ProductEvaluation

class ProductEvaluation(*args)

Proxy of C++ OT::ProductEvaluation.

Attributes:
thisown

The membership flag

Methods

__call__(*args) Call self as a function.
draw(*args) Draw the output of function as a Graph.
getCallsNumber() Accessor to the number of times the function has been called.
getClassName() Accessor to the object’s name.
getDescription() Accessor to the description of the inputs and outputs.
getId() Accessor to the object’s id.
getInputDescription() Accessor to the description of the inputs.
getInputDimension() Accessor to the number of the inputs.
getMarginal(*args) Accessor to marginal.
getName() Accessor to the object’s name.
getOutputDescription() Accessor to the description of the outputs.
getOutputDimension() Accessor to the number of the outputs.
getParameter() Accessor to the parameter values.
getParameterDescription() Accessor to the parameter description.
getParameterDimension() Accessor to the dimension of the parameter.
getShadowedId() Accessor to the object’s shadowed id.
getVisibility() Accessor to the object’s visibility state.
hasName() Test if the object is named.
hasVisibleName() Test if the object has a distinguishable name.
isActualImplementation() Accessor to the validity flag.
parameterGradient(inP) Gradient against the parameters.
setDescription(description) Accessor to the description of the inputs and outputs.
setInputDescription(inputDescription) Accessor to the description of the inputs.
setName(name) Accessor to the object’s name.
setOutputDescription(outputDescription) Accessor to the description of the outputs.
setParameter(parameter) Accessor to the parameter values.
setParameterDescription(description) Accessor to the parameter description.
setShadowedId(id) Accessor to the object’s shadowed id.
setVisibility(visible) Accessor to the object’s visibility state.
__init__(*args)

Initialize self. See help(type(self)) for accurate signature.

draw(*args)

Draw the output of function as a Graph.

Available usages:

draw(inputMarg, outputMarg, CP, xiMin, xiMax, ptNb)

draw(firstInputMarg, secondInputMarg, outputMarg, CP, xiMin_xjMin, xiMax_xjMax, ptNbs)

draw(xiMin, xiMax, ptNb)

draw(xiMin_xjMin, xiMax_xjMax, ptNbs)

Parameters:
outputMarg, inputMarg : int, outputMarg, inputMarg \geq 0

outputMarg is the index of the marginal to draw as a function of the marginal with index inputMarg.

firstInputMarg, secondInputMarg : int, firstInputMarg, secondInputMarg \geq 0

In the 2D case, the marginal outputMarg is drawn as a function of the two marginals with indexes firstInputMarg and secondInputMarg.

CP : sequence of float

Central point.

xiMin, xiMax : float

Define the interval where the curve is plotted.

xiMin_xjMin, xiMax_xjMax : sequence of float of dimension 2.

In the 2D case, define the intervals where the curves are plotted.

ptNb : int ptNb > 0 or list of ints of dimension 2 ptNb_k > 0, k=1,2

The number of points to draw the curves.

Notes

We note f: \Rset^n \rightarrow \Rset^p where \vect{x} = (x_1, \dots, x_n) and f(\vect{x}) = (f_1(\vect{x}), \dots,f_p(\vect{x})), with n\geq 1 and p\geq 1.

  • In the first usage:

Draws graph of the given 1D outputMarg marginal f_k: \Rset^n \rightarrow \Rset as a function of the given 1D inputMarg marginal with respect to the variation of x_i in the interval [x_i^{min}, x_i^{max}], when all the other components of \vect{x} are fixed to the corresponding ones of the central point CP. Then it draws the graph: t\in [x_i^{min}, x_i^{max}] \mapsto f_k(CP_1, \dots, CP_{i-1}, t,  CP_{i+1} \dots, CP_n).

  • In the second usage:

Draws the iso-curves of the given outputMarg marginal f_k as a function of the given 2D firstInputMarg and secondInputMarg marginals with respect to the variation of (x_i, x_j) in the interval [x_i^{min}, x_i^{max}] \times [x_j^{min}, x_j^{max}], when all the other components of \vect{x} are fixed to the corresponding ones of the central point CP. Then it draws the graph: (t,u) \in [x_i^{min}, x_i^{max}] \times [x_j^{min}, x_j^{max}] \mapsto f_k(CP_1, \dots, CP_{i-1}, t, CP_{i+1}, \dots, CP_{j-1}, u,  CP_{j+1} \dots, CP_n).

