Difference between revisions of "ECE 110/Fall 2014/Final"

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# Current methods - be able to solve for voltages, currents, and powers absorbed or delivered by clearly using the mesh or branch current method to determine mesh or branch currents, possibly followed by functions of those currents to get element currents, voltages, or powers.  
 
# Current methods - be able to solve for voltages, currents, and powers absorbed or delivered by clearly using the mesh or branch current method to determine mesh or branch currents, possibly followed by functions of those currents to get element currents, voltages, or powers.  
 
# Current and Voltage division - be able to efficiently solve circuit problems by using current and voltage division.  
 
# Current and Voltage division - be able to efficiently solve circuit problems by using current and voltage division.  
# Superposition - be able to efficiently solve circuit problems by using superposition.   
+
# Superposition
#*Remember that dependent sources must be included in the different subdivisions of a superposition problem regardless of the independent source or sources you leave on.  
+
## Be able to efficiently solve circuit problems by using superposition.   
<!-- # Thévenin and Norton Equivalent Circuits - be able to solve for the source and resistance of a Thévenin or Norton Equivalent Circuit for a circuit comprised of independent and dependent sources and resistors. Be able to draw both Thévenin and Norton Equivalent Circuits.  Be able to use Thévenin and Norton Equivalent Circuits to determine the maximum power delivered to a load and the required resistance of that load to receive the maximum power. -->
+
## In life, remember that dependent sources must be included in the different subdivisions of a superposition problem regardless of the independent source or sources you leave on. On the test however, the superposition problem -- if there is one -- will not have a dependent source.
 +
## Note that power can only be calculated once the superposition process is over and the '''total''' voltages or currents have been found.
 +
# Thévenin and Norton Equivalent Circuits (Resistive only)
 +
## Be able to solve for the source and resistance of a Thévenin or Norton Equivalent Circuit for a circuit comprised of independent and dependent sources and resistors.  
 +
## Be able to draw both Thévenin and Norton Equivalent Circuits.   
 +
## Be able to use Thévenin and Norton Equivalent Circuits to determine the maximum power delivered to a load and the required resistance of that load to receive the maximum power.  
 
# Reactive elements
 
# Reactive elements
 +
## Know main model equation relating voltage and current and what it means for the voltage across a capacitor or the current through an inductor
 +
## Know the equation for energy stored in a capacitor or an inductor.  Note that if you use superposition to find the capacitor voltage or inductor current, you must wait until the end of the superposition process, when you have the total voltage or current, to find the energy stored.
 
## Be able to represent a circuit with reactive elements in the DC Steady State
 
## Be able to represent a circuit with reactive elements in the DC Steady State
## Switched circuits / constant source circuits
+
## Be able to determine a model equation for circuits comprised of R, C, and sources or R, L, and sources
### Determine initial conditions given constant forcing functions
+
# DC Switched circuits / constant source circuits
### Set up and solve first-order differential equation with initial conditions and constant forcing functions
+
## Determine initial conditions given constant forcing functions
 +
## Set up and solve a first-order differential equation with initial conditions and constant forcing functions
 
## Be able to find the closed form solution for a circuit that can be modeled as a first-order linear differential equation with a constant forcing function and some means for determining a value for the unknown variable at some time
 
## Be able to find the closed form solution for a circuit that can be modeled as a first-order linear differential equation with a constant forcing function and some means for determining a value for the unknown variable at some time
 
### Accurately sketch solution to switched circuit / constant source circuit
 
### Accurately sketch solution to switched circuit / constant source circuit
## Be able to determine a model equation for circuits comprised of R, C, and sources or R, L, and sources
 
## Know the equation for energy stored in a capacitor or an.  Note that if you use superposition to find the capacitor voltage or inductor current, you must wait until the end of the superposition process, when you have the total voltage or current, to find the energy stored.
 
