circuit analysis - Access Engineering from McGraw-Hill

Relevant Material	Type	Description	Source
SI Units in Electrical Engineering	Text	Basic units required for circuit analysis	Standard Handbook for Electrical Engineers
SI Base Units	Table	Table 1-1 summarizes the standard metric units for length, mass, time and current.	Standard Handbook for Electrical Engineers
SI Derived Units	Table	Table 1-3 summarizes units for frequency, force, pressure,energy, power, charge, capacitance, resistance, conductance, and inductance.	Standard Handbook for Electrical Engineers
SI Symbols in Electrical Engineering			Standard Handbook for Electrical Engineers
SI Prefixes	Table	Table 1-6 describes standard prefixes for expressing powers of 10 such as micro, milli, mega and kilo.	Standard Handbook for Electrical Engineers
Standard Symbols for Quantities	Table	Table 1-10 provides the symbols for standard electrical quantities such as frequency, area, volume, length, and velocity.	Standard Handbook for Electrical Engineers
Standard Symbols for Units	Table	Table 1-11 summarizes standard electrical units such as ampete, bel, coulomb, decibel, giga, henry and ohm.	Standard Handbook for Electrical Engineers
Phasor Quantities	Table	This table summarizes quantities for complex numbers which are helpful for phasor analysis.	Standard Handbook for Electrical Engineers
Numerical Values	Table	Table 1-13 summarizes constants to help with circuits calculations such as pi, e, log, and powers	Standard Handbook for Electrical Engineers
Conversion Factors			Standard Handbook for Electrical Engineers
Length	Table	Table 1-15 summarizes how to find length conversions between meters, feet, yards, kilometrs, etc.	Standard Handbook for Electrical Engineers
Length Conversions - Table 1-15: Video 1	Video	This video will describe using Table 1-15 to perform length conversions such as meters to inches.	Standard Handbook for Electrical Engineers
Length Conversions - Table 1-15: Video 2	Video	This video demonstrates how to use Table 1-15 to perform length conversions such as millimeters to micrometers.	Standard Handbook for Electrical Engineers
Area	Table	Table 1-16 summarizes how to find area conversions between swuare meters, square kilometers, acres, etc.	Standard Handbook for Electrical Engineers
Volume and Capacity	Table	Table 1-17 summarizes how to perform volume conversions between cubic meter, cubic centimeter, liters, cutic feet, cubic yards, etc.	Standard Handbook for Electrical Engineers
Time	Table	Table 1-19 summarizes how to make time conversions between seconds, microseconds, solar seconds and solar days.	Standard Handbook for Electrical Engineers
Velocity	Table	Table 1-20 summarizes how to make velocity conversions between meter per second, kilometer per hour, inch per second, etc.	Standard Handbook for Electrical Engineers
Force	Table	Table 1-22 summarizes how to perform force conversions between newton, slug-force, kilogram force, dyne, etc.	Standard Handbook for Electrical Engineers
Energy	Table	Table 1-25 summarizes how to perform energy/work conversions such as joules, kiljoules, foot-pounds-force, BTU, kilowatthours, etc.	Standard Handbook for Electrical Engineers
Energy Conversions - Table 1-25: Video 1	Video	This video demonstrates how to use Table 1-25 to perform energy/work conversions such as finding energy in Joules given power and time.	Standard Handbook for Electrical Engineers
Energy Conversions - Table 1-25: Video 2	Video	This video demonstrates how to use Table 1-25 to perform energy/work conversions such as finding energy in calories and W-h given power and time.	Standard Handbook for Electrical Engineers
Problem 1.14: Energy Example	Video	This video demonstrates how to find the total energy transferred to a circuit element.	Schaum's Outline of Electric Circuits
Power	Table	Table 1-26 summarizes how to perform power conversions such as watts, kilowatts, BTU, kilocalories, horsepower, etc.	Standard Handbook for Electrical Engineers
Problem 1.9: Work and Power Example	Video	This video demonstrates how to calculate the work and power required to move a mass up a plane.	Schaum's Outline of Electric Circuits
Temperature	Table	Table 1-27 summarizes how to perform temperature conversions between Celsius, Farenheit and Kelvin.	Standard Handbook for Electrical Engineers