  • In the third usage:

The same as the first usage but only for function f: \Rset \rightarrow \Rset.

  • In the fourth usage:

The same as the second usage but only for function f: \Rset^2 \rightarrow \Rset.

Examples

>>> import openturns as ot
>>> from openturns.viewer import View
>>> f = ot.SymbolicFunction(['x'], ['sin(2*pi_*x)*exp(-x^2/2)'])
>>> graph = f.draw(-1.2, 1.2, 100)
>>> View(graph).show()
getCallsNumber()

Accessor to the number of times the function has been called.

Returns:
calls_number : int

Integer that counts the number of times the function has been called since its creation.

getClassName()

Accessor to the object’s name.

Returns:
class_name : str

The object class name (object.__class__.__name__).

getDescription()

Accessor to the description of the inputs and outputs.

Returns:
description : Description

Description of the inputs and the outputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getDescription())
[x1,x2,y0]
getId()

Accessor to the object’s id.

Returns:
id : int

Internal unique identifier.

getInputDescription()

Accessor to the description of the inputs.

Returns:
description : Description

Description of the inputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getInputDescription())
[x1,x2]
getInputDimension()

Accessor to the number of the inputs.

Returns:
number_inputs : int

Number of inputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getInputDimension())
2
getMarginal(*args)

Accessor to marginal.

Parameters:
indices : int or list of ints

Set of indices for which the marginal is extracted.

Returns:
marginal : Function

Function corresponding to either f_i or (f_i)_{i \in indices}, with f:\Rset^n \rightarrow \Rset^p and f=(f_0 , \dots, f_{p-1}).

getName()

Accessor to the object’s name.

Returns:
name : str

The name of the object.

getOutputDescription()

Accessor to the description of the outputs.

Returns:
description : Description

Description of the outputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getOutputDescription())
[y0]
getOutputDimension()

Accessor to the number of the outputs.

Returns:
number_outputs : int

Number of outputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getOutputDimension())
1
getParameter()

Accessor to the parameter values.

Returns:
parameter : Point

The parameter values.

getParameterDescription()

Accessor to the parameter description.

Returns:
parameter : Description

The parameter description.

getParameterDimension()

Accessor to the dimension of the parameter.

Returns:
parameter_dimension : int

Dimension of the parameter.

getShadowedId()

Accessor to the object’s shadowed id.

Returns:
id : int

Internal unique identifier.

getVisibility()

Accessor to the object’s visibility state.

Returns:
visible : bool

Visibility flag.

hasName()

Test if the object is named.

Returns:
hasName : bool

True if the name is not empty.

hasVisibleName()

Test if the object has a distinguishable name.

Returns:
hasVisibleName : bool

True if the name is not empty and not the default one.

isActualImplementation()

Accessor to the validity flag.

Returns:
is_impl : bool

Whether the implementation is valid.

parameterGradient(inP)

Gradient against the parameters.

Parameters:
x : sequence of float

Input point

Returns:
parameter_gradient : Matrix

The parameters gradient computed at x.

setDescription(description)

Accessor to the description of the inputs and outputs.

Parameters:
description : sequence of str

Description of the inputs and the outputs.

Examples

>>> import openturns as ot
>>> f = ot.SymbolicFunction(['x1', 'x2'],
...                         ['2 * x1^2 + x1 + 8 * x2 + 4 * cos(x1) * x2 + 6'])
>>> print(f.getDescription())
[x1,x2,y0]
>>> f.setDescription(['a','b','y'])
>>> print(f.getDescription())
[a,b,y]
setInputDescription(inputDescription)

Accessor to the description of the inputs.

Returns:
description : Description

Description of the inputs.

setName(name)

Accessor to the object’s name.

Parameters:
name : str

The name of the object.

setOutputDescription(outputDescription)

Accessor to the description of the outputs.

Returns:
description : Description

Description of the outputs.

setParameter(parameter)

Accessor to the parameter values.

Parameters:
parameter : sequence of float

The parameter values.

setParameterDescription(description)

Accessor to the parameter description.

Parameters:
parameter : Description

The parameter description.

setShadowedId(id)

Accessor to the object’s shadowed id.

Parameters:
id : int

Internal unique identifier.

setVisibility(visible)

Accessor to the object’s visibility state.

Parameters:
visible : bool

Visibility flag.

thisown

The membership flag