EE2301

From The Circuits and Biology Lab at UMN
Revision as of 14:40, 24 October 2016 by Student (talk | contribs) (→‎Homeworks)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigationJump to search

Introduction to Digital System Design, Fall 2014

Announcements

  • Please email Marc if you haven't been received his emails to the class.
  • There will be no labs or discussions the first week of the semester.

Organization

People

Lecture

  • Tu. & Th. 9:45am - 11:00am, AmundH B75

Discussions

  • Discussion (Section 20): Th. 12:20 P.M. - 01:10 P.M., KHKH 2-26
  • Discussion (Section 21): Th. 01:25 P.M. - 02:15 P.M., STSS 131
  • Discussion (Section 22): Th. 02:30 P.M. - 03:20 P.M., STSS 530
  • Discussion (Section 23): F. 11:15 A.M. - 12:05 P.M., STSS 33

Lab

  • Lab (Section 02), M. 10:10 A.M. - 12:05 P.M., KHKH 2-178
  • Lab (Section 03), M. 01:25 P.M. - 03:20 P.M., KHKH 2-178
  • Lab (Section 04), M. 03:35 P.M. - 05:30 P.M., KHKH 2-178
  • Lab (Section 05), Tu. 11:15 A.M. - 01:10 P.M., KHKH 2-178
  • Lab (Section 06), Tu. 01:25 P.M. - 03:20 P.M., KHKH 2-178
  • Lab (Section 07), Tu. 03:35 P.M. - 05:30 P.M., KHKH 2-178
  • Lab (Section 09), F. 10:10 A.M. - 12:05 P.M., KHKH 2-178
  • Lab (Section 10), W. 01:25 P.M. - 03:20 P.M., KHKH 2-178
  • Lab (Section 11), Th. 04:40 P.M. - 06:35 P.M., KHKH 2-178
  • Lab (Section 12), M. 08:00 A.M. - 09:55 A.M., KHKH 2-178

Office Hours

  • Marc Riedel, KHKH EE/CSi 4-167: Tue. 12:00pm - 2:00pm
  • Tor Anderson, KHKH 2-127: Thurs. 11:00am - 1:00pm
  • Luke Everson, KHKH Lower Level Atrium Commons: Wed. (Table 5) & Fri. (Table 4) 11:00am - 12:00pm
  • Sangho Yun, KHKH EE/Csi 4-149: Wed. 10:00am - 12:00pm
  • Han-Tai Shiao, KHKH EE/CSi 6-110: Mon. 12:00pm - 1:00pm
  • Brandon Veber, KHKH EE/CSi 2-178: Thurs. 3:30pm - 4:30pm

Text & Manuals

Text: Charles H. Roth, Jr., and Larry Kinney, Fundamentals of Logic Design, 7th ed.

Lab Manual: The parts you need for the laboratory are available as a laboratory kit in the ECE stockroom.

Grading

  • Homework: 20%
    • 8 homeworks (2.5% each)
  • Laboratory: 20%
    • 8 experiments (2.5% each)
    • For each experiment:
      • Attendance: 10%
      • Prelab: 10%
      • Report: 60%
      • Evaluation of Lab Work: 20%
  • Midterm Exam 1 (Tu. Oct. 14, 9:45am - 11:00am, AmundH B75): 15%
  • Midterm Exam 2 (Tu.. Nov. 25, 9:45am - 11:00am, AmundH B75): 15%
  • Final Exam (Th. Dec. 18, 8:00am-10:00am, AmundH B75): 30%

Policies

  • Exams are open book/open notes, held in class.
  • Calculators, phones, computers, or any other electronic devices may not be used in the exams.
  • There will be no make-up exams except for verifiable illness or incapacity, approved by the university.
  • An incomplete grade will only be given when all but a small portion of the coursework is complete and the student is unable to finish because of verifiable illness or incapacity, approved by the university. See University Senate Grading Policy.
  • All work submitted for the course must be the sole work of the student. Any student who copies from another or cheats in any manner will receive a 0 for that assignment/exam with the possibility of more severe punishment, such as receiving an 'F' for the course or expulsion. See University Student Conduct Policies: http://regents.umn.edu/sites/regents.umn.edu/files/policies/Student_Conduct_Code.pdf.

Description

The course introduces the students to the theory and th e practice of digital system design, covering topics such as Boolean algebra, logic gates, combinational logic, logic simplification, sequential logic, design of synchronous sequential logic, VHDL modeling, and design of logic circuits lab.

