GPGPU Applications

4TU Delft
4TU Eindhoven
4TU Twente
4TU Wageningen

Graphics processing units (GPUs) initially were designed to support computer graphics. Their specific architecture provides high processing power and massive parallelism, which allows for efficient solving of typical graphics-related tasks. However, soon it was realised that such architectures are also suitable for many other computational tasks, which led to the development of the area of GPGPU (General Purpose GPU) programming. As a result, GPUs are now used in many different fields, including numerical simulation, media processing, medical imaging, eye-tracking, genomics, fluid dynamics, and machine learning.

Complex GPU applications typically need to be programmed at a relatively low level, since they require expert knowledge on the specific hardware used. Given the importance, range and increasing complexity of GPGPU applications today, the main research challenge for GPGPU programming is that we urgently need systematic techniques that can optimise given GPGPU applications without requiring expert knowledge. This would allow GPGPU applications to be developed at a more convenient higher abstraction level. These techniques should offer a predictable performance increase, while preserving the original behaviour.

  • Prof.Dr. Marieke Huisman, Professor UT (Formal Methods and Tools) 
  • Dr. Ing. Anton Wijs,
 Assistant Professor TUE (Software Engineering & Technology)
  • Dr. Ana-Lucia Varbanescu, Assistant Professor UvA (System and Network Engineering), TUD (Distributed Systems)
  • Drs. Sven Warris, Researcher WUR (Applied Bioinformatics)
  • Dr. Ben van Werkhoven, eScience Coordinator Netherlands eScience Center 

For more information, please refer to the website.

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GPGPU Applications

Graphics processing units (GPUs) initially were designed to support computer graphics. Their specific architecture provides high processing power and massive parallelism, which allows for efficient solving of typical graphics-related tasks. However, soon it was realised that such architectures are also suitable for many other computational tasks, which led to the development of the area of GPGPU (General Purpose GPU) programming. As a result, GPUs are now used in many different fields, including numerical simulation, media processing, medical imaging, eye-tracking, genomics, fluid dynamics, and machine learning.

Complex GPU applications typically need to be programmed at a relatively low level, since they require expert knowledge on the specific hardware used. Given the importance, range and increasing complexity of GPGPU applications today, the main research challenge for GPGPU programming is that we urgently need systematic techniques that can optimise given GPGPU applications without requiring expert knowledge. This would allow GPGPU applications to be developed at a more convenient higher abstraction level. These techniques should offer a predictable performance increase, while preserving the original behaviour.

  • Prof.Dr. Marieke Huisman, Professor UT (Formal Methods and Tools) 
  • Dr. Ing. Anton Wijs,
 Assistant Professor TUE (Software Engineering & Technology)
  • Dr. Ana-Lucia Varbanescu, Assistant Professor UvA (System and Network Engineering), TUD (Distributed Systems)
  • Drs. Sven Warris, Researcher WUR (Applied Bioinformatics)
  • Dr. Ben van Werkhoven, eScience Coordinator Netherlands eScience Center 

For more information, please refer to the website.