Your search keyword '"Hongliang Fang"' showing total 21 results

1. Retrieval and validation of vertical LAI profile derived from airborne and spaceborne LiDAR data at a deciduous needleleaf forest site

Author

Yao Wang, Hongliang Fang, Yinghui Zhang, Sijia Li, Yong Pang, Tian Ma, and Yu Li

Subjects

General Earth and Planetary Sciences

Published

2023

2. Photosynthetically active radiation and foliage clumping improve satellite-based NIRv estimates of gross primary production

Author

Iolanda Filella, Adrià Descals, Manuela Balzarolo, Gaofei Yin, Aleixandre Verger, Hongliang Fang, and Josep Peñuelas

Subjects

Chemistry, Economics, Physics, General Earth and Planetary Sciences, Biology, Engineering sciences. Technology

Abstract

Monitoring gross primary production (GPP) is necessary for quantifying the terrestrial carbon balance. The near-infrared reflectance of vegetation (NIRv) has been proven to be a good predictor of GPP. Given that radiation powers photosynthesis, we hypothesized that (i) the addition of photosynthetic photon flux density (PPFD) information to NIRv would improve estimates of GPP and that (ii) a further improvement would be obtained by incorporating the estimates of radiation distribution in the canopy provided by the foliar clumping index (CI). Thus, we used GPP data from FLUXNET sites to test these possible improvements by comparing the performance of a model based solely on NIRv with two other models, one combining NIRv and PPFD and the other combining NIRv, PPFD and the CI of each vegetation cover type. We tested the performance of these models for different types of vegetation cover, at various latitudes and over the different seasons. Our results demonstrate that the addition of daily radiation information and the clumping index for each vegetation cover type to the NIRv improves its ability to estimate GPP. The improvement was related to foliage organization, given that the foliar distribution in the canopy (CI) affects radiation distribution and use and that radiation drives productivity. Evergreen needleleaf forests are the vegetation cover type with the greatest improvement in GPP estimation after the addition of CI information, likely as a result of their greater radiation constraints. Vegetation type was more determinant of the sensitivity to PPFD changes than latitude or seasonality. We advocate for the incorporation of PPFD and CI into NIRv algorithms and GPP models to improve GPP estimates.

Published

2023

3. Correction: Sun et al. A Method to Estimate Clear-Sky Albedo of Paddy Rice Fields. Remote Sens. 2022, 14, 5185

Author

Tao Sun, Hongliang Fang, Liding Chen, and Ranhao Sun

Subjects

General Earth and Planetary Sciences

Abstract

Addition of an Author [...]

Published

2023

4. Determination of the Leaf Inclination Angle (LIA) through Field and Remote Sensing Methods: Current Status and Future Prospects

Author

Sijia Li, Hongliang Fang, and Yinghui Zhang

Subjects

General Earth and Planetary Sciences

Abstract

The leaf inclination angle (LIA), defined as the leaf or needle inclination angle to the horizontal plane, is vital in radiative transfer, precipitation interception, evapotranspiration, photosynthesis, and hydrological processes. This paper reviews the field and remote sensing methods to determine LIA. In the field, LIA is determined using direct and indirect methods. The direct methods include direct contact, photographic, and light detection and ranging (LiDAR) methods, while the indirect methods are composed of the gap fraction, four-component, and polarization measurement methods. The direct methods can obtain LIA accurately at individual leaves, crown, and plot scales, whereas the indirect methods work well for crops at the plot level. The remote sensing methods to estimate LIA are mainly based on the empirical, radiative transfer model, and gap fraction methods. More advanced inversion strategies and validation studies are necessary to improve the robustness of LIA remote sensing estimation. In future studies, automated observation systems can be developed and the LIA measurement can be incorporated into existing ground observation networks to enhance spatial coverage.

