ece 214 { electrical circuits lab lecture 6
TRANSCRIPT
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ECE 214 – Electrical Circuits LabLecture 6
Vince Weaver
http://www.eece.maine.edu/~vweaver
17 March 2015
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Announcements
• Lab re-starts this week!
• Remember you can change up lab partners
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Midterm Review
1. Test Equipment
(a) Oscope plot. What does the ”1 1.0V” mean?
i. Vpp Signal 1 = Peak to Peak = 8V
ii. Vpp Signal 2 = 4V
iii. Period = 2ms. Frequency = 1T = 500Hz
iv. Phase shift = f*dt*360 or just note is 360/10 blocks
= 36 degrees
(b) Lissajous.
sin−1(1.41422 )
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Watch your sig figs, and watch your rounding!
2. RC Circuits
(a) i. high pass filter
ii. 3rd order
iii. 12πRC = 750.7Hz
iv. 60dB/decade
(b) Bode plot. Cutoff at 751Hz, drop 60 dB/decade, high
pass.
3. OpAmp
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(a) Gain is −R2R1
= -2
(b) Plot is twice as big, inverted.
4. Schmitt Trigger
(a) Hysterisis plot. −Vsup to Vsup and −R1R2
to R1R2
.
Did not want square/triangle wave output.
5. Schmitt Trigger Oscillator
(a) Vout1 = Square
(b) Vout2 = Triangle
(c) f = R24R1R3C
. Solve, R3 = 500Ω
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6. Space ship question.
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Lab Notebooks
• Overall good
• Follow directions. Plots, semi-log. Label axes.
• Micro-cap. Know it’s a pain. For the integrator plots,
main issue was getting +/- 5V, not starting at zero.
Calculus. Op-amp issues.
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Lab #6 – DC – DC Converter
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Diodes
anode cathode
Breakdown Reverse Forward
V
I
• Many kinds: signal, zener, photo, schottky, (my favorite)
LED.
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• Block current going one way (ideal).
Real world more complicated; too much reverse voltage
and will eventually breakdown. Also have a forward
voltage drop (typically around 0.6V for Si diodes).
• Zener diodes have breakdown voltage of values like 5V,
can be used for simple power supplies.
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AC/DC conversion
• Motor feeding into a generator?
• Huge transformer with differing coils
• Bridge rectifier
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Villard DoublerC1
D1
C2
D2VIN
VOUT
• Technically the Villard Circuit only has one diode and
one capacitor and doesn’t behave well.
• We’ll actually be building a Greinacher circuit.
Also called a Cockroft-Walton multiplier
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Negative Half
C1
D1 C2
D2
VIN
VOUT
VIN
+-
• D1 Turns on, Charges C1 to Vin
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Positive Half
C1
D1 C2
D2
VIN
VOUT
VIN
+-
VIN = 2VIN+
• D1 Turns off, D2 Turns on, Output is C1 + Vin.
• C2 charges to 2*Vin
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Ripple
• Formula: Vripple = Iload(2fC) ∗ n ∗ (n+ 1)
• I = current load, f = frequency, C = capacitance, n =
number of stages (1 in our case)
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Drop
• Formula: Vdrop = Iload(6fC) ∗ (4n3 + 3n2 − n)
• I = current load, f = frequency, C = capacitance, n =
number of stages (1 in our case)
• Also worry about voltage drop in diodes (0.6V?)
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Multiple Stages
• Can multiply out an arbitrary number
• Ripple will increase. can be mitigated somewhat by
increasing capacitor values.
• What tolerances for cap/diode?
• USB destroyer in the news
http://hackaday.com/2015/03/11/killer-usb-drive-is-designed-to-fry-laptops/
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Circuit to Build
+
−
D1
D2
C1
C2
VDC
Vacos(ωt)
VOUT=VDC+2Va
+
-
• Want to input 10V DC, get more than 15V DC out.
• Can you double DC alone?
No, you need some sort of AC component.
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PreLab
• Design it.
• Run it through micro-cap.
• Use 1N4001 in microcap. Also pick a cap value from
10nF to 100nF.
• Remember to include oscilloscope output resistance, etc.
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Lab
• Build it.
• The diodes available in lab are 1N4004. See data sheet
for difference (hint, breakdown voltage)
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Postlab
• Compare.
• Write-up
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