Almost 70% of planet Earth is covered by water. A large percentage of underwater
environment is unexplored. In the past two decades, there has been an increase in the
interest of exploring and monitoring underwater life among scientists and in industry.
Underwater operations are extremely difficult due to the lack of cheap and efficient
means. Recently, Wireless Sensor Networks have been introduced in underwater
environment applications. However, underwater communication via acoustic waves is
subject to several performance limitations, which makes the relevant research issues
very different from those on land. In this thesis, we investigate node placement
for building an initial Underwater Wireless Sensor Network infrastructure. Firstly,
we formulated the problem into a nonlinear mathematic program with objectives of
minimizing the total transmission loss under a given number of sensor nodes and
targeted volume. We conducted experiments to verify the proposed formulation,
which is solved using Matlab optimization tool. We represented each node with a
truncated octahedron to fill out the 3D space. The truncated octahedrons are tiled in
the 3D space with each node in the center where locations of the nodes are given using 3D coordinates. Results are supported using ns-3 simulator. Results from simulation
are consistent with the obtained results from mathematical model with less than 10%
error.
Date of Award | Oct 2011 |
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Original language | English (US) |
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Awarding Institution | - Computer, Electrical and Mathematical Sciences and Engineering
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Supervisor | Basem Shihada (Supervisor) |
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- wireless
- sensor
- network
- underwater
- design
- performance