Relevant Material	Type	Description	Source
Resistors and Resistance	Text	Definition of resistor and Ohm's Law	Standard Handbook for Electrical Engineers
Resistor	Figure	Figure 2-8 provides an image of a resistor which is a circuit element that resists the flow of current.	Standard Handbook for Electrical Engineers
Ohm's Law	Figure	Figure 2-9 shows and example of how to use Ohm's Law to find current given a voltage.	Standard Handbook for Electrical Engineers
Problem 2.21: Voltage Example	Video	This video demonstrates how to find the voltage across a circuit element given the current waveform.	Schaum's Outline of Electric Circuits
Phase of Resistor	Figure	Figure 2-10 shows that the phase of a resistor which indicates that the current and voltage are in phase.	Standard Handbook for Electrical Engineers
Inductors and Inductance	Text	Definition of inductor and inductance. These equations provide the relationship between voltage, current and energy for an inductor.	Standard Handbook for Electrical Engineers
Inductor	Figure	Figure 2-11 provides an image of an inductor which is a circuit element that stores electromagnetic energy in its magnetic field.	Standard Handbook for Electrical Engineers
Problem 6.32: Voltage and Current for an Inductor	Video	This video demonstrates how to find the current through and energy for an inductor given the current waveform.	Schaum's Outline of Electric Circuits
Inductor Model	Figure	Figure 2-12 provides an image of an inductor which is a circuit element that stores electromagnetic energy in its magnetic field.	Standard Handbook for Electrical Engineers
Phase of Inductor	Figure	Figure 2-13 shows that the phase of an inductor which indicates that the voltage is out of phase with the current.	Standard Handbook for Electrical Engineers
Mutual Inductance	Figure	Figure 2-14 shows the mutual inductance model which illustates that when two coils are coiled around the same form with a changing current, a voltage is induced from the primary to secondary coil.	Standard Handbook for Electrical Engineers
Mutual Inductance Equation	Text	These equations illustrate that based upon the dot convention there is a voltage relationship for each coil based upon the self and mutual inductance.	Standard Handbook for Electrical Engineers
Capacitors and Capacitance	Text	Definition of a capacitor. These equations describe the current, voltage and energy relationships for a capacitor.	Standard Handbook for Electrical Engineers
Capacitor	Figure	Figure 2-15 shows an image of a capacitor which is a circuit element which is used to store electric energy.	Standard Handbook for Electrical Engineers
Capacitor model	Figure	Figure 2-16 shows the capacitor symbol and the relationship between voltage and current.	Standard Handbook for Electrical Engineers
Phase of capacitor	Figure	Figure 2-17: this graph shows the phase of a capacitor and indicates that the current and voltage are out of phase.	Standard Handbook for Electrical Engineers
Electrical Devices and Sources			Standard Handbook for Electrical Engineers
Electrical Devices, Voltage and Current Sources	Figure	Figure 2-18 shows a circuit element with the voltage and current drawn such that it obeys the passive sign convention. The ideal DC voltage source is a device with the same potential difference for all currents through it. The ideal DC current source is a device which produces the same current for all voltages across it.	Standard Handbook for Electrical Engineers
DC Source	Figure	Figure 2-23 shows the circuit symbol for a DC source such as a battery with a value of 1VDC.	Standard Handbook for Electrical Engineers
AC Source	Figure	Figure 2-24 shows the circuit symbol for an AC source with a value of 1VAC.	Standard Handbook for Electrical Engineers
Controlled Sources: Figure 1	Figure	Figure 2-25 shows the Pspice symbols for the four types of dependent sources: voltage controlled and current-controlled voltage and current sources.	Standard Handbook for Electrical Engineers
Controlled Sources: Figure 2	Figure	Figure 2-26 shows circuit symbols for the four types of dependent sources: voltage controlled and current-controlled voltage and current sources.	Standard Handbook for Electrical Engineers
Power Definition	Text	This text describes the power definition and formulas for finding the power for a circuit element including resistors.	Standard Handbook for Electrical Engineers
I2R Loss for a DC System	Video	This video demonstrates how to calculate I2R loss for a DC system.	Standard Handbook for Electrical Engineers
Voltage Drop for a DC System	Video	This video demonstrates how to calculate voltage drop in a DC system.	Standard Handbook for Electrical Engineers
Conductor Size for a DC System	Video	This video demonstrates how to calculate a conductor size for a certain voltage drop for a DC system.	Standard Handbook for Electrical Engineers

