Difference between revisions of "Team:Cambridge-JIC/Notebook"

graph.commit('design', 'Hardware Design', $('<div>17 July 2015: Printed the new upright stage, with x- and y-axis translation systems. Also made some lens holders for our optics bench. Simon loves printing.</div><div class="teamen"><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/b/b1/CamJIC-Notebook-Optics3.jpg)"><div class="blur"></div><div class="profile"><h3>Optics</h3><p>Some filters arrived today. These are typically used for photography - put in front of the camera flash. But we are trying to find out (using a spectrophotometer) whether they could be good enough to incorporate in a fluorescent microscope. Collecting filter specs with a spectrophotometer and plotting in MatLab.</p></div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/6/6f/CamJIC-Notebook-Optics1.jpg)"><div class="blur"></div><div class="profile"><h3>Optics & Hardware</h3><p>Simon testing his freshly printed lens holder. We came up with the idea to use a magnetic whiteboard as a substitute of an optical table worth thousands of pounds. It is all about the open source cheap stuff now!</p></div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/8/8d/CamJIC-Notebook-Optics2.jpg)"><div class="blur"></div><div class="profile"><h3>Optics</h3><p>The resolution which can be achieved with a single lens with a short focal distance is amazing: the individual plastic fibres of the 3D printed parts are easily visible.</p></div></div></div>'));

graph.commit('design', 'Hardware Design', $('<div>17 July 2015: Printed the new upright stage, with x- and y-axis translation systems. Also made some lens holders for our optics bench. Simon loves printing.</div><div class="teamen"><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/b/b1/CamJIC-Notebook-Optics3.jpg)"><div class="blur"></div><div class="profile"><h3>Optics</h3><p>Some filters arrived today. These are typically used for photography - put in front of the camera flash. But we are trying to find out (using a spectrophotometer) whether they could be good enough to incorporate in a fluorescent microscope. Collecting filter specs with a spectrophotometer and plotting in MatLab.</p></div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/6/6f/CamJIC-Notebook-Optics1.jpg)"><div class="blur"></div><div class="profile"><h3>Optics & Hardware</h3><p>Simon testing his freshly printed lens holder. We came up with the idea to use a magnetic whiteboard as a substitute of an optical table worth thousands of pounds. It is all about the open source cheap stuff now!</p></div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/8/8d/CamJIC-Notebook-Optics2.jpg)"><div class="blur"></div><div class="profile"><h3>Optics</h3><p>The resolution which can be achieved with a single lens with a short focal distance is amazing: the individual plastic fibres of the 3D printed parts are easily visible.</p></div></div></div>'));

graph.commit('sw', 'Software', $('<div>20 July 2015: Playing around with some face recognition software. If we can digitally recognise faces, we could possibly also recognise cells, right?</div>'));

graph.commit('sw', 'Software', $('<div>20 July 2015: Playing around with some face recognition software. If we can digitally recognise faces, we could possibly also recognise cells, right?</div>'));