99515 - EARTH OBSERVATION FOR CLIMATE SCIENCE

Learning outcomes

Satellite earth observation is an essential tool that allows a global and integrated view of the whole earth system, allowing quantitative measurements of a large number of relevant geophysical parameters including essential climate variables. In this courses, the students will learn the main capabilities of current satellite earth observing system and the main techniques used for the derivation of key products concerning the earth's atmosphere and surface properties. Practical exercises on satellite data analysis will be proposed during the classes.

Course contents

Module 1

1 Satellite measurements of LW and SW radiance fields (2h: theory)

•Introduction to satellite measurements and retrieva•Effective Bi-Directional Reflectance Function•Surface spectral signatures at sw•Brightness temperature•Surface emissivity at lw•The 4 microns band

2 Multi Spectral Radiometers: Detection of snow and vegetation (4h: theory and practice)

•AVHRR, ABI, SEVIRI and MODIS •Normalized difference snow index•Fractional snow cover•Ice surface emissivity and temperature•Vegetation index•Leaf Area index and Enhanced VI•Atmospheric perturbations on snow and vegetation index

3 Sea surface temperature (2h: theory and practice)

•Absorption and emission of radiation by sea water•Sea Surface temperature from infrared radiometers

4 Fire detection (2h: theory and practice)

•Fire Radiative power T•Physical rationale: Temperature sensitivity•Multichannel threshold and contextual algorithms•Normalized burn ratio

5 Water Vapor and Land Surface temperature

•Precipitable water vapor from sw channels•Split window techniques: Land surface temperature

6 RGB techniques (2h: theory and practice)

•The process of creating RGB: examples•Meteosat RGBs: natural, airmass, dust

7 Detection of aerosols from passive methods (2h: theory and practice)

•Radiative transfer equation in single scattering approximation•Aerosol reflectance over black and reflective surfaces •Global aerosol optical depth

8 Detection of clouds from passive measurements (4h: theory and practice)

•The full radiative transfer equation and the cloud parameters•Detection of thin cirrus clouds•Cloud phase derivation: techniques•Cloud altitude: co2 slicing and sorting•Nakajima-King method for cloud OD and Reff

9 Sounder data (4h: theory)

•The information content in the high spectral resolution measurements•Inversion techniques for derivation of gas and temperature profile•Optimal estimation, the role of the a-priori information•Detection of volcanic ash and outgas•Examples from IASI

 

Module 2

Basics of satellite orbits and sensor parameters:

Geostationary and low Earth orbits

Parameters: Pixel, Field of view, dwell time

Scanning techniques: whiskbroom and pushbroom sensors

Sensor noise: NeSR, NeDT, SNR

Resolution: temporal, spatial, spectral, radiometric

Dataset and products:

Climate Data Records

Copernicus Services

The Earth’s atmosphere and surface in the microwave spectrum:

RTE in the microwave

Absorption and emission of gases

Properties of water vapour and particles

Surface emissivity

Microwave active sensors:

radar equation

ground based and space-borne systems

Techniques to estimate precipitation rates with passive sensors:

The GPM constellation

Statistical and physical methods

Blended techniques

Techniques to estimate snow/ice parameters:

microwave emission from snow and glacier ice

Techniques to estimate soil moisture:

microwave emission from wet soil

space gravimetry

Validation of satellite products

Readings/Bibliography

Lecture notes and selected articles and documents

Teaching methods

The Teachers will develop the course content (6 ects) by using both the blackboard and the video projector.

The topics comprise a theoretical part (front lecture) followed by application and exercises using simple software tools ( in MATLAB) for the visualisation and analysis of satellite data.

Assessment methods

The assessment of the student's learnings is obtained by means of an oral test which serves to evaluate the achievements of the main objectives of the course:

*) understanding the fundamental laws regulating the radiative transfer in atmosphere and their application to measurements

*)understanding the main satellite measurements' methods

*) the ability to interpret satellite remote sensing data and products of atmosphere and surface

Students should demonstrate to be familiar and have a good understanding of the different subjects.

The organization of the presentation and a rigorous scientific language will be also considered for the formulation of the final grade.

The oral test will last at about 1 hour. A final grade (out of 30) is foreseen. The “cum laude” honor is granted to students who demonstrate a personal and critical rethinking of the subject

Teaching tools

The following items will be made available to Students:

* Lectures notes (in pdf format).

* Scientific articles useful for the investigation of specific lines of research.

* A data analysis software kit (in MATLAB) and satellite data

* Bibliography and references

Office hours

See the website of Tiziano Maestri

See the website of Federico Porcù