Package “step_or_map_diagrams”¶
-
class
+tc_toolbox.+step_or_map_diagrams.
AbstractAxisType
¶ The abstract base class for all axis types.
-
class
+tc_toolbox.+step_or_map_diagrams.
AbstractPhaseDiagramCalculation
(back)¶ Abstract configuration required for a property diagram calculation.
Note
This is an abstract class that cannot be used directly.
-
AbstractPhaseDiagramCalculation
(back)¶ Call base constructor:
tc_toolbox.AbstractCalculation
.
-
add_initial_equilibrium
(initial_equilibrium)¶ Add initial equilibrium start points from which a phase diagram is calculated.
Scans along the axis variables and generates start points when the scan procedure crosses a phase boundary.
It may take a little longer to execute than using the minimum number of start points, as some lines may be calculated more than once. But the core remembers all node points and subsequently stops calculations along a line when it finds a known node point.
It is also possible to create a sequence of start points from one initial equilibria.
- Parameters
initial_equilibrium – The initial equilibrium
- Returns
This
PhaseDiagramCalculation
object
-
calculate
(keep_previous_results, timeout_in_minutes)¶
-
disable_global_minimization
()¶ Disables global minimization.
Default: Enabled
- Returns
This
PhaseDiagramCalculation
object
-
dont_keep_default_equilibria
()¶ Do not keep the initial equilibria added by default.
This is only relevant in combination with
add_initial_equilibrium()
.This is the default behavior.
- Returns
This
PhaseDiagramCalculation
object
-
enable_global_minimization
()¶ Enables global minimization.
Default: Enabled
- Returns
This
PhaseDiagramCalculation
object
-
get_components
()¶ Returns the names of the components in the system (including all components auto-selected by the database(s)).
- Returns
The component names
-
get_configuration_as_string
()¶ Returns detailed information about the current state of the calculation object.
Warning
The structure of the calculator objects is an implementation detail and might change between releases without notice. Therefore do not rely on the internal object structure.
-
get_gibbs_energy_addition_for
(phase)¶ Used to get the additional energy term (always being a constant) of a given phase. The value given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
- Returns
Gibbs energy addition to G per mole formula unit.
-
get_system_data
()¶ Returns the content of the database for the currently loaded system. This can be used to modify the parameters and functions and to change the current system by using
with_system_modifications()
.Note
Parameters can only be read from unencrypted (i.e. user) databases loaded as *.tdb-file.
- Returns
The system data
-
invalidate
()¶ Invalidates the object and frees the disk space used by it. This is only required if the disk space occupied by the object needs to be released during the calculation. No data can be retrieved from the object afterwards.
-
keep_default_equilibria
()¶ Keep the initial equilibria added by default. This is only relevant in combination with
add_initial_equilibrium()
.Default behavior is to not keep default equilibria.
- Returns
This
PhaseDiagramCalculation
object
-
remove_all_initial_equilibria
()¶ Removes all previously added initial equilibria.
- Returns
This
PhaseDiagramCalculation
object
-
run_poly_command
(command)¶ Runs a Thermo-Calc command from the Console Mode POLY module immediately in the engine.
Note
It should not be necessary for most users to use this method, try to use the corresponding method implemented in the API instead.
Warning
As this method runs raw Thermo-Calc commands directly in the engine, it may hang the program in case of spelling mistakes (e.g. forgotten equals sign).
- Parameters
command – The Thermo-Calc Console Mode command
- Returns
This
PhaseDiagramCalculation
object
-
set_gibbs_energy_addition_for
(phase, gibbs_energy)¶ Used to specify the additional energy term (always being a constant) of a given phase. The value (gibbs_energy) given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
gibbs_energy – Addition to G per mole formula unit
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_dormant
(phase)¶ Sets the phase to the status DORMANT, necessary for calculating the driving force to form the specified phase.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_entered
(phase, amount)¶ Sets the phase to the status ENTERED, that is the default state.
- Parameters
phase – The phase name or ALL_PHASES for all phases
amount – The phase fraction (between 0.0 and 1.0)
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_fixed
(phase, amount)¶ Sets the phase to the status FIXED, i.e. it is guaranteed to have the specified phase fraction after the calculation.
- Parameters
phase – The phase name
amount – The fixed phase fraction (between 0.0 and 1.0)
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_suspended
(phase)¶ Sets the phase to the status SUSPENDED, i.e. it is ignored in the calculation.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PhaseDiagramCalculation
object
-
with_options
(options)¶ Sets the simulation options.
- Parameters
options – The simulation options
- Returns
This
PhaseDiagramCalculation
object
-
with_reference_state
(component, phase, temperature, pressure)¶ The reference state for a component is important when calculating activities, chemical potentials and enthalpies and is determined by the database being used. For each component the data must be referred to a selected phase, temperature and pressure, i.e. the reference state.
All data in all phases where this component dissolves must use the same reference state. However, different databases can use different reference states for the same element/component. It is important to be careful when combining data obtained from different databases.
By default, activities, chemical potentials and so forth are computed relative to the reference state used by the database. If the reference state in the database is not suitable for your purposes, use this command to set the reference state for a component using SER, i.e. the Stable Element Reference (which is usually set as default for a major component in alloys dominated by the component). In such cases, the temperature and pressure for the reference state is not needed.
For a phase to be usable as a reference for a component, the component needs to have the same composition as an end member of the phase. The reference state is an end member of a phase. The selection of the end member associated with the reference state is only performed once this command is executed.
If a component has the same composition as several end members of the chosen reference phase, then the end member that is selected at the specified temperature and pressure will have the lowest Gibbs energy.
- Parameters
component – The name of the element must be given.
phase – Name of a phase used as the new reference state. Or SER for the Stable Element Reference.
temperature – The Temperature (in K) for the reference state. Or
CURRENT_TEMPERATURE
which means that the current temperature is used at the time of evaluation of the reference energy for the calculation.pressure – The Pressure (in Pa) for the reference state.
- Returns
This
PhaseDiagramCalculation
object
-
with_system_modifications
(system_modifications)¶ Updates the system of this calculator with the supplied system modification (containing new phase parameters and system functions).
Note
This is only possible if the system has been read from unencrypted (i.e. user) databases loaded as a
*.tdb
-file.- Parameters
system_modifications – The system modification to be performed
- Returns
This
PhaseDiagramCalculation
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
AbstractPropertyDiagramCalculation
(back)¶ Abstract configuration required for a property diagram calculation.
