### 22,000

The approximate number of living ECE ILLINOIS alumni worldwide.

Title | Rubric | Section | CRN | Type | Hours | Times | Days | Location | Instructor |
---|---|---|---|---|---|---|---|---|---|

Elec & Electronic Circuits | ECE205 | AB1 | 65803 | LAB | 0 | 0800 - 0950 | M | 4074 ECE Building | Kiwook Lee |

Elec & Electronic Circuits | ECE205 | AB2 | 65804 | LAB | 0 | 1000 - 1150 | M | 4074 ECE Building | Arunita Kar |

Elec & Electronic Circuits | ECE205 | AB3 | 65805 | LAB | 0 | 1500 - 1650 | M | 4074 ECE Building | Ali Abavisani |

Elec & Electronic Circuits | ECE205 | AB4 | 65806 | LAB | 0 | 1700 - 1850 | M | 4074 ECE Building | James Patrick Keiller |

Elec & Electronic Circuits | ECE205 | AB5 | 65808 | LAB | 0 | 0800 - 0950 | W | 4074 ECE Building | Aditya Shivashankar Shivashankar |

Elec & Electronic Circuits | ECE205 | AB6 | 65809 | LAB | 0 | 1000 - 1150 | W | 4074 ECE Building | Ali Abavisani |

Elec & Electronic Circuits | ECE205 | AB7 | 65810 | LAB | 0 | 1500 - 1650 | W | 4074 ECE Building | Arunita Kar |

Elec & Electronic Circuits | ECE205 | AB8 | 65811 | LAB | 0 | 1700 - 1850 | W | 4074 ECE Building | Tian Xia |

Elec & Electronic Circuits | ECE205 | AB9 | 65812 | LAB | 0 | 0800 - 0950 | R | 4074 ECE Building | Siyan Guo |

Elec & Electronic Circuits | ECE205 | ABA | 65813 | LAB | 0 | 1700 - 1850 | R | 4074 ECE Building | Kyle Richard Michal |

Elec & Electronic Circuits | ECE205 | ABB | 65814 | LAB | 0 | 1000 - 1150 | F | 4074 ECE Building | Yaofeng Chen |

Elec & Electronic Circuits | ECE205 | ABC | 65815 | LAB | 0 | 1500 - 1650 | F | 4074 ECE Building | Kiwook Lee |

Elec & Electronic Circuits | ECE205 | AL1 | 59020 | LEC | 3 | 1200 - 1250 | M W F | 1002 ECE Building | Chandrasekhar Radhakrishnan Zuofu Cheng |

Basic principles of circuit analysis; transient analysis; AC steady-state analysis; introduction to semiconductor devices and fabrication; digital logic circuits; op-amps; A/D and D/A conversion. Course Information: Credit is not given to Computer or Electrical Engineering majors. Prerequisite: PHYS 212. Class Schedule Information: Students must register for one lecture and one lab.

Core Curriculum

Basic principles of circuit analysis, transient analysis, AC steady-state analysis, introduction to semiconductor devices and fabrication, digital logic circuits, op-amps, and A/D and D/A conversion.

ECE students may not receive credit for this course.

This course is designed to give non-majors in engineering an introduction to electric circuits, semiconductor devices, and microelectronic circuits.

- Introduction: Charge, current, voltage, power, circuit elements, Ohm's law
- Kirchhoff's current and voltage laws, voltage and current divisions
- Node-voltage, mesh-current methods, superposition, and equivalence theorems
- RC and RL circuits, first-order network, step response
- Sinusoidal excitation and phasors
- AC steady-state analysis and AC steady-state power
- Frequency response, passive filters
- Semiconductor physics
- Diodes, diode circuit analysis
- MOS cicuit analysis
- MOS logic circuits: nMOS and CMOS
- BJT circuit analysis
- BJT logic circuits: RTL, DTL, TTL, and ECL
- Propagation delay, rise and fall time, and noise margin
- Op-amps, DAC and ADC

This course is designed to give non-majors in engineering an introduction to electric circuits, semiconductor devices, and microelectronic circuits.

