Note: This unit is an archived version! See Overview tab for delivered versions.
AMME5981: Computational Biomedical Engineering (2014 - Semester 1)
| Unit: | AMME5981: Computational Biomedical Engineering (6 CP) |
| Mode: | Normal-Day |
| On Offer: | Yes |
| Level: | Postgraduate |
| Faculty/School: | School of Aerospace, Mechanical & Mechatronic Engineering |
| Unit Coordinator/s: |
Professor Li, Qing
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| Session options: | Semester 1 |
| Versions for this Unit: | |
| Site(s) for this Unit: |
http://web.aeromech.usyd.edu.au/AMME5981/ |
| Campus: | Camperdown/Darlington |
| Pre-Requisites: | None. |
| Brief Handbook Description: | This UoS will give students a comprehensive understanding of finite element method, material constitutive modelling, CT/MRI based solid modelling, design analysis and optimisation, and their applications in biomedical engineering. The students are expected to expand their research and development skills in relevant topics, and gain experience and skills in finite element software for the solution to sophisticated problems associated with biomedical engineering. The objectives are: 1. Understanding of the nature of biomedical engineering problems; 2. Exploring CT/MRI image processing, solid modelling etc; 3. Understanding of finite element methods and developing FE models for biomedical engineering analysis; 4. Understanding biomaterials constitutive modelling; 5. Understanding bone remodelling simulation, fracture mechanics; 6. Developing prosthetic design optimisation. |
| Assumed Knowledge: | AMME5301 AND AMME5302 AND AMME5500 AND MECH5361 AND MECH3921. AMME5302 (Materials 1), AMME5301 (Mechanics of Solids 1), AMME5500 (Engineering Dynamics); MECH3921 (Biomedical Design and Technology), MECH 5361 (Mechanics of Solids 2) |
| Additional Notes: | The primary teaching delivery method will be lectures. This UoS builds on the assumed knowledge of engineering principles and junior and intermediate biology. The purpose of this UoS is prepare students for the challenges presented in taking innovative ideas and successfully converting them to valuable products. |
| Lecturer/s: |
Professor Li, Qing
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| Tutor/s: | Paul Wong, Phillip Tran, Andrian Sue and Zhipeng Liao | ||||||||||||||||||||||||||||||
| Timetable: | AMME5981 Timetable | ||||||||||||||||||||||||||||||
| Time Commitment: |
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| T&L Activities: | Lecture: 3 Hrs Lectures per week Tutorial: 2 Hrs computer lab tutorial per week Project Work - Each student is expected to join a team/group with no more than 6 members for a real life research and development project in biomedical engineering. The student is expected to meet at least once per week to discuss thei rproject work. Each student will present to the entire class twice per semester. study time: 7 hours per week outside of formal contact hours will be needed in order to successfully complete assignments, project and study. |
Attributes listed here represent the key course goals (see Course Map tab) designated for this unit. The list below describes how these attributes are developed through practice in the unit. See Learning Outcomes and Assessment tabs for details of how these attributes are assessed.
| Attribute Development Method | Attribute Developed |
| Develop ability for design of biomedical devices and skills for presenting the design analysis. | Design (Level 4) |
| Specialisation of biomedical engineering comprising anatomy, biomechanics, biomaterials, biofabrication, biofluids, design and prototype. | Engineering/IT Specialisation (Level 4) |
| The unit provides systematic practice in use of finite element method, material constitutive modelling and CT/MRI based solid modelling in analysing the biomedical designs. In the major project, it is compulsory for postgraduates to acquire first hand raw data (CT or MRI) for the component of computational modelling. As such, they gain experience in an entire procedure from human/animals to analysis and design. | Maths/Science Methods and Tools (Level 3) |
| Information literacy. This will be developed through the literature review and project reporting. | Information Seeking (Level 3) |
| Seminar presentations and report writing as part of major project. Each student is required to conduct two presentations (mid-term and end-term) and to submit an individual report including literature review, methods and materials, results, discussion, conclusion and references. | Communication (Level 3) |
| Ethical, social, and professional understanding. This will be developed through the lecture material. | Professional Conduct (Level 3) |
| This is a project based learning unit, where students develop and implement their own projects over the course of the semester. | Project and Team Skills (Level 3) |
For explanation of attributes and levels see Engineering & IT Graduate Outcomes Table.
Learning outcomes are the key abilities and knowledge that will be assessed in this unit. They are listed according to the course goal supported by each. See Assessment Tab for details how each outcome is assessed.
