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Binary Numbers Material on Data Representation can be found in Chapter 2 of Computer Architecture (Nicholas Carter) CSIT 301 (Blum)
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Can’t get away from the noise
CSIT 301 (Blum)
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Why Binary? Maximal distinction among values minimal corruption from noise. Imagine taking the same physical attribute of a circuit, e.g. a voltage lying between 0 and 5 volts, to represent a number. The overall range can be divided into any number of regions. CSIT 301 (Blum)
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Don’t sweat the small stuff
For decimal numbers, fluctuations must be less than 0.25 volts. For binary numbers, fluctuations must be less than 1.25 volts. 5 volts 0 volts Decimal Binary CSIT 301 (Blum)
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Range actually split in three
High Forbidden range Low CSIT 301 (Blum)
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It doesn’t matter …. Two of the standard voltages coming from a computer’s power supply are ideally supposed to be 5.00 volts and volts Measurements often reveal values that are slightly off – e.g volts or volts or some such value. So what, who cares. CSIT 301 (Blum)
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How to represent big integers
Use positional weighting, same as with decimal numbers 205 = 2 100 = 127 + 126 + 025 + 0 23 + 122 + 021 + 1 = = 205 CSIT 301 (Blum)
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Converting 205 to Binary 205/2 = 102 with a remainder of 1, place the 1 in the least significant digit position Repeat 102/2 = 51, remainder 0 1 1 CSIT 301 (Blum)
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Iterate 51/2 = 25, remainder 1 25/2 = 12, remainder 1
1 1 CSIT 301 (Blum)
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Iterate 6/2 = 3, remainder 0 3/2 = 1, remainder 1 1/2 = 0, remainder 1
1 1 1 CSIT 301 (Blum)
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Recap 205 1 127 + 126 + 025 + 024 + 123 + 122 + 021 + 120
CSIT 301 (Blum)
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Finite representation
Typically we just think computers do binary math. But an important distinction between binary math in the abstract and what computers do is that computers are finite. There are only so many flip-flops or logic gates in the computer. When we declare a variable, we set aside a certain number of flip-flops (bits of memory) to hold the value of the variable. And this limits the values the variable can have. CSIT 301 (Blum)
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Same number, different representation
5 using 8 bits 5 using 16 bits 5 using 32 bits CSIT 301 (Blum)
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Adding Binary Numbers Same as decimal; if the sum of digits in a given position exceeds the base (10 for decimal, 2 for binary) then there is a carry into the next higher position 1 3 9 + 5 7 4 CSIT 301 (Blum)
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Adding Binary Numbers 1 + carries 39 35 74 CSIT 301 (Blum)
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Uh oh, overflow What if you use a byte (8 bits) to represent an integer A byte may not be enough to represent the sum of two such numbers. 1 170 204 118??? CSIT 301 (Blum)
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Biggest unsigned* integers
4 bit: 1111 15 = 8 bit: 255 = 28 – 1 16 bit: 65535= 216 – 1 32 bit: = 232 – 1 Etc. *If one uses all of the bits available to represent only positive counting numbers, one is said to be working with unsigned integers. CSIT 301 (Blum)
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Bigger Numbers High-level languages often offer a hierarchy of types that differ in the number of bits used. You can represent larger numbers than allowed by the highest type in the hierarchy by using more words. You just have to keep track of the overflows to know how the lower numbers (less significant words) are affecting the larger numbers (more significant words). CSIT 301 (Blum)
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Negative numbers Negative x is the number that when added to x gives zero Ignoring overflow the two eight-bit numbers above add up to zero 1 x -x CSIT 301 (Blum)
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Two’s Complement: a two-step procedure for finding -x from x
Step 1: exchange 1’s and 0’s Step 2: add 1 (to the lowest bit only) 1 x 1 1 -x CSIT 301 (Blum)
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Sign bit With the two’s complement approach, all positive numbers start with a 0 in the left-most, most-significant bit and all negative numbers start with 1. So the first bit is called the sign bit. But note you have to work harder than just strip away the first bit. IS NOT the 8-bit version of –1 CSIT 301 (Blum)
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Add 1’s to the left to get the same negative number using more bits
-5 using 8 bits -5 using 16 bits -5 using 32 bits When the numbers represented are whole numbers (positive or negative), they are called just integers or signed. CSIT 301 (Blum)
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3-bit signed and unsigned
7 1 6 5 4 3 2 3 1 2 -1 -2 -3 -4 Think of driving a brand new car in reverse. What would happen to the odometer? CSIT 301 (Blum)
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Biggest signed integers
4 bit: 0111 7 = 8 bit: 127 = 27 – 1 16 bit: 32767= 215 – 1 32 bit: = 231 – 1 Etc. CSIT 301 (Blum)
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Most negative signed integers
4 bit: 1000 -8 = - 23 8 bit: = - 27 16 bit: = - 215 32 bit: = - 231 Etc. CSIT 301 (Blum)
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XKCD CSIT 301 (Blum)
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Some Java numerical types
CSIT 301 (Blum)
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Riddle 1 Is it 214? Or is it – 42? Or is it Ö? Or is it …?
