# Numerical precision in simple financial computations

I did a course at university that explained how (amongst other things) to order your mathematical execution to maximize precision and reduce the risk of rounding errors in a finite precision environment.

We are working on a financial system with your usual interest calculations and such. Can somebody please share/remind me how to structure your calculations as to minimze loss of precision?

I know that, for instance, division must be avoided. Also, when you divide, to divide the largest number first, if possible.

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Hmmmm, you're working on a financial system and propose taking advice on how to do it properly from SO ? I think you'd be better off digging out the notes you took during your university education. –  High Performance Mark Oct 19 '10 at 13:57
Yes I agree, I should do that too. –  Andre Luus Oct 19 '10 at 14:56

The cardinal rule of numerical computing is to avoid subtracting nearly equal numbers. Multiplication and division are always accurate: you lose at most one bit of precision in performing a multiply or divide. But if two numbers agree to n bits, you can lose up to n bits of precision in their subtraction.

There are all kinds of tricks for avoiding such subtractions. For example, suppose you need to calculate exp(x) - 1 for small values of x. (This is something you might do in an interest calculation.) If x is so small that exp(x) equals 1 to all the precision of the computer, then the subtraction will give exactly 0, and the resulting relative error will be 100%. But if you use the Taylor approximation exp(x) - 1 = x + x^2/2 + ... you could get a more accurate answer. For example, exp(10^-17) - 1 will be completely inaccurate, but 10^-17, the one-term Taylor approximation, would be very accurate. This is how functions like `expm1` work. See the explanation of `log1p` and `expm1` here.

If you're concerned about numerical accuracy, you need to understand the anatomy of floating point numbers in order to know what is safe and what is not.

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When subtracting, if one number is very large and the other is small, the result will be the same large number unaltered; and that repeated many times can yield to a significant drift too. –  fortran Oct 19 '10 at 14:13
Aha! I now remember the Taylor approximation used in this context. You are making exactly the kinds of arguments I was looking for. You don't have any online sources that I can continue reading up on? I'll check your blog soon. –  Andre Luus Oct 19 '10 at 14:54
Besides the links in my answer, you might want to look at johndcook.com/blog/2010/07/27/sine-approximation-for-small-x. It's specifically about sine functions, but more generally it's about Taylor approximations, relative error, etc. –  John D. Cook Oct 19 '10 at 15:02

Use amounts in cents, not dollars.

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Loss of precision is usually related to the use of floating point binary representations. A financial system should not use such representations and use arbitrary precision numbers instead (Such as BigDecimal in Java and decimal in .NET). That should be your first move.

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Yes, we're already working with decimals. –  Andre Luus Oct 19 '10 at 14:57

There is also the possibility to employ Interval Arithmetic

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