Note
This is an abstract class that cannot be used directly.
-
AbstractPropertyDiagramCalculation
(back)¶ Call base constructor:
tc_toolbox.AbstractCalculation
.
-
calculate
(keep_previous_results, timeout_in_minutes)¶
-
disable_global_minimization
()¶ Disables global minimization.
Default: Enabled
- Returns
This
PropertyDiagramCalculation
object
-
disable_step_separate_phases
()¶ Disables step separate phases. This is the default setting.
- Returns
This
PropertyDiagramCalculation
object
-
enable_global_minimization
()¶ Enables global minimization.
Default: Enabled
- Returns
This
PropertyDiagramCalculation
object
-
enable_step_separate_phases
()¶ Enables step separate phases.
Default: By default separate phase stepping is disabled
Note
This is an advanced option, it is used mostly to calculate how the Gibbs energy for a number of phases varies for different compositions. This is particularly useful to calculate Gibbs energies for complex phases with miscibility gaps and for an ordered phase that is never disordered (e.g. SIGMA-phase, G-phase, MU-phase, etc.).
- Returns
This
PropertyDiagramCalculation
object
-
get_components
()¶ Returns the names of the components in the system (including all components auto-selected by the database(s)).
- Returns
The component names
-
get_configuration_as_string
()¶ Returns detailed information about the current state of the calculation object.
Warning
The structure of the calculator objects is an implementation detail and might change between releases without notice. Therefore do not rely on the internal object structure.
-
get_gibbs_energy_addition_for
(phase)¶ Used to get the additional energy term (always being a constant) of a given phase. The value given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
- Returns
Gibbs energy addition to G per mole formula unit.
-
get_system_data
()¶ Returns the content of the database for the currently loaded system. This can be used to modify the parameters and functions and to change the current system by using
with_system_modifications()
.Note
Parameters can only be read from unencrypted (i.e. user) databases loaded as *.tdb-file.
- Returns
The system data
-
invalidate
()¶ Invalidates the object and frees the disk space used by it. This is only required if the disk space occupied by the object needs to be released during the calculation. No data can be retrieved from the object afterwards.
-
run_poly_command
(command)¶ Runs a Thermo-Calc command from the Console Mode POLY module immediately in the engine.
Note
It should not be necessary for most users to use this method, try to use the corresponding method implemented in the API instead.
Warning
As this method runs raw Thermo-Calc commands directly in the engine, it may hang the program in case of spelling mistakes (e.g. forgotten equals sign).
- Parameters
command – The Thermo-Calc Console Mode command
- Returns
This
PropertyDiagramCalculation
object
-
set_gibbs_energy_addition_for
(phase, gibbs_energy)¶ Used to specify the additional energy term (always being a constant) of a given phase. The value (gibbs_energy) given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
gibbs_energy – Addition to G per mole formula unit
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_dormant
(phase)¶ Sets the phase to the status DORMANT, necessary for calculating the driving force to form the specified phase.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_entered
(phase, amount)¶ Sets the phase to the status ENTERED, that is the default state.
- Parameters
phase – The phase name or ALL_PHASES for all phases
amount – The phase fraction (between 0.0 and 1.0)
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_fixed
(phase, amount)¶ Sets the phase to the status FIXED, i.e. it is guaranteed to have the specified phase fraction after the calculation.
- Parameters
phase – The phase name
amount – The fixed phase fraction (between 0.0 and 1.0)
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_suspended
(phase)¶ Sets the phase to the status SUSPENDED, i.e. it is ignored in the calculation.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PropertyDiagramCalculation
object
-
with_options
(options)¶ Sets the simulation options.
- Parameters
options – The simulation options
- Returns
This
PropertyDiagramCalculation
object
-
with_reference_state
(component, phase, temperature, pressure)¶ The reference state for a component is important when calculating activities, chemical potentials and enthalpies and is determined by the database being used. For each component the data must be referred to a selected phase, temperature and pressure, i.e. the reference state.
All data in all phases where this component dissolves must use the same reference state. However, different databases can use different reference states for the same element/component. It is important to be careful when combining data obtained from different databases.
By default, activities, chemical potentials and so forth are computed relative to the reference state used by the database. If the reference state in the database is not suitable for your purposes, use this command to set the reference state for a component using SER, i.e. the Stable Element Reference (which is usually set as default for a major component in alloys dominated by the component). In such cases, the temperature and pressure for the reference state is not needed.
For a phase to be usable as a reference for a component, the component needs to have the same composition as an end member of the phase. The reference state is an end member of a phase. The selection of the end member associated with the reference state is only performed once this command is executed.
If a component has the same composition as several end members of the chosen reference phase, then the end member that is selected at the specified temperature and pressure will have the lowest Gibbs energy.
- Parameters
component – The name of the element must be given.
phase – Name of a phase used as the new reference state. Or SER for the Stable Element Reference.
temperature – The Temperature (in K) for the reference state. Or
CURRENT_TEMPERATURE
which means that the current temperature is used at the time of evaluation of the reference energy for the calculation.pressure – The Pressure (in Pa) for the reference state.
- Returns
This
PropertyDiagramCalculation
object
-
with_system_modifications
(system_modifications)¶ Updates the system of this calculator with the supplied system modification (containing new phase parameters and system functions).
Note
This is only possible if the system has been read from unencrypted (i.e. user) databases loaded as a
*.tdb
-file.- Parameters
system_modifications – The system modification to be performed
- Returns
This
PropertyDiagramCalculation
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
AxisType
¶ Factory class providing objects for configuring a logarithmic or linear axis by using
AxisType.linear()
orAxisType.logarithmic()
.-
static
linear
()¶ Creates an object for configuring a linear calculation axis.
Default: A minimum number of 40 steps.
Note
The returned object can be configured regarding the maximum step size or the minimum number of steps on the axis.
- Returns
A new
Linear
object
-
static
logarithmic
()¶ Creates an object for configuring a logarithmic calculation axis.
Default: A scale factor of 1.1
Note
The returned object can be configured regarding the scale factor.
- Returns
A new
Logarithmic
object
-
static
-
class
+tc_toolbox.+step_or_map_diagrams.
CalculationAxis
(quantity)¶ A calculation axis used for property and phase diagram calculations.
