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Author: Li Fang Publisher: ISBN: Category : Geostationary satellites Languages : en Pages : 172
Book Description
Geostationary Operational Environmental Satellite (GOES) have been continuously monitoring earth surface since early 1970. The frequent observations provided by GOES sensors make them attractive for deriving information on the diurnal land surface temperature (LST) cycle and diurnal temperature range. These parameters are of great value for the research on the Earth's diurnal variability and climate change. Accurate extraction of satellite-based LSTs has long been an interesting and challenging research area in thermal remote sensing. However, derivation of LST from satellite measurements is a difficult task because surface emitted thermal infrared radiance is dependent on both land surface temperature and land surface emissivity (LSE), two closely coupled variables. Satellite LST retrievals have been conducted for over forty years from a variety of polar-orbiting satellites and geostationary satellites. Literature relevant to satellite-based LST retrieval techniques have been reviewed. Specifically, the evolution of two LST algorithm families, temperature and emissivity separation method (TES) and Split Window (SW) approach, have been studied in this work. This work also summarizes the LST retrieval methods especially adopted for geostationary satellites. All the existing methods could be a valuable reference to develop the LST retrieval algorithms for generating GOES LST product. The primary objective of this study is the development of models for deriving consistent GOES LSTs with high spatial and high temporal coverage. Proper LST retrieval algorithms will be studied according to the characteristics of sensors onboard the GOES series. A new TES approach is proposed in this study for deriving LST and LSE simultaneously by using multiple-temporal satellite observations from GOES 8 to GOES 12 series. Two split-window regression formulas are selected for this approach, and two satellite observations over the same geolocation within a certain time interval are utilized. This method is particularly applicable to geostationary satellite missions from which qualified multiple-temporal observations are available. Dual-window LST algorithm is adopted to derive LST from GOES M (12)-Q series. Instead of using conventional training method to generate optimum coefficients of the LST regression algorithms, a regression tree technique is introduced to automatically select the criteria and the boundary of the sub-ranges for generating algorithm coefficients under different conditions. GOES measurements as well as ancillary data, including satellite and solar geometry, water vapor, cloud mask, land emissivity etc., have been collected to test the performance of the proposed LST retrieval algorithms. In addition, in order to validate the retrieval precision, the satellite-based temperature will be compared against ground truth temperatures, which include direct skin temperature measurements from the Atmospheric Radiation Measurement program (ARM), as well as indirect measurements like surface long-wave radiation observations over six vegetated sites from the SURFace RADiation Budget (SURFRAD) Network. The validation results demonstrate that the proposed GOES LST algorithms are capable of deriving consistent surface temperatures with good retrieval precision. Consistent GOES LST retrievals with high spatial and temporal coverage are expected to better serve the detections and observations of meteorological phenomena and climate change over the land surface.
Author: Li Fang Publisher: ISBN: Category : Geostationary satellites Languages : en Pages : 172
Book Description
Geostationary Operational Environmental Satellite (GOES) have been continuously monitoring earth surface since early 1970. The frequent observations provided by GOES sensors make them attractive for deriving information on the diurnal land surface temperature (LST) cycle and diurnal temperature range. These parameters are of great value for the research on the Earth's diurnal variability and climate change. Accurate extraction of satellite-based LSTs has long been an interesting and challenging research area in thermal remote sensing. However, derivation of LST from satellite measurements is a difficult task because surface emitted thermal infrared radiance is dependent on both land surface temperature and land surface emissivity (LSE), two closely coupled variables. Satellite LST retrievals have been conducted for over forty years from a variety of polar-orbiting satellites and geostationary satellites. Literature relevant to satellite-based LST retrieval techniques have been reviewed. Specifically, the evolution of two LST algorithm families, temperature and emissivity separation method (TES) and Split Window (SW) approach, have been studied in this work. This work also summarizes the LST retrieval methods especially adopted for geostationary satellites. All the existing methods could be a valuable reference to develop the LST retrieval algorithms for generating GOES LST product. The primary objective of this study is the development of models for deriving consistent GOES LSTs with high spatial and high temporal coverage. Proper LST retrieval algorithms will be studied according to the characteristics of sensors onboard the GOES series. A new TES approach is proposed in this study for deriving LST and LSE simultaneously by using multiple-temporal satellite observations from GOES 8 to GOES 12 series. Two split-window regression formulas are selected for this approach, and two satellite observations over the same geolocation within a certain time interval are utilized. This method is particularly applicable to geostationary satellite missions from which qualified multiple-temporal observations are available. Dual-window LST algorithm is adopted to derive LST from GOES M (12)-Q series. Instead of using conventional training method to generate optimum coefficients of the LST regression algorithms, a regression tree technique is introduced to automatically select the criteria and the boundary of the sub-ranges for generating algorithm coefficients under different conditions. GOES measurements as well as ancillary data, including satellite and solar geometry, water vapor, cloud mask, land emissivity etc., have been collected to test the performance of the proposed LST retrieval algorithms. In addition, in order to validate the retrieval precision, the satellite-based temperature will be compared against ground truth temperatures, which include direct skin temperature measurements from the Atmospheric Radiation Measurement program (ARM), as well as indirect measurements like surface long-wave radiation observations over six vegetated sites from the SURFace RADiation Budget (SURFRAD) Network. The validation results demonstrate that the proposed GOES LST algorithms are capable of deriving consistent surface temperatures with good retrieval precision. Consistent GOES LST retrievals with high spatial and temporal coverage are expected to better serve the detections and observations of meteorological phenomena and climate change over the land surface.
