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Robot
Project Examples
Here
are some ideas that you could use as a term or
year-end project in your School, College or
University.
Floor
plan mapping: using
Radio modem, transmit dimensions of a floor plan back to PC CAD
drawing package.
Robot
Tag and robot war gaming strategies:
Develop
your own 'Robot Tag' game using the IR Control Freak that transmit
unique ID's for each robot and team. The robots can identify 'friend' or
'foe'. Specific data codes are used to 'ZAP' the opponent robots.
Robot's can also communicate with each other using the IR
Control Freak™ module.
See white
Paper - Robot Tag
Robocode
Wiki - (strategy games)
Balance
robots: Build and race balancing robots around
an obstacle course with ramps! An excellent exercise for any physics class!
(click
to zoom)
Examples:
http://www.geology.smu.edu/~dpa-www/robo/nbot/
http://www.tedlarson.com/robots/balancingbot.htm
http://leiwww.epfl.ch/joe/
Medical
thought Processes Simulation
Simulate thought processes that are
required to balance a robot on two wheel two legs:
Fuzzy Logic development
& simulation Using the IR
Control Freak™ Module you can develop and simulate your own rule
structure and rule matrix. See: FUZZY
LOGIC - AN INTRODUCTION by Steven D. Kaehler
School, College, University Project
Support We are interested to support Schools, Colleges and
Universities with a good project idea. Your organization can apply for a
Beta Test Program. Please download the application form here and email to
support@robotmaker.co.uk for evaluation
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Robots Swarms and Robot flocking:
Use
the MEGAbitty controller to develop a nano-class robot. There
are a lot of interesting research projects going on in this area at the
moment.
Project
Collective Microrobotics
At
Stuttgart University the “Collective
micro-robotics team” aims to explore new and innovative principles
of information and knowledge processing, adaptation and learning for the
design and development of very limited autonomous systems. These systems
represent the result of miniaturization process in such fields as
robotics, micro- and embedded controllers, sensor networks,
non-destructing control, environmental monitoring, ubiquitous systems,
medical research and several nano-technological areas. Not only software
aspects, but also a development of corresponding hardware represent the
first point of our research.
In the second point they will focus on self-organizing
phenomena in technical, in particularly micro-robotic systems. They believe
that artificial self-organization has an enormous potential: the
self-organizing systems are cheaper, more reliable, flexible and
scalable in comparison to other types of systems.
Design and implementation of
self-organizing and self-assembling artifacts.
Swarm-bots
is a project sponsored by the Future
and Emerging Technologies program of the European Community
(IST-2000-31010), aimed to study new approaches to the design and
implementation of self-organizing and self-assembling artifacts.
The project, that lasted 42 months, was successfully
completed on March 31, 2005. It has been selected as one of the success
stories of the Future and Emerging Technologies (FET) program of the
European Commission.
Large
scale distributed robot
One
project concept would be to "enable embodied research into large
scale distributed robot, sensor networks and massively distributed
robotics connected over the Internet."
Click
to Zoom
When
space is limited a three dimensional flexible printed circuit boards are
required to produce a compact design. In this example small watch motors
where use to drive the robot.
Micromechanical Flying Insect
(MFI)
http://robotics.eecs.berkeley.edu/~ronf/MFI/
Microrobotics
and Millirobotics Research
http://robotics.eecs.berkeley.edu/~ronf/milli-robot.html
Millibot
This link to the paper below. presents the design of a localization system for a team of centimeter-scale robots (Millibots) that collaborate to map and explore unknown environments. The localization system uses ultrasound to measure the distance from each moving robot to three stationary robots that serve as beacons. From these distance measurements the position of the robots is derived using a trilateration algorithm. The robot team can move over
large distances by using a 'leap-frog' approach in which different robots serve as beacons at different times.
The localization system is able to obtain position estimates more accurate than can be achieved through dead reckoning, and yet, does not require any landmarks or previously deployed beacons.
http://www-2.cs.cmu.edu/~cyberscout/new-www/publications/FSR99.pdf
Other references for Millibots are:
Pradeep
Khosla, the Philip and Marsha Dowd Professor of Engineering and Robotics and
head of the Electrical and Computer Engineering Department at PITTSBURGH-Carnegie
Mellon University
talks about the Milibot concept.
http://octopus.ius.cs.cmu.edu/~millibots/millibot_video/millibots_media_pradeep.mpg
http://www.contrib.andrew.cmu.edu/~rjg/millibots/millibot_project.html
http://octopus.ius.cs.cmu.edu/~millibots/millibot_video.html
Alice
Sandia
Liam
Smoothy
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