Difference between revisions of "EGR 224/RC ACSS Analysis"
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− | The following page provides some supplemental information for the '''RC ACSS Analysis''' lab for [[EGR 224|EGR 224L]]. It has been updated for Spring, | + | The following page provides some supplemental information for the '''RC ACSS Analysis''' lab for [[EGR 224|EGR 224L]]. It has been updated for Spring, 2023. |
+ | == Typographical Errors / Clarifications == | ||
+ | None yet for 2022! | ||
== Element Values == | == Element Values == | ||
− | Take the number attached to your NetID (use 0 if no number), calculate that number modulo 8 (i.e. the remainder after dividing by the largest whole number of 8's), and add 1. Use the resistor and capacitor values based on that number: | + | Take the number attached to your NetID (use 0 if no number), calculate that number modulo 8 (i.e. the remainder after dividing by the largest whole number of 8's), and add 1. Use the resistor and capacitor values based on that number. If you are not sure, run the following code in Python:<syntaxhighlight lang=python> |
+ | num = int(input('Number attached to NetID? ')) | ||
+ | print('Use values from category {}'.format((num % 8) + 1))</syntaxhighlight> | ||
*Resistances: | *Resistances: | ||
**1: 2.2 k<math>\Omega</math> | **1: 2.2 k<math>\Omega</math> | ||
Line 18: | Line 22: | ||
Use a small breadboard, a '''function generator''' (not a power supply), a resistor, a capacitor, and whatever wires you need to model the circuit. | Use a small breadboard, a '''function generator''' (not a power supply), a resistor, a capacitor, and whatever wires you need to model the circuit. | ||
* Put in three oscilloscopes - one to show the total voltage across the RC circuit, one to show just the voltage across the capacitor, and one to show just the voltage across the resistor. Change the time scale of the scopes so that the time per division is approximately equal to the time constant $$\tau=RC$$ of your circuit. | * Put in three oscilloscopes - one to show the total voltage across the RC circuit, one to show just the voltage across the capacitor, and one to show just the voltage across the resistor. Change the time scale of the scopes so that the time per division is approximately equal to the time constant $$\tau=RC$$ of your circuit. | ||
− | * Set the function generator to make a square wave with an amplitude of 2.5 V, a DC Offset of 1.25 V, and a frequency equal to $$f=\frac{1}{8\tau}$$ where again $$\tau=RC$$ for your circuit. This will make a wave that is "on" for four time constants and then "off" for four time constants. Take a | + | * Set the function generator to make a square wave with an amplitude of 2.5 V, a DC Offset of 1.25 V, and a frequency equal to $$f=\frac{1}{8\tau}$$ where again $$\tau=RC$$ for your circuit. This will make a wave that is "on" for four time constants and then "off" for four time constants. Take a screenshot of your simulation in action. |
* Note that the scopes are not triggered in sync - the time axes for each are shifted and generally centered where a wave is equal to half its maximum amplitude and rising. Given that, we will not be able to use Tinkercad to get phase information but you can at least get an idea about amplitude. | * Note that the scopes are not triggered in sync - the time axes for each are shifted and generally centered where a wave is equal to half its maximum amplitude and rising. Given that, we will not be able to use Tinkercad to get phase information but you can at least get an idea about amplitude. | ||
− | * Set the function generator to generate a sinusoid instead of a rectangular pulse. Note that the amplitudes of the voltages across the resistor and capacitor are just about equal. This is because $$f=\frac{1}{8\tau}$$ is very close to the cutoff frequency $$f_{co}=\frac{\omega_{co}}{2\pi}=\frac{1}{2\pi\tau}$$. At exactly the cutoff frequency, we would expect the amplitude of both signals to be $$\frac{1}{\sqrt{2}}$$ of the total amplitude. Take a | + | * Set the function generator to generate a sinusoid instead of a rectangular pulse. Note that the amplitudes of the voltages across the resistor and capacitor are just about equal. This is because $$f=\frac{1}{8\tau}$$ is very close to the cutoff frequency $$f_{co}=\frac{\omega_{co}}{2\pi}=\frac{1}{2\pi\tau}$$. At exactly the cutoff frequency, we would expect the amplitude of both signals to be $$\frac{1}{\sqrt{2}}$$ of the total amplitude. Take a screenshot of your simulation in action. |
