Available Student and Research Projects
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==Micro-Manipulation== | ==Micro-Manipulation== |
Revision as of 23:41, 4 March 2008
Contents |
Student Projects
We always offer projects to motivated students (first degree, Masters of Science, ERASMUS student, ...). If you are interested in doing a project in computer vision, let us know. Here is a description of ongoing research areas to give you an idea of possible projects.
You can also suggest a research topic yourself.
If you work with us, you can learn a lot of skills which are relevant for a career as a software developer:
- Computer Vision, Signal processing, Robotics
- Linear Algebra, Analysis
- Software Engineering
We are using state-of-the-art cross-platform software tools:
- Source-code documentation with doxygen
- Cross-platform user-interfaces with Qt. You can develop full-featured GUI-software which runs under GNU/Linux, Microsoft Windows, and MacOS!
- Platform-independent Standard Template Library
- Platform-independent Boost Library
- Scripting using the dynamically-typed object-oriented programming language Ruby
Project areas
Stitching for microscopes
Premise
- A microscope-video of an object being moved in x-, and y-direction (parallel to the focussed plane)
- Later a microscope-video of an object being moved in x-, y-, and z-direction (i.e. including depth changes)
To Do
- Generate stitched image from the input-video (linear complexity desirable) without feedback from microscope-drive
- Cross-compare images to avoid a drift of the estimated shift
- Later provide extended depth of field by maximising a focus measure.
See Also
External Links
Micro-Manipulation
This project is about manipulating objects which can be seen under a microscope. The size of the objects typically is up to about 750 micrometers.
Premise
An optical microscope with a motorized stage and a low-cost firewire video camera. There is an early prototype of a gripper mounted on a microtranslation stage. Parts with limited accuracy can be manufactured using rapid prototyping or in the lab.
To Do
The task is to construct and build a more advanced gripper. Possible ideas are:
- Use strain gauges to have feedback
- Develop gripper with more degrees of freedom
See Also
External Links
- John Speich, Michael Goldfarb: A compliant-mechanism-based three degree-of-freedom manipulator for small-scale manipulation (PDF)
- Ying-Chien Tsai, Sio Hou Lei, Hendra Sudin: Design and analysis of planar compliant microgripper based on kinematic approach