Courses & Units

Modelling and Simulation of Marine Systems JEE506

Launceston, Online

Students must have access to MATLAB/Simulink software. The student version is acceptable.

Introduction

The purpose of this unit is to provide students with an understanding of modelling and simulation techniques and their application to the analysis of marine engineering systems. Students are introduced to numerical methods, control systems, first and second order systems, and the associated modelling strategies. This unit is structured around the application software MATLAB/Simulink which students will use to create programs that simulate marine systems such as pump-pipe networks, heating, ventilation and air conditioning (HVAC), marine electrical systems, and propulsion systems. The intensive learning sessions begin with learning activities on representations of dynamic systems, theory modelling of marine systems and numerical methods. Topics on theoretical modelling and simulation techniques lead on to programming activities with MATLAB and Simulink. The MALTAB and Simulink simulation programs can be used to predict dynamics of marine systems and they are validated with realistic marine systems.

Summary

Unit name	Modelling and Simulation of Marine Systems
Unit code	JEE506
Credit points	12.5
College/School	College of Sciences and Engineering Australian Maritime College
Discipline	National Centre for Maritime Engineering and Hydrodynamics
Coordinator	Doctor Hung Nguyen
Delivered By	University of Tasmania
Level	Postgraduate

Availability

Location	Study period	Attendance options		Available to
Launceston	Semester 2	On-Campus		International	Domestic
Online	Semester 2		Off-Campus	International	Domestic

Key

: On-campus
: Off-Campus
: International students
: Domestic students

Note

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Units are offered in attending mode unless otherwise indicated (that is attendance is required at the campus identified). A unit identified as offered by distance, that is there is no requirement for attendance, is identified with a nominal enrolment campus. A unit offered to both attending students and by distance from the same campus is identified as having both modes of study.

Key Dates

Study Period	Start date	Census date	WW date	End date
Semester 2	22/7/2024	16/8/2024	9/9/2024	27/10/2024

* The Final WW Date is the final date from which you can withdraw from the unit without academic penalty, however you will still incur a financial liability (refer to How do I withdraw from a unit? for more information).

Unit census dates currently displaying for 2024 are indicative and subject to change. Finalised census dates for 2024 will be available from the 1st October 2023. Note census date cutoff is 11.59pm AEST (AEDT during October to March).

About Census Dates

Learning Outcomes

1. Apply engineering principles in theoretical modelling of marine systems;
2. Apply simulation techniques, including numerical methods and block diagrams, in development of computer simulation programs for marine systems;
3. Develop MATLAB programming skills for simulation of marine systems;
4. Develop Simulink programming skills for simulation of marine systems; and
5. Use computer simulation programs to learn behaviour and characteristics of the simulated marine systems under varying conditions.

Fee Information

Field of Education	Commencing Student Contribution ^1,3	Grandfathered Student Contribution ^1,3	Approved Pathway Course Student Contribution ^2,3	Domestic Full Fee ⁴
031701	$1,118.00	$1,118.00	not applicable	$3,115.00

Available as a Commonwealth Supported Place
HECS-HELP is available on this unit, depending on your eligibility³
FEE-HELP is available on this unit, depending on your eligibility⁴

¹ Please refer to more information on student contribution amounts.
² Please refer to more information on eligibility and Approved Pathway courses.
³ Please refer to more information on eligibility for HECS-HELP.
⁴ Please refer to more information on eligibility for FEE-HELP.

If you have any questions in relation to the fees, please contact UConnect or more information is available on StudyAssist.

Please note: international students should refer to What is an indicative Fee? to get an indicative course cost.

Teaching

Teaching Pattern	Students are recommended to go through theoretical modules on MyLO. During the workshop session, students will practise modelling and programming.
Assessment	Assignment (25%)\|Assignment (25%)\|Assignment (50%)
Timetable	View the lecture timetable \| View the full unit timetable

