 3195 of file vcs_solve.cpp.
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private |
Delete memory that isn't just resizable STL containers.
This gets called by the destructor or by InitSizes().
Definition at line 3230 of file vcs_solve.cpp.
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private |
Initialize the internal counters.
Initialize the internal counters containing the subroutine call values and times spent in the subroutines.
ifunc = 0 Initialize only those counters appropriate for the top of vcs_solve_TP(). = 1 Initialize all counters.
Definition at line 3241 of file vcs_solve.cpp.
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private |
Create a report on the plog file containing timing and its information.
timing_print_lvl | If 0, just report the iteration count. If larger than zero, report the timing information |
Definition at line 3259 of file vcs_solve.cpp.
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private |
Definition at line 3461 of file vcs_solve_TP.cpp.
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private |
Definition at line 3474 of file vcs_solve_TP.cpp.
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private |
Update all underlying vcs_VolPhase objects.
Update the mole numbers and the phase voltages of all phases in the vcs problem
stateCalc | Location of the update (either VCS_STATECALC_NEW or VCS_STATECALC_OLD). |
Definition at line 3484 of file vcs_solve_TP.cpp.
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private |
Definition at line 291 of file vcs_solve_TP.cpp.
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private |
Definition at line 323 of file vcs_solve_TP.cpp.
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Definition at line 1173 of file vcs_solve_TP.cpp.
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private |
Definition at line 1293 of file vcs_solve_TP.cpp.
void prob_report | ( | int | print_lvl | ) |
Print out the problem specification in all generality as it currently exists in the VCS_SOLVE object.
print_lvl | Parameter lvl for printing
|
Definition at line 3285 of file vcs_solve.cpp.
void addPhaseElements | ( | vcs_VolPhase * | volPhase | ) |
Add elements to the local element list.
This routine sorts through the elements defined in the vcs_VolPhase object. It then adds the new elements to the VCS_SOLVE object, and creates a global map, which is stored in the vcs_VolPhase object. Id and matching of elements is done strictly via the element name, with case not mattering.
The routine also fills in the position of the element in the vcs_VolPhase object's ElGlobalIndex field.
volPhase | Object containing the phase to be added. The elements in this phase are parsed for addition to the global element list |
Definition at line 3382 of file vcs_solve.cpp.
size_t addOnePhaseSpecies | ( | vcs_VolPhase * | volPhase, |
size_t | k, | ||
size_t | kT | ||
) |
This routines adds entries for the formula matrix for one species.
This routines adds entries for the formula matrix for this object for one species
This object also fills in the index filed, IndSpecies, within the volPhase object.
volPhase | object containing the species |
k | Species number within the volPhase k |
kT | global Species number within this object |
Definition at line 3408 of file vcs_solve.cpp.
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 end of the element list.
The element name is added. Formula vector entries ang element abundances for the new element are set to zero.
elNameNew | New name of the element |
elType | Type of the element |
elactive | boolean indicating whether the element is active |
Definition at line 3428 of file vcs_solve.cpp.
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static |
Disable printing of timing information.
Used to generate consistent output for tests.
Definition at line 3448 of file vcs_solve.cpp.
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friend |
Definition at line 1512 of file vcs_solve.h.
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Definition at line 977 of file vcs_solve.h.
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Definition at line 978 of file vcs_solve.h.
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Definition at line 979 of file vcs_solve.h.
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Definition at line 980 of file vcs_solve.h.
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private |
Definition at line 981 of file vcs_solve.h.
int m_printLvl |
Print level for print routines.
Definition at line 985 of file vcs_solve.h.
MultiPhase* m_mix |
Definition at line 987 of file vcs_solve.h.
size_t m_nsp |
Total number of species in the problems.
Definition at line 1045 of file vcs_solve.h.
size_t m_nelem = 0 |
Number of element constraints in the problem.
Definition at line 1048 of file vcs_solve.h.
size_t m_numComponents = 0 |
Number of components calculated for the problem.
Definition at line 1051 of file vcs_solve.h.
size_t m_numRxnTot = 0 |
Total number of non-component species in the problem.
Definition at line 1054 of file vcs_solve.h.
size_t m_numSpeciesRdc |
Current number of species in the problems.
Species can be deleted if they aren't stable under the current conditions
Definition at line 1058 of file vcs_solve.h.
size_t m_numRxnRdc = 0 |
Current number of non-component species in the problem.
Species can be deleted if they aren't stable under the current conditions
Definition at line 1062 of file vcs_solve.h.
size_t m_numRxnMinorZeroed = 0 |
Number of active species which are currently either treated as minor species.
