386 research outputs found
Digital elevation model correction in urban areas using extreme gradient boosting, land cover and terrain parameters
The accuracy of digital elevation models (DEMs) in urban areas is influenced
by numerous factors including land cover and terrain irregularities. Moreover,
building artifacts in global DEMs cause artificial blocking of surface flow
pathways. This compromises their quality and adequacy for hydrological and
environmental modelling in urban landscapes where precise and accurate terrain
information is needed. In this study, the extreme gradient boosting (XGBoost)
ensemble algorithm is adopted for enhancing the accuracy of two
medium-resolution 30m DEMs over Cape Town, South Africa: Copernicus GLO-30 and
ALOS World 3D (AW3D). XGBoost is a scalable, portable and versatile gradient
boosting library that can solve many environmental modelling problems. The
training datasets are comprised of eleven predictor variables including
elevation, urban footprints, slope, aspect, surface roughness, topographic
position index, terrain ruggedness index, terrain surface texture, vector
roughness measure, forest cover and bare ground cover. The target variable
(elevation error) was calculated with respect to highly accurate airborne
LiDAR. After training and testing, the model was applied for correcting the
DEMs at two implementation sites. The correction achieved significant accuracy
gains which are competitive with other proposed methods. The root mean square
error (RMSE) of Copernicus DEM improved by 46 to 53% while the RMSE of AW3D DEM
improved by 72 to 73%. These results showcase the potential of gradient boosted
trees for enhancing the quality of DEMs, and for improved hydrological
modelling in urban catchments.Comment: 8 page
The E-Agriculture Research Landscape In South Africa: A Systematic Literature Review
Despite the growing interest in e-agriculture research in South Africa, academic studies have not sufficiently and deeply investigated the current e-agriculture research trends in the South African context. It is unclear how primary e-agriculture research in South Africa will aid both current and future generations to create new and better ways to transform agricultural development using this modern technology. This study sought to determine the current status of e-agriculture research in the South African context. A systematic literature review was used to gather and analyze data. The results indicate that 17 papers (26.5%) were published during the first two years (2010-2011) and 28 papers (43.7%) during the last two years (2014-2015). The results of the study further indicate that the use of satellite enhancing agriculture (14 papers, 21.8%) was the most prominent e-agriculture research area in South Africa (27 papers, 23.6%). The results of this study show that information mapping was the most used research method by researchers in their studies (30 papers, 46.8%). The results of the study helped to understand the importance of enhancing research capability and socio-economic transformation of farmworkers and farmers through enhanced communication of agriculture research knowledge in the area of agricultural informatics
Target tracking enhancement using a Kalman filter in the presence of interference
In this paper we present a new target tracking enhancement system that uses a Kalman filter in the presence of interference. If the radar (seeker) is affected by different types of interference, this will affect the missile trajectory towards the target and may cause inaccurate tracking. In the new system a six-state Kalman filter is utilized to perform the tracking task and to carry out smoothing to the corrupted trajectory. This also provides good information about the target velocity in three dimensions which is very important information about the target. A three dimensional scenario between target (with high manoeuvre) and missile is used to illustrate the performance of the system in the case when (i) no interference is present and (ii) interference is present. The performance of the filtered trajectory using the Kalman tracker will be assessed for different guidance methods: including (i) proportional navigation (ii) pure pursuit and (iii) constant bearing. The Kalman improvement for the tacking for the three guidance method will be analysed
Characteristics of the Global Radio Frequency Interference in the Protected Portion of L-Band
The National Aeronautics and Space Administration’s (NASA’s) Soil Moisture Active–Passive (SMAP) radiometer has been providing geolocated power moments measured within a 24 MHz band in the protected portion of L-band, i.e., 1400–1424 MHz, with 1.2 ms and 1.5 MHz time and frequency resolutions, as its Level 1A data. This paper presents important spectral and temporal properties of the radio frequency interference (RFI) in the protected portion of L-band using SMAP Level 1A data. Maximum and average bandwidth and duration of RFI signals, average RFI-free spectrum availability, and variations in such properties between ascending and descending satellite orbits have been reported across the world. The average bandwidth and duration of individual RFI sources have been found to be usually less than 4.5 MHz and 4.8 ms; and the average RFI-free spectrum is larger than 20 MHz in most regions with exceptions over the Middle East and Central and Eastern Asia. It has also been shown that, the bandwidth and duration of RFI signals can vary as much as 10 MHz and 10 ms, respectively, between ascending and descending orbits over certain locations. Furthermore, to identify frequencies susceptible to RFI contamination in the protected portion of L-band, observed RFI signals have been assigned to individual 1.5 MHz SMAP channels according to their frequencies. It has been demonstrated that, contrary to common perception, the center of the protected portion can be as RFI contaminated as its edges. Finally, there have been no significant correlations noted among different RFI properties such as amplitude, bandwidth, and duration within the 1400–1424 MHz ban
Digital elevation model correction in urban areas using extreme gradient boosting, land cover and terrain parameters
The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLVIII-4/W9-2024
GeoAdvances 2024 – 8th International Conference on GeoInformation Advances, 11–12 January 2024, Istanbul, Türkiye.LIDAR data for the
City of Cape Town was provided by the Information and
Knowledge Management Department, City of Cape Town.The accuracy of digital elevation models (DEMs) in urban areas is influenced by numerous factors including land cover and terrain
irregularities. Moreover, building artefacts in global DEMs cause artificial blocking of surface flow pathways. This compromises
their quality and adequacy for hydrological and environmental modelling in urban landscapes where precise and accurate terrain
information is needed. In this study, the extreme gradient boosting (XGBoost) ensemble algorithm is adopted for enhancing the
accuracy of two medium-resolution 30-metre DEMs over Cape Town, South Africa: Copernicus GLO-30 and ALOS World 3D
(AW3D). XGBoost is a scalable, portable and versatile gradient boosting library that can solve many environmental modelling
problems. The training datasets are comprised of eleven predictor variables including elevation, urban footprints, slope, aspect,
surface roughness, topographic position index, terrain ruggedness index, terrain surface texture, vector roughness measure, forest
cover and bare ground cover. The target variable (elevation error) was calculated with respect to highly accurate airborne LiDAR.