Default: A
Linear
axis with a minimum number of 40 stepsNote
A calculation axis is defining the varied condition and the range of variation. It is the same concept as in Thermo-Calc Graphical Mode or Console Mode.
-
CalculationAxis
(quantity)¶ Default: A
Linear
axis with a minimum number of 40 steps- Parameters
quantity – The
ThermodynamicQuantity
to set as axis variable; a Console Mode syntax string can be used as an alternative (for example “X(Cr)”)
-
set_max
(max)¶ Sets the maximum quantity value of the calculation axis.
There is no default value set, it always needs to be defined.
- Parameters
max – The maximum quantity value of the axis [unit according to the axis quantity]
- Returns
This
CalculationAxis
object
-
set_min
(min)¶ Sets the minimum quantity value of the calculation axis.
There is no default value set, it always needs to be defined.
- Parameters
min – The minimum quantity value of the axis [unit according to the axis quantity]
- Returns
This
CalculationAxis
object
-
set_start_at
(at)¶ Sets the starting point of the calculation on the axis.
Default: The default starting point is the center between the minimum and maximum quantity value
- Parameters
at – The starting point on the axis [unit according to the axis quantity]
- Returns
This
CalculationAxis
object
-
with_axis_type
(axis_type)¶ Sets the type of the axis.
Default: A
Linear
axis with a minimum number of 40 steps- Parameters
axis_type – The axis type (linear or logarithmic)
- Returns
This
CalculationAxis
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
Direction
¶ An enumeration.
-
class
+tc_toolbox.+step_or_map_diagrams.
InitialEquilibrium
(first_axis, second_axis)¶ -
InitialEquilibrium
(first_axis, second_axis)¶
-
add_equilibria_at_all_phase_changes
()¶ This generates one start point for each set of phase change in the chosen direction of the specified axis This ensures finding all possible phase boundary lines (not just the first one) along such an axis direction.
Default behavior is to only generate one start point at the first phase change.
- Returns
This
InitialEquilibrium
object
-
add_equilibria_at_first_phase_change
()¶ This generates one start point at the first phase change.
This is the default behavior.
- Returns
This
InitialEquilibrium
object
-
set_direction
(direction_enum)¶ Specifies along which axes the initial equilibria should be added.
The default direction is
INCREASE_FIRST_AXIS
.- Parameters
direction_enum –
- Returns
This
InitialEquilibrium
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
Linear
¶ Represents a linear axis.
-
get_type
()¶ Convenience method for getting axis type.
- Returns
The type
-
static
linear
()¶ Creates an object for configuring a linear calculation axis.
Default: A minimum number of 40 steps.
Note
The returned object can be configured regarding the maximum step size or the minimum number of steps on the axis.
- Returns
A new
Linear
object
-
static
logarithmic
()¶ Creates an object for configuring a logarithmic calculation axis.
Default: A scale factor of 1.1
Note
The returned object can be configured regarding the scale factor.
- Returns
A new
Logarithmic
object
-
set_max_step_size
(max_step_size)¶ Sets the axis to use the maximum step size configuration.
Default: This is not the default which is minimum number of steps
Note
Either maximum step size or minimum number of steps can be used but not both at the same time.
- Parameters
max_step_size – The maximum step size [unit according to the axis quantity]
- Returns
This
Linear
object
-
set_min_nr_of_steps
(min_nr_of_steps)¶ Sets the axis to use the minimum number of steps configuration.
Default: This is the default option (with a minimum number of steps of 40)
Note
Either maximum step size or minimum number of steps can be used but not both at the same time.
- Parameters
min_nr_of_steps – The minimum number of steps
- Returns
This
Linear
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
Logarithmic
(scale_factor)¶ Represents a logarithmic axis.
Note
A logarithmic axis is useful for low fractions like in a gas phase where 1E-7 to 1E-2 might be an interesting range. For the pressure a logarithmic axis is often also useful.
-
Logarithmic
(scale_factor)¶ Creates an object representing a logarithmic axis.
Default: 1.1
- Parameters
scale_factor – The scale factor setting the maximum factor between two calculated values, must be larger than 1.0.
-
get_type
()¶ Convenience method for getting axis type.
- Returns
The type
-
static
linear
()¶ Creates an object for configuring a linear calculation axis.
Default: A minimum number of 40 steps.
Note
The returned object can be configured regarding the maximum step size or the minimum number of steps on the axis.
- Returns
A new
Linear
object
-
static
logarithmic
()¶ Creates an object for configuring a logarithmic calculation axis.
Default: A scale factor of 1.1
Note
The returned object can be configured regarding the scale factor.
- Returns
A new
Logarithmic
object
-
set_scale_factor
(scale_factor)¶ Sets the scale factor.
Default: 1.1
- Parameters
scale_factor – The scale factor setting the maximum factor between two calculated values, must be larger than 1.0
- Returns
This
Logarithmic
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PhaseDiagramCalculation
(back)¶ Configuration for a phase diagram calculation.
Note
Specify the conditions, the calculation is performed with
calculate()
.-
PhaseDiagramCalculation
(back)¶ Call base constructor:
tc_toolbox.step_or_map_diagrams.AbstractPhaseDiagramCalculation
.
-
add_initial_equilibrium
(initial_equilibrium)¶ Add initial equilibrium start points from which a phase diagram is calculated.
Scans along the axis variables and generates start points when the scan procedure crosses a phase boundary.
It may take a little longer to execute than using the minimum number of start points, as some lines may be calculated more than once. But the core remembers all node points and subsequently stops calculations along a line when it finds a known node point.
It is also possible to create a sequence of start points from one initial equilibria.
- Parameters
initial_equilibrium – The initial equilibrium
- Returns
This
PhaseDiagramCalculation
object
-
calculate
(keep_previous_results, timeout_in_minutes)¶ Performs the phase diagram calculation.
Warning
If you use keep_previous_results=True, you must not use another calculator or even get results in between the calculations using calculate(). Then the previous results will actually be lost.
- Parameters
keep_previous_results – If True, results from any previous call to this method are appended. This can be used to combine calculations with multiple start points if the mapping fails at a certain condition.
timeout_in_minutes – Used to prevent the calculation from running longer than what is wanted, or from hanging. If the calculation runs longer than timeout_in_minutes, a UnrecoverableCalculationException will be thrown, the current TCPython-block will be unusable and a new TCPython block must be created for further calculations.
