Your search keyword '"Mikša, Mladen"' showing total 15 results

1. A Generalized Method for Proving Polynomial Calculus Degree Lower Bounds

Author

Mikša, Mladen and Nordström, Jakob

Subjects

Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Computer Science - Logic in Computer Science, Mathematics - Combinatorics, F.2.2, F.1.3, I.2.3, F.4.1

Abstract

We study the problem of obtaining lower bounds for polynomial calculus (PC) and polynomial calculus resolution (PCR) on proof degree, and hence by [Impagliazzo et al. '99] also on proof size. [Alekhnovich and Razborov '03] established that if the clause-variable incidence graph of a CNF formula F is a good enough expander, then proving that F is unsatisfiable requires high PC/PCR degree. We further develop the techniques in [AR03] to show that if one can "cluster" clauses and variables in a way that "respects the structure" of the formula in a certain sense, then it is sufficient that the incidence graph of this clustered version is an expander. As a corollary of this, we prove that the functional pigeonhole principle (FPHP) formulas require high PC/PCR degree when restricted to constant-degree expander graphs. This answers an open question in [Razborov '02], and also implies that the standard CNF encoding of the FPHP formulas require exponential proof size in polynomial calculus resolution. Thus, while Onto-FPHP formulas are easy for polynomial calculus, as shown in [Riis '93], both FPHP and Onto-PHP formulas are hard even when restricted to bounded-degree expanders., Comment: Full-length version of paper to appear in Proceedings of the 30th Annual Computational Complexity Conference (CCC '15), June 2015

Published

2015

2. From Small Space to Small Width in Resolution

Author

Filmus, Yuval, Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, and Vinyals, Marc

Subjects

Computer Science - Computational Complexity, Computer Science - Discrete Mathematics, Computer Science - Logic in Computer Science, F.1.3, F.4.1, F.2.2

Abstract

In 2003, Atserias and Dalmau resolved a major open question about the resolution proof system by establishing that the space complexity of CNF formulas is always an upper bound on the width needed to refute them. Their proof is beautiful but somewhat mysterious in that it relies heavily on tools from finite model theory. We give an alternative, completely elementary proof that works by simple syntactic manipulations of resolution refutations. As a by-product, we develop a "black-box" technique for proving space lower bounds via a "static" complexity measure that works against any resolution refutation---previous techniques have been inherently adaptive. We conclude by showing that the related question for polynomial calculus (i.e., whether space is an upper bound on degree) seems unlikely to be resolvable by similar methods.

Published

2014

3. Long Proofs of (Seemingly) Simple Formulas

Author

Mikša, Mladen, Nordström, Jakob, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Kobsa, Alfred, editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Weikum, Gerhard, editor, Sinz, Carsten, editor, and Egly, Uwe, editor

Published

2014

4. Towards an Understanding of Polynomial Calculus: New Separations and Lower Bounds : (Extended Abstract)

Author

Filmus, Yuval, Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, Vinyals, Marc, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Fomin, Fedor V., editor, Freivalds, Rūsiņš, editor, Kwiatkowska, Marta, editor, and Peleg, David, editor

Published

2013

5. Towards an Understanding of Polynomial Calculus: New Separations and Lower Bounds

Author

Filmus, Yuval, primary, Lauria, Massimo, additional, Mikša, Mladen, additional, Nordström, Jakob, additional, and Vinyals, Marc, additional

Published

2013

6. On Complexity Measures in Polynomial Calculus

Author

Mikša, Mladen

Subjects

TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGES, Datavetenskap (datalogi), Computer Sciences

Abstract

Proof complexity is the study of different resources that a proof needs in different proof systems for propositional logic. This line of inquiry relates to the fundamental questions in theoretical computer science, as lower bounds on proof size for an arbitrary proof system would separate P from NP. We study two simple proof systems: resolution and polynomial calculus. In resolution we reason using clauses, while in polynomial calculus we use polynomials. We study three measures of complexity of proofs: size, space, and width/degree. Size is the number of clauses or monomials that appear in a resolution or polynomial calculus proof, respectively. Space is the maximum number of clauses/monomials we need to keep at each time step of the proof. Width/degree is the size of the largest clause/monomial in a proof. Width is a lower bound for space in resolution. The original proof of this claim used finite model theory. In this thesis we give a different, more direct proof of the space-width relation. We can ask whether a similar relation holds between space and degree in polynomial calculus. We make some progress on this front by showing that when a formula F requires resolution width w then the XORified version of F requires polynomial calculus space Ω(w). We also show that space lower bounds do not imply degree lower bounds in polynomial calculus. Width/degree and size are also related, as strong lower bounds for width/degree imply strong lower bounds for size. Currently, proving width lower bounds has a well-developed machinery behind it. However, the degree measure is much less well-understood. We provide a unified framework for almost all previous degree lower bounds. We also prove some new degree and size lower bounds. In addition, we explore the relation between theory and practice by running experiments on some current state-of-the-art SAT solvers. QC 20161206 Understanding the Hardness of Theorem Proving

