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122 lines
4.2 KiB
Plaintext
122 lines
4.2 KiB
Plaintext
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[sect:optim Optimisation Examples}
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[h4 Poisson Distribution - Optimization and Accuracy is quite complicated.
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The general formula for calculating the CDF uses the incomplete gamma thus:
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return gamma_q(k+1, mean);
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But the case of small integral k is *very* common, so it is worth considering optimisation.
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The first obvious step is to use a finite sum of each pdf (Probability *density* function)
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for each value of k to build up the cdf (*cumulative* distribution function).
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This could be done using the pdf function for the distribution,
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for which there are two equivalent formulae:
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return exp(-mean + log(mean) * k - lgamma(k+1));
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return gamma_p_derivative(k+1, mean);
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The pdf would probably be more accurate using gamma_p_derivative.
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The reason is that the expression:
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-mean + log(mean) * k - lgamma(k+1)
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Will produce a value much smaller than the largest of the terms, so you get
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cancellation error: and then when you pass the result to exp() which