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Publications of Author

1. Thomas Fahringer, Eduard Mehofer
   Buffer-Safe Communication Optimization Based on Data Flow Analysis and Performance Prediction. [Citation Graph (0, 0)][DBLP]
   IEEE PACT, 1997, pp:189-200 [Conf]
   
2. Thomas Fahringer, Jun Qin, S. Hainzer
   Specification of grid workflow applications with AGWL: an Abstract Grid Workflow Language. [Citation Graph (0, 0)][DBLP]
   CCGRID, 2005, pp:676-685 [Conf]
   
3. C. Seragiotto, Thomas Fahringer
   Performance analysis for distributed and parallel Java programs with Aksum. [Citation Graph (0, 0)][DBLP]
   CCGRID, 2005, pp:1024-1031 [Conf]
   
4. Hong Linh Truong, Thomas Fahringer, Francesco Nerieri, Schahram Dustdar
   Performance metrics and ontology for describing performance data of grid workflows. [Citation Graph (0, 0)][DBLP]
   CCGRID, 2005, pp:301-308 [Conf]
   
5. Thomas Fahringer, Alexandru Jugravu, Beniamino Di Martino, Salvatore Venticinque, Hans Moritsch
   On the Evaluation of JavaSymphony for Cluster Applications. [Citation Graph (0, 0)][DBLP]
   CLUSTER, 2002, pp:394-0 [Conf]
   
6. Radu Prodan, Thomas Fahringer
   ZENTURIO: An Experiment Management System for Cluster and Grid Computing. [Citation Graph (0, 0)][DBLP]
   CLUSTER, 2002, pp:9-18 [Conf]
   
7. Thomas Fahringer
   Automatically Estimating Network Contention of Parallel Programs. [Citation Graph (0, 0)][DBLP]
   Computer Performance Evaluation, 1994, pp:389-405 [Conf]
   
8. Sabri Pllana, Thomas Fahringer, Johannes Testori, Siegfried Benkner, Ivona Brandic
   Towards an UML Based Graphical Representation of Grid Workflow Applications. [Citation Graph (0, 0)][DBLP]
   European Across Grids Conference, 2004, pp:149-158 [Conf]
   
9. Hong Linh Truong, Thomas Fahringer
   SCALEA-G: A Unified Monitoring and Performance Analysis System for the Grid. [Citation Graph (0, 0)][DBLP]
   European Across Grids Conference, 2004, pp:202-211 [Conf]
   
10. Radu Prodan, Thomas Fahringer
    Optimising Parallel Applications on the Grid Using Irregular Array Distributions. [Citation Graph (0, 0)][DBLP]
    EGC, 2005, pp:527-537 [Conf]
    
11. Mumtaz Siddiqui, Thomas Fahringer
    GridARM: Askalon's Grid Resource Management System. [Citation Graph (0, 0)][DBLP]
    EGC, 2005, pp:122-131 [Conf]
    
12. Rubing Duan, Thomas Fahringer, Radu Prodan, Jun Qin, Alex Villazón, Marek Wieczorek
    Real World Workflow Applications in the Askalon Grid Environment. [Citation Graph (0, 0)][DBLP]
    EGC, 2005, pp:454-463 [Conf]
    
13. Hong Linh Truong, Thomas Fahringer
    Online Performance Monitoring and Analysis of Grid Scientific Workflows. [Citation Graph (0, 0)][DBLP]
    EGC, 2005, pp:1154-1164 [Conf]
    
14. Thomas Fahringer, Wolfgang E. Nagel
    Performance Evaluation and Prediction. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2000, pp:105-107 [Conf]
    
15. Jeffrey K. Hollingsworth, Allen D. Malony, Jesús Labarta, Thomas Fahringer
    Performance Evaluation and Prediction. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2003, pp:87- [Conf]
    
16. Alexandru Jugravu, Thomas Fahringer
    Scheduling Workflow Distributed Applications in JavaSymphony. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2005, pp:272-281 [Conf]
    
17. Allen D. Malony, Thomas Fahringer, Allan Snavely, Luís Silva
    Topic 2 - Performance Prediction and Evaluation. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2005, pp:93- [Conf]
    
18. Hong Linh Truong, Thomas Fahringer
    SCALEA: A Performance Analysis Tool for Distributed and Parallel Programs. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2002, pp:75-85 [Conf]
    
