bin_dec_hex - How to use binary, decimal, and hexadecimal notation.
Most people use the decimal numbering system. This system uses ten symbols to
represent numbers. When those ten symbols are used up, they start all over
again and increment the position to the left. The digit 0 is only shown if it
is the only symbol in the sequence, or if it is not the first one.
If this sounds cryptic to you, this is what I've just said in numbers:
0
1
2
3
4
5
6
7
8
9
10
11
12
13
and so on.
Each time the digit nine is incremented, it is reset to 0 and the position
before (to the left) is incremented (from 0 to 1). Then number 9 can be seen
as "00009" and when we should increment 9, we reset it to zero and
increment the digit just before the 9 so the number becomes "00010".
Leading zeros we don't write except if it is the only digit (number 0). And of
course, we write zeros if they occur anywhere inside or at the end of a
number:
"00010" -> " 0010" -> " 010" -> " 10", but not " 1 ".
This was pretty basic, you already knew this. Why did I tell it? Well, computers
usually do not represent numbers with 10 different digits. They only use two
different symbols, namely "0" and "1". Apply the same
rules to this set of digits and you get the binary numbering system:
0
1
10
11
100
101
110
111
1000
1001
1010
1011
1100
1101
and so on.
If you count the number of rows, you'll see that these are again 14 different
numbers. The numbers are the same and mean the same as in the first list, we
just used a different representation. This means that you have to know the
representation used, or as it is called the numbering system or base.
Normally, if we do not explicitly specify the numbering system used, we
implicitly use the decimal system. If we want to use any other numbering
system, we'll have to make that clear. There are a few widely adopted methods
to do so. One common form is to write
1010(2) which means that you wrote down
a number in its binary representation. It is the number ten. If you would
write 1010 without specifying the base, the number is interpreted as one
thousand and ten using base 10.
In books, another form is common. It uses subscripts (little characters, more or
less in between two rows). You can leave out the parentheses in that case and
write down the number in normal characters followed by a little two just
behind it.
As the numbering system used is also called the base, we talk of the number 1100
base 2, the number 12 base 10.
Within the binary system, it is common to write leading zeros. The numbers are
written down in series of four, eight or sixteen depending on the context.
We can use the binary form when talking to computers (...programming...), but
the numbers will have large representations. The number 65'535 (often in the
decimal system a ' is used to separate blocks of three digits for readability)
would be written down as
1111111111111111(2) which is 16 times the digit 1.
This is difficult and prone to errors. Therefore, we usually would use another
base, called hexadecimal. It uses 16 different symbols. First the symbols from
the decimal system are used, thereafter we continue with alphabetic
characters. We get 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, B, C, D, E and F. This
system is chosen because the hexadecimal form can be converted into the binary
system very easily (and back).
There is yet another system in use, called the octal system. This was more
common in the old days, but is not used very often anymore. As you might find
it in use sometimes, you should get used to it and we'll show it below. It's
the same story as with the other representations, but with eight different
symbols.
Binary (2)
Octal (8)
Decimal (10)
Hexadecimal (16)
(2) (8) (10) (16)
00000 0 0 0
00001 1 1 1
00010 2 2 2
00011 3 3 3
00100 4 4 4
00101 5 5 5
00110 6 6 6
00111 7 7 7
01000 10 8 8
01001 11 9 9
01010 12 10 A
01011 13 11 B
01100 14 12 C
01101 15 13 D
01110 16 14 E
01111 17 15 F
10000 20 16 10
10001 21 17 11
10010 22 18 12
10011 23 19 13
10100 24 20 14
10101 25 21 15
Most computers used nowadays are using bytes of eight bits. This means that they
store eight bits at a time. You can see why the octal system is not the most
practical for that: You'd need three digits to represent the eight bits and
this means that you'd have to use one complete digit to represent only two
bits (2+3+3=8). This is a waste. For hexadecimal digits, you need only two
digits which are used completely:
(2) (8) (10) (16)
11111111 377 255 FF
You can see why binary and hexadecimal can be converted quickly: For each
hexadecimal digit there are exactly four binary digits. Take a binary number:
take four digits from the right and make a hexadecimal digit from it (see the
table above). Repeat this until there are no more digits. And the other way
around: Take a hexadecimal number. For each digit, write down its binary
equivalent.