Relevant Material	Type	Description	Source
Kirchhoff's Current Law (KCL)	Text	Definition of Kirchoff's Current Law which states that the sum of the currents into and out of a node is zero.	Standard Handbook for Electrical Engineers
KCL Example	Figure	Figure 2-21 shows a simple circuit built in Pspice with mesh currents and each of the branch circuits labeled to confirm KCL at each node.	Standard Handbook for Electrical Engineers
Problem 2.24: KCL Example	Video	This video demonstrates how to use KCL to find the voltage and current for a circuit with a dependent source.	Schaum's Outline of Electric Circuits
Problem 3.15: Current Division Example	Video	This video demonstrates how to use current division to find the source current in a circuit.	Schaum's Outline of Electric Circuits
Kirchhoff's Voltage Law (KVL)	Text	Definition of Kirchoff's Voltage Law which states that the sum of the voltages around a loop is zero.	Standard Handbook for Electrical Engineers
KVL Example	Figure	Figure 2-22 shows a circuit built in Pspice with each of the node voltages labeled in order to confirm KVL at each mesh.	Standard Handbook for Electrical Engineers
Problem 2.23: KVL Example	Video	This video demonstrates how to use KVL to find the voltage and current for a circuit with a dependent source.	Schaum's Outline of Electric Circuits
Problem 3.14: Voltage Division Example	Video	This video demonstrates how to use voltage division to find the voltage across elements in a circuit.	Schaum's Outline of Electric Circuits
Solved Problems	Examples	Problems and solutions on circuit laws	Schaum's Outline of Electric Circuits

Relevant Material	Type	Description	Source
Circuits Reduction Techniques	Text	Methods to reduce circuits.	Standard Handbook for Electrical Engineers
Series	Text	Defines a series connection of circuit elements is where exactly two elements meet at a node.	Standard Handbook for Electrical Engineers
Series-Connected Elements and Equivalents	Figure	Figure 2-27: (a) shows equivalent resistance for resistors in series sum. (b) shows that the equivalent capacitor of capacitors in series is the product over the sum of the individual capacitances. (c-d) shows that the equivalent inductance of series mutual inductors sums but may have a positive or negative equivalent mutual inductance based upon the dot convention.	Standard Handbook for Electrical Engineers
Parallel	Text	Defines the parallel connection of circuit elements is where circuit elements share a single node pair.	Standard Handbook for Electrical Engineers
Parallel-Connected Elements and Equivalents	Figure	Figure 2-28: (a) shows that the equivalent resistance for resistors in series is the product over the sum of the individual resistances. (b) shows that the equivalent capacitance of capacitors in parallel is the sum of the individual capacitances. (c-d) shows that the equivalent inductance of inductors in parallel with their mutual inductances.	Standard Handbook for Electrical Engineers
Wye-Delta Connections	Text	Defintion of Wye and Delta Interconnections	Standard Handbook for Electrical Engineers
Wye-Delta connected elements	Figure	Figure 2-29 shows the Wye-Delta connections as well as the equations to convert between the two networks.	Standard Handbook for Electrical Engineers
Thevenin-Norton Theorem	Text	Describes the Thevenin and Norton equivalent of an electric circuit.	Standard Handbook for Electrical Engineers
Thevenin and Norton Equivalent Circuits	Figure	Figure 2-30 shows the Thevenin and Norton equivalent of an electric circuit.	Standard Handbook for Electrical Engineers
Thevenin and Norton Equivalent Example	Figure	Figure 2-31 shows an example of finding the Thevenin and Norton equivalent of a circuit with a dependent source.	Standard Handbook for Electrical Engineers
Thevenin and Norton Equivalents: Video 1	Video	This video demonstrates how to find the Thevenin and Norton equivalent of a circuit with independent sources.	Standard Handbook for Electrical Engineers
Thevenin and Norton Equivalents: Video 2	Video	This video demonstrates how to find the Thevenin and Norton equivalent of a circuit with dependent sources.	Standard Handbook for Electrical Engineers
Problem 4.33: Thevenin and Norton Equivalent	Video	This video demonstrates how to use the node-voltage method to find the Thevenin and Norton equivalent for a DC circuit and to select a load resistor for maximum power transfer.	Schaum's Outline of Electric Circuits
Nodal and Loop Analysis	Text	Description of nodal and loop analysis.	Standard Handbook for Electrical Engineers
Nodal Analysis	Text	Describes the process of using a systematic application of KCL or nodal analysis to find the node-voltages in a circuit.	Standard Handbook for Electrical Engineers
Nodal Analysis	Figure	Figure 2-33 shows an example of how to use KCL to find the node voltages in an electric circuit.	Standard Handbook for Electrical Engineers
Loop Analysis	Text	Describes the process of using a systematic application of KVL or loop analysis to solve for the mesh currents in a circuit.	Standard Handbook for Electrical Engineers
Loop Analysis	Figure	Figure 2-35 shows the PSPice results for finding the node voltages and branch currents in an electric circuit.	Standard Handbook for Electrical Engineers
Problem 4.17/4.18: Mesh Current Method Example	Video	This video demonstrates how to use the mesh current method to find unknown currents in a circuit.	Schaum's Outline of Electric Circuits
Problem 4.47: Superposition Example	Video	This video demonstrates how to use superposition to find unknown voltages in a circuit.	Schaum's Outline of Electric Circuits
Solved Problems	Example	Problems and solutions on analysis methods.	Schaum's Outline of Electric Circuits
First Order Circuits	Text	Explains how to find the response of first-order circuits.	Schaum's Outline of Electric Circuits
Problem 7.27: Transient response of an RC circuit	Video	This video shows how to find the voltage across a resistor in an RC circuit.	Schaum's Outline of Electric Circuits
Problem 7.30: Transient response of an RL circuit	Video	This video shows how to find the voltage across a resistor in an RL cicuit.	Schaum's Outline of Electric Circuits
Solved Problems	Example	Problems and solutions on first order circuits.	Schaum's Outline of Electric Circuits
Second Order Circuits	Text	Presents several examples of second-order circuits.	Schaum's Outline of Electric Circuits
Problem 8.27: RLC Circuit example	Video	This video shows how to find the current in a a RLC circuit.	Schaum's Outline of Electric Circuits
Supplementary Problem 2.58: RLC Circuit Example	Video	This video illustrates how to derive the differential equation for a series RLC circuit.	Schaum's Outline of Signals and Systems

