| [section:relative_error Relative Error] |
| |
| Given an actual value /a/ and a found value /v/ the relative error can be |
| calculated from: |
| |
| [equation error2] |
| |
| However the test programs in the library use the symmetrical form: |
| |
| [equation error1] |
| |
| which measures /relative difference/ and happens to be less error |
| prone in use since we don't have to worry which value is the "true" |
| result, and which is the experimental one. It guarantees to return a value |
| at least as large as the relative error. |
| |
| Special care needs to be taken when one value is zero: we could either take the |
| absolute error in this case (but that's cheating as the absolute error is likely |
| to be very small), or we could assign a value of either 1 or infinity to the |
| relative error in this special case. In the test cases for the special functions |
| in this library, everything below a threshold is regarded as "effectively zero", |
| otherwise the relative error is assigned the value of 1 if only one of the terms |
| is zero. The threshold is currently set at `std::numeric_limits<>::min()`: |
| in other words all denormalised numbers are regarded as a zero. |
| |
| All the test programs calculate /quantized relative error/, whereas the graphs |
| in this manual are produced with the /actual error/. The difference is as |
| follows: in the test programs, the test data is rounded to the target real type |
| under test when the program is compiled, |
| so the error observed will then be a whole number of /units in the last place/ |
| either rounded up from the actual error, or rounded down (possibly to zero). |
| In contrast the /true error/ is obtained by extending |
| the precision of the calculated value, and then comparing to the actual value: |
| in this case the calculated error may be some fraction of /units in the last place/. |
| |
| Note that throughout this manual and the test programs the relative error is |
| usually quoted in units of epsilon. However, remember that /units in the last place/ |
| more accurately reflect the number of contaminated digits, and that relative |
| error can /"wobble"/ by a factor of 2 compared to /units in the last place/. |
| In other words: two implementations of the same function, whose |
| maximum relative errors differ by a factor of 2, can actually be accurate |
| to the same number of binary digits. You have been warned! |
| |
| [#zero_error][h4 The Impossibility of Zero Error] |
| |
| For many of the functions in this library, it is assumed that the error is |
| "effectively zero" if the computation can be done with a number of guard |
| digits. However it should be remembered that if the result is a |
| /transcendental number/ |
| then as a point of principle we can never be sure that the result is accurate |
| to more than 1 ulp. This is an example of /the table makers dilemma/: consider what |
| happens if the first guard digit is a one, and the remaining guard digits are all zero. |
| Do we have a tie or not? Since the only thing we can tell about a transcendental number |
| is that its digits have no particular pattern, we can never tell if we have a tie, |
| no matter how many guard digits we have. Therefore, we can never be completely sure |
| that the result has been rounded in the right direction. Of course, transcendental |
| numbers that just happen to be a tie - for however many guard digits we have - are |
| extremely rare, and get rarer the more guard digits we have, but even so.... |
| |
| Refer to the classic text |
| [@http://docs.sun.com/source/806-3568/ncg_goldberg.html What Every Computer Scientist Should Know About Floating-Point Arithmetic] |
| for more information. |
| |
| [endsect][/section:relative_error Relative Error] |
| |
| [/ |
| Copyright 2006 John Maddock and Paul A. Bristow. |
| Distributed under the Boost Software License, Version 1.0. |
| (See accompanying file LICENSE_1_0.txt or copy at |
| http://www.boost.org/LICENSE_1_0.txt). |
| ] |
