Remote Sensing for Environmental Management
Module title | Remote Sensing for Environmental Management |
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Module code | GEO2441 |
Academic year | 2021/2 |
Credits | 15 |
Module staff | Professor Karen Anderson (Convenor) |
Duration: Term | 1 | 2 | 3 |
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Duration: Weeks | 10 |
Number students taking module (anticipated) | 40 |
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Module description
Spatial data acquired by satellites, and other flying platforms are increasingly used in decision-making processes about the natural environment. These ‘remotely sensed’ data are fundamentally measurements describing the way that electromagnetic radiation interacts with materials and substances on the Earth’s surface and scientists can use these to create dynamic maps and build models describing Earth system processes through space and time. In this module you will learn about the different ways that we can use remote sensing to monitor the Earth, starting from the ground and working upwards into space where Earth observation satellites are in orbit.
Module aims - intentions of the module
This module explores the wide range of methods used by scientists for ‘remote sensing’ the Earth’s many complex processes. The module is designed so that you can explore remote sensing from a range of scales and perspectives. We begin on the ground, learning the fundamentals of electromagnetic radiation and the physics of light. This allows you to grasp the background physical principles underlying the remote sensing approach. From here, we begin to scale up – firstly to drones – lightweight aircraft operated from the ground that are emerging as the latest, and most opportunistic remote sensing tools for environmental managers to use. Then we move to piloted aircraft systems, where sensors such as LiDAR are widely used. Finally, we move into space where you will learn about the plethora of Earth observation systems in operation. Throughout the focus is on considering the applications of Earth observation data, particularly within environmental science subject areas.
You will gain hands-on experience in working with data from a range of remote sensing as we move through the module, learning cutting-edge approaches and practicing the manipulation of data through open-source software (e.g. QGIS) and cloud-based geospatial processing workflows (e.g. Google Earth Engine). We will use a variety of case studies to teach you how to use algorithms for converting remote sensing data into spatial information products that are useful to the environmental sector. By the end of the module, you will have an appreciation for the range of remote sensing systems available to environmental managers, and will be able to make decisions about the best techniques and technology to utilise for different environmental applications in your future career. These skills will be especially useful if you are seeking jobs in the environmental sector, particularly within consultancy or management companies, who are frequently turning to remote sensing to assist in environmental decision-making.
The teaching contributions on this module are drawn from practical research experience gained by Karen Anderson, principally in areas of research including field spectroscopy, laser scanning, landscape modelling, drone-based sensing and satellite data analysis.
Intended Learning Outcomes (ILOs)
ILO: Module-specific skills
On successfully completing the module you will be able to...
- 1. Recall the fundamental physical basis of remote sensing, and to describe key elements of the electromagnetic spectrum
- 2. Describe the main differences between different remote sensing systems and evaluate their relative merits effectively
- 3. Handle remote sensing data from a range of systems using computers and appropriate software
- 4. Arrive at appropriate decisions about the best remote sensing platforms and sensors for particular environmental management applications
- 5. Apply key algorithms for the extraction of spatial information from remote sensing data
- 6. Evaluate uncertainties in different remote sensing data sets
ILO: Discipline-specific skills
On successfully completing the module you will be able to...
- 7. Describe in some detail essential facts and theory across a sub-discipline of the environmental sciences
- 8. Identify critical questions from the literature and synthesise research-informed examples from the literature into written work
- 9. Identify and implement, with guidance, appropriate methodologies and theories for addressing specific research problems in environmental sciences
- 10. With some guidance, deploy established techniques of analysis, practical investigation, and enquiry within environmental sciences
- 11. Describe and evaluate approaches to our understanding of the environmental sciences with reference to primary literature, reviews and research articles
ILO: Personal and key skills
On successfully completing the module you will be able to...
