SAO/NASA ADS Physics Abstract Service
Document Type
Article
Journal/Book Title/Conference
AGU Fall Meeting Abstracts
Publisher
Agu
Publication Date
1-1-2013
First Page
4
Last Page
4
Abstract
This research focuses on using the cloud to address computational challenges associated with hydrologic modeling. One example is calibration of a watershed-scale hydrologic model, which can take days of execution time on typical computers. While parallel algorithms for model calibration exist and some researchers have used multi-core computers or clusters to run these algorithms, these solutions do not fully address the challenge because (i) calibration can still be too time consuming even on multicore personal computers and (ii) few in the community have the time and expertise needed to manage a compute cluster. Given this, another option for addressing this challenge that we are exploring through this work is the use of the cloud for speeding-up calibration of watershed-scale hydrologic models. The cloud used in this capacity provides a means for renting a specific number and type of machines for only the time needed to perform a calibration model run. The cloud allows one to precisely balance the duration of the calibration with the financial costs so that, if the budget allows, the calibration can be performed more quickly by renting more machines. Focusing specifically on the SWAT hydrologic model and a parallel version of the DDS calibration algorithm, we show significant speed-up time across a range of watershed sizes using up to 256 cores to perform a model calibration. The tool provides a simple web-based user interface and the ability to monitor the calibration job submission process during the calibration process. Finally this talk concludes with initial work to leverage the cloud for other tasks associated with hydrologic modeling including tasks related to preparing inputs for constructing place-based hydrologic models.
Recommended Citation
Goodall, Jonathan L.; Ercan, M B.; Castronova, Anthony M.; Humphrey, M; Beekwilder, N; Steele, J; and Kim, I, "SAO/NASA ADS Physics Abstract Service" (2013). Civil and Environmental Engineering Faculty Publications. Paper 1221.
https://digitalcommons.usu.edu/cee_facpub/1221