I have seen these mentioned in the context of C and C++, but what is the difference between signed and unsigned variables?
Signed variables, such as signed integers will allow you to represent numbers both in the positive and negative ranges.
Unsigned variables, such as unsigned integers, will only allow you to represent numbers in the positive and zero.
Unsigned and signed variables of the same type (such as int
and byte
) both have the same range (range of 65,536 and 256 numbers, respectively), but unsigned can represent a larger magnitude number than the corresponding signed variable.
For example, an unsigned byte
can represent values from 0
to 255
, while signed byte
can represent 128
to 127
.
Wikipedia page on Signed number representations explains the difference in the representation at the bit level, and the Integer (computer science) page provides a table of ranges for each signed/unsigned integer type.

Positive numbers are greater than zero. Signed numbers, at least in C, may use a sign bit rather than a complement representation, so do not have the same range as unsigned due to repeated +/ zero. If you say an int is 16 bit, say the platform; most modern systems are 32 or 64 bit. – Pete Kirkham Mar 7 '09 at 10:20
While commonly referred to as a 'sign bit', the binary values we usually use do not have a true sign bit.
Most computers use two'scomplement arithmetic. Negative numbers are created by taking the one'scomplement (flip all the bits) and adding one:
5 (decimal) > 00000101 (binary)
1's complement: 11111010
add 1: 11111011 which is 'FB' in hex
This is why a signed byte holds values from 128 to +127 instead of 127 to +127:
1 0 0 0 0 0 0 0 = 128
1 0 0 0 0 0 0 1 = 127
  
1 1 1 1 1 1 1 0 = 2
1 1 1 1 1 1 1 1 = 1
0 0 0 0 0 0 0 0 = 0
0 0 0 0 0 0 0 1 = 1
0 0 0 0 0 0 1 0 = 2
  
0 1 1 1 1 1 1 0 = 126
0 1 1 1 1 1 1 1 = 127
(add 1 to 127 gives:)
1 0 0 0 0 0 0 0
which we see at the top of this chart is 128.
If we had a proper sign bit, the value range would be the same (e.g., 127 to +127) because one bit is reserved for the sign. If the mostsignificantbit is the sign bit, we'd have:
5 (decimal) > 00000101 (binary)
5 (decimal) > 10000101 (binary)
The interesting thing in this case is we have both a zero and a negative zero:
0 (decimal) > 00000000 (binary)
0 (decimal) > 10000000 (binary)
We don't have 0 with two'scomplement; what would be 0 is 128 (or to be more general, one more than the largest positive value). We do with one's complement though; all 1 bits is negative 0.
Mathematically, 0 equals 0. I vaguely remember a computer where 0 < 0, but I can't find any reference to it now.

3Thank you very much! I was really confused why it is 128 to 127 for a signed byte and not 127 to 127. This answer needs more up votes! – das Keks Apr 23 '13 at 18:34
Signed variables use one bit to flag whether they are positive or negative. Unsigned variables don't have this bit, so they can store larger numbers in the same space, but only nonnegative numbers, e.g. 0 and higher.
For more: Unsigned and Signed Integers

thank, after 2 minutes of google searching, this was my favorite answer to clarify for me – SheldonH Jun 14 '12 at 15:40

That's not exactly true. The first bit is not the sign bit in 2's complement, but it shows the sign! – Afshin Moazami Nov 16 '12 at 14:17
Unsigned variables can only be positive numbers, because they lack the ability to indicate that they are negative.
This ability is called the 'sign' or 'signing bit'.
A side effect is that without a signing bit, they have one more bit that can be used to represent the number, doubling the maximum number it can represent.
Signed variables can be 0, positive or negative.
Unsigned variables can be 0 or positive.
Unsigned variables are used sometimes because more bits can be used to represent the actual value. Giving you a larger range. Also you can ensure that a negative value won't be passed to your function for example.
unsigned is used when ur value must be positive, no negative value here, if signed for int range 32768 to +32767 if unsigned for int range 0 to 65535
Unsigned variables are variables which are internally represented without a mathematical sign (plus or minus) can store 'zero' or positive values only. Let us say the unsigned variable is n bits in size, then it can represent 2^n (2 power n) values  0 through (2^n 1). A signed variable on the other hand, 'loses' one bit for representing the sign, so it can store values from (2^(n1) 1) through (2^(n1)) including zero. Thus, a signed variable can store positive values, negative values and zero.
P.S.:
Internally, the mathematical sign may be represented in one's complement form, two's complement form or with a sign bit (eg: 0 > +, 1> )
All these methods effectively divide the range of representable values in n bits (2^n) into three parts, positive, negative and zero.
This is just my two cents worth.
I hope this helps.
This may not be the exact definition but I'll give you an example: If you were to create a random number taking it from the system time, here using the unsigned variable is beneficial as there is large scope for random numbers as signed numbers give both positive and negative numbers. As the system time can't be negative we use unsigned variable(Only positive numbers) and we have more wide range of random numbers.