Computers (or rather the parsers running on them) would have a hard time
converting a number like 1234(16). Therefore hexadecimal numbers are specified
with a prefix. This prefix depends on the language you're writing in. Some of
the prefixes are "0x" for C, "$" for Pascal, "#"
for HTML. It is common to assume that if a number starts with a zero, it is
octal. It does not matter what is used as long as you know what it is. I will
use "0x" for hexadecimal, "%" for binary and "0"
for octal. The following numbers are all the same, just their representation
(base) is different: 021 0x11 17 %00010001
To do arithmetics and conversions you need to understand one more thing. It is
something you already know but perhaps you do not "see" it yet:
If you write down 1234, (no prefix, so it is decimal) you are talking about the
number one thousand, two hundred and thirty four. In sort of a formula:
1 * 1000 = 1000
2 * 100 = 200
3 * 10 = 30
4 * 1 = 4
This can also be written as:
1 * 10^3
2 * 10^2
3 * 10^1
4 * 10^0
where ^ means "to the power of".
We are using the base 10, and the positions 0,1,2 and 3. The right-most position
should NOT be multiplied with 10. The second from the right should be
multiplied one time with 10. The third from the right is multiplied with 10
two times. This continues for whatever positions are used.
It is the same in all other representations:
0x1234 will be
1 * 16^3
2 * 16^2
3 * 16^1
4 * 16^0
01234 would be
1 * 8^3
2 * 8^2
3 * 8^1
4 * 8^0
This example can not be done for binary as that system only uses two symbols.
Another example:
%1010 would be
1 * 2^3
0 * 2^2
1 * 2^1
0 * 2^0
It would have been easier to convert it to its hexadecimal form and just
translate %1010 into 0xA. After a while you get used to it. You will not need
to do any calculations anymore, but just know that 0xA means 10.
To convert a decimal number into a hexadecimal you could use the next method. It
will take some time to be able to do the estimates, but it will be easier when
you use the system more frequently. We'll look at yet another way afterwards.
First you need to know how many positions will be used in the other system. To
do so, you need to know the maximum numbers you'll be using. Well, that's not
as hard as it looks. In decimal, the maximum number that you can form with two
digits is "99". The maximum for three: "999". The next
number would need an extra position. Reverse this idea and you will see that
the number can be found by taking 10^3 (10*10*10 is 1000) minus 1 or 10^2
minus one.
This can be done for hexadecimal as well:
16^4 = 0x10000 = 65536
16^3 = 0x1000 = 4096
16^2 = 0x100 = 256
16^1 = 0x10 = 16
If a number is smaller than 65'536 it will fit in four positions. If the number
is bigger than 4'095, you must use position 4. How many times you can subtract
4'096 from the number without going below zero is the first digit you write
down. This will always be a number from 1 to 15 (0x1 to 0xF). Do the same for
the other positions.
Let's try with 41'029. It is smaller than 16^4 but bigger than 16^3-1. This
means that we have to use four positions. We can subtract 16^3 from 41'029 ten
times without going below zero. The left-most digit will therefore be
"A", so we have 0xA????. The number is reduced to 41'029 - 10*4'096
= 41'029-40'960 = 69. 69 is smaller than 16^3 but not bigger than 16^2-1. The
second digit is therefore "0" and we now have 0xA0??. 69 is smaller
than 16^2 and bigger than 16^1-1. We can subtract 16^1 (which is just plain
16) four times and write down "4" to get 0xA04?. Subtract 64 from 69
(69 - 4*16) and the last digit is 5 --> 0xA045.
The other method builds up the number from the right. Let's try 41'029 again.
Divide by 16 and do not use fractions (only whole numbers).
41'029 / 16 is 2'564 with a remainder of 5. Write down 5.