Definition at line 1066 of file vcs_solve.h.
size_t m_numPhases |
Number of Phases in the problem.
Definition at line 1069 of file vcs_solve.h.
Array2D m_formulaMatrix |
Formula matrix for the problem.
FormulaMatrix(kspec,j) = Number of elements, j, in the kspec species
Both element and species indices are swapped.
Definition at line 1077 of file vcs_solve.h.
Array2D m_stoichCoeffRxnMatrix |
Stoichiometric coefficient matrix for the reaction mechanism expressed in Reduced Canonical Form.
This is the stoichiometric coefficient matrix for the reaction which forms species kspec from the component species. A stoichiometric coefficient of one is assumed for the species kspec in this mechanism.
NOTE: kspec = irxn + m_numComponents
m_stoichCoeffRxnMatrix(j,irxn)
: j refers to the component number, and irxn refers to the irxn_th non-component species. The stoichiometric coefficients multiplied by the Formula coefficients of the component species add up to the negative value of the number of elements in the species kspec.
size = nelements0 x nspecies0
Definition at line 1096 of file vcs_solve.h.
vector<double> m_scSize |
Absolute size of the stoichiometric coefficients.
scSize[irxn] = abs(Size) of the stoichiometric coefficients. These are used to determine whether a given species should be handled by the alt_min treatment or should be handled as a major species.
Definition at line 1105 of file vcs_solve.h.
vector<double> m_spSize |
total size of the species
This is used as a multiplier to the mole number in figuring out which species should be components.
Definition at line 1112 of file vcs_solve.h.
vector<double> m_SSfeSpecies |
Standard state chemical potentials for species K at the current temperature and pressure.
The first NC entries are for components. The following NR entries are for the current non-component species in the mechanism.
Definition at line 1120 of file vcs_solve.h.
vector<double> m_feSpecies_old |
Free energy vector from the start of the current iteration.
The free energies are saved at the start of the current iteration. Length = number of species
Definition at line 1127 of file vcs_solve.h.
vector<double> m_feSpecies_new |
Dimensionless new free energy for all the species in the mechanism at the new tentative T, P, and mole numbers.
The first NC entries are for components. The following NR entries are for the current non-component species in the mechanism. Length = number of species
Definition at line 1136 of file vcs_solve.h.
int m_doEstimateEquil = -1 |
Setting for whether to do an initial estimate.
Initial estimate: 0 Do not estimate the solution at all. Use the supplied mole numbers as is. 1 Only do an estimate if the element abundances aren't satisfied. -1 Force an estimate of the soln. Throw out the input mole numbers.
Definition at line 1146 of file vcs_solve.h.
vector<double> m_molNumSpecies_old |
Total moles of the species.
Total number of moles of the kth species. Length = Total number of species = m
Definition at line 1153 of file vcs_solve.h.
vector<int> m_speciesUnknownType |
Specifies the species unknown type.
There are two types. One is the straightforward species, with the mole number w[k], as the unknown. The second is the an interfacial voltage where w[k] refers to the interfacial voltage in volts.
These species types correspond to metallic electrons corresponding to electrodes. The voltage and other interfacial conditions sets up an interfacial current, which is set to zero in this initial treatment. Later we may have non-zero interfacial currents.
Definition at line 1166 of file vcs_solve.h.
Array2D m_deltaMolNumPhase |
Change in the number of moles of phase, iphase, due to the noncomponent formation reaction, irxn, for species, k:
m_deltaMolNumPhase(iphase,irxn) = k = nc + irxn
Definition at line 1173 of file vcs_solve.h.
Array2D m_phaseParticipation |
This is 1 if the phase, iphase, participates in the formation reaction irxn, and zero otherwise.
PhaseParticipation(iphase,irxn)
Definition at line 1177 of file vcs_solve.h.
vector<double> m_phasePhi |
electric potential of the iph phase
Definition at line 1180 of file vcs_solve.h.
vector<double> m_molNumSpecies_new |
Tentative value of the mole number vector.
It's also used to store the mole fraction vector.
Definition at line 1184 of file vcs_solve.h.
vector<double> m_deltaGRxn_new |
Delta G(irxn) for the noncomponent species in the mechanism.
Computed by the subroutine deltaG. m_deltaGRxn is the free energy change for the reaction which forms species K from the component species. This vector has length equal to the number of noncomponent species in the mechanism. It starts with the first current noncomponent species in the mechanism.
Definition at line 1194 of file vcs_solve.h.
vector<double> m_deltaGRxn_old |
Last deltag[irxn] from the previous step.