Published

2023

5. Evaluation of Clumping Effects on the Estimation of Global Terrestrial Evapotranspiration

Author

Xuehe Lu, Bin Chen, Muhammad Altaf Arain, Yang Liu, Xiaobo Wang, Jinghua Chen, Hongliang Fang, Shaoqiang Wang, Fei Jiang, Zhenhai Liu, and Jing M. Chen

Subjects

Canopy, canopy radiation transfer, leaf area index, Science, evapotranspiration, Boreal ecosystem, canopy structural parameters, Evergreen, Spatial distribution, Atmospheric sciences, Deciduous, clumping index, Evapotranspiration, General Earth and Planetary Sciences, Environmental science, Terrestrial ecosystem, two-leaf model, Leaf area index

Abstract

In terrestrial ecosystems, leaves are aggregated into different spatial structures and their spatial distribution is non-random. Clumping index (CI) is a key canopy structural parameter, characterizing the extent to which leaf deviates from the random distribution. To assess leaf clumping effects on global terrestrial ET, we used a global leaf area index (LAI) map and the latest version of global CI product derived from MODIS BRDF data as well as the Boreal Ecosystem Productivity Simulator (BEPS) to estimate global terrestrial ET. The results show that global terrestrial ET in 2015 was 511.9 ± 70.1 mm yr−1 for Case I, where the true LAI and CI are used. Compared to this baseline case, (1) global terrestrial ET is overestimated by 4.7% for Case II where true LAI is used ignoring clumping, (2) global terrestrial ET is underestimated by 13.0% for Case III where effective LAI is used ignoring clumping. Among all plant functional types (PFTs), evergreen needleleaf forests were most affected by foliage clumping for ET estimation in Case II, because they are most clumped with the lowest CI. Deciduous broadleaf forests are affected by leaf clumping most in Case III because they have both high LAI and low CI compared to other PFTs. The leaf clumping effects on ET estimation in both Case II and Case III is robust to the errors in major input parameters. Thus, it is necessary to consider clumping effects in the simulation of global terrestrial ET, which has considerable implications for global water cycle research.

Published

2021

6. A Method to Estimate Clear-Sky Albedo of Paddy Rice Fields

Author

Tao Sun, Hongliang Fang, Liding Chen, and Ranhao Sun

Subjects

surface albedo, paddy rice, agricultural ecosystem, GHG, General Earth and Planetary Sciences

Abstract

As a major crop type in the global agroecosystem, paddy rice fields contribute to global greenhouse gas emissions. Surface albedo plays a vital role in estimating carbon emissions. However, it is difficult to find a broadband albedo estimation over paddy rice fields. The objective of this study was to derive an applicable method to improve albedo estimation over a paddy rice field. Field multiangle reflectance and surface albedo were collected throughout the growing season. A physically based model (AMBRALS) was utilized to reconstruct the directional reflectance into the spectral albedo. Multiple spectral albedos (at the wavelengths of 470, 550, 660, 850, 1243, 1640 and 2151 nm) were calculated, and new narrowband to broadband conversion coefficients were derived between the observed spectral albedo and broadband albedo. The conversion schemes showed high consistency with the field albedo observations in the shortwave (285–3000 nm), infrared (700–3000 nm), and visible (400–700 nm) bands. This method can help improve albedo estimation in partially submerged environments.

Published

2022

7. Real-Time Software for the Efficient Generation of the Clumping Index and Its Application Based on the Google Earth Engine

Author

Yu Li and Hongliang Fang

Subjects

google earth engine, clumping index, General Earth and Planetary Sciences, remote sensing product, landTrendr

Abstract

Canopy clumping index (CI) is a key structural parameter related to vegetation phenology and the absorption of radiation, and it is usually retrieved from remote sensing data based on an empirical relationship with the Normalized Difference between Hotspot and Darkspot (NDHD) index. A rapid production software was developed to implement the CI algorithm based on the Google Earth Engine (GEE) to update current CI products and promote the application of CI in different fields. Daily, monthly, and yearly global CI products are continuously generated and updated in real-time by the software. Users can directly download the product or work with CI without paying attention to data generation. For the application case study, a change detection algorithm, LandTrendr, was implemented on the GEE to examine the global CI trend from 2000 to 2020. The results indicate that the area of increase trend (28.7%, ΔCI > 0.02) is greater than that of the decrease trend (17.1%, ΔCI < −0.02). Our work contributes toward the retrieval, application, and validation of CI.