2'564 / 16 is 160 with a remainder of 4. Write the 4 before the 5.
160 / 16 is 10 with no remainder. Prepend 45 with 0.
10 / 16 is below one. End here and prepend 0xA. End up with 0xA045.
Which method to use is up to you. Use whatever works for you. I use them both
without being able to tell what method I use in each case, it just depends on
the number, I think. Fact is, some numbers will occur frequently while
programming. If the number is close to one I am familiar with, then I will use
the first method (like 32'770 which is into 32'768 + 2 and I just know that it
is 0x8000 + 0x2 = 0x8002).
For binary the same approach can be used. The base is 2 and not 16, and the
number of positions will grow rapidly. Using the second method has the
advantage that you can see very easily if you should write down a zero or a
one: if you divide by two the remainder will be zero if it is an even number
and one if it is an odd number:
41029 / 2 = 20514 remainder 1
20514 / 2 = 10257 remainder 0
10257 / 2 = 5128 remainder 1
5128 / 2 = 2564 remainder 0
2564 / 2 = 1282 remainder 0
1282 / 2 = 641 remainder 0
641 / 2 = 320 remainder 1
320 / 2 = 160 remainder 0
160 / 2 = 80 remainder 0
80 / 2 = 40 remainder 0
40 / 2 = 20 remainder 0
20 / 2 = 10 remainder 0
10 / 2 = 5 remainder 0
5 / 2 = 2 remainder 1
2 / 2 = 1 remainder 0
1 / 2 below 0 remainder 1
Write down the results from right to left: %1010000001000101
Group by four:
%1010000001000101
%101000000100 0101
%10100000 0100 0101
%1010 0000 0100 0101
Convert into hexadecimal: 0xA045
Group %1010000001000101 by three and convert into octal:
%1010000001000101
%1010000001000 101
%1010000001 000 101
%1010000 001 000 101
%1010 000 001 000 101
%1 010 000 001 000 101
%001 010 000 001 000 101
1 2 0 1 0 5 --> 0120105
So: %1010000001000101 = 0120105 = 0xA045 = 41029
Or: 1010000001000101(2) = 120105(8) = A045(16) = 41029(10)
Or: 1010000001000101(2) = 120105(8) = A045(16) = 41029
At first while adding numbers, you'll convert them to their decimal form and
then back into their original form after doing the addition. If you use the
other numbering system often, you will see that you'll be able to do
arithmetics directly in the base that is used. In any representation it is the
same, add the numbers on the right, write down the right-most digit from the
result, remember the other digits and use them in the next round. Continue
with the second digit from the right and so on:
%1010 + %0111 --> 10 + 7 --> 17 --> %00010001
will become
%1010
%0111 +
||||
|||+-- add 0 + 1, result is 1, nothing to remember
||+--- add 1 + 1, result is %10, write down 0 and remember 1
|+---- add 0 + 1 + 1(remembered), result = 0, remember 1
+----- add 1 + 0 + 1(remembered), result = 0, remember 1
nothing to add, 1 remembered, result = 1
--------
%10001 is the result, I like to write it as %00010001
For low values, try to do the calculations yourself, then check them with a
calculator. The more you do the calculations yourself, the more you'll find
that you didn't make mistakes. In the end, you'll do calculi in other bases as
easily as you do them in decimal.
When the numbers get bigger, you'll have to realize that a computer is not
called a computer just to have a nice name. There are many different
calculators available, use them. For Unix you could use "bc" which
is short for Binary Calculator. It calculates not only in decimal, but in all
bases you'll ever want to use (among them Binary).
For people on Windows: Start the calculator
(start->programs->accessories->calculator) and if necessary click
view->scientific. You now have a scientific calculator and can compute in
binary or hexadecimal.
I hope you enjoyed the examples and their descriptions. If you do, help other
people by pointing them to this document when they are asking basic questions.
They will not only get their answer, but at the same time learn a whole lot
more.
Alex van den Bogaerdt <
[email protected]>