KAUST's Visualization Core Lab (KVL) has released inshimtu, a pseudo in situ visualization system for scientists working with large datasets and supercomputer simulations. Inshimtu simplifies the implementation of in situ visualization by using existing simulation output files without requiring changes to the simulation code. It helps scientists determine if implementing a full in situ visualization into their code is worthwhile. Why it matters: This open-source tool can improve the efficiency of supercomputing research in the region by allowing researchers to assess the value of in situ visualization before fully committing to it.
KAUST's Visual Computing Center (VCC) hosted an Open House event on March 28, showcasing its interdisciplinary research in visual computing. Demonstrations included a virtual reality driving simulator by FalconViz, intended for driver education in Saudi Arabia. Researchers also presented a drone trained to autonomously navigate race courses and a neural network for autonomous driving using image-based technology without GPS. Why it matters: The VCC's work highlights KAUST's role in advancing visual computing applications relevant to Saudi Arabia, from driver training to autonomous systems.
KAUST's Visual Computing Center had two papers recognized at IEEE VIS 2023. One paper, from Prof. Markus Hadwiger's group, introduced a new method for detecting and visualizing vortex structures in 2D fluid flows, which was recognized as one of the best papers. The second paper, from Prof. Ivan Viola's team, presented Dr. KID, a visualization framework for physicalizing biological structures into 3D-printed models, receiving an honorable mention. Why it matters: These awards highlight KAUST's contributions to cutting-edge visualization techniques with potential applications in diverse scientific and engineering fields.
KAUST's Technology Transfer and Innovation (TTI) department has facilitated the release of KUBE, an open-source benchmarking framework developed by Craig Kapfer and his team. KUBE allows users to analyze the performance of software applications and high-performance computing (HPC) systems over time, using user-defined metrics. The software integrates with batch scheduling tools and provides historical time reporting and visualization capabilities. Why it matters: This release provides a valuable tool for optimizing applications and systems, potentially enhancing research and development in computational labs and computing centers in Saudi Arabia and beyond.
KAUST researchers used the Shaheen XC40 supercomputer to simulate airflow around a McLaren 17D Formula One front wing endplate. They then 3D printed the wing with colored flow patterns to visualize key aerodynamic features. The team combined expertise from the Extreme Computing Research Center (ECRC), the Advanced Algorithm and Numerical Simulations Lab (AANSLab), and the Prototyping and Product Development Core Lab (PCL). Why it matters: This project showcases KAUST's supercomputing and 3D printing capabilities for advanced engineering applications, potentially impacting fields beyond Formula One aerodynamics.