− | * Change the frequency of the function generator (which should still generate a sinusoid) to 10 times its current value (that is $$f=\frac{1.25}{\tau}$$) and change the time per division to $$\tau/10$$. Take a screen shot of this simulation as well. Carefully note the voltage ranges on the oscilloscopes. You should see that the voltage across the resistor now has a significantly larger amplitude than the voltage across the capacitor. Take a | + | * Change the frequency of the function generator (which should still generate a sinusoid) to 10 times its current value (that is $$f=\frac{1.25}{\tau}$$) and change the time per division to $$\tau/10$$. Take a screen shot of this simulation as well. Carefully note the voltage ranges on the oscilloscopes. You should see that the voltage across the resistor now has a significantly larger amplitude than the voltage across the capacitor. Take a screenshot of your simulation in action. |
== Multisim == | == Multisim == | ||
Line 28: | Line 32: | ||
* Put one probe at the top of the voltage source, a second probe at the top of the capacitor, and a third probe on the left side of the resistor (i.e. on the wire connecting the resistor to the source). Click on this third probe and then set the reference (V-) to the right side of the resistor. This will allow the probe to take a voltage measurement across the resistor. | * Put one probe at the top of the voltage source, a second probe at the top of the capacitor, and a third probe on the left side of the resistor (i.e. on the wire connecting the resistor to the source). Click on this third probe and then set the reference (V-) to the right side of the resistor. This will allow the probe to take a voltage measurement across the resistor. | ||
* Run the simulator, then click on Grapher. (horrible, isn't it?) | * Run the simulator, then click on Grapher. (horrible, isn't it?) | ||
− | * Click on Schematic again, then where it says Interactive, change this to Transient. This will allow us to graph for a particular period of time. Open the settings by clicking the gear on the top right. In the simulation settings, change the end time to $$ | + | * Click on Schematic again, then where it says Interactive, change this to Transient. This will allow us to graph for a particular period of time. Open the settings by clicking the gear on the top right. In the simulation settings, change the end time to $$25\tau$$ for your circuit and then press play to run the simulation. You should have three curves and each should have four peaks (though one of the initial peaks for the resistor voltage will not be full height. The capacitor voltage (probe 2) and resistor voltage (probe 3) should eventually have peaks of equal height that are $$\pm45^o$$ out of phase from the total voltage and at a height that is approximately 70% of the total voltage. You can hover over the curves to pick off specific values. |
* The time domain here is a little jagged. To make it smoother, go back to the schematic and in the settings section, open the Maximum time step section. Change it to manual time step and set this to 1e-5 which is the largest possible manual time step. Re-run the simulation and look at the graphs now - much smoother! | * The time domain here is a little jagged. To make it smoother, go back to the schematic and in the settings section, open the Maximum time step section. Change it to manual time step and set this to 1e-5 which is the largest possible manual time step. Re-run the simulation and look at the graphs now - much smoother! | ||
* When you hover over a curve to pick off values, there may be times that the two curves intersect. Note that the cursor color indicates which curve you are looking at. If you need to turn a curve off so that it does not interfere, uncheck the box next to its name in the Plots part of the settings box. | * When you hover over a curve to pick off values, there may be times that the two curves intersect. Note that the cursor color indicates which curve you are looking at. If you need to turn a curve off so that it does not interfere, uncheck the box next to its name in the Plots part of the settings box. | ||
