Team:SDU-Denmark/project-m

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(5. A 2-D model of the system)
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In this chapter we will present our model a bit more precisely and present some of the results it has given us.
In this chapter we will present our model a bit more precisely and present some of the results it has given us.
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The 2-D model consists of a one dimensional grid, to which flagella are attached. Each flagellum produces a force which creates a flow which pushed every other flagellum, and thus a dynamic system is created. To calculate how big the flow will be at a given point, a vector from the tip of the force-producing flagellum to the point where the you wish to know the flow must be created. To know how a flagellum is affected by the flow, the flow at the tip of the flagellum must be calculated. The situation is sketched below.
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The 2-D model consists of a one dimensional grid, to which flagella are attached. Each flagellum produces a force which creates a flow which pushed every other flagellum, and thus a dynamic system is created. To calculate how big the flow will be at a given point, a vector from the tip of the force-producing flagellum to the point where the you wish to know the flow must be created. To know how a flagellum is affected by the flow, the flow at the tip of the flagellum must be calculated. The situation is sketched in figure XX.  
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The compleatly velocity controled equation of motion then becomes(using the notation in figure XX):
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The best way to illustrate the result from this model, is to se the dynamic in action:
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It is clear that
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Billede
 
Once you have this vector and the vector corresponding to the force. The flow can be calculated using stokeslet or the Oseen-Blake tensor depending on whether there is a wall nearby. In our system there is a wall so we will be using the Oseen-Blake tensor. This means that we are also required to find a vector from the mirrorpoint of the force, to the point at which we wish to know the flow.
Once you have this vector and the vector corresponding to the force. The flow can be calculated using stokeslet or the Oseen-Blake tensor depending on whether there is a wall nearby. In our system there is a wall so we will be using the Oseen-Blake tensor. This means that we are also required to find a vector from the mirrorpoint of the force, to the point at which we wish to know the flow.
After this it is a matter of summarizing over all the flagella to find the total flowfield.
After this it is a matter of summarizing over all the flagella to find the total flowfield.
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=== 6. A stationary 2-D model ===
=== 6. A stationary 2-D model ===

Revision as of 18:48, 16 October 2010