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Cylindric algebras with terms

Published online by Cambridge University Press:  12 March 2014

Norman Feldman
Norman Feldman*
Affiliation:
Department of Mathematics, Sonoma State University, Rohnert Park, California 94928
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In this paper we discuss cylindric algebras with terms. The setting is two—sorted algebras—one sort for terms and one for Boolean elements. As with cylindric algebras, a cylindric algebra with terms has its roots in first order predicate logic [HMT1].

Let Σ be a set of sentences in a first order language with terms, equality and variables u0,u1,u2, …, Define a relation ≡Σ on Fm, the set of formulas, by φΣθ if and only if Σφθ, and on Tm, the set of terms, by τΣσ if and only if Στ ≈ σ. The operations +, ·, cκ, 0, 1 are defined as usual on equivalence classes. Define , where is σ with τ substituted for all occurrences of uκ. That the operation *κ, for κ < α, is well defined follows from the first order axioms of equality. Let vκ = [uκ]. To establish the link between terms and Booleans, define operations oκ as follows: , where φ' is a variant of φ such that uκ is free for τ in φ′ and is φ′ with τ substituted for all free occurrences of uκ in φ′. From the first order axioms it follows that oκ, for κ < α, is well defined. Finally, instead of diagonal elements, we define a Boolean-valued operation on terms as follows: [τ] e [σ] = [τ ≈ σ].

Type
Research Article
Information
The Journal of Symbolic Logic , Volume 55 , Issue 2 , June 1990 , pp. 854 - 866
Copyright
Copyright © Association for Symbolic Logic 1990

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References

REFERENCES

[AS]Andréka, H. and Sain, I., Connections between algebraic logic and initial algebra semantics of CF languages, Mathematical logic in computer science (Dömölki, B. and Gergely, T., editors), Colloquia Societatis Mathematica János Bolyai, vol. 26, North-Holland, Amsterdam, 1981, pp. 2583.Google Scholar
[C1]Cirulis, J., An algebraization of first order logic with terms, Algebraic logic (Proceedings, Budapest, 1988), Colloquia Mathematica Societatis János Bolyai, North-Holland, Amsterdam (to appear).Google Scholar
[C2]Cirulis, J., Two generalizations of the notion of a polyadic algebra, Izvestiya Vysshikh Vchebnykh Zavedeniĭ Matematika 1988, no. 12, pp. 3949; English translation, Soviet Mathematics (Izv. VUZ Mat.), vol. 32 (1988), no. 12, pp. 61–78.Google Scholar
[F1]Feldman, N., Axiomatization of polynomial substitution algebras, this Journal, vol. 47 (1982), pp. 481492.Google Scholar
[F2]Feldman, N., Representation of substitution algebras, this Journal, vol. 49 (1984), pp. 677678.Google Scholar
[HMT1]Henkin, L., Monk, D., and Tarski, A., Cylindric algebras. Part I, North-Holland, Amsterdam, 1971.Google Scholar
[HMT2]Henkin, L., Cylindric algebras. Part II, North-Holland, Amsterdam, 1985.Google Scholar
[HMTAN]Henkin, L., Monk, D., Tarski, A., Andréka, H., and Németi, I., Cylindric set algebras and related structures, Lecture Notes in Mathematics, vol. 883, Springer-Verlag, Berlin, 1981.CrossRefGoogle Scholar