Relevant Material	Type	Description	Source
Definition of a Phasor	Text	Definition of a phasor which will be used to perform complex math on sinusoidal steady-state analysis.	Standard Handbook for Electrical Engineers
Impedance of Passive Circuit Elements	Text	Describes the impedance, admittance, reactance and susceptance for the three passive circuit elements: resistors, inductors, capacitors. These are used to describe the relationship between voltage and current in phasor analysis.	Standard Handbook for Electrical Engineers
Sinusoidal steady-state analysis	Figure	Figure 2-33 shows an example of how to use KCL to find the node voltages in an electric circuit.	Standard Handbook for Electrical Engineers
Phasor Analysis Example 1	Video	This video demonstrates how to use phasor analysis and KCL to analyze a circuit to find voltages and currents in the sinusoidal steady state.	Standard Handbook for Electrical Engineers
Phasor Analysis Example 2	Video	This video demonstrates how to use phasor analysis and KVL to analyze a circuit to find voltages and currents in the sinusoidal steady state.	Standard Handbook for Electrical Engineers
Problem 6.29: Average and Effective Values	Video	This video demonstrates how to find the average and effective values for periodic waveforms.	Schaum's Outline of Electric Circuits
Problem 8.34: Transfer Function Example	Video	This video demonstrates how to find the transfer function for a network. The transfer function will be used to construct the pole-zero plot and also find the output voltage.	Schaum's Outline of Electric Circuits
Problem 9.42: Impedance Example	Video	This video demonstrates how to find the impedance in a parallel circuit given the phasor voltage and current.	Schaum's Outline of Electric Circuits
Problem 9.59: Sinusoidal-Steady State Example	Video	This video demonstrates how to find the sinusoidal steady-state voltage a current for an electric circuit.	Schaum's Outline of Electric Circuits
Solved Problems	Example	Problems and solutions on sinusoidal steady-state circuit analysis.	Schaum's Outline of Electric Circuits

Relevant Material	Type	Description	Source
Effective Power	Text	Describes the average and effective power for a resistor in an electric circuit.	Standard Handbook for Electrical Engineers
Problem 10.51: Average Power Example	Video	This video demonstrates how to analyze a circuit to find the average power for each circuit element.	Schaum's Outline of Electric Circuits
Instantaneous Power	Text	Describes the instantaneous power for an electric circuit element.	Standard Handbook for Electrical Engineers
Complex Power	Text	Describes the complex power for an electric circuit element.	Standard Handbook for Electrical Engineers
Problem 10.29: Complex Power Example	Video	This video demonstrates how to find the power triangle and complex power for a parallel circuit.	Schaum's Outline of Electric Circuits
AC Power: Example 1		This video demonstrates how to use phasor analysis to solve for average and reactive power in a circuit and confirm that the circuit obeys the law of conservation of energy.	Standard Handbook for Electrical Engineers
AC Power: Example 2	Video	This video demonstrates how to use phasor analysis to solve for maximum power transfer in a circuit.	Standard Handbook for Electrical Engineers
Voltage Drop for an AC System	Video	This video demonstrates how to calculate voltage drop and voltage regulation in an AC system.	Standard Handbook for Electrical Engineers
I2R loss for an AC System	Video	This video demonstrates how to calculate the I²R loss and efficiency for an AC system.	Standard Handbook for Electrical Engineers

