Microwave Remote Sensing Tools in Environmental Science , 1st ed. 2020

Contents

1 Basic Concepts of Microwave Radiometry

1.1 Introduction

1.2 Principal Concept of Remote Monitoring Technology

1.3 Microwave Emission from the Water and Land Surfaces

1.3.1 Brightness Temperature

1.3.2 Dielectric Constant

1.3.4 Microwave Radiation Sensitivity to Variations of Basic Environmental Parameters

1.4 Remote-Sensing Research Platforms and their Equipping

1.5 Microwave Polarization Characteristics of Snow

1.5.1 Introduction

1.5.2 Theoretical and Empirical Tools for Studying the Microwave Irradiation of the Snow Layer

1.5.3 Experimental measurements

2 Remote Sensing Technologies and Data Processing Algorithms

2.1 Microwave Methods

2.2 Physical, Theoretical and Experimental Background of Microwave Monitoring

2.3 Remote Sensing Technologies in Infrared and Optical Bands

2.4 The atmosphere Microwave Monitoring

2.5 Algorithms for Remote Data Processing

2.5.1 Data Reconstruction Using the Harmonic Functions

2.5.2 Method for Parametric Identification of Environmental Objects

2.5.3 Method of Differential Approximation

2.5.4 Quasi-linearization Method

2.6 Interpretation Technology for Remote Sensing Data

2.7 Multi-Channel Microwave Sensor to Measure Environmental Parameters

2.8 Direct and Inverse Problems of Microwave Monitoring

2.9 Interferometry Methods in the Geo-risk Assessment Tasks

3 Constructive Method of Vegetation Microwave Monitoring

3.1 The Information-Modeling Technology

3.2 Microwave Monitoring of Soil-Plant Formations

3.3 Links between Experiments, Algorithms, and Models

3.4 Microwave model of vegetation cover

3.4.1 Two-Level Model of Vegetation Cover

3.4.2 Analytical Model of Vegetation Cover

3.5 Microwave Radiation of the Soil-Plant Systems

4 Microwave Remote Sensing of Soil Moisture

4.1 Uncertainty and Risk Sources in Remote Sensing

4.2 Practical Microwave Radiometric Risk Assessment of Agricultural Function

4.3 Geoinformation Monitoring System of Agricultural Function

4.4 Microwave Monitoring of Soil Moisture
4.5 The State of Soils and Water Objects Evaluated by Means of Radiometry Methods