Published

2022

8. Spatio-Temporal Characteristics and Driving Factors of the Foliage Clumping Index in the Sanjiang Plain from 2001 to 2015

Author

Kehong Hu, Min Gao, Hongliang Fang, Zhengnan Gu, Yijie Lu, and Zhen Zhang

Subjects

Sanjiang Plain, 010504 meteorology & atmospheric sciences, Science, 0211 other engineering and technologies, Growing season, 02 engineering and technology, Spatial distribution, 01 natural sciences, spatio-temporal variation, Vegetation type, medicine, Leaf area index, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Driving factors, Vegetation, Seasonality, medicine.disease, geographical detector model, clumping index, General Earth and Planetary Sciences, Environmental science, Physical geography, trend analysis, driving factors

Abstract

The Sanjiang Plain is the largest agricultural reclamation area and the biggest marsh area in China. The regional vegetation coverage in this area is vital to local ecological systems, and vegetation growth is affected by natural and anthropogenic factors. The clumping index (CI) is of great significance for land surface models and obtaining information on other vegetation structures. However, most existing ecological models and the retrieval of other vegetation structures do not consider the spatial and temporal variations of CI, and few studies have focused on detecting factors that influence the spatial differentiation of CI. To address these issues, this study investigated the spatial and temporal characteristics of foliage CI in the Sanjiang Plain, analysing the correlation between CI and leaf area index (LAI) through multiple methods (such as Theil−Sen trend analysis, the Mann−Kendall test, and the correlation coefficient) based on the 2001−2015 Chinese Academy of Sciences Clumping Index (CAS CI) and Global LAnd Surface Satellite Leaf Area Index (GLASS LAI). The driving factors of the spatial differentiation of CI were also investigated based on the geographical detector model (GDM) with natural data (including the average annual temperature, annual precipitation, elevation, slope, aspect, vegetation type, soil type, and geomorphic type) and anthropogenic data (the land use type). The results showed that (1) the interannual variation of foliage CI was not obvious, but the seasonal variation was obvious in the Sanjiang Plain from 2001 to 2015; (2) the spatial distribution of the multiyear mean CI of each season in the Sanjiang Plain was similar to the spatial distribution of the land use type, and the CI decreased slightly with increases in elevation; (3) the correlation between the growing season mean CI (CIGS) and the growing season mean LAI (LAIGS) time series was not significant, but their spatial distributions were negatively correlated; (4) topographic factors (elevation and slope) and geomorphic type dominated the spatial differentiation of foliage CI in the Sanjiang Plain, and the interactions between driving factors enhanced their explanatory power in terms of the spatial distribution of foliage CI. This study can help improve the accuracy of the retrieval of other vegetation structures and the simulation of land surface models in the Sanjiang Plain, providing invaluable insight for the analysis of the spatial and temporal variations of vegetation based on CI. Moreover, the results of this study support a theoretical basis for understanding the explanatory power of natural and anthropogenic factors in the spatial distribution of CI, along with its driving mechanism.

Published

2021

9. Estimation of LAI with the LiDAR Technology: A Review

Author

Yao Wang and Hongliang Fang

Subjects

010504 meteorology & atmospheric sciences, Light detection, Laser scanning, leaf area index (LAI), 0211 other engineering and technologies, airborne laser scanning (ALS), Ranging, 02 engineering and technology, Vegetation, vertical foliage profile (VFP), 01 natural sciences, Footprint, Validation methods, Lidar, terrestrial laser scanning (TLS), spaceborne laser scanning (SLS), General Earth and Planetary Sciences, Environmental science, lcsh:Q, Leaf area index, lcsh:Science, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing

Abstract

Leaf area index (LAI) is an important vegetation parameter. Active light detection and ranging (LiDAR) technology has been widely used to estimate vegetation LAI. In this study, LiDAR technology, LAI retrieval and validation methods, and impact factors are reviewed. First, the paper introduces types of LiDAR systems and LiDAR data preprocessing methods. After introducing the application of different LiDAR systems, LAI retrieval methods are described. Subsequently, the review discusses various LiDAR LAI validation schemes and limitations in LiDAR LAI validation. Finally, factors affecting LAI estimation are analyzed. The review presents that LAI is mainly estimated from LiDAR data by means of the correlation with the gap fraction and contact frequency, and also from the regression of forest biophysical parameters derived from LiDAR. Terrestrial laser scanning (TLS) can be used to effectively estimate the LAI and vertical foliage profile (VFP) within plots, but this method is affected by clumping, occlusion, voxel size, and woody material. Airborne laser scanning (ALS) covers relatively large areas in a spatially contiguous manner. However, the capability of describing the within-canopy structure is limited, and the accuracy of LAI estimation with ALS is affected by the height threshold and sampling size, and types of return. Spaceborne laser scanning (SLS) provides the global LAI and VFP, and the accuracy of estimation is affected by the footprint size and topography. The use of LiDAR instruments for the retrieval of the LAI and VFP has increased; however, current LiDAR LAI validation studies are mostly performed at local scales. Future research should explore new methods to invert LAI and VFP from LiDAR and enhance the quantitative analysis and large-scale validation of the parameters.