Topics:

- Introduction: Charge, current, voltage, power, circuit elements, Ohm's law
- Kirchhoff's current and voltage laws, voltage and current divisions
- Node-voltage, mesh-current methods, superposition, and equivalence theorems
- RC and RL circuits, first-order network, step response
- Sinusoidal excitation and phasors
- AC steady-state analysis and AC steady-state power
- Frequency response, passive filters
- Semiconductor physics
- Diodes, diode circuit analysis
- MOS cicuit analysis
- MOS logic circuits, including nMOS and CMOS
- BJT circuit analysis
- BJT logic circuits, including RTL and TTL
- Propagation delay, rise and fall time, and noise margin
- Op-amps, DAC and ADC

ECE students may not receive credit for this course.

ECE 205 homework and quiz problems are computerized using Lon-Capa, a web-based education system.

- Physics in electricity and magnetism
- Differential and integral calculus
- Linear, ordinary differential equations

*Essentials of Electrical and Computer Engineering* by D. V. Kerns, Jr. and J. D. Irwin, Prentice-Hall.

Engineering Science: 100%

ECE 205 is an introductory course in circuit analysis for non-majors in engineering. The goals are to impart the fundamental principles of electric circuits, semiconductor devices, and electronic circuits that constitute the foundation for preparing a non-major to take follow-on courses involving electric and electronic circuits. The lab work is provided in ECE 206.

**By the time of Hour Exam I (after 9 lectures + review), the students should be able to do the following:**

- Calculate the currents and voltages in resistive circuits using Ohm’s law, KCL, KVL, reduction of series and parallel resistances, and voltage and current divisions (a)
- Find the node voltages in resistive circuits containing current sources and voltage sources using nodal analysis (a)
- Find the mesh currents and branch currents in resistive circuits containing voltage sources and current sources using mesh analysis (a)
- Analyze resistive circuits containing multiple sources by using superposition (a)
- Apply Thevenin’s and Norton’s theorems to simplify a resistive circuit by finding the Thevenin or Norton equivalent of a two-terminal network (a)
- Determine the initial conditions of circuits containing capacitors and inductors using capacitor rules and inductor rules (a)
- Calculate the currents and voltages of a first-order network containing a switch, and find the step response of a first-order network containing a step source (a, m)
- Calculate the currents and voltages in a circuit containing diodes using the simple constant-voltage model for the diode(s) (a, m)

**By the time of Hour Exam II (after 19 lectures + review(s)), the students should be able to do all of the items listed under A, plus the following:**

- Determine the modes of operation of the MOSFET and calculate the voltages and currents in a MOS dc circuit, and find the power dissipated by the MOSFET (a, m)
- Determine the modes of operation of the MOSFETs and find the output voltage and the drain current(s) of various simple inverter circuits for given input voltages (a, m)
- Determine the modes of operation of the MOSFETs and find the output voltage and the drain current of a CMOS inverter for given input voltages (a, m)
- Calculate the static power dissipated by a MOS logic circuit for given input voltages (a, m)
- Determine the modes of operation of the BJT and calculate the voltages and currents in a BJT dc circuit, and find the power dissipated by the BJT (a, m)
- Determine the modes of operation of the BJTs and the on/off condition of the diodes, and calculate the voltages and currents in various simple BJT/diode circuits for given input voltages (a, m)
- Calculate the voltages and currents in a circuit containing ideal op amps using ideal op amp rules (a, m)

**By the time of the Final Exam (25 lectures + review(s)), the student should be able to do all of the items listed under A and B, plus the following:**

- Find the phasor voltage (current) for a given sinusoidal voltage (current), and find the sinusoidal voltage (current) for given phasor voltage (current) and frequency (a)
- Find the impedances of resistors, capacitors, and inductors for a given frequency (a)
- Analyze a phasor circuit using Ohm’s law, KCL, KVL, reduction of series and parallel impedances, and voltage and current divisions (a)
- Calculate the phasor voltages and currents in a phasor circuit by applying nodal analysis (a)
- Calculate the phasor voltages and currents in a phasor circuit by applying mesh analysis (a)
- Find the phasor voltages and currents in a phasor circuit containing multiple sources using superposition (a)
- Apply Thevenin’s and Norton’s theorems to simplify a phasor circuit by finding the Thevenin or Norton equivalent of a two-terminal network (a)
- Calculate AC steady-state power dissipated by the circuit elements in a circuit (a)
- Compute the RMS value for a given voltage (current) waveform (a, m)
- Determine the power factor of a two-terminal network, and find the impedance for required power factor correction (a, m)
- Find the transfer function of a passive filter, determine the type of the filter, and calculate the cutoff frequencies (a, m)

8/22/2014by Michael J. Haney

The approximate number of living ECE ILLINOIS alumni worldwide.

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