Improving the real-time probabilistic channel flood forecasting by incorporating the uncertainty of inflow using the particle filter

Xu, Xingya; Zhang, Xuesong; Fang, Hongwei; Lai, Ruixun; Zhang, Yuefeng; Huang, Lei; Liu, Xiaobo

doi:10.1007/s42241-018-0110-x

Improving the real-time probabilistic channel flood forecasting by incorporating the uncertainty of inflow using the particle filter

Journal Article · Mon Oct 01 00:00:00 EDT 2018 · Journal of Hydrodynamics

DOI:https://doi.org/10.1007/s42241-018-0110-x· OSTI ID:1558415

Xu, Xingya ^[1]; ^[2]; Fang, Hongwei ^[3]; Lai, Ruixun ^[4]; Zhang, Yuefeng ^[3]; Huang, Lei ^[3]; Liu, Xiaobo ^[5]

UNIVERSITY PROGRAMS
BATTELLE (PACIFIC NW LAB)
Tsinghua University
Yellow River Institute of Hydraulic Research, China
Department of Water Environment, China Institute of Water Resources and Hydropower Research, Beijing

An accurate and reliable real-time flood forecast is crucial for mitigating flood disasters. The errors associated with the inflow boundary forcing data are considered as an important source of uncertainties in hydraulic model. In this paper, a real-time probabilistic channel flood forecasting model is developed with a novel function to incorporate the uncertainty of the forcing inflow. This new approach couples a hydraulic model with the particle filter (PF) data assimilation algorithm, a sequential Bayesian Monte Carlo method. The stage observations at hydrological stations are assimilated at each time step to update the model states in order to improve the next time step’s forecasting. This new approach is tested against a real flood event occurred in the upper Yangtze River. As compared with the open loop simulations, the evaluations of model performance with several deterministic and probabilistic metrics indicate that the accuracy of the ensemble mean prediction and the reliability of the uncertainty quantification are improved pronouncedly as a result of the PF assimilation. Further assessment of the prediction results at different lead times shows that the improvement of model performance deteriorates with the increase of the lead time due to the gradual diminishing of the updating effect for the initial conditions. Based on the analyses of the number of particles and the assimilation frequency, we find that the optimal number of particles can be determined by balancing the model performance and the computation cost, while a high assimilation frequency is preferred to incorporate the emerging observations to update the model states to match the real conditions.

Research Organization:: Pacific Northwest National Laboratory (PNNL), Richland, WA (United States)

Sponsoring Organization:: USDOE

DOE Contract Number:: AC05-76RL01830

OSTI ID:: 1558415

Report Number(s):: PNNL-SA-124747

Journal Information:: Journal of Hydrodynamics, Journal Name: Journal of Hydrodynamics Journal Issue: 5 Vol. 30

Country of Publication:: United States

Language:: English

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