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<div id="modelingContainer"> | <div id="modelingContainer"> | ||
<p class="title">Model Introduction</p> | <p class="title">Model Introduction</p> | ||
− | <p class="content">Modeling always | + | <p class="content">Modeling has always played an important role in every field of science. In our project, modeling comes up with real data, and thus makes biological theories easier to be realized and observed. Carl Gauss said, “Mathematics is the queen of the science.” A proposition of mathematics is reliable and indisputable, whereas other science theories have always been at risk of being overthrown. The reason why modeling has a good reputation and a certain status is that it theorems scientific phenomena, and makes them more trustworthy. By conducting modeling, we can have a reasonable embryonic form to formulate a possible solution to a difficult problem. However, the reaction series or the operation mechanism of an unknown equation needs to be reasonably presumed, and this is the most difficult part in the whole process. Inappropriate assumption can lead to erroneous results. Once the right theories are established, we can amend our hypothetical surmise, and build another model. In the modeling process we’ve done, the main technique we used is DE (differential equation). We use derivative to describe the difference of any variables that vary within a very short time. But we’ve encountered some very complicated equations when trying to solve the problem, so we use the program MATLAB to help calculate the results.</p> |
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<img src="https://static.igem.org/mediawiki/2017/e/e5/Modeling11.png" class="bigphoto" width="70%"> | <img src="https://static.igem.org/mediawiki/2017/e/e5/Modeling11.png" class="bigphoto" width="70%"> | ||
− | <p class="content">According to this simulation diagram, we can know that cjblue and BFP increase faster—coming to 90% of maximum only takes about | + | <p class="content">According to this simulation diagram, we can know that cjblue and BFP increase faster—coming to 90% of maximum only takes about 3 hours. As for RFP, it takes about 5 hours to reach 70% of maximum, which is also acceptable.</p> |
<p class="content">Through mathematical modeling, when observing the sicker changing to a specific color, we can calculate the ratio of each kind of chromoprotein by quantifying it.</p> | <p class="content">Through mathematical modeling, when observing the sicker changing to a specific color, we can calculate the ratio of each kind of chromoprotein by quantifying it.</p> | ||
<img src="" class="bigphoto" width="70%"> | <img src="" class="bigphoto" width="70%"> | ||
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<p class="title">Conclusion</p> | <p class="title">Conclusion</p> | ||
<p class="content"> | <p class="content"> | ||
+ | <br> - Through combining modeling and <a href="https://2017.igem.org/Team:TCFSH_Taiwan/Demonstrate" style="color: orange">device</a>, we are able to design a better application.</br> | ||
<br> - Through mathematical modelling, we can estimate how much LB filled in the sticker is adequate.</br> | <br> - Through mathematical modelling, we can estimate how much LB filled in the sticker is adequate.</br> | ||
<br> - Cjblue and BFP comes to 90% of maximum only takes about 3 hours. As for RFP, it takes about 5 hours to reach 70% of maximum, which is also acceptable.</br> | <br> - Cjblue and BFP comes to 90% of maximum only takes about 3 hours. As for RFP, it takes about 5 hours to reach 70% of maximum, which is also acceptable.</br> |
Latest revision as of 03:53, 2 November 2017