 
# Complex numbers and sinusoids
 
# Complex numbers and sinusoids
 
# Impedance <math>\Bbb{Z}=R+jX</math>, Admittance <math>\Bbb{Y}=G+jB</math>, Resistance <math>R</math>, Reactance <math>X</math>, Conductance <math>G</math>, Susceptance <math>B</math>
 
# Impedance <math>\Bbb{Z}=R+jX</math>, Admittance <math>\Bbb{Y}=G+jB</math>, Resistance <math>R</math>, Reactance <math>X</math>, Conductance <math>G</math>, Susceptance <math>B</math>
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## For "simple" circuits, be able to determine output phasors numerically and translate into time domain
 
## For "simple" circuits, be able to determine output phasors numerically and translate into time domain
 
# Frequency response, transfer functions
 
# Frequency response, transfer functions
# Linearity and superposition
+
# Bode magnitude plots / straight-line approximations
## Note that you can solve ACSS problems with sources of different frequencies, but you can only solve for one frequency at a time - do not mix phasors that represent signals at different frequencies!
 
<!-- # Bode magnitude and phase plots / straight-line approximations -->
 
# Fourier series
 
## Analysis of periodic signals comprised of sinusoids with frequencies at integer multiples of the fundamental frequency of the signal
 
## Analysis of periodic signals using analysis equation (will either be simple signal or can be left as integral)
 
## Determination of Fourier series coefficients for an output given a signal (or its Fourier series coefficients) and a circuit or a transfer function (real or ideal)
 
## Synthesis of periodic signals at output of a circuit given Fourier series coefficients
 
<!-- ## HW 8 Written part - '''so''' hot right now. -->
 
 
# Filters
 
# Filters
## First order (RC and RL) and second order (LRC)
+
## Be able to determine transfer function for and design first order (using RC and/or RL) with gains other than 1 (using OpAmps)  
## Determination of filter type via <!-- Bode or --> magnitude analysis
+
## Determination of filter type via Bode magnitude analysis
## Building a circuit to implement a particular first-order filter (will not require op-amps)
 
 
# Operational Amplifiers
 
# Operational Amplifiers
 
## Know the requirements for the Ideal Op-Amp Assumptions (feedback between the output and the inverting input), the Ideal Op-Amp assumptions (infinite internal input impedance, zero internal output impedance, and infinite internal voltage gain), and the results of the Ideal Op-Amp Assumptions given feedback to the negative input (no voltage drop across the input terminals and no current into/out of the input terminals).
 
## Know the requirements for the Ideal Op-Amp Assumptions (feedback between the output and the inverting input), the Ideal Op-Amp assumptions (infinite internal input impedance, zero internal output impedance, and infinite internal voltage gain), and the results of the Ideal Op-Amp Assumptions given feedback to the negative input (no voltage drop across the input terminals and no current into/out of the input terminals).
## Know how to analyze <!-- and build --> buffers, noninverting and inverting amplifiers, summing and difference amplifiers.
+
## Know how to analyze and build buffers, noninverting amplifiers, and inverting amplifiers
 
## Know how to analyze non-standard configurations (i.e. every other kind of circuit with an OpAmp, including those with reactive elements).
 
## Know how to analyze non-standard configurations (i.e. every other kind of circuit with an OpAmp, including those with reactive elements).

