Team:SDU-Denmark/project-m

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(Difference between revisions)
m (3. Description of model)
m (4. Flagella dynamics)
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First the fluid velocity at the given point is found. The method is the same whether there is 0, 1 or two walls, but the tensor used varies.
First the fluid velocity at the given point is found. The method is the same whether there is 0, 1 or two walls, but the tensor used varies.
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</p>
[[Image:Team-SDU-Denmark-2010-v(r)-dummie.gif]]
[[Image:Team-SDU-Denmark-2010-v(r)-dummie.gif]]
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The dragforce created by the fluid on the bead is calculated using the same formula we used in chapter 3
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<p style="text-align: justify;">The dragforce created by the fluid on the bead is calculated using the same formula we used in chapter 3</p>
[[Image:Team-SDU-Denmark-2010-Force-2.gif|center]]
[[Image:Team-SDU-Denmark-2010-Force-2.gif|center]]
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Once we have the force we can use it to calculate the torque on the bead, we then summarize the torques of the individual beads to get the total torque
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<p style="text-align: justify;">Once we have the force we can use it to calculate the torque on the bead, we then summarize the torques of the individual beads to get the total torque </p>
[[Image:Team-SDU-Denmark-2010-Torque-2.gif|center]]
[[Image:Team-SDU-Denmark-2010-Torque-2.gif|center]]
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We then go to from the torque to the angular acceleration by dividing with the inertia. This is also where we introduce the potential, that we mentioned earlier
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<p style="text-align: justify;">We then go to from the torque to the angular acceleration by dividing with the inertia. This is also where we introduce the potential, that we mentioned earlier</p>
[[Image:Team-SDU-Denmark-2010-Acceleration-2.gif|center]]
[[Image:Team-SDU-Denmark-2010-Acceleration-2.gif|center]]
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Now that we have the angular acceleration we can insert it into the equation of motion. This allows us to calculate the position of the flagella at the next timestep by using it's position at the current and at the previous timestep.
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<p style="text-align: justify;">Now that we have the angular acceleration we can insert it into the equation of motion. This allows us to calculate the position of the flagella at the next timestep by using it's position at the current and at the previous timestep. </p>
[[Image:Team-SDU-Denmark-2010-Angle-2.gif|center]]
[[Image:Team-SDU-Denmark-2010-Angle-2.gif|center]]
   
   
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In the end this model showed us that in less than 100ns the velocity of the flagella would be the same as the velocity of the fluid when the flagella started with a velocity of zero, after that the two velocity never diverged far from each other. Since the velocity of the flagella always went to the velocity of the fluid on such a short timescale and since these calculations took a lot of computerpower we decided that instead of force calculations we would simpy find the flowvelocity at the tip of the flagellum and convert that directly to the angular velocity of the flagellum.
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<p style="text-align: justify;">In the end this model showed us that in less than 100ns the velocity of the flagella would be the same as the velocity of the fluid when the flagella started with a velocity of zero, after that the two velocity never diverged far from each other. Since the velocity of the flagella always went to the velocity of the fluid on such a short timescale and since these calculations took a lot of computerpower we decided that instead of force calculations we would simpy find the flowvelocity at the tip of the flagellum and convert that directly to the angular velocity of the flagellum.
</p>
</p>
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=== 5. A 2-D model of the system ===
=== 5. A 2-D model of the system ===
<p style="text-align: justify;">
<p style="text-align: justify;">

Revision as of 10:21, 22 October 2010