mirror of
https://github.com/saitohirga/WSJT-X.git
synced 2024-11-18 01:52:05 -05:00
247 lines
11 KiB
Plaintext
247 lines
11 KiB
Plaintext
|
[section:lanczos The Lanczos Approximation]
|
||
|
|
||
|
[h4 Motivation]
|
||
|
|
||
|
['Why base gamma and gamma-like functions on the Lanczos approximation?]
|
||
|
|
||
|
First of all I should make clear that for the gamma function
|
||
|
over real numbers (as opposed to complex ones)
|
||
|
the Lanczos approximation (See [@http://en.wikipedia.org/wiki/Lanczos_approximation Wikipedia or ]
|
||
|
[@http://mathworld.wolfram.com/LanczosApproximation.html Mathworld])
|
||
|
appears to offer no clear advantage over more traditional methods such as
|
||
|
[@http://en.wikipedia.org/wiki/Stirling_approximation Stirling's approximation].
|
||
|
__pugh carried out an extensive comparison of the various methods available
|
||
|
and discovered that they were all very similar in terms of complexity
|
||
|
and relative error. However, the Lanczos approximation does have a couple of
|
||
|
properties that make it worthy of further consideration:
|
||
|
|
||
|
* The approximation has an easy to compute truncation error that holds for
|
||
|
all /z > 0/. In practice that means we can use the same approximation for all
|
||
|
/z > 0/, and be certain that no matter how large or small /z/ is, the truncation
|
||
|
error will /at worst/ be bounded by some finite value.
|
||
|
* The approximation has a form that is particularly amenable to analytic
|
||
|
manipulation, in particular ratios of gamma or gamma-like functions
|
||
|
are particularly easy to compute without resorting to logarithms.
|
||
|
|
||
|
It is the combination of these two properties that make the approximation
|
||
|
attractive: Stirling's approximation is highly accurate for large z, and
|
||
|
has some of the same analytic properties as the Lanczos approximation, but
|
||
|
can't easily be used across the whole range of z.
|
||
|
|
||
|
As the simplest example, consider the ratio of two gamma functions: one could
|
||
|
compute the result via lgamma:
|
||
|
|
||
|
exp(lgamma(a) - lgamma(b));
|
||
|
|
||
|
However, even if lgamma is uniformly accurate to 0.5ulp, the worst case
|
||
|
relative error in the above can easily be shown to be:
|
||
|
|
||
|
Erel > a * log(a)/2 + b * log(b)/2
|
||
|
|
||
|
For small /a/ and /b/ that's not a problem, but to put the relationship another
|
||
|
way: ['each time a and b increase in magnitude by a factor of 10, at least one
|
||
|
decimal digit of precision will be lost.]
|
||
|
|
||
|
In contrast, by analytically combining like power
|
||
|
terms in a ratio of Lanczos approximation's, these errors can be virtually eliminated
|
||
|
for small /a/ and /b/, and kept under control for very large (or very small
|
||
|
for that matter) /a/ and /b/. Of course, computing large powers is itself a
|
||
|
notoriously hard problem, but even so, analytic combinations of Lanczos
|
||
|
approximations can make the difference between obtaining a valid result, or
|
||
|
simply garbage. Refer to the implementation notes for the __beta function for
|
||
|
an example of this method in practice. The incomplete
|
||
|
[link math_toolkit.sf_gamma.igamma gamma_p gamma] and
|
||
|
[link math_toolkit.sf_beta.ibeta_function beta] functions
|
||
|
use similar analytic combinations of power terms, to combine gamma and beta
|
||
|
functions divided by large powers into single (simpler) expressions.
|
||
|
|
||
|
[h4 The Approximation]
|
||
|
|
||
|
The Lanczos Approximation to the Gamma Function is given by:
|
||
|
|
||
|
[equation lanczos0]
|
||
|
|
||
|
Where S[sub g](z) is an infinite sum, that is convergent for all z > 0,
|
||
|
and /g/ is an arbitrary parameter that controls the "shape" of the
|
||
|
terms in the sum which is given by:
|
||
|
|
||
|
[equation lanczos0a]
|
||
|
|
||
|
With individual coefficients defined in closed form by:
|
||
|
|
||
|
[equation lanczos0b]
|
||
|
|
||
|
However, evaluation of the sum in that form can lead to numerical instability
|
||
|
in the computation of the ratios of rising and falling factorials (effectively
|
||
|
we're multiplying by a series of numbers very close to 1, so roundoff errors
|
||
|
can accumulate quite rapidly).