- Returns
A new
PhaseDiagramResult
object which later can be used to get specific values from the calculated result.
-
disable_global_minimization
()¶ Disables global minimization.
Default: Enabled
- Returns
This
PhaseDiagramCalculation
object
-
dont_keep_default_equilibria
()¶ Do not keep the initial equilibria added by default.
This is only relevant in combination with
add_initial_equilibrium()
.This is the default behavior.
- Returns
This
PhaseDiagramCalculation
object
-
enable_global_minimization
()¶ Enables global minimization.
Default: Enabled
- Returns
This
PhaseDiagramCalculation
object
-
get_components
()¶ Returns the names of the components in the system (including all components auto-selected by the database(s)).
- Returns
The component names
-
get_configuration_as_string
()¶ Returns detailed information about the current state of the calculation object.
Warning
The structure of the calculator objects is an implementation detail and might change between releases without notice. Therefore do not rely on the internal object structure.
-
get_gibbs_energy_addition_for
(phase)¶ Used to get the additional energy term (always being a constant) of a given phase. The value given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
- Returns
Gibbs energy addition to G per mole formula unit.
-
get_system_data
()¶ Returns the content of the database for the currently loaded system. This can be used to modify the parameters and functions and to change the current system by using
with_system_modifications()
.Note
Parameters can only be read from unencrypted (i.e. user) databases loaded as *.tdb-file.
- Returns
The system data
-
invalidate
()¶ Invalidates the object and frees the disk space used by it. This is only required if the disk space occupied by the object needs to be released during the calculation. No data can be retrieved from the object afterwards.
-
keep_default_equilibria
()¶ Keep the initial equilibria added by default. This is only relevant in combination with
add_initial_equilibrium()
.Default behavior is to not keep default equilibria.
- Returns
This
PhaseDiagramCalculation
object
-
remove_all_conditions
()¶ Removes all set conditions.
- Returns
This
PhaseDiagramCalculation
object
-
remove_all_initial_equilibria
()¶ Removes all previously added initial equilibria.
- Returns
This
PhaseDiagramCalculation
object
-
remove_condition
(quantity)¶ Removes the specified condition.
- Parameters
quantity – The thermodynamic quantity to set as condition; a Console Mode syntax string can be used as an alternative (for example X(Cr))
- Returns
This
ThermodynamicCalculation
object
-
run_poly_command
(command)¶ Runs a Thermo-Calc command from the Console Mode POLY module immediately in the engine.
Note
It should not be necessary for most users to use this method, try to use the corresponding method implemented in the API instead.
Warning
As this method runs raw Thermo-Calc commands directly in the engine, it may hang the program in case of spelling mistakes (e.g. forgotten equals sign).
- Parameters
command – The Thermo-Calc Console Mode command
- Returns
This
PhaseDiagramCalculation
object
-
set_condition
(quantity, value)¶ Sets the specified condition.
- Parameters
quantity – The thermodynamic quantity to set as condition; a Console Mode syntax string can be used as an alternative (for example X(Cr))
value – The value of the condition
- Returns
This
PhaseDiagramCalculation
object
-
set_gibbs_energy_addition_for
(phase, gibbs_energy)¶ Used to specify the additional energy term (always being a constant) of a given phase. The value (gibbs_energy) given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
gibbs_energy – Addition to G per mole formula unit
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_dormant
(phase)¶ Sets the phase to the status DORMANT, necessary for calculating the driving force to form the specified phase.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_entered
(phase, amount)¶ Sets the phase to the status ENTERED, that is the default state.
- Parameters
phase – The phase name or ALL_PHASES for all phases
amount – The phase fraction (between 0.0 and 1.0)
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_fixed
(phase, amount)¶ Sets the phase to the status FIXED, i.e. it is guaranteed to have the specified phase fraction after the calculation.
- Parameters
phase – The phase name
amount – The fixed phase fraction (between 0.0 and 1.0)
- Returns
This
PhaseDiagramCalculation
object
-
set_phase_to_suspended
(phase)¶ Sets the phase to the status SUSPENDED, i.e. it is ignored in the calculation.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PhaseDiagramCalculation
object
-
with_first_axis
(axis)¶ Sets the first calculation axis.
- Parameters
axis – The axis
- Returns
This
PhaseDiagramCalculation
object
-
with_options
(options)¶ Sets the simulation options.
- Parameters
options – The simulation options
- Returns
This
PhaseDiagramCalculation
object
-
with_reference_state
(component, phase, temperature, pressure)¶ The reference state for a component is important when calculating activities, chemical potentials and enthalpies and is determined by the database being used. For each component the data must be referred to a selected phase, temperature and pressure, i.e. the reference state.
All data in all phases where this component dissolves must use the same reference state. However, different databases can use different reference states for the same element/component. It is important to be careful when combining data obtained from different databases.
By default, activities, chemical potentials and so forth are computed relative to the reference state used by the database. If the reference state in the database is not suitable for your purposes, use this command to set the reference state for a component using SER, i.e. the Stable Element Reference (which is usually set as default for a major component in alloys dominated by the component). In such cases, the temperature and pressure for the reference state is not needed.
For a phase to be usable as a reference for a component, the component needs to have the same composition as an end member of the phase. The reference state is an end member of a phase. The selection of the end member associated with the reference state is only performed once this command is executed.
If a component has the same composition as several end members of the chosen reference phase, then the end member that is selected at the specified temperature and pressure will have the lowest Gibbs energy.
- Parameters
component – The name of the element must be given.
phase – Name of a phase used as the new reference state. Or SER for the Stable Element Reference.
temperature – The Temperature (in K) for the reference state. Or
CURRENT_TEMPERATURE
which means that the current temperature is used at the time of evaluation of the reference energy for the calculation.pressure – The Pressure (in Pa) for the reference state.
- Returns
This
PhaseDiagramCalculation
object
-
with_second_axis
(axis)¶ Sets the second calculation axis.
- Parameters
axis – The axis
- Returns
This
PhaseDiagramCalculation
object
-
with_system_modifications
(system_modifications)¶ Updates the system of this calculator with the supplied system modification (containing new phase parameters and system functions).
Note
This is only possible if the system has been read from unencrypted (i.e. user) databases loaded as a
*.tdb
-file.- Parameters
system_modifications – The system modification to be performed
- Returns
This
PhaseDiagramCalculation
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PhaseDiagramOptions
¶ Simulation options for phase diagram calculations.