Relevant Material	Type	Description	Source
Balanced 3-Phase Power	Text	This text describes three phase sources as well as the circuit symbol for Wye and Delta Connections.	Standard Handbook for Electrical Engineers
3-Phase Source Connections: Delta and Wye Connections	Figure	Figure 2-37: (a) shows a delta connected 3 phase source and (b) shows a wye connected 3 phase source.	Standard Handbook for Electrical Engineers
Average Power	Text	This section describes the average power for a balanced 3 phase source to a balanced load.	Standard Handbook for Electrical Engineers
Problem 11.41: Polyphase Circuits Example 1	Video	This video demonstrates how to find the average power, reactive power, apparent power and power factor for a three-phase circuit.	Schaum's Outline of Electric Circuits
Problem 11.42: Polyphase Circuits Example 2	Video	This video demonstrates how to find the line current and power for a balanced delta-connected load.	Schaum's Outline of Electric Circuits
3-Phase System	Figure	Figure 2-38 shows the image of a 3-phase system.	Standard Handbook for Electrical Engineers
Unbalanced 3-Phase Power	Text	Definition of unbalanced 3-phase power.	Standard Handbook for Electrical Engineers
Balanced AC System with Y-Connected Load	Video	This video demonstrates how to calculate voltage drop and voltage regulation in a balanced AC system with a Y-connected load.	Standard Handbook for Electrical Engineers
Balanced AC System with Delta-Connected Load	Video	This video demonstrates how to calculate voltage drop and voltage regulation in a balanced AC system with a Delta-connected load.	Standard Handbook for Electrical Engineers
Unbalanced AC System with Y-Connected Load	Video	This video demonstrates how to calculate power characteristics in an unbalanced AC system with a Y-connected load.	Standard Handbook for Electrical Engineers
Unbalanced AC System with Delta-Connected Load	Video	This video demonstrates how to calculate power characteristics in an unbalanced AC system with a Delta-connected load.	Standard Handbook for Electrical Engineers

Relevant Material	Type	Description	Source
Two Ports	Text	Describes an electric circuit with two ports, one for the source and one for the load.	Standard Handbook for Electrical Engineers
Two Port Model	Figure	Figure 2-39 provides an image of a two-port model with voltage and current definitions.	Standard Handbook for Electrical Engineers
Two Port Conversions	Table	Table 2-1 provides a summary of all of the two-port parameter conversions.	Standard Handbook for Electrical Engineers
Transmission Lines	Figure	Figure 2-40 provides an example of two-port analysis with transmission lines to find the h parameters.	Standard Handbook for Electrical Engineers

Relevant Material	Type	Description	Source
Laplace Transform	Text	This section describes the standard equation used to define a Laplace transform.	Standard Handbook for Electrical Engineers
Laplace Transforms	Table	Table 2-2 describes the standard Laplace Transform Theorems.	Standard Handbook for Electrical Engineers
Laplace Transform Pairs	Table	Table 2-3 describes the most frequently used Laplace Transform Pairs.	Standard Handbook for Electrical Engineers
Problem 3.43: Laplace Transforms	Video	This video illustrates how to find the Laplace transform of a signal.	Schaum's Outline of Signals and Systems
Problem 3.49: Inverse Laplace Transforms	Video	This video demonstrates how to find the inverse Laplace transform of a signal.	Schaum's Outline of Signals and Systems
Laplace Transform Circuit Analysis	Figure	Figure 2-41 shows an example of Laplace transform circuit analaysis on a circuit with nonzero initial conditions.	Standard Handbook for Electrical Engineers
Laplace Analysis: Example 1	Video	This video demonstrates how to use Laplace transforms to analyze a circuit with a switch to find the transient and DC steady-state voltages and currents.	Standard Handbook for Electrical Engineers
Laplace Analysis: Example 2	Video	This video demonstrates how to use Laplace transforms to analyze a circuit to find the transient and sinusoidal steady-state reponse.	Standard Handbook for Electrical Engineers
Problem 4.49: Laplace Transforms	Video	This video demonstrates using Laplace transforms to find the forced response of a differential equation.	Schaum's Outline of Feedback and Control Systems
Problem 6.44: Transfer Function Example 1	Video	This video shows how to find the transfer function of an RC Circuit.	Schaum's Outline of Feedback and Control Systems
Problem 4.44/4.45: Initial and Final Value Theorems	Video	This video shows how to find the initial and final values of a function, f(t).	Schaum's Outline of Feedback and Control Systems