Definition at line 1197 of file vcs_solve.h.
vector<double> m_deltaGRxn_Deficient |
Last deltag[irxn] from the previous step with additions for possible births of zeroed phases.
Definition at line 1201 of file vcs_solve.h.
vector<double> m_deltaGRxn_tmp |
Temporary vector of Rxn DeltaG's.
This is used from time to time, for printing purposes
Definition at line 1207 of file vcs_solve.h.
vector<double> m_deltaMolNumSpecies |
Reaction Adjustments for each species during the current step.
delta Moles for each species during the current step. Length = number of species
Definition at line 1214 of file vcs_solve.h.
vector<double> m_elemAbundances |
Element abundances vector.
Vector of moles of each element actually in the solution vector. Except for certain parts of the algorithm, this is a constant. Note other constraint conditions are added to this vector. This is input from the input file and is considered a constant from thereon. units = kmoles
Definition at line 1223 of file vcs_solve.h.
vector<double> m_elemAbundancesGoal |
Element abundances vector Goals.
Vector of moles of each element that are the goals of the simulation. This is a constant in the problem. Note other constraint conditions are added to this vector. This is input from the input file and is considered a constant from thereon. units = kmoles
Definition at line 1232 of file vcs_solve.h.
double m_totalMolNum = 0.0 |
Total number of kmoles in all phases.
This number includes the inerts. -> Don't use this except for scaling purposes
Definition at line 1239 of file vcs_solve.h.
vector<double> m_tPhaseMoles_old |
Total kmols of species in each phase.
This contains the total number of moles of species in each phase
Length = number of phases
Definition at line 1247 of file vcs_solve.h.
vector<double> m_tPhaseMoles_new |
total kmols of species in each phase in the tentative soln vector
This contains the total number of moles of species in each phase in the tentative solution vector
Length = number of phases
Definition at line 1256 of file vcs_solve.h.
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mutable |
Temporary vector of length NPhase.
Definition at line 1259 of file vcs_solve.h.
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mutable |
Temporary vector of length NPhase.
Definition at line 1262 of file vcs_solve.h.
vector<double> m_deltaPhaseMoles |
Change in the total moles in each phase.
Length number of phases.
Definition at line 1268 of file vcs_solve.h.
double m_temperature |
Temperature (Kelvin)
Definition at line 1271 of file vcs_solve.h.
double m_pressurePA |
Pressure.
Definition at line 1274 of file vcs_solve.h.
vector<double> TPhInertMoles |
Total kmoles of inert to add to each phase.
TPhInertMoles[iph] = Total kmoles of inert to add to each phase length = number of phases
Definition at line 1281 of file vcs_solve.h.
double m_tolmaj = 1e-8 |
Tolerance requirement for major species.
Definition at line 1284 of file vcs_solve.h.
double m_tolmin = 1e-6 |
Tolerance requirements for minor species.
Definition at line 1287 of file vcs_solve.h.
double m_tolmaj2 = 1e-10 |
Below this, major species aren't refined any more.
Definition at line 1290 of file vcs_solve.h.
double m_tolmin2 = 1e-8 |
Below this, minor species aren't refined any more.
Definition at line 1293 of file vcs_solve.h.
vector<size_t> m_speciesMapIndex |
Index vector that keeps track of the species vector rearrangement.
At the end of each run, the species vector and associated data gets put back in the original order.
Example
k = m_speciesMapIndex[kspec] kspec = current order in the vcs_solve object k = original order in the MultiPhase object
Definition at line 1307 of file vcs_solve.h.
vector<size_t> m_speciesLocalPhaseIndex |
Index that keeps track of the index of the species within the local phase.
This returns the local index of the species within the phase. Its argument is the global species index within the VCS problem.
k = m_speciesLocalPhaseIndex[kspec]
k varies between 0 and the nSpecies in the phase
Length = number of species
Definition at line 1321 of file vcs_solve.h.
vector<size_t> m_elementMapIndex |
Index vector that keeps track of the rearrangement of the elements.
At the end of each run, the element vector and associated data gets put back in the original order.
Example
e = m_elementMapIndex[eNum] eNum = current order in the vcs_solve object e = original order in the MultiPhase object
Definition at line 1334 of file vcs_solve.h.
vector<size_t> m_indexRxnToSpecies |
Mapping between the species index for noncomponent species and the full species index.
ir[irxn] = Mapping between the reaction index for noncomponent formation reaction of a species and the full species index.