Published

2016

7. From small space to small width in resolution

Author

Filmus, Y., Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, Vinyals, M., Filmus, Y., Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, and Vinyals, M.

Abstract

In 2003, Atserias and Dalmau resolved a major open question about the resolution proof system by establishing that the space complexity of a Conjunctive Normal Form (CNF) formula is always an upper bound on the width needed to refute the formula. Their proof is beautiful but uses a nonconstructive argument based on Ehrenfeucht-Fraïssé games. We give an alternative, more explicit, proof that works by simple syntactic manipulations of resolution refutations. As a by-product, we develop a "black-box" technique for proving space lower bounds via a "static" complexitymeasure that works against any resolution refutation-previous techniques have been inherently adaptive. We conclude by showing that the related question for polynomial calculus (i.e., whether space is an upper bound on degree) seems unlikely to be resolvable by similarmethods., QC 20151111

Published

2015

8. From small space to small width in resolution

Author

Filmus, Yuval, Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, Vinyals, Marc, Filmus, Yuval, Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, and Vinyals, Marc

Abstract

In 2003, Atserias and Dalmau resolved a major open question about the resolution proof system by establishing that the space complexity of a Conjunctive Normal Form (CNF) formula is always an upper bound on the width needed to refute the formula. Their proof is beautiful but uses a nonconstructive argument based on Ehrenfeucht-Fraïssé games. We give an alternative, more explicit, proof that works by simple syntactic manipulations of resolution refutations. As a by-product, we develop a "black-box" technique for proving space lower bounds via a "static" complexitymeasure that works against any resolution refutation-previous techniques have been inherently adaptive. We conclude by showing that the related question for polynomial calculus (i.e., whether space is an upper bound on degree) seems unlikely to be resolvable by similarmethods.

Published

2015

9. A generalized method for proving polynomial calculus degree lower bounds

Author

Zuckerman, David, Mikša, Mladen, Nordström, Jakob, Zuckerman, David, Mikša, Mladen, and Nordström, Jakob

Abstract

We study the problem of obtaining lower bounds for polynomial calculus (PC) and polynomial calculus resolution (PCR) on proof degree, and hence by [Impagliazzo et al. '99] also on proof size. [Alekhnovich and Razborov'03] established that if the clause-variable incidence graph of a CNF formula F is a good enough expander, then proving that F is unsatisfiable requires high PC/PCR degree. We further develop the techniques in [AR03] to show that if one can "cluster" clauses and variables in a way that "respects the structure" of the formula in a certain sense, then it is sufficient that the incidence graph of this clustered version is an expander. As a corollary of this, we prove that the functional pigeonhole principle (FPHP) formulas require high PC/PCR degree when restricted to constant-degree expander graphs. This answers an open question in [Razborov'02], and also implies that the standard CNF encoding of the FPHP formulas require exponential proof size in polynomial calculus resolution. Thus, while Onto-FPHP formulas are easy for polynomial calculus, as shown in [Riis'93], both FPHP and Onto-PHP formulas are hard even when restricted to bounded-degree expanders.

Published

2015

10. From Small Space to Small Width in Resolution

Author

Filmus, Yuval, primary, Lauria, Massimo, additional, Mikša, Mladen, additional, Nordström, Jakob, additional, and Vinyals, Marc, additional

Published

2015

11. Croatian OCR Error Correction Using Character Confusions and Language Modelling

Author

Marović, Mladen, Mikša, Mladen, Šnajder, Jan, Dalbelo Bašić, Bojana, Auer, Boris, Bača, Miroslav, and Schatten, Markus

Subjects

Natural language processing, OCR, character confusions, character n-grams, word merge errors, language model, Croatian language, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING

Abstract

Manual correction of errors produced by optical character recognition (OCR) is a time-consuming task. This paper presents an automatic post- processing system that utilizes various methods for improving the OCR results of Croatian language texts. The system relies on knowledge of general characteristics of OCR errors, as well as language-specific knowledge. Used methods include character confusions, a character n-gram model, and word-splitting. A statistical language model is used for ranking the generated candidates depending on the sentential context. Experimental evaluation, performed on newspaper texts supplied by the Croatian News Agency, shows an error rate reduction of above 20%. These results amount to about 36% of the performance of manual correction.