Design (Level 4)
1. Knowledge and skills of design of biomedical devices
2. Understanding of design analysis, and validation
Engineering/IT Specialisation (Level 4)
3. Knowledge of materials selection in biomedical product development.
4. Knowledge of biological response, including remodelling and wound healing, in biomedical product development.
5. Knowledge of biomechanical issues in biomedical product development.
Communication (Level 3)
6. Skills of technical reporting and individual seminar presentation.
Professional Conduct (Level 3)
7. Knowledge of modelling and simulation issues in biomedical product development.
8. Knowledge of commercialisation strategies and IP protection in biomedical product development.
9. Understanding of professional society, ethics and regulationary affairs
Project and Team Skills (Level 3)
10. Skills in a team based project environment
11. Project management skills and ability of progressing the project
Information Seeking (Level 3)
12. Skills of seaching for relevant literature and patents
| Assessment Methods: |
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| Assessment Description: |
Assignment: Assignment 1 (Week 4) Assignment: Assignment 2 (Week 8) Assignment: Assignment 3 (Week 12) Report: Literature Review Report (cover 40~50 scientific articles in peer-reviewed journals) Quiz: Week 12 (total: 30%) Project: Research project on a product development issue (group work start from week 1) Give mid-term and final seminars at Week 8 and 13 respectively, and final individual report at week 13. |
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| Grading: |
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| Policies & Procedures: | See the policies page of the faculty website at http://sydney.edu.au/engineering/student-policies/ for information regarding university policies and local provisions and procedures within the Faculty of Engineering and Information Technologies. |
| Online Course Content: | http://web.aeromech.usyd.edu.au/AMME5981/ |
Note that the "Weeks" referred to in this Schedule are those of the official university semester calendar https://web.timetable.usyd.edu.au/calendar.jsp
| Week | Description |
| Week 1 | Introduction to computational modelling and software in biomedical engineering |
| Week 2 | Biomechanical modelling of musculoskeletal systems |
| Week 3 | Constitutive models of biomaterials |
| Week 4 | Introduction to CT/MRI and image processing |
| Assessment Due: Assignment #1 - CT/MRI modelling mini-project | |
| Week 5 | Solid modelling and design optimisation |
| Week 6 | Fundamentals of finite element method |
| Week 7 | Finite element modelling issues |
| Week 8 | Report of literature review and preliminary studies |
| Assessment Due: Assignment #2 - Prosthesis Modeling mini-project | |
| Assessment Due: Major Individual Project Report | |
| Week 9 | Bone remodelling and simulation |
| Week 10 | Modelling of damage, fracture and healing |
| Week 11 | Clinical applications of modelling |
| Week 12 | Quiz (one hour paper and 2 hour computer) |
| Assessment Due: Quiz | |
| Week 13 | Seminar and Final Report |
| Assessment Due: Assignment #3 - Bone Remodelling topical study | |
| Assessment Due: Presentation/Seminar (mid term) | |
| Assessment Due: Presentation/Seminar (Final) |
Course Relations
The following is a list of courses which have added this Unit to their structure.
| Course | Year(s) Offered |
| Master of Professional Engineering (Biomedical) | 2010, 2011, 2012, 2013, 2014 |
| Master of Engineering (including Grad Cert & Grad Dip) | 2013, 2014 |
Course Goals
This unit contributes to the achievement of the following course goals:
| Attribute | Practiced | Assessed |
| Design (Level 4) | Yes | 16.5% |
| Engineering/IT Specialisation (Level 4) | Yes | 40.5% |
| Communication (Level 3) | Yes | 11.5% |
| Maths/Science Methods and Tools (Level 3) | Yes | 0% |
| Professional Conduct (Level 3) | Yes | 18% |
| Project and Team Skills (Level 3) | Yes | 10.5% |
| Information Seeking (Level 3) | Yes | 3% |
These goals are selected from Engineering & IT Graduate Outcomes Table which defines overall goals for courses where this unit is primarily offered. See Engineering & IT Graduate Outcomes Table for details of the attributes and levels to be developed in the course as a whole. Percentage figures alongside each course goal provide a rough indication of their relative weighting in assessment for this unit. Note that not all goals are necessarily part of assessment. Some may be more about practice activity. See Learning outcomes for details of what is assessed in relation to each goal and Assessment for details of how the outcome is assessed. See Attributes for details of practice provided for each goal.