Initially set to a value of K = NC + I This vector has length equal to number of noncomponent species in the mechanism. It starts with the first current noncomponent species in the mechanism. kspec = ir[irxn]
Definition at line 1347 of file vcs_solve.h.
vector<int> m_speciesStatus |
Major -Minor status vector for the species in the problem.
The index for this is species. The reaction that this is referring to is kspec = irxn + m_numComponents
. For possible values and their meanings, see vcs_evaluate_speciesType().
Definition at line 1355 of file vcs_solve.h.
vector<size_t> m_phaseID |
Mapping from the species number to the phase number.
Definition at line 1358 of file vcs_solve.h.
vector<char> m_SSPhase |
Boolean indicating whether a species belongs to a single-species phase.
Definition at line 1362 of file vcs_solve.h.
vector<string> m_speciesName |
Species string name for the kth species.
Definition at line 1365 of file vcs_solve.h.
vector<string> m_elementName |
Vector of strings containing the element names.
ElName[j] = String containing element names
Definition at line 1371 of file vcs_solve.h.
vector<int> m_elType |
Type of the element constraint.
Definition at line 1386 of file vcs_solve.h.
vector<int> m_elementActive |
Specifies whether an element constraint is active.
The default is true. Length = nelements
Definition at line 1392 of file vcs_solve.h.
vector<unique_ptr<vcs_VolPhase> > m_VolPhaseList |
Array of Phase Structures. Length = number of phases.
Definition at line 1395 of file vcs_solve.h.
vector<int> m_actConventionSpecies |
specifies the activity convention of the phase containing the species
length = number of species
Definition at line 1404 of file vcs_solve.h.
vector<int> m_phaseActConvention |
specifies the activity convention of the phase.
length = number of phases
Definition at line 1413 of file vcs_solve.h.
vector<double> m_lnMnaughtSpecies |
specifies the ln(Mnaught) used to calculate the chemical potentials
For molar based activity conventions this will be equal to 0.0. length = number of species.
Definition at line 1420 of file vcs_solve.h.
vector<double> m_actCoeffSpecies_new |
Molar-based Activity Coefficients for Species.
Length = number of species
Definition at line 1424 of file vcs_solve.h.
vector<double> m_actCoeffSpecies_old |
Molar-based Activity Coefficients for Species based on old mole numbers.
These activity coefficients are based on the m_molNumSpecies_old values Molar based activity coefficients. Length = number of species
Definition at line 1431 of file vcs_solve.h.
Array2D m_np_dLnActCoeffdMolNum |
Change in the log of the activity coefficient with respect to the mole number multiplied by the phase mole number.
size = nspecies x nspecies
This is a temporary array that gets regenerated every time it's needed. It is not swapped wrt species.
Definition at line 1441 of file vcs_solve.h.
vector<double> m_wtSpecies |
Molecular weight of each species.
units = kg/kmol. length = number of species.
note: this is a candidate for removal. I don't think we use it.
Definition at line 1449 of file vcs_solve.h.
vector<double> m_chargeSpecies |
Charge of each species. Length = number of species.
Definition at line 1452 of file vcs_solve.h.
vector<vector<size_t> > phasePopProblemLists_ |
Definition at line 1454 of file vcs_solve.h.
vector<unique_ptr<VCS_SPECIES_THERMO> > m_speciesThermoList |
Vector of pointers to thermo structures which identify the model and parameters for evaluating the thermodynamic functions for that particular species.
SpeciesThermo[k] pointer to the thermo information for the kth species
Definition at line 1462 of file vcs_solve.h.
int m_useActCoeffJac = 0 |
Choice of Hessians.
If this is true, then we will use a better approximation to the Hessian based on Jacobian of the ln(ActCoeff) with respect to mole numbers
Definition at line 1469 of file vcs_solve.h.
double m_totalVol |
Total volume of all phases. Units are m^3.
Definition at line 1472 of file vcs_solve.h.
vector<double> m_PMVolumeSpecies |
Partial molar volumes of the species.
units = mks (m^3/kmol) Length = number of species
Definition at line 1479 of file vcs_solve.h.
double m_Faraday_dim |
dimensionless value of Faraday's constant, F / RT (1/volt)
Definition at line 1482 of file vcs_solve.h.
VCS_COUNTERS* m_VCount = nullptr |
Timing and iteration counters for the vcs object.
Definition at line 1485 of file vcs_solve.h.
int m_debug_print_lvl = 0 |
Debug printing lvl.
Levels correspond to the following guidelines
Definition at line 1499 of file vcs_solve.h.
int m_timing_print_lvl = 1 |
printing level of timing information
Definition at line 1506 of file vcs_solve.h.