AbstractLA is a simple and natural logical system for reasoning about matrices. We show that LA, over finite fields, proves a host of matrix identities (so-called “hard matrix identities”) from the matrix form of the pigeonhole principle. LAP is LA with matrix powering; we show that LAP extended with quantification over permutations is strong enough to prove fundamental theorems of linear algebra (such as the Cayley–Hamilton Theorem). Furthermore, we show that LA with quantification over permutations expresses NP graph-theoretic properties, and proves the soundness of the Hajós Calculus. Several open problems are stated
AbstractIn Arai (1996), we introduced a new inference rule called permutation to propositional calcu...
We introduce three formal theories of increasing strength for linear algebra in order to study the ...
AbstractWe give a new proof of the NP-completeness of multiplicative linear logic without constants ...
LA is a simple and natural logical system for reasoning about matrices. We show that LA, over finite...
AbstractLA is a simple and natural logical system for reasoning about matrices. We show that LA, ove...
grantor: University of TorontoIn this thesis we are concerned with building logical founda...
AbstractWe introduce three formal theories of increasing strength for linear algebra in order to stu...
Motivated by the fundamental lower bounds questions in proof complexity, we initiate the study of ma...
In this paper, a new propositional proof system H is introduced, that allows quantification over per...
AbstractWe show that the logical theory QLA proves the Cayley–Hamilton theorem from the Steinitz exc...
Abstract. We introduce a new propositional proof system, which we call H, that allows quantification...
We study the problem of polynomial identity testing (PIT) for depth $2$ arithmetic circuits over mat...
AbstractAn elementary combinatorial proof of the Cayley-Hamilton theorem is given. At the conclusion...
Abstract. We investigate the theories LA, LAP, ∀LAP of linear algebra, which were originally defined...
We study arithmetic proof systems Pc(F) and Pf (F) operating with arithmetic circuits and arithmetic...
AbstractIn Arai (1996), we introduced a new inference rule called permutation to propositional calcu...
We introduce three formal theories of increasing strength for linear algebra in order to study the ...
AbstractWe give a new proof of the NP-completeness of multiplicative linear logic without constants ...
LA is a simple and natural logical system for reasoning about matrices. We show that LA, over finite...
AbstractLA is a simple and natural logical system for reasoning about matrices. We show that LA, ove...
grantor: University of TorontoIn this thesis we are concerned with building logical founda...
AbstractWe introduce three formal theories of increasing strength for linear algebra in order to stu...
Motivated by the fundamental lower bounds questions in proof complexity, we initiate the study of ma...
In this paper, a new propositional proof system H is introduced, that allows quantification over per...
AbstractWe show that the logical theory QLA proves the Cayley–Hamilton theorem from the Steinitz exc...
Abstract. We introduce a new propositional proof system, which we call H, that allows quantification...
We study the problem of polynomial identity testing (PIT) for depth $2$ arithmetic circuits over mat...
AbstractAn elementary combinatorial proof of the Cayley-Hamilton theorem is given. At the conclusion...
Abstract. We investigate the theories LA, LAP, ∀LAP of linear algebra, which were originally defined...
We study arithmetic proof systems Pc(F) and Pf (F) operating with arithmetic circuits and arithmetic...
AbstractIn Arai (1996), we introduced a new inference rule called permutation to propositional calcu...
We introduce three formal theories of increasing strength for linear algebra in order to study the ...
AbstractWe give a new proof of the NP-completeness of multiplicative linear logic without constants ...