default search action
Google
Google Scholar
Semantic Scholar
Internet Archive Scholar
CiteSeerX
ORCIDDaniel Merkle
Person information
- affiliation: University of Southern Denmark, Dept. of Mathematics and Computer Science, Odense, Denmark
SPARQL queries 
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
showing all ?? records
2020 – today
- 2024
[j48]Casper Asbjørn Eriksen
, Jakob Lykke Andersen, Rolf Fagerberg, Daniel Merkle:
Toward the Reconciliation of Inconsistent Molecular Structures from Biochemical Databases. J. Comput. Biol. 31(6): 498-512 (2024)- [j47]Tieu-Long Phan, Klaus Weinbauer, Thomas Gärtner, Daniel Merkle, Jakob L. Andersen, Rolf Fagerberg, Peter F. Stadler:
Reaction rebalancing: a novel approach to curating reaction databases. J. Cheminformatics 16(1): 82 (2024) - [j46]Marcos E. González Laffitte, Klaus Weinbauer, Tieu-Long Phan, Nora Beier, Nico Domschke, Christoph Flamm, Thomas Gatter, Daniel Merkle, Peter F. Stadler:
Partial Imaginary Transition State (ITS) Graphs: A Formal Framework for Research and Analysis of Atom-to-Atom Maps of Unbalanced Chemical Reactions and Their Completions. Symmetry 16(9): 1217 (2024) - [i26]Jakob L. Andersen, Akbar Davoodi, Rolf Fagerberg, Christoph Flamm, Walter Fontana, Juraj Kolcák, Christophe V. F. P. Laurent, Daniel Merkle, Nikolai Nøjgaard:
Automated Inference of Graph Transformation Rules. CoRR abs/2404.02692 (2024) - 2023
- [c46]Casper Asbjørn Eriksen, Jakob Lykke Andersen, Rolf Fagerberg, Daniel Merkle:
Reconciling Inconsistent Molecular Structures from Biochemical Databases. ISBRA 2023: 58-71 - [c45]Jakob L. Andersen, Sissel Banke, Rolf Fagerberg, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
On the Realisability of Chemical Pathways. ISBRA 2023: 409-419 - [i25]Casper Asbjørn Eriksen, Jakob Lykke Andersen, Rolf Fagerberg, Daniel Merkle:
Reconciling Inconsistent Molecular Structures from Biochemical Databases. CoRR abs/2308.12735 (2023) - [i24]Jakob L. Andersen, Sissel Banke, Rolf Fagerberg, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
On the Realisability of Chemical Pathways. CoRR abs/2309.10629 (2023) - 2022
- [j45]Jakob L. Andersen, Rolf Fagerberg, Christoph Flamm, Walter Fontana, Juraj Kolcák, Christophe V. F. P. Laurent, Daniel Merkle, Nikolai Nøjgaard:
Representing Catalytic Mechanisms with Rule Composition. J. Chem. Inf. Model. 62(22): 5513-5524 (2022) - [j44]Christoph Flamm, Marc Hellmuth, Daniel Merkle, Nikolai Nøjgaard, Peter F. Stadler:
Generic Context-Aware Group Contributions. IEEE ACM Trans. Comput. Biol. Bioinform. 19(1): 429-442 (2022) - [i23]Jakob L. Andersen, Rolf Fagerberg, Juraj Kolcák, Christophe V. F. P. Laurent, Daniel Merkle, Nikolai Nøjgaard:
Efficient Modular Graph Transformation Rule Application. CoRR abs/2201.04360 (2022) - [i22]Jakob L. Andersen, Rolf Fagerberg, Christoph Flamm, Walter Fontana, Juraj Kolcák, Christophe V. F. P. Laurent, Daniel Merkle, Nikolai Nøjgaard:
Characterizing Catalytic Mechanisms with Overlay Graphs. CoRR abs/2201.04515 (2022) - 2021
- [j43]Jakob L. Andersen, Rolf Fagerberg, Christoph Flamm, Walter Fontana, Juraj Kolcák, Christophe V. F. P. Laurent, Daniel Merkle, Nikolai Nøjgaard:
