You are asking how to calculate a correct result (whether one value is greater than another value) from incorrect input (some values that have errors in them). Obviously, this is impossible in general: Incorrect input produces incorrect output. However, in some specific situations, we can salvage something. The following discusses one situation.

Let’s suppose you have calculated some `a`

and `b`

that approximate the ideal values *a* and *b*, where *a* and *b* are the results you would have if the calculations were done with exact mathematics. Also suppose that we know error bounds *e*_{a} and *e*_{b} such that *a* – *e*_{a} ≤ `a`

≤ *a* + *e*_{a} and *a* – *e*_{b} ≤ `b`

≤ *b* + *e*_{b}. In other words, the calculated `a`

and `b`

lie within some intervals around *a* and *b*, respectively. (Depending on the operations performed, it is possible that errors could cause `a`

or `b`

to lie in some unconnected intervals, possibly not even containing *a* or *b*. But we will suppose you have “well behaved” errors.)

In that case, if `a`

– *e*_{a} > `b`

+ *e*_{b}, then you can be certain that *a* > *b*.

However, suppose you test for this condition and return `true`

if it holds. Then, whenever this returns `true`

, you will know that *a* > *b*. However, when it returns `false`

, you will not be sure that *a* > *b* is false. So, this test is good if you want to perform some action **only** when you are **certain** that *a* > *b*. But this causes you to miss performing the action in some cases when *a* > *b*.

Suppose you do not want to miss any of those cases. Then consider the condition `a`

+ *e*_{a} > `b`

– *e*_{b}. If *a* > *b*, then this condition must be true. So, if you test for this condition and perform the desired action when it holds, then the action will **always** be performed when *a* > *b*. However, the action may also be performed some times when it is not true that *a* > *b*.

This shows that you have choices to make. If you have errors in your calculations, sometimes your application will do the wrong thing. You must choose:

- How acceptable it is for your application to perform the action when it is false that
*a* > *b*. Is it always acceptable/unacceptable, or does it depend on how close *a* is to *b*?
- How acceptable it is for your application to not perform the action when it is true that
*a* > *b*. Is it always acceptable/unacceptable, or does it depend on how close *a* is to *b*?

If you can find some satisfactory compromise, then you set your condition to some intermediate level, and you test for the condition `a-b > e`

, for some `e`

that lies between – *e*_{a} – *e*_{b} and + *e*_{a} + *e*_{b}, inclusive. If you cannot find a satisfactory compromise, then you need to improve the calculations of `a`

and `b`

to reduce the errors, or you need to redesign your program in some way.

Note: The final test in this scenario is `a-b > e`

rather than `a > b+e`

because there may be a small rounding error calculating `b+e`

. There may also be a rounding error calculating `a-b`

, but only if `a`

and `b`

are not near each other, in which case the difference, even with rounding, is much larger than `e`

(unless your error interval is atrocious). In the cases where we care about precision, when `a`

is near `b`

, the calculation of `a-b`

is exact.

if any is needed. The same understanding will lead you to the right decision for`a>b`

. There is no general solution for`a==b`

(you can complain to whomever told you there was), and there is no general solution for`a>b`

. – Pascal Cuoq Dec 8 '12 at 10:05`if (a > b - eps)`

, which is equivalent to your second`if`

statement, you'll get some false positives. Whether those false positives are acceptable for your particular application is impossible to gauge without further information. – Mark Dickinson Dec 8 '12 at 10:44`epsilon`

may not be sufficient, since the correct choice of an epsilon depends on the relative magnitudes involved. It's definitely worth looking at these issues in depth. Goldberg's paper is a classic, and heavy on theory. There's also a good series of articles here. – Brett Hale Dec 8 '12 at 12:40