Active and Passive Microwave Remote Sensing



Similar documents
The most widely used active remote sensing systems include:

A remote sensing instrument collects information about an object or phenomenon within the

Passive remote sensing systems record electromagnetic energy that was reflected (e.g., blue, green, red, and near-infrared light) or emitted (e.g.

Remote sensing is the collection of data without directly measuring the object it relies on the

Geography 403 Lecture 7 Scanners, Thermal, and Microwave

Review for Introduction to Remote Sensing: Science Concepts and Technology

Remote Sensing an Introduction

Mapping Earth from Space Remote sensing and satellite images. Remote sensing developments from war

Weather Radar Basics

High Resolution RF Analysis: The Benefits of Lidar Terrain & Clutter Datasets

Monitoring a Changing Environment with Synthetic Aperture Radar. Alaska Satellite Facility National Park Service Don Atwood

Monitoring Soil Moisture from Space. Dr. Heather McNairn Science and Technology Branch Agriculture and Agri-Food Canada

LIDAR and Digital Elevation Data

1. Introduction. FER-Zagreb, Satellite communication systems 2011/12

D.S. Boyd School of Earth Sciences and Geography, Kingston University, U.K.

Two primary advantages of radars: all-weather and day /night imaging

ENVIRONMENTAL MONITORING Vol. I - Remote Sensing (Satellite) System Technologies - Michael A. Okoye and Greg T. Koeln

AirborneHydroMapping. New possibilities in bathymetric and topographic survey

SAMPLE MIDTERM QUESTIONS

2.3 Spatial Resolution, Pixel Size, and Scale

Geospatial Software Solutions for the Environment and Natural Resources

Electromagnetic Radiation (EMR) and Remote Sensing

The premier software for extracting information from geospatial imagery.

ENVI THE PREMIER SOFTWARE FOR EXTRACTING INFORMATION FROM GEOSPATIAL IMAGERY.

Information Contents of High Resolution Satellite Images

LiDAR for vegetation applications

Joint Polar Satellite System (JPSS)

Let s SAR: Mapping and monitoring of land cover change with ALOS/ALOS-2 L-band data

Remote Sensing, GPS and GIS Technique to Produce a Bathymetric Map

NASA Earth System Science: Structure and data centers

Hyperspectral Satellite Imaging Planning a Mission

Overview. What is EMR? Electromagnetic Radiation (EMR) LA502 Special Studies Remote Sensing

Multisensor Data Integration in O&G Business Lutz Petrat Hélène Lemonnier Michael Hall

Appendix B. Introduction to Landslide Evaluation Tools Mapping, Remote Sensing, and Monitoring of Landslides

Monitoring top soil moisture through remote sensing to aid hydrologic modelling

Synthetic Aperture Radar: Principles and Applications of AI in Automatic Target Recognition

How To Monitor Sea Level With Satellite Radar

STAAR Science Tutorial 30 TEK 8.8C: Electromagnetic Waves

How Landsat Images are Made

16 th IOCCG Committee annual meeting. Plymouth, UK February mission: Present status and near future

Precipitation Remote Sensing

Global environmental information Examples of EIS Data sets and applications

Welcome to NASA Applied Remote Sensing Training (ARSET) Webinar Series

Radar Interferometric and Polarimetric Possibilities for Determining Sea Ice Thickness

Digital Remote Sensing Data Processing Digital Remote Sensing Data Processing and Analysis: An Introduction and Analysis: An Introduction

Synthetic Sensing: Proximity / Distance Sensors

Satellite Altimetry Missions

History of satellites, and implications for hurricanes monitoring and forecasting

COLLATED QUESTIONS: ELECTROMAGNETIC RADIATION

GPS Use in U.S. Critical Infrastructure. and Emergency Communications. Presented to the


Pima Regional Remote Sensing Program

The following was presented at DMT 14 (June 1-4, 2014, Newark, DE).

