Presentation is loading. Please wait.

Presentation is loading. Please wait.

Representation of Data (Part II) Computer Studies Notes: chapter 19 Ma King Man.

Published byDorothy Barker Modified over 8 years ago

Similar presentations

Presentation on theme: "Representation of Data (Part II) Computer Studies Notes: chapter 19 Ma King Man."— Presentation transcript:

1 Representation of Data (Part II) Computer Studies Notes: chapter 19 Ma King Man

2 Floating-point number representation E.g.110.011 (2) can be written as 11.0011 x 2 1 or 1.10011 x 2 2 or 0.11011 x 2 3 (Normalized form)

3 Format The basic format is shown as follow: Sign bit Exponent Mantissa Sign bitExponentMantissa

4 Note… Excess 128 method That is, add 128 to the current value.

5 Eg 1 Assume 16-bit word and EXCESS 128 method is used: 13.125 = 1011.001 (ii) = 0.1011001 x 2 4 Fraction= 0.1011001 Exponent= 4 x 128 = 132 = 10000100 (ii) Since the number is positive, therefore the sign bit is 0. Therefore 13.125 will be stored as 0100001001011001

6 E.g.2 -29.75= -11101.11 (ii) = -0.1110111 x 2 5 (normalization) Fraction= 0.1110111 Fraction= 5 + 128 = 133 = 10000101 (ii) Since the number is negative, therefore the sign bit is 1. Therefore –29.75 will be stored as 1100001011110111

7 E.g.3 -0.0625= -0.0001 (ii) = -0.1 x 2 -3 (normalization) Fraction= 0.1000000 Exponent= -3 + 128 = 125 = 01111101 (ii) Since the number is negative, therefore the sign bit is1. Therefore –0.0625 will be stored as 1011111011000000

8 Comparison between fixed-point representation and floating point representation Range Fixed-point numbers Largest positive number = 01111111 11111111 = +32767 Smallest negative number= 10000000 0000000= -32768 Therefore, in 16-bit word storage: -32768 <= fixed point number <= +32767

9 Floating-point representation AAssume excess-128 method and 16-bit word is used, a dloating point representation cab have the following values: Largest positive number= 0 111111111111111  2 +127  10 +38 Smallest positive number= 0 000000001000000  2 -128  10 -39

10 More… Largest negative number= 1 00000001000000  2 -128  -10 -39 Smallest negative number= 1 111111111111111  -2 +127  -10 +38

11 More…thus… Therefore, the range of floating number: -2 127  -2 -128, 0, 2 -128  2 127 From the above, we can see that the range of the floating-point representation is wider than that of fixed-point representation.

Download ppt "Representation of Data (Part II) Computer Studies Notes: chapter 19 Ma King Man."

Similar presentations

Computer Engineering FloatingPoint page 1 Floating Point Number system corresponding to the decimal notation 1,837 * 10 significand exponent A great number.

Computer Engineering FloatingPoint page 1 Floating Point Number system corresponding to the decimal notation 1,837 * 10 significand exponent A great number.
Floating Point (FLP) Representation A Floating Point value: f = m*r**e Where: m – mantissa or fractional r – base or radix, usually r = 2 e - exponent.

Floating Point (FLP) Representation A Floating Point value: f = m*r**e Where: m – mantissa or fractional r – base or radix, usually r = 2 e - exponent.
Faculty of Computer Science © 2006 CMPUT 229 Floating Point Representation Operating with Real Numbers.

Faculty of Computer Science © 2006 CMPUT 229 Floating Point Representation Operating with Real Numbers.
Chapter 1.7 Storing Fractions. Excess Notation, continued… In this notation, m indicates the total number of bits. For us (working with 8 bits), it.

Chapter 1.7 Storing Fractions. Excess Notation, continued… In this notation, "m" indicates the total number of bits. For us (working with 8 bits), it.
CS 447 – Computer Architecture Lecture 3 Computer Arithmetic (2)

CS 447 – Computer Architecture Lecture 3 Computer Arithmetic (2)
Computer ArchitectureFall 2007 © September 5, 2007 Karem Sakallah CS 447 – Computer Architecture.

Computer ArchitectureFall 2007 © September 5, 2007 Karem Sakallah CS 447 – Computer Architecture.
1 CSE1301 Computer Programming Lecture 30: Real Number Representation.

1 CSE1301 Computer Programming Lecture 30: Real Number Representation.
Booth’s Algorithm.

Booth’s Algorithm.
Lecture 3 Number Representation 2 This week – Recap Addition – Addition circuitry – Subtraction of integers in binary – Representing numbers with fractional.

Lecture 3 Number Representation 2 This week – Recap Addition – Addition circuitry – Subtraction of integers in binary – Representing numbers with fractional.
Chapter 5 Floating Point Numbers. Real Numbers l Floating point representation is used whenever the number to be represented is outside the range of integer.

Chapter 5 Floating Point Numbers. Real Numbers l Floating point representation is used whenever the number to be represented is outside the range of integer.
1 Lecture 3 Bit Operations Floating Point – 32 bits or 64 bits 1.

1 Lecture 3 Bit Operations Floating Point – 32 bits or 64 bits 1.
Floating Point Numbers

Floating Point Numbers
Floating Point Numbers

Floating Point Numbers
Computer ArchitectureFall 2008 © August 27, 2008 www.qatar.cmu.edu/~msakr/15447-f08/ CS 447 – Computer Architecture Lecture 4 Computer Arithmetic (2)

Computer ArchitectureFall 2008 © August 27, CS 447 – Computer Architecture Lecture 4 Computer Arithmetic (2)
Computer Science 210 Computer Organization Floating Point Representation.

Computer Science 210 Computer Organization Floating Point Representation.
Binary Number Systems.

Binary Number Systems.
Chapter 3 Data Representation part2 Dr. Bernard Chen Ph.D. University of Central Arkansas Spring 2010.

Chapter 3 Data Representation part2 Dr. Bernard Chen Ph.D. University of Central Arkansas Spring 2010.
Chapter3 Fixed Point Representation Dr. Bernard Chen Ph.D. University of Central Arkansas Spring 2009.

Chapter3 Fixed Point Representation Dr. Bernard Chen Ph.D. University of Central Arkansas Spring 2009.
The Binary Number System

The Binary Number System
Binary Real Numbers. Introduction Computers must be able to represent real numbers (numbers w/ fractions) Two different ways:  Fixed-point  Floating-point.

Binary Real Numbers. Introduction Computers must be able to represent real numbers (numbers w/ fractions) Two different ways:  Fixed-point  Floating-point.

Similar presentations

Ads by Google