Published

2020

10. The Impact of Potential Land Cover Misclassification on MODIS Leaf Area Index (LAI) Estimation: A Statistical Perspective

Author

Wenjuan Li, Hongliang Fang, and Ranga B. Myneni

Subjects

Estimation, Future studies, biome type, Science, Biome, leaf area index (LAI), uncertainty, land cover, subpixel mixture, biome misclassification, MODIS, Vegetation, Land cover, Evergreen, Photosynthetically active radiation, Climatology, General Earth and Planetary Sciences, Environmental science, Leaf area index, Remote sensing

Abstract

Understanding the impact of vegetation mixture and misclassification on leaf area index (LAI) estimation is crucial for algorithm development and the application community. Using the MODIS standard land cover and LAI products, global LAI climatologies and statistics were obtained for both pure and mixed pixels to evaluate the effects of biome mixture on LAI estimation. Misclassification between crops and shrubs does not generally translate into large LAI errors (

Published

2013

11. Seasonal dynamic pattern analysis on global FPAR derived from AVHRR GIMMS NDVI

Author

Bing Zhang, Dailiang Peng, Hongliang Fang, Dongmei Chen, Yong Hu, and Liangyun Liu

Subjects

Advanced very-high-resolution radiometer, Seasonality, medicine.disease, Normalized Difference Vegetation Index, Computer Science Applications, Geography, Spectroradiometer, Photosynthetically active radiation, Climatology, Vegetation type, medicine, Spatial ecology, General Earth and Planetary Sciences, Leaf area index, Software

Abstract

The purpose of this paper is to develop Advanced Very High Resolution Radiometer (AVHRR) Global Inventory Modelling and Mapping Studies (GIMMS) Normalised Difference Vegetation Index (NDVI; AVHRR GIMMS NDVI for short) based fraction of absorbed photosynthetically active radiation (FPAR) from 1982 to 2006 and focus on their seasonal and spatial patterns analysis. The available relationship between FPAR and NDVI was used to calculate FPAR values from 1982 to 2006 and validated by Moderate-resolution Imaging Spectroradiometer (MODIS) FPAR product. Then, the seasonal dynamic patterns were analysed, as well as the driving force of climatic factors. Results showed that there was an agreement between FPAR values from this study and those of the MODIS product in seasonal dynamic, and the spatial patterns of FPAR vary with vegetation type distribution and seasonal cycles. The time series of average FPAR revealed a strong seasonal variation, regular periodic variations from January 1982 to December 2006, a...

Published

2011

12. Integration of MODIS LAI and vegetation index products with the CSM–CERES–Maize model for corn yield estimation

Author

Shunlin Liang, Hongliang Fang, and Gerrit Hoogenboom

Subjects

Data assimilation, Crop yield, General Earth and Planetary Sciences, Environmental science, Growing season, Enhanced vegetation index, Moderate-resolution imaging spectroradiometer, Leaf area index, Cropping system, Atmospheric sciences, Normalized Difference Vegetation Index, Remote sensing

Abstract

Advanced information on crop yield is important for crop management and food policy making. A data assimilation approach was developed to integrate remotely sensed data with a crop growth model for crop yield estimation. The objective was to model the crop yield when the input data for the crop growth model are inadequate, and to make the yield forecast in the middle of the growing season. The Cropping System Model (CSM)-Crop Environment Resource Synthesis (CERES)-Maize and the Markov Chain canopy Reflectance Model (MCRM) were coupled in the data assimilation process. The Moderate Resolution Imaging Spectroradiometer (MODIS) Leaf Area Index (LAI) and vegetation index products were assimilated into the coupled model to estimate corn yield in Indiana, USA. Five different assimilation schemes were tested to study the effect of using different control variables: independent usage of LAI, normalized difference vegetation index (NDVI) and enhanced vegetation index (EVI), and synergic usage of LAI and EVI or NDVI. Parameters of the CSM-CERES-Maize model were initiated with the remotely sensed data to estimate corn yield for each county of Indiana. Our results showed that the estimated corn yield agreed very well with the US Department of Agriculture (USDA) National Agricultural Statistics Service (NASS) data. Among different scenarios, the best results were obtained when both MODIS vegetation index and LAI products were assimilated and the relative deviations from the NASS data were less than 3.5%. Including only LAI in the model performed moderately well with a relative difference of 8.6%. The results from using only EVI or NDVI were unacceptable, as the deviations were as high as 21% and -13% for the EVI and NDVI schemes, respectively. Our study showed that corn yield at harvest could be successfully predicted using only a partial year of remotely sensed data.