3D Model of the City Using LiDAR and Visualization of Flood in Three-Dimension

Satellite'&'NASA'Data'Intro'

Remote Sensing Satellite Information Sheets Geophysical Institute University of Alaska Fairbanks

Spectral Response for DigitalGlobe Earth Imaging Instruments

Finnish Meteorological Institute s Services for Insurance Sector

Land Use/Land Cover Map of the Central Facility of ARM in the Southern Great Plains Site Using DOE s Multi-Spectral Thermal Imager Satellite Images

Groundwater exploration WATEX applications with Ground Penetrating Radars. Dr.Saud Amer USGS Dr.Alain Gachet Radar Technologies France

See Lab 8, Natural Resource Canada RS Tutorial web pages Tues 3/24 Supervised land cover classification See Lab 9, NR Canada RS Tutorial web pages

Soil degradation monitoring by active and passive remote-sensing means: examples with two degradation processes

'Developments and benefits of hydrographic surveying using multispectral imagery in the coastal zone

Selecting the appropriate band combination for an RGB image using Landsat imagery

Real-time Global Flood Monitoring and Forecasting using an Enhanced Land Surface Model with Satellite and NWP model based Precipitation

Using LIDAR to monitor beach changes: Goochs Beach, Kennebunk, Maine

Preface. Ko Ko Lwin Division of Spatial Information Science University of Tsukuba 2008

Resolutions of Remote Sensing

From Whitehall to orbit and back again: using space in government

FOREST PARAMETER ESTIMATION BY LIDAR DATA PROCESSING

REMOTE SENSING AND ENVIRONMENTAL MONITORING. P. M. Mather School of Geography, The University of Nottingham, U.K.

Application of Google Earth for flood disaster monitoring in 3D-GIS

Photogrammetric Point Clouds

Files Used in this Tutorial

The YellowScan system: A test on the oppida of Nages/Roque de Viou (Languedoc, France) Tristan Allouis, PhD Research and Development, L'Avion Jaune

Ensuring the Preparedness of Users: NOAA Satellites GOES R, JPSS Laura K. Furgione

Christine E. Hatch University of Nevada, Reno

E190Q Lecture 5 Autonomous Robot Navigation

Istanbul Technical University-Center for Satellite Communications and Remote Sensing (ITU-CSCRS)

Overview of the IR channels and their applications

Wireless Broadband: Health & Safety Information

Notable near-global DEMs include

Introduction to Remote Sensing and Image Processing

Soil Moisture Estimation Using Active DTS at MOISST Site

Robot Perception Continued

Amplification of the Radiation from Two Collocated Cellular System Antennas by the Ground Wave of an AM Broadcast Station

SESSION 8: GEOGRAPHIC INFORMATION SYSTEMS AND MAP PROJECTIONS

COASTAL WIND ANALYSIS BASED ON ACTIVE RADAR IN QINGDAO FOR OLYMPIC SAILING EVENT

Chapter Contents Page No

Infrared Moisture Detection

CHAPTER 4. Electromagnetic Spectrum

Evaluating GCM clouds using instrument simulators

Various Technics of Liquids and Solids Level Measurements. (Part 3)

Treasure Hunt. Lecture 2 How does Light Interact with the Environment? EMR Principles and Properties. EMR and Remote Sensing

Transcription:

Active and Passive Microwave Remote Sensing Passive remote sensing system record EMR that was reflected (e.g., blue, green, red, and near IR) or emitted (e.g., thermal IR) from the surface of the Earth. Atmosphere 1

Active and Passive Microwave Remote Sensing Active remote sensing systems are not dependent on the Sun's EMR or the thermal properties of the Earth. Active remote sensors create their own electromagnetic energy that: 1. is transmitted from the sensor toward the terrain (and is largely unaffected by the atmosphere), 2. interacts with the terrain producing a backscatter of energy, and 3. is recorded by the remote sensor's receiver. The most widely used active remote sensing systems include: Active microwave (RADAR= RAdio Detection and Ranging), which is based on the transmission of long-wavelength microwave (e.g., 3-25 cm) through the atmosphere and then recording the amount of energy backscattered from the terrain. The beginning of the RADAR technology was using radio waves. Although radar systems now use microwave wavelength energy almost exclusively instead of radio wave, the acronym was never changed. 2