Graph transformation for enzymatic mechanisms. Bioinform. 37(Supplement): 392-400 (2021) - [j42]Nikolai Nøjgaard, Walter Fontana, Marc Hellmuth, Daniel Merkle:
Cayley Graphs of Semigroups Applied to Atom Tracking in Chemistry. J. Comput. Biol. 28(7): 701-715 (2021) - [j41]Nicolas Behr, Jean Krivine, Jakob L. Andersen, Daniel Merkle:
Rewriting theory for the life sciences: A unifying theory of CTMC semantics. Theor. Comput. Sci. 884: 68-115 (2021) - [i21]Jakob L. Andersen, Rolf Fagerberg, Christoph Flamm, Walter Fontana, Juraj Kolcák, Christophe V. F. P. Laurent, Daniel Merkle, Nikolai Nøjgaard:
Graph Transformation for Enzymatic Mechanisms. CoRR abs/2102.03292 (2021) - [i20]Nicolas Behr, Jean Krivine, Jakob L. Andersen, Daniel Merkle:
Rewriting Theory for the Life Sciences: A Unifying Theory of CTMC Semantics (Long version). CoRR abs/2106.02573 (2021) - [i19]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Defining Autocatalysis in Chemical Reaction Networks. CoRR abs/2107.03086 (2021) - [i18]Nikolai Nøjgaard, Walter Fontana, Marc Hellmuth, Daniel Merkle:
Cayley Graphs of Semigroups Applied to Atom Tracking in Chemistry. CoRR abs/2108.04077 (2021) - 2020
- [j40]Jakob L. Andersen, Daniel Merkle, Peter S. Rasmussen:
Combining Graph Transformations and Semigroups for Isotopic Labeling Design. J. Comput. Biol. 27(2): 269-287 (2020) - [j39]Jakob L. Andersen, Daniel Merkle:
A Generic Framework for Engineering Graph Canonization Algorithms. ACM J. Exp. Algorithmics 25: 1-26 (2020) - [c44]Marc Hellmuth, Daniel Merkle, Nikolai Nøjgaard:
Atom Tracking Using Cayley Graphs. ISBRA 2020: 406-415 - [c43]Jakob Lykke Andersen, Marc Hellmuth, Daniel Merkle, Nikolai Nøjgaard, Marco Peressotti:
A Graph-Based Tool to Embed the π-Calculus into a Computational DPO Framework. SOFSEM (Doctoral Student Research Forum) 2020: 121-132
2010 – 2019
- 2019
- [j38]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Chemical Transformation Motifs - Modelling Pathways as Integer Hyperflows. IEEE ACM Trans. Comput. Biol. Bioinform. 16(2): 510-523 (2019) - [c42]Jakob L. Andersen, Daniel Merkle, Peter S. Rasmussen:
Graph Transformations, Semigroups, and Isotopic Labeling. ISBRA 2019: 196-207 - [i17]Jakob Lykke Andersen, Marc Hellmuth, Daniel Merkle, Nikolai Nøjgaard, Marco Peressotti:
A Graph-Based Tool to Embed the π-Calculus into a Computational DPO Framework. CoRR abs/1911.00407 (2019) - 2018
- [j37]Nikolai Nøjgaard, Manuela Geiß, Daniel Merkle, Peter F. Stadler, Nicolas Wieseke, Marc Hellmuth:
Time-consistent reconciliation maps and forbidden time travel. Algorithms Mol. Biol. 13(1): 2:1-2:17 (2018) - [j36]Rolf Fagerberg, Christoph Flamm, Rojin Kianian, Daniel Merkle, Peter F. Stadler:
Finding the K best synthesis plans. J. Cheminformatics 10(1): 19:1-19:21 (2018) - [j35]Bjarke N. Hansen, Kim S. Larsen, Daniel Merkle, Alexei Mihalchuk:
DNA-templated synthesis optimization. Nat. Comput. 17(4): 693-707 (2018) - [c41]Jakob L. Andersen, Daniel Merkle:
A Generic Framework for Engineering Graph Canonization Algorithms. ALENEX 2018: 139-153 - [c40]Marc Hellmuth, Anders S. Knudsen, Michal Kotrbcík, Daniel Merkle, Nikolai Nøjgaard:
Linear Time Canonicalization and Enumeration of Non-Isomorphic 1-Face Embeddings. ALENEX 2018: 154-168 - [c39]Nikolai Nøjgaard, Nadia El-Mabrouk, Daniel Merkle, Nicolas Wieseke, Marc Hellmuth:
Partial Homology Relations - Satisfiability in Terms of Di-Cographs. COCOON 2018: 403-415 - 2017
- [c38]Bjarke N. Hansen, Kim S. Larsen, Daniel Merkle, Alexei Mihalchuk:
DNA-Templated Synthesis Optimization. DNA 2017: 17-32 - [c37]Jakob Lykke Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Chemical Graph Transformation with Stereo-Information. ICGT 2017: 54-69 - [c36]Nikolai Nøjgaard, Manuela Geiß, Daniel Merkle, Peter F. Stadler, Nicolas Wieseke, Marc Hellmuth:
Forbidden Time Travel: Characterization of Time-Consistent Tree Reconciliation Maps. WABI 2017: 17:1-17:12 - [i16]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
An Intermediate Level of Abstraction for Computational Systems Chemistry. CoRR abs/1701.09097 (2017) - [i15]Nikolai Nøjgaard, Manuela Geiß, Peter F. Stadler, Daniel Merkle, Nicolas Wieseke, Marc Hellmuth:
Forbidden Time Travel: Characterization of Time-Consistent Tree Reconciliation Maps. CoRR abs/1705.02179 (2017) - [i14]Nikolai Nøjgaard, Nadia El-Mabrouk, Daniel Merkle, Nicolas Wieseke, Marc Hellmuth:
Partial Orthology, Paralogy and Xenology Relations - Satisfiability in terms of Di-Cographs. CoRR abs/1711.00504 (2017) - [i13]Jakob L. Andersen, Daniel Merkle:
A Generic Framework for Engineering Graph Canonization Algorithms. CoRR abs/1711.08289 (2017) - [i12]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Chemical Transformation Motifs - Modelling Pathways as Integer Hyperflows. CoRR abs/1712.02594 (2017) - [i11]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Algorithmic Cheminformatics (Dagstuhl Seminar 17452). Dagstuhl Reports 7(11): 28-45 (2017) - 2016
- [c35]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
A Software Package for Chemically Inspired Graph Transformation. ICGT 2016: 73-88 - [c34]Christoph Flamm, Daniel Merkle, Peter F. Stadler, Uffe Thorsen:
Automatic Inference of Graph Transformation Rules Using the Cyclic Nature of Chemical Reactions. ICGT 2016: 206-222 - [i10]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
A Software Package for Chemically Inspired Graph Transformation. CoRR abs/1603.02481 (2016) - [i9]Christoph Flamm, Daniel Merkle, Peter F. Stadler, Uffe Thorsen:
Automatic Inference of Graph Transformation Rules Using the Cyclic Nature of Chemical Reactions. CoRR abs/1604.06379 (2016) - 2015
- [j34]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Task allocation in organic computing systems: networks with reconfigurable helper units. Int. J. Auton. Adapt. Commun. Syst. 8(1): 60-80 (2015) - [j33]Jakob L. Andersen, Christoph Flamm, Martin M. Hanczyc, Daniel Merkle:
Towards Optimal DNA-Templated Computing. Int. J. Unconv. Comput. 11(3-4): 185-203 (2015) - [i8]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Support for Eschenmoser's Glyoxylate Scenario. CoRR abs/1502.07555 (2015) - 2014
- [j32]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Generic strategies for chemical space exploration. Int. J. Comput. Biol. Drug Des. 7(2/3): 225-258 (2014) - [c33]Jakob L. Andersen, Christoph Flamm, Martin M. Hanczyc, Daniel Merkle:
Towards an Optimal DNA-Templated Molecular Assembler. ALIFE 2014: 557-564 - [c32]Jakob Lykke Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
