EHB 322E: Digital Electronic Circuits

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Contents

Announcements

  • Apr. 4th The second homework has been posted that is due 17/04/2017 (before the lecture).
  • Mar. 16th Midterm-1 will be held in rooms 5302 and 5202 between 15:30 - 17:30 on March 20th.
  • Feb. 20th The first homework has been posted that is due 06/03/2017 (before the lecture).
  • Feb. 6th The class is given in the room 5302 (third floor), EEF.
  • Feb. 3rd As a simulation tool, Spice is required for homeworks. Among different Spice-based programs, LTspice is a good and free choice; you can download it by clicking here.

Syllabus

EHB 322E: Digital Electronic Circuits, CRN: 21161, Mondays 13:30-16:30, Room: 5302 (EEF), Spring 2017.
Instructor

Mustafa Altun

  • Email: altunmus@itu.edu.tr
  • Tel: 02122856635
  • Office hours: 15:00 – 16:30 on Tuesdays in Room:3005, EEF (or stop by my office any time)
Teaching Assistant

Furkan Peker

  • Email: furkan.peker061@gmail.com
  • Room: 3207 EEF
Grading
  • Quizzes: 10%
    • 2 pop-up quizzes (5% each) - no prior announcement of quiz dates and times
  • Homeworks: 10%
    • 3 homeworks (3.3% each)
  • Midterm Exams: 40%
    • 2 midterms (20% each) during the lecture time that will on 20/3/2017 and 24/4/2017.
  • Final Exam: 40%
Reference Books
  • Rabaey, J. M., Chandrakasan, A. P., & Nikolic, B. (20XX). Digital integrated circuits. Englewood Cliffs: Prentice hall.
  • Uyemura, J. P. (20XX). CMOS logic circuit design. Springer.
  • Kang, S. M., & Leblebici, Y. (20XX). Cmos Digital Integrated Circuits. McGraw-Hill Education.
Policies
  • Homeworks are due at the beginning of class. Late homeworks will be downgraded by 20% for each day passed the due date.
  • Quizzes and exams are in closed-notes and closed-books format.
  • To be eligible of taking the final or the resit exam, your midterm average should be at least 25 (out of 100).

Weekly Course Plan

Date
Topic
Week 1, 6/2/2017 Introduction
Week 2, 13/2/2017 Switching theory & devices for digital circuits and inverters
Week 3, 20/2/2017 NMOS/CMOS inverters & their static and dynamic behaviors
Weeks 4, 27/2/2017 Optimization of multiple-stage inverters and buffers
Weeks 5, 6/3/2017 Static logic gates and area-delay-power performance analysis
Week 6, 13/3/2017 Complex logic gates and their delays
Weeks 7, 20/3/2017 MIDTERM I
Week 8, 27/3/2017 HOLIDAY, no class
Week 9, 3/4/2017 Pass transistor logic with Shannon's expansion and performance analysis
Weeks 10, 10/4/2017 Dynamic logic gates, synchronization, and performance analysis
Week 11, 17/4/2017 Static and dynamic memory elements: D, SR, and JK flip-flops
Week 12, 24/4/2017 MIDTERM II
Weeks 13, 1/5/2017 HOLIDAY, no class
Weeks 14, 8/5/2017 Synchronization and timing analysis of digital circuits having logic and memory elements
Weeks 15, 15/5/2017 Semiconductor memories and gate arrays: RAM's, ROM's, and flash memories

Course Materials

Homeworks & Solutions Quizzes & Solutions Exams
Homework 1 & Solutions Quiz 1 & Solutions Midterm 1
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