Author: Shunlin Liang Publisher: Springer Science & Business Media ISBN: 3319025880 Category : Technology & Engineering Languages : en Pages : 171
Book Description
This book describes the algorithms, validation and preliminary analysis of the Global LAnd Surface Satellite (GLASS) products, a long-term, high-quality dataset that is now freely available worldwide to government organizations and agencies, scientific research institutions, students and members of the general public. The GLASS products include leaf area index, broadband albedo, broadband emissivity, downward shortwave radiation and photosynthetically active radiation. The first three GLASS products cover 1981 to 2012 with 1km and 5km spatial resolutions and 8-day temporal resolution, and the last two GLASS products span 2008 to 2010 with 3-hour temporal resolution and 5km spatial resolution. These GLASS products are unique. The first three are spatially continuous and cover the longest period of time among all current similar satellite products. The other two products are the highest spatial-resolution global radiation products from satellite observations that are currently available. These products can be downloaded from Beijing Normal University at http://glass-product.bnu.edu.cn/ and the University of Maryland Global Land Cover Facility at http://www.glcf.umd.edu/ The GLASS products are the outcome of a key research project entitled “Generation & Applications of Global Products of Essential Land Variables”, supported by funding from the High-Tech Research and Development Program of China and involving dozens of institutions and nearly one hundred scientists and researchers. Following an introduction, the book contains five chapters corresponding to these five GLASS products: background, algorithm, quality control and validation, preliminary analysis and applications. It discusses the long-term environmental changes detected from the GLASS products and other data sources at both global and local scales and also provides detailed analysis of regional hotspots where environmental changes are mainly associated with climate change, drought, land-atmosphere interactions, and human activities. The book is based primarily on a set of published journal papers about these five GLASS products and includes updated information. Since these products have now begun to be widely used, this book is an essential reference document. It is also a very helpful resource to anyone interested in satellite remote sensing and its applications.
Author: Juan Manuel Sánchez Publisher: Mdpi AG ISBN: 9783036514284 Category : Science Languages : en Pages : 338
Book Description
This book is a collection of recent developments, methodologies, calibration and validation techniques, and applications of thermal remote sensing data and derived products from UAV-based, aerial, and satellite remote sensing. A set of 15 papers written by a total of 70 authors was selected for this book. The published papers cover a wide range of topics, which can be classified in five groups: algorithms, calibration and validation techniques, improvements in long-term consistency in satellite LST, downscaling of LST, and LST applications and land surface emissivity research.
Author: Steven J. Goodman Publisher: Elsevier ISBN: 0128143282 Category : Science Languages : en Pages : 306
Book Description
The GOES-R Series: A New Generation of Geostationary Environmental Satellites introduces the reader to the most significant advance in weather technology in a generation. The world’s new constellation of geostationary operational environmental satellites (GOES) are in the midst of a drastic revolution with their greatly improved capabilities that provide orders of magnitude improvements in spatial, temporal and spectral resolution. Never before have routine observations been possible over such a wide area. Imagine satellite images over the full disk every 10 or 15 minutes and monitoring of severe storms, cyclones, fires and volcanic eruptions on the scale of minutes. Introduces the GOES-R Series, with chapters on each of its new products Provides an overview of how to read new satellite images Includes full-color images and online animations that demonstrate the power of this new technology
Author: Glynn Hulley Publisher: Elsevier ISBN: 0128144599 Category : Science Languages : en Pages : 256
Book Description
Taking the Temperature of the Earth: Steps towards Integrated Understanding of Variability and Change presents an integrated, collaborative approach to observing and understanding various surface temperatures from a whole-Earth perspective. The book describes the progress in improving the quality of surface temperatures across different domains of the Earth’s surface (air, land, sea, lakes and ice), assessing variability and long-term trends, and providing applications of surface temperature data to detect and better understand Earth system behavior. As cooperation is essential between scientific communities, whose focus on particular domains of Earth’s surface and on different components of the observing system help to accelerate scientific understanding and multiply the benefits for society, this book bridges the gap between domains. Includes sections on data validation and uncertainty, data availability and applications Integrates remote sensing and in situ data sources Presents a whole earth perspective on surface temperature datasets, delving into all domains to build and understand relationships between the datasets
Author: John Qu Publisher: Springer Science & Business Media ISBN: 9400758723 Category : Science Languages : en Pages : 372
Book Description
Climate and other environmental changes are drawing unprecedented concern and attention from national governments, international organizations and local communities. Global warming has left noticeable impacts on the environment and the ecosystems it supports (including humans), and has important implications for sustainable economic and social development in the future. Satellite observations of climate and environmental change have become an increasingly important tool in recent years in helping to shape the response of international communities to this critical global challenge. The book presents the latest advances in satellite-based remote sensing of the Earth’s environment - ranging from applications in climate and atmospheric science to hydrology, oceanography, hydrology, geomorphology, ecology and fire studies. Introductory chapters also cover key technical aspects such as instrumentation, calibration, data analysis, and GIS tools for decision-making.
Author: Li Fang
Author: Li Fang
Author: Shunlin Liang
Author: Juan Manuel Sánchez
Author: Steven J. Goodman
Author: Glynn Hulley
Author: Olalekan R. Sodeinde
Author: D. D. Turner
Author: A. J. Prata
Author: John Qu
Author: Joshua D. Rhoads