-
PhaseDiagramOptions
()¶ Simulation options for the phase diagram calculations. Constructs an instance of
PhaseDiagramOptions
.
-
disable_approximate_driving_force_for_metastable_phases
()¶ Disables the approximation of the driving force for metastable phases.
Default: Enabled
Note
When enabled, the metastable phases are included in all iterations. However, these may not have reached their most favorable composition and thus their driving forces may be only approximate.
- Returns
This
PhaseDiagramOptions
object
-
disable_control_step_size_during_minimization
()¶ Disables stepsize control during minimization (non-global).
Default: Enabled
- Returns
This
PhaseDiagramOptions
object
-
disable_force_positive_definite_phase_hessian
()¶ Disables forcing of positive definite phase Hessian. This determines how the minimum of an equilibrium state in a normal minimization procedure (non-global) is reached. For details, search the Thermo-Calc documentation for “Hessian minimization”.
Default: Enabled
- Returns
This
PhaseDiagramOptions
object
-
dont_use_auto_start_points
()¶ Switches the usage of automatic starting points for the mapping off.
Default: Switched on
- Returns
This
PhaseDiagramOptions
object
-
dont_use_inside_mesh_points
()¶ Switches the usage of inside meshing points for the mapping off.
Default: Switched off
- Returns
This
PhaseDiagramOptions
object
-
enable_approximate_driving_force_for_metastable_phases
()¶ Enables the approximation of the driving force for metastable phases.
Default: Enabled
Note
When enabled, the metastable phases are included in all iterations. However, these may not have reached their most favorable composition and thus their driving forces may be only approximate.
- Returns
This
PhaseDiagramOptions
object
-
enable_control_step_size_during_minimization
()¶ Enables stepsize control during normal minimization (non-global).
Default: Enabled
- Returns
This
PhaseDiagramOptions
object
-
enable_force_positive_definite_phase_hessian
()¶ Enables forcing of positive definite phase Hessian. This determines how the minimum of an equilibrium state in a normal minimization procedure (non-global) is reached. For details, search the Thermo-Calc documentation for “Hessian minimization”.
Default: Enabled
- Returns
This
PhaseDiagramOptions
object
-
set_global_minimization_max_grid_points
(max_grid_points)¶ Sets the maximum number of grid points in global minimization. ** Only applicable if global minimization is actually used**.
Default: 2000 points
- Parameters
max_grid_points – The maximum number of grid points
- Returns
This
PhaseDiagramOptions
object
-
set_global_minimization_test_interval
(global_test_interval)¶ Sets the interval for the global test.
Default: 0
- Parameters
global_test_interval – The global test interval
- Returns
This
PhaseDiagramOptions
object
-
set_max_no_of_iterations
(max_no_of_iterations)¶ Set the maximum number of iterations.
Default: max. 500 iterations
Note
As some models give computation times of more than 1 CPU second/iteration, this number is also used to check the CPU time and the calculation stops if 500 CPU seconds/iterations are used.
- Parameters
max_no_of_iterations – The max. number of iterations
- Returns
This
PhaseDiagramOptions
object
-
set_no_of_mesh_along_axis
(no_of_mesh_along_axis)¶ Sets the number of meshes along an axis for the mapping.
Default: 3
- Parameters
no_of_mesh_along_axis – The number of meshes
- Returns
This
PhaseDiagramOptions
object
-
set_required_accuracy
(accuracy)¶ Sets the required relative accuracy.
Default: 1.0E-6
Note
This is a relative accuracy, and the program requires that the relative difference in each variable must be lower than this value before it has converged. A larger value normally means fewer iterations but less accurate solutions. The value should be at least one order of magnitude larger than the machine precision.
- Parameters
accuracy – The required relative accuracy
- Returns
This
PhaseDiagramOptions
object
-
set_smallest_fraction
(smallest_fraction)¶ Sets the smallest fraction for constituents that are unstable.
It is normally only in the gas phase that you can find such low fractions.
The default value for the smallest site-fractions is 1E-12 for all phases except for IDEAL phase with one sublattice site (such as the GAS mixture phase in many databases) for which the default value is always as 1E-30.
- Parameters
smallest_fraction – The smallest fraction for constituents that are unstable
- Returns
This
PhaseDiagramOptions
object
-
use_auto_start_points
()¶ Switches the usage of automatic starting points for the mapping on.
Default: Switched on
- Returns
This
PhaseDiagramOptions
object
-
use_inside_mesh_points
()¶ Switches the usage of inside meshing points for the mapping off.
Default: Switched off
- Returns
This
PhaseDiagramOptions
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PhaseDiagramResult
(back)¶ Result of a phase diagram calculation, it can be evaluated using quantities or Console Mode syntax.
-
PhaseDiagramResult
(back)¶ Call base constructor:
tc_toolbox.AbstractResult
.
-
add_coordinate_for_phase_label
(x, y)¶ Sets a coordinate in the result plot for which the stable phases will be evaluated and provided in the result data object. This can be used to plot the phases of a region into the phase diagram or just to programmatically evaluate the phases in certain regions.
Warning
This method takes coordinates of the plot axes and not of the calculation axis.
- Parameters
x – The coordinate of the first plot axis (“x-axis”) [unit of the plot axis]
y – The coordinate of the second plot axis (“y-axis”) [unit of the plot axis]
- Returns
This
PhaseDiagramResult
object
-
get_values_grouped_by_quantity_of
(x_quantity, y_quantity)¶ Returns x-y-line data grouped by the multiple datasets of the specified quantities (for example in dependency of components). The available quantities can be found in the documentation of the factory class
ThermodynamicQuantity
. Usually the result data represents the phase diagram.Note
The different datasets will contain NaN-values between different subsections and are not sorted (because they are unsortable due to their nature).
Note
Its possible to use functions as axis variables, either by using ThermodynamicQuantity.user_defined_function, or by using an expression that contains ‘=’.
