MSP 
MSP in Digital System design
Tushar Mehmi, Taruna Rohdia, Upender Yadav
Dronacharya College of Engineering
Abstract— The paper represents the study about MSP( Modeling, Synchronization, Performance) in Digital System Design using VHDL. In digital system design, synchronization ensures that operations occur in the logically correct order, and is a critical factor in ensuring the correct and reliable system operation. As the physical size of a system increases, or as the speed of operation increases, synchronization plays an increasingly dominant role in the system design. Digital communication has developed a number of techniques to deal with synchronization on a global and even cosmic scale; and as the clock speeds of chip, board, and room-sized digital systems increase, they may benefit from similar techniques. The most systematic approaches do not capture the overall performance of the fuzzy circuits during the control process. This paper discusses the influence of different parameters on the global performance of FLCs. Because VHDL is a very powerful and flexible language, it was used here to describe and simulate the fuzzy circuits. Paper is concluded by highlighting some cursory view of RTL level designing part and test benches to verify the functionality of any design.
Keywords— VHDL, PPI, 8255, FLCs
I. Introduction
Microcomputers have developed into a powerful and versatile tool in today’s industry and research labs. In order to control a process by a microcomputer an interface must exist from the microcomputer to the hardware being controlled. An interface can span from a simple to complex design. OPERATIONS in digital systems can either proceed concurrently, or they must obey a precedence relationship.
The most common approach to synchronization is to distribute a clock signal to all modules of the system. With the scaling of feature-sizes in VLSI design, clock speeds are increasing rapidly, but increases in complexity tend to prevent significant
Tushar Mehmi, Taruna Rohdia, Upender Yadav
Dronacharya College of Engineering
Abstract— The paper represents the study about MSP( Modeling, Synchronization, Performance) in Digital System Design using VHDL. In digital system design, synchronization ensures that operations occur in the logically correct order, and is a critical factor in ensuring the correct and reliable system operation. As the physical size of a system increases, or as the speed of operation increases, synchronization plays an increasingly dominant role in the system design. Digital communication has developed a number of techniques to deal with synchronization on a global and even cosmic scale; and as the clock speeds of chip, board, and room-sized digital systems increase, they may benefit from similar techniques. The most systematic approaches do not capture the overall performance of the fuzzy circuits during the control process. This paper discusses the influence of different parameters on the global performance of FLCs. Because VHDL is a very powerful and flexible language, it was used here to describe and simulate the fuzzy circuits. Paper is concluded by highlighting some cursory view of RTL level designing part and test benches to verify the functionality of any design.
Keywords— VHDL, PPI, 8255, FLCs
I. Introduction
Microcomputers have developed into a powerful and versatile tool in today’s industry and research labs. In order to control a process by a microcomputer an interface must exist from the microcomputer to the hardware being controlled. An interface can span from a simple to complex design. OPERATIONS in digital systems can either proceed concurrently, or they must obey a precedence relationship.
The most common approach to synchronization is to distribute a clock signal to all modules of the system. With the scaling of feature-sizes in VLSI design, clock speeds are increasing rapidly, but increases in complexity tend to prevent significant
References: [1] . Michael Combs, Ahmad Zargari, “Construction and Application of a Computer Based Interface Card “ Proceedings of the 2002 American Society for Engineering Education Annual Conference & Exposition, session 3547, 2002. [3] . J.Bhasker, A Vhdl Primer , Third Edition , Prentice-Hall, 1999. [5] . 8255 interface card applications manual. Philadelphia, Boondog Automation Rafiquzzaman, M [11] . Goody, R. W. (1993). Intel microprocessors: Hardware, software and applications. New York,Glencoe. [14] . Widiatmo, H. Eduard and Fendi, “Learning Microprosessor- Microcontroler”, by PT Elex Media Komputindo, Jakarta, Indonesia (1994).