Difference between revisions of "Team:KU Leuven/Modeling"

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The fascinating properties of pattern creating bacteria may be translated into the language of mathematics. In this subsection we are investigating the equations behind the behaviour of the genetically modified organisms created in the wetlab. We do so using a layered approach. Colony level modeling employs partial differential equations to describe large cell groups which are treated as a continuum. Internal level models describe the interactions that happen within single cells. Finally the hybrid model merges the two approaches into a final description of our pattern forming cells.
 
The fascinating properties of pattern creating bacteria may be translated into the language of mathematics. In this subsection we are investigating the equations behind the behaviour of the genetically modified organisms created in the wetlab. We do so using a layered approach. Colony level modeling employs partial differential equations to describe large cell groups which are treated as a continuum. Internal level models describe the interactions that happen within single cells. Finally the hybrid model merges the two approaches into a final description of our pattern forming cells.

Revision as of 20:15, 28 July 2015

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The fascinating properties of pattern creating bacteria may be translated into the language of mathematics. In this subsection we are investigating the equations behind the behaviour of the genetically modified organisms created in the wetlab. We do so using a layered approach. Colony level modeling employs partial differential equations to describe large cell groups which are treated as a continuum. Internal level models describe the interactions that happen within single cells. Finally the hybrid model merges the two approaches into a final description of our pattern forming cells.