Classical proof forestry

Annals of Pure and Applied Logic 161 (11):1346-1366 (2010)
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Abstract

Classical proof forests are a proof formalism for first-order classical logic based on Herbrand’s Theorem and backtracking games in the style of Coquand. First described by Miller in a cut-free setting as an economical representation of first-order and higher-order classical proof, defining features of the forests are a strict focus on witnessing terms for quantifiers and the absence of inessential structure, or ‘bureaucracy’.This paper presents classical proof forests as a graphical proof formalism and investigates the possibility of composing forests by cut-elimination. Cut-reduction steps take the form of a local rewrite relation that arises from the structure of the forests in a natural way. Yet reductions, which are significantly different from those of the sequent calculus, are combinatorially intricate and do not exclude the possibility of infinite reduction traces, of which an example is given.Cut-elimination, in the form of a weak normalisation theorem, is obtained using a modified version of the rewrite relation inspired by the game-theoretic interpretation of the forests. It is conjectured that the modified reduction relation is, in fact, strongly normalising

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10.1016/j.apal.2010.04.006

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Citations of this work

Herbrand's theorem as higher order recursion.Bahareh Afshari, Stefan Hetzl & Graham E. Leigh - 2020 - Annals of Pure and Applied Logic 171 (6):102792.
A Simplified Proof of the Epsilon Theorems.Stefan Hetzl - 2024 - Review of Symbolic Logic 17 (4):1248-1263.

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References found in this work

Identity of proofs based on normalization and generality.Kosta Došen - 2003 - Bulletin of Symbolic Logic 9 (4):477-503.
A semantics of evidence for classical arithmetic.Thierry Coquand - 1995 - Journal of Symbolic Logic 60 (1):325-337.
A compact representation of proofs.Dale A. Miller - 1987 - Studia Logica 46 (4):347 - 370.
Locality for Classical Logic.Kai Brünnler - 2006 - Notre Dame Journal of Formal Logic 47 (4):557-580.

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