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ORCIDHendrik Molter
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- affiliation: Ben-Gurion University of The Negev, Israel
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2020 – today
- 2024
[j28]Danny Hermelin
, Hendrik Molter, Dvir Shabtay:
Minimizing the Weighted Number of Tardy Jobs via (max,+)-Convolutions. INFORMS J. Comput. 36(3): 836-848 (2024)- [j27]Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Dvir Shabtay:
On the parameterized complexity of interval scheduling with eligible machine sets. J. Comput. Syst. Sci. 144: 103533 (2024) - [j26]Hendrik Molter, Malte Renken, Philipp Zschoche:
Temporal reachability minimization: Delaying vs. deleting. J. Comput. Syst. Sci. 144: 103549 (2024) - [j25]Nina Klobas, George B. Mertzios, Hendrik Molter, Paul G. Spirakis:
The complexity of computing optimum labelings for temporal connectivity. J. Comput. Syst. Sci. 146: 103564 (2024) - [j24]Sebastian Buß, Hendrik Molter, Rolf Niedermeier, Maciej Rymar:
Algorithmic aspects of temporal betweenness. Netw. Sci. 12(2): 160-188 (2024) - [c39]Juhi Chaudhary, Hendrik Molter, Meirav Zehavi:
How to Make Knockout Tournaments More Popular? AAAI 2024: 9582-9589 - [c38]Juhi Chaudhary, Hendrik Molter, Meirav Zehavi:
Parameterized Analysis of Bribery in Challenge the Champ Tournaments. IJCAI 2024: 2704-2712 - [c37]Nina Klobas, George B. Mertzios, Hendrik Molter, Paul G. Spirakis:
Temporal Graph Realization from Fastest Paths. SAND 2024: 16:1-16:18 - [i44]Juhi Chaudhary, Hendrik Molter, Meirav Zehavi:
Parameterized Analysis of Bribery in Challenge the Champ Tournaments. CoRR abs/2403.17587 (2024) - [i43]George B. Mertzios, Hendrik Molter, Paul G. Spirakis:
Realizing temporal transportation trees. CoRR abs/2403.18513 (2024) - [i42]Klaus Heeger, Hendrik Molter:
Minimizing the Number of Tardy Jobs with Uniform Processing Times on Parallel Machines. CoRR abs/2404.14208 (2024) - [i41]Klaus Heeger, Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Dvir Shabtay:
Fair Repetitive Interval Scheduling. CoRR abs/2407.03987 (2024) - [i40]Matthias Kaul, Matthias Mnich, Hendrik Molter:
Single-Machine Scheduling to Minimize the Number of Tardy Jobs with Release Dates. CoRR abs/2408.12967 (2024) - 2023
- [j23]Nina Klobas, George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Philipp Zschoche:
Interference-free walks in time: temporally disjoint paths. Auton. Agents Multi Agent Syst. 37(1): 1 (2023) - [j22]Nicolas Maack, Hendrik Molter, Rolf Niedermeier, Malte Renken:
On finding separators in temporal split and permutation graphs. J. Comput. Syst. Sci. 135: 1-14 (2023) - [j21]George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Viktor Zamaraev, Philipp Zschoche:
Computing maximum matchings in temporal graphs. J. Comput. Syst. Sci. 137: 1-19 (2023) - [j20]Maciej Rymar, Hendrik Molter, André Nichterlein, Rolf Niedermeier:
Towards Classifying the Polynomial-Time Solvability of Temporal Betweenness Centrality. J. Graph Algorithms Appl. 27(3): 173-194 (2023) - [j19]Klaus Heeger, Danny Hermelin, George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Dvir Shabtay:
Equitable scheduling on a single machine. J. Sched. 26(2): 209-225 (2023) - [j18]Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Rolf Niedermeier:
Temporal interval cliques and independent sets. Theor. Comput. Sci. 961: 113885 (2023) - [c36]Pascal Kunz, Hendrik Molter, Meirav Zehavi:
In Which Graph Structures Can We Efficiently Find Temporally Disjoint Paths and Walks? IJCAI 2023: 180-188 - [c35]Jessica A. Enright, Kitty Meeks, Hendrik Molter:
Counting Temporal Paths. STACS 2023: 30:1-30:19 - [i39]Pascal Kunz, Hendrik Molter, Meirav Zehavi:
In Which Graph Structures Can We Efficiently Find Temporally Disjoint Paths and Walks? CoRR abs/2301.10503 (2023) - [i38]Nina Klobas, George B. Mertzios, Hendrik Molter, Paul G. Spirakis:
Realizing temporal graphs from fastest travel times. CoRR abs/2302.08860 (2023) - [i37]Juhi Chaudhary, Hendrik Molter, Meirav Zehavi:
How to Make Knockout Tournaments More Popular? CoRR abs/2309.09967 (2023) - 2022
- [j17]Roman Haag, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Feedback edge sets in temporal graphs. Discret. Appl. Math. 307: 65-78 (2022) - [j16]Hendrik Molter:
The complexity of finding temporal separators under waiting time constraints. Inf. Process. Lett. 175: 106229 (2022) - [c34]Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Dvir Shabtay:
Hardness of Interval Scheduling on Unrelated Machines. IPEC 2022: 18:1-18:16 - [c33]Nina Klobas, George B. Mertzios, Hendrik Molter, Paul G. Spirakis:
The Complexity of Computing Optimum Labelings for Temporal Connectivity. MFCS 2022: 62:1-62:15 - [c32]Eugen Füchsle, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Temporal Connectivity: Coping with Foreseen and Unforeseen Delays. SAND 2022: 17:1-17:17 - [c31]Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Rolf Niedermeier:
Temporal Unit Interval Independent Sets. SAND 2022: 19:1-19:16 - [c30]Eugen Füchsle, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Delay-Robust Routes in Temporal Graphs. STACS 2022: 30:1-30:15 - [i36]Eugen Füchsle, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Temporal Connectivity: Coping with Foreseen and Unforeseen Delays. CoRR abs/2201.05011 (2022) - [i35]Eugen Füchsle, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Delay-Robust Routes in Temporal Graphs. CoRR abs/2201.05390 (2022) - [i34]Nina Klobas, George B. Mertzios, Hendrik Molter, Paul G. Spirakis:
The complexity of computing optimum labelings for temporal connectivity. CoRR abs/2202.05880 (2022) - [i33]Danny Hermelin, Hendrik Molter, Dvir Shabtay:
Single Machine Weighted Number of Tardy Jobs Minimization With Small Weights. CoRR abs/2202.06841 (2022) - [i32]Jessica A. Enright, Kitty Meeks, Hendrik Molter:
Counting Temporal Paths. CoRR abs/2202.12055 (2022) - [i31]Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Dvir Shabtay:
Hardness of Interval Scheduling on Unrelated Machines. CoRR abs/2206.12825 (2022) - 2021
- [j15]Junjie Luo, Hendrik Molter, André Nichterlein, Rolf Niedermeier:
Parameterized Dynamic Cluster Editing. Algorithmica 83(1): 1-44 (2021) - [j14]Arnaud Casteigts, Anne-Sophie Himmel, Hendrik Molter, Philipp Zschoche:
Finding Temporal Paths Under Waiting Time Constraints. Algorithmica 83(9): 2754-2802 (2021) - [j13]George B. Mertzios, Hendrik Molter, Viktor Zamaraev:
Sliding window temporal graph coloring. J. Comput. Syst. Sci. 120: 97-115 (2021) - [j12]Junjie Luo, Hendrik Molter, Ondrej Suchý:
A Parameterized Complexity View on Collapsing k-Cores. Theory Comput. Syst. 65(8): 1243-1282 (2021) - [j11]Hendrik Molter, Rolf Niedermeier, Malte Renken:
Isolation concepts applied to temporal clique enumeration. Netw. Sci. 9(S1): S83-S105 (2021) - [c29]Klaus Heeger, Danny Hermelin, George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Dvir Shabtay:
Equitable Scheduling on a Single Machine. AAAI 2021: 11818-11825 - [c28]Nicolas Maack, Hendrik Molter, Rolf Niedermeier, Malte Renken:
On Finding Separators in Temporal Split and Permutation Graphs. FCT 2021: 385-398 - [c27]Nina Klobas, George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Philipp Zschoche:
Interference-free Walks in Time: Temporally Disjoint Paths. IJCAI 2021: 4090-4096 - [c26]George B. Mertzios, Hendrik Molter, Malte Renken, Paul G. Spirakis, Philipp Zschoche:
The Complexity of Transitively Orienting Temporal Graphs. MFCS 2021: 75:1-75:18 - [c25]Hendrik Molter, Malte Renken, Philipp Zschoche:
Temporal Reachability Minimization: Delaying vs. Deleting. MFCS 2021: 76:1-76:15 - [c24]Maciej Rymar, Hendrik Molter, André Nichterlein, Rolf Niedermeier:
Towards Classifying the Polynomial-Time Solvability of Temporal Betweenness Centrality. WG 2021: 219-231 - [i30]George B. Mertzios, Hendrik Molter, Malte Renken, Paul G. Spirakis, Philipp Zschoche:
The Complexity of Transitively Orienting Temporal Graphs. CoRR abs/2102.06783 (2021) - [i29]Hendrik Molter, Malte Renken, Philipp Zschoche:
Temporal Reachability Minimization: Delaying vs. Deleting. CoRR abs/2102.10814 (2021) - [i28]Nina Klobas, George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Philipp Zschoche:
Interference-free Walks in Time: Temporally Disjoint Paths. CoRR abs/2105.08335 (2021) - [i27]Nicolas Maack, Hendrik Molter, Rolf Niedermeier, Malte Renken:
On Finding Separators in Temporal Split and Permutation Graphs. CoRR abs/2105.12003 (2021) - [i26]Maciej Rymar, Hendrik Molter, André Nichterlein, Rolf Niedermeier:
Towards Classifying the Polynomial-Time Solvability of Temporal Betweenness Centrality. CoRR abs/2105.13055 (2021) - [i25]Hendrik Molter:
The Complexity of Finding Temporal Separators under Waiting Time Constraints. CoRR abs/2107.01609 (2021) - [i24]Danny Hermelin, Yuval Itzhaki, Hendrik Molter, Rolf Niedermeier:
Temporal Unit Interval Independent Sets. CoRR abs/2112.06172 (2021) - [i23]Danny Hermelin, Hendrik Molter, Rolf Niedermeier, Dvir Shabtay:
Equitable Scheduling for the Total Completion Time Objective. CoRR abs/2112.13824 (2021) - 2020
- [b1]Hendrik Molter:
Classic graph problems made temporal - a parameterized complexity analysis. Technical University of Berlin, Germany, 2020, ISBN 978-3-7983-3172-3, pp. 1-206 - [j10]Henning Fernau, Till Fluschnik, Danny Hermelin, Andreas Krebs, Hendrik Molter, Rolf Niedermeier:
Diminishable parameterized problems and strict polynomial kernelization. Comput. 9(1): 1-24 (2020) - [j9]Marcelo Garlet Millani, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Efficient algorithms for measuring the funnel-likeness of DAGs. J. Comb. Optim. 39(1): 216-245 (2020) - [j8]Philipp Zschoche, Till Fluschnik, Hendrik Molter, Rolf Niedermeier:
The complexity of finding small separators in temporal graphs. J. Comput. Syst. Sci. 107: 72-92 (2020) - [j7]René van Bevern, Christian Komusiewicz, Hendrik Molter, Rolf Niedermeier, Manuel Sorge, Toby Walsh:
h-Index manipulation by undoing merges. Quant. Sci. Stud. 1(4): 1529-1552 (2020) - [j6]Till Fluschnik, Hendrik Molter, Rolf Niedermeier, Malte Renken, Philipp Zschoche:
Temporal graph classes: A view through temporal separators. Theor. Comput. Sci. 806: 197-218 (2020) - [c23]Till Fluschnik, Hendrik Molter, Rolf Niedermeier, Malte Renken, Philipp Zschoche:
As Time Goes By: Reflections on Treewidth for Temporal Graphs. Treewidth, Kernels, and Algorithms 2020: 49-77 - [c22]Arnaud Casteigts, Anne-Sophie Himmel, Hendrik Molter, Philipp Zschoche:
Finding Temporal Paths Under Waiting Time Constraints. ISAAC 2020: 30:1-30:18 - [c21]Sebastian Buß, Hendrik Molter, Rolf Niedermeier, Maciej Rymar:
Algorithmic Aspects of Temporal Betweenness. KDD 2020: 2084-2092 - [c20]George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Viktor Zamaraev, Philipp Zschoche:
Computing Maximum Matchings in Temporal Graphs. STACS 2020: 27:1-27:14 - [c19]Roman Haag, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Feedback Edge Sets in Temporal Graphs. WG 2020: 200-212 - [i22]Roman Haag, Hendrik Molter, Rolf Niedermeier, Malte Renken:
Feedback Edge Sets in Temporal Graphs. CoRR abs/2003.13641 (2020) - [i21]Till Fluschnik, Hendrik Molter, Rolf Niedermeier, Malte Renken, Philipp Zschoche:
As Time Goes By: Reflections on Treewidth for Temporal Graphs. CoRR abs/2004.13491 (2020) - [i20]Sebastian Buß, Hendrik Molter, Rolf Niedermeier, Maciej Rymar:
Algorithmic Aspects of Temporal Betweenness. CoRR abs/2006.08668 (2020) - [i19]Klaus Heeger, Danny Hermelin, George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Dvir Shabtay:
Equitable Scheduling on a Single Machine. CoRR abs/2010.04643 (2020)
2010 – 2019
- 2019
- [j5]Matthias Bentert, Anne-Sophie Himmel, Hendrik Molter, Marco Morik, Rolf Niedermeier, René Saitenmacher:
Listing All Maximal k-Plexes in Temporal Graphs. ACM J. Exp. Algorithmics 24(1): 1.13:1-1.13:27 (2019) - [j4]Robert Bredereck, Christian Komusiewicz, Stefan Kratsch, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Assessing the computational complexity of multilayer subgraph detection. Netw. Sci. 7(2): 215-241 (2019) - [c18]George B. Mertzios, Hendrik Molter, Viktor Zamaraev:
Sliding Window Temporal Graph Coloring. AAAI 2019: 7667-7674 - [c17]Hendrik Molter, Rolf Niedermeier, Malte Renken:
Enumerating Isolated Cliques in Temporal Networks. COMPLEX NETWORKS (2) 2019: 519-531 - [i18]George B. Mertzios, Hendrik Molter, Rolf Niedermeier, Viktor Zamaraev, Philipp Zschoche:
Computing Maximum Matchings in Temporal Graphs. CoRR abs/1905.05304 (2019) - [i17]Hendrik Molter, Rolf Niedermeier, Malte Renken:
Enumerating Isolated Cliques in Temporal Networks. CoRR abs/1909.06292 (2019) - [i16]Arnaud Casteigts, Anne-Sophie Himmel, Hendrik Molter, Philipp Zschoche:
The Computational Complexity of Finding Temporal Paths under Waiting Time Constraints. CoRR abs/1909.06437 (2019) - 2018
- [j3]René van Bevern, Till Fluschnik, George B. Mertzios, Hendrik Molter, Manuel Sorge, Ondrej Suchý:
The parameterized complexity of finding secluded solutions to some classical optimization problems on graphs. Discret. Optim. 30: 20-50 (2018) - [c16]Matthias Bentert, Anne-Sophie Himmel, Hendrik Molter, Marco Morik, Rolf Niedermeier, René Saitenmacher:
Listing All Maximal k-Plexes in Temporal Graphs. ASONAM 2018: 41-46 - [c15]Henning Fernau, Till Fluschnik, Danny Hermelin, Andreas Krebs, Hendrik Molter, Rolf Niedermeier:
Diminishable Parameterized Problems and Strict Polynomial Kernelization. CiE 2018: 161-171 - [c14]Junjie Luo, Hendrik Molter, André Nichterlein, Rolf Niedermeier:
Parameterized Dynamic Cluster Editing. FSTTCS 2018: 46:1-46:15 - [c13]Jiehua Chen, Hendrik Molter, Manuel Sorge, Ondrej Suchý:
Cluster Editing in Multi-Layer and Temporal Graphs. ISAAC 2018: 24:1-24:13 - [c12]Marcelo Garlet Millani, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Efficient Algorithms for Measuring the Funnel-Likeness of DAGs. ISCO 2018: 183-195 - [c11]Junjie Luo, Hendrik Molter, Ondrej Suchý:
A Parameterized Complexity View on Collapsing k-Cores. IPEC 2018: 7:1-7:14 - [c10]Philipp Zschoche, Till Fluschnik, Hendrik Molter, Rolf Niedermeier:
The Complexity of Finding Small Separators in Temporal Graphs. MFCS 2018: 45:1-45:17 - [c9]Clemens Hoffmann, Hendrik Molter, Manuel Sorge:
The Parameterized Complexity of Centrality Improvement in Networks. SOFSEM 2018: 111-124 - [c8]Till Fluschnik, Hendrik Molter, Rolf Niedermeier, Philipp Zschoche:
Temporal Graph Classes: A View Through Temporal Separators. WG 2018: 216-227 - [i15]Marcelo Garlet Millani, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Efficient Algorithms for Measuring the Funnel-likeness of DAGs. CoRR abs/1801.10401 (2018) - [i14]Till Fluschnik, Hendrik Molter, Rolf Niedermeier, Philipp Zschoche:
Temporal Graph Classes: A View Through Temporal Separators. CoRR abs/1803.00882 (2018) - [i13]Junjie Luo, Hendrik Molter, Ondrej Suchý:
A Parameterized Complexity View on Collapsing k-Cores. CoRR abs/1805.12453 (2018) - [i12]Matthias Bentert, Anne-Sophie Himmel, Hendrik Molter, Marco Morik, Rolf Niedermeier, René Saitenmacher:
Listing All Maximal k-Plexes in Temporal Graphs. CoRR abs/1806.10210 (2018) - [i11]Junjie Luo, Hendrik Molter, André Nichterlein, Rolf Niedermeier:
Parameterized Dynamic Cluster Editing. CoRR abs/1810.06625 (2018) - [i10]George B. Mertzios, Hendrik Molter, Viktor Zamaraev:
Sliding Window Temporal Graph Coloring. CoRR abs/1811.04753 (2018) - 2017
- [j2]Anne-Sophie Himmel, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Adapting the Bron-Kerbosch algorithm for enumerating maximal cliques in temporal graphs. Soc. Netw. Anal. Min. 7(1): 35:1-35:16 (2017) - [c7]Robert Bredereck, Christian Komusiewicz, Stefan Kratsch, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Assessing the Computational Complexity of Multi-layer Subgraph Detection. CIAC 2017: 128-139 - [c6]Till Fluschnik, Meike Hatzel, Steffen Härtlein, Hendrik Molter, Henning Seidler:
The Minimum Shared Edges Problem on Grid-Like Graphs. WG 2017: 249-262 - [i9]Till Fluschnik, Meike Hatzel, Steffen Härtlein, Hendrik Molter, Henning Seidler:
The Minimum Shared Edges Problem on Grid-like Graphs. CoRR abs/1703.02332 (2017) - [i8]Jiehua Chen, Hendrik Molter, Manuel Sorge, Ondrej Suchý:
A Parameterized View on Multi-Layer Cluster Editing. CoRR abs/1709.09100 (2017) - [i7]Clemens Hoffmann, Hendrik Molter, Manuel Sorge:
The Parameterized Complexity of Centrality Improvement in Networks. CoRR abs/1710.01576 (2017) - [i6]Philipp Zschoche, Till Fluschnik, Hendrik Molter, Rolf Niedermeier:
The Computational Complexity of Finding Separators in Temporal Graphs. CoRR abs/1711.00963 (2017) - 2016
- [j1]Carme Àlvarez, Maria J. Blesa, Hendrik Molter:
Firefighting as a Strategic Game. Internet Math. 12(1-2): 101-120 (2016) - [c5]Anne-Sophie Himmel, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Enumerating maximal cliques in temporal graphs. ASONAM 2016: 337-344 - [c4]René van Bevern, Christian Komusiewicz, Hendrik Molter, Rolf Niedermeier, Manuel Sorge, Toby Walsh:
h-Index Manipulation by Undoing Merges. ECAI 2016: 895-903 - [c3]René van Bevern, Till Fluschnik, George B. Mertzios, Hendrik Molter, Manuel Sorge, Ondrej Suchý:
Finding Secluded Places of Special Interest in Graphs. IPEC 2016: 5:1-5:16 - [i5]René van Bevern, Christian Komusiewicz, Hendrik Molter, Rolf Niedermeier, Manuel Sorge, Toby Walsh:
h-Index Manipulation by Undoing Merges. CoRR abs/1604.04827 (2016) - [i4]Robert Bredereck, Christian Komusiewicz, Stefan Kratsch, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Assessing the Computational Complexity of Multi-Layer Subgraph Detection. CoRR abs/1604.07724 (2016) - [i3]Anne-Sophie Himmel, Hendrik Molter, Rolf Niedermeier, Manuel Sorge:
Enumerating Maximal Cliques in Temporal Graphs. CoRR abs/1605.03871 (2016) - [i2]René van Bevern, Till Fluschnik, George B. Mertzios, Hendrik Molter, Manuel Sorge, Ondrej Suchý:
Finding Secluded Places of Special Interest in Graphs. CoRR abs/1606.09000 (2016) - [i1]Henning Fernau, Till Fluschnik, Danny Hermelin, Andreas Krebs, Hendrik Molter, Rolf Niedermeier:
Diminishable Parameterized Problems and Strict Polynomial Kernelization. CoRR abs/1611.03739 (2016) - 2014
- [c2]Carme Àlvarez, Maria J. Blesa, Hendrik Molter:
Firefighting as a Game. WAW 2014: 108-119 - 2012
- [c1]Timo Kötzing, Hendrik Molter:
ACO Beats EA on a Dynamic Pseudo-Boolean Function. PPSN (1) 2012: 113-122
Coauthor Index
[j24] [j23] [j22] [j21] [j20] [j19] [j18] [j17] [c32] [c31] [c30] [i36] [i35] [j15] [j11] [c29] [c28] [c27] [c24] [i28] [i27] [i26] [i24] [i23] [j10] [j9] [j8] [j7] [j6] [c23] [c21] [c20] [c19] [i22] [i21] [i20] [i19] [j5] [j4] [c17] [i18] [i17] [c16] [c15] [c14] [c12] [c10] [c8] [i15] [i14] [i12] [i11] [j2] [c7] [i6] [c5] [c4] [i5] [i4] [i3] [i1]
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