Textbooks

Required	1. The lecturer's prepared lecture notes on MyLO. 2. Palm III, W. (2013). System Dynamics, 3rd Edition. McGraw Hill, New York.
Recommended	Chapman, S.J. (2020). MATLAB® Programming for Engineers, 6E. CL Engineering. Chapra, S.C. and R.P. Canale (2006). Numerical Methods for Engineers, 5th Edition. McGraw-Hill Higher Education, Inc. New York. Egaland, O. and J. Tommy (2002). Modelling and Simulation for Automatic Control. Marine Cybernetics, Trondheim, Norway. Fossen, T.I. (1994). Guidance and Control of Ocean Vehicles, Wiley and Sons, Inc. Fossen, T.I. (2002). Marine Control Systems – Guidance, Navigation, and Control of Ships, Rigs, and Underwater Vehicles, Marine Cybernetics, Trondheim, Norway, 2002. Fossen, T.I. (2011). Handbook of Marine Crafts Hydrodynamics and Motion Control. John Wiley and Sons, Inc. Hansen, J.F. (2000). Modelling and Control of Marine Power Systems. PhD Thesis. Norwegian University of Science and Technology. Trondheim, Norway. Huruzzaman, M. (2004). Modeling and Simulation in Simulink for Engineers and Scientists. Author House. Indiana. Kulakkowski, B.T., J.F. Gardner and J.L. Shearer (2007). Dynamic Modelling and Control of Engineering Systems. Cambridge University Press. New York. Ong, C.M. (1998). Dynamic Simulation of Electric Machinary Using MATLAB®/Simulink®. Prentice-Hall, Inc. New Jersey. Palm III, W.J. (2010). System Dynamics. 2nd Edition. McGraw Hill Higher Education. Taylor, D.A. (1987) Marine Control Practice. Butterworths, UK. Tewari, A. (2002). Modern Control Design with MATLAB and Simulink. John Wiley and Sons, Ltd. Woods, R.L. and K.L. Lawrence (1997). Modelling and Simulation of Dynamic Systems. Prentice-Hall, Inc., Upper Saddle River, New Jersey. http://www.marinecontrol.org/ http://www.marinecontrol.org/Tutorial.html http://www.mathworks.com/academia/student_center/tutorials/launchpad.html Numerical recipes series: http://www.nr.com/

Required

1. The lecturer's prepared lecture notes on MyLO.

2. Palm III, W. (2013). System Dynamics, 3rd Edition. McGraw Hill, New York.

Recommended

Chapman, S.J. (2020). MATLAB® Programming for Engineers, 6E. CL Engineering.
Chapra, S.C. and R.P. Canale (2006). Numerical Methods for Engineers, 5th Edition. McGraw-Hill Higher Education, Inc. New York.
Egaland, O. and J. Tommy (2002). Modelling and Simulation for Automatic Control. Marine Cybernetics, Trondheim, Norway.
Fossen, T.I. (1994). Guidance and Control of Ocean Vehicles, Wiley and Sons, Inc.
Fossen, T.I. (2002). Marine Control Systems – Guidance, Navigation, and Control of Ships, Rigs, and Underwater Vehicles, Marine Cybernetics, Trondheim, Norway, 2002.
Fossen, T.I. (2011). Handbook of Marine Crafts Hydrodynamics and Motion Control. John Wiley and Sons, Inc.
Hansen, J.F. (2000). Modelling and Control of Marine Power Systems. PhD Thesis. Norwegian University of Science and Technology. Trondheim, Norway.
Huruzzaman, M. (2004). Modeling and Simulation in Simulink for Engineers and Scientists. Author House. Indiana.
Kulakkowski, B.T., J.F. Gardner and J.L. Shearer (2007). Dynamic Modelling and Control of Engineering Systems. Cambridge University Press. New York.
Ong, C.M. (1998). Dynamic Simulation of Electric Machinary Using MATLAB®/Simulink®. Prentice-Hall, Inc. New Jersey.
Palm III, W.J. (2010). System Dynamics. 2nd Edition. McGraw Hill Higher Education.
Taylor, D.A. (1987) Marine Control Practice. Butterworths, UK.
Tewari, A. (2002). Modern Control Design with MATLAB and Simulink. John Wiley and Sons, Ltd.
Woods, R.L. and K.L. Lawrence (1997). Modelling and Simulation of Dynamic Systems. Prentice-Hall, Inc., Upper Saddle River, New Jersey.
http://www.marinecontrol.org/
http://www.marinecontrol.org/Tutorial.html
http://www.mathworks.com/academia/student_center/tutorials/launchpad.html
Numerical recipes series: http://www.nr.com/

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