Book description
As digital circuit elements decrease in physical size, resulting in increasingly complex systems, a basic logic model that can be used in the control and design of a range of semiconductor devices is vital. Finite State Machines (FSM) have numerous advantages; they can be applied to many areas (including motor control, and signal and serial data identification to name a few) and they use less logic than their alternatives, leading to the development of faster digital hardware systems.
This clear and logical book presents a range of novel techniques for the rapid and reliable design of digital systems using FSMs, detailing exactly how and where they can be implemented. With a practical approach, it covers synchronous and asynchronous FSMs in the design of both simple and complex systems, and Petri-Net design techniques for sequential/parallel control systems. Chapters on Hardware Description Language cover the widely-used and powerful Verilog HDL in sufficient detail to facilitate the description and verification of FSMs, and FSM based systems, at both the gate and behavioural levels.
Throughout, the text incorporates many real-world examples that demonstrate designs such as data acquisition, a memory tester, and passive serial data monitoring and detection, among others. A useful accompanying CD offers working Verilog software tools for the capture and simulation of design solutions.
With a linear programmed learning format, this book works as a concise guide for the practising digital designer. This book will also be of importance to senior students and postgraduates of electronic engineering, who require design skills for the embedded systems market.
Note: The ebook version does not provide access to the companion files.
Table of contents
- Cover Page
- Title Page
- Copyright
- Contents
- Preface
- Acknowledgements
- 1: Introduction to Finite-State Machines and State Diagrams for the Design of Electronic Circuits and Systems
- 2: Using State Diagrams to Control External Hardware Subsystems
- 3: Synthesizing Hardware from a State Diagram
-
4: Synchronous Finite-State Machine Designs
- 4.1 TRADITIONAL STATE DIAGRAM SYNTHESIS METHOD
- 4.2 DEALING WITH UNUSED STATES
- 4.3 DEVELOPMENT OF A HIGH/LOW ALARM INDICATOR SYSTEM
- 4.4 SIMPLE WAVEFORM GENERATOR
- 4.5 THE DICE GAME
- 4.6 BINARY DATA SERIAL TRANSMITTER
- 4.7 DEVELOPMENT OF A SERIAL ASYNCHRONOUS RECEIVER
- 4.8 ADDING PARITY DETECTION TO THE SERIAL RECEIVER SYSTEM
- 4.9 AN ASYNCHRONOUS SERIAL TRANSMITTER SYSTEM
- 4.10 CLOCKED WATCHDOG TIMER
- 4.11 SUMMARY
-
5: The One Hot Technique in Finite-State Machine Design
- 5.1 THE ONE HOT TECHNIQUE
- 5.2 A DATA ACQUISITION SYSTEM
- 5.3 A SHARED MEMORY SYSTEM
- 5.4 FAST WAVEFORM SYNTHESIZER
- 5.5 CONTROLLING THE FINITE-STATE MACHINE FROM A MICROPROCESSOR/MICROCONTROLLER
- 5.6 A MEMORY-CHIP TESTER
- 5.7 COMPARING ONE HOT WITH THE MORE CONVENTIONAL DESIGN METHOD OF CHAPTER 4
- 5.8 A DYNAMIC MEMORY ACCESS CONTROLLER
- 5.9 HOW TO CONTROL THE DYNAMIC MEMORY ACCESS FROM A MICROPROCESSOR