* Go back to the schematic editor and change the frequency to 0.159 Hz (1 rad/s). In the Document settings, change the end time to 62.83 (10 times the period of the sinusoid). Unclick the Manual time step option. Run the simulation. This is a relatively low frequency so the capacitor voltage (probe 2) should be very close to the total voltage and nearly in phase, while the resistor voltage will be small and almost $$90^o$$ ahead. Export this data set using the export button at the top right. The file will be saved to an "Untitled Circuit" file; find that file and change its name to "Data001.csv" | * Go back to the schematic editor and change the frequency to 0.159 Hz (1 rad/s). In the Document settings, change the end time to 62.83 (10 times the period of the sinusoid). Unclick the Manual time step option. Run the simulation. This is a relatively low frequency so the capacitor voltage (probe 2) should be very close to the total voltage and nearly in phase, while the resistor voltage will be small and almost $$90^o$$ ahead. Export this data set using the export button at the top right. The file will be saved to an "Untitled Circuit" file; find that file and change its name to "Data001.csv" | ||
− | * You are now going to repeat this process for frequencies of $$\omega=2, 5, 12, 25, 60, 130, 300$$ rad/s. Each time, change the frequency of the source to the correct value $$f=\frac{\omega}{2\pi}$$ and change the | + | * You are now going to repeat this process for frequencies of $$\omega=2, 5, 12, 25, 60, 130, 300$$ rad/s. Each time, change the frequency of the source to the correct value $$f=\frac{\omega}{2\pi}$$ and change the end time to 10 times the period of the sinusoid ($$T=\frac{1}{f}$$ so use $$\frac{20\pi}{\omega}$$. If the higher frequency graphs start to look jagged, you can change the minimum time step back to manual. Save the data set each time where the numerical part will be a three-digit representation of the frequency in rad/s. Note how the peak value and locations for the resistor and capacitor voltage change with frequency. |
=== AC Sweep === | === AC Sweep === | ||
− | * Next you are going to have Multisim analyze the AC Steady State for the circuit as a function of the frequency. Change from a Transient Analysis to an AC Sweep using the dropdown at the top left of the screen. In the Document Settings, change the Start frequency to 0.016 Hz ($$\approx$$0.1 rad/s) and the Stop frequency to 480 Hz ($$\approx$$3000 rad/s). Note that this range is a decade before and a decade beyond the frequencies you just used. Run the simulation. The grapher will now be showing you the | + | * Next you are going to have Multisim analyze the AC Steady State for the circuit as a function of the frequency. Change from a Transient Analysis to an AC Sweep using the dropdown at the top left of the screen. In the Document Settings, change the Start frequency to 0.016 Hz ($$\approx$$0.1 rad/s) and the Stop frequency to 480 Hz ($$\approx$$3000 rad/s). Note that this range is a decade before and a decade beyond the frequencies you just used. Run the simulation. The grapher will now be showing you the magnitude and phase plots for the three voltages we are measuring. Confirm that the capacitor voltage looks like a low pass filter, the resistor voltage looks like a high pass filter, and that the two magnitudes are equal at the cutoff frequency $$f_{co}=\frac{\omega_{co}}{2\pi}=\frac{1}{2\pi RC}$$ for your filter. If you want a higher resolution sweep, go back to the Document settings and change the Points per decade setting and rerun the simulation. '''Note''': if you hover over the magnitude curves you get the multiplicative values by default. If you want readings in dB, you will need to go to the Document settings and change the Vertical scale to Decibel. '''Be sure to change it back to Logarithmic and re-run the simulation before the next step.''' Your saved data will need to be logarithmic and not dB. |
* Export the Schematic Image, the Grapher Image, and the Grapher Data for this circuit. | * Export the Schematic Image, the Grapher Image, and the Grapher Data for this circuit. | ||
+ | |||
+ | == Hints from Previous Semesters == | ||
+ | * [https://docs.scipy.org/doc/scipy/reference/generated/scipy.signal.find_peaks.html scipy.signal.find_peaks] can be very helpful for...finding...peaks. | ||
+ | <HTML> | ||
+ | <iframe src="https://trinket.io/embed/python3/e17b8dda14" width="100%" height="600" frameborder="0" marginwidth="0" marginheight="0" allowfullscreen></iframe> | ||
+ | </html> | ||
+ | * [[Python:Loading and Saving Data]] | ||
+ | * [[Python:Flexible_Programming]] - note that your data files have similar names; you can use this to your advantage when writing a loop to load and analyze the data from each file. | ||
[[Category:EGR 224]] | [[Category:EGR 224]] |
Latest revision as of 15:10, 4 April 2023
The following page provides some supplemental information for the RC ACSS Analysis lab for EGR 224L. It has been updated for Spring, 2023.