- Parameters
x_quantity – The first quantity (“x-axis”), Console Mode syntax strings can be used as an alternative (for example ‘T’), or even a function (for example ‘f=T*1.01’)
y_quantity – The second quantity (“y-axis”), Console Mode syntax strings can be used as an alternative (for example ‘NV’), or even a function (for example ‘CP=HM.T’)
- Returns
The phase diagram data
-
get_values_grouped_by_stable_phases_of
(x_quantity, y_quantity)¶ Returns x-y-line data grouped by the sets of “stable phases” (for example “LIQUID” or “LIQUID + FCC_A1”). The available quantities can be found in the documentation of the factory class
ThermodynamicQuantity
. Usually the result data represents the phase diagram.Note
The different datasets will contain NaN-values between different subsections and are not sorted (because they are unsortable due to their nature).
Note
Its possible to use functions as axis variables, either by using ThermodynamicQuantity.user_defined_function, or by using an expression that contains ‘=’.
- Parameters
x_quantity – The first quantity (“x-axis”), Console Mode syntax strings can be used as an alternative (for example ‘T’), or even a function (for example ‘f=T*1.01’)
y_quantity – The second quantity (“y-axis”), Console Mode syntax strings can be used as an alternative (for example ‘NV’), or even a function (for example ‘CP=HM.T’)
- Returns
The phase diagram data
-
invalidate
()¶ Invalidates the object and frees the disk space used by it. This is only required if the disk space occupied by the object needs to be released during the calculation. No data can be retrieved from the object afterwards.
-
remove_phase_labels
()¶ Erases all added coordinates for phase labels.
- Returns
This
PhaseDiagramResult
object
-
save_to_disk
(path)¶ Saves the result to disc. Note that a result is a folder, containing potentially many files. The result can later be loaded with
load_result_from_disk()
- Parameters
path – the path to the folder you want the result to be saved in. It can be relative or absolute.
- Returns
this
PhaseDiagramResult
object
-
set_phase_name_style
(phase_name_style_enum)¶ Sets the style of the phase name labels that will be used in the result data object (constitution description, ordering description, …).
Default: PhaseNameStyle.NONE
- Parameters
phase_name_style_enum – The phase name style
- Returns
This
PhaseDiagramResult
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PhaseDiagramResultValues
(back)¶ Represents the data of a phase diagram.
-
PhaseDiagramResultValues
(back)¶ Constructs an instance of
PhaseDiagramResultValues
.
-
get_invariants
()¶ Returns the x- and y-datasets of all invariants in the phase diagram.
Note
The datasets will normally contain different sections separated by NaN-values.
- Returns
The invariants dataset object
-
get_lines
()¶ Returns the x- and y-datasets of all phase boundaries in the phase diagram.
Note
The datasets will normally contain different sections separated by NaN-values.
- Returns
Containing the phase boundary datasets with the quantities or stable phases as keys (depending on the used method to get the values)
-
get_phase_labels
()¶ Returns the phase labels added for certain coordinates using
PhaseDiagramResult.add_coordinate_for_phase_label()
.- Returns
The list with the phase label data (that contains plot coordinates and stable phases)
-
get_tie_lines
()¶ Returns the x- and y-datasets of all tie-lines in the phase diagram.
Note
The datasets will normally contain different sections separated by NaN-values.
- Returns
The tie-line dataset object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PhaseLabel
(back)¶ Represents a phase label at a plot coordinate, i.e. the stable phases that are present at that plot coordinate.
-
PhaseLabel
(back)¶ Constructs an instance of
PhaseLabel
.
-
get_text
()¶ Accessor for the phase label :return: the phase label
-
get_x
()¶ Accessor for the x-value :return: the x value
-
get_y
()¶ Accessor for the y-value :return: the y value
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PhaseNameStyle
¶ The style of the phase names used in the labels.
-
class
+tc_toolbox.+step_or_map_diagrams.
PropertyDiagramCalculation
(back)¶ Abstract configuration required for a property diagram calculation.
Note
This is an abstract class that cannot be used directly.
-
PropertyDiagramCalculation
(back)¶ Call base constructor:
tc_toolbox.step_or_map_diagrams.AbstractPropertyDiagramCalculation
.
-
calculate
(keep_previous_results, timeout_in_minutes)¶ Performs the property diagram calculation.
Warning
If you use keep_previous_results=True, you must not use another calculator or even get results in between the calculations using
calculate()
. Then the previous results will actually be lost.- Parameters
keep_previous_results – If True, results from any previous call to this method are appended. This can be used to combine calculations with multiple start points if the stepping fails at a certain condition.
timeout_in_minutes – Used to prevent the calculation from running longer than what is wanted, or from hanging. If the calculation runs longer than timeout_in_minutes, a UnrecoverableCalculationException will be thrown, the current TCPython-block will be unusable and a new TCPython block must be created for further calculations.
- Returns
A new
PropertyDiagramResult
object which later can be used to get specific values from the calculated result
-
disable_global_minimization
()¶ Disables global minimization.
Default: Enabled
- Returns
This
PropertyDiagramCalculation
object
-
disable_step_separate_phases
()¶ Disables step separate phases. This is the default setting.
- Returns
This
PropertyDiagramCalculation
object
-
enable_global_minimization
()¶ Enables global minimization.
Default: Enabled
- Returns
This
PropertyDiagramCalculation
object
-
enable_step_separate_phases
()¶ Enables step separate phases.
Default: By default separate phase stepping is disabled
Note
This is an advanced option, it is used mostly to calculate how the Gibbs energy for a number of phases varies for different compositions. This is particularly useful to calculate Gibbs energies for complex phases with miscibility gaps and for an ordered phase that is never disordered (e.g. SIGMA-phase, G-phase, MU-phase, etc.).
- Returns
This
PropertyDiagramCalculation
object
-
get_components
()¶ Returns the names of the components in the system (including all components auto-selected by the database(s)).
- Returns
The component names
-
get_configuration_as_string
()¶ Returns detailed information about the current state of the calculation object.
Warning
The structure of the calculator objects is an implementation detail and might change between releases without notice. Therefore do not rely on the internal object structure.
-
get_gibbs_energy_addition_for
(phase)¶ Used to get the additional energy term (always being a constant) of a given phase. The value given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
- Returns
Gibbs energy addition to G per mole formula unit.
-
get_system_data
()¶ Returns the content of the database for the currently loaded system. This can be used to modify the parameters and functions and to change the current system by using
with_system_modifications()
.Note
Parameters can only be read from unencrypted (i.e. user) databases loaded as *.tdb-file.
- Returns
The system data
-
invalidate
()¶ Invalidates the object and frees the disk space used by it. This is only required if the disk space occupied by the object needs to be released during the calculation. No data can be retrieved from the object afterwards.