LIDAR (LIght Detection And Ranging), which is based on the transmission of relatively shortwavelength laser light (e.g., 0.90 m) and then recording the amount of light backscattered from the terrain; SONAR (SOund NAvigation Ranging), which is based on the transmission of sound waves through a water column and then recording the amount of energy backscattered from the bottom or from objects within the water column. 3

RADAR (RAdio Detection and Ranging) The ranging capability is achieved by measuring the time delay from the time a signal is transmitted to the terrain until its echo is received. Radar is capable of detecting frequency and polarization shifts. Because the sensor transmitted a signal of known wavelength, it is possible to compare the received signal with the transmitted signal. From such comparisons imaging radar detects changes in frequency that form the basis of capabilities not possible with other sensors. 4

Brief History of RADAR 1922, Taylor and Young tested radio transmission cross the Anacostia River near Washington D.C. 1935, Young and Taylor combined the antenna transmitter and receiver in the same instrument. Late 1936, Experimental RADAR were working in the U.S., Great Britain, Germany, and the Soviet Union. 1940, Plane-The circularly scanning Doppler radar (that we watch everyday during TV weather updates to identify the geographic locations of storms) 1950s, Military began using side-looking airborne radar (SLAR or SLR) 1960s, synthetic aperture radar (SAR) 1970s and 1980s, NASA launched SARs, SEASAT, Shuttle-Imaging Radar (SIR) 1990s, RADARSAT 5

Advantages: Pass through cloud, precipitation, tree canopy, dry surface deposits, snow All weather, day-and-night imaging capacity 6

7

Side-Looking (Airborne) Radar (SLAR or SLR) 8

Synthetic Aperture Radar (SAR) The principal disadvantage of real-aperture radar is that its resolution is limited by antenna length. SAR produce a very long antenna synthetically or artificially by using the forward motion of the platform to carry a relatively short real antenna to successive position along the flight line. These successive portions are treated electronically as an individual elements of the same antenna. Therefore the resolution is improved. Radar Measurements 9

Radar Measurements Wavelength and Penetration of Canopy The longer the microwave wavelength, the greater the penetration of vegetation canopy. 10

Wavelength and Penetration of Canopy The longer the microwave wavelength, the greater the penetration of vegetation canopy. 11

Imaging Radar Applications Environmental Monitoring Vegetation mapping Monitoring vegetation regrowth, timber yields Detecting flooding underneath canopy, flood plain mapping Assessing environmental damage to vegetation Hydrology Soil moisture maps and vegetation water content monitoring Snow cover and wetness maps Measuring rain-fall rates in tropical storms Oceanography Monitoring and routing ship traffic Detection oil slicks (natural and man-made) Measuring surface current speeds Sea ice type and monitoring for directing ice-breakers 12

LIDAR (LIght Detection And Ranging) Is a rapidly emerging technology for determining the shape of the ground surface plus natural and man-made features. Buildings, trees and power lines are individually discernible features. This data is digital and is directly processed to produce detailed bare earth DEMs at vertical accuracies of 0.15 meters to 1 meter. Derived products include contour maps, slope/aspect, three-dimensional topographic images, virtual reality visualizations and more. LIDAR (LIght Detection And Ranging) LIDAR data can be integrated with other data sets, including orthophotos, multispectral, hyperspectral and panchromatic imagery. LIDAR is combined with GIS data and other surveying information to generate complex geomorphic-structure mapping products, building renderings, advanced three dimensional modeling/earthworks and many more high quality mapping products. 13

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information