Undergraduate Course: Remote Sensing and Global Climate Change (GEGR10055)
|School||School of Geosciences
||College||College of Science and Engineering
|Credit level (Normal year taken)||SCQF Level 10 (Year 3 Undergraduate)
||Availability||Available to all students
|Summary||Remote sensing from satellite platforms has become increasingly important as the only way to obtain environmental data at the spatial and temporal coverage needed to understand the processes governing global climate change. The aim of this course is to explore the role of remote sensing in monitoring planetary scale phenomena, with particular focus on the use of techniques and instruments designed to monitor the global environmental properties of the Earth. The course will also consider the significance of these measurements for testing existing models, such as ozone depletion, the hydrological cycle, global climate change and other aspects of the Earth's environment.
Week 1. INTRODUCTION (aims, course structure, context, history & importance)
Week 2. PRINCIPLES OF REMOTE SENSING (the underlying physical principles of remote sensing techniques, and some of the instruments currently in use).
Week 3. ATMOSPHERES (Dynamics, pressure, temperature, surface winds, water vapour, ozone, aerosols, cloud cover, precipitation)
Week 4. OCEANS (Sea surface temperature, ocean currents, ocean colour, bathymetry, ocean biomass, El Niņo)
Week 5. THE CRYOSPHERE (Snow and ice extent, ice sheet mapping & monitoring)
Week 6. GLOBAL WARMING (Earth radiation budget, global mean temperatures, cloud cover and feedback loops, EO and the Gaia hypothesis)
Week 7. CATCH UP AND VIDEOS
Week 8. LAND COVER AND THE BIOSPHERE (global biomass, terrestrial carbon dynamics, desertification, soil moisture, land-atmosphere interaction)
Week 9. NATURAL HAZARDS AND DISASTERS (global monitoring input to hazard warning and disaster management, radar interferometry, SST, extreme weather)
Week 10. CAPACITY BUILDING AND SUSTAINABLE DEVELOPMENT (global monitoring input to sustainable use of natural resources, international development and environmental security)
Week 11. REVISION SESSION (discussions and poster work)
Information for Visiting Students
|High Demand Course?
Course Delivery Information
|Not being delivered|
On completion of this course, the student will be able to:
- provide a detailed overview of remote sensing techniques used for measuring planetary scale processes, to convey the importance of such measurements and to explore how understanding in this subject has been developed
- explore issues of data quality, accuracy, validation and reliability, when critically assessing the value of remotely sensed data
- gain knowledge of appropriate remote sensing terminology
- think about remote sensing within a wider subject and to emphasise the role of remote sensing as a compliment rather than an alternative to other monitoring methods
- critically identify and analyse complex problems in the field of remote sensing and global climate change
|R.J. Gurney, J.L. Foster and C.L. Parkinson, Atlas of satellite observations related to global change (Cambridge University Press, 1993).|
J.E. Harries, Earthwatch: The climate from space (Ellis Horwood, 1990).
Lillesand and Kiefer, Remote Sensing and Image Interpretation (third edition) (Wiley: 1994)
Elachi, Introduction to the physics and techniques of remote sensing (John Wiley and Sons) 1987.
Houghton, Global Warming: The Complete Briefing (Cambridge University Press, 1997)
Graedel and Crutzen, Atmospheric Change, an Earth System Approach (Freeman, 1993).
I.H. Woodhouse, Introduction to Microwave Remote Sensing. (Taylor and Francis, CRC Press, 2005)
I.H. Woodhouse,Thirteen Short Chapters on Remote Sensing. (Currently only available as an eBook from Amazon, 2013)
|Graduate Attributes and Skills
|Course organiser||Prof Iain Woodhouse
Tel: (0131 6)50 2527
|Course secretary||Miss Carry Arnold
Tel: (0131 6)50 9847