Relevant Material	Type	Description	Source
Inverting Amplifier	Figure	Figure 11.4.6 shows an example of an inverting amplifier with two resistors.	Standard Handbook of Electronic Engineering
Integrating Amplifier	Figure	Figure 11.4.7 shows an example of an integrating amplifier with a capacitor in the feedback loop.	Standard Handbook of Electronic Engineering
Differentiating Amplifier	Figure	Figure 11.4.8 shows an example of a differentiating amplifier with an input capacitor.	Standard Handbook of Electronic Engineering
Low Noise Op-Amp Design	Figure	Figure 11.4.17 demonstrates the use of bias to reduce the noise from sources in an operational amplifier design.	Standard Handbook of Electronic Engineering
Nonideal Operational Amplifiers	Video	This video demonstrates how to find the output of a non-ideal operational amplifier with DC offset voltage and currents.	Analog Filter and Circuit Design Handbook
Slew-Rate Limiting on Operational Amplifiers	Video	This video demonstrates how to determine the frequency of the input signal to an op amp given the maximum slew rate.	Analog Filter and Circuit Design Handbook
The Instrumentation Amplifier	Video	This video demonstrates how to derive the transfer function for an instrumentation amplifier and design it for a specified gain.	Analog Filter and Circuit Design Handbook
Half-Wave Precision Rectifier	Video	This video demonstrates how to analyze a half-wave precision rectifier to find the transfer function characteristics.	Analog Filter and Circuit Design Handbook
Full-Wave Precision Rectifier	Video	This video demonstrates how to analyze a full-wave precision rectifier to find the transfer function characteristics.	Analog Filter and Circuit Design Handbook
The Integrator	Video	This video demonstrates how to design an integrator circuit to have certain input and output characteristics.	Analog Filter and Circuit Design Handbook
The Differentiator	Video	This video demonstrates how to design a differentiator circuit to have certain input and output characteristics.	Analog Filter and Circuit Design Handbook
Basic Comparator and Window Comparator	Video	This video demonstrates how to design a comparator to produce a square wave between a given high and low reference voltage.	Analog Filter and Circuit Design Handbook
Converters	Video	This video demonstrates how to design current to voltage and voltage to current converters to have a specific output.	Analog Filter and Circuit Design Handbook
Phase Shift Oscillators	Video	This video demonstrates how to design a phase shift oscillator to produce a sine wave with a certain frequency.	Analog Filter and Circuit Design Handbook
The Wien Bridge Oscillator	Video	This video demonstrates how to design a Wien Bridge Oscillator to exhibit certain characteristics.	Analog Filter and Circuit Design Handbook
Square Wave Relaxation Oscillator	Video	This video demonstrates how to design a square wave relaxation oscillator to produce a square wave with certain characteristics.	Analog Filter and Circuit Design Handbook
Triangular Wave Relaxation Oscillator	Video	This video demonstrates how to design a triangular wave relaxation oscillator to produce a triangular wave with certain characteristics.	Analog Filter and Circuit Design Handbook
Op Amp Design Example 1	Video	This video demonstrates the design of an op amp circuit to satisfy certain output requirements.	Schaum's Outline of Electric Circuits
Op Amp Design Example 2	Video	This video demonstrates how to design an op amp to satisfy a given input-output characteristic and input resistance.	Schaum's Outline of Electric Circuits