50 Shades of Rule Composition - From Chemical Reactions to Higher Levels of Abstraction. FMMB 2014: 117-135 - [c31]Felix Palludan Hargreaves, Daniel Merkle, Peter Schneider-Kamp:
Group communication patterns for high performance computing in scala. FHPC@ICFP 2014: 75-85 - [i7]Felix Palludan Hargreaves, Daniel Merkle, Peter Schneider-Kamp:
Group Communication Patterns for High Performance Computing in Scala. CoRR abs/1406.6163 (2014) - [i6]Wolfgang Banzhaf, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Algorithmic Cheminformatics (Dagstuhl Seminar 14452). Dagstuhl Reports 4(11): 22-39 (2014) - 2013
- [j31]Jakob L. Andersen, Tommy Andersen, Christoph Flamm, Martin M. Hanczyc, Daniel Merkle, Peter F. Stadler:
Navigating the Chemical Space of HCN Polymerization and Hydrolysis: Guiding Graph Grammars by Mass Spectrometry Data. Entropy 15(10): 4066-4083 (2013) - [j30]Alexander Scheidler, Daniel Merkle, Martin Middendorf:
Swarm controlled emergence for ant clustering. Int. J. Intell. Comput. Cybern. 6(1): 62-82 (2013) - [j29]Rolf Fagerberg, Christoph Flamm, Daniel Merkle, Philipp Peters, Peter F. Stadler:
On the Complexity of Reconstructing Chemical Reaction Networks. Math. Comput. Sci. 7(3): 275-292 (2013) - [c30]Christoph Flamm, Chris Hemmingsen, Daniel Merkle:
Barrier Trees for Metabolic Adjustment Landscapes. ECAL 2013: 1151-1158 - [c29]Felix Palludan Hargreaves, Daniel Merkle:
FooPar: A Functional Object Oriented Parallel Framework in Scala. PPAM (2) 2013: 118-129 - [i5]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Generic Strategies for Chemical Space Exploration. CoRR abs/1302.4006 (2013) - [i4]Felix Palludan Hargreaves, Daniel Merkle:
FooPar: A Functional Object Oriented Parallel Framework in Scala. CoRR abs/1304.2550 (2013) - [i3]Rolf Fagerberg, Christoph Flamm, Daniel Merkle, Philipp Peters, Peter F. Stadler:
On the Complexity of Reconstructing Chemical Reaction Networks. CoRR abs/1309.7198 (2013) - 2012
- [c28]Rolf Fagerberg, Christoph Flamm, Daniel Merkle, Philipp Peters:
Exploring Chemistry Using SMT. CP 2012: 900-915 - [i2]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Inferring Chemical Reaction Patterns Using Rule Composition in Graph Grammars. CoRR abs/1208.3153 (2012) - 2011
- [j28]Matthias Bernt, Kuan-Yu Chen, Ming-Chiang Chen, An-Chiang Chu, Daniel Merkle, Hung-Lung Wang, Kun-Mao Chao, Martin Middendorf:
Finding all sorting tandem duplication random loss operations. J. Discrete Algorithms 9(1): 32-48 (2011) - [p3]Alexander Scheidler, Arne Brutschy, Konrad Diwold, Daniel Merkle, Martin Middendorf:
Ant Inspired Methods for Organic Computing. Organic Computing 2011: 95-109 - [i1]Jakob L. Andersen, Christoph Flamm, Daniel Merkle, Peter F. Stadler:
Maximizing Output and Recognizing Autocatalysis in Chemical Reaction Networks is NP-Complete. CoRR abs/1110.6051 (2011) - 2010
- [j27]Daniel Merkle, Martin Middendorf, Nicolas Wieseke:
A parameter-adaptive dynamic programming approach for inferring cophylogenies. BMC Bioinform. 11(S-1): 60 (2010) - [c27]Jacob Midtgaard-Olesen, Carsten Baldauf, Daniel Merkle:
Barrier Trees for Continuous Fitness Landscapes. ALIFE 2010: 368-369 - [e2]Harold Fellermann, Mark Dörr, Martin M. Hanczyc, Lone Ladegaard Laursen, Sarah Elizabeth Maurer, Daniel Merkle, Pierre-Alain Monnard, Kasper Støy, Steen Rasmussen:
Proceedings of the Twelfth International Conference on the Synthesis and Simulation of Living Systems, ALIFE 2010, Odense, Denmark, August 19-23, 2010. MIT Press 2010, ISBN 9780262290753 [contents]
2000 – 2009
- 2009
- [j26]Konrad Diwold, Daniel Merkle, Martin Middendorf:
Adapting to Dynamic Environments: Polyethism in Response Threshold Models for Social Insects. Adv. Complex Syst. 12(3): 327-346 (2009) - [j25]Konstantin Klemm, Daniel Merkle, Eckehard Olbrich:
Editorial: Artificial Life. Adv. Complex Syst. 12(3) (2009) - [j24]Marc Hellmuth, Daniel Merkle, Martin Middendorf:
Extended shapes for the combinatorial design of RNA sequences. Int. J. Comput. Biol. Drug Des. 2(4): 371-384 (2009) - [j23]Karl F. Doerner, Daniel Merkle, Thomas Stützle:
Special issue on ant colony optimization. Swarm Intell. 3(1): 1-2 (2009) - [c26]Matthias Bernt, Ming-Chiang Chen, Daniel Merkle, Hung-Lung Wang, Kun-Mao Chao, Martin Middendorf:
Finding All Sorting Tandem Duplication Random Loss Operations. CPM 2009: 301-313 - [c25]Marc Hellmuth, Daniel Merkle, Martin Middendorf:
On the Design of RNA Sequences for Realizing Extended Shapes. IJCBS 2009: 167-173 - 2008
- [j22]Stefan Janson, Daniel Merkle, Martin Middendorf:
Molecular docking with multi-objective Particle Swarm Optimization. Appl. Soft Comput. 8(1): 666-675 (2008) - [j21]Stefan Janson, Daniel Merkle, Martin Middendorf:
A decentralization approach for swarm intelligence algorithms in networks applied to multi swarm PSO. Int. J. Intell. Comput. Cybern. 1(1): 25-45 (2008) - [j20]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Self-Organized Task Allocation for Service Tasks in Computing Systems with Reconfigurable Components. J. Math. Model. Algorithms 7(2): 237-254 (2008) - [j19]Daniel Merkle, Martin Middendorf:
Swarm intelligence and signal processing [DSP Exploratory]. IEEE Signal Process. Mag. 25(6): 152-158 (2008) - [j18]Matthias Bernt, Daniel Merkle, Martin Middendorf:
Solving the Preserving Reversal Median Problem. IEEE ACM Trans. Comput. Biol. Bioinform. 5(3): 332-347 (2008) - [j17]Alexander Scheidler, Daniel Merkle, Martin Middendorf:
Stability and performance of ant queue inspired task partitioning methods. Theory Biosci. 127(2): 149-161 (2008) - [c24]Arne Brutschy, Alexander Scheidler, Daniel Merkle, Martin Middendorf:
Learning from House-Hunting Ants: Collective Decision-Making in Organic Computing Systems. ANTS Conference 2008: 96-107 - [c23]Alexander Scheidler, Christian Blum, Daniel Merkle, Martin Middendorf:
Emergent Sorting in Networks of Router Agents. ANTS Conference 2008: 299-306 - [c22]Alexander Scheidler, Daniel Merkle, Martin Middendorf:
Congestion Control in Ant Like Moving Agent Systems. BICC 2008: 33-43 - [c21]Matthias Bernt, Daniel Merkle, Martin Middendorf:
An Algorithm for Inferring Mitogenome Rearrangements in a Phylogenetic Tree. RECOMB-CG 2008: 143-157 - [p2]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Self-adaptive Worker-Helper Systems with Self-Organized Task Allocation. Organic Computing 2008: 221-239 - [p1]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Organic Computing and Swarm Intelligence. Swarm Intelligence 2008: 253-281 - [e1]Christian Blum, Daniel Merkle:
Swarm Intelligence: Introduction and Applications. Natural Computing Series, Springer 2008, ISBN 978-3-540-74088-9 [contents] - 2007
- [j16]Matthias Bernt, Daniel Merkle, Martin Middendorf:
Using median sets for inferring phylogenetic trees. Bioinform. 23(2): 129-135 (2007) - [j15]Matthias Bernt, Daniel Merkle, Kai Ramsch, Guido Fritzsch, Marleen Perseke, Detlef Bernhard, Martin Schlegel, Peter F. Stadler, Martin Middendorf:
CREx: inferring genomic rearrangements based on common intervals. Bioinform. 23(21): 2957-2958 (2007) - [c20]Matthias Bernt, Daniel Merkle, Martin Middendorf:
A Fast and Exact Algorithm for the Perfect Reversal Median Problem. ISBRA 2007: 305-316 - [c19]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Swarm Controlled Emergence - Designing an Anti-Clustering Ant System. SIS 2007: 242-249 - 2006
- [j14]Daniel Merkle, Martin Middendorf:
Marco Dorigo and Thomas Stützle, Ant Colony Optimization, MIT Press (2004) ISBN 0-262-04219-3. Eur. J. Oper. Res. 168(1): 269-271 (2006) - [j13]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Modeling Ant Brood ending Patterns with Cellular Automata. J. Cell. Autom. 1(2): 183-194 (2006) - [j12]Matthias Bernt, Daniel Merkle, Martin Middendorf:
Genome Rearrangement Based on Reversals that Preserve Conserved Intervals. IEEE ACM Trans. Comput. Biol. Bioinform. 3(3): 275-288 (2006) - [c18]Matthias Bernt, Daniel Merkle, Martin Middendorf:
The Reversal Median Problem, Common Intervals, and Mitochondrial Gene Orders. CompLife 2006: 52-63 - [c17]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Using Decentralized Clustering for Task Allocation in Networks with Reconfigurable Helper Units. IWSOS/EuroNGI 2006: 137-147 - [c16]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Self-organized task allocation for computing systems with reconfigurable components. IPDPS 2006 - 2005
- [j11]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Decentralized packet clustering in router-based networks. Int. J. Found. Comput. Sci. 16(2): 321-341 (2005) - [j10]Daniel Merkle, Martin Middendorf:
On solving permutation scheduling problems with ant colony optimization. Int. J. Syst. Sci. 36(5): 255-266 (2005) - [j9]Daniel Merkle, Christian Blum:
Swarm Intelligence - An Optimization-Based Introduction. Künstliche Intell. 19(4): 5-10 (2005) - [j8]Daniel Merkle, Martin Middendorf:
Reconstruction of the cophylogenetic history of related phylogenetic trees with divergence timing information. Theory Biosci. 123(4): 277-299 (2005) - [c15]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Dynamic Decentralized Packet Clustering in Networks. EvoWorkshops 2005: 574-583 - [c14]Stefan Janson, Daniel Merkle:
A New Multi-objective Particle Swarm Optimization Algorithm Using Clustering Applied to Automated Docking. Hybrid Metaheuristics 2005: 128-141 - [c13]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Modelling Ant Brood Tending Behavior with Cellular Automata. International Conference on Computational Science (2) 2005: 412-419 - [c12]Matthias Bernt, Daniel Merkle, Martin Middendorf:
A Parallel Algorithm for Solving the Reversal Median Problem. PPAM 2005: 1089-1096 - 2004