19. Hong Linh Truong, Thomas Fahringer
    On Utilizing Experiment Data Repository for Performance Analysis of Parallel Applications. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2003, pp:27-37 [Conf]
    
20. Hong Linh Truong, Thomas Fahringer
    Soft Computing Approach to Performance Analysis of Parallel and Distributed Programs. [Citation Graph (0, 0)][DBLP]
    Euro-Par, 2005, pp:50-60 [Conf]
    
21. Radu Prodan, Thomas Fahringer
    From Web Services to OGSA: Experiences in Implementing an OGSA-based Grid Application. [Citation Graph (0, 0)][DBLP]
    GRID, 2003, pp:2-9 [Conf]
    
22. Thomas Fahringer, Clovis Seragiotto Jr.
    Automatic Search for Performance Problems in Parallel and Distributed Programs by Using Multi-experiment Analysis. [Citation Graph (0, 0)][DBLP]
    HiPC, 2002, pp:151-162 [Conf]
    
23. Alexandru Jugravu, Thomas Fahringer
    Advanced Resource Management and Scheduling of Workflow Applications in JavaSymphony. [Citation Graph (0, 0)][DBLP]
    HiPC, 2005, pp:235-246 [Conf]
    
24. Alexandru Jugravu, Thomas Fahringer
    On the Implementation of JavaSymphony. [Citation Graph (0, 0)][DBLP]
    HIPS, 2003, pp:34-0 [Conf]
    
25. Peter Brunner, Hong Linh Truong, Thomas Fahringer
    Performance Monitoring and Visualization of Grid Scientific Workflows in ASKALON. [Citation Graph (0, 0)][DBLP]
    HPCC, 2006, pp:170-179 [Conf]
    
26. Rubing Duan, Radu Prodan, Thomas Fahringer
    DEE: A Distributed Fault Tolerant Workflow Enactment Engine for Grid Computing. [Citation Graph (0, 0)][DBLP]
    HPCC, 2005, pp:704-716 [Conf]
    
27. Thomas Fahringer
    Effective Symbolic Analysis to Support Parallelizing Compilers and Performance Analysis. [Citation Graph (0, 0)][DBLP]
    HPCN Europe, 1997, pp:781-790 [Conf]
    
28. Thomas Fahringer
    Estimating Cache Performance for Sequential and Data Parallel Programs. [Citation Graph (0, 0)][DBLP]
    HPCN Europe, 1997, pp:840-849 [Conf]
    
29. Thomas Fahringer, Sabri Pllana, Johannes Testori
    Teuta: Tool Support for Performance Modeling of Distributed and Parallel Applications. [Citation Graph (0, 0)][DBLP]
    International Conference on Computational Science, 2004, pp:456-463 [Conf]
    
30. Thomas Fahringer, Sabri Pllana, Alex Villazón
    A-GWL: Abstract Grid Workflow Language. [Citation Graph (0, 0)][DBLP]
    International Conference on Computational Science, 2004, pp:42-49 [Conf]
    
31. Alexandru Jugravu, Thomas Fahringer
    JavaSymphony, a Programming Model for the Grid. [Citation Graph (0, 0)][DBLP]
    International Conference on Computational Science, 2004, pp:18-25 [Conf]
    
32. Radu Prodan, Andreas Bonelli, Andreas Adelmann, Thomas Fahringer, Christoph Überhuber
    Benchmarking Parallel Three Dimensional FFT Kernels with ZENTURIO. [Citation Graph (0, 0)][DBLP]
    International Conference on Computational Science, 2004, pp:459-466 [Conf]
    
33. Hong Linh Truong, Thomas Fahringer
    Performance Analysis, Data Sharing, and Tools Integration in Grids: New Approach Based on Ontology. [Citation Graph (0, 0)][DBLP]
    International Conference on Computational Science, 2004, pp:424-431 [Conf]
    
34. Thomas Fahringer, Michael Gerndt, Graham D. Riley, Jesper Larsson Träff
    Specification of Performance Problems in MPI Programs with ASL. [Citation Graph (0, 0)][DBLP]
    ICPP, 2000, pp:51-0 [Conf]
    
35. Radu Prodan, Thomas Fahringer
    ZEN: A Directive-Based Language for Automatic Experiment Management of Distributed and Parallel Programs. [Citation Graph (0, 0)][DBLP]
    ICPP, 2002, pp:93-100 [Conf]
    