|
||
|
|
||
|
The Lanczos approximation is therefore often written in partial fraction form
|
||
|
with the leading constants absorbed by the coefficients in the sum:
|
||
|
|
||
|
[equation lanczos1]
|
||
|
|
||
|
where:
|
||
|
|
||
|
[equation lanczos2]
|
||
|
|
||
|
Again parameter /g/ is an arbitrarily chosen constant, and /N/ is an arbitrarily chosen
|
||
|
number of terms to evaluate in the "Lanczos sum" part.
|
||
|
|
||
|
[note
|
||
|
Some authors
|
||
|
choose to define the sum from k=1 to N, and hence end up with N+1 coefficients.
|
||
|
This happens to confuse both the following discussion and the code (since C++
|
||
|
deals with half open array ranges, rather than the closed range of the sum).
|
||
|
This convention is consistent with __godfrey, but not __pugh, so take care
|
||
|
when referring to the literature in this field.]
|
||
|
|
||
|
[h4 Computing the Coefficients]
|
||
|
|
||
|
The coefficients C0..CN-1 need to be computed from /N/ and /g/
|
||
|
at high precision, and then stored as part of the program.
|
||
|
Calculation of the coefficients is performed via the method of __godfrey;
|
||
|
let the constants be contained in a column vector P, then:
|
||
|
|
||
|
P = D B C F
|
||
|
|
||
|
where B is an NxN matrix:
|
||
|
|
||
|
[equation lanczos4]
|
||
|
|
||
|
D is an NxN matrix:
|
||
|
|
||
|
[equation lanczos3]
|
||
|
|
||
|
C is an NxN matrix:
|
||
|
|
||
|
[equation lanczos5]
|
||
|
|
||
|
and F is an N element column vector:
|
||
|
|
||
|
[equation lanczos6]
|
||
|
|
||
|
Note than the matrices B, D and C contain all integer terms and depend
|
||
|
only on /N/, this product should be computed first, and then multiplied
|
||
|
by /F/ as the last step.
|
||
|
|
||
|
[h4 Choosing the Right Parameters]
|
||
|
|
||
|
The trick is to choose
|
||
|
/N/ and /g/ to give the desired level of accuracy: choosing a small value for
|
||
|
/g/ leads to a strictly convergent series, but one which converges only slowly.
|
||
|
Choosing a larger value of /g/ causes the terms in the series to be large
|
||
|
and\/or divergent for about the first /g-1/ terms, and to then suddenly converge
|
||
|
with a "crunch".
|
||
|
|
||
|
__pugh has determined the optimal
|
||
|
value of /g/ for /N/ in the range /1 <= N <= 60/: unfortunately in practice choosing
|
||
|
these values leads to cancellation errors in the Lanczos sum as the largest
|
||
|
term in the (alternating) series is approximately 1000 times larger than the result.
|
||
|
These optimal values appear not to be useful in practice unless the evaluation
|
||
|
can be done with a number of guard digits /and/ the coefficients are stored
|
||
|
at higher precision than that desired in the result. These values are best
|
||
|
reserved for say, computing to float precision with double precision arithmetic.
|
||
|
|
||
|
[table Optimal choices for N and g when computing with guard digits (source: Pugh)
|
||
|
[[Significand Size] [N] [g][Max Error]]
|
||
|
[[24] [6] [5.581][9.51e-12]]
|
||
|
[[53][13][13.144565][9.2213e-23]]
|
||
|
]
|
||
|
|
||
|
The alternative described by __godfrey is to perform an exhaustive
|
||
|
search of the /N/ and /g/ parameter space to determine the optimal combination for
|
||
|
a given /p/ digit floating-point type. Repeating this work found a good
|
||
|
approximation for double precision arithmetic (close to the one __godfrey found),
|
||
|
but failed to find really
|
||
|
good approximations for 80 or 128-bit long doubles. Further it was observed
|
||
|
that the approximations obtained tended to optimised for the small values
|
||
|
of z (1 < z < 200) used to test the implementation against the factorials.
|
||
|
Computing ratios of gamma functions with large arguments were observed to
|
||
|
suffer from error resulting from the truncation of the Lancozos series.
|
||
|
|
||
|
__pugh identified all the locations where the theoretical error of the
|
||
|
approximation were at a minimum, but unfortunately has published only the largest
|
||
|
of these minima. However, he makes the observation that the minima
|
||
|
coincide closely with the location where the first neglected term (a[sub N]) in the
|
||
|
Lanczos series S[sub g](z) changes sign. These locations are quite easy to
|
||
|
locate, albeit with considerable computer time. These "sweet spots" need
|
||
|
only be computed once, tabulated, and then searched when required for an
|
||
|
approximation that delivers the required precision for some fixed precision
|
||
|
type.
