KAUST researchers are using autonomous gliders in the Red Sea to monitor variables such as temperature, salinity, and chlorophyll, providing continuous, detailed measurements of the sea's physical and biogeochemical processes. These gliders can measure a number of variables, including temperature, salinity, chlorophyll, and concentration of dissolved organic matter. One glider was deployed for three months and monitored the formation of mesoscale eddies and anthropogenic inputs from aquaculture. Why it matters: This technology allows for a more comprehensive understanding of the Red Sea ecosystem and its dynamics, benefiting research and applications such as monitoring the impact of aquaculture, with potential implications for environmental management and sustainable resource utilization.
A glider deployed by KAUST's Coastal and Marine Resources Core Lab (CMOR) completed 1,000 dives in the Red Sea. The dives, completed by November 22, 2015, are part of ongoing marine research at KAUST. The glider is maintained by Lloyd Smith, supervisor of marine electronics at CMOR. Why it matters: This demonstrates KAUST's commitment to environmental monitoring and research in the Red Sea, contributing to a better understanding of the region's unique marine ecosystem.
KAUST researchers are working on solutions to regional and global problems. A KAUST underwater glider completed 1,000 dives in the Red Sea. KAUST was ranked 19th globally in the Nature Index 2016 of top institutions for high-quality science. Why it matters: This illustrates KAUST's commitment to impactful research and its role as a leading scientific institution in the region.
The Autonomous Robotics Research Center (ARRC) at TII won the Nanocopter AI Challenge 2022, part of the International Micro Air Vehicle Conference. The challenge involved developing AI-enabled solutions for Bitcraze’s Crazyflie nanocopters to perform vision-based obstacle avoidance. The ARRC team's nano-drone completed a 110m flight in 5 minutes with no crashes in a dynamic environment. Why it matters: This victory demonstrates the growing expertise in autonomous robotics and AI-powered drone technology within the UAE, with potential applications in search and rescue, industrial inspection, and precision agriculture.
Dr. Jeffrey Schnapp from Harvard University discussed the shift from mobility to movability and human-centric autonomy in robotics at KAUST's 2018 Winter Enrichment Program. He presented Gita, a cargo robot designed to move like humans and support pedestrian lifestyles. Piaggio Fast Forward, Schnapp's company, aims to create robots that coexist with humans and enhance the quality of life in pedestrian-friendly environments. Why it matters: This highlights KAUST's engagement with innovative robotics research and its focus on exploring human-robot interaction for future urban development in Saudi Arabia.
This article summarizes presentations from an internal Quantum Research Center (QRC) workshop at the Technology Innovation Institute (TII). Topics covered included superconducting quantum computers, quantum coherent networks, quantum simulation, and quantum machine learning. Several presentations also discussed experimental quantum technologies. Why it matters: The workshop highlights TII's ongoing research activities in quantum computing and related technologies, signaling its commitment to advancing the field in the UAE.
This paper presents the synthesis of a 1-DoF six-bar gripper mechanism for aerial grasping, designed for a task in the Mohamed Bin Zayed International Robotics Challenge (MBZIRC) 2020. The synthesis process involves selecting the mechanism class, determining the number of links and joints using algebraic methods, and optimizing link dimensions via geometric programming. The gripper was modeled in CAD software, additively manufactured, and mounted on a UAV with a DC motor for gripping spherical objects. Why it matters: The research contributes to advancements in robotics and aerial manipulation, with potential applications in various industries, particularly for tasks requiring remote object retrieval and manipulation.
Prof. Simon Gröblacher from Delft University of Technology presented a seminar on using mechanical systems in quantum information processing, focusing on their potential as quantum memories and transducers. The seminar highlighted experiments demonstrating non-classical behavior of mechanical motion by coupling a micro-fabricated acoustic resonator to single optical photons. Quantum control over acoustic motion was established, including the generation and readout of single phononic excitations, along with light-matter entanglement. Why it matters: This research advances the use of micro-fabricated acoustic resonators for quantum information processing and fundamental tests of quantum physics.