I have been trying for the last three days to understand the exact differences between floating and fixed point representations. I am confused reading the material and I'm unable to decide what is right and what is wrong.

One of the problems is with the meaning of few technical terms like 'precision', 'mantissa', 'denormalised', 'underflows' etcetera.

Can anyone give the differences with examples?

The points I have been able to find out until now (and able to understand clearly) are as follows :-

Floating point -
1. Advantage Provides a very large range
2. Disadvantage Rounds off large numbers

Fixed point -
1. Advantage Numbers are represented exactly (Used when 'money' is involved)
2. Disadvantage Provide a very limited range

But I know there are a lot more differences (Advantages and disadvantages mainly) . Can anyone list them out with explanation ? :) Thanks :)

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Wikipedia should give you at least a grounding in terminology, but if you are willing to devote some time to the subject, the paper by David Goldberg should give you an excellent understanding of the concepts, limitations, and subtleties of floating-point arithmetic. You don't need to understand every proof, but if you're serious about C/C++ (or any?) programming as you mention, this stuff is vital. –  Brett Hale Mar 10 '12 at 15:26
@Hale Thanks for your help :) Basically I began exploring this topic when I stumbled upon datatypes in Oracle SQL . Also I am learning Principles of programming languages in my college . –  jsp99 Mar 10 '12 at 15:40

The technalities behind floating point take a lot of time to get used to. I will not go into detail here.

Simply stated, floating points achieve a high domain (from very small numbers close to zero to very high numbers, sometimes even higher than the number of atoms in the universe). Floating points achieve this by keeping the relative error constant. I.e. the number will start to be rounded after an fixed number of decimals (this is a simplification, but helps to understand the principle). This is very similar to the concept of "significant figures" from most natural sciences. However this means that floating point numbers are always somehow rounded. If you add a very small number to a very big number, the small number will just be truncated and the big number will stay. This happens when the small number is below the the threshold. If you add many numbers it might sometimes be necessary to sort them first and adding the small ones before the big ones. There is also the concept of numeric stability to consider, i.e. how an algorithm will drift of from the correct result due to the rounding.

Fixed point representation on the other hand will always have the same absolute error. If you store currency with 4 decimal places, you know your data will be off by a maximum of .00005 cent. If you add your data however, this error again might accumulate, but the rules for this are a lot different from the rules for floating points.

Unless you are duing heavy duty numeric work, these problems probably should not be considered. Most of the times floating point numbers and fixed point numbers work just fine, when good care is taken (i.e. never use `==` on floating point numbers or fixed point numbers. The correct way to compare them however is differnt for both). Also AFAIK floats are used more often in scientific work, because most often the scientists will have training in numerics, know how to deal with rounding and are only interested in relatively exact results. Fixed points are used in finances, where each rounding has to be accounted and stored somewhere (often the banks will just keep the rounded half microcents), so you have to have a very good controll of the absolute error to be later able to account for it.

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I understand the technicalities (the representation) atleast to some extent . Thanks for the very simple explanation :) Can you tell me the difference between having a constant order relative error and a constant order absolute error –  jsp99 Mar 10 '12 at 13:22
"Unless you are doing heavy duty numeric work" - I couldn't disagree more with this statement. That one-in-a-million case where the results blow up due to "catastrophic cancellation", that can't be easily replayed and debugged. Or sloppy numerical methods hidden in opaque / complex code libraries. Better to quantify any source of floating-point error and handle it correctly, like any other 'exceptional' condition in a program. –  Brett Hale Mar 10 '12 at 15:43
@BrettHale: Ok, I guess I should have been more carefull with such a statement. My usuall work really does not contain much floating point operations, so I am not very experienced in it (at least not much more, than what I have learned in classes). I think I should be more carefull with such statements. –  LiKao Mar 11 '12 at 1:07

Floating point numbers are good for, well, floating points, i.e. when you need to express numbers across varying scales. You sacrifice precision to gain range of scale.

On the other hand, fixed point numbers are only suitable at a fixed scale (and they'll over- or underrun if you scale them too much), but you gain precision as long as you remain within the desired scale.

In short: If you multiply a lot but don't add numbers of different scales, use floating points. If you add a lot but don't multiply, use fixed points.

(A good example of a fixed-point use case is anything relating with currency: Essentially, you can fix your unit to be cents, or one hundredth of a cent, and make all your monetary values be integers in that unit.)

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Hi kerrek :) Can u tell me EXACTLY what is meant by 'precision'.. I understand the English meaning . But in for example Oracle SQL , we define a number(precision,scale) , where precision means total number of 'digits' . Its just confusing ! –  jsp99 Mar 10 '12 at 13:06
Floating point Advantages: High precision Disadvantages: Expensive in terms of area and power (computationally intensive) Fixed point Advantages: area and power efficient Disadvantages: dynamic range and accuracy –  jsp99 Mar 10 '12 at 13:08
@Appy: Precision refers to the amount of information. For example, if you measure the length of something, you could say it's 1m long, or 1.2m or 1.2041m. All those are 'correct' to some degree, but the measurements are of increasing precision -- i.e. they contain more significant digits worth of information (at the expense of requiring more storage, and also finer instruments). Also, it's important to understand that higher precision does not mean higher accuracy: If the object is truly 1.2100m long, then 1.2m is accurate at its precision, but 1.2041m is not accurate at its precision. –  Kerrek SB Mar 10 '12 at 13:10
This is what I saw on a pdf document . Heres the link - ee.ucla.edu/~ingrid/Courses/ee201aS02/lectures/… –  jsp99 Mar 10 '12 at 13:11
Precission is refering to the amount of information given. I.e. how many figures are there. If you have n figures, the precision can be measured from that. A number with n figures after the . is suggesting it can measure correctly at this level of detail. I.e. for 1.2 it tells you that it can measure the number up to one decimal. It does not tell you anything about the next decimals, so for the promise it gives you it is correct. The number 1.2041 tells you, that it can measure up to four decimals, but it is wrong at the second decimal. I.e. it has higher precision, but it is wrong. –  LiKao Mar 10 '12 at 13:27
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