- 12. Develop, with some guidance, a logical and reasoned argument with valid conclusions
- 13. Communicate ideas, principles and theories fluently using a variety of formats in a manner appropriate to the intended audience
- 14. Collect and interpret appropriate data and complete research-like tasks, drawing on a range of sources, with limited guidance
- 15. Evaluate own strengths and weaknesses in relation to professional and practical skills, and apply own evaluation criteria
- 16. Reflect effectively on learning experiences and summarise personal achievements
- 17. Work in a small team and deal proficiently with the issues that teamwork requires (ie communication, motivation, decision-making, awareness, responsibility, and management skills, including setting and working to deadlines)
Syllabus plan
The programme will consist of a a series of lectures and wider-reading focused workshops each week. During some weeks there will be a hands-on practical exercise for you to undertake, or a demonstration, or a seminar. The delivery may vary due to social distancing rules, and all practical classes will be designed to run on open source software or over cloud-based internet platforms such as Sentinel Hub and Google Earth Engine.
Topics covered include:
- Fundamentals and history of remote sensing
- Electromagnetic spectrum
- Issues of scale and resolution – spatial, spectral, temporal
- Calibration of data and quality control
- Atmospheric impacts on remote sensing data
- Platforms and sensors in remote sensing
- Monitoring land surfaces
- Monitoring ocean surfaces
- Field spectroscopy
- Drones and applications
- Airborne LiDAR and applications
- Satellite remote sensing of the Earth system
- Landsat and time-series monitoring from space
- Global remote sensing products and processing data on the cloud
- New horizons for remote sensing
Practicals will cover the following broad themes:
- Spectroscopy
- Sentinel Hub
- LiDAR analysis
- Ecological zones using Google Earth Engine
- Image classification using Google Earth Engine
- Satellite-based time series analysis using Google Earth Engine
- Drone practical (outdoors, weather permitting)
Learning activities and teaching methods (given in hours of study time)
Scheduled Learning and Teaching Activities | Guided independent study | Placement / study abroad |
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39 | 111 | 0 |
Details of learning activities and teaching methods
Category | Hours of study time | Description |
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Scheduled Learning and Teaching | 16 | Lectures |
Scheduled Learning and Teaching | 16 | Practicals and demonstrations for hands-on learning |
Scheduled Learning and Teaching | 4 | Help sessions for practical work |
Scheduled Learning and Teaching | 1 | Revision and exam preparation |
Scheduled Learning and Teaching | 2 | Student-led lecture on new RS missions for environmental data |
Guided Independent Study | 111 | Additional reading, research and preparation for module assessments |
Formative assessment
Form of assessment | Size of the assessment (eg length / duration) | ILOs assessed | Feedback method |
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Quizzes completed online | 30 minutes | All | Written feedback |
Summative assessment (% of credit)
Coursework | Written exams | Practical exams |
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100 | 0 | 0 |
Details of summative assessment
Form of assessment | % of credit | Size of the assessment (eg length / duration) | ILOs assessed | Feedback method |
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Poster | 10 | 500 words, one A3 page | 1-2, 4, 6-11, 12-16 | Written |
Practical write up | 40 | 1200 words | 1-16 | Written |
Coursework essay | 50 | 1500 words | 1-16 | Written |
Details of re-assessment (where required by referral or deferral)
Original form of assessment | Form of re-assessment | ILOs re-assessed | Timescale for re-assessment |
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Poster | Poster | 1-2, 4, 6-11, 12-14 | August assessment period |
Practical write up | Alternative essay | 1-14 | August assessment period |
Coursework essay | Coursework essay | 1-14 | August assessment period |
Re-assessment notes
Deferral – if you miss an assessment for certificated reasons judged acceptable by the Mitigation Committee, you will normally be either deferred in the assessment or an extension may be granted. The mark given for a re-assessment taken as a result of deferral will not be capped and will be treated as it would be if it were your first attempt at the assessment.
Referral – if you have failed the module overall (i.e. a final overall module mark of less than 40%) you will be required to submit a further assessment. The mark given for a re-assessment taken as a result of referral will count for 100% of the final mark and will be capped at 40%.
Indicative learning resources - Basic reading
- Campbell, J.B. (2007), Introduction to Remote Sensing.
- Lillesand, T., Kieffer, R.W., and Chipman, J. (2008) Remote Sensing and Image Interpretation
Indicative learning resources - Web based and electronic resources
Credit value | 15 |
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Module ECTS | 7.5 |
Module pre-requisites | None |
Module co-requisites | None |
NQF level (module) | 5 |
Available as distance learning? | No |
Origin date | 21/11/2013 |
Last revision date | 17/08/2020 |