-
remove_all_conditions
()¶ Removes all set conditions.
- Returns
This
PropertyDiagramCalculation
object
-
remove_condition
(quantity)¶ Removes the specified condition.
- Parameters
quantity – The thermodynamic quantity to set as condition; a Console Mode syntax string can be used as an alternative (for example X(Cr))
- Returns
This
PropertyDiagramCalculation
object
-
run_poly_command
(command)¶ Runs a Thermo-Calc command from the Console Mode POLY module immediately in the engine.
Note
It should not be necessary for most users to use this method, try to use the corresponding method implemented in the API instead.
Warning
As this method runs raw Thermo-Calc commands directly in the engine, it may hang the program in case of spelling mistakes (e.g. forgotten equals sign).
- Parameters
command – The Thermo-Calc Console Mode command
- Returns
This
PropertyDiagramCalculation
object
-
set_condition
(quantity, value)¶ Sets the specified condition.
- Parameters
quantity – The thermodynamic quantity to set as condition; a Console Mode syntax string can be used as an alternative (for example X(Cr))
value – The value of the condition
- Returns
This
PropertyDiagramCalculation
object
-
set_gibbs_energy_addition_for
(phase, gibbs_energy)¶ Used to specify the additional energy term (always being a constant) of a given phase. The value (gibbs_energy) given is added to the Gibbs energy of the (stoichiometric or solution) phase. It can represent a nucleation barrier, surface tension, elastic energy, etc.
It is not composition-, temperature- or pressure-dependent.
- Parameters
phase – Specify the name of the (stoichiometric or solution) phase with the addition
gibbs_energy – Addition to G per mole formula unit
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_dormant
(phase)¶ Sets the phase to the status DORMANT, necessary for calculating the driving force to form the specified phase.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_entered
(phase, amount)¶ Sets the phase to the status ENTERED, that is the default state.
- Parameters
phase – The phase name or ALL_PHASES for all phases
amount – The phase fraction (between 0.0 and 1.0)
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_fixed
(phase, amount)¶ Sets the phase to the status FIXED, i.e. it is guaranteed to have the specified phase fraction after the calculation.
- Parameters
phase – The phase name
amount – The fixed phase fraction (between 0.0 and 1.0)
- Returns
This
PropertyDiagramCalculation
object
-
set_phase_to_suspended
(phase)¶ Sets the phase to the status SUSPENDED, i.e. it is ignored in the calculation.
- Parameters
phase – The phase name or ALL_PHASES for all phases
- Returns
This
PropertyDiagramCalculation
object
-
with_axis
(axis)¶ Sets the calculation axis.
- Parameters
axis – The axis
- Returns
This
PropertyDiagramCalculation
object
-
with_options
(options)¶ Sets the simulation options.
- Parameters
options – The simulation options
- Returns
This
PropertyDiagramCalculation
object
-
with_reference_state
(component, phase, temperature, pressure)¶ The reference state for a component is important when calculating activities, chemical potentials and enthalpies and is determined by the database being used. For each component the data must be referred to a selected phase, temperature and pressure, i.e. the reference state.
All data in all phases where this component dissolves must use the same reference state. However, different databases can use different reference states for the same element/component. It is important to be careful when combining data obtained from different databases.
By default, activities, chemical potentials and so forth are computed relative to the reference state used by the database. If the reference state in the database is not suitable for your purposes, use this command to set the reference state for a component using SER, i.e. the Stable Element Reference (which is usually set as default for a major component in alloys dominated by the component). In such cases, the temperature and pressure for the reference state is not needed.
For a phase to be usable as a reference for a component, the component needs to have the same composition as an end member of the phase. The reference state is an end member of a phase. The selection of the end member associated with the reference state is only performed once this command is executed.
If a component has the same composition as several end members of the chosen reference phase, then the end member that is selected at the specified temperature and pressure will have the lowest Gibbs energy.
- Parameters
component – The name of the element must be given.
phase – Name of a phase used as the new reference state. Or SER for the Stable Element Reference.
temperature – The Temperature (in K) for the reference state. Or
CURRENT_TEMPERATURE
which means that the current temperature is used at the time of evaluation of the reference energy for the calculation.pressure – The Pressure (in Pa) for the reference state.
- Returns
This
PropertyDiagramCalculation
object
-
with_system_modifications
(system_modifications)¶ Updates the system of this calculator with the supplied system modification (containing new phase parameters and system functions).
Note
This is only possible if the system has been read from unencrypted (i.e. user) databases loaded as a
*.tdb
-file.- Parameters
system_modifications – The system modification to be performed
- Returns
This
PropertyDiagramCalculation
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PropertyDiagramOptions
¶ Simulation options for the property diagram calculations.
-
PropertyDiagramOptions
()¶ Simulation options for property diagram calculations. Constructs an instance of
PropertyDiagramOptions
.
-
disable_approximate_driving_force_for_metastable_phases
()¶ Disables the approximation of the driving force for metastable phases.
Default: Enabled
Note
When enabled, the metastable phases are included in all iterations. However, these may not have reached their most favorable composition and thus their driving forces may be only approximate.
- Returns
This
PropertyDiagramOptions
object
-
disable_control_step_size_during_minimization
()¶ Disables stepsize control during minimization (non-global).
Default: Enabled
- Returns
This
PropertyDiagramOptions
object
-
disable_force_positive_definite_phase_hessian
()¶ Disables forcing of positive definite phase Hessian. This determines how the minimum of an equilibrium state in a normal minimization procedure (non-global) is reached. For details, search the Thermo-Calc documentation for “Hessian minimization”.
Default: Enabled
- Returns
This
PropertyDiagramOptions
object
-
enable_approximate_driving_force_for_metastable_phases
()¶ Enables the approximation of the driving force for metastable phases.
Default: Enabled
Note
When enabled, the metastable phases are included in all iterations. However, these may not have reached their most favorable composition and thus their driving forces may be only approximate.
- Returns
This
PropertyDiagramOptions
object
-
enable_control_step_size_during_minimization
()¶ Enables stepsize control during normal minimization (non-global).
Default: Enabled
- Returns
This
PropertyDiagramOptions
object
-
enable_force_positive_definite_phase_hessian
()¶ Enables forcing of positive definite phase Hessian. This determines how the minimum of an equilibrium state in a normal minimization procedure (non-global) is reached. For details, search the Thermo-Calc documentation for “Hessian minimization”.
