3.9: Computers and Modeling

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The development of computers revolutionized ocean sciences just as it has other aspects of human society. Ocean sciences are particularly dependent on computers for two important functions: analysis and display of the three-dimensional variations in important parameters, and data analysis using mathematical models.

Almost all studies conducted by ocean scientists involve parameters or processes that vary both geographically, with depth, over time. Data of importance to ocean processes must therefore be organized in a three-dimensional framework (four dimensions with time) and displayed visually for analysis and interpretation. Many of the illustrations in this text display data on maps or on vertical map sections. As we discussed earlier in this chapter, the relatively simple seafloor map that Heezen and Tharp generated by hand before the advent of computers was a massive undertaking. Computerized mapping now makes the development of such maps much simpler and quicker, even given the massive amounts of data that can be generated by satellites and automated sensors. Most computerized mapping is now done using Geographic Information Systems (GIS). GIS is designed to store data for any parameter that is collected at a specific location and time—for example, salinity, temperature, phytoplankton concentration, light intensity. The GIS system stores each data point referenced to its geographic coordinates (three-dimensional to include depth, where appropriate) and collection time. Simple-to-use software tools allow data for multiple parameters to be overlaid on each other (spatially and temporally) for comparison and analysis, and for these results to be displayed in a variety of ways.

Ocean sciences are heavily dependent on mathematical modeling, described in CC10, because the processes studied occur on very variable time and space scales, and many processes, especially biological parameters and interactions, are characterized by very limited data. Global climate models, used to investigate ocean-atmosphere interactions, greenhouse-induced global climate change, global weather patterns, and many other questions, rely particularly heavily on computers. As explained in Chapter 8, the scale of water motion in the ocean is one-tenth the scale of atmospheric motions that contribute to weather and climate. Furthermore, oceans are more complex vertically than the atmosphere. As a result, if the ocean part of the global model is to operate effectively, it must be split into smaller model cells and separated into more vertical layers than the atmosphere. Thus, the ocean component of these models can require as much as four orders of magnitude more computer time than the atmospheric component requires. For these models, this complexity is significant because it can take months to run the models through just a few years of simulated climate even on the fastest supercomputers.

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