Aymn Elhaddad scite author profile

Abstract. Characterization of spatial variability of hydraulic properties of groundwater systems at high resolution is essential to simulate flow and transport phenomena. This paper investigates two schemes to invert transient hydraulic head data resulting from multiple pumping tests for the purpose of estimating the spatial distributions of the hydraulic conductivity, K, and the specific storage, S s , of an aquifer. The two methods are centralized fusion and decentralized fusion. The centralized fusion of transient data is achieved when data from all pumping tests are processed concurrently using a central inversion processor, whereas the decentralized fusion inverts data from each pumping test separately to obtain optimal local estimates of hydraulic parameters, which are consequently fused using the generalized Millman formula, an algorithm for merging multiple correlated or uncorrelated local estimates. For both data fusion schemes, the basic inversion processor employed is the ensemble Kalman filter, which is employed to assimilate the temporal moments of impulse response functions obtained from the transient hydraulic head measurements resulting from multiple pumping tests. Assimilating the temporal moments instead of the hydraulic head transient data themselves is shown to provide a significant improvement in computational efficiency. Additionally, different assimilation strategies to improve the estimation of S s are investigated. Results show that estimation of the K and S s distributions using temporal moment analysis is fairly good, and the centralized inversion scheme consistently outperforms the decentralized inversion scheme.

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ReSET-Raster: Surface Energy Balance Model for Calculating Evapotranspiration Using a Raster Approach

Elhaddad

Garcia

2011

J. Irrig. Drain Eng.

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Impact of Shallow Groundwater on Evapotranspiration Losses from Uncultivated Land in an Irrigated River Valley

Niemann

Lehman

Gates

et al. 2011

J. Irrig. Drain Eng.

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Remote Sensing and District Database Programs for Irrigation Monitoring and Evaluation at a Regional Scale

Chalghaf

Elhaddad

Garcia

et al. 2015

J. Irrig. Drain Eng.

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Aymn Elhaddad

Using a Surface Energy Balance Model to Calculate Spatially Distributed Actual Evapotranspiration

Estimation of heterogeneous aquifer parameters using centralized and decentralized fusion of hydraulic tomography data

ReSET-Raster: Surface Energy Balance Model for Calculating Evapotranspiration Using a Raster Approach

Impact of Shallow Groundwater on Evapotranspiration Losses from Uncultivated Land in an Irrigated River Valley

Remote Sensing and District Database Programs for Irrigation Monitoring and Evaluation at a Regional Scale

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