Contents
Typographical Errors / Clarifications
None yet for 2022!
Element Values
Take the number attached to your NetID (use 0 if no number), calculate that number modulo 8 (i.e. the remainder after dividing by the largest whole number of 8's), and add 1. Use the resistor and capacitor values based on that number. If you are not sure, run the following code in Python:
num = int(input('Number attached to NetID? '))
print('Use values from category {}'.format((num % 8) + 1))
- Resistances:
- 1: 2.2 k\(\Omega\)
- 2, 3: 4.7 k\(\Omega\)
- 4, 5: 10 k\(\Omega\)
- 6: 15 k\(\Omega\)
- 7, 8: 22 k\(\Omega\)
- Capacitances
- 1, 3: 22 \(\mu\)F
- 2, 5: 10 \(\mu\)F
- 4, 6, 8: 4.7 \(\mu\)F
- 7: 2.2 \(\mu\)F
Tinkercad
Use a small breadboard, a function generator (not a power supply), a resistor, a capacitor, and whatever wires you need to model the circuit.
- Put in three oscilloscopes - one to show the total voltage across the RC circuit, one to show just the voltage across the capacitor, and one to show just the voltage across the resistor. Change the time scale of the scopes so that the time per division is approximately equal to the time constant $$\tau=RC$$ of your circuit.
- Set the function generator to make a square wave with an amplitude of 2.5 V, a DC Offset of 1.25 V, and a frequency equal to $$f=\frac{1}{8\tau}$$ where again $$\tau=RC$$ for your circuit. This will make a wave that is "on" for four time constants and then "off" for four time constants. Take a screenshot of your simulation in action.
- Note that the scopes are not triggered in sync - the time axes for each are shifted and generally centered where a wave is equal to half its maximum amplitude and rising. Given that, we will not be able to use Tinkercad to get phase information but you can at least get an idea about amplitude.
- Set the function generator to generate a sinusoid instead of a rectangular pulse. Note that the amplitudes of the voltages across the resistor and capacitor are just about equal. This is because $$f=\frac{1}{8\tau}$$ is very close to the cutoff frequency $$f_{co}=\frac{\omega_{co}}{2\pi}=\frac{1}{2\pi\tau}$$. At exactly the cutoff frequency, we would expect the amplitude of both signals to be $$\frac{1}{\sqrt{2}}$$ of the total amplitude. Take a screenshot of your simulation in action.
- Change the frequency of the function generator (which should still generate a sinusoid) to 10 times its current value (that is $$f=\frac{1.25}{\tau}$$) and change the time per division to $$\tau/10$$. Take a screen shot of this simulation as well. Carefully note the voltage ranges on the oscilloscopes. You should see that the voltage across the resistor now has a significantly larger amplitude than the voltage across the capacitor. Take a screenshot of your simulation in action.
Multisim
Single Frequency Sinusoids
- Build the same circuit in Multisim but use an AC Voltage source for the source (Multisim does not have a function generator). Be sure to include a ground and set your capacitor and resistor values to your specific values. Set the frequency to $$f=\frac{1}{2\pi\tau}$$
- Put one probe at the top of the voltage source, a second probe at the top of the capacitor, and a third probe on the left side of the resistor (i.e. on the wire connecting the resistor to the source). Click on this third probe and then set the reference (V-) to the right side of the resistor. This will allow the probe to take a voltage measurement across the resistor.
