Multi-Scale Quantitative Precipitation Forecasting Using Nonlinear And Nonstationary Teleconnection Signals And Artificial Neural Network Models
Keywords
Artificial neural networks; Climate change; Forecasting; Precipitation; Sea surface temperature; Teleconnection patterns; Wavelet
Abstract
Global sea surface temperature (SST) anomalies are observed to have a significant effect on terrestrial precipitation patterns throughout the United States. SST variations have been correlated with terrestrial precipitation via ocean–atmospheric interactions known as climate teleconnections. This study demonstrates how the scale effect could affect the forecasting accuracy with or without the inclusion of those newly discovered unknown teleconnection signals between Adirondack precipitation and SST anomaly in the Atlantic and Pacific oceans. Unique SST regions of both known and unknown telecommunication signals were extracted from the wavelet analysis and used as input variables in an artificial neural network (ANN) forecasting model. Monthly and seasonal scales were considered with respect to a host of long-term (30-year) nonlinear and nonstationary teleconnection signals detected locally at the study site of Adirondack. Similar intra-annual time-lag effects of SST on precipitation variability are salient at both time scales. Sensitivity analysis of four scenarios reveals that more improvements of the forecasting accuracy of the ANN model can be observed by including both known and unknown teleconnection patterns at both time scales, although such improvements are not salient. Research findings also highlight the importance of choosing the forecasting model at the seasonal scale to predict more accurate peak values and global trends of terrestrial precipitation in response to teleconnection signals. The scale shift from monthly to seasonal may improve results by 17% and 17 mm/day in terms of R squared and root of mean square error values, respectively, if both known and unknown SST regions are considered for forecasting.
Publication Date
5-1-2017
Publication Title
Journal of Hydrology
Volume
548
Number of Pages
305-321
Document Type
Article
Personal Identifier
scopus
DOI Link
https://doi.org/10.1016/j.jhydrol.2017.03.003
Copyright Status
Unknown
Socpus ID
85015455639 (Scopus)
Source API URL
https://api.elsevier.com/content/abstract/scopus_id/85015455639
STARS Citation
Chang, Ni Bin; Yang, Y. Jeffrey; Imen, Sanaz; and Mullon, Lee, "Multi-Scale Quantitative Precipitation Forecasting Using Nonlinear And Nonstationary Teleconnection Signals And Artificial Neural Network Models" (2017). Scopus Export 2015-2019. 5686.
https://stars.library.ucf.edu/scopus2015/5686