5 Vegetation Screening Effect in the Remote Sensing Monitoring

5.1 Introduction

5.2 Attenuation of Electromagnetic Waves in Vegetation Media

5.3 Measuring System for Retrieving Attenuation of Microwaves in the Vegetation.

5.4 Experimental Results

5.5 Theoretical Generalization

5.6 Conclusions and Discussion

6 Microwave Tools for the Diagnostics of Forest Fires

6.1 Wildfire Causes

6.2 Wildfires and Global Ecodynamics

6.2.1 Fires and Forest Ecosystems

6.2.2 Wildfires, Dynamics of the Biosphere, and Climate

6.2.3 Biomass Burning and Atmospheric Chemistry

6.3 Microwave Radiometric Observations of Temperature Anomalies

6.4. Features of Microwave Monitoring of Wildfires

6.4.1 Microwave Model of the Wildfires

6.4.2 Fire Forest Risks

6.4.3 SHF-Radiation of the Forest Fires

6.4.4 Natural SHF-Radiation of the Peat Formations

7. Space Methods and Monitoring Tools for the Investigation of Aquatic Systems.

7.1 Introduction

7.2 Microwave Radiometry in the Remote Monitoring of the Ocean

7.3 Application of Big Data Approach to the Study of Arctic Basin Pollution

7.3.1. Introduction

7.3.2 Geoecological Information-Modeling System

7.3.3 Modeling the Pollutant Dynamics in the Arctic Basin

7.3.4 Simulation Experiments

7.3.5 Conclusions and Discussion

7.4 Implication of Geoecological Information-Modeling System for the Okhotsk Sea Ecosystem Study

7.4.1 Quick Analysis of the Okhotsk Sea Ecosystem

7.4.2 Model of the Okhotsk Sea Ecosystem

7.4.3 Biocomplexity and Survivability Indicators

7.4.4 Simulation Results

7.4.5 Conclusion and Discussion

7.5 The Peruvian Current Ecosystem and Ecoinformatics Tools

7.5.1 Introduction

7.5.2 Block-Diagram and Principal Equations of the Peruvian Current Ecosystem Model

7.5.3 Results of Simulation Experiments

7.5.4 The Effects of Environment Parameter Variations

7.6 A New Scenario for Recovering the Water Balance of the Aral Sea

7.6.1 Water Problems in Central Asia

7.6.2 Aral-Caspian Regional Water Cycle Model.

7.6.3 Remote Sensing Database of the Aral Sea Zone Environment

7.7 Mathematical Modelling and Numerical Experiment in the Geophysical Study of the Aral Sea Region

7.7.1 Model for Structured-Functional Analysis of Hydrophysical Fields of the Aral Sea

7.7.2 Model of the Regional Water Balance of the Aral Sea Aqua-geosystem

7.7.3 Model of the Kara-Bogaz-Gol Gulf Aqua-geosystem

7.7.4 Parameterization of the Water Balance of the Aral Sea Region

7.8 Simulation Experiments and Forecast of the Water Balance Components of the Aral Sea Hollow

7.8.1 Scenario for Potential Directions of the Change in Water Balance Components of the Aral Sea

7.8.2 Model Estimation of the Aral Sea Water Balance Dynamics in Case of the Preserved Natural-Anthropogenic Situation in the Region

7.8.3 Recommendations for the Monitoring Regime of the Aral Sea Aqua-geosystem

7.8.4 Reliability of Scenario Realization

8 Microwave Remote Sensing Monitoring and Global Climate Change Problems

8.1 Introduction

8.2 Interactive Character of the Global Climate Problems

8.2.1 Anomalous Situations and Climate

8.2.2 Global Carbon Cycle and its Climatic Implications

8.2.3 Sources and Sinks of Carbon Dioxide in the Biosphere

8.3 Anthropogenic Sources of Carbon

8.4 Resources of the Biosphere and the Greenhouse Effect

8.5 The Greenhouse Effect and Global Carbon Cycle

8.6 A Coupled Model of Carbon Dioxide and Methane Global Cycles

8.6.1 Introduction

8.6.2 Conceptual Scheme of Global Carbon Dioxide and Methane Global Cycles

8.6.3 Simulation Results

8.6.4 Conclusions and Discussion of the Results

8.7 Microwave Remote Sensing Monitoring and Environmental Problems

8.8 Aerosol Radiative Forcing and Climate

8.8.1 The Problem with Survey

8.8.2 Empirical Diagnostics of the Global Climate

8.8.3 The Radiative Forcing

9 Global Climate Monitoring with Microwave Measurements

9.1 Microwave Monitoring of Disasters

9.2 Nature and Human Society Interactions

9.4 Spatial and Temporal Characteristics of Natural Disasters

9.5 Environmental Impacts of Natural Disasters

9.6 Role of Natural Disasters in the Climate/Biosphere System Evolution

9.7 Reality and Expected Changes of the Environment

9.8 The Current Needs on Ecological-Climatic Modelling

9.9 Satellite Observations of Climate-Nature-Society System Dynamics

9.10.1 Short Description of the Problem

9.10.2 General Description of the Survivability Model

9.10.3 A Scenario-Based Prognosis

9.10.4 With a View to the Future

References

Index

Vladimir F. Krapivin was educated at the Moscow State University as mathematician in 1959. He received his PhD in radiophysics from the Kotelnikov Institute of Radioengineering and Electronics (KIRE) of Russian Academy of Sciences (RAS) in 1966. The Doctoral Dissertation in geophysics was defended him at the Moscow Institute of Oceanology of RAS in 1973. He became Full Professor of Radiophysics in 1987. The title “Honoured Worker of Science” was given to him in 1999 by Russian Government. He was appointed Grand Professor in 2012 at the Nguyen Tat Thanh University (Vietnam). Vladimir Krapivin is a full member of the Russian Academy of Natural Sciences. He has published 37 books and 570 papers in the field of ecoinformatics, remote-sensing and global modeling. At present time he is chief scientists of KIRE and he has specialized in investigating global environmental change by th

Offers interdisciplinary knowledge for the parameterization of global biogeochemical cycles

Highlights new approaches to the to the building-up of environmental monitoring systems, based on physics, mathematics, ecology and informatics

A focus on applications areas of eco-informatics methods and remote sensing tools