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James Tam Numerical Representations On The Computer: Negative And Rational Numbers How are negative and rational numbers represented on the computer?

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Presentation on theme: "James Tam Numerical Representations On The Computer: Negative And Rational Numbers How are negative and rational numbers represented on the computer?"— Presentation transcript:

1 James Tam Numerical Representations On The Computer: Negative And Rational Numbers How are negative and rational numbers represented on the computer?

2 James Tam Representing Negative Numbers Real world Positive numbers – just use the appropriate type and number of digits e.g., 12345. Negative numbers – same as the case of positive numbers but precede the number with a negative sign “-” e.g., -123456. Computer world Positive numbers – convert the number to binary e.g., 7 becomes 111 Negative numbers – employ signed representations.

3 James Tam Unsigned Binary All of the digits (bits) are used to represent the number e.g. 1010 2 = 10 10 The sign must be represented explicitly (with a minus sign “-”). e.g. –1010 2 = -10 10

4 James Tam Signed Binary One bit (called the sign bit or the most significant bit/MSB) is used to indicate the sign of the number If the MSB equals 0 then number is positive e.g. 0 bbb is a positive number (bbb stands for a binary number) If the MSB equals 1 then the number is negative e.g. 1 bbb is a negative number (bbb stands for a binary number) Types of signed representations One's complement Two's complement Positive Negative

5 James Tam Converting From Unsigned Binary to 1’s Complement For positive values there is no difference e.g., positive seven 0111 (unsigned) For negative values reverse (flip) the bits (i.e., a 0 becomes 1 and 1 becomes 0). e.g., minus six -0110 (unsigned) 0111 (1’s complement) 1001 (1’s complement)

6 James Tam Converting From Unsigned Binary to 2’s Complement For positive values there is no difference e.g., positive seven 0111 (unsigned) For negative values reverse (flip) the bits (i.e., a 0 becomes 1 and 1 becomes 0) and add one to the result. e.g., minus six -0110 (unsigned) 0111 (2’s complement) 1010 (2’s complement)

7 James Tam Interpreting The Pattern Of Bits Bit patternUnsigned binary1’s complement2's complement 0000000 0001111 0010222 0011333 0100444 0101555 0110666 0111777 10008-7-8 10019-6-7 101010-5-6 101111-4-5 110012-3-4 110113-2-3 111014-2 111115-0

8 James Tam Overflow: Unsigned Occurs when you don't have enough bits to represent a value Binary (1 bit) Value 00 11 Binary (2 bits) Value 000 011 102 113 Binary (3 bits) Value 0000 0011 0102 0113 1004 1015 1106 1117

9 James Tam Overflow: Signed In all cases it occurs do to a “shortage of bits” Subtraction – subtracting two negative numbers results in a positive number. e.g. - 7 - 1 + 7 Addition – adding two positive numbers results in a negative number. e.g. 7 + 1 - 8

10 James Tam Summary Diagram Of The 3 Binary Representations Overflow

11 James Tam Binary Subtraction Unsigned binary subtraction e.g., 1000 2 - 0010 2 0110 2 Subtraction via complements (negate and add) A - B Becomes A + (-B)

12 James Tam Binary Subtraction Via Negate And Add: A High- Level View What is x – y (in decimal)? I only speak binary

13 James Tam Binary Subtraction Via Negate And Add: A High- Level View I only do subtractions via complements

14 James Tam Binary Subtraction Via Negate And Add: A High- Level View 1) Convert the decimal values to unsigned binary 4) Convert the complements to decimal values 2) Convert the unsigned binary values to complements 5) Convert the unsigned binary values to decimal 3) Perform the subtraction via negate and add This section

15 James Tam Crossing The Boundary Between Unsigned And Signed Unsigned binary One's complement Two's complement Each time that this boundary is crossed (steps 2 & 4) apply the rule: 1)Positive numbers pass unchanged 2)Negative numbers must be converted

16 James Tam Binary Subtraction Through 1’s Complements 1)Negate any negative numbers (flip the bits) to convert to 1's complement 2)Add the two binary numbers 3)Check if there is overflow (a bit is carried out) and if so add it back. 4)Convert the 1’s complement value back to unsigned binary (check the value of the MSB) a)If the MSB = 0, the number is positive (leave it alone) b)If the MSB = 1, the number is negative (flip the bits) and precede the number with a negative sign

17 James Tam Binary subtraction through 1’s complements e.g. 01000 2 - 00010 2 Step 1: Negate 01000 2 11101 2 Step 2: Add no.’s 01000 2 11101 2 00101 2 1 Step 3: Check for overflow ______ +1 2 Step 3: Add it back in 00110 2 Step 4: Check MSB

18 James Tam Binary subtraction through 1’s complements e.g. 01000 2 - 00010 2 Step 1: Negate 01000 2 11101 2 Step 2: Add no.’s 01000 2 11101 2 00101 2 ______ +1 2 Step 3: Add it back in 00110 2 Leave it alone

19 James Tam Binary subtraction through 2’s complements 1)Negate any negative numbers to convert from unsigned binary to 2's complement values a)Flip the bits. b)Add one to the result. 2)Add the two binary numbers 3)Check if there is overflow (a bit is carried out) and if so discard it. 4)Convert the 2’s complement value back to unsigned binary (check the value of the MSB) a)If the MSB = 0, the number is positive (leave it alone) b)If the MSB = 1, the number is negative (flip the bits and add one) and precede the number with a negative sign

20 James Tam Binary subtraction through 2’s complements e.g. 01000 2 - 00010 2 Step 1A: flip bits 01000 2 11101 2 Step 2: Add no’s 01000 2 11110 2 00110 2 1 Step 3: Check for overflow Step 1B: add 1 01000 2 11110 2

21 James Tam Binary subtraction through 2’s complements e.g. 01000 2 - 00010 2 Step 1A: flip bits 01000 2 11101 2 Step 2: Add no’s 01000 2 11110 2 00110 2 Step 1B: add 1 01000 2 11110 2 1

22 James Tam Binary subtraction through 2’s complements e.g. 01000 2 - 00010 2 Step 1A: flip bits 01000 2 11101 2 Step 2: Add no’s 01000 2 11110 2 00110 2 Step 4: Check MSB Step 1B: add 1 01000 2 11110 2 Step 3: Discard it

23 James Tam Binary subtraction through 2’s complements e.g. 01000 2 - 00010 2 Step 1A: flip bits 01000 2 11101 2 Step 2: Add no’s 01000 2 11110 2 00110 2 Step 1B: add 1 01000 2 11110 2 Step 4: Leave it alone

24 James Tam Representing Real Numbers Via Floating Point Numbers are represented through a sign bit, a base and an exponent Examples with 5 digits used to represent the mantissa: e.g. One: 123.45 is represented as 12345 * 10 -2 e.g. Two: 0.12 is represented as 12000 * 10 -5 e.g. Three: 123456 is represented as 12345 * 10 1 Sign Mantissa (base) Exponent Floating point numbers may result in a loss of accuracy!

25 James Tam Summary How negative numbers are represented using 1’s and 2’s complements How to convert unsigned values to values into their 1’s or 2’s complement equivalent What is meant by overflow How to perform binary subtractions via the negate and add technique. How are real numbers represented through floating point representations

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