Comparison of two Satellite Imaging Platforms for Evaluating Sand Dune Migration in the Ubari Sand Sea (Libyan Fazzan)

Huang

et al. 2018

Sensors

Vegetation in arid and semi-arid regions frequently exists in patches, which can be effectively mapped by remote sensing. However, not all satellite images are suitable to detect the decametric-scale vegetation patches because of low spatial resolution. This study compared the capability of the first Gaofen Satellite (GF-1), the second Gaofen Satellite (GF-2), and China-Brazil Earth Resource Satellite 4 (CBERS-04) panchromatic images for mapping quasi-circular vegetation patches (QVPs) with K-Means (KM) and object-based example-based feature extraction with support vector machine classification (OEFE) in the Yellow River Delta, China. Both approaches provide relatively high classification accuracy with GF-2. For all five images, the root mean square errors (RMSEs) for area, perimeter, and perimeter/area ratio were smaller using the KM than the OEFE, indicating that the results from the KM are more similar to ground truth. Although the mapped results of the QVPs from finer-spatial resolution images appeared more accurate, accuracy improvement in terms of QVP area, perimeter, and perimeter/area ratio was limited, and most of the QVPs detected only by finer-spatial resolution imagery had a more than 40% difference with the actual QVPs in these three parameters. Compared with the KM approach, the OEFE approach performed better for vegetation patch shape description. Coupling the CBERS-04 with the OEFE approach could suitably map the QVPs (overall accuracy 75.3%). This is important for ecological protection managers concerned about cost-effectiveness between image spatial resolution and mapping the QVPs.

Section: Introductionmentioning

confidence: 99%

Comparison of CBERS-04, GF-1, and GF-2 Satellite Panchromatic Images for Mapping Quasi-Circular Vegetation Patches in the Yellow River Delta, China

Huang

et al. 2018

Sensors

Earth Surf Processes Landf

“…Early studies relied mainly on passive optical systems, such as Landsat 1 (ERTS), to map and classify dunes McKee, 1979). More recent studies have exploited improvements in the spectral and spatial resolution of remote sensing technologies (Maman et al, 2011;Hugenholtz et al, 2012;Hereher, 2014;Els et al, 2015;Martone et al, 2016;Paillou et al, 2016) for quantitative investigations of dune features, forms and pattern development, which were not possible with the earlier types of imagery (Ewing and Kocurek, 2010;Hugenholtz and Barchyn, 2010;Yang et al, 2011;Hermas et al, 2012;Livingstone, 2013).…”

Section: Introductionmentioning

confidence: 99%

Mapping dune dynamics by InSAR coherence

Havivi

Amir

Schvartzman

et al. 2018

It is generally held that subtle changes in sandy environments are very difficult to detect in imagery. Nonetheless, this study demonstrates how synthetic aperture radar (SAR) interferometric decorrelation can be used to identify changes in individual sand dunes. The use of coherence maps over time facilitates the analysis of dune dynamics, both temporally and spatially. The Ashdod‐Nizzanim coastal dunes, along the southern coastal plain of Israel, were chosen as an illustrative example of the analysis of dune dynamics. High‐resolution TerraSAR‐X (TSX) radar images covering the entire research area were acquired for the period February to July 2012, together with meteorology data (wind and rain) for the area. The coherence results enabled the stability of individual dunes to be described as a function of time. It was found that the dune crests were more stable than the windward slopes and that the degree of stability was dependent on the distance of the dune from the sea. The results of this study show the potential of using interferometric synthetic aperture radar (InSAR) decorrelation for aeolian studies, even in areas characterized by low coherence. Copyright © 2017 John Wiley & Sons, Ltd.

“…In Nouakchott, the most vulnerable area is the eastern and northern part of the city, with vulnerability values ranging from medium to high (23 to 27) ( Figure 7, bottom-right). The center and south of the city evidence lower vulnerability, with values from medium to low (17)(18)(19)(20)(21)(22). It should be noted that a small area in the western part of Nouakchott is missing due to a lack of information for some of the factors, such that it was not possible to calculate the SDEVI.…”

Section: Resultsmentioning

confidence: 99%

“…However, we also included other parameters that derive from geology, land cover/land use and remotely sensed soil moisture information. This new index is called the Sand Dune Encroachment Vulnerability Index (SDEVI), and aims to improve on previous efforts [18][19][20] carried out to assess vulnerability to the advance of sand as well as to help local authorities and decision-makers to devise predictive and mitigation measures. We considered adding remote sensing data in order to boost the adaptability of the assessment to our local conditions, as described in Equation 1.…”

Section: Vulnerability Analysismentioning

confidence: 99%

“…In addition, Lancaster et al [17] suggest that validation methods are often difficult because field measures are short and not available on a multi-year basis. Some studies have focused on reducing the vulnerability of affected areas [18,19] and on monitoring the mobility of sand dunes [20]. In order to ensure the success of this type of project, satellite remote sensing approaches have been used to efficiently monitor large and difficult to access areas [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Detecting Areas Vulnerable to Sand Encroachment Using Remote Sensing and GIS Techniques in Nouakchott, Mauritania

et al. 2018

Sand dune advances poses a major threat to inhabitants and local authorities in the area of Nouakchott, Mauritania. Despite efforts to control dune mobility, accurate and adequate local studies are still needed to tackle sand encroachment. We have developed a Sand Dune Encroachment Vulnerability Index (SDEVI) to assess Nouakchott’s vulnerability to sand dune encroachment. Said index is based on the geo-physical characteristics of the area (wind direction and intensity, slope and surface height, land use, vegetation or soil properties) with Geographic Information System (GIS) techniques that can support local authorities and decision-makers in implementing preventive measures or reducing impact on the population and urban infrastructures. In order to validate this new index, we use two remote sensing approaches: optical-Sentinel 2 and Synthetic Aperture Radar (SAR)–Sentinel 1 data. Results show that the greatest vulnerability is located in the north-eastern part of Nouakchott, where local conditions favor the advance of sand in the city, although medium to high values are also found in the eastern part. Optical images enabled us to distinguish desert sand using the ratio between near infrared/blue bands, and SAR Coherence Change Detection (CCD) imagery was used to assess the degree of stability of those sand bodies. The nature of the SDEVI index allows us to currently assess which areas are vulnerable to sand encroachment since we use long data records. Nevertheless, optical and SAR remote sensing allow sand evolution to be monitored on a near real-time basis.