Transposition of variables is hard to describe

Abstract

The function pxy that interchanges two logical variables x,y in formulas is hard to describe in the following sense. Let F denote the Lindenbaum-Tarski formula-algebra of a finite-variable first order logic, endowed with pxy as a unary function. Each equational axiom system for the equational theory of F has to contain, for each finite n, an equation that contains together with pxy at least n algebraic variables, and each of the operations ∃, =, . This solves a problem raised by Johnson [J. Symb. Logic] more than 50 years ago: the class of representable polyadic equality algebras of a finite dimension α 3 cannot be axiomatized by adding finitely many equations to the equational theory of representable cylindric algebras of dimension α. Consequences for proof systems of finite-variable logic and for defining equations of polyadic equality algebras are given. The proof uses a family of nonrepresentable polyadic equality algebras An that are more and more nearly representable as n increases: their n-generated subalgebras as well as their proper reducts are representable. The lattice of subvarieties of RPEAα is investigated and new open problems are asked about the interplay between the transposition operations and about generalizability of the results to infinite dimensions.