After training and testing, the model was applied for correcting the DEMs at two implementation sites. The corrections achieved
significant accuracy gains which are competitive with other proposed methods. There was a 46 – 53% reduction in the root mean
square error (RMSE) of Copernicus DEM, and a 72 - 73% reduction in the RMSE of AW3D DEM. These results showcase the
potential of gradient-boosted decision trees for enhancing the quality of global DEMs, especially in urban areas.The Commonwealth Scholarship Commission
UK, and the University of Cape Town Postgraduate Funding
Office.http://www.isprs.org/publications/archives.aspxhj2024Geography, Geoinformatics and MeteorologySDG-11:Sustainable cities and communitie
Evaluation of ALOS PALSAR Data for High-Resolution Mapping of Vegetated Wetlands in Alaska
As the largest natural source of methane, wetlands play an important role in the carbon cycle. High-resolution maps of wetland type and extent are required to quantify wetland responses to climate change. Mapping northern wetlands is particularly important because of a disproportionate increase in temperatures at higher latitudes. Synthetic aperture radar data from a spaceborne platform can be used to map wetland types and dynamics over large areas. Following from earlier work by Whitcomb et al. (2009) using Japanese Earth Resources Satellite (JERS-1) data, we applied the “random forests” classification algorithm to variables from L-band ALOS PALSAR data for 2007, topographic data (e.g., slope, elevation) and locational information (latitude, longitude) to derive a map of vegetated wetlands in Alaska, with a spatial resolution of 50 m. We used the National Wetlands Inventory and National Land Cover Database (for upland areas) to select training and validation data and further validated classification results with an independent dataset that we created. A number of improvements were made to the method of Whitcomb et al. (2009): (1) more consistent training data in upland areas; (2) better distribution of training data across all classes by taking a stratified random sample of all available training pixels; and (3) a more efficient implementation, which allowed classification of the entire state as a single entity (rather than in separate tiles), which eliminated discontinuities at tile boundaries. The overall accuracy for discriminating wetland from upland was 95%, and the accuracy at the level of wetland classes was 85%. The total area of wetlands mapped was 0.59 million km2, or 36% of the total land area of the state of Alaska. The map will be made available to download from NASA’s wetland monitoring website
A Global Systematic Review of Improving Crop Model Estimations by Assimilating Remote Sensing Data: Implications for Small-Scale Agricultural Systems
There is a growing effort to use access to remote sensing data (RS) in conjunction with crop model simulation capability to improve the accuracy of crop growth and yield estimates. This is critical for sustainable agricultural management and food security, especially in farming communities with limited resources and data. Therefore, the objective of this study was to provide a systematic review of research on data assimilation and summarize how its application varies by country, crop, and farming systems. In addition, we highlight the implications of using process-based crop models (PBCMs) and data assimilation in small-scale farming systems. Using a strict search term, we searched the Scopus and Web of Science databases and found 497 potential publications. After screening for relevance using predefined inclusion and exclusion criteria, 123 publications were included in the final review. Our results show increasing global interest in RS data assimilation approaches; however, 81% of the studies were from countries with relatively high levels of agricultural production, technology, and innovation. There is increasing development of crop models, availability of RS data sources, and characterization of crop parameters assimilated into PBCMs. Most studies used recalibration or updating methods to mainly incorporate remotely sensed leaf area index from MODIS or Landsat into the WOrld FOod STudies (WOFOST) model to improve yield estimates for staple crops in large-scale and irrigated farming systems. However, these methods cannot compensate for the uncertainties in RS data and crop models. We concluded that further research on data assimilation using newly available high-resolution RS datasets, such as Sentinel-2, should be conducted to significantly improve simulations of rare crops and small-scale rainfed farming systems. This is critical for informing local crop management decisions to improve policy and food security assessments
Remote Sensing of Snow Cover Using Spaceborne SAR: A Review
The importance of snow cover extent (SCE) has been proven to strongly link with various
natural phenomenon and human activities; consequently, monitoring snow cover is one the most
critical topics in studying and understanding the cryosphere. As snow cover can vary significantly
within short time spans and often extends over vast areas, spaceborne remote sensing constitutes
an efficient observation technique to track it continuously. However, as optical imagery is limited
by cloud cover and polar darkness, synthetic aperture radar (SAR) attracted more attention for its
ability to sense day-and-night under any cloud and weather condition. In addition to widely applied
backscattering-based method, thanks to the advancements of spaceborne SAR sensors and image
processing techniques, many new approaches based on interferometric SAR (InSAR) and polarimetric
SAR (PolSAR) have been developed since the launch of ERS-1 in 1991 to monitor snow cover under
both dry and wet snow conditions. Critical auxiliary data including DEM, land cover information,
and local meteorological data have also been explored to aid the snow cover analysis. This review
presents an overview of existing studies and discusses the advantages, constraints, and trajectories of
the current developments
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