Difference between revisions of "Team:Cambridge-JIC/Description"
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<p><b><span style="font-size:200%">The mechanics</span></b> of the stage can be automated using stepper motors. The user has remote control of the microscope, and can introduce tailor-made programs to facilitate their experiments.</p> | <p><b><span style="font-size:200%">The mechanics</span></b> of the stage can be automated using stepper motors. The user has remote control of the microscope, and can introduce tailor-made programs to facilitate their experiments.</p> | ||
<p><b><span style="font-size:200%">The optics</span></b> are low-cost, low-energy and modular. Illumination using LEDs means reducing power consumption and cost. A Raspberry Pi camera makes the microscope digital, and an epi-fluorescence cube makes imaging GFP a reality. With sub-micrometer resolution in brightfield and darkfield modes, you are ready to image single cells or whole tissues.</p> | <p><b><span style="font-size:200%">The optics</span></b> are low-cost, low-energy and modular. Illumination using LEDs means reducing power consumption and cost. A Raspberry Pi camera makes the microscope digital, and an epi-fluorescence cube makes imaging GFP a reality. With sub-micrometer resolution in brightfield and darkfield modes, you are ready to image single cells or whole tissues.</p> | ||
− | <p><b> | + | <p><b><span style="font-size:200%">The software</span></b> uses OpenCV and forms a core part of the project. The Webshell gives you real-time control over the microscope live-stream: from time-lapse to scale-bars. MicroMaps uses image stitching and sample recognition algorithms to give you the whole sample field in one, ready for annotation and screening. Autofocus capabilities allow automation of OpenScope’s motors, letting you image dynamic samples without supervision.</p> |
− | <p><b>The documentation</b> is comprehensive, non-proprietary and easy to access. And its licensed to make sure it stays that way.</p> | + | <p><b><span style="font-size:200%">The documentation</span></b> is comprehensive, non-proprietary and easy to access. And its licensed to make sure it stays that way.</p> |
− | <p><b>The community</b> of ‘makers’ is free to develop, modify and redistribute the documentation. OpenScope can evolve, improve and adapt to different needs.</p> | + | <p><b><span style="font-size:200%">The community</span></b> of ‘makers’ is free to develop, modify and redistribute the documentation. OpenScope can evolve, improve and adapt to different needs.</p> |
− | <p><b>The overall cost</b> is below £200, orders of magnitude below commercial lab microscopes.</p> | + | <p><b><span style="font-size:200%">The overall cost</span></b> is below £200, orders of magnitude below commercial lab microscopes.</p> |
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− | <p><b>The result?</b></p> | + | <p><b><span style="font-size:200%">The result?</span></b></p> |
<p>A microscopy solution for synthetic biologists, letting researchers tailor the microscope to their needs. Image in the incubator, fume-hood or the field using remote access and battery power, or use OpenScope for rapid preliminary screening.</p> | <p>A microscopy solution for synthetic biologists, letting researchers tailor the microscope to their needs. Image in the incubator, fume-hood or the field using remote access and battery power, or use OpenScope for rapid preliminary screening.</p> | ||
<p>A microscopy solution for schools, providing education in programming, optics and one of the most ubiquitous techniques in biological research: fluorescence imaging.</p> | <p>A microscopy solution for schools, providing education in programming, optics and one of the most ubiquitous techniques in biological research: fluorescence imaging.</p> |
Revision as of 11:24, 17 September 2015