Relevant Material	Type	Description	Source
Scaling Components on Prototype Filters	Video	This video demonstrates scaling the component values on a prototype filter.	Standard Handbook of Electronic Engineering
Frequency and Impedance Scaling	Example	Example 2-1 describes how to scale a low pass third order Butterworth filter.	Electronic Filter Design Handbook, Fourth Edition
Scaling Cut Off frequency on Prototype Filters	Video	This video demonstrates scaling the cutoff frequency on a prototype filter.	Standard Handbook of Electronic Engineering
Problem 5.75: RC Filters	Video	This video demonstrates how to use Fourier transforms to find the frequency response, H(w) and the type of filter.	Schaum's Outline of Signals and Systems
Low Pass Filters			Electronic Filter Design Handbook, Fourth Edition
Low Pass Butterworth Filter Design: Example 1	Video	This video demonstrates how to derive a low pass Butterworth filter by using the explicit formulas.	Standard Handbook of Electronic Engineering
Low Pass Butterworth Filter Design: Example 2	Video	This video demonstrates how to derive a low pass Butterworth filter by using a table of values.	Standard Handbook of Electronic Engineering
Low Pass Bessel Filter Design: Example 1	Video	This video illustrates the design of a time delay network by using a Bessel approximation.	Standard Handbook of Electronic Engineering
Low Pass Bessel Filter Design: Example 2	Video	This video illustrates the design of a time delay network by using a Bessel approximation.	Standard Handbook of Electronic Engineering
Normalize and Design a Low Pass Filter	Example	Example 2-3 describes how to normalize the specification for a low pas filter given the cutoff frequency at 1 dB.	Electronic Filter Design Handbook, Fourth Edition
Normalize and Design a Low Pass Filter	Example	Example 2-2 describes how to normalize the specification for a low pas filter given the cutoff frequency at 3 dB.	Electronic Filter Design Handbook, Fourth Edition
Design of an LC Low-Pass Filter	Example	Example 3-1 describes the design of an LC low-pass filter given the cutoff frequency, minimum attenuation and resistor values.	Electronic Filter Design Handbook, Fourth Edition
Design of an LC Low-Pass Filter	Example	Example 3-4 describes the design of a passive low pass filter with a different source and load resistance.	Electronic Filter Design Handbook, Fourth Edition
Design of an Active Low-Pass Filter	Example	Example 3-8 describes the design of an active low-pass filter given the cutoff frequency and minimum attenuation.	Electronic Filter Design Handbook, Fourth Edition
Design of an Active Low-Pass Filter	Example	Example 3-9 describes the design of an active low-pass Butterworth filter given the cutoff frequency and minimum attenuation with a separate real pole section.	Electronic Filter Design Handbook, Fourth Edition
Design of an Active Low-Pass Filter	Example	Example 3-10 describes the design of an active low-pass Butterworth filter given the gain in dB.	Electronic Filter Design Handbook, Fourth Edition
Design of an Active Bessel Low-Pass Filter	Example	Example 3-11 describes the design of an active low-pass Bessel filter given the gain in dB.	Electronic Filter Design Handbook, Fourth Edition
Design of a Chebyshev Low-Pass Filter	Example	Example 2-20 describes the design of a low pass Chebyshev filter and to calculate the pole locations and frequency response.	Electronic Filter Design Handbook, Fourth Edition
Design of a Chebyshev Low-Pass Filter	Example	Example 3-12 describes the design of an active low-pass Chebyshev filter with uniform capacitor values.	Electronic Filter Design Handbook, Fourth Edition
Design of a Butterwoth Low-Pass Filter	Example	Example 2-19 describes how to design a low pass Butterworth filter and calculate the frequency response and pole locations.	Electronic Filter Design Handbook, Fourth Edition
High Pass Filters			Electronic Filter Design Handbook, Fourth Edition
High Pass Chebyshev Filter Design: Example 1	Video	This video illustrates the design of a high pass Chebyshev filter using a table of values.	Standard Handbook of Electronic Engineering
Normalize a High-Pass Specification	Example	Example 2-4 describes how to normalize a high-pass filter given the cutoff frequency	Electronic Filter Design Handbook, Fourth Edition
Design of an Active High-Pass Filter	Example	Example 4-4 demonstrates the design of an active high-pass filter given the cutoff frequency and minimum attenuation.	Electronic Filter Design Handbook, Fourth Edition
Design of a Passive High-Pass Filter	Example	Example 4-1 describes the design of a passive high-pass filter from a normalized low pass filter given the cutoff freqeucny, minimum attentuation and resistor values.	Electronic Filter Design Handbook, Fourth Edition
