Description
Mathematics for Engineering
Module title | Mathematics for Engineering |
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Module code | INT0046 |
Academic year | 2020/1 |
Credits | 20 |
Module staff | Robin Patrick Dixon (Convenor) |
Duration: Term | 1 | 2 | 3 |
---|---|---|---|
Duration: Weeks | 10 (C1) | 10 (C2) |
Number students taking module (anticipated) | 30 |
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Description - summary of the module content
Module description
Now that you have completed Foundation Mathematics, you will be able to study techniques that are applied to current engineering problems. This module will introduce you to the techniques you will develop further in your engineering or mathematics degree: you will learn the basics of the mathematics used in the construction of machines, buildings or satellites; develop the skills in calculus needed for basic weather forecasting and climate studies; study the mechanics used for planning the movements of objects, such as car engines, trains pulling uphill or rockets launching into space; and the trigonometry used to design communications networks, aerials and medical treatments for diseases such as cancer.
If you study this module, you will also need to take INT0045 Advanced Mathematics
Module aims - intentions of the module
This module aims to provide an advanced foundation in mathematics for students who intend to follow a degree programme in the areas of Mathematics, Engineering or related disciplines. It builds on the skills and knowledge developed in the Foundation Mathematics module. Students will be expected to manage their time successfully in order to complete a series of coursework and other tasks.
Intended Learning Outcomes (ILOs)
ILO: Module-specific skills
On successfully completing the module you will be able to...
- 1. Apply mathematical methods to solve problems requiring the use of algebraic and trigonometric formulae
- 2. Demonstrate recognition of and apply introductory techniques required in undergraduate mathematical courses
- 3. Demonstrate understanding of the basic principles of mathematics
- 4. Demonstrate understanding of the use of vectors in applications to geometry and mechanics
- 5. Apply techniques in calculus
- 6. Recognise when particular techniques are used in a variety of mathematical or engineering situations
ILO: Discipline-specific skills
On successfully completing the module you will be able to...
- 7. Demonstrate understanding of mathematical principles in Engineering and Mathematical disciplines
- 8. Construct models and solve problems which represent situations in science and engineering
- 9. Interpret answers to problems with appropriate accuracy
ILO: Personal and key skills
On successfully completing the module you will be able to...
- 10. Apply mathematical methods to address a well-defined problem
- 11. Communicate effectively in the written form
Syllabus plan
Syllabus plan
- Vectors. The scalar product; Angle between two vectors. Cartesian co-ordinates of vector in 3 dimensions. The vector equation of a straight line. Resolving vectors into horizontal and vertical components.
- Two-dimensional trigonometry. Solving trig equations for any angle in degrees in a given interval. Trigonometrical identities. Addition formula. Double angle formula. The sine and cosine rules. Solving equations of the form asinx +bcosx. Radian measure. Arc length and sector area. Solving trig equations for any angle in radians for 0 < angle < 2π.
- Polar co-ordinates. Converting between Cartesian and polar coordinates.
- Introduction to complex numbers. Adding, subtracting, and multiplying. Complex conjugate.
- Parametric equations. Drawing curves given by parametric equations.
- Differentiation of sin x, cos x, tan x. Velocity and acceleration. Differentiating functions given implicitly and parametrically. Simple Partial Differentiation (of 2 variables)
- Integrations of trig functions. Use of trig identities to integrate functions such as cos2x. Application of integration to volumes of revolution.
- Differential equations. Forming and solving simple differential equations. First order, variables separable differential equations. Numerical Solution of differential equations.
- Mechanics. Variable Acceleration. Elastic collisions; Centre of mass; Simple harmonic motion.
- Co-ordinate Geometry of Circles
Learning and teaching
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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60 | 140 | 0 |
Details of learning activities and teaching methods
Category | Hours of study time | Description |
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Scheduled Learning and Teaching activities | 40 | Small group lessons, including lectures, examples, practice and use of computing techniques (synchronous) |
Formative Assessed Activities | 20 | Working on problem solving activities and online activities (asynchronous) |
Guided independent study | 140 | Study of written notes, practise examples, using resources supplied on ELE and other on-line learning material. |
Assessment
Formative assessment
Form of assessment | Size of the assessment (eg length / duration) | ILOs assessed | Feedback method |
---|---|---|---|
Class tests and activities | 1 or 2 hours | 1-11 | Verbal and answers on ELE |
Summative assessment (% of credit)
Coursework | Written exams | Practical exams |
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30 | 70 | 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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Coursework assignments | 30 | 15 hours | 1-10 | Online feedback immediately after submission |
Final Examination (open book) | 70 | 2 hour online quiz | 1-11 | Written feedback on formal submission |
Re-assessment
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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Examination | Examination (2 hour online quiz) | 1-11 | Next assessment opportunity |
Re-assessment notes
Deferral – if you miss an assessment for reasons judged legitimate by the Mitigation Committee, the applicable assessment will normally be deferred. See ‘Details of reassessment’ for the form that assessment usually takes. When deferral occurs there is ordinarily no change to the overall weighting of that 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 take a re-sit exam. Only your performance in this exam will count towards your final module grade. A grade of 40% will be awarded if the examination is passed.
Resources
Indicative learning resources - Basic reading
Berry, C., Hanrahan, V., Porkess, R. & Secker, P. (2004). MEIA2 Pure Mathematics C3-C4: MEI Structured Mathematics. London: Hodder and Murray.
Bryden, P. (2004). MEI Mechanics 1: MEI Structured Mathematics. London: Hodder and Murray.
Bryden, P., David Holland (2004). MEI Mechanics 2: MEI Structured Mathematics. London: Hodder and Murray.
Indicative learning resources - Web based and electronic resources
ELE –http://vle.exeter.ac.uk/course/view.php?id=7016
Module has an active ELE page
Indicative learning resources - Other resources
Pledger, K., Attwood, G., MacPherson, A., Moran, B., Petran, J., Staley, G. & Wilkins, D. (2004). Core Mathematics 3: Heinemann Modular Mathematics.Oxford: Heinemann Educational.
Pledger, K., Attwood, G., MacPherson, A., Moran, B., Petran, J., Staley, G. & Wilkins, D. (2004). Core Mathematics 4: Heinemann Modular Mathematics.Oxford: Heinemann Educational.
Hebborn, J & Littlewood, J. (2004). Mechanics 1: Heinemann Modular Mathematics. Oxford: Heinemann Educational.
Credit value | 20 |
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Module ECTS | 10 |
Module pre-requisites | INT0007 Foundation Maths |
Module co-requisites | INT0020 Maths 1 for Foundation |
NQF level (module) | 3 |
Available as distance learning? | Yes |
Origin date | 20/08/2019 |
Last revision date | 30/07/2020 |