Latest revision as of 20:51, 10 December 2014

Exam Fall 2014 Coverage

  1. Digital Logic
    1. Be able to represent and interpret digital logic functions through the use of a digital logic function (of course), expansion by minors, truth tables, or Karnaugh maps
    2. Be able to simplify digital logic functions into minimum sum of products and minimum product of sums forms
    3. Be able to accurate draw a gated representation of a digital logic function using NOT gates and two-input AND and OR gates
    4. Be able to determine the complexity of a representation so drawn
  2. Basic electrical entities - be able to fill in the following chart:
    \(\begin{align} \begin{array}{cccc} \mbox{Name} & \mbox{Variable} & \mbox{Units} & \mbox{Equation} \\ \hline \hline \mbox{charge} & q & \mbox{coulombs (C)} & q(t) = q(t_0) + \int_{t_0}^t i(\tau)~d\tau \\ \hline \mbox{current} & i & \mbox{amperes (A)} & i = \frac{dq}{dt} \\ \hline \mbox{work} & w & \mbox{joules (J)} & \\ \hline \mbox{voltage} & v & \mbox{volts (V)} & v = \frac{dw}{dq} \\ \hline \mbox{power} & p & \mbox{watts (W)} & p = \frac{dw}{dt} = vi \\ \hline \mbox{resistance} & R & \mbox{ohms}~(\Omega) & R = \frac{v}{i} \\ \hline \mbox{conductance} & G & \mbox{mhos}~(\mho) & \\ \hline \end{array} \end{align}\)
  3. Power - know the general equation for instantaneous power absorbed or delivered by an element, and know three equations that can be used to calculate power in a resistive element. Know the difference between absorbed power and delivered power. Be able to solve circuit variables using the idea that net power in a circuit is zero.
  4. Sources - know the four kinds of dependent source and the properties of sources (i.e. current sources can have any voltage across them and voltage sources can have any amount of current through them).
  5. Ohm’s Law - know Ohm’s Law and the requirement of the passive sign convention for resistors.
  6. Kirchhoff’s Laws - know what Kirchhoff’s Laws are, be able to state them clearly in words, and be able to apply them to circuit elements to solve for unknown currents and voltages.
  7. Equivalent resistances - be able to simplify a resistive network with series and parallel resistances.
  8. Node voltage method - be able to solve for voltages, currents, and power absorbed or delivered by clearly using the node voltage method to determine node voltages, possibly followed by functions of those node voltages to get currents or powers.
  9. Current methods - be able to solve for voltages, currents, and powers absorbed or delivered by clearly using the mesh or branch current method to determine mesh or branch currents, possibly followed by functions of those currents to get element currents, voltages, or powers.
  10. Current and Voltage division - be able to efficiently solve circuit problems by using current and voltage division.
  11. Superposition
    1. Be able to efficiently solve circuit problems by using superposition.
    2. In life, remember that dependent sources must be included in the different subdivisions of a superposition problem regardless of the independent source or sources you leave on. On the test however, the superposition problem -- if there is one -- will not have a dependent source.
    3. Note that power can only be calculated once the superposition process is over and the total voltages or currents have been found.
  12. Thévenin and Norton Equivalent Circuits (Resistive only)
    1. Be able to solve for the source and resistance of a Thévenin or Norton Equivalent Circuit for a circuit comprised of independent and dependent sources and resistors.
    2. Be able to draw both Thévenin and Norton Equivalent Circuits.
    3. Be able to use Thévenin and Norton Equivalent Circuits to determine the maximum power delivered to a load and the required resistance of that load to receive the maximum power.
  13. Reactive elements
    1. Know main model equation relating voltage and current and what it means for the voltage across a capacitor or the current through an inductor
    2. Know the equation for energy stored in a capacitor or an inductor. Note that if you use superposition to find the capacitor voltage or inductor current, you must wait until the end of the superposition process, when you have the total voltage or current, to find the energy stored.
    3. Be able to represent a circuit with reactive elements in the DC Steady State
    4. Be able to determine a model equation for circuits comprised of R, C, and sources or R, L, and sources
  14. DC Switched circuits / constant source circuits
    1. Determine initial conditions given constant forcing functions
    2. Set up and solve a first-order differential equation with initial conditions and constant forcing functions
    3. Be able to find the closed form solution for a circuit that can be modeled as a first-order linear differential equation with a constant forcing function and some means for determining a value for the unknown variable at some time
      1. Accurately sketch solution to switched circuit / constant source circuit
  15. Complex numbers and sinusoids
  16. Impedance \(\Bbb{Z}=R+jX\), Admittance \(\Bbb{Y}=G+jB\), Resistance \(R\), Reactance \(X\), Conductance \(G\), Susceptance \(B\)
  17. AC Steady State / Phasor Analysis
    1. Draw circuit in frequency domain
    2. Determine series of equations using NVM, MCM, and/or BCM to solve relationships in frequency domain
    3. For "simple" circuits, be able to determine output phasors numerically and translate into time domain
  18. Frequency response, transfer functions
  19. Bode magnitude plots / straight-line approximations
  20. Filters
    1. Be able to determine transfer function for and design first order (using RC and/or RL) with gains other than 1 (using OpAmps)
    2. Determination of filter type via Bode magnitude analysis
  21. Operational Amplifiers
    1. Know the requirements for the Ideal Op-Amp Assumptions (feedback between the output and the inverting input), the Ideal Op-Amp assumptions (infinite internal input impedance, zero internal output impedance, and infinite internal voltage gain), and the results of the Ideal Op-Amp Assumptions given feedback to the negative input (no voltage drop across the input terminals and no current into/out of the input terminals).
    2. Know how to analyze and build buffers, noninverting amplifiers, and inverting amplifiers
    3. Know how to analyze non-standard configurations (i.e. every other kind of circuit with an OpAmp, including those with reactive elements).