Course image ETE2261: DIGITAL AND ELECTRONIC CIRCUITS
Trimester 2
ETE2261: DIGITAL AND ELECTRONIC CIRCUITS
  1.      Course description

This module gives a deep knowledge to further understand the working principles of electronic devices and circuits. It covers Logic Gates, Combinational Circuits, Flip-flops, Registers and Counters, Semiconductor memories and Fundamentals of sequential circuit modes.

      2.      Learning Outcomes

Knowledge and Understanding

Having successfully completed the module, students should be able to demonstrate knowledge and understanding of:

  1. Different technologies of implementing logic gates
  2. Various common combinational circuits
  3. Flip-flops, registers and counters
  4. Semiconductors memories
  5. Principles of sequential circuits design

 Cognitive/Intellectual skills/Application of Knowledge

Having successfully completed the module, students should be able to:

  1. Implement logic gates using various technologies
  2. Design various combinational circuits such as adders, subtractors, encoders, decoders, multiplexers and demultiplexers, comparators, and code converters.
  3. Implement combinational circuits using EPROM, EEPROM, PAL and PLA
  4. Design counters and other sequential circuits.

Communication/ICT/Numeracy/Analytic Techniques/Practical Skills

Having successfully completed the module, students should be able to:

  1. Demonstrate in-depth understanding of design of Combinational circuit.
  2. Analyze Combinational and sequential circuits.
  3. Apply methods of solution to Combinational and sequential circuits

General transferable   skills

Having successfully completed the module, students should be able to:

  1. Undertake self-learning in Digital Electronics
  2. Communicate technical ideas in writing

 3.       Indicative Content

Numbers systems, Binary numbers, Boolean algebra, Boolean minimisation, Combinational circuits, Logic families, flip flops Counters, Multivariable Boolean reduction,

Synchronous and asynchronous sequential circuits, Programmable logic design techniques

Logic Gates

RTL, DTL, TTL, ECL, ICL, HTL, NMOS & CMOS logic gates, Circuit diagram and analysis characteristics and specifications, tri-state gates.

Combinational Circuits

Problem formulation and design of combinational circuits, Adder / Subtractor, Encoder / decoder, Mux/Demux, Code-converters, Comparators, Implementation of combinational logic using standard ICs, ROM, EPROM, EEPROM, PAL, PLA and their use in combinational circuit design.

Sequential Circuits

Flipflops - SR, JK, T, D, Master/Slave FF, Triggering of FF, Analysis of clocked sequential circuits - their design, State minimization, state assignment, Circuit implementation, Registers-Shift registers, Ripple counters, Synchronous counters, Timing signal, RAM, Memory decoding, Semiconductor memories.

Fundamental Mode Sequential Circuits

Stable, Unstable states, Output specifications, Cycles and Races, Racefree Assignments, Hazards, Essential hazards, Pulse mode sequential circuits.

4. LEARNING AND TEACHING STRATEGY

Students will learn factual material through lectures and guided reading. Tutorials will be used to apply the basic principles. Laboratory work that will be done in a co-requisite separate course will be used to demonstrate concepts and show differences between theory and reality.

Lecture notes will be given to students prior to all lectures. That would help the learners to clarify their doubts during lecture time and make it more interactive.

Problem sheets are given out to students and after time, the problems are discussed in class.  Some of the problems will be handed in and then marked by peers to give formative feedback to fellow students.

5.      ASSESSMENT STRATEGY

To assess understanding by a written examination

To assess self-learning by an open-ended assignment

6. ASSESSMENT PATTERN

Component

Weighting (%)

In-course assessment:

 

Assessment Test

30%

CAT

20%

 

 

Final examination

50%

7.  Strategy for feedback and student support during module 

Interactive lecturing style, with opportunities for questions, and requirement to work on simple problems,Peer marking of tutorial questions for formative feedback.

Tutorial classes where students can ask questions and be lead through solutions as required.

Marked assessments handed back to students, with comments.

Opportunities to consult lecturer and/or tutorial assistant in office hours.

8.      INDICATIVE RESOURCES

Core Text (include number in library or URL) (Inc ISBN)

  1. Digital Principles and Applications by Malvino Leach
  2. Modern Digital Electronics by R.P. Jain
  3. Digital fundamentals by Thomas L. Floyd        

Background Texts (include number in library or URL) (inc ISBN)

  1. Digital Computer Electronics by Malvino Brown
  2. Fundamental of Electrical Engineering by Bobrow
  3. Kohavi, Z., Switching & Finite automata Theory, Tata McGraw-Hill, New Delhi, 1981
  4. Hachtel, G.D. &Somenzi, F., Logic Synthesis and Verification algorithms, Kluwer academic press 1996.
  5. Hill. J. Peterson, G.L., Switching Theory and Logical design, John Wiley III Edition, 1981.
  6. Lee, S., Digital Circuits & Logic Design, Prentice Hall India, 1980.
  7. DIGITAL ELECTRONICS: Circuits and Systems, By Puri, V. TMH , 2005