Published

2011

13. Corn‐yield estimation through assimilation of remotely sensed data into the CSM‐CERES‐Maize model

Author

Michel A. Cavigelli, John R. Teasdale, Hongliang Fang, Gerrit Hoogenboom, and Shunlin Liang

Subjects

Hydrology, Data assimilation, Crop yield, General Earth and Planetary Sciences, Environmental science, Growing season, Enhanced vegetation index, Moderate-resolution imaging spectroradiometer, Cropping system, Leaf area index, Crop simulation model, Remote sensing

Abstract

One of the applications of crop simulation models is to estimate crop yield during the current growing season. Several studies have tried to integrate crop simulation models with remotely sensed data through data-assimilation methods. This approach has the advantage of allowing reinitialization of model parameters with remotely sensed observations to improve model performance. In this study, the Cropping System Model-CERES-Maize was integrated with the Moderate Resolution Imaging Spectroradiometer (MODIS) leaf area index (LAI) products for estimating corn yield in the state of Indiana, USA. This procedure, inversion of crop simulation model, facilitates several different user input modes and outputs a series of agronomic and biophysical parameters, including crop yield. The estimated corn yield in 2000 compared reasonably well with the US Department of Agriculture National Agricultural Statistics Service statistics for most counties. Using the seasonal LAI in the optimization procedure produced the best results compared with only the green-up LAIs or the highest LAI values. Planting, emergence and maturation dates, and N fertilizer application rates were also estimated at a regional level. Further studies will include investigating model uncertainties and using other MODIS products, such as the enhanced vegetation index.

Published

2008

14. Biophysical characterization and management effects on semiarid rangeland observed from Landsat ETM+ data

Author

Roberto C. Izaurralde, Allison M. Thomson, Shunlin Liang, Stuart E. Marsh, W.J.D. van Leeuwen, Mitchel P. McClaran, Sam Drake, Hongliang Fang, and Norman J. Rosenberg

Subjects

Hydrology, Enhanced vegetation index, Atmospheric sciences, Normalized Difference Vegetation Index, Photosynthetically active radiation, Thematic Mapper, medicine, General Earth and Planetary Sciences, Environmental science, Moderate-resolution imaging spectroradiometer, Electrical and Electronic Engineering, Rangeland, Leaf area index, medicine.symptom, Vegetation (pathology)

Abstract

Semiarid rangelands are very sensitive to global climatic change; studies of their biophysical attributes are crucial to understanding the dynamics of rangeland ecosystems under human disturbance. In the Santa Rita Experimental Range, AZ, the vegetation has changed considerably, and there have been many management activities applied. This study calculates seven surface variables: the enhanced vegetation index, the normalized difference vegetation index (NDVI), surface albedos (total shortwave, visible, and near-infrared), leaf area index (LAI), and the fraction of photosynthetically active radiation (FPAR) absorbed by green vegetation from the Enhanced Thematic Mapper (ETM+) data. Comparison with the Moderate Resolution Imaging Spectroradiometer vegetation index and albedo products indicates they agree well with our estimates from ETM+, while their LAI and FPAR are larger than from ETM+. Human disturbance has significantly changed the cover types and biophysical conditions. Statistical tests indicate that surface albedos increased and FPAR decreased following tree-cutting disturbances. The recovery will require more than 67 years and is about 50% complete within 40 years at the higher elevation. Grass cover, vegetation indexes, albedos, and LAI recovered from cutting faster at the higher elevation. Woody plants, vegetation indexes, and LAI have recovered to their original characteristics after 65 years at the lower elevation. More studies are needed to examine the spectral characteristics of different ground components.