High Pass Chebyshev Filter Design: Example 2	Video	This video illustrates the design of a high pass Chebyshev filter using the explicit formulas.	Standard Handbook of Electronic Engineering
Bandpass Filter			Electronic Filter Design Handbook, Fourth Edition
Bandpass Chebyshev Filter	Video	This video illustrates the design of a bandpass filter by using a Chebyshev approximation.	Standard Handbook of Electronic Engineering
Normalize and Design a Wideband Bandpass Filter	Example	Example 2-5 describes how to design a bandpass filter given the cutoff frequency and a minimum attenuation at a certain frequency.	Electronic Filter Design Handbook, Fourth Edition
Normalize and Design a Bandpass Filter	Example	Example 2-6 describes how to design a bandpass filter given the center frequency and attenuation at a given frequencies.	Electronic Filter Design Handbook, Fourth Edition
Determine Bandpass Filter Bandwidths	Example	Example 2-7 explains how to determine the bandwidth of a bandpass filter.	Electronic Filter Design Handbook, Fourth Edition
Design of a Passive Bandpass Filter	Example	Example 5-2 describes the design of a passive bandpass filter given the center frequency, cutoff frequencies and resistor values.	Electronic Filter Design Handbook, Fourth Edition
Design of a Wideband Bandpass Filter	Example	Example 5-1 describes the design of a wideband passive bandpass filter given the cutoff frequencies, minimum attenuation and resistor values.	Electronic Filter Design Handbook, Fourth Edition
Design of a Wideband Bandpass Filter	Example	Example 5-10 describes the design of an active wideband bandpass filter given the minimum and maximum attenuation and gain.	Electronic Filter Design Handbook, Fourth Edition
Design a Nonsymmetrical Bandpass Filter	Example	Example 2-8 describes how to normalize a bandpass filter requirement given minimum attenuations and passband limits.	Electronic Filter Design Handbook, Fourth Edition
Bandpass Butterworth Filter	Video	This video illustrates the design of a bandpass filter by using a Butterworth approximation.	Standard Handbook of Electronic Engineering
Band-Reject Filters			Electronic Filter Design Handbook, Fourth Edition
Band-Elimination Butterworth Filter	Video	This video illustrates the design of a band-elimination filter by using a Butterworth approximation.	Standard Handbook of Electronic Engineering
Band-Elimination Chebyshev Filter	Video	This video illustrates the design of a band-elimination filter by using a Chebyshev approximation.	Standard Handbook of Electronic Engineering
Design and Normalize a Narrowband Band-Reject Filter	Example	Example 2-10 describes the design of a narrowband bandreject filter with a given center frequency and cutoff frequencies.	Electronic Filter Design Handbook, Fourth Edition
Design and Normalize a Wideband Band-Reject Filter	Example	Example 2-9 describes the design of a wideband bandreject filter given the cutoff frequencies and miinimum attenauation.	Electronic Filter Design Handbook, Fourth Edition
Design of a Passive Band-Reject Filter	Example	Example 6-1 describes how to design a passive band-reject filter given the center frequency and cutoff frequencies.	Electronic Filter Design Handbook, Fourth Edition
Band-Reject Filter Characteristics	Example	Example 6-2 describes how to find the maximum rejection as a function of the Q.	Electronic Filter Design Handbook, Fourth Edition
Design of an Active Wideband Band-Reject Filter	Example	Example 6-6 describes the design of a wideband band-reject filter given the cutoff frequencies and attenuation.	Electronic Filter Design Handbook, Fourth Edition
Design of an Active Band-Reject Filter	Example	Example 6-8 describes the design of an active band-reject filter given a certain gain.	Electronic Filter Design Handbook, Fourth Edition
Design a Twin-T Band-Reject Filter	Example	Example 6-9 describes the design of twin-t band-reject filter with a given center frequency and bandwidth.	Electronic Filter Design Handbook, Fourth Edition
Attenuators			Standard Handbook of Electronic Engineering
Attenuator PI Network Design	Video	This video illustrates the design of an attenuator by using a PI and T network.	Standard Handbook of Electronic Engineering
Attenuator Bridged-T Network Design	Video	This video illustrates the design of an attenuator by using a bridged-T network.	Standard Handbook of Electronic Engineering

Curriculum Map

Course: Circuit Analysis (DC and AC)

Course Topics

Circuits Quantities

Circuits Elements

Kirchoff's Laws

Circuit Analysis Techniques

Phasor Analysis (Sinusoidal Steady-State)

AC Power

Three-Phase Circuits

Two Ports

Laplace Analysis

Operational Amplifiers

Filters

Sign in

Login for UK Access Management Federation Institutions (Shibboleth)