Evaluating the Capability of Satellite Hyperspectral Imager, the ZY1–02D, for Topsoil Nitrogen Content Estimation and Mapping of Farmlands in Black Soil Area, China

Xu, Zhengyuan; Chen, Shengbo; Zhu, Bingxue; Chen, Liwen; Ye, Yinghui; Lü, Peng

doi:10.3390/rs14041008

Cited by 8 publications

(5 citation statements)

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“…Although the accuracies were lower than the R results, the models developed with A spectra also presented acceptable results. The validation accuracies of models based on R' and C spectra were relatively poor, which is consistent with previous studies reporting that, although the spectral transformation of the first derivative and the continuum removal of spectral reflectance could effectively enhance the calibration accuracies of statistical models [31][32][33][34][35][36][37], the characteristic spectral bands of certain specific soil attributes show obvious discontinuous and unstable variation on the whole VNIR-SWIR spectral region when the R' and C spectra are employed, which can distinctly influence validation accuracies [47]. Regarding the influence of soil temperature on the spectra variation and corresponding estimation ability, the results showed no distinct regularities between the estimation accuracy and the variation in soil temperature: In most cases, the benchmark models developed with soil spectra measured at a soil temperature of 20 • C showed the best estimation accuracies; however, the model TaR' (30 • C) obtained the highest R 2 v = 0.538 of the treatments in its group (Table 4 green zone).…”

Section: Spectral Response and Estimation Results Under Soil Temperat...supporting

confidence: 88%

Optimizing a Standard Spectral Measurement Protocol to Enhance the Quality of Soil Spectra: Exploration of Key Variables in Lab-Based VNIR-SWIR Spectral Measurement

Chen

Lü

et al. 2022

Remote Sensing

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The method of proximal VNIR-SWIR (with a spectral region of 400–2500 nm) spectroscopy in a laboratory setting has been widely employed in soil property estimations. Increasing attention has been focused recently on establishing an agreed-upon protocol for soil spectral measurement, fueled by the recognition that studies carried out under different laboratory settings have made future data sharing and model comparisons difficult. This study aimed to explore the key factors in a lab-based spectral measurement procedure to provide recommendations for enhancing the spectra quality and promoting the development of the spectral measurement protocol. To this aim, with the support of the standard spectral laboratory at Jilin University, China, we designed and performed control experiments on four key factors—the light interference in the measurement course, soil temperature, soil moisture, and soil particle size—to quantify the variation in the spectra quality by the subsequent estimation accuracies of different estimation models developed with different spectra obtained from control groups. The results showed that (1) the soil–probe contact measurement derived the optimum spectra quality and estimation accuracy; however, close-non-contact measurement also achieved acceptable results; (2) sieving the soil sample into particle sizes below 1 mm and drying before spectral measurement effectively enhanced spectra quality and estimation accuracy; (3) the variation in soil temperature did not have a distinct influence on spectra quality, and the estimation accuracies of models developed based on soil samples at 20–50 °C were all acceptable. Moreover, a 30-min warm-up of the spectrometer and contact probe was found to be effective. We carried out a complete and detailed control experiment process, the results of which offer a guide for optimizing the process of laboratory-based soil proximal spectral measurement to enhance spectra quality and corresponding estimation accuracy. Furthermore, we present theoretical support for the development of the spectral measurement protocol. We also present optional guidance with relatively lower accuracy but effective results, which are save time and are low cost for future spectral measurement projects.

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Section: Spectral Response and Estimation Results Under Soil Temperat...supporting

confidence: 88%

Optimizing a Standard Spectral Measurement Protocol to Enhance the Quality of Soil Spectra: Exploration of Key Variables in Lab-Based VNIR-SWIR Spectral Measurement

Chen

Lü

et al. 2022

Remote Sensing

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“…Despite the fact that research has been carried out for about 40 years in this field, there are many shortcomings yet to be overcome in all of the steps included in hyperspectral image pre-processing [ 49 , 72 , 73 ], processing [ 9 , 46 , 74 ], and validation [ 30 , 31 , 75 ]. However, not only the pre-processing, processing, and validation steps, but also sensor characteristics determine the capability of hyperspectral images.…”

Section: Discussionmentioning

confidence: 99%

“…With regard to the first approach, because spectral unmixing analysis is the most widely applied method to hyperspectral images (e.g., [ 32 , 33 , 34 ]), some authors proposed methods to solve the unmixing problem (e.g., pixel purity index [ 35 ], N-FINDR [ 36 ], interactive error analysis [ 37 ]), or to estimate the endmember fractional abundances (e.g., [ 38 ]), whereas other authors developed methods based on spatial analysis (e.g., Spectral Angle Mapping—SAM [ 39 ] and Spectral Information Divergence—SID [ 40 ]). With regard to the second approach, the results obtained from hyperspectral data were compared with those obtained from other hyperspectral data (e.g., Hyperion images were compared with CHRIS [ 41 ], Hyperspectral Satellite TianGong-1 [ 42 ], and PRISMA [ 43 ] hyperspectral data), from multispectral data (e.g., CASI and MIVIS hyperspectral images were compared with ATM multispectral data [ 44 ], and PRISMA hyperspectral images were compared with Sentinel-2A multispectral data [ 45 ]), and from other data (e.g., AHSI hyperspectral data were compared with the GlobalLand30 land cover data set [ 46 ]; MIVIS hyperspectral image was merged with DEM [ 47 ]). However, there are many sources of error as the capability evaluated from real image is due to both the characteristics of the sensor and each step of image pre-processing and processing (i.e., calibration [ 7 , 48 ]; atmospheric [ 49 , 50 ] and geometric [ 51 ] corrections; dimension reduction [ 30 ]; selected method [ 52 ]; etc.).…”