Published

2005

15. Statistical comparison of MISR, ETM+ and MODIS land surface reflectance and albedo products of the BARC land validation core site, USA

Author

C.L. Walthall, Shunlin Liang, Mingzhen Chen, Craig S. T. Daughtry, and Hongliang Fang

Subjects

Spectroradiometer, Thematic Mapper, Photosynthetically active radiation, General Earth and Planetary Sciences, Environmental science, Satellite, Moderate-resolution imaging spectroradiometer, Leaf area index, Albedo, Snow, Remote sensing

Abstract

The Multi-angle Imaging Spectroradiometer (MISR) and Moderate Resolution Imaging Spectroradiometer (MODIS) onboard the National Aeronautics and Space Administration (NASA)'s Earth Observing System (EOS) Terra satellite are crucial for generation of other products such as the Fraction of Photosynthetically Active Radiation (FPAR) and Leaf Area Index (LAI). The analysis reported here compares the reflectance and albedo products from MODIS (MOD09 and MOD43B3), MISR and Landsat Enhanced Thematic Mapper (ETM)+ data using general statistical methods. Four MISR land surface products are examined: hemispherical–directional reflectance factors (HDRF), bidirectional reflectance factors (BRF), bi-hemispherical reflectance (BHR) and directional–hemispherical reflectance (DHR). Ground measurements were used to validate ETM+ reflectance and albedo products (30 m) which were then upscaled and compared with MISR products (1.1 km). The results from 11 May 2000, 5 December 2000 and 22 January 2001 show that: (1) under clea...

Published

2004

16. Retrieving leaf area index with a neural network method: simulation and validation

Author

Shunlin Liang and Hongliang Fang

Subjects

Canopy, Meteorology, Artificial neural network, Thematic Mapper, Radiance, Radiative transfer, Atmospheric correction, General Earth and Planetary Sciences, Environmental science, Vegetation, Electrical and Electronic Engineering, Leaf area index, Remote sensing

Abstract

Leaf area index (LAI) is a crucial biophysical parameter that is indispensable for many biophysical and climatic models. A neural network algorithm in conjunction with extensive canopy and atmospheric radiative transfer simulations is presented in this paper to estimate LAI from Landsat-7 Enhanced Thematic Mapper Plus data. Two schemes were explored; the first was based on surface reflectance, and the second on top-of-atmosphere (TOA) radiance. The implication of the second scheme is that atmospheric corrections are not needed for estimating the surface LAI. A soil reflectance index (SRI) was proposed to account for variable soil background reflectances. Ground-measured LAI data acquired at Beltsville, Maryland were used to validate both schemes. The results indicate that both methods can be used to estimate LAI accurately. The experiments also showed that the use of SRI is very critical.

Published

2003

17. Estimation and validation of land surface broadband albedos and leaf area index from eo-1 ali data

Author

Shunlin Liang, Tim R. McVicar, M. Kaul, Craig S. T. Daughtry, J. Pearlman, Hongliang Fang, T.G. Van Niel, C.L. Walthall, and Karl F. Huemmrich

Subjects

Meteorology, Thematic Mapper, Multispectral image, Atmospheric correction, General Earth and Planetary Sciences, Environmental science, Satellite, Spectral bands, Electrical and Electronic Engineering, Leaf area index, Albedo, Atmospheric optics, Remote sensing

Abstract

The Advanced Land Imager (ALI) is a multispectral sensor onboard the National Aeronautics and Space Administration Earth Observing 1 (EO-1) satellite. It has similar spatial resolution to Landsat-7 Enhanced Thematic Mapper Plus (ETM+), with three additional spectral bands. We developed new algorithms for estimating both land surface broadband albedo and leaf area index (LAI) from ALI data. A recently developed atmospheric correction algorithm for ETM+ imagery was extended to retrieve surface spectral reflectance from ALI top-of-atmosphere observations. A feature common to these algorithms is the use of new multispectral information from ALI. The additional blue band of ALI is very useful in our atmospheric correction algorithm, and two additional ALI near-infrared bands are valuable for estimating both broadband albedo and LAI. Ground measurements at Beltsville, MD, and Coleambally, Australia, were used to validate the products generated by these algorithms.

