MMME4056 Integrated System sAnalysis Simulink

ESSENTIAL INFORMATIONMODULE CODE

MODULE TITLE SSESSMENT TYPE

MMME4056Integrated SystemsAnalysisSimulink and Report

COURSEWORK TITLE

WEIGHT (INDICATIVE EFFORT) MMME4056, ISA 2024, COURSEWORK30% (Approx. 10-15hrs)

FEEDBACK DETAILS

Feedback will be provided within 20 working days and will consist of an individual feedbackform. Please note the marks released on Moodle are raw. If you have made a late submissionand it is not covered by an EC or an accommodation then the deductions will be made when Isubmit the marks to the board after the exams.LEARNING OUTCOMES ASSESSED (IN BOLD)

1. Demonstrate an understanding of the concept of system behaviour and the design of

experiments for characterising system components. - AHEP4: 2, 6

2. Critically evaluate and analyse complex dynamic systems behaviour using an

appropriate numerical or analytical methodology - AHEP4: 1, 2, 3, 6

3. Evaluate the reliability of the separable system components, coupled system

components and systems as a whole - AHEP4: 6, 9

SUBMISSION REQUIREMENTS

• This exercise constitutes 30% of the total course mark and is marked out of 100.

Marks for individual sections are indicated for that section.

• Submit your coursework via MOODLE as a ZIP file. This ZIP-file should contain the

coursework report itself (as a pdf document) and all files that you used in the CW.

Please adopt the file-naming suggested in this coursework specification. More details

about ‘WHAT TO SUBMIT’ can be found in the ASSESSMENT DETAILS.

• It must be possible to open the SIMULINK models submitted using MATLAB release

R2023 or later. Models presented in different releases that cannot be opened will not

be marked.

• Your report should not exceed 20 pages including the cover page, references, and

appendixes.

• Your Coursework should have a front page which will have your name and student

number.

• Text elements should be typed. Ideally in Arial 11 point.
• Drawings and figures must be made by computer. Drawings and figures may not becopied from the internet. In ALL cases they should be appropriately titled andcaptioned. The titles and captions should be clear and legible.

• You may not discuss the details of your answers with other students. Software checkswill be made to ensure no copying or plagiarism has occurred.

• Whenever you talk about someone else’s work (including journal papers, books,conference papers, technical reports, theses/dissertations, websites, etc.) if necessary,you must include a reference to the original source of this information. You should usethe IEEE referencing style for your report. MMME4056... Integrated Systems Analysis COURSEWORK

SYSTEM DESCRIPTION.Figure 1 shows a floating wind turbine of spar-buoy type. These floatingsupports for wind turbines achieve stability by having a centre of massbelow the centre of buoyancy (i.e. the centre of gravity of the displacedwater).Spar-buoy floating arrangements are considered by some to be suitable for

very deep water. They are relatively compliant in “pitch”. That is to say,when the wind blows and exerts a downwind thrust force on the rotor ofthe wind turbine, the entire structure rocks backwards a little bit. As thestructure is moving backwards relative to the oncoming wind, the relativewind speed reduces and so a coupling arises between the thrust force, F(t),acting on the turbine and the angle of tilt, (t), of the platform. Thiscoursework is based on modelling the dynamics of such a floating windturbine platform and applying the methods taught within代写MMME4056 Integrated System sAnalysis Simulink MMME4056.The downwind thrust on a wind turbine rotor is not a simple function of

the wind speed, v(t). Every modern wind turbine has a particular fixedrated wind speed vrated. For wind speeds lower than the rated wind speed(v(t) < vrated),theturbine controller tries to extract the maximum availablepower from the air and this results in a downwind thrust that isproportional to the square of the wind speed,