1. Introduction to Digital Electronics

2. Suplementary Reading Digital Design by - John F. Wakerly –www.ddpp.com - you will find some solutions at this site. –www.xilinx.com - Xlinix Web site Logic and Computer Design Fundamentals by - M. Morris Mano & Charles R. Kime Digital Design by - M. Morris Mano Digital Logic Circuit Analysis and Design by - Victor P. Nelson, H. Troy Nagle, J. David Irwin & Bill D. Carrol

3. Digital Electronics Digital Electronics represents information (0, 1) with only two discrete values. Ideally “no voltage” (e.g., 0v) represents a 0 and “full source voltage” (e.g., 5v) represents a 1 Realistically “low voltage” (e.g., 4v) represents a 1 We achieve these discrete values by using switches. We use transistor switches, which operates at high speed, electronically, a small in size.

4. Analog versus Digital Analog systems process time-varying signals that can take on any value across a continuous range of voltages (in electrical/electronics systems). Digital systems process time-varying signals that can take on only one of two discrete values of voltages (in electrical/electronics systems). –Discrete values are called 1 and 0 (ON and OFF, HIGH and LOW, TRUE and FALSE, etc.)

5. Representing Information Electronically A light bulb has to represent 4 different information: Bulb off-no student inside Bulb 1/3 lit -1 student inside Bulb 2/3 lit -2 student inside Bulb Full lit -3 student inside A light bulb has to represent 10 different information: –Is it possible to differentiate the ten different light intensity?

6. Representing Information Electronically A light bulb has to represent 2 different information: Bulb off-no student inside Bulb Full lit -1 student inside A light bulb has to represent 4 different information: –How? With one bulb? –Use two bulbs A light bulb has to represent 10 different information: –Use four bulbs

7. Representing Information Electronically “Analog electronics” deals with non-discrete values “Digital electronics” deals with discrete values

8. Benefits of Digital over Analog Reproducibility Not effected by noise means quality Ease of design Data protection Programmable Speed Economy

9. Digital Revolution Digital systems started back in 1940s. Digital systems cover all areas of life: –still pictures –digital video –digital audio –telephone –traffic lights –Animation

10. Digital Devices Gates Flip-Flops PLDs FPGAs

11. Gates The most basic digital devices are called gates. Gates got their name from their function of allowing or blocking (gating) the flow of digital information. A gate has one or more inputs and produces an output depending on the input(s). A gate is called a combinational circuit. Three most important gates are: AND, OR, NOT

12. Digital Logic Binary system -- 0 & 1, LOW & HIGH, negated and asserted. Basic building blocks -- AND, OR, NOT

13. AND, OR, NOT Gates

15. Electronic Aspects of Digital Design How we represent digital information in electronic devices? By discrete voltages.

16. What is the Basic Digital Element in Electronics ? a Switch

17. Using Switch to represent digital information

18. Digital Abstraction It is difficult to make ideal switches means a switch is completely ON or completely OFF. So, we impose some rules that allow analog behavior to be ignored in most cases, so circuits can be modeled as if they really did process 0s and 1s, known as digital abstraction. Digital abstraction allows us to associate a noise margin with each logic values (0 and 1).

19. Real Switches to represent digital information 5v 1k  10k  5v4.5v Output

20. Logic levels Undefined region is inherent digital, not analog Switching threshold varies with voltage, temp need “noise margin” Logic voltage levels decreasing with new processors. 5, 3.3, 2.5, 1.8 V

21. MOS Transistors NMOS PMOS Voltage-controlled resistance

22. CMOS Inverter

23. Switch model

24. Flip-flops A device that stores either a 0 or 1. Stored value can be changed only at certain times determined by a clock input. New value depend on the current state and it’s control inputs A digital circuit that contains filp-flops is called a sequential circuit

25. Flip-flops S-R latch symbolsD flip-flop J-K flip-flops

26. Integrated Circuits A collection of one or more gates fabricated on a single silicon chip is called an integrated circuit (IC). ICs were classified by size: –SSI - small scale integration - 1~20 gates –MSI - medium scale integration - 20~200 gates –LSI - large scale integration - 200~200,000 gates –VLSI - very large scale integration - over 1M transistors Pentium-III - 40 million transistors

27. DIP Packages

28. Gates in ICs

29. Programmable Logic Devices PLDs allow the function to be programmed into them after they are manufactured. Complex PLDs (CPLD) are a collection of PLDs on the same chip. Another programmable logic chip is FPGA - field-programmable gate arrays.

30. CPLDs and FPGAs FPGACPLD

31. Application Specific ICs (ASICs) Chips designed for a particular application are called semicustom ICs or application-specific ICs (ASICs). ASICs generally reduce the total component and manufacturing cost of a product by reducing chip count, physical size, and power consumption, and they often provide higher performance. But costly if not produced in bulk.

32. Printed-Circuit Boards An IC is normally mounted on a printed-circuit board (PCB) that connects it to other ICs in a system. Individual wire connection or traces can be as narrow as 4 mils with 4 mils spacing (one- thousandth of an inch) Now a days, most of the components use surface mount technology. They are normally layered.

33. Software Aspects of Digital Design Today software tools are an essential part of digital design. Software tools improve productivity, correctness and quality of designs Software tools are: –Schematic entry –HDL (Hardware Description Language) Editors –Simulators - to verify the behaviour of the design –Synthesis tools - circuit design –Timing analyzers and verifiers

34. Digital Design Levels the lowest level of design is device physics and IC manufacturing processes. design at the transistor level level of functional building blocks level of logic design using HDLs computer design and overall system design.

35. Different Design Levels Consider a simple design example: Build a multiplexer with two data inputs A and B, a control input S, and an output Z. Switch model for the example multiplexer

36. Designing at the transistor level Transistor-level circuit diagrams Gate symbols (for simple elements)

37. Logic design using Truth tables

38. Logic design using boolean algebra Equations: Z = S  A  + S  B Logic diagrams

39. Prepackaged building blocks, e.g. multiplexer

40. Various hardware description languages –ABEL –VHDL We’ll start with gates and work our way up

41. Name of the program module the type of PLD pin numbers ABEL statement to achieve the multiplexer Standard library and a set of definitions Inputs and outputs functions behaviour

42. Structural VHDL program for the multiplexer

43. Summery Design to minimize cost. Rule of thumb is to minimize the number of ICs. Though PLDs costs more but uses less PCB area. Unless mass production avoid ASIC design. Design to solve real life problems.