Published

2003

18. Calculating environmental moisture for per-field discrimination of rice crops

Author

T.G. Van Niel, Hongliang Fang, Tim R. McVicar, and Shunlin Liang

Subjects

Irrigation, Spectral signature, Moisture, Thematic Mapper, General Earth and Planetary Sciences, Paddy field, Growing season, Radiometry, Humidity, Soil science, Mathematics, Remote sensing

Abstract

The accuracies of rice classifications determined from density slices of broadband moisture indices were compared to results from a standard supervised technique using six reflective Enhanced Thematic Mapper plus (ETM+) bands. Index-based methods resulted in higher accuracies early in the growing season when background moisture differences were at a maximum. Analysis of depth of ETM+ band 5 resulted in the highest accuracy over the growing season (97.74%). This was more accurate than the highest supervised classification accuracy (95.81%), demonstrating the usefulness of spectral feature selection of moisture for classifying rice.

Published

2003

19. Atmospheric correction of Landsat ETM+ land surface imagery. II. Validation and applications

Author

Chad J Shuey, Shunlin Liang, Mingzhen Chen, Craig S. T. Daughtry, Jeffrey T. Morisette, Hongliang Fang, and C.L. Walthall

Subjects

Spectroradiometer, SeaWiFS, Meteorology, Thematic Mapper, Multispectral image, Atmospheric correction, General Earth and Planetary Sciences, Environmental science, Land cover, Electrical and Electronic Engineering, Change detection, Atmospheric optics, Remote sensing

Abstract

For pt.I see ibid., vol.39, no.11, p.2490-8 (2001). This is the second paper of the series on atmospheric correction of Enhanced Thematic Mapper-Plus (ETM+) land surface imagery. In the first paper, a new algorithm that corrects heterogeneous aerosol scattering and surface adjacency effects was presented. In this study, our objectives are to (1) evaluate the accuracy of this new atmospheric correction algorithm using ground radiometric measurements, (2) apply this algorithm to correct Moderate-Resolution Imaging Spectroradiometer (MODIS) and SeaWiFS imagery, and (3) demonstrate how much atmospheric correction of ETM+ imagery can improve land cover classification, change detection, and broadband albedo calculations. Validation results indicate that this new algorithm can retrieve surface reflectance from ETM+ imagery accurately. All experimental cases demonstrate that this algorithm can be used for correcting both MODIS and SeaWiFS imagery. Although more tests and validation exercises are needed, it has been proven promising to correct different multispectral imagery operationally. We have also demonstrated that atmospheric correction does matter.

Published

2002

20. Atmospheric correction of Landsat ETM+ land surface imagery. I. Methods

Author

Shunlin Liang, Hongliang Fang, and Mingzhen Chen

Subjects

Surface (mathematics), Thematic map, Meteorology, Thematic Mapper, Atmospheric correction, General Earth and Planetary Sciences, Environmental science, Adjacency list, Electrical and Electronic Engineering, Reflectivity, Atmospheric optics, Aerosol, Remote sensing

Abstract

To extract quantitative information from the Enhanced Thematic Mapper-Plus (ETM+) imagery accurately, atmospheric correction is a necessary step. After reviewing historical development of atmospheric correction of Landsat Thematic Mapper (TM) imagery, the authors present a new algorithm that can effectively estimate the spatial distribution of atmospheric aerosols and retrieve surface reflectance from ETM+ imagery under general atmospheric and surface conditions. This algorithm is therefore suitable for operational applications. A new formula that accounts for adjacency effects is also presented. Several examples are given to demonstrate that this new algorithm works very well under a variety of atmospheric and surface conditions.

Published

2001

21. Using NOAA AVHRR and Landsat TM to estimate rice area year-by-year

Author

Haiyan Liu, Hongliang Fang, Xuan Huang, and Bingfang Wu

Subjects

Crop production, Thematic Mapper, Area change, General Earth and Planetary Sciences, Radiometry, Environmental science, High resolution, Vegetation, Remote sensing

Abstract

Remote sensing has been widely used to estimate crop area and production. Forecasting the crop area year-by-year is the key step to realizing crop production forecasting. In this letter, a methodology to calculate rice area using NOAA AVHRR and Landsat TM data is introduced. The rice area in 1992 was estimated using Landsat TM data. 'Rice' pixels in 1992 and 1994 were calculated and the rice area change trend determined using NOAA AVHRR data for the two years. With a linear statistical model, the rice area of 1994 was forecast. Its accuracy was 84.5 per cent compared to the data released by the Agricultural Investigation Team(AIT) of Hubei province. The same method was applied to estimate the rice area of 1995. The accuracy was 91.6 per cent compared with AIT data.

Published

1998