SATELLITE REMOTE SENSING - 2023/4
Module code: EEEM033
Module Overview
Expected prior learning: None specifically advised.
Module purpose: Earth and planetary observation with remote sensing data is playing a key role in the present understanding of natural phenomena, prevention of disasters, resources monitoring, comprehension of origins of life.
Through a series of lectures, seminars, open discussions and “thinking breaks” in class, the module aims to give an introduction to the scientific principles of remote sensing – both passive and active – as carried out by spacecraft. Remote sensing is discussed in terms of instrumentation, missions, products and applications.
IMPORTANT: The Second assessment pattern (Written Exam) is only applicable to the MSc Short Course Students.
Module provider
Computer Science and Electronic Eng
Module Leader
GUIDA Raffaella (Maths & Phys)
Number of Credits: 15
ECTS Credits: 7.5
Framework: FHEQ Level 7
Module cap (Maximum number of students): 90
Overall student workload
Independent Learning Hours: 94
Lecture Hours: 11
Tutorial Hours: 11
Laboratory Hours: 4
Guided Learning: 15
Captured Content: 15
Module Availability
Semester 1
Prerequisites / Co-requisites
None.
Module content
Indicative content includes the following.
Section 1 - INTERACTIONS, SENSORS & PLATFORMS
Introduction to Remote Sensing: Radiometry, Electromagnetic Spectrum, Radiant and Spectral quantities, Blackbodies, Planck law, Stefan-Boltzmann law, Wien displacement law.
Energy Interactions: Physics of interactions, interactions in the atmosphere (influence factors, mechanisms, effects), interactions at the Earth’s surface (the energy balance, different kinds of reflectors). Mechanisms of reflection, transmission, absorbance, scattering (Rayleigh, Mie, Non-selective).
Data acquisition and interpretation: Data acquisition, data analysis, reference data, calibration.
Sensors and Platforms: Active and Passive systems, Spatial, Spectral, Radiometric and Temporal Resolution, Swath Width, Coverage (Along-track scanner, Across-track scanner), Nadir, Signal to Noise Ratio (SNR), Payload design considerations,. Examples of some multispectral missions: LANDSAT program, SPOT program, NOAA program.
Section 2 - RADAR REMOTE SENSING
Radar Remote Sensing: Viewing geometry, Antenna Beam. Signal properties in Time Domain (Continuous wave CW and Pulsed wave PW) and Frequency domains, (Spectrum for CW and PW). Linear Frequency Modulation. Range and Doppler discrimination. Geometric distortions (Foreshortening, Layover, Shadow). Real Aperture Radar (RAR), Radar Equation (Bistatic and Monostatic), Swath width, Range resolution, Azimuth resolution, Signal Fading (speckle).
Synthetic Aperture Radar (SAR): Synthetic-Array approach, Doppler-Synthesis approach, lower and upper bounds for PRF. Configurations: stripmap, spotlight, hybrid, scansar. SAR Missions and Applications. SAR Interferometry. SAR Polarimetry. Scatterometer: basic principles. Altimeter: basic principles. Examples of SAR missions.
Section 3 - DATA QUALITY & IMAGE PROCESSING
Image Processing: Image rectification and restoration (Geometric correction, Radiometric correction, Noise removal); Image enhancement (Contrast manipulation, Spatial feature manipulation, Multi-image manipulation). Image classification (supervised and unsupervised), classifiers. Data merging: principles.
Assessment pattern
Assessment type | Unit of assessment | Weighting |
---|---|---|
Examination | 2 HOUR (OPEN BOOK) EXAM | 100 |
Alternative Assessment
N/A
Assessment Strategy
The assessment strategy for this module is designed to provide students with the opportunity to demonstrate the following:
- a basic knowledge of remote sensing principles and instrumentation and a good understanding of the interactions of radiation with the earth’s surface and atmosphere, assessed through coursework and examination;
- a good understanding of Synthetic Aperture Radar principles and applications, assessed through coursework and examination;
- a good capability of analysing end-users requirements for specific remote sensing application and converting them in technical specifications for the design of remote sensing instrumentation, assessed through coursework;
- a good knowledge of basic image processing and interpretation skills of remote sensing products, assessed through examination.
Thus, the summative assessment for this module consists of the following.
· Open book examination.
- These deadlines are indicative. For confirmation of exact date and time, please check the Departmental assessment calendar issued to you.
Formative assessment and feedback
For the module, students will receive formative assessment/feedback in the following ways.
