Abstract
Abstract Seasonal streamflow prediction skill can derive from catchment initial hydrological conditions (IHCs) and from the future seasonal climate forecasts (SCFs) used to produce the hydrological forecasts. Although much effort has gone into producing state-of-the-art seasonal streamflow forecasts from improving IHCs and SCFs, these developments are expensive and time consuming and the forecasting skill is still limited in most parts of the world. Hence, sensitivity analyses are crucial to funnel the resources into useful modeling and forecasting developments. It is in this context that a sensitivity analysis technique, the variational ensemble streamflow prediction assessment (VESPA) approach, was recently introduced. VESPA can be used to quantify the expected improvements in seasonal streamflow forecast skill as a result of realistic improvements in its predictability sources (i.e., the IHCs and the SCFs)—termed “skill elasticity”—and to indicate where efforts should be targeted. The VESPA approach is, however, computationally expensive, relying on multiple hindcasts having varying levels of skill in IHCs and SCFs. This paper presents two approximations of the approach that are computationally inexpensive alternatives. These new methods were tested against the original VESPA results using 30 years of ensemble hindcasts for 18 catchments of the contiguous United States. The results suggest that one of the methods, end point blending, is an effective alternative for estimating the forecast skill elasticities yielded by the VESPA approach. The results also highlight the importance of the choice of verification score for a goal-oriented sensitivity analysis.
Highlights
Unprecedented increases in computer capabilities have shaped the last several decades’advances in Numerical Weather Prediction (NWP), and with them, the development of environmental forecasting and modelling systems
1) Can End Point Interpolation (EPI) and End Point Blending (EPB) discriminate the influence of initial hydrological conditions (IHCs) and seasonal climate forecasts (SCFs) errors on seasonal streamflow forecast uncertainties?
For the first part of this study, the Crystal River (CO; US Geological Survey (USGS) gauge 009081600), a snowmelt driven catchment, will be used as a test case to illustrate the skill surface plots obtained from the EPI and the EPB methods, compared to the variational ensemble streamflow prediction assessment (VESPA) approach
Summary
Advances in Numerical Weather Prediction (NWP), and with them, the development of environmental forecasting and modelling systems This has led to a shift in the strategy of operational forecasting centres towards more integrated modelling and forecasting approaches, such as coupled systems and Earth System Models (ESMs), with the final aim to extend the limits of predictability (i.e., sub-seasonal to seasonal forecasting). These developments are supported by the assimilation of more and better quality observation data as well as the increase in model resolutions and complexity. They are valuable for applications such as reservoir management for hydropower, agriculture and urban water supply, spring flood and drought prediction and navigation, among others
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