36. Xian-He Sun, Mario Pantano, Thomas Fahringer
    Performance Range Comparison for Restructuring Compilation. [Citation Graph (0, 0)][DBLP]
    ICPP, 1998, pp:595-0 [Conf]
    
37. Sabri Pllana, Thomas Fahringer
    Performance Prophet: A Performance Modeling and Prediction Tool for Parallel and Distributed Programs. [Citation Graph (0, 0)][DBLP]
    ICPP Workshops, 2005, pp:509-516 [Conf]
    
38. Thomas Fahringer, Roman Blasko, Hans P. Zima
    Automatic performance prediction to support parallelization of Fortran programs for massively parallel systems. [Citation Graph (0, 0)][DBLP]
    ICS, 1992, pp:347-356 [Conf]
    
39. Thomas Fahringer, Matthew Haines, Piyush Mehrotra
    On the Utility of Threads for Data Parallel Programming. [Citation Graph (0, 0)][DBLP]
    International Conference on Supercomputing, 1995, pp:51-59 [Conf]
    
40. Thomas Fahringer, Eduard Mehofer
    Problem and Machine Sensitive Communication Optimization. [Citation Graph (0, 0)][DBLP]
    International Conference on Supercomputing, 1998, pp:117-124 [Conf]
    
41. Thomas Fahringer, Bernhard Scholz
    Symbolic Evaluation for Parallelizing Compilers. [Citation Graph (0, 0)][DBLP]
    International Conference on Supercomputing, 1997, pp:261-268 [Conf]
    
42. Thomas Fahringer, Hans P. Zima
    A Static Parameter Based Performance Prediction Tool for Parallel Programs. [Citation Graph (0, 0)][DBLP]
    International Conference on Supercomputing, 1993, pp:207-219 [Conf]
    
43. Thomas Fahringer
    Toward Symbolic Performance Prediction of Parallel Programs. [Citation Graph (0, 0)][DBLP]
    IPPS, 1996, pp:474-478 [Conf]
    
44. Thomas Fahringer, A. Pozgaj, Hans Moritsch, J. Luitz
    Evaluation of P3T+: A Performance Estimator for Distributed and Parallel Applications. [Citation Graph (0, 0)][DBLP]
    IPDPS, 2000, pp:229-234 [Conf]
    
45. Alexandru Jugravu, Thomas Fahringer
    On the Implementation of JavaSymphony. [Citation Graph (0, 0)][DBLP]
    IPDPS, 2003, pp:129- [Conf]
    
46. Radu Prodan, Thomas Fahringer
    A Web Service-Based Experiment Management System for the Grid. [Citation Graph (0, 0)][DBLP]
    IPDPS, 2003, pp:85- [Conf]
    
47. Xian-He Sun, Mario Pantano, Thomas Fahringer, Zhaohua Zhan
    SCALA: A Framework for Performance Evaluation of Scalable Computing. [Citation Graph (0, 0)][DBLP]
    IPPS/SPDP Workshops, 1999, pp:49-62 [Conf]
    
48. Hong Linh Truong, Thomas Fahringer
    Self-Managing Sensor-Based Middleware for Performance Monitoring and Data Integration in Grids. [Citation Graph (0, 0)][DBLP]
    IPDPS, 2005, pp:- [Conf]
    
49. Thomas Fahringer
    Towards a sophisticated grid workflow development and computing environment. [Citation Graph (0, 0)][DBLP]
    IPDPS, 2006, pp:- [Conf]
    
50. Thomas Fahringer, Michael Gerndt, Graham D. Riley, Jesper Larsson Träff
    On Performance Modeling for HPF Applications with ASL. [Citation Graph (0, 0)][DBLP]
    ISHPC, 2000, pp:191-204 [Conf]
    
51. Thomas Fahringer, Michael Gerndt, Graham D. Riley, Jesper Larsson Träff
    Formalizing OpenMP Performance Properties with ASL. [Citation Graph (0, 0)][DBLP]
    ISHPC, 2000, pp:428-439 [Conf]
    
52. Thomas Fahringer, Alexandru Jugravu
    JavaSymphony: new directives to control and synchronize locality, parallelism, and load balancing for cluster and GRID-computing. [Citation Graph (0, 0)][DBLP]
    Java Grande, 2002, pp:8-17 [Conf]
    
53. Jürgen Hofer, Alex Villazón, Mumtaz Siddiqui, Thomas Fahringer
    The Otho Toolkit: Generating Tailor-made Scientific Grid Application Wrappers. [Citation Graph (0, 0)][DBLP]
    NODe/GSEM, 2005, pp:323-337 [Conf]
    