- During lectures, by question and answer sessions and discussions
- During tutorial classes
- By means of unassessed tutorial problem sheets (with answers/model solutions)
- By means of quizzes set in SurreyLearn
- During meetings with the module coordinator
Module aims
- Introduce the student to remote sensing principles, the physical interactions of radiation with atmosphere and Earth's features;
- Introduce the student to the processing of remotely sensed data and the development of applications for Earth's resources management and monitoring for the achievement of Sustainable Development Goals (SDGs)
Learning outcomes
Attributes Developed | Ref | ||
---|---|---|---|
001 | Have a good understanding of the interactions of radiation with the earth's surface and atmosphere and be able to use this knowledge to approach the design of new sensors and address specific problems | KCPT | M2, M5 |
002 | Have a good knowledge of remote sensing instrumentation, and radar in particular | KC | M1, M6 |
003 | Have a good understanding and basic interpretation skills of remote sensing products | KCPT | M3, M4, M13 |
004 | Be capable of analysing the requirements for some relevant application in remote sensing | CPT | M5, M7 |
Attributes Developed
C - Cognitive/analytical
K - Subject knowledge
T - Transferable skills
P - Professional/Practical skills
Methods of Teaching / Learning
The learning and teaching strategy is designed to achieve the following aims:
- Through the introduction of the key concepts, representative examples and selected case studies of the use of satellite remote sensing technology.
- Through the use of revision questions with full solutions, allow the student will be able to pace their own learning in parallel with the lecture course.
Learning and teaching methods include the following.
- Lectures where key concepts will be introduced, and students will learn about the key conceptions and applications of satellite remote sensing.
- Problem classes with full sample solutions to allow the students to pace their learning at the pace they are comfortable with.
- Lab sessions allow students to gain experience of analysis of satellite remote sensing data.
- Revision sessions of past examination papers; students will be encouraged to attempt the examination papers in advance and to compare their answers with the model solution
Indicated Lecture Hours (which may also include seminars, tutorials, workshops and other contact time) are approximate and may include in-class tests where one or more of these are an assessment on the module. In-class tests are scheduled/organised separately to taught content and will be published on to student personal timetables, where they apply to taken modules, as soon as they are finalised by central administration. This will usually be after the initial publication of the teaching timetable for the relevant semester.
Reading list
https://readinglists.surrey.ac.uk
Upon accessing the reading list, please search for the module using the module code: EEEM033
Other information
This module has a capped number and may not be available to exchange students. Please check with the International Engagement Office email: ieo.incoming@surrey.ac.uk
Digital Capabilities: In this module students will be required to master specific digital resources and online platforms related to the development of Earth Observation (EO) applications. These include the Sentinel Tool Box and the Sentinel Data Hub through which they will learn about satellite data acquisition plans, data order and processing.
Employability: The module learning outcomes and the formative assessments are designed to provide students with the analytical and design skills required for an EO and image analyst expert thus developing leaders in a fast growing market, that of EO applications and services, as also prioritized by many national space strategies, included the UK one.
Global and Cultural Capabilities: through exercises of formative assessment, students will be introduced to the real world task of designing an EO application for a group of stakeholders of different background (can be cultural, societal, educational, geographical etc.) with the challenge to understand their end-users requirements and translate them in technical specifications for the EO application to develop. The challenge of dealing with a large heterogeneity in the groups of customers considered, from a specific Ministry in a Small Island Development State (SIDS) to group of farmers till defence agencies, will equip the students with the necessary global and cultural capabilities to address the same in a real work environment.
Sustainability: Earth Observation with satellite data is considered today one of the most efficient way to accelerate the achievement of the UN Sustainable Development Goals (SDGs). During the different forms of formative assessment, the design of an EO applications for a specific group of stakeholders identified, is accomplished by the students by first identifying the UN SDGs involved and then considering the indicators defined by the UN to measure the achievement of those SDGs. Students are required to specify how the use of satellite data can facilitate the tracking of the indicators involved.
Programmes this module appears in
Programme | Semester | Classification | Qualifying conditions |
---|---|---|---|
Electronic Engineering with Space Systems MEng | 1 | Optional | A weighted aggregate mark of 50% is required to pass the module |
Electronic Engineering MEng | 1 | Optional | A weighted aggregate mark of 50% is required to pass the module |
Space Engineering MSc | 1 | Optional | A weighted aggregate mark of 50% is required to pass the module |
Computer Vision, Robotics and Machine Learning MSc | 1 | Optional | A weighted aggregate mark of 50% is required to pass the module |
Electronic Engineering MSc | 1 | Optional | A weighted aggregate mark of 50% is required to pass the module |
Electronic Engineering with Computer Systems MEng | 1 | Optional | A weighted aggregate mark of 50% is required to pass the module |
Please note that the information detailed within this record is accurate at the time of publishing and may be subject to change. This record contains information for the most up to date version of the programme / module for the 2023/4 academic year.