Difference between revisions of "EGR 224/Measurements 2"

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== Clarifications / Troubleshooting ==  
 
== Clarifications / Troubleshooting ==  
 +
* Instead of using measuring the resistance or capacitance values, just use the nominal values in each case.
 
* If you get a "specified device not found" or something like that, try using 'Dev2' instead of 'Dev1' in the TestFunction code.
 
* If you get a "specified device not found" or something like that, try using 'Dev2' instead of 'Dev1' in the TestFunction code.
 
* If one of your figures looks wrong, it probably is!  Be sure to have a TA check your figures so that you leave the lab with a valid data set.
 
* If one of your figures looks wrong, it probably is!  Be sure to have a TA check your figures so that you leave the lab with a valid data set.

Latest revision as of 17:29, 19 February 2019

The following page provides some supplemental information for the Basic Electrical Measurements II lab for EGR 224L. It has been updated for Spring, 2019.

Clarifications / Troubleshooting

  • Instead of using measuring the resistance or capacitance values, just use the nominal values in each case.
  • If you get a "specified device not found" or something like that, try using 'Dev2' instead of 'Dev1' in the TestFunction code.
  • If one of your figures looks wrong, it probably is! Be sure to have a TA check your figures so that you leave the lab with a valid data set.

Element Values

  • Resistances:
    • 1, 9, 17: 2.2 k\(\Omega\)
    • 2, 3, 10, 11, 18, 19: 4.7 k\(\Omega\)
    • 4, 5, 12, 13, 20, 21: 10 k\(\Omega\)
    • 6, 14, 16, 22: 15 k\(\Omega\)
    • 7, 8, 15, 23, 24: 22 k\(\Omega\)
  • Capacitances
    • 7, 15, 23: 2.2 \(\mu\)F
    • 4, 6, 8, 12, 14, 16, 20, 22, 24: 4.7 \(\mu\)F
    • 2, 5, 10, 13, 18, 21: 10 \(\mu\)F
    • 1, 3, 9, 11, 17, 19: 22 \(\mu\)F

Links

Wiring Images

Click on the pictures above to make them larger.

Plotting

For your plots, the total voltage should be a solid (dark) red line, the capacitor voltage should be a dash-dot (dark) blue line, and the resistor voltage should be a dashed (dark) green line. Here are some examples of how to do that in Maple, (less efficiently) in all versions of MATLAB, more efficiently in newer versions of MATLAB, and in Python, that shows plotting \(t^2\), \(t\), and \(t^2-t\). Note that you will need to add code for the axis labels and titles.

Maple

plot([t^2, t, t^2-t], t = 0 .. 3, linestyle = [1, 4, 3], legend = ['Total', 'vC', 'vR'])

All MATLAB

The following set the line widths to 1 for each plot and then sets the color based on a value for red, green, and blue -- these need to be between 0 and 1 for each component. [0.5 0 0] is thus dark red, [0 0 0.5] is dark blue, and [0 0.5 0] is dark green. These need to be darker than MATLAB's defaults because, for example, the default green is too light.

Time = linspace(0, 3, 100);
plot(Time, Time.^2,      'k-',  'LineW', 1, 'Color', [0.5 0 0])
hold on
plot(Time, Time,         'k-.', 'LineW', 1, 'Color', [0 0 0.5])
plot(Time, Time.^2-Time, 'k--', 'LineW', 1, 'Color', [0 0.5 0])
hold off
legend('Total', 'v_{C}', 'v_{R}', 'location', 'best')

Newer MATLAB

For MATLAB 2014b or newer, there is a more efficient way to use the plot object to do the same work:

Time = linspace(0, 3, 100);
p=plot(Time, Time.^2, 'k-', Time, Time, 'k-.', Time, Time.^2-Time, 'k--');
p(1).Color = [0.5 0 0]; p(1).LineWidth = 1;
p(2).Color = [0 0 0.5]; p(2).LineWidth = 1;
p(3).Color = [0 0.5 0]; p(3).LineWidth = 1;
legend('Total', 'v_{C}', 'v_{R}', 'location', 'best')

The p object has information about each of the items that were plotted; you can then set them individually rather than having to have multiple plot commands. Note that Duke's UNIX system has MATLAB 2014a (so close!) so this will not work as yet on that system.

Python

Python's default colors are darker, so the code:

import numpy as np
import matplotlib.pyplot as plt

time = np.linspace(0, 3, 100)
fig, ax = plt.subplots(num=1)
fig.clf()
fig, ax = plt.subplots(num=1)

ax.plot(time, time**2, 'k-', linewidth=1, color=[0.5, 0, 0])
ax.plot(time, time, 'k-.', linewidth=1, color=[0, 0, 0.5])
ax.plot(time, time**2 - time, 'k--', linewidth=1, color=[0, 0.5, 0])
ax.legend(['Total', '$v_{C}$', '$v_{R}$'], loc='best')

could be simplified a little to be:

import numpy as np
import matplotlib.pyplot as plt

time = np.linspace(0, 3, 100)
fig, ax = plt.subplots(num=1)
fig.clf()
fig, ax = plt.subplots(num=1)

ax.plot(time, time**2, 'r-', linewidth=1)
ax.plot(time, time, 'b-.', linewidth=1)
ax.plot(time, time**2 - time, 'g--', linewidth=1)
ax.legend(['Total', '$v_{C}$', '$v_{R}$'], loc='best')

to use the format string versus the color kwarg.