The past several decades revealed a well pronounced trend in geosciences. This trend marks a transition from investigating simpler linear or weakly nonlinear single-disciplinary systems like simplified atmospheric or oceanic systems that include a limited description of the physical processes, to studying complex nonlinear multidisciplinary systems like coupled atmospheric-oceanic climate systems that take into account atmospheric physics, chemistry, land-surface interactions, etc. The most important property of a complex interdisciplinary system is that it consists of subsystems that, by themselves, are complex systems. Accordingly, the scientific and practical significance of interdisciplinary complex geophysical/environmental numerical models has increased tremendously during the last few decades, due to improvements in their quality via developments in numerical modeling and computing capabilities.
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Keywords
- Short Wave Radiation
- Climate Simulation
- Long Wave Radiation
- Outgoing Long Wave Radiation
- Original Parameterization
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
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Krasnopolsky, V.M. (2009). Neural Network Applications to Developing Hybrid Atmospheric and Oceanic Numerical Models. In: Haupt, S.E., Pasini, A., Marzban, C. (eds) Artificial Intelligence Methods in the Environmental Sciences. Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-9119-3_11
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