Artificial neural network coupled with wavelet transform for estimating snow water equivalent using passive microwave data

Dariane, Alireza B.; Azimi, Shima; Zakerinejad, A

doi:10.1007/s12040-014-0485-1

Cited by 7 publications

(4 citation statements)

References 29 publications

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“…Nonetheless, they may struggle to extract information from nonstationary signals and can easily get trapped in local optima. 1,34 To mitigate these challenges, researchers integrated wavelet transform with ANN models to overcome the impacts of internal snow properties and external environmental factors, such as feedforward neural networks (FFNN) and general regression neural networks (GRNN), with wavelet transform. 34,35 The wavelet transform technique has been shown to enhance the capabilities of ANN models in estimating the snow depth in regions with complex topography and variable snow cover.…”

Section: Introductionmentioning

confidence: 99%

“…1,34 To mitigate these challenges, researchers integrated wavelet transform with ANN models to overcome the impacts of internal snow properties and external environmental factors, such as feedforward neural networks (FFNN) and general regression neural networks (GRNN), with wavelet transform. 34,35 The wavelet transform technique has been shown to enhance the capabilities of ANN models in estimating the snow depth in regions with complex topography and variable snow cover. [36][37][38] Adib et al 39 advanced snow depth retrieval by integrating multiple artificial intelligence models and a multiresolution-based maximal overlap discrete wavelet transform (MODWT-MRA).…”

Section: Introductionmentioning

confidence: 99%

“…The above studies indicate that the ANN can improve the estimation accuracy of snow products, especially in mountainous areas. Nonetheless, they may struggle to extract information from nonstationary signals and can easily get trapped in local optima 1 , 34 …”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Snow depth retrieval from microwave remote sensing by combining wavelet transform and machine learning models in Northern Xinjiang, China

Hou,

Hu,

Chu

et al. 2024

J. Appl. Rem. Sens.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Snow depth retrieval from microwave remote sensing by combining wavelet transform and machine learning models in Northern Xinjiang, China

Hou,

Hu,

Chu

et al. 2024

J. Appl. Rem. Sens.

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“…Many studies have been developed to map SWE for dates with available ground‐truth data, matching them with satellite‐based observations (Harshburger et al, ) applying multiple regression techniques). Dariane, Azimi, and Zakerinejad () applied an ANN coupled with wavelet transform to estimate the SWE using passive microwave data.…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal estimation of snow depth using point data from snow stakes, digital terrain models, and satellite data

Collados‐Lara

Pardo‐Igúzquiza

Pulido-Velázquez

2017

Hydrological Processes

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Snow availability in Alpine catchments plays an important role in water resources management. In this paper, we propose a method for an optimal estimation of snow depth (areal extension and thickness) in Alpine systems from point data and satellite observations by using significant explanatory variables deduced from a digital terrain model. It is intended to be a parsimonious approach that may complement physical-based methodologies. Different techniques (multiple regression, multicriteria analysis, and kriging) are integrated to address the following issues: We identify the explanatory variables that could be helpful on the basis of a critical review of the scientific literature. We study the relationship between ground observations and explanatory variables using a systematic procedure for a complete multiple regression analysis. Multiple regression models are calibrated combining all suggested model structures and explanatory variables. We also propose an evaluation of the models (using indices to analyze the goodness of fit) and select the best approaches (models and variables) on the basis of multicriteria analysis.Estimation of the snow depth is performed with the selected regression models. The residual estimation is improved by applying kriging in cases with spatial correlation. The final estimate is obtained by combining regression and kriging results, and constraining the snow domain in accordance with satellite data. The method is illustrated using the case study of the Sierra Nevada mountain range (Southern Spain). A cross-validation experiment has confirmed the efficiency of the proposed procedure. Finally, although it is not the scope of this work, the snow depth is used to asses a first estimation of snow water equivalent resources.

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Snow depth retrieval from passive microwave imagery using different artificial neural networks

Zaerpour

Adib

Motamedi³

2020

Arab J Geosci

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Artificial neural network coupled with wavelet transform for estimating snow water equivalent using passive microwave data

Cited by 7 publications

References 29 publications

Snow depth retrieval from microwave remote sensing by combining wavelet transform and machine learning models in Northern Xinjiang, China

Snow depth retrieval from microwave remote sensing by combining wavelet transform and machine learning models in Northern Xinjiang, China

Spatiotemporal estimation of snow depth using point data from snow stakes, digital terrain models, and satellite data

Snow depth retrieval from passive microwave imagery using different artificial neural networks

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