54. Mumtaz Siddiqui, Thomas Fahringer, Jürgen Hofer, Ioan Toma
    Grid Resource Ontologies and Asymmetric Resource-Correlation. [Citation Graph (0, 0)][DBLP]
    NODe/GSEM, 2005, pp:205-219 [Conf]
    
55. Barbara M. Chapman, Thomas Fahringer, Hans P. Zima
    Automatic Support for Data Distribution on Distributed Memory Multiprocessor Systems. [Citation Graph (0, 0)][DBLP]
    LCPC, 1993, pp:184-199 [Conf]
    
56. Bartosz Balis, Hong Linh Truong, Marian Bubak, Thomas Fahringer, Krzysztof Guzy, Kuba Rozkwitalski
    An Instrumentation Infrastructure for Grid Workflow Applications. [Citation Graph (0, 0)][DBLP]
    OTM Conferences (2), 2006, pp:1305-1314 [Conf]
    
57. Thomas Fahringer, K. Sowa-Pieklo, J. Luitz, Hans Moritsch
    On Using SPiDER to Examine and Debug Real-World Data-Parallel Applications. [Citation Graph (0, 0)][DBLP]
    PaCT, 2001, pp:211-225 [Conf]
    
58. Rocco Aversa, Beniamino Di Martino, Thomas Fahringer, Salvatore Venticinque
    On the Evaluation of the Distributed Objects and Mobile Agents Programming Models for a Distributed Optimization Application. [Citation Graph (0, 0)][DBLP]
    PARA, 2002, pp:233-242 [Conf]
    
59. Thomas Fahringer, Nicola Mazzocca, Massimiliano Rak, Sabri Pllana, Umberto Villano, Georg Madsen
    Performance Modeling of Scientific Applications: Scalability Analysis of LAPW0. [Citation Graph (0, 0)][DBLP]
    PDP, 2003, pp:5-12 [Conf]
    
60. Radu Prodan, Thomas Fahringer, Michael Geissler, Georg Madsen, Franz Franchetti, Hans Moritsch
    On Using ZENTURIO for Performance and Parameter Studies on Cluster and Grid Architectures. [Citation Graph (0, 0)][DBLP]
    PDP, 2003, pp:185-192 [Conf]
    
61. Clovis Seragiotto Jr., Thomas Fahringer, Michael Geissler, Georg Madsen, Hans Moritsch
    On Using Aksum for Semi-Automatically Searching of Performance Problems in Parallel and Distributed Programs. [Citation Graph (0, 0)][DBLP]
    PDP, 2003, pp:385-392 [Conf]
    
62. Bernhard Scholz, Johann Blieberger, Thomas Fahringer
    Symbolic Pointer Analysis for Detecting Memory Leaks. [Citation Graph (0, 0)][DBLP]
    PEPM, 2000, pp:104-113 [Conf]
    
63. Marek Wieczorek, Radu Prodan, Thomas Fahringer
    Comparison of Workflow Scheduling Strategies on the Grid. [Citation Graph (0, 0)][DBLP]
    PPAM, 2005, pp:792-800 [Conf]
    
64. Hong Linh Truong, Bartosz Balis, Marian Bubak, Jakub Dziwisz, Thomas Fahringer, Andreas Hoheisel
    Towards Distributed Monitoring and Performance Analysis Services in the K-WfGrid Project. [Citation Graph (0, 0)][DBLP]
    PPAM, 2005, pp:156-163 [Conf]
    
65. Hong Linh Truong, Thomas Fahringer, Michael Geissler, Georg Madsen
    Performance Analysis for MPI Applications with SCALEA. [Citation Graph (0, 0)][DBLP]
    PVM/MPI, 2002, pp:421-431 [Conf]
    
66. Radu Prodan, Thomas Fahringer
    Dynamic scheduling of scientific workflow applications on the grid: a case study. [Citation Graph (0, 0)][DBLP]
    SAC, 2005, pp:687-694 [Conf]
    
67. Thomas Fahringer, Clovis Seragiotto Jr.
    Modeling and detecting performance problems for distributed and parallel programs with JavaPSL. [Citation Graph (0, 0)][DBLP]
    SC, 2001, pp:35- [Conf]
    