|
||
|
|
||
|
Unfortunately, following this path failed to find a really good approximation
|
||
|
for 128-bit long doubles, and those found for 64 and 80-bit reals required an
|
||
|
excessive number of terms. There are two competing issues here: high precision
|
||
|
requires a large value of /g/, but avoiding cancellation errors in the evaluation
|
||
|
requires a small /g/.
|
||
|
|
||
|
At this point note that the Lanczos sum can be converted into rational form
|
||
|
(a ratio of two polynomials, obtained from the partial-fraction form using
|
||
|
polynomial arithmetic),
|
||
|
and doing so changes the coefficients so that /they are all positive/. That
|
||
|
means that the sum in rational form can be evaluated without cancellation
|
||
|
error, albeit with double the number of coefficients for a given N. Repeating
|
||
|
the search of the "sweet spots", this time evaluating the Lanczos sum in
|
||
|
rational form, and testing only those "sweet spots" whose theoretical error
|
||
|
is less than the machine epsilon for the type being tested, yielded good
|
||
|
approximations for all the types tested. The optimal values found were quite
|
||
|
close to the best cases reported by __pugh (just slightly larger /N/ and slightly
|
||
|
smaller /g/ for a given precision than __pugh reports), and even though converting
|
||
|
to rational form doubles the number of stored coefficients, it should be
|
||
|
noted that half of them are integers (and therefore require less storage space)
|
||
|
and the approximations require a smaller /N/ than would otherwise be required,
|
||
|
so fewer floating point operations may be required overall.
|
||
|
|
||
|
The following table shows the optimal values for /N/ and /g/ when computing
|
||
|
at fixed precision. These should be taken as work in progress: there are no
|
||
|
values for 106-bit significand machines (Darwin long doubles & NTL quad_float),
|
||
|
and further optimisation of the values of /g/ may be possible.
|
||
|
Errors given in the table
|
||
|
are estimates of the error due to truncation of the Lanczos infinite series
|
||
|
to /N/ terms. They are calculated from the sum of the first five neglected
|
||
|
terms - and are known to be rather pessimistic estimates - although it is noticeable
|
||
|
that the best combinations of /N/ and /g/ occurred when the estimated truncation error
|
||
|
almost exactly matches the machine epsilon for the type in question.
|
||
|
|
||
|
[table Optimum value for N and g when computing at fixed precision
|
||
|
[[Significand Size][Platform/Compiler Used][N][g][Max Truncation Error]]
|
||
|
[[24][Win32, VC++ 7.1] [6] [1.428456135094165802001953125][9.41e-007]]
|
||
|
[[53][Win32, VC++ 7.1] [13] [6.024680040776729583740234375][3.23e-016]]
|
||
|
[[64][Suse Linux 9 IA64, gcc-3.3.3] [17] [12.2252227365970611572265625][2.34e-024]]
|
||
|
[[116][HP Tru64 Unix 5.1B \/ Alpha, Compaq C++ V7.1-006] [24] [20.3209821879863739013671875][4.75e-035]]
|
||
|
]
|
||
|
|
||
|
Finally note that the Lanczos approximation can be written as follows
|
||
|
by removing a factor of exp(g) from the denominator, and then dividing
|
||
|
all the coefficients by exp(g):
|
||
|
|
||
|
[equation lanczos7]
|
||
|
|
||
|
This form is more convenient for calculating lgamma, but for the gamma
|
||
|
function the division by /e/ turns a possibly exact quality into an
|
||
|
inexact value: this reduces accuracy in the common case that
|
||
|
the input is exact, and so isn't used for the gamma function.
|
||
|
|
||
|
[h4 References]
|
||
|
|
||
|
# [#godfrey]Paul Godfrey, [@http://my.fit.edu/~gabdo/gamma.txt "A note on the computation of the convergent
|
||
|
Lanczos complex Gamma approximation"].
|
||
|
# [#pugh]Glendon Ralph Pugh,
|
||
|
[@http://bh0.physics.ubc.ca/People/matt/Doc/ThesesOthers/Phd/pugh.pdf
|
||
|
"An Analysis of the Lanczos Gamma Approximation"],
|
||
|
PhD Thesis November 2004.
|
||
|
# Viktor T. Toth,
|
||
|
[@http://www.rskey.org/gamma.htm "Calculators and the Gamma Function"].
|
||
|
# Mathworld, [@http://mathworld.wolfram.com/LanczosApproximation.html
|
||
|
The Lanczos Approximation].
|
||
|
|
||
|
[endsect][/section:lanczos The Lanczos Approximation]
|
||
|
|
||
|
[/
|
||
|
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).
|
||
|
]
|