| 1. identify parallel circuits and apply
circuit laws to parallel circuits (Criterion 2, items a, b, f)
2. find total resistance and conductance of a parallel resistive circuit
(Criterion 2, items a, b, f)
3. analyze circuits with parallel voltage and current supplies (Criterion
2, items a, b, f)
4. determine and apply the Norton model to circuit analysis (Criterion
2, items a, b, f)
5. be able to use oscilloscope in AC/DC laboratory experiments (Criterion
2, items a, c)
6. be able to operate function generators in AC/DC laboratory experiments
(Criterion 2, items a, c)
7. identify and apply circuit laws to series-parallel circuits (Criterion
2, items a, b, f)
8. be able to work with a laboratory lab team to produce joint reports
(Criterion 2, items e, f)
9. use the Thevenin model to analyze bridge circuits (Criterion 2, items
a, b, f)
10. identify the wave shape and key characteristics of a sine-, square-,
rectangle-, triangle-, and saw tooth waveform (Criterion 2, items a,
b, f)
11. be able to design and verify a simple power supply (Criterion 2,
items a, b, c, d, e, f)
12. calculate the rms value of a sine-, square-, rectangle-, triangle-,
and sawtooth wave (Criterion 2, items a, b, c, d, e, f)
13. analyze AC signals applied to electronic circuits (Criterion 2,
items a, b, c, d, e, f)
14. describe the basic structure of capacitor components (Criterion
2, items a, b, c, d, e, f)
15. find the total capacitance for series, parallel, and series-parallel
capacitors (Criterion 2, items a, b, c, d, e, f)
16. find the reactance of a capacitor in an AC circuit (Criterion 2,
items a, b, f)
17. analyze RC networks including calculating tau, determining rise
and fall times, and sketching voltage and current waveforms. (Criterion
2, items a, b, f)
18. analyze and design 555 timer circuits (Criterion 2, items a, b,
c, d, f)
19. analyze RC op-amp circuits such as RC integrators, RC differentiators
and RC waveform generators (Criterion 2, items a, b, f)
20. list the key characteristics of inductance (Criterion 2, items a,
b, f)
21. define and apply the inductive reactance formula (Criterion 2, items
a, b, f)
22. analyze RL networks, including calculating tau, determining the
instantaneous formula for voltage and current, and drawing transient
and steady state waveforms for square and sine waves(Criterion 2, items
a, b, f)
23. describe the basic elements of a transformer (Criterion 2, items
a, b, f)
24. produce and apply the Thevenin model of a transformer circuit (Criterion
2, items a, b, f)
25. identify and state the basic building blocks of a dc power supply
(Criterion 2, items a, b, f)
26. analyze lightly loaded to heavily loaded filtered, but unregulated
dc power supplies (Criterion 2, items a, b, f)
27. apply and analyze the zener voltage regulator (Criterion 2, items
a, b, f)
28. analyze and apply the pass transistor circuit and current limiting
circuits in the output stages of a dc power supply (Criterion 2, items
a, b, f)
29. analyze and apply three-terminal IC regulators to a dc power supply
(Criterion 2, items a, b, f)
30. analyze and design circuits to transfer maximum voltage, current,
or power (Criterion 2, items a, b, d, f)
31. identify, model, and apply basic active circuit models such as ideal
voltage amplifiers, current to voltage converters, voltage to current
converters and current amplifiers (Criterion 2, items a, b, f)
|
Lab 1
Lab 1a
Lab 2
Lab 3
Lab 4
Lab 5
Lab 6
Lab 7
|
Chapter 18 - 1, 12, 39a
Chapter 19 - 1, 2, 4, 17, 18
Chapter 20 - 1, 2, 3, 13, 21
Chapter 21 - 14, 19a, 23a, 26, 35a, 37a,
Chapter 22 - 4a, 5, 8, 23
Chapter 23 - Know the definition of a polyphase system and the difference between Y and Delta connection
Chapter 24 - Know the definition of the Fourier Series, Fundemential Frequency, DC value, and harmonics |
