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ORCIDTomás Peitl
Person information
- unicode name: Tomáš Peitl
- affiliation: Friedrich Schiller University of Jena, Institute of Computer Science, Germany
- affiliation (former): TU Vienna, Institute of Logic and Computation, Austria
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2020 – today
- 2025
[c19]Mikolás Janota, Markus Kirchweger, Tomás Peitl, Stefan Szeider:
Breaking Symmetries in Quantified Graph Search: A Comparative Study. AAAI 2025: 11246-11254- [c18]Leroy Chew
, Tomás Peitl:
Better Extension Variables in DQBF via Independence. SAT 2025: 11:1-11:24 - [d2]Tomás Peitl, Stefan Szeider, Markus Kirchweger, Hai Xia:
Supplementary material for Smart Cubing for Graph Search: A Comparative Study. Zenodo, 2025
- [i13]Markus Kirchweger, Hai Xia, Tomás Peitl, Stefan Szeider:
Smart Cubing for Graph Search: A Comparative Study. CoRR abs/2501.17201 (2025) - [i12]Mikolás Janota, Markus Kirchweger, Tomás Peitl, Stefan Szeider:
Breaking Symmetries in Quantified Graph Search: A Comparative Study. CoRR abs/2502.15078 (2025) - [i11]Leroy Chew, Tomás Peitl:
Better Extension Variables in DQBF via Independence. CoRR abs/2505.20069 (2025) - [i10]Markus Kirchweger, Tomás Peitl, Bernardo Subercaseaux, Stefan Szeider:
From the Finite to the Infinite: Sharper Asymptotic Bounds on Norin's Conjecture via SAT. CoRR abs/2511.08386 (2025) - [i9]Leroy Chew, Tomás Peitl:
Strong (D)QBF Dependency Schemes via Pure Universal Resolution Paths. Electron. Colloquium Comput. Complex. TR25 (2025) - 2024
- [j10]Benjamin Böhm, Tomás Peitl, Olaf Beyersdorff:
QCDCL with cube learning or pure literal elimination - What is best? Artif. Intell. 336: 104194 (2024) - [j9]Benjamin Böhm, Tomás Peitl, Olaf Beyersdorff:
Should Decisions in QCDCL Follow Prefix Order? J. Autom. Reason. 68(1): 5 (2024) - [j8]Olaf Beyersdorff, Joshua Blinkhorn, Meena Mahajan, Tomás Peitl, Gaurav Sood:
Hard QBFs for Merge Resolution. ACM Trans. Comput. Theory 16(2): 6:1-6:24 (2024) - [j7]Olaf Beyersdorff, Joshua Lewis Blinkhorn, Tomás Peitl:
Strong (D)QBF Dependency Schemes via Implication-free Resolution Paths. ACM Trans. Comput. Theory 16(4): 22:1-22:25 (2024) - [c17]Tianwei Zhang, Tomás Peitl, Stefan Szeider:
Small Unsatisfiable k-CNFs with Bounded Literal Occurrence. SAT 2024: 31:1-31:22 - [d1]Tomás Peitl, Markus Kirchweger, Mikolás Janota, Stefan Szeider:
Supplementary Material for Breaking Symmetries in Quantified Graph Search: A Comparative Study. Zenodo, 2024 - [i8]Tianwei Zhang, Tomás Peitl, Stefan Szeider:
Small unsatisfiable k-CNFs with bounded literal occurrence. CoRR abs/2405.16149 (2024) - 2023
- [j6]Tomás Peitl, Stefan Szeider:
Are hitting formulas hard for resolution? Discret. Appl. Math. 337: 173-184 (2023) - [j5]Olaf Beyersdorff, Joshua Blinkhorn, Meena Mahajan, Tomás Peitl:
Hardness Characterisations and Size-width Lower Bounds for QBF Resolution. ACM Trans. Comput. Log. 24(2): 10:1-10:30 (2023) - [c16]Markus Kirchweger, Tomás Peitl, Stefan Szeider:
Co-Certificate Learning with SAT Modulo Symmetries. IJCAI 2023: 1944-1953 - [c15]Markus Kirchweger, Tomás Peitl, Stefan Szeider:
A SAT Solver's Opinion on the Erdős-Faber-Lovász Conjecture. SAT 2023: 13:1-13:17 - [i7]Markus Kirchweger, Tomás Peitl, Stefan Szeider:
Co-Certificate Learning with SAT Modulo Symmetries. CoRR abs/2306.10427 (2023) - 2022
- [c14]Benjamin Böhm, Tomás Peitl, Olaf Beyersdorff:
