Fuzzy subset: Difference between revisions
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: is there a precise definition of the notion of ''set of big numbers'' ? | : is there a precise definition of the notion of ''set of big numbers'' ? | ||
=== The notion of | === The notion of fuzzy subset === | ||
An attempt to give an answer to such a question was proposed in 1965 by Lotfi Zadeh and at the same time, by Dieter Klaua in the framework of multi-valued logic. Now recall that the ''[[characteristic function]]'' of a classical subset ''X'' of ''S'' is the map ''c''<sub>X</sub> : → {0,1} such that ''c<sub>X</sub>''(''x'') = 1 if ''x'' is an element in ''X'' and ''c<sub>X</sub>''(''x'') = 0 otherwise. Obviously, it is possible to identify every subset ''X'' with its characteristic function ''c<sub>X</sub>'' and therefore the extension of a property with a suitable characteristic function. This suggests that we can define the subset of big elements by a generalized characteristic function in which instead of the Boolean algebra {0,1} we can consider, for example, the interval [0,1]. The following is a precise definition. | An attempt to give an answer to such a question was proposed in 1965 by Lotfi Zadeh and at the same time, by Dieter Klaua in the framework of multi-valued logic. Now recall that the ''[[characteristic function]]'' of a classical subset ''X'' of ''S'' is the map ''c''<sub>X</sub> : → {0,1} such that ''c<sub>X</sub>''(''x'') = 1 if ''x'' is an element in ''X'' and ''c<sub>X</sub>''(''x'') = 0 otherwise. Obviously, it is possible to identify every subset ''X'' with its characteristic function ''c<sub>X</sub>'' and therefore the extension of a property with a suitable characteristic function. This suggests that we can define the subset of big elements by a generalized characteristic function in which instead of the Boolean algebra {0,1} we can consider, for example, the interval [0,1]. The following is a precise definition. | ||
Revision as of 04:49, 4 January 2009
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Introduction
The term fuzzy subset is a generalization of the subset concept from set theory. Observe that we can obtain a subset of a given set S by considering the extension of a well defined property P in S. Indeed, the axiom of comprehension reads that a subset B of S exists whose members are precisely those objects in S satisfying P. For example if S is the set of natural numbers and P is the property "to be prime", then the subset B of prime numbers is defined. Assume that P is a vague property as "to be big", "to be young": is there a way to define the extension of P ? For example:
- is there a precise definition of the notion of set of big numbers ?
The notion of fuzzy subset
An attempt to give an answer to such a question was proposed in 1965 by Lotfi Zadeh and at the same time, by Dieter Klaua in the framework of multi-valued logic. Now recall that the characteristic function of a classical subset X of S is the map cX : → {0,1} such that cX(x) = 1 if x is an element in X and cX(x) = 0 otherwise. Obviously, it is possible to identify every subset X with its characteristic function cX and therefore the extension of a property with a suitable characteristic function. This suggests that we can define the subset of big elements by a generalized characteristic function in which instead of the Boolean algebra {0,1} we can consider, for example, the interval [0,1]. The following is a precise definition.
Definition. Let S be a nonempty set, then an L-subset or fuzzy subset of S is a map s from S into [0,1]. We denote by [0,1]S the class of all the fuzzy subsets of S. If S1,...Sn are nonempty sets then a fuzzy subset of S1×. . .×Sn is called an n-ary L-relation.
The elements in [0,1] are interpreted as truth values and, in accordance, for every x in S, the number s(x) is interpreted as the membership degree of x to s. We say that a fuzzy subset s is crisp if s(x) is in {0,1} for every x in S. By associating every classical subsets of S with its characteristic function, we can identify the subsets of S with the crisp fuzzy subsets. In particular we call "empty subset" of S the fuzzy subset of S constantly equal to 0. Notice that in such a way there is not a unique empty subsets.
Some set-theoretical notions for fuzzy subsets
In classical mathematics the definitions of union, intersection and complement are related with the interpretation of the basic logical connectives . In order to define the same operations for fuzzy subsets, we have to fix suitable operations and ~ in [0,1] to interpret these connectives. Once this was done, we can set
- ,
- ,
- .
In such a way an algebraic structure is defined and this structure is the direct power of the structure ~,0 ,1) with index set S. In Zadeh's original papers the operations , ~ are defined by setting for every x and y in [0,1]:
- = min(x, y) ; = max(x,y) ; = 1-x.
In such a case is a complete, completely distributive lattice with an involution. Several authors prefer to consider different operations, as an example to assume that is a triangular norm in [0,1] and that is the corresponding triangular co-norm.
In all the cases the interpretation of a logical connective is conservative in the sense that its restriction to {0,1} coincides with the classical one. This entails that the map associating any subset X of a set S with the related characteristic function is an embedding of the Boolean algebra into the algebra .
Valuation structures
In the framework of fuzzy logic usually one admits sets of truth values different from [0,1]. Usually one considers bounded lattices equipped with suitable operations to interpret the logical connectives.