Difference between revisions of "Team:NCKU Tainan/Hardware"

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                   <p class="pcontent">See the code on <a href="https://github.com/vicky87106/2018iGEM_NCKU-Tainan" style="color:#28ff28;">github</a></br></br></p>
 
                   <p class="pcontent">See the code on <a href="https://github.com/vicky87106/2018iGEM_NCKU-Tainan" style="color:#28ff28;">github</a></br></br></p>
                   <p class="pcontent"><h8>Experiment</h8></br>
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                   <h8>Experiment</h8></br>
                   Experiment 1: Instrument calibration</br>
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                   <ul><li>Experiment 1: Instrument calibration</li>
                  1. Experimental purpose:</br>
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                      <ol><li>Experimental purpose:</li>
                  Because the analog value returned by each sensor may be inaccurate, and the carbon dioxide concentration in each area may be slightly different, it must be corrected before use.</br>
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                          <ul><li>Because the analog value returned by each sensor may be inaccurate, and the carbon dioxide concentration in each area may be slightly different, it must be corrected before use.</li></ul>
                  2. Experimental method:</br>
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                          <li>Experimental method:</li>
                  (1) Connect the power supply to 3.3V and use arduino to measure the analog value of output A0. Its stable value is about 3.3/5*1024=675.84.</br>
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                  (2) Let the sensor enter a steady state and operate in an unventilated environment for at least 48 hours.</br>
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                  (3) At this time, the analogy value of the atmospheric carbon dioxide concentration (about 400 ppm) was measured, and we measured 705.</br>
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                  (4) The known carbon dioxide concentration is adjusted by a float flowmeter, and the ppm can be obtained according to the formula conversion, and the analogy value of the concentration is obtained.</br>
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Ex: We put the carbon dioxide sensor into 100% carbon dioxide and measured its analogy value to 260.</br>
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                  (5) We assume that the carbon dioxide logarithmic concentration is negatively linearly related to the output analog value, and can be found by the known two points.</br>
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                  3. Experimental formula:</br></p>
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                  <div class="carousel-item active" style="background-image: url('http://placehold.it/1900x1080')"></div>
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                          <ul><li>(1) Connect the power supply to 3.3V and use arduino to measure the analog value of output A0. Its stable value is about 3.3/5*1024=675.84.</li>
 +
                              <li>(2) Let the sensor enter a steady state and operate in an unventilated environment for at least 48 hours.</li>
 +
                              <li>(3) At this time, the analogy value of the atmospheric carbon dioxide concentration (about 400 ppm) was measured, and we measured 705.</li>
 +
                              <li>(4) The known carbon dioxide concentration is adjusted by a float flowmeter, and the ppm can be obtained according to the formula conversion, and the analogy value of the concentration is obtained.</li>
 +
Ex: We put the carbon dioxide sensor into 100% carbon dioxide and measured its analogy value to 260.</li>
 +
                              <li>(5) We assume that the carbon dioxide logarithmic concentration is negatively linearly related to the output analog value, and can be found by the known two points.</li>
 +
                          </ul>
  
                  <p class="pcontent">
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                          <li>Experimental formula:</li>
                  Experiment 2: CO2 trend line verification</br>
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                  1. Experimental purpose: to verify whether the logarithmic concentration of carbon dioxide is negatively linear with the output analog value.</br>
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                          <div class="carousel-item active" style="background-image: url('http://placehold.it/1900x1080')"></div></ol>
                  2. Experimental method:</br>
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                      <li>Experiment 2: CO2 trend line verification</li>
                  Use a float flowmeter to call up the known carbon dioxide concentration and measure its analogy to see if it is on this line.</br>
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                      <ol><li>Experimental purpose: to verify whether the logarithmic concentration of carbon dioxide is negatively linear with the output analog value.</li>
                  3. Experimental results:</br>
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                  還沒做這星期做完實驗補</br></br>
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                          <li>Experimental method:</li>
 +
                          <ul><li>Use a float flowmeter to call up the known carbon dioxide concentration and measure its analogy to see if it is on this line.</li></ul>
 +
                          <li>Experimental results:</li>
 +
                          <ul><li>還沒做這星期做完實驗補</li></ul>
 
                   <h8>Precautions</h8></br>
 
                   <h8>Precautions</h8></br>
 
                   It is best to preheat for the first time for 24 hours, use it for more than six hours, preheat for 1-2 hours, power off for more than 72 hours, and preheat for 24 hours.</br></p>
 
                   It is best to preheat for the first time for 24 hours, use it for more than six hours, preheat for 1-2 hours, power off for more than 72 hours, and preheat for 24 hours.</br></p>
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                   1.Arduino UNO</br>
 
                   1.Arduino UNO</br>
 
                   2.DS18B20 temperature sensor</br>
 
                   2.DS18B20 temperature sensor</br>
                   (1)Power supply range is 3.0V to 5.5V</br>
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                    (1)Power supply range is 3.0V to 5.5V</br>
 
                     (2)Measures temperatures from -55°C to +125°C (-67°F to +257°F)±0.5°C accuracy from –10°C to +85°C (14 to 185°F)</br>
 
                     (2)Measures temperatures from -55°C to +125°C (-67°F to +257°F)±0.5°C accuracy from –10°C to +85°C (14 to 185°F)</br>
 
                   3. a register of 4700 ohms</br></br></p>
 
                   3. a register of 4700 ohms</br></br></p>

Revision as of 04:15, 16 September 2018

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