It’s a matter of interpretation How was it declared? 1 CSIT 301 (Blum)
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Hexadecimal Numbers Even moderately sized decimal numbers end up as long strings in binary. Hexadecimal numbers (base 16) are often used because the strings are shorter and the conversion to binary is easier. There are 16 digits: 0-9 and A-F. CSIT 301 (Blum)
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Decimal Binary Hex 0 0000 0 1 0001 1 2 0010 2
3 0011 3 4 0100 4 5 0101 5 6 0110 6 7 0111 7 8 1000 8 9 1001 9 10 1010 A 11 1011 B 12 1100 C 13 1101 D 14 1110 E 15 1111 F CSIT 301 (Blum)
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Binary to Hex Break a binary string into groups of four bits (nibbles). Convert each nibble separately. 1 E C 9 CSIT 301 (Blum)
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Some Hex CSIT 301 (Blum)
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Numbers from Logic All of the numerical operations we have talked about are really just combinations of logical operations. E.g. the adding operation is just a particular combination of logic operations Possibilities for adding two bits 0+0=0 (with no carry) 0+1=1 (with no carry) 1+0=1 (with no carry) 1+1=0 (with a carry) CSIT 301 (Blum)
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Addition Truth Table INPUT OUTPUT A B Sum A XOR B Carry A AND B 1
1 CSIT 301 (Blum)
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Multiplication: Shift and add
1 + shift shift CSIT 301 (Blum)
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Fractions Similar to what we’re used to with decimal numbers 3.14159 =
3 · · · · · · 10-5 = 1 · · · · 2-2 + 1 · · · 2-5 + 1 · 2-6 ( ) CSIT 301 (Blum)
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Converting decimal to binary II
98.61 Integer part 98 / 2 = 49 remainder 0 49 / 2 = 24 remainder 1 24 / 2 = 12 remainder 0 12 / 2 = 6 remainder 0 6 / 2 = 3 remainder 0 3 / 2 = 1 remainder 1 1 / 2 = 0 remainder 1 CSIT 301 (Blum)
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Converting decimal to binary III
98.61 Fractional part 0.61 2 = 1.22 0.22 2 = 0.44 0.44 2 = 0.88 0.88 2 = 1.76 0.76 2 = 1.52 0.52 2 = 1.04 CSIT 301 (Blum)
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Another Example (Whole number part)
Integer part 123 / 2 = 61 remainder 1 61 / 2 = 30 remainder 1 30 / 2 = 15 remainder 0 15 / 2 = 7 remainder 1 7 / 2 = 3 remainder 1 3 / 2 = 1 remainder 1 1 / 2 = 0 remainder 1 CSIT 301 (Blum)
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Checking: Go to All Programs/Accessories/Calculator
PHY 201 (Blum)
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Put the calculator in Programmer view
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Enter number, put into binary mode
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Another Example (fractional part)
Fractional part 0.456 2 = 0.912 0.912 2 = 1.824 0.824 2 = 1.648 0.648 2 = 1.296 0.296 2 = 0.592 0.592 2 = 1.184 0.184 2 = 0.368 … … CSIT 301 (Blum)
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Convert to decimal mode, then
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Edit/Copy result. Switch to Scientific View. Edit/Paste
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Divide by 2 raised to the number of digits (in this case 7, including leading zero)
1 2 3 4 PHY 201 (Blum)
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Finally hit the equal sign. In most cases it will not be exact
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Other way around Multiply fraction by 2 raised to the desired number of digits in the fractional part. For example .456 27 = Throw away the fractional part and represent the whole number 58 111010 But note that we specified 7 digits and the result above uses only 6. Therefore we need to put in the leading 0 CSIT 301 (Blum)
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Fixed point If one has a set number of bits reserved for representing the whole number part and another set number of bits reserved for representing the fractional part of a number, then one is said to be using fixed point representation. The point dividing whole number from fraction has an unchanging (fixed) place in the number. CSIT 301 (Blum)
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Limits of the fixed point approach
Suppose you use 4 bits for the whole number part and 4 bits for the fractional part (ignoring sign for now). The largest number would be = The smallest, non-zero number would be = .0625 CSIT 301 (Blum)
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References Computer Architecture, Nicholas Carter
Computer Systems: Organization and Architecture, John Carpinelli CSIT 301 (Blum)
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