Transforming the sensing and numerical prediction of high-impact local weather through dynamic adaptation

Abstract: Mesoscale weather, such as convective systems, intense local rainfall resulting in flash floods and lake effect snows, frequently is characterized by unpredictable rapid onset and evolution, heterogeneity and spatial and temporal intermittency. Ironically, most of the technologies used to observe the atmosphere, predict its evolution and compute, transmit or store information about it, operate in a static pre-scheduled framework that is fundamentally inconsistent with, and does not accommodate, the dynamic beh… Show more

“…Weather forecasting and seasonal climate prediction are initial-value problems, while long-term climate prediction is a boundary-value problem, and the computing challenges are somewhat different. This difference is well illustrated by Droegemeier (2009), who shows a set of examples that bring together observations and advanced models in real time to improve predictions. Along with many other papers in this issue, he uses computing clusters to speed up modelling.…”

“…This difference is well illustrated by Droegemeier (2009), who shows a set of examples that bring together observations and advanced models in real time to improve predictions. Along with many other papers in this issue, he uses computing clusters to speed up modelling.…”

The environmental eScience revolution

“…Weather forecasting and seasonal climate prediction are initial-value problems, while long-term climate prediction is a boundary-value problem, and the computing challenges are somewhat different. This difference is well illustrated by Droegemeier (2009), who shows a set of examples that bring together observations and advanced models in real time to improve predictions. Along with many other papers in this issue, he uses computing clusters to speed up modelling.…”

“…This difference is well illustrated by Droegemeier (2009), who shows a set of examples that bring together observations and advanced models in real time to improve predictions. Along with many other papers in this issue, he uses computing clusters to speed up modelling.…”

The environmental eScience revolution

“…The successes of eScience and grid computing have tended to focus on large projects with coordinated infrastructure, such as in the work of Droegemeier (2009). The Wikipedia definition of eScience notes: 'Due to the complexity of the software and the backend infrastructural requirements, eScience projects usually involve large teams managed and developed by research laboratories, large universities or governments'.…”

The evolution of the Web and implications for eResearch

The World at One's Fingertips: Interactive Interpretation of Environmental Data