Section: Introductionmentioning

confidence: 99%

The Weight of Hyperion and PRISMA Hyperspectral Sensor Characteristics on Image Capability to Retrieve Urban Surface Materials in the City of Venice

Cavalli

2023

Sensors

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Following the success of the first hyperspectral sensor, the evaluation of hyperspectral image capability became a challenge in research, which mainly focused on improving image pre-processing and processing steps to minimize their errors, whereas in this study, the focus was on the weight of hyperspectral sensor characteristics on image capability in order to distinguish this effect from errors caused by image pre-processing and processing steps and improve our knowledge of errors. For these purposes, two satellite hyperspectral sensors with similar spatial and spectral characteristics (Hyperion and PRISMA) were compared with corresponding synthetic images, and the city of Venice was selected as the study area. After creating the synthetic images, the errors in the simulation of Hyperion and PRISMA images were evaluated (1.6 and 1.1%, respectively). The same spectral unmixing procedure was performed using real and synthetic images, and their accuracies were compared. The spectral accuracies in root mean square error were equal to 0.017 and 0.016, respectively. In addition, 72.3 and 77.4% of these values were related to sensor characteristics. The spatial accuracies in the mean absolute error were equal to 3.93 and 3.68, respectively. A total of 55.6 and 59.0% of these values were related to sensor characteristics, and 22.6 and 22.3% were related to co-localization and spatial resampling errors. The difference between the radiometric precision values of the sensors was 6.81 and 5.91% regarding the spectral and spatial accuracies of Hyperion image. In conclusion, the results of this study showed that the combined use of two or more real hyperspectral images with similar characteristics and their synthetic images quantifies the weight of hyperspectral sensor characteristics on their image capability and improves our knowledge regarding processing errors, and thus image capability.

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“…The spectral data set for identifying the characteristic absorption bands of hydromagnesite is generated by preprocessing the laboratory spectra [42] . The raw spectra collected by the spectrometer were reflectance transformed and then converted into the txt file by ENVI software.The spectral data is processed by Savitzky-Golay (SG) filtering and smoothing using python language.…”

Section: Laboratory Spectra Pre-processingmentioning

confidence: 99%

Hydromagnesite determination method based on Landsat8 and ZY1-02D data: A case study of the Jiezechaka Salt Lake in Tibet

Zhao,

Dai,

Zhao

et al. 2023

Preprint

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Hydromagnesite is a natural carbonate mineral that is widely distributed, but large sedimentary hydromagnesite deposits with industrial exploitation value are rare globally. In China, hydromagnesite is mainly distributed in the salt lake area of Qinghai-Tibet Plateau. Because of the harsh environment, it is difficult to use the traditional method to search for ore. Remote sensing technology has been successfully applied to research skarn, pegmatite lithium-beryllium, porphyry-epithermal, salt lake lithium, magmatic nickel-chromium, and orogenic gold deposits; however, research regarding remote sensing determination of hydromagnesite from salt lakes is lacking. We determined the mineral composition and content of hydromagnesite samples in the Jiezechaka area by X-ray diffraction (XRD), and the reflection spectral curve of the hydromagnesite samples was measured using an ASD FieldSpec4 short-wave infrared spectrometer. The analysis indicated three and seven absorption valleys with high and low absorption intensities, respectively, in the reflectance spectral curves of the hydromagnesite samples in the Jiezechaka area. Then, on this basis, we used Landsat8 OLI and ZY1-02D AHSI data, with the mixture tuned matched filtering (MTMF) method to extract hydromagnesite information around Jiezechaka Salt Lake in Tibet. A confusion matrix operation was used to compare the determination results of the two types of data. Among them, the overall accuracy of the extraction results based on Landsat8 data was > 67%, and the kappa coefficient was 0.668. The overall accuracy of the extraction results based on ZY1-02D data was > 72%, and the kappa coefficient was 0.743. Finally, using overlay analysis of the two kinds of data determination results, we concluded that hydromagnesite outcrops in the Jiezechaka area are mainly distributed in the northwestern and southeastern regions of the lake. This study provides a rapid assessment technique for measuring hydromagnesite information from salt lakes.

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Evaluating the Capability of Satellite Hyperspectral Imager, the ZY1–02D, for Topsoil Nitrogen Content Estimation and Mapping of Farmlands in Black Soil Area, China

Cited by 8 publications

References 65 publications

Optimizing a Standard Spectral Measurement Protocol to Enhance the Quality of Soil Spectra: Exploration of Key Variables in Lab-Based VNIR-SWIR Spectral Measurement

Optimizing a Standard Spectral Measurement Protocol to Enhance the Quality of Soil Spectra: Exploration of Key Variables in Lab-Based VNIR-SWIR Spectral Measurement

The Weight of Hyperion and PRISMA Hyperspectral Sensor Characteristics on Image Capability to Retrieve Urban Surface Materials in the City of Venice

Hydromagnesite determination method based on Landsat8 and ZY1-02D data: A case study of the Jiezechaka Salt Lake in Tibet

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