Published

2010

12. Correcting Word Merge Errors in Croatian Texts

Author

Mikša, Mladen, Šnajder, Jan, Dalbelo Bašić, Bojana, Tadić, Marko, Dimitrova-Vulchanova, Mila, and Koeva, Svetla

Subjects

word merge errors, OCR errors, combinatorial optimization, language modeling, natural language processing, Croatian language

Abstract

In many text processing tasks character-level errors (due to mistyping, OCR, etc.) typically lead to performance degradation. Most approaches to error correction are dictionary based and cannot be used to correct word boundary errors. Word boundary errors are quite common in OCR- generated texts, especially the word merge errors. In this paper we describe an approach to correcting word merge errors in texts written in Croatian language. The approach is based on combinatorial optimization with beam search strategy that determines the most plausible segmentation of the input token. The plausibility of the segmentation is assessed using a statistical language model and several heuristics. We evaluate the performance of our approach on a sample of artificially generated word merge errors. The achieved results are comparable to the results of the approaches found in the literature.

Published

2010

13. Ispravljanje pogrešaka stapanja riječi u tekstovima dobivenim postupkom optičkog raspoznavanja znakova

Author

Mikša, Mladen

Subjects

obrada prirodnog jezika, OCR, stapanje riječi, trie, jezični model, hrvatski jezik

Abstract

Problem ispravljanja pogrešaka OCR-a važan je i težak problem, a kao bitna komponenta problem ističe se pogreška stapanja riječi. Ovim radom predstavljen je automatski postupak rastavljanja riječi u tekstovima dobivenim OCR-om orijentiran na hrvatski jezik. Postupak se temelji na kombinatornom pretraživanju rastavljanja riječi uz korištenje jezičnog modela za pružanje kontekstne informacije. Provedena je eksperimentalna evaluacija postupka rastavljanja kojom je demonstrirana preciznost od 97.28% i odziv od 96.60% za 90.40% točan tekst. Evaluacija sustava pokazala je poboljšanje točnosti teksta od 0.81%, odnosno ostvarenje 30% stope smanjenja pogreške. Tim rezultatom ostvareno je oko 48% uspješnosti ručnog ispravljanja.

Published

2010

14. From small space to small width in resolution

Author

Filmus, Y., Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, Vinyals, Marc, Filmus, Y., Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, and Vinyals, Marc

Abstract

In 2003, Atserias and Dalmau resolved a major open question about the resolution proof system by establishing that the space complexity of formulas is always an upper bound on the width needed to refute them. Their proof is beautiful but somewhat mysterious in that it relies heavily on tools from finite model theory. We give an alternative, completely elementary, proof that works by simple syntactic manipulations of resolution refutations. As a by-product, we develop a "black-box" technique for proving space lower bounds via a "static" complexity measure that works against any resolution refutation-previous techniques have been inherently adaptive. We conclude by showing that the related question for polynomial calculus (i.e., whether space is an upper bound on degree) seems unlikely to be resolvable by similar methods., QC 20141222

Published

2014

15. From small space to small width in resolution

Author

Portier, Natacha, Mayr, Ernst W., Filmus, Yuval, Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, Vinyals, Marc, Portier, Natacha, Mayr, Ernst W., Filmus, Yuval, Lauria, Massimo, Mikša, Mladen, Nordström, Jakob, and Vinyals, Marc

Abstract

In 2003, Atserias and Dalmau resolved a major open question about the resolution proof system by establishing that the space complexity of formulas is always an upper bound on the width needed to refute them. Their proof is beautiful but somewhat mysterious in that it relies heavily on tools from finite model theory. We give an alternative, completely elementary, proof that works by simple syntactic manipulations of resolution refutations. As a by-product, we develop a "black-box" technique for proving space lower bounds via a "static" complexity measure that works against any resolution refutation-previous techniques have been inherently adaptive. We conclude by showing that the related question for polynomial calculus (i.e., whether space is an upper bound on degree) seems unlikely to be resolvable by similar methods.

Published

2014