Topics

  • Number Systems (1 week)
  • Introduction to Digital Logic (2 weeks)
    • Gates
    • Combinational Circuits
    • Boolean Expressions
    • Representation of Boolean Functions
      • Truth Tables
      • Two-Level Forms (AND/OR/NAND/NOR)
  • Circuits for Arithmetic Operations (1 week)
    • Design of a Ripple Adder
    • Subtraction, Multiplication by a Scalar
  • Timing Analysis (0.5 weeks)
  • Reduced, Ordered Binary Decision Diagrams (0.5 weeks)
  • Intro to Logic Minimization (1 weeks)
    • Karnaugh maps
  • Advanced to Logic Minimization (1 weeks)
    • Quine-McCluskey Method
    • Joint Minimization of Multiple Functions
  • Hazards (0.5 weeks)
  • Design with "Don't Cares" (0.5 weeks)
  • Combinational Circuit Design (2 weeks)
    • Combinational Logic Modules
      • Multiplexers
      • Encoders/Decoders
      • Comparators
  • Introduction to Sequential Circuits (2 weeks)
    • Latches & Flip-flops
      • S-R and D Latches
      • S-R, J-K, D, and T Flip-Flops
  • Intro to Verilog (1 week)
  • Sequential Circuit Design (3 weeks)
    • State Graphs and Tables
    • Sequential Logic Modules
      • Shifters
      • Counters
      • Registers
    • State Machines
      • State Assignments
      • State Reduction
  • More Verilog (1 week)

Final Exam

Lecture Summaries

[Recommended reading in brackets.]

09/02/14

  • How EE2301 Fits Into ECE Curriculum
  • Why Digital Design is Relevant
  • Why Computers are Amazing
  • Discussion of Grading and Course Organization

[Text 1.1]

09/04/14

All About Number Systems.

  • Converting from base 10 to base x.
  • Converting from base x to base 10.
  • Converting from base x to base y.
  • Converting between base 2, 8, and 16 (or any two bases where one is a power of the other)
  • Fractional numbers.
  • Converting fractional numbers between base 10 and base 2.

[Text 1.2, 1.4]

09/09/14

Binary Arithmetic

  • Addition
  • Multiplication
  • Subtraction
  • Intro Boolean Algebra
  • Truth Table, Circuits, and Boolean Expressions

[Text 1.3, 2.1, 2.2, 2.3]

09/11/14

From Truth Tables to Circuits

  • AND-OR (a.k.a. sum of products)
  • OR-AND (a.k.a. product of sums)

[Text 4.2]

09/16/14

Boolean Algebra

  • Basic Theorems
    • Distributive Law / Factoring
    • De Morgan's Law
    • Uniting, Absorption, Elimination, and Consensus

Exclusive OR

  • Properties
  • XNF Form (a.k.a. Reed-Mueller Form)

[Text 2.4, 2.4, 2.6, 2.7, 2.8, 3.1, 3.2, 3.3]

09/18/14

  • Two-Level Forms
    • AND-OR, NAND-NAND, OR-NAND, NOR-OR
    • OR-AND, NOR-NOR, AND-NOR, NAND-AND
    • AND-XOR (with no negations)
  • Transforming and Simplifying Logic Circuits

[Text 7.3]

09/23/14

  • Combinational vs. Sequential Circuits
  • Acylic vs. Cyclic Circuits
  • Timing Analysis

[Slides, Text 8.3]

09/25/14

09/30/14

  • Graphs, Parity Trees
  • XOR Function of many variables
  • XOR Function with AND/OR gates

10/2/14

Two-Level Logic Minimization

  • Uniting and Absorption Laws
  • K-Maps (Part I)

[Text 2.6, 5]

10/7/14

  • K-Maps (Part II)
  • Quine-McCluskey Method (Part I)

[Text 5, 6]

10/9/14

  • Quine-McCluskey Method (Part II)
  • Multiplexers

[Text 6, 9.2]

10/16/14

  • Midterm

10/21/14

  • Combinational vs. Sequential Circuits
  • Synchronous Sequential Circuits
  • Memory
  • Clocks
  • Ring Oscillator

[Text 13.4]

10/23/14

  • Latches vs. Flip-Flops
  • S-R Latch
  • Gated D Latch
  • Hazards

[Text 8.4, 11.1, 11.2, 11.3]

10/28/14

  • Flip-Flops with Holds and Clears
  • Registers
    • Shift Registers
    • Parallel Load Registers

[Text 11.8, 12.1, 12.2, 12.4]

10/30/14

  • Counters
  • Linear-Feedback Shift Registers

[Text 12.3], Wikipedia Page

11/04/14

  • Special Presentation by Misha Burich: A Career in Digital Design

11/06/14

  • Moore vs. Mealy Machines
  • State Transition Graphs
  • State Transition Diagrams

[Text 14.1, 14.2, 14.3]

11/11/14

  • Synthesizing FSMs with D Flip-Flops and JK Flip-Flops
  • Elimination of Redundant States

[Text 15.1, 15.2, 15.6]

11/13/14

  • Sorting Networks, Part I, Slides

11/18/14

  • Sorting Networks, Part II, Slides

11/20/14

  • Intro to Hardware Description Languages

MIT Slides

12/02/14

  • State Machine Designs with JK Flip-Flops
  • Arithmetic Operations

[Text 12.5, 18.1]

12/04/14

[Text 19]

12/09/14

  • Ideas in Logic Synthesis, Slides

Labs

Lab Experiments

Lab Equipment

Sample Problems

Homeworks

Exams