Decimal to binary number conversion

What is the binary form of -10? How it is calculated?

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Please retag this as homework if appropriate. I'd do it but Neil butterworth will call my mom. –  David Lively Jan 29 '10 at 5:20
-10 is binary (equals -2 in decimal). "-" is not restricted to just decimal numbers. ;) –  mbeckish Jan 29 '10 at 5:35
As you might be able to tell from some of these answers, the representation depends on multiple factors, such as what the processor architecture is or which protocol or file format the number appears in. Not all platforms have the same byte ordering, and not all use two's compliment (though many do) –  Jacob Jan 29 '10 at 6:15
The question is not fully stated. There is no "the" binary form of -10, even if we ignore endian-ness (which we should, because the question, as stated, is not about how the number is stored in memory). –  Alok Singhal Jan 29 '10 at 6:40

To convert -10 (decimal) to binary:

Repeatedly divide the absolute value (|-10| = 10) of the number by 2 until you get 0 in the quotient:

``````(10 / 2 = 5 R 0)
(5  / 2 = 2 R 1)
(2  / 2 = 1 R 0)
(1  / 2 = 0 R 1) // zero is the value in the quotient so we stop dividing
``````

Place the remainders in order to obtain the binary equivalent:

``````1010
``````

For an 8-bit cell the answer is 0000 1010, 16-bit cell 0000 0000 0000 1010, and so on.

Take the one's complement by inverting the bits (we will assume an 8-bit cell holds the final value):

``````0000 1010
1111 0101 // bits are inverted
``````

Now take the 2's complement by adding 1:

`````` 1111 0101
+        1
----------
``````

What happens with a 4-bit cell?

The one's complement would be:

``````1010
0101 // inverted bits
``````

Taking the 2's complement produces:

`````` 0101
+   1
----
0110 // final answer for a 4-bit cell
``````

Since the number should be negative and the result does not indicate that (the number begins with 0 when it should begin with a 1) an overflow condition would occur.

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very detailed +1. You might want to mention Big/Little Endian too. –  Johannes Rudolph Jan 29 '10 at 5:52
@Johannes: Endianness doesn't come into picture when talking about binary representations. That's only significant when > 1 byte is stored in a computer. @Brandon: nit: it's ones' complement, not one's. –  Alok Singhal Jan 29 '10 at 6:30
@Alok: yep, see the 16 bit cell ^^ –  Johannes Rudolph Jan 29 '10 at 6:45
@Johannes: Again, that comes into the picture only when storing a number in memory. It's equivalent to saying that the number "one thousand, two hundred and thirty four" has the representations 1234 or 4321 based upon endianness. The number has only one representation, it's only when we're storing it in memory do we talk about endianness. –  Alok Singhal Jan 29 '10 at 6:57

Take the binary form of 10, invert all the bits, and add one.

```10       0000 1010
invert   1111 0101
```
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Refer to two's complement: en.wikipedia.org/wiki/Twos_complement –  Lytol Jan 29 '10 at 5:24
Assuming twos complement and no overflow. –  David Lively Jan 29 '10 at 5:25
Your answer is correct for an 8-bit cell. What about a 4-bit or 16-bit cell? –  Brandon Jan 29 '10 at 5:30
thanks for answer. yes what about 4 bit cell ? –  Dinesh Jan 29 '10 at 5:37
@Brandon: The answer is correct regardless of word size; it just so happens that 10 will overflow a signed 4-bit word. –  Ignacio Vazquez-Abrams Jan 29 '10 at 5:38

Follow this link. You can find the binary form of a negative number say `-n` by finding out the `two's complement` of `n`.

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You're assuming two's complement. There is no "the" binary form of a negative number. –  Alok Singhal Jan 29 '10 at 6:46

Your question has no "right" answer. First, you have to define the representation you want to use. Do you want to use two's complement, ones' complement, sign-magnitude, or something else? Then you have to define how many bits to use.

Let's say we are working with 5-bits wide representations.

``````+10: 0 1 0 1 0
``````

Let's look at sign-magnitude system. In this system, the most significant bit (bit 5) is `1` if a number is negative, and `0` otherwise. The rest of the bits represent the magnitude (absolute value) of the number.

So we get:

``````-10: 1 1 0 1 0 (sign-magnitude, 5 bits)
``````

Let's look at ones' complement now. Here, a negative number is represented by just changing `1`s to `0`s and vice-versa (hence the name ones' complement—you complement a number with respect to a long sequence of `1`s).

So we get:

``````-10: 1 0 1 0 1 (ones' complement, 5 bits)
``````

Finally, let's look at two's complement system. In this, we take a number in its ones' complement system, and then add `1` to it.

So we get:

``````-10: 1 0 1 0 1
1
---------
1 0 1 1 0 (two's complement, 5 bits)
---------
``````

Thus, the binary representation of a negative number depends upon the system we use, and the number of bits available to us.

Also, you might have noticed the position of the apostrophe in ones' complement and two's complement. Why is is not one's complement or twos' complement? Then answer, from Knuth:

A two's complement number is complemented with respect to a single power of 2, while a ones' complement number is complemented with respect to a long sequence of 1s. Indeed, there is also a "twos' complement notation," which has radix 3 and complementation with respect to (2...22)3

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