QCDCL with Cube Learning or Pure Literal Elimination - What is Best? IJCAI 2022: 1781-1787 - [c13]Benjamin Böhm, Tomás Peitl, Olaf Beyersdorff:
Should Decisions in QCDCL Follow Prefix Order? SAT 2022: 11:1-11:19 - [i6]Tomás Peitl, Stefan Szeider:
Are Hitting Formulas Hard for Resolution? CoRR abs/2206.15225 (2022) - [i5]Benjamin Böhm, Tomás Peitl, Olaf Beyersdorff:
Should decisions in QCDCL follow prefix order? Electron. Colloquium Comput. Complex. TR22 (2022) - 2021
- [j4]Tomás Peitl, Stefan Szeider:
Finding the Hardest Formulas for Resolution. J. Artif. Intell. Res. 72: 69-97 (2021) - [c12]Tomás Peitl, Stefan Szeider:
Finding the Hardest Formulas for Resolution (Extended Abstract). IJCAI 2021: 4814-4818 - [c11]Joshua Blinkhorn, Tomás Peitl, Friedrich Slivovsky:
Davis and Putnam Meet Henkin: Solving DQBF with Resolution. SAT 2021: 30-46 - [i4]Olaf Beyersdorff, Joshua Blinkhorn, Tomás Peitl:
Strong (D)QBF Dependency Schemes via Implication-free Resolution Paths. Electron. Colloquium Comput. Complex. TR21 (2021) - 2020
- [c10]Tomás Peitl, Stefan Szeider:
Finding the Hardest Formulas for Resolution. CP 2020: 514-530 - [c9]Olaf Beyersdorff, Joshua Blinkhorn, Meena Mahajan, Tomás Peitl, Gaurav Sood:
Hard QBFs for Merge Resolution. FSTTCS 2020: 12:1-12:15 - [c8]Robert Ganian, Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Fixed-Parameter Tractability of Dependency QBF with Structural Parameters. KR 2020: 392-402 - [c7]Olaf Beyersdorff, Joshua Blinkhorn, Tomás Peitl:
Strong (D)QBF Dependency Schemes via Tautology-Free Resolution Paths. SAT 2020: 394-411 - [i3]Olaf Beyersdorff, Joshua Blinkhorn, Meena Mahajan, Tomás Peitl, Gaurav Sood:
Hard QBFs for Merge Resolution. CoRR abs/2012.06779 (2020) - [i2]Olaf Beyersdorff, Joshua Blinkhorn, Meena Mahajan, Tomás Peitl, Gaurav Sood:
Hard QBFs for Merge Resolution. Electron. Colloquium Comput. Complex. TR20 (2020) - [i1]Olaf Beyersdorff, Joshua Blinkhorn, Tomás Peitl:
Strong (D)QBF Dependency Schemes via Tautology-free Resolution Paths. Electron. Colloquium Comput. Complex. TR20 (2020)
2010 – 2019
- 2019
- [j3]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Dependency Learning for QBF. J. Artif. Intell. Res. 65: 180-208 (2019) - [j2]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Long-Distance Q-Resolution with Dependency Schemes. J. Autom. Reason. 63(1): 127-155 (2019) - [j1]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Qute in the QBF Evaluation 2018. J. Satisf. Boolean Model. Comput. 11(1): 261-272 (2019) - [c6]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Combining Resolution-Path Dependencies with Dependency Learning. SAT 2019: 306-318 - [c5]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Proof Complexity of Fragments of Long-Distance Q-Resolution. SAT 2019: 319-335 - 2018
- [c4]Holger H. Hoos, Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Portfolio-Based Algorithm Selection for Circuit QBFs. CP 2018: 195-209 - [c3]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Polynomial-Time Validation of QCDCL Certificates. SAT 2018: 253-269 - 2017
- [c2]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Dependency Learning for QBF. SAT 2017: 298-313 - 2016
- [c1]Tomás Peitl, Friedrich Slivovsky, Stefan Szeider:
Long Distance Q-Resolution with Dependency Schemes. SAT 2016: 500-518
Coauthor Index
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