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2020 – today
- 2024
- [j45]Tobias Harks, Anja Schedel:
Stackelberg pricing games with congestion effects. Math. Program. 203(1): 763-799 (2024) - [c44]Tobias Harks, Sven Jäger, Michael Markl, Philine Schiewe:
Computing User Equilibria for Schedule-Based Transit Networks with Hard Vehicle Capacities. ATMOS 2024: 17:1-17:17 - [c43]José Correa, Tobias Harks, Anja Schedel, José Verschae:
Equilibrium Dynamics in Market Games with Exchangeable and Divisible Resources. SODA 2024: 547-568 - [i33]Tobias Harks, Sven Jäger, Michael Markl, Philine Schiewe:
Computing User Equilibria for Schedule-Based Transit Networks with Hard Vehicle Capacities. CoRR abs/2406.17153 (2024) - [i32]Lukas Graf, Tobias Harks, Julian Schwarz:
A Decomposition Theorem for Dynamic Flows. CoRR abs/2407.04761 (2024) - [i31]Lukas Graf, Tobias Harks, Michael Markl:
Stochastic Prediction Equilibrium for Dynamic Traffic Assignment. CoRR abs/2409.12650 (2024) - 2023
- [j44]Lukas Graf, Tobias Harks, Kostas Kollias, Michael Markl:
Prediction Equilibrium for Dynamic Network Flows. J. Mach. Learn. Res. 24: 310:1-310:33 (2023) - [j43]Lukas Graf, Tobias Harks:
A finite time combinatorial algorithm for instantaneous dynamic equilibrium flows. Math. Program. 197(2): 761-792 (2023) - [j42]Tobias Harks, Julian Schwarz:
A Unified Framework for Pricing in Nonconvex Resource Allocation Games. SIAM J. Optim. 33(2): 1223-1249 (2023) - [c42]Lukas Graf, Tobias Harks:
Side-Constrained Dynamic Traffic Equilibria. EC 2023: 814 - 2022
- [j41]Tobias Harks, Veerle Timmermans:
Equilibrium computation in resource allocation games. Math. Program. 194(1): 1-34 (2022) - [j40]Tobias Harks, Veerle Timmermans:
Correction to: Equilibrium computation in resource allocation games. Math. Program. 194(1): 35-40 (2022) - [j39]Kai-Simon Goetzmann, Tobias Harks, Max Klimm:
Correction to: Broadcasting a file in a communication network. J. Sched. 25(2): 257 (2022) - [c41]Lukas Graf, Tobias Harks, Kostas Kollias, Michael Markl:
Machine-Learned Prediction Equilibrium for Dynamic Traffic Assignment. AAAI 2022: 5059-5067 - [c40]Tobias Harks, Mona Henle, Max Klimm, Jannik Matuschke, Anja Schedel:
Multi-Leader Congestion Games with an Adversary. AAAI 2022: 5068-5075 - [c39]Lukas Graf, Tobias Harks, Prashant Palkar:
Dynamic Traffic Assignment for Electric Vehicles. ATMOS 2022: 6:1-6:15 - [i30]Lukas Graf, Tobias Harks, Prashant Palkar:
Dynamic Traffic Assignment for Electric Vehicles. CoRR abs/2207.04454 (2022) - [i29]Lukas Graf, Tobias Harks:
Side-Constrained Dynamic Traffic Equilibria. CoRR abs/2211.03194 (2022) - 2021
- [j38]Tobias Harks, Max Klimm, Jannik Matuschke:
Pure Nash Equilibria in Resource Graph Games. J. Artif. Intell. Res. 72: 185-213 (2021) - [j37]Tobias Harks, Martin Hoefer, Anja Schedel, Manuel Surek:
Efficient Black-Box Reductions for Separable Cost Sharing. Math. Oper. Res. 46(1): 134-158 (2021) - [j36]Giorgos Christodoulou, Tobias Harks:
Introduction to the Special Issue on WINE'18: Part 1. ACM Trans. Economics and Comput. 9(1): 1:1 (2021) - [j35]Giorgos Christodoulou, Tobias Harks:
Introduction to the Special Issue on WINE'18: Part 2. ACM Trans. Economics and Comput. 9(2): 8:1 (2021) - [c38]Lukas Graf, Tobias Harks:
A Finite Time Combinatorial Algorithm for Instantaneous Dynamic Equilibrium Flows. IPCO 2021: 104-118 - [c37]Tobias Harks, Julian Schwarz:
Generalized Nash Equilibrium Problems with Mixed-Integer Variables. WINE 2021: 552 - [i28]Tobias Harks, Julian Schwarz:
Generalized Nash Equilibrium Problems with Mixed-Integer Variables. CoRR abs/2107.13298 (2021) - [i27]Lukas Graf, Tobias Harks, Kostas Kollias, Michael Markl:
Machine-Learned Prediction Equilibrium for Dynamic Traffic Assignment. CoRR abs/2109.06713 (2021) - [i26]Tobias Harks, Mona Henle, Max Klimm, Jannik Matuschke, Anja Schedel:
Multi-Leader Congestion Games with an Adversary. CoRR abs/2112.07435 (2021) - 2020
- [j34]Lukas Graf, Tobias Harks, Leon Sering:
Dynamic flows with adaptive route choice. Math. Program. 183(1): 309-335 (2020) - [j33]Kai-Simon Goetzmann, Tobias Harks, Max Klimm:
Broadcasting a file in a communication network. J. Sched. 23(2): 211-232 (2020) - [c36]Lukas Graf, Tobias Harks:
The Price of Anarchy for Instantaneous Dynamic Equilibria. WINE 2020: 237-251 - [e2]Tobias Harks, Max Klimm:
Algorithmic Game Theory - 13th International Symposium, SAGT 2020, Augsburg, Germany, September 16-18, 2020, Proceedings. Lecture Notes in Computer Science 12283, Springer 2020, ISBN 978-3-030-57979-1 [contents] - [i25]Lukas Graf, Tobias Harks:
The Price of Anarchy for Instantaneous Dynamic Equilibria. CoRR abs/2007.07794 (2020) - [i24]Lukas Graf, Tobias Harks:
A Finite Time Combinatorial Algorithm for Instantaneous Dynamic Equilibrium Flows. CoRR abs/2007.07808 (2020) - [i23]Tobias Harks, Max Klimm, Jannik Matuschke:
Pure Nash Equilibria in Resource Graph Games. CoRR abs/2007.09017 (2020)
2010 – 2019
- 2019
- [j32]Tobias Harks, Marc Schröder, Dries Vermeulen:
Toll caps in privatized road networks. Eur. J. Oper. Res. 276(3): 947-956 (2019) - [j31]Tobias Harks, Anja Schedel, Manuel Surek:
A Characterization of Undirected Graphs Admitting Optimal Cost Shares. SIAM J. Discret. Math. 33(4): 1932-1996 (2019) - [c35]Lukas Graf, Tobias Harks:
Dynamic Flows with Adaptive Route Choice. IPCO 2019: 219-232 - [c34]Tobias Harks, Anja Schedel:
Capacity and Price Competition in Markets with Congestion Effects. WINE 2019: 341 - [i22]Tobias Harks, Anja Schedel:
Capacity and Price Competition in Markets with Congestion Effects. CoRR abs/1905.05683 (2019) - [i21]Tobias Harks:
Pricing in Resource Allocation Games Based on Duality Gaps. CoRR abs/1907.01976 (2019) - 2018
- [j30]Tobias Harks, Veerle Timmermans:
Uniqueness of equilibria in atomic splittable polymatroid congestion games. J. Comb. Optim. 36(3): 812-830 (2018) - [j29]Tobias Harks, Max Klimm, Manuel Schneider:
Bottleneck routing with elastic demands. Oper. Res. Lett. 46(1): 93-98 (2018) - [j28]Tobias Harks, Max Klimm, Britta Peis:
Sensitivity Analysis for Convex Separable Optimization Over Integral Polymatroids. SIAM J. Optim. 28(3): 2222-2245 (2018) - [j27]Tobias Harks, Britta Peis, Daniel Schmand, Bjoern Tauer, Laura Vargas Koch:
Competitive Packet Routing with Priority Lists. ACM Trans. Economics and Comput. 6(1): 4:1-4:26 (2018) - [c33]Tobias Harks, Martin Hoefer, Anja Huber, Manuel Surek:
Efficient Black-Box Reductions for Separable Cost Sharing. ICALP 2018: 154:1-154:15 - [e1]George Christodoulou, Tobias Harks:
Web and Internet Economics - 14th International Conference, WINE 2018, Oxford, UK, December 15-17, 2018, Proceedings. Lecture Notes in Computer Science 11316, Springer 2018, ISBN 978-3-030-04611-8 [contents] - [i20]Tobias Harks, Martin Hoefer, Anja Huber, Manuel Surek:
Efficient Black-Box Reductions for Separable Cost Sharing. CoRR abs/1802.10351 (2018) - [i19]Tobias Harks, Marc Schröder, Dries Vermeulen:
Toll Caps in Privatized Road Networks. CoRR abs/1802.10514 (2018) - [i18]Tobias Harks, Veerle Timmermans:
Computing Equilibria in Atomic Splittable Polymatroid Congestion Games with Convex Costs. CoRR abs/1808.04712 (2018) - [i17]Lukas Graf, Tobias Harks:
Dynamic Flows with Adaptive Route Choice. CoRR abs/1811.07381 (2018) - [i16]Roberto Cominetti, Tobias Harks, Carolina Osorio, Britta Peis:
Dynamic Traffic Models in Transportation Science (Dagstuhl Seminar 18102). Dagstuhl Reports 8(3): 21-38 (2018) - 2017
- [j26]José Correa, Tobias Harks, Vincent J. C. Kreuzen, Jannik Matuschke:
Fare Evasion in Transit Networks. Oper. Res. 65(1): 165-183 (2017) - [j25]Satoru Fujishige, Michel X. Goemans, Tobias Harks, Britta Peis, Rico Zenklusen:
Matroids Are Immune to Braess' Paradox. Math. Oper. Res. 42(3): 745-761 (2017) - [j24]Martin Gairing, Tobias Harks, Max Klimm:
Complexity and Approximation of the Continuous Network Design Problem. SIAM J. Optim. 27(3): 1554-1582 (2017) - [c32]Tobias Harks, Veerle Timmermans:
Equilibrium Computation in Atomic Splittable Singleton Congestion Games. IPCO 2017: 442-454 - [c31]Tobias Harks, Anja Huber, Manuel Surek:
A Characterization of Undirected Graphs Admitting Optimal Cost Shares. WINE 2017: 237-251 - [i15]Tobias Harks, Anja Huber, Manuel Surek:
A Characterization of Undirected Graphs Admitting Optimal Cost Shares. CoRR abs/1704.01983 (2017) - 2016
- [j23]André Berger, James Gross, Tobias Harks, Simon Tenbusch:
Constrained Resource Assignments: Fast Algorithms and Applications in Wireless Networks. Manag. Sci. 62(7): 2070-2089 (2016) - [j22]Tobias Harks, Max Klimm:
Congestion Games with Variable Demands. Math. Oper. Res. 41(1): 255-277 (2016) - [j21]Tobias Harks, Tim Oosterwijk, Tjark Vredeveld:
A logarithmic approximation for polymatroid congestion games. Oper. Res. Lett. 44(6): 712-717 (2016) - [j20]Tobias Harks, Philipp von Falkenhausen:
Robust Quantitative Comparative Statics for a Multimarket Paradox. ACM Trans. Economics and Comput. 5(1): 3:1-3:22 (2016) - [j19]Tobias Harks, Martin Hoefer, Kevin Schewior, Alexander Skopalik:
Routing Games With Progressive Filling. IEEE/ACM Trans. Netw. 24(4): 2553-2562 (2016) - [j18]Tobias Harks, Felix G. König, Jannik Matuschke, Alexander T. Richter, Jens Schulz:
An Integrated Approach to Tactical Transportation Planning in Logistics Networks. Transp. Sci. 50(2): 439-460 (2016) - [c30]Tobias Harks, Veerle Timmermans:
Uniqueness of Equilibria in Atomic Splittable Polymatroid Congestion Games. ISCO 2016: 98-109 - [c29]Tobias Harks, Britta Peis, Daniel Schmand, Laura Vargas Koch:
Competitive Packet Routing with Priority Lists. MFCS 2016: 49:1-49:14 - [i14]Tobias Harks, Max Klimm, Britta Peis:
Sensitivity Analysis for Convex Separable Optimization over Integral Polymatroids. CoRR abs/1611.05372 (2016) - [i13]Veerle Timmermans, Tobias Harks:
Equilibrium Computation in Atomic Splittable Singleton Congestion Games. CoRR abs/1612.00190 (2016) - 2015
- [j17]Dimitris Fotakis, Tobias Harks:
Preface to Special Issue on Algorithmic Game Theory - Dedicated to the Memory of Berthold Vöcking. Theory Comput. Syst. 57(3): 673-680 (2015) - [j16]Tobias Harks, Ingo Kleinert, Max Klimm, Rolf H. Möhring:
Computing network tolls with support constraints. Networks 65(3): 262-285 (2015) - [j15]Satoru Fujishige, Michel X. Goemans, Tobias Harks, Britta Peis, Rico Zenklusen:
Congestion games viewed from M-convexity. Oper. Res. Lett. 43(3): 329-333 (2015) - [c28]Tobias Harks, Max Klimm, Manuel Schneider:
Bottleneck Routing with Elastic Demands. WINE 2015: 384-397 - [p1]Tobias Harks, Britta Peis:
Resource Buying Games. Gems of Combinatorial Optimization and Graph Algorithms 2015: 103-111 - [i12]Satoru Fujishige, Michel X. Goemans, Tobias Harks, Britta Peis, Rico Zenklusen:
Matroids are Immune to Braess Paradox. CoRR abs/1504.07545 (2015) - [i11]Tobias Harks, Veerle Timmermans:
Uniqueness of Equilibria in Atomic Splittable Polymatroid Congestion Games. CoRR abs/1512.01375 (2015) - [i10]José R. Correa, Tobias Harks, Kai Nagel, Britta Peis, Martin Skutella:
Dynamic Traffic Models in Transportation Science (Dagstuhl Seminar 15412). Dagstuhl Reports 5(10): 19-34 (2015) - 2014
- [j14]Tobias Harks, Britta Peis:
Resource Buying Games. Algorithmica 70(3): 493-512 (2014) - [j13]Tobias Harks, Philipp von Falkenhausen:
Optimal cost sharing for capacitated facility location games. Eur. J. Oper. Res. 239(1): 187-198 (2014) - [c27]Martin Gairing, Tobias Harks, Max Klimm:
Complexity and Approximation of the Continuous Network Design Problem. APPROX-RANDOM 2014: 226-241 - [c26]Tobias Harks, Martin Hoefer, Kevin Schewior, Alexander Skopalik:
Routing games with progressive filling. INFOCOM 2014: 352-360 - [c25]Tobias Harks, Max Klimm:
Multimarket Oligopolies with Restricted Market Access. SAGT 2014: 182-193 - [c24]Tobias Harks, Max Klimm, Britta Peis:
Resource Competition on Integral Polymatroids. WINE 2014: 189-202 - [i9]José R. Correa, Tobias Harks, Vincent J. C. Kreuzen, Jannik Matuschke:
Fare Evasion in Transit Networks. CoRR abs/1405.2826 (2014) - [i8]Tobias Harks, Max Klimm, Britta Peis:
Resource Competition on Integral Polymatroids. CoRR abs/1407.7650 (2014) - 2013
- [j12]Tobias Harks, Max Klimm, Rolf H. Möhring:
Strong equilibria in games with the lexicographical improvement property. Int. J. Game Theory 42(2): 461-482 (2013) - [j11]Philipp von Falkenhausen, Tobias Harks:
Optimal Cost Sharing for Resource Selection Games. Math. Oper. Res. 38(1): 184-208 (2013) - [j10]Tobias Harks, Martin Hoefer, Max Klimm, Alexander Skopalik:
Computing pure Nash and strong equilibria in bottleneck congestion games. Math. Program. 141(1-2): 193-215 (2013) - [j9]Tobias Harks, Felix G. König, Jannik Matuschke:
Approximation Algorithms for Capacitated Location Routing. Transp. Sci. 47(1): 3-22 (2013) - [c23]Tobias Harks, Philipp von Falkenhausen:
Quantitative Comparative Statics for a Multimarket Paradox. WINE 2013: 230-231 - [i7]Philipp von Falkenhausen, Tobias Harks:
Optimal cost sharing for capacitated facility location games. CTW 2013: 99-102 - [i6]Martin Gairing, Tobias Harks, Max Klimm:
Complexity and Approximation of the Continuous Network Design Problem. CoRR abs/1307.4258 (2013) - [i5]Tobias Harks, Philipp von Falkenhausen:
Quantitative Comparative Statics for a Multimarket Paradox. CoRR abs/1307.5617 (2013) - [i4]Tobias Harks, Martin Hoefer, Kevin Schewior, Alexander Skopalik:
Routing Games with Progressive Filling. CoRR abs/1308.3161 (2013) - 2012
- [j8]Tobias Harks, Max Klimm:
On the Existence of Pure Nash Equilibria in Weighted Congestion Games. Math. Oper. Res. 37(3): 419-436 (2012) - [c22]Tobias Harks, Britta Peis:
Resource Buying Games. ESA 2012: 563-574 - [i3]Tobias Harks, Britta Peis:
Resource Buying Games. CoRR abs/1204.4111 (2012) - 2011
- [j7]Tobias Harks, Konstantin Miller:
The Worst-Case Efficiency of Cost Sharing Methods in Resource Allocation Games. Oper. Res. 59(6): 1491-1503 (2011) - [j6]Tobias Harks:
Stackelberg Strategies and Collusion in Network Games with Splittable Flow. Theory Comput. Syst. 48(4): 781-802 (2011) - [j5]Tobias Harks, Max Klimm, Rolf H. Möhring:
Characterizing the Existence of Potential Functions in Weighted Congestion Games. Theory Comput. Syst. 49(1): 46-70 (2011) - [c21]Kai-Simon Goetzmann, Tobias Harks, Max Klimm, Konstantin Miller:
Optimal File Distribution in Peer-to-Peer Networks. ISAAC 2011: 210-219 - [c20]Philipp von Falkenhausen, Tobias Harks:
Optimal cost sharing protocols for scheduling games. EC 2011: 285-294 - [c19]Tobias Harks, Max Klimm:
Congestion games with variable demands. TARK 2011: 111-120 - [c18]Tobias Harks, Max Klimm:
Demand Allocation Games: Integrating Discrete and Continuous Strategy Spaces. WINE 2011: 194-205 - 2010
- [j4]Vincenzo Bonifaci, Tobias Harks, Guido Schäfer:
Stackelberg Routing in Arbitrary Networks. Math. Oper. Res. 35(2): 330-346 (2010) - [c17]Tobias Harks, Martin Hoefer, Max Klimm, Alexander Skopalik:
Computing Pure Nash and Strong Equilibria in Bottleneck Congestion Games. ESA (2) 2010: 29-38 - [c16]Tobias Harks, Max Klimm:
On the Existence of Pure Nash Equilibria in Weighted Congestion Games. ICALP (1) 2010: 79-89 - [c15]André Berger, James Gross, Tobias Harks:
The k-Constrained Bipartite Matching Problem: Approximation Algorithms and Applications to Wireless Networks. INFOCOM 2010: 2043-2051 - [i2]Tobias Harks, Max Klimm:
Congestion Games with Variable Demands. CoRR abs/1012.1938 (2010)
2000 – 2009
- 2009
- [j3]Tobias Harks, Stefan Heinz, Marc E. Pfetsch:
Competitive Online Multicommodity Routing. Theory Comput. Syst. 45(3): 533-554 (2009) - [c14]Tobias Harks, Konstantin Miller:
Efficiency and stability of Nash equilibria in resource allocation games. GAMENETS 2009: 393-402 - [c13]Tobias Harks, Max Klimm, Rolf H. Möhring:
Characterizing the Existence of Potential Functions in Weighted Congestion Games. SAGT 2009: 97-108 - [c12]Tobias Harks, Max Klimm, Rolf H. Möhring:
Strong Nash Equilibria in Games with the Lexicographical Improvement Property. WINE 2009: 463-470 - [i1]Tobias Harks, Max Klimm, Rolf H. Möhring:
Strong Nash Equilibria in Games with the Lexicographical Improvement Property. CoRR abs/0909.0347 (2009) - 2008
- [j2]Tobias Harks, Tobias Poschwatta:
Congestion control in utility fair networks. Comput. Networks 52(15): 2947-2960 (2008) - [j1]Ariffin Datuk Yahaya, Tobias Harks, Tatsuya Suda:
iREX: efficient automation architecture for the deployment of inter-domain QoS policy. IEEE Trans. Netw. Serv. Manag. 5(1): 50-64 (2008) - [c11]Konstantin Miller, Tobias Harks:
Utility Max-Min Fair Congestion Control with Time-Varying Delays. INFOCOM 2008: 331-335 - [c10]Tobias Harks:
Stackelberg Strategies and Collusion in Network Games with Splittable Flow. WAOA 2008: 133-146 - [c9]Vincenzo Bonifaci, Tobias Harks, Guido Schäfer:
Stackelberg Routing in Arbitrary Networks. WINE 2008: 239-250 - 2007
- [c8]Tobias Harks, László A. Végh:
Nonadaptive Selfish Routing with Online Demands. CAAN 2007: 27-45 - 2006
- [c7]Tobias Harks, Tobias Poschwatta:
On user strategies in a network implementing congestion pricing. CCNC 2006: 681-685 - [c6]Ariffin Datuk Yahaya, Tobias Harks, Tatsuya Suda:
iREX: Efficient Inter-Domain QoS Policy Architecture. GLOBECOM 2006 - [c5]Tobias Harks, Tobias Poschwatta:
Utility Fair Congestion Control for Real-Time Traffic. INFOCOM 2006 - [c4]Tobias Harks, Stefan Heinz, Marc E. Pfetsch:
Competitive Online Multicommodity Routing. WAOA 2006: 240-252 - 2005
- [c3]Tobias Harks, Tobias Poschwatta:
Priority Pricing in Utility Fair Networks. ICNP 2005: 311-320 - [c2]Tobias Harks, Tobias Poschwatta:
Utility fair congestion control for real-time traffic. INFOCOM 2005: 2786-2791 - [c1]Tobias Harks:
Utility Proportional Fair Bandwidth Allocation: An Optimization Oriented Approach. QoS-IP 2005: 61-74
Coauthor Index
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