Default: Enabled
- Returns
This
PropertyDiagramOptions
object
-
set_global_minimization_max_grid_points
(max_grid_points)¶ Sets the maximum number of grid points in global minimization. Only applicable if global minimization is actually used.
Default: 2000 points
- Parameters
max_grid_points – The maximum number of grid points
- Returns
This
PropertyDiagramOptions
object
-
set_global_minimization_test_interval
(global_test_interval)¶ Sets the interval for the global test.
Default: 0
- Parameters
global_test_interval – The global test interval
- Returns
This
PropertyDiagramOptions
object
-
set_max_no_of_iterations
(max_no_of_iterations)¶ Set the maximum number of iterations.
Default: max. 500 iterations
Note
As some models give computation times of more than 1 CPU second/iteration, this number is also used to check the CPU time and the calculation stops if 500 CPU seconds/iterations are used.
- Parameters
max_no_of_iterations – The max. number of iterations
- Returns
This
PropertyDiagramOptions
object
-
set_required_accuracy
(accuracy)¶ Sets the required relative accuracy.
Default: 1.0E-6
Note
This is a relative accuracy, and the program requires that the relative difference in each variable must be lower than this value before it has converged. A larger value normally means fewer iterations but less accurate solutions. The value should be at least one order of magnitude larger than the machine precision.
- Parameters
accuracy – The required relative accuracy
- Returns
This
PropertyDiagramOptions
object
-
set_smallest_fraction
(smallest_fraction)¶ Sets the smallest fraction for constituents that are unstable.
It is normally only in the gas phase that you can find such low fractions.
The default value for the smallest site-fractions is 1E-12 for all phases except for IDEAL phase with one sublattice site (such as the GAS mixture phase in many databases) for which the default value is always as 1E-30.
- Parameters
smallest_fraction – The smallest fraction for constituents that are unstable
- Returns
This
PropertyDiagramOptions
object
-
-
class
+tc_toolbox.+step_or_map_diagrams.
PropertyDiagramResult
(back)¶ Result of a property diagram. This can be used to query for specific values.
-
PropertyDiagramResult
(back)¶ Call base constructor:
tc_toolbox.AbstractResult
.
-
get_values_grouped_by_quantity_of
(x_quantity, y_quantity, sort_and_merge)¶ Returns x-y-line data grouped by the multiple datasets of the specified quantities (typically the phases). The available quantities can be found in the documentation of the factory class
ThermodynamicQuantity
.Note
The different datasets might contain NaN-values between different subsections and might not be sorted even if the flag `sort_and_merge` has been set (because they might be unsortable due to their nature).
Note
Its possible to use functions as axis variables, either by using ThermodynamicQuantity.user_defined_function, or by using an expression that contains ‘=’.
- Parameters
x_quantity – The first quantity (“x-axis”), Console Mode syntax strings can be used as an alternative (for example ‘T’), or even a function (for example ‘f=T*1.01’)
y_quantity – The second quantity (“y-axis”), Console Mode syntax strings can be used as an alternative (for example ‘NV’), or even a function (for example ‘CP=HM.T’)
sort_and_merge – If True, the data is sorted and merged into as few subsections as possible (divided by NaN)
- Returns
Containing the datasets with the quantities as their keys
-
get_values_grouped_by_stable_phases_of
(x_quantity, y_quantity, sort_and_merge)¶ Returns x-y-line data grouped by the sets of “stable phases” (for example “LIQUID” or “LIQUID + FCC_A1”). The available quantities can be found in the documentation of the factory class
ThermodynamicQuantity
.Note
The different datasets might contain NaN-values between different subsections and different lines of an ambiguous dataset. They might not be sorted even if the flag `sort_and_merge` has been set (because they might be unsortable due to their nature).
Note
Its possible to use functions as axis variables, either by using ThermodynamicQuantity.user_defined_function, or by using an expression that contains ‘=’.
- Parameters
x_quantity – The first quantity (“x-axis”), Console Mode syntax strings can be used as an alternative (for example ‘T’), or even a function (for example ‘f=T*1.01’)
y_quantity – The second quantity (“y-axis”), Console Mode syntax strings can be used as an alternative (for example ‘NV’), or even a function (for example ‘CP=HM.T’)
sort_and_merge – If True, the data will be sorted and merged into as few subsections as possible (divided by NaN)
- Returns
Containing the datasets with the quantities as their keys
-
get_values_of
(x_quantity, y_quantity)¶ Returns sorted x-y-line data without any separation. Use
get_values_grouped_by_quantity_of()
orget_values_grouped_by_stable_phases_of()
instead if you need such a separation. The available quantities can be found in the documentation of the factory classThermodynamicQuantity
.Note
This method will always return sorted data without any NaN-values. If it is unsortable that might give data that is hard to interpret. In such a case you need to choose the quantity in another way or use one of the other methods. One example of this is to use quantities with All-markers, for example MassFractionOfAComponent(“All”).
Note
Its possible to use functions as axis variables, either by using ThermodynamicQuantity.user_defined_function, or by using an expression that contains ‘=’.
- Parameters
x_quantity – The first Thermodynamic quantity (“x-axis”), Console Mode syntax strings can be used as an alternative (for example ‘T’) or even a function (for example ‘f=T*1.01’)
y_quantity – The second Thermodynamic quantity (“y-axis”), Console Mode syntax strings can be used as an alternative (for example ‘NV’), or even a function (for example ‘CP=HM.T’)
- Returns
A tuple containing the x- and y-data in lists
-
invalidate
()¶ Invalidates the object and frees the disk space used by it. This is only required if the disk space occupied by the object needs to be released during the calculation. No data can be retrieved from the object afterwards.
-
save_to_disk
(path)¶ Saves the result to disc. Note that a result is a folder, containing potentially many files. The result can later be loaded with
load_result_from_disk()
- Parameters
path – the path to the folder you want the result to be saved in. It can be relative or absolute.
- Returns
this
PropertyDiagramResult
object
-
set_phase_name_style
(phase_name_style_enum)¶ Sets the style of the phase name labels that will be used in the result data object (constitution description, ordering description, …).
Default: PhaseNameStyle.NONE
- Parameters
phase_name_style_enum – The phase name style
- Returns
This
PropertyDiagramResult
object
-