- [j7]Daniel Merkle, Martin Middendorf:
Dynamic Polyethism and Competition for Tasks in Threshold Reinforcement Models of Social Insects. Adapt. Behav. 12(3-4): 251-262 (2004) - [c11]Daniel Merkle, Martin Middendorf:
Competition Controlled Pheromone Update for Ant Colony Optimization. ANTS Workshop 2004: 95-105 - [c10]Daniel Merkle, Martin Middendorf, Alexander Scheidler:
Decentralized Packet Clustering in Networks. IPDPS 2004 - 2003
- [j6]Daniel Merkle, Martin Middendorf:
Ant Colony Optimization with Global Pheromone Evaluation for Scheduling a Single Machine. Appl. Intell. 18(1): 105-111 (2003) - [j5]Stefan Janson, Daniel Merkle, Martin Middendorf, Hossam A. ElGindy, Hartmut Schmeck:
On Enforced Convergence of ACO and its Implementation on the Reconfigurable Mesh Architecture Using Size Reduction Tasks. J. Supercomput. 26(3): 221-238 (2003) - 2002
- [b1]Daniel Merkle:
Ameisenalgorithmen: Optimierung und Modellierung. Karlsruhe Institute of Technology, Germany, 2002, pp. 1-212 - [j4]Daniel Merkle, Martin Middendorf:
Modeling the Dynamics of Ant Colony Optimization. Evol. Comput. 10(3): 235-262 (2002) - [j3]Daniel Merkle, Thomas Worsch:
Formal language recognition by stochastic cellular automata. Fundam. Informaticae 52(1-3): 183-201 (2002) - [j2]Daniel Merkle, Martin Middendorf:
Fast Ant Colony Optimization on Runtime Reconfigurable Processor Arrays. Genet. Program. Evolvable Mach. 3(4): 345-361 (2002) - [j1]Daniel Merkle, Martin Middendorf, Hartmut Schmeck:
Ant colony optimization for resource-constrained project scheduling. IEEE Trans. Evol. Comput. 6(4): 333-346 (2002) - [c9]Daniel Merkle, Martin Middendorf:
Modelling ACO: Composed Permutation Problems. Ant Algorithms 2002: 149-162 - [c8]Jürgen Branke, Michael Decker, Daniel Merkle, Hartmut Schmeck:
Coevolutionary Ant Algorithms Playing Games. Ant Algorithms 2002: 298-299 - [c7]Daniel Merkle, Martin Middendorf:
Ant Colony Optimization with the Relative Pheromone Evaluation Method. EvoWorkshops 2002: 325-333 - [c6]Daniel Merkle, Martin Middendorf:
Studies On The Dynamics Of Ant Colony Optimization Algorithms. GECCO 2002: 105-112 - 2001
- [c5]Steffen Iredi, Daniel Merkle, Martin Middendorf:
Bi-Criterion Optimization with Multi Colony Ant Algorithms. EMO 2001: 359-372 - [c4]Daniel Merkle, Martin Middendorf:
A New Approach to Solve Permutation Scheduling Problems with Ant Colony Optimization. EvoWorkshops 2001: 484-494 - [c3]Daniel Merkle, Martin Middendorf:
Fast ant colony optimization on reconfigurable processor arrays. IPDPS 2001: 144 - 2000
- [c2]Daniel Merkle, Martin Middendorf:
An Ant Algorithm with a New Pheromone Evaluation Rule for Total Tardiness Problems. EvoWorkshops 2000: 287-296 - [c1]Daniel Merkle, Martin Middendorf, Hartmut Schmeck:
Ant Colony Optimization for Resource-Constrained Projet Scheduling. GECCO 2000: 893-
Coauthor Index
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from 
to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the 
of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from 
, 
, and 
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from 
.
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-12-02 21:33 CET by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by:
