Specificity shift in solving fuzzy relational equations

Kaoru Hirota; Witold Pedrycz

doi:10.1016/S0165-0114(97)00286-8

Specificity shift in solving fuzzy relational equations

Kaoru Hirota, Witold Pedrycz^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Studied is a system of "N" fuzzy relational equations with a max-t composition x(k)□R = y(k), where the input-output fuzzy sets (x(k) and y(k)) are available while the fuzzy relation (R) needs to be determined. The solution to these equations is derived through a new paradigm of specificity shift. The main objective is to modify a level of specificity of the fuzzy sets (relational constraint) so that the modified constraints allow for the use of some standard theoretical results of the theory of fuzzy relational equations that otherwise would have been found totally unjustifiable. In more detail, the specificity of the available input fuzzy sets becomes gradually increased while an opposite tendency is observed for the output fuzzy sets. The optimization of the specificity levels is discussed in detail. Numerical studies are also included. Finally, the use of the specificity shift is discussed in a conjunction with the exploitation of standard gradient-based techniques.

Original language	English
Pages (from-to)	211-220
Number of pages	10
Journal	Fuzzy Sets and Systems
Volume	106
Issue number	2
DOIs	https://doi.org/10.1016/S0165-0114(97)00286-8
Publication status	Published - 1 Sept 1999
Externally published	Yes

Keywords

Approximate solutions
Fuzzy relational equations
Gradient-oriented methods
Hybrid methods
Max-t composition
Specificity shift

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10.1016/S0165-0114(97)00286-8

Cite this

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title = "Specificity shift in solving fuzzy relational equations",

abstract = "Studied is a system of {"}N{"} fuzzy relational equations with a max-t composition x(k)□R = y(k), where the input-output fuzzy sets (x(k) and y(k)) are available while the fuzzy relation (R) needs to be determined. The solution to these equations is derived through a new paradigm of specificity shift. The main objective is to modify a level of specificity of the fuzzy sets (relational constraint) so that the modified constraints allow for the use of some standard theoretical results of the theory of fuzzy relational equations that otherwise would have been found totally unjustifiable. In more detail, the specificity of the available input fuzzy sets becomes gradually increased while an opposite tendency is observed for the output fuzzy sets. The optimization of the specificity levels is discussed in detail. Numerical studies are also included. Finally, the use of the specificity shift is discussed in a conjunction with the exploitation of standard gradient-based techniques.",

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AU - Pedrycz, Witold

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AB - Studied is a system of "N" fuzzy relational equations with a max-t composition x(k)□R = y(k), where the input-output fuzzy sets (x(k) and y(k)) are available while the fuzzy relation (R) needs to be determined. The solution to these equations is derived through a new paradigm of specificity shift. The main objective is to modify a level of specificity of the fuzzy sets (relational constraint) so that the modified constraints allow for the use of some standard theoretical results of the theory of fuzzy relational equations that otherwise would have been found totally unjustifiable. In more detail, the specificity of the available input fuzzy sets becomes gradually increased while an opposite tendency is observed for the output fuzzy sets. The optimization of the specificity levels is discussed in detail. Numerical studies are also included. Finally, the use of the specificity shift is discussed in a conjunction with the exploitation of standard gradient-based techniques.

KW - Approximate solutions

KW - Fuzzy relational equations

KW - Gradient-oriented methods

KW - Hybrid methods

KW - Max-t composition

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Specificity shift in solving fuzzy relational equations

Abstract

Keywords

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