real
Discrete, epistemic uncertain variable - real numbers within a set
Topics
discrete_variables, epistemic_uncertain_variables
Specification
Alias: None
Arguments: INTEGER
Default: no discrete uncertain set real variables
Child Keywords:
Required/Optional |
Description of Group |
Dakota Keyword |
Dakota Keyword Description |
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Optional |
Number of admissible elements for each set variable |
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Required |
The permissible values for each discrete variable |
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Optional |
This keyword defines the probabilities for the various elements of discrete sets. |
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Optional |
Whether the set-valued variables are categorical or relaxable |
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Optional |
Initial values for variables |
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Optional |
Labels for the variables |
Description
Discrete set variables may be used to specify categorical choices which are epistemic. For example, if we have three possible forms for a physics model (model 1, 2, or 3) and there is epistemic uncertainty about which one is correct, a discrete uncertain set may be used to represent this type of uncertainty.
This variable is defined by a set of reals, in which the discrete variable may take any value defined within the real set (for example, a parameter may have two allowable real values, 3.285 or 4.79).
Other epistemic types include:
discrete_uncertain_set variables-discrete_uncertain_set-integer
discrete_uncertain_set variables-discrete_uncertain_set-string
Examples
Let d1 be 2.1 or 1.3 and d2 be 0.4, 5 or 2.6. The following specification is for an interval analysis:
discrete_uncertain_set
integer
num_set_values 2 3
set_values 2.1 1.3 0.4 5 2.6
descriptors 'dr1' 'dr2'
Theory
The discrete_uncertain_set-integer
variable is NOT a discrete random variable.
It can be contrasted to a the histogram-defined random variables:
variables-histogram_bin_uncertain and variables-histogram_point_uncertain.
It is used in epistemic uncertainty analysis, where one is trying to model
uncertainty due to lack of knowledge.
The discrete uncertain set integer variable is used in both interval analysis and in Dempster-Shafer theory of evidence.
interval analysis
-the values are integers, equally weighted -the true value of the random variable is one of the integers in this set -output is the minimum and maximum function value conditionalon the specified inputs
Dempster-Shafer theory of evidence
-the values are integers, but they can be assigned different weights -outputs are called “belief” and “plausibility.”Belief represents the smallest possible probability that is consistent with the evidence, while plausibility represents the largest possible probability that is consistent with the evidence. Evidence is the values together with their weights.