An infinite sequence $\bgD=\ $ of possibly infinite sets of formulas in $n+1$ variables $\seq x0{n-1},y$ and a possibly infinite system of parameters $\vu$ is a \emph{parameterized graded deduction-detachment} \emph{system} for a deductive system $\bcS$ over a $\bcS$-theory $T$ if, for every $n $, where $\Fi_\bcS\sbA$ is the set of all $\bcS$-filters on $\sbA$.Theorem.Let $\bcS$ be a protoalgebraic deductive system over a countable language type. If $\bcS$ has a Leibniz-generating PGDD system ov…
Read moreAn infinite sequence $\bgD=\ $ of possibly infinite sets of formulas in $n+1$ variables $\seq x0{n-1},y$ and a possibly infinite system of parameters $\vu$ is a \emph{parameterized graded deduction-detachment} \emph{system} for a deductive system $\bcS$ over a $\bcS$-theory $T$ if, for every $n $, where $\Fi_\bcS\sbA$ is the set of all $\bcS$-filters on $\sbA$.Theorem.Let $\bcS$ be a protoalgebraic deductive system over a countable language type. If $\bcS$ has a Leibniz-generating PGDD system over all Leibniz theories, then $\bcS$ has a fully adequate Gentzen system.Theorem.Let $\bcS$ be a protoalgebraic deductive system. If $\bcS$ has a fully adequate Gentzen system, then $\bcS$ has a Leibniz-generating PGDD system over every Leibniz theory.Corollary.If $\bcS$ is a weakly algebraizable deductive system over a countable language type, then $\bcS$ has a fully adequate Gentzen system iff it has the multiterm deduction-detachment theorem.Corollary.If $\bcS$ is a finitely equivalential deductive system over a countable language type, then $\bcS$ has a fully adequate Gentzen system iff there is a finite Leibniz-generating \textup{GDD} system for $\bcS$ over all Leibniz $\bcS$-filters.