Fractional Snow-Cover Mapping Based on MODIS and UAV Data over the Tibetan Plateau

Liang, Hui; Huang, Xiaodong; Sun, Yanhua; Wang, Yunlong; Liang, Tiangang

doi:10.3390/rs9121332

Cited by 29 publications

(30 citation statements)

References 41 publications

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“…In general, optically based products have a high spatial resolution and are influenced by cloud cover, whereas microwave-based products have a low resolution and a good cloud-penetrating capacity. Therefore, the fusion of optical and microwave data has been the most representative multisource fusion method of cloud removal, e.g., MODIS and AMSR-E (Liang et al, 2008a;Gao et al, 2011b;Akyurek et al, 2010;Huang et al, 2014Huang et al, , 2016Deng et al, 2015;Bergeron et al, 2014), GOES and SSM/I (Romanov et al, 2000), and the visible/infrared spin-scan radiometer (VISSR) and microwave radiation imager (MWRI; Yang et al, 2014).…”

Section: Optical and Microwave Observationsmentioning

confidence: 99%

“…The cloudy pixels of the MODIS product are reclassified as land if SWE = 0 or as snow if SWE ranges from 1 to 240 (Wang et al, 2015). For more fusion rules, please refer to Liang et al (2008a). After re-coding the MODIS and AMSR-E products, some scholars have adopted a rule of the maximum value composite (Yu et al, 2012;Wang et al, 2018).…”

Section: Optical and Microwave Observationsmentioning

confidence: 99%

“…In addition, for the AMSR-E SWE, the gaps with daily changing locations are filled by the ATD method (Wang et al, 2015). The fusion accuracy is much higher than the MODIS daily and 8 d products (Liang et al, 2008a). However, the fusion decreases the spatial resolution and results in uncertainties because of the low spatial resolution of AMSR-E (Gao et al, 2010a, b).…”

Section: Optical and Microwave Observationsmentioning

confidence: 99%

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The recent developments in cloud removal approaches of MODIS snow cover product

Jing

Shen

et al. 2019

Hydrol. Earth Syst. Sci.

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Abstract. The snow cover products of optical remote sensing systems play an important role in research into global climate change, the hydrological cycle, and the energy balance. Moderate Resolution Imaging Spectroradiometer (MODIS) snow cover products are the most popular datasets used in the community. However, for MODIS, cloud cover results in spatial and temporal discontinuity for long-term snow monitoring. In the last few decades, a large number of cloud removal methods for MODIS snow cover products have been proposed. In this paper, our goal is to make a comprehensive summarization of the existing algorithms for generating cloud-free MODIS snow cover products and to expose the development trends. The methods of generating cloud-free MODIS snow cover products are classified into spatial methods, temporal methods, spatio-temporal methods, and multi-source fusion methods. The spatial methods and temporal methods remove the cloud cover of the snow product based on the spatial patterns and temporal changing correlation of the snowpack, respectively. The spatio-temporal methods utilize the spatial and temporal features of snow jointly. The multi-source fusion methods utilize the complementary information among different sources among optical observations, microwave observations, and station observations.

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Section: Optical and Microwave Observationsmentioning

confidence: 99%

Section: Optical and Microwave Observationsmentioning

confidence: 99%

Section: Optical and Microwave Observationsmentioning

confidence: 99%

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The recent developments in cloud removal approaches of MODIS snow cover product

Jing

Shen

et al. 2019

Hydrol. Earth Syst. Sci.

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“…Previous studies have shown that the linear regression algorithm employed by MOD10A1 exhibits large errors in the TP, and linear spectral mixture analysis can somehow improve the accuracy of FSC algorithms, but its accuracy is still unsatisfactory because complex terrain causes mixed pixel problems over the TP. Compared with the snow map retrieved from Landsat, the root mean square error (RMSE) of the MOD10A1 FSC is approximately 0.30, and the difference in the average FSC is approximately 6.71% in the TP [24,25]. However, machine learning algorithms boast a higher FSC mapping efficiency and accuracy than other algorithms in the TP, and the RMSE can be reduced to 0.22 [25].…”

Section: Introductionmentioning

confidence: 99%

MODIS Fractional Snow Cover Mapping Using Machine Learning Technology in a Mountainous Area

Liu

Huang

et al. 2020

Remote Sensing

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To improve the poor accuracy of the MODIS (Moderate Resolution Imaging Spectroradiometer) daily fractional snow cover product over the complex terrain of the Tibetan Plateau (RMSE = 0.30), unmanned aerial vehicle and machine learning technologies are employed to map the fractional snow cover based on MODIS over this terrain. Three machine learning models, including random forest, support vector machine, and back-propagation artificial neural network models, are trained and compared in this study. The results indicate that compared with the MODIS daily fractional snow cover product, the introduction of a highly accurate snow map acquired by unmanned aerial vehicles as a reference into machine learning models can significantly improve the MODIS fractional snow cover mapping accuracy. The random forest model shows the best accuracy among the three machine learning models, with an RMSE (root-mean-square error) of 0.23, especially over forestland and shrubland, with RMSEs of 0.13 and 0.18, respectively. Although the accuracy of the support vector machine and back-propagation artificial neural network models are worse over forestland and shrubland, their average errors are still better than that of MOD10A1. Different fractional snow cover gradients also affect the accuracy of the machine learning algorithms. Nevertheless, the random forest model remains stable in different fractional snow cover gradients and is, therefore, the best machine learning algorithm for MODIS fractional snow cover mapping in Tibetan Plateau areas with complex terrain and severely fragmented snow cover.

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“…Methods based on ultrasonic technology were used to measure depth of snow even on the ground, in Europe and Alaska [6,7]. However, snow cover monitoring of large areas is mainly based on Synthetic Aperture Radar SAR-type scanning [8,9], or satellite mapping [10,11]. This makes it possible to obtain coverage maps and forecasts for regions or even entire countries.…”

mentioning

confidence: 99%

Structural Health Monitoring System for Snow and Wind Load Measurement

Dziadak

2020

Electronics

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This article presents a system for monitoring the load caused by strong winds and snow on buildings’ roofs. An estimation of the total load on the structure is obtained by measuring the strain on the main roof girders. The system is based on a wireless sensor network structure. The measurement node uses metal strain gauges and strain sensors based on conductive carbon polymers. The application of such sensors allowed us to achieve a measurement resolution of 5.5 ustrain. The node is managed by an Atmeg8A microcontroller. The use of energy saving modes allows for a battery life of 6 months.

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Fractional Snow-Cover Mapping Based on MODIS and UAV Data over the Tibetan Plateau

Cited by 29 publications

References 41 publications

The recent developments in cloud removal approaches of MODIS snow cover product

The recent developments in cloud removal approaches of MODIS snow cover product

MODIS Fractional Snow Cover Mapping Using Machine Learning Technology in a Mountainous Area

Structural Health Monitoring System for Snow and Wind Load Measurement

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