last modified:
This concerns a Course |
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ECTS credit points: 3 |
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Faculty of Mechanical Engineering and Marine
Technology |
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Section of Engineering Mechanics |
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Lecturer(s): Daniel J. Rixen |
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Catalog data: |
Course year: |
MSc 1st year |
Course language: |
English |
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In case of Dutch: Please contact the lecturer about an English
alternative, whenever needed. |
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Semester: |
2A / 2B |
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Hours per week: |
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Other hours: |
16 |
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Assessment: |
Oral exam |
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Assessment period: |
2B, August |
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(see academic
calendar) |
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Prerequisites (course
codes):
Statics and
Strength of materials, Dynamics (e.g. wb1418,
wb1419), Linear Algebra, Numerical Analysis (e.g.
wi3097wb), Finite Elements (e.g.
wb1212-1214) |
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Follow up (course
codes):
Multibody
Dynamics B (wb1413) |
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Detailed description
of topics:
Using
engineering tools as black boxes can be dangerous and inefficient. This is
especially true when performing dynamic analysis of structures in a finite
element package. Choosing the right finite element types and the suitable
solution procedure is critical to get accurate results and to compute
solutions efficiently. In order to discuss basic principles of numerical
methods for dynamics and to explain fundamental concepts related to dynamic
analysis, the course will cover the following topics:
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Linear solvers, storage techniques and singular systems
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Free vibration modes, mode superposition techniques and eigensolvers
for large systems
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Accuracy of modal superposition, modal acceleration, system excited
through support
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model reduction, including dynamic substructuring
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time-integration of linear and non-linear systems
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computing senstitivity of modes and eigenfrequency to design parameters,
model updating
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Parallel computing techniques for fast solvers
Some topics might be dropped depending on
students background. Specific topics might also be discussed if time permits.
In this courses emphasis will be
put on understanding fundamental concepts of numerical methods and how they
relate to the mechanics of structures. Therefore, the oral (open book) exam
will concentrate on the mastering of concepts rather than on formulation
details. If time permits, a computational project will be included (using
Matlab pre-cooked routines and/or Ansys-Nastran). |
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Course material: |
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References from
literature:
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Remarks assessment,
entry requirements, etc.:
An assignment
will be given in ANSYS/Matlab (topic can be defined by students) time
permitting. |
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Learning goals:
The objective of
the course is to explain basic concepts specific to numerical methods
typically used in dynamic analysis codes for engineers. |
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Computer use: |
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Laboratory project(s): |
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Design content: |
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