15 research outputs found
Implicit Resolution
Let \Omega be a set of unsatisfiable clauses, an implicit resolution
refutation of \Omega is a circuit \beta with a resolution proof {\alpha} of the
statement "\beta describes a correct tree-like resolution refutation of
\Omega". We show that such system is p-equivalent to Extended Frege. More
generally, let {\tau} be a tautology, a [P, Q]-proof of {\tau} is a pair
(\alpha,\beta) s.t. \alpha is a P-proof of the statement "\beta is a circuit
describing a correct Q-proof of \tau". We prove that [EF,P] \leq p [R,P] for
arbitrary Cook-Reckhow proof system P
Polylogarithmic Cuts in Models of V^0
We study initial cuts of models of weak two-sorted Bounded Arithmetics with
respect to the strength of their theories and show that these theories are
stronger than the original one. More explicitly we will see that
polylogarithmic cuts of models of are models of
by formalizing a proof of Nepomnjascij's Theorem in such cuts. This is a
strengthening of a result by Paris and Wilkie. We can then exploit our result
in Proof Complexity to observe that Frege proof systems can be sub
exponentially simulated by bounded depth Frege proof systems. This result has
recently been obtained by Filmus, Pitassi and Santhanam in a direct proof. As
an interesting observation we also obtain an average case separation of
Resolution from AC0-Frege by applying a recent result with Tzameret.Comment: 16 page
Resolution Lower Bounds for Refutation Statements
For any unsatisfiable CNF formula we give an exponential lower bound on the
size of resolution refutations of a propositional statement that the formula
has a resolution refutation. We describe three applications. (1) An open
question in (Atserias, M\"uller 2019) asks whether a certain natural
propositional encoding of the above statement is hard for Resolution. We answer
by giving an exponential size lower bound. (2) We show exponential resolution
size lower bounds for reflection principles, thereby improving a result in
(Atserias, Bonet 2004). (3) We provide new examples of CNFs that exponentially
separate Res(2) from Resolution (an exponential separation of these two proof
systems was originally proved in (Segerlind, Buss, Impagliazzo 2004))
Classes of representable disjoint NP-pairs
For a propositional proof system P we introduce the complexity class of all disjoint -pairs for which the disjointness of the pair is efficiently provable in the proof system P. We exhibit structural properties of proof systems which make canonical -pairs associated with these proof systems hard or complete for . Moreover, we demonstrate that non-equivalent proof systems can have equivalent canonical pairs and that depending on the properties of the proof systems different scenarios for and the reductions between the canonical pairs exist
PAC Quasi-automatizability of Resolution over Restricted Distributions
We consider principled alternatives to unsupervised learning in data mining
by situating the learning task in the context of the subsequent analysis task.
Specifically, we consider a query-answering (hypothesis-testing) task: In the
combined task, we decide whether an input query formula is satisfied over a
background distribution by using input examples directly, rather than invoking
a two-stage process in which (i) rules over the distribution are learned by an
unsupervised learning algorithm and (ii) a reasoning algorithm decides whether
or not the query formula follows from the learned rules. In a previous work
(2013), we observed that the learning task could satisfy numerous desirable
criteria in this combined context -- effectively matching what could be
achieved by agnostic learning of CNFs from partial information -- that are not
known to be achievable directly. In this work, we show that likewise, there are
reasoning tasks that are achievable in such a combined context that are not
known to be achievable directly (and indeed, have been seriously conjectured to
be impossible, cf. (Alekhnovich and Razborov, 2008)). Namely, we test for a
resolution proof of the query formula of a given size in quasipolynomial time
(that is, "quasi-automatizing" resolution). The learning setting we consider is
a partial-information, restricted-distribution setting that generalizes
learning parities over the uniform distribution from partial information,
another task that is known not to be achievable directly in various models (cf.
(Ben-David and Dichterman, 1998) and (Michael, 2010))