经典三段论的物质价值及有效三段论规则向不定项结论性三段论规则的推广

IF 0.7 3区 数学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Dan Constantin Radulescu
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引用次数: 0

摘要

通过构造一个6 × 6的矩阵,将6个范畴P-前提a (P,M), O(P,M), a (M,P*), O(M,P*)与6个相似的范畴S-前提(P *∈{P,P '})与6个相似的范畴S-前提配对,从而列出可由正项S,P,M表述的不同的范畴前提对(pps)。一个展示了有效三段论(RofVS)的五个规则如何选择15个不同的pcp,这些pcp包含属于集合L+的逻辑结果(lc): = {A(P,S), O(P,S), A(S,P), E(S,P), O(S,P), I(S,P)}。可容许LCs的选择可以看作是与RofVS中包含的条件(或公理)分离的条件:当唯一可容许LCs属于集合L: = {a (S,P), E(S,P), O(S,P), I(S,P)}且不考虑存在性导入时,通常可以生成有效三段论的八个(布尔)pcp。当pcp和LCs都可以包含不确定项时,得到64 pcp -矩阵——正项S,P,M,以及它们的互补集S ',P ',M ',在论域U中,称为负项。现在我们可以接受8个lc: A(S*,P*), I(S*,P*),其中P*∈{P,P '}, S*∈{S,S '},并且有32个结论性pcp,包含精确的“U的一个划分子集”lc。结论性三段论的四个规则(RofCS)在从精确的lc中剔除中间项后,预测出不太精确的lc。RofCS还预测,64个pcp矩阵中的其他32个pcp是不确定的。对RofVS和RofCS进行了推广,并给出了论证,以接受可通过正项表述的结论性三段论作为有效的三段论,其中包含LCs A(P,S)和O(P,S)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Matricial Vue of Classical Syllogistic and an Extension of the Rules of Valid Syllogism to Rules of Conclusive Syllogisms with Indefinite Terms

One lists the distinct pairs of categorical premises (PCPs) formulable via only the positive terms, S,P,M, by constructing a six by six matrix obtained by pairing the six categorical P-premises, A(P,M), O(P,M), A(M,P*), O(M,P*), where P* ∈ {P,P′}, with the six, similar, categorical S-premises. One shows how five rules of valid syllogism (RofVS), select only 15 distinct PCPs that entail logical consequences (LCs) belonging to the set L+: = {A(P,S), O(P,S), A(S,P), E(S,P), O(S,P), I(S,P)}. The choice of admissible LCs can be regarded as a condition separated from the conditions (or axioms) contained in the RofVS: the usual eight (Boolean) PCPs that generate valid syllogisms are obtained when the only admissible LCs belong to the set L: = {A(S,P), E(S,P), O(S,P), I(S,P)} and no existential imports are addressed. A 64 PCP-matrix obtains when both PCPs and LCs may contain indefinite terms—the positive, S,P,M, terms, and their complementary sets, S′,P′, M′, in the universe of discourse, U, called the negative terms. Now one can accept eight LCs: A(S*,P*), I(S*,P*), where P* ∈ {P,P′}, S* ∈ {S,S′}, and there are 32 conclusive PCPs, entailing precise, “one partitioning subset of U” LCs. The four rules of conclusive syllogisms (RofCS) predict the less precise LCs, left after eliminating the middle term from the exact LCs. The RofCS also predict that the other 32 PCPs of the 64 PCP-matrix are non-conclusive. The RofVS and the RofCS are generalized, and arguments are given, for also accepting as valid syllogisms the conclusive syllogisms formulable via positive terms which entail the LCs A(P,S) and O(P,S).

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来源期刊
Journal of Logic Language and Information
Journal of Logic Language and Information COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCEL-LOGIC
CiteScore
1.70
自引率
12.50%
发文量
40
期刊介绍: The scope of the journal is the logical and computational foundations of natural, formal, and programming languages, as well as the different forms of human and mechanized inference. It covers the logical, linguistic, and information-theoretic parts of the cognitive sciences. Examples of main subareas are Intentional Logics including Dynamic Logic; Nonmonotonic Logic and Belief Revision; Constructive Logics; Complexity Issues in Logic and Linguistics; Theoretical Problems of Logic Programming and Resolution; Categorial Grammar and Type Theory; Generalized Quantification; Information-Oriented Theories of Semantic Structure like Situation Semantics, Discourse Representation Theory, and Dynamic Semantics; Connectionist Models of Logical and Linguistic Structures. The emphasis is on the theoretical aspects of these areas.
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