Terminology in Interpretive Structural Modeling: Difference between revisions

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|[[Flexible Interpretive Structural Modeling]]
|[[Flexible Interpretive Structural Modeling]]
|Extended and improved version of Warfield's ISM.
|Extended version of Warfield's ISM; allows corrections while a structural model is being developed, or after it has been developed.
|[[Ohuchi & Kaji, 1989]].
|[[Ohuchi & Kaji, 1989]].
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|[[Transitive Coupling Problem]]
|[[Transitive Coupling Problem]]
|mmmmmmmm
|The problem of interconnecting two multilevel subsystem models defined on the same contextual relation that is transitive.
|ref
|ref
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|[[Complete implication matrix Ψ]]
|[[Complete Implication Matrix Ψ]]
|mmmmmmmm
|mmmmmmmm
|ref
|ref
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|[[Total Interpretive Structural Modeling]]
|[[Total Interpretive Structural Modeling]]
|mmmmmmmm
|Approach used for theory building; helps researchers answer the fundamental research questions of what, how, and why; helps identify and define the variables, the relationship between them, and the reason for causality between variables.
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|[[Flexible Interpretive Structural Modeling]]
|mmmmmmmm
|ref
|ref
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|[[Transitive bordering]]
|[[Transitive bordering]]
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|Special case of [[Transitive Coupling]] in which the sub-system B consists of a single element.
|ref
|ref
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|[[Transitive System]]
|[[Transitive System]]
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|A system whose elements are related with [[Transitive Relations]].
|ref
|ref
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|[[Question Algorithm]]
|[[Question Algorithm]]
|mmmmmmmm
|The logic used to select the next unknown for questioning
|ref
|ref
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|[[One-first Procedure]]
|[[One-first Procedure]]
|mmmmmmmm
|Performed when the [[One-first Selection Rule]] is chosen.
|ref
|ref
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|[[Structural Self-Interaction Matrix]]
|[[Structural Self-Interaction Matrix]]
|ref
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|[[Deletion Procedure]]
|Deletion of one or more elements and their connections in the M matrix.
|ref
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|[[Addition Procedure]]
|Addition of one or more elements and their connections in the M matrix.
|ref
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|[[Standard Form to Condensation Matrix]]
|Replace a cycle set with one of the elements in the set.
|ref
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|[[Hierarchical Matrices]]
|
|ref
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|[[Characteristic Logic Equation]]
|Expresses the necessary and sufficient conditions to be satisfied by the entries in an [[Interconnection Matrix]] M<sub>BA</sub>, that interconnects two hierarchical digraphs A<sup>*</sup> and B<sup>*</sup> for which M<sub>AB</sub> = 0.
|ref
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|[[Cascade Interconnection of Digraphs]]
|Two [[Digraphs]] are said to be cascaded if all interconnections are oriented from one of the digraphs to the other.
|ref
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|[[Digraphs]]
|A directed graph, also called a digraph, is a graph in which the edges have a direction.
|ref
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|[[Reachability Matrix]]
|Reachability refers to the ability to get from one vertex to another within a graph.
|ref
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|[[Structural Equation Modeling]]
|Set of statistical techniques used to measure and analyze the relationships of observed and latent variables.
|ref
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|[[Transitive Relations]]
|Relationships for which if element X is related to element Y, and element Y is related to element Z of the set, we can derive thatelement A must be related to element Z.
|ref
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|[[Transitive Closure]]
|...
|ref
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|[[Binary Matrices]]
|All elements are either 0 or 1; In ISM they are square.
|ref
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|[[Partitioning of an Element]]
|e.
|ref
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|[[Binary Matrix Model]]
|A binary matrix and three associations (indicated by colons), i.e. <br> M = { N, V: I<sub>s</sub>, H: I<sub>t</sub>, ''R̂'': ''R'' }
|ref
|ref
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