- 5.10 DETECTING SEQUENTIAL BINARY SEQUENCES USING A FINITE-STATE MACHINE
- 5.11 SUMMARY
- 6: Introduction to Verilog HDL
- 7: Elements of Verilog HDL
-
8: Describing Combinational and Sequential Logic using Verilog HDL
- 8.1 THE DATA-FLOW STYLE OF DESCRIPTION: REVIEW OF THE CONTINUOUS ASSIGNMENT
- 8.2 THE BEHAVIOURAL STYLE OF DESCRIPTION: THE SEQUENTIAL BLOCK
- 8.3 ASSIGNMENTS WITHIN SEQUENTIAL BLOCKS: BLOCKING AND NONBLOCKING
- 8.4 DESCRIBING COMBINATIONAL LOGIC USING A SEQUENTIAL BLOCK
- 8.5 DESCRIBING SEQUENTIAL LOGIC USING A SEQUENTIAL BLOCK
- 8.6 DESCRIBING MEMORIES
- 8.7 DESCRIBING FINITE-STATE MACHINES
- REFERENCES
-
9: Asynchronous Finite-State Machines
- 9.1 INTRODUCTION
- 9.2 DEVELOPMENT OF EVENT-DRIVEN LOGIC
- 9.3 USING THE SEQUENTIAL EQUATION TO SYNTHESIZE AN EVENT FINITE-STATE MACHINE
- 9.4 IMPLEMENTING THE DESIGN USING SUM OF PRODUCT AS USED IN A PROGRAMMABLE LOGIC DEVICE
- 9.5 DEVELOPMENT OF AN EVENT VERSION OF THE SINGLE-PULSE GENERATOR WITH MEMORY FINITE-STATE MACHINE
- 9.6 ANOTHER EVENT FINITE-STATE MACHINE DESIGN FROM SPECIFICATION THROUGH TO SIMULATION
- 9.7 THE HOVER MOWER FINITE-STATE MACHINE
- 9.8 AN EXAMPLE WITH A TRANSITION WITHOUT ANY INPUT
- 9.9 UNUSUAL EXAMPLE: RESPONDING TO A MICROPROCESSOR-ADDRESSED LOCATION
- 9.10 AN EXAMPLE THAT USES A MEALY OUTPUT
- 9.11 AN EXAMPLE USING A RELAY CIRCUIT
- 9.12 RACE CONDITIONS IN AN EVENT FINITE-STATE MACHINE
- 9.13 WAIT-STATE GENERATOR FOR A MICROPROCESSOR SYSTEM
- 9.14 DEVELOPMENT OF AN ASYNCHRONOUS FINITE-STATE MACHINE FOR A CLOTHES SPINNER SYSTEM
- 9.15 CAUTION WHEN USING TWO-WAY BRANCHES
- 9.16 SUMMARY
- REFERENCES
-
10: Introduction to Petri Nets
- 10.1 INTRODUCTION TO SIMPLE PETRI NETS
- 10.2 SIMPLE SEQUENTIAL EXAMPLE USING A PETRI NET
- 10.3 PARALLEL PETRI NETS
- 10.4 SYNCHRONIZING FLOW IN A PARALLEL PETRI NET
- 10.5 SYNCHRONIZATION OF TWO PETRI NETS USING ENABLING AND DISABLING ARCS
- 10.6 CONTROL OF A SHARED RESOURCE
- 10.7 A SERIAL RECEIVER OF BINARY DATA
- 10.8 SUMMARY
- REFERENCE
- Appendix A: Logic Gates and Boolean Algebra Used in the Book
-
Appendix B: Counting and Shifting Circuit Techniques
- B.1 BASIC UP AND DOWN SYNCHRONOUS BINARY COUNTER DEVELOPMENT
- B.2 EXAMPLE FOR A 4-BIT SYNCHRONOUS UP-COUNTER USING T-TYPE FLIP-FLOPS
- B.3 PARALLEL-LOADING COUNTERS: USING T FLIP-FLOPS
- B.4 USING D FLIP-FLOPS TO BUILD PARALLEL-LOADING COUNTERS WITH CHEAP PROGRAMMABLE LOGIC DEVICES
- B.5 SIMPLE BINARY UP-COUNTER: WITH PARALLEL INPUTS
- B.6 CLOCK CIRCUIT TO DRIVE THE COUNTER (AND FINITE-STATE MACHINES)
- B.7 COUNTER DESIGN USING DON'T CARE STATES
- B.8 SHIFT REGISTERS
- B.9 ASYNCHRONOUS RECEIVER DETAILS OF CHAPTER 4
- B.10 SUMMARY
- Appendix C: Tutorial on the Use of Verilog HDL to Simulate a Finite-State Machine Design
- Appendix D: Implementing State Machines using Verilog Behavioural Mode
- Index
Product information
- Title: FSM-based Digital Design using Verilog HDL
- Author(s):
- Release date: May 2008
- Publisher(s): Wiley
- ISBN: 9780470060704
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