- Run the simulator, then click on Grapher. (horrible, isn't it?)
- Click on Schematic again, then where it says Interactive, change this to Transient. This will allow us to graph for a particular period of time. Open the settings by clicking the gear on the top right. In the simulation settings, change the end time to $$25\tau$$ for your circuit and then press play to run the simulation. You should have three curves and each should have four peaks (though one of the initial peaks for the resistor voltage will not be full height. The capacitor voltage (probe 2) and resistor voltage (probe 3) should eventually have peaks of equal height that are $$\pm45^o$$ out of phase from the total voltage and at a height that is approximately 70% of the total voltage. You can hover over the curves to pick off specific values.
- The time domain here is a little jagged. To make it smoother, go back to the schematic and in the settings section, open the Maximum time step section. Change it to manual time step and set this to 1e-5 which is the largest possible manual time step. Re-run the simulation and look at the graphs now - much smoother!
- When you hover over a curve to pick off values, there may be times that the two curves intersect. Note that the cursor color indicates which curve you are looking at. If you need to turn a curve off so that it does not interfere, uncheck the box next to its name in the Plots part of the settings box.
- Go back to the schematic editor and change the frequency to 0.159 Hz (1 rad/s). In the Document settings, change the end time to 62.83 (10 times the period of the sinusoid). Unclick the Manual time step option. Run the simulation. This is a relatively low frequency so the capacitor voltage (probe 2) should be very close to the total voltage and nearly in phase, while the resistor voltage will be small and almost $$90^o$$ ahead. Export this data set using the export button at the top right. The file will be saved to an "Untitled Circuit" file; find that file and change its name to "Data001.csv"
- You are now going to repeat this process for frequencies of $$\omega=2, 5, 12, 25, 60, 130, 300$$ rad/s. Each time, change the frequency of the source to the correct value $$f=\frac{\omega}{2\pi}$$ and change the end time to 10 times the period of the sinusoid ($$T=\frac{1}{f}$$ so use $$\frac{20\pi}{\omega}$$. If the higher frequency graphs start to look jagged, you can change the minimum time step back to manual. Save the data set each time where the numerical part will be a three-digit representation of the frequency in rad/s. Note how the peak value and locations for the resistor and capacitor voltage change with frequency.
AC Sweep
- Next you are going to have Multisim analyze the AC Steady State for the circuit as a function of the frequency. Change from a Transient Analysis to an AC Sweep using the dropdown at the top left of the screen. In the Document Settings, change the Start frequency to 0.016 Hz ($$\approx$$0.1 rad/s) and the Stop frequency to 480 Hz ($$\approx$$3000 rad/s). Note that this range is a decade before and a decade beyond the frequencies you just used. Run the simulation. The grapher will now be showing you the magnitude and phase plots for the three voltages we are measuring. Confirm that the capacitor voltage looks like a low pass filter, the resistor voltage looks like a high pass filter, and that the two magnitudes are equal at the cutoff frequency $$f_{co}=\frac{\omega_{co}}{2\pi}=\frac{1}{2\pi RC}$$ for your filter. If you want a higher resolution sweep, go back to the Document settings and change the Points per decade setting and rerun the simulation. Note: if you hover over the magnitude curves you get the multiplicative values by default. If you want readings in dB, you will need to go to the Document settings and change the Vertical scale to Decibel. Be sure to change it back to Logarithmic and re-run the simulation before the next step. Your saved data will need to be logarithmic and not dB.
- Export the Schematic Image, the Grapher Image, and the Grapher Data for this circuit.
Hints from Previous Semesters
- scipy.signal.find_peaks can be very helpful for...finding...peaks.
- Python:Loading and Saving Data
- Python:Flexible_Programming - note that your data files have similar names; you can use this to your advantage when writing a loop to load and analyze the data from each file.