68. Mumtaz Siddiqui, Alex Villazón, Jürgen Hofer, Thomas Fahringer
    GLARE: A Grid Activity Registration, Deployment and Provisioning Framework. [Citation Graph (0, 0)][DBLP]
    SC, 2005, pp:52- [Conf]
    
69. Hong Linh Truong, Thomas Fahringer, Georg Madsen, Allen D. Malony, Hans Moritsch, Sameer Shende
    On using SCALEA for performance analysis of distributed and parallel programs. [Citation Graph (0, 0)][DBLP]
    SC, 2001, pp:34- [Conf]
    
70. Mumtaz Siddiqui, Alex Villazón, Thomas Fahringer
    Grid allocation and reservation - Grid capacity planning with negotiation-based advance reservation for optimized QoS. [Citation Graph (0, 0)][DBLP]
    SC, 2006, pp:103- [Conf]
    
71. Sabri Pllana, Thomas Fahringer
    On Customizing the UML for Modeling Performance-Oriented Applications. [Citation Graph (0, 0)][DBLP]
    UML, 2002, pp:259-274 [Conf]
    
72. Thomas Fahringer, Bernhard Scholz, Xian-He Sun
    Execution-driven performance analysis for distributed and parallel systems. [Citation Graph (0, 0)][DBLP]
    Workshop on Software and Performance, 2000, pp:204-215 [Conf]
    
73. Sabri Pllana, Thomas Fahringer
    Parallel and distributed systems: UML based modeling of performance oriented parallel and distributed applications. [Citation Graph (0, 0)][DBLP]
    Winter Simulation Conference, 2002, pp:497-505 [Conf]
    
74. Thomas Fahringer
    Estimating and Optimizing Performance for Parallel Programs. [Citation Graph (0, 0)][DBLP]
    IEEE Computer, 1995, v:28, n:11, pp:47-56 [Journal]
    
75. Thomas Fahringer
    On estimating the useful work distribution of parallel programs under P3T: a static performance estimator. [Citation Graph (0, 0)][DBLP]
    Concurrency - Practice and Experience, 1996, v:8, n:4, pp:261-282 [Journal]
    
76. Thomas Fahringer, P. Blaha, A. Hössinger, J. Luitz, Eduard Mehofer, Hans Moritsch, Bernhard Scholz
    Development and performance analysis of real-world applications for distributed and parallel architectures. [Citation Graph (0, 0)][DBLP]
    Concurrency and Computation: Practice and Experience, 2001, v:13, n:10, pp:841-868 [Journal]
    
77. Thomas Fahringer, Alexandru Jugravu
    JavaSymphony: a new programming paradigm to control and synchronize locality, parallelism and load balancing for parallel and distributed computing. [Citation Graph (0, 0)][DBLP]
    Concurrency - Practice and Experience, 2005, v:17, n:7-8, pp:1005-1025 [Journal]
    
78. Thomas Fahringer, Alexandru Jugravu, Sabri Pllana, Radu Prodan, Clovis Seragiotto Jr., Hong Linh Truong
    ASKALON: a tool set for cluster and Grid computing. [Citation Graph (0, 0)][DBLP]
    Concurrency - Practice and Experience, 2005, v:17, n:2-4, pp:143-169 [Journal]
    
79. Thomas Fahringer, K. Sowa-Pieklo, Przemyslaw Czerwinski, Peter Brezany, Marian Bubak, Rainer Koppler, Roland Wismüller
    SPiDER - An advanced symbolic debugger for Fortran 90/HPF programs. [Citation Graph (0, 0)][DBLP]
    Concurrency and Computation: Practice and Experience, 2002, v:14, n:2, pp:103-136 [Journal]
    
80. Hong Linh Truong, Thomas Fahringer
    SCALEA: a performance analysis tool for parallel programs. [Citation Graph (0, 0)][DBLP]
    Concurrency and Computation: Practice and Experience, 2003, v:15, n:11-12, pp:1001-1025 [Journal]
    
81. Thomas Fahringer, K. Sowa-Pieklo
    Debugging real-world data-parallel programs with SPiDER. [Citation Graph (0, 0)][DBLP]
    Future Generation Comp. Syst., 2002, v:18, n:6, pp:779-788 [Journal]
    
82. Alexandru Jugravu, Thomas Fahringer
    JavaSymphony, a programming model for the Grid. [Citation Graph (0, 0)][DBLP]
    Future Generation Comp. Syst., 2005, v:21, n:1, pp:239-247 [Journal]
    
83. Radu Prodan, Thomas Fahringer
    ZENTURIO: A Grid Service-Based Tool for Optimising Parallel and Grid Applications. [Citation Graph (0, 0)][DBLP]
    J. Grid Comput., 2004, v:2, n:1, pp:15-29 [Journal]
    
84. Hong Linh Truong, Thomas Fahringer, Schahram Dustdar
    Dynamic Instrumentation, Performance Monitoring and Analysis of Grid Scientific Workflows. [Citation Graph (0, 0)][DBLP]
    J. Grid Comput., 2005, v:3, n:1-2, pp:1-18 [Journal]
    
85. Thomas Fahringer
    Compile-Time Estimation of Communication Costs for Data Parallel Programs. [Citation Graph (0, 0)][DBLP]
    J. Parallel Distrib. Comput., 1996, v:39, n:1, pp:46-65 [Journal]
    
86. Thomas Fahringer, Eduard Mehofer
    Buffer-Safe and Cost-Driven Communication Optimization. [Citation Graph (0, 0)][DBLP]
    J. Parallel Distrib. Comput., 1999, v:57, n:1, pp:33-63 [Journal]
    
87. Radu Prodan, Thomas Fahringer
    ZENTURIO: a grid middleware-based tool for experiment management of parallel and distributed applications. [Citation Graph (0, 0)][DBLP]
    J. Parallel Distrib. Comput., 2004, v:64, n:6, pp:693-707 [Journal]
    
88. Johann Blieberger, Thomas Fahringer, Bernhard Scholz
    Symbolic Cache Analysis for Real-Time Systems. [Citation Graph (0, 0)][DBLP]
    Real-Time Systems, 2000, v:18, n:2/3, pp:181-215 [Journal]
    
89. Marek Wieczorek, Radu Prodan, Thomas Fahringer
    Scheduling of scientific workflows in the ASKALON grid environment. [Citation Graph (0, 0)][DBLP]
    SIGMOD Record, 2005, v:34, n:3, pp:56-62 [Journal]
    
90. Thomas Fahringer, A. Pozgaj
    P^3T+: A performance estimator for distributed and parallel programs. [Citation Graph (0, 0)][DBLP]
    Scientific Programming, 2000, v:8, n:2, pp:73-93 [Journal]
    
91. Hong Linh Truong, Thomas Fahringer
    SCALEA-G: A unified monitoring and performance analysis system for the grid. [Citation Graph (0, 0)][DBLP]
    Scientific Programming, 2004, v:12, n:4, pp:225-237 [Journal]
    
92. Thomas Fahringer
    Efficient Symbolic Analysis for Parallelizing Compilers and Performance Estimators. [Citation Graph (0, 0)][DBLP]
    The Journal of Supercomputing, 1998, v:12, n:3, pp:227-252 [Journal]
    
93. Thomas Fahringer, Bernhard Scholz
    A Unified Symbolic Evaluation Framework for Parallelizing Compilers. [Citation Graph (0, 0)][DBLP]
    IEEE Trans. Parallel Distrib. Syst., 2000, v:11, n:11, pp:1105-1125 [Journal]
    
94. Xian-He Sun, Mario Pantano, Thomas Fahringer
    Integrated Range Comparison for Data-Parallel Compilation Systems. [Citation Graph (0, 0)][DBLP]
    IEEE Trans. Parallel Distrib. Syst., 1999, v:10, n:5, pp:448-458 [Journal]
    
95. Jürgen Hofer, Thomas Fahringer
    Presenting Scientific Legacy Programs as Grid Services via Program Synthesis. [Citation Graph (0, 0)][DBLP]
    e-Science, 2006, pp:34- [Conf]
    
96. Hong Linh Truong, Robert Samborski, Thomas Fahringer
    Towards a Framework for Monitoring and Analyzing QoS Metrics of Grid Services. [Citation Graph (0, 0)][DBLP]
    e-Science, 2006, pp:65- [Conf]
    
97. Hong Linh Truong, Peter Brunner, Thomas Fahringer, Francesco Nerieri, Robert Samborski, Bartosz Balis, Marian Bubak, Kuba Rozkwitalski
    K-WfGrid Distributed Monitoring and Performance Analysis Services for Workflows in the Grid. [Citation Graph (0, 0)][DBLP]
    e-Science, 2006, pp:15- [Conf]
    
98. Francesco Nerieri, Radu Prodan, Thomas Fahringer
    Kalipy: A Tool for Online Performance Analysis of Grid Workflows through Event Correlation. [Citation Graph (0, 0)][DBLP]
    e-Science, 2006, pp:18- [Conf]
    
99. Farrukh Nadeem, Muhammad Murtaza Yousaf, Radu Prodan, Thomas Fahringer
    Soft Benchmarks-Based Application Performance Prediction Using a Minimum Training Set. [Citation Graph (0, 0)][DBLP]
    e-Science, 2006, pp:71- [Conf]
    
100. Marek Wieczorek, Mumtaz Siddiqui, Alex Villazón, Radu Prodan, Thomas Fahringer
     Applying Advance Reservation to Increase Predictability of Workflow Execution on the Grid. [Citation Graph (0, 0)][DBLP]
     e-Science, 2006, pp:82- [Conf]
     
101. Rubing Duan, Radu Prodan, Thomas Fahringer
     Run-time Optimisation of Grid Workflow Applications. [Citation Graph (0, 0)][DBLP]
     GRID, 2006, pp:33-40 [Conf]
     
102. Jürgen Hofer, Thomas Fahringer
     Specification-based Synthesis of Tailor-made Grid Service Wrappers for Scientific Legacy Codes. [Citation Graph (0, 0)][DBLP]
     GRID, 2006, pp:305-306 [Conf]
     
103. Francesco Nerieri, Radu Prodan, Thomas Fahringer, Hong Linh Truong
     Overhead Analysis of Grid Workflow Applications. [Citation Graph (0, 0)][DBLP]
     GRID, 2006, pp:17-24 [Conf]
     
104. Thomas Fahringer, Radu Prodan, Rubing Duan, Francesco Nerieri, Stefan Podlipnig, Jun Qin, Mumtaz Siddiqui, Hong Linh Truong, Alex Villazón, Marek Wieczorek
     ASKALON: a Grid application development and computing environment. [Citation Graph (0, 0)][DBLP]
     GRID, 2005, pp:122-131 [Conf]
     
105. Farrukh Nadeem, Radu Prodan, Thomas Fahringer
     Optimizing Performance of Automatic Training Phase for Application Performance Prediction in the Grid. [Citation Graph (0, 0)][DBLP]
     HPCC, 2007, pp:309-321 [Conf]
     
106. Jürgen Hofer, Thomas Fahringer
     Grid Application Fault Diagnosis Using Wrapper Services and Machine Learning. [Citation Graph (0, 0)][DBLP]
     ICSOC, 2007, pp:233-244 [Conf]
     
107. Thomas Fahringer
     Symbolic expression evaluation to support parallelizing compilers. [Citation Graph (0, 0)][DBLP]
     PDP, 1997, pp:173-180 [Conf]
     
108. Thomas Fahringer, Christoph Anthes, Alexis Arragon, Arton Lipaj, Jens Müller-Iden, Christopher J. Rawlings, Radu Prodan, Mike Surridge
     The edutain@grid Project. [Citation Graph (0, 0)][DBLP]
     GECON, 2007, pp:182-187 [Conf]
     
109. Hong Linh Truong, Schahram Dustdar, Thomas Fahringer
     Performance metrics and ontologies for Grid workflows. [Citation Graph (0, 0)][DBLP]
     Future Generation Comp. Syst., 2007, v:23, n:6, pp:760-772 [Journal]
     
110. 
     Synthesizing Byzantine Fault-Tolerant Grid Application Wrapper Services. [Citation Graph (, )][DBLP]
     
     
111. 
     Bi-criteria Scheduling of Scientific Workflows for the Grid. [Citation Graph (, )][DBLP]
     
     
112. 
     Characterizing, Modeling and Predicting Dynamic Resource Availability in a Large Scale Multi-purpose Grid. [Citation Graph (, )][DBLP]
     
     
113. 
     Using Templates to Predict Execution Time of Scientific Workflow Applications in the Grid. [Citation Graph (, )][DBLP]
     
     
114. 
     A Hybrid Intelligent Method for Performance Modeling and Prediction of Workflow Activities in Grids. [Citation Graph (, )][DBLP]
     
     
115. 
     Identification, Modelling and Prediction of Non-periodic Bursts in Workloads. [Citation Graph (, )][DBLP]
     
     
116. 
     Dynamic load management for MMOGs in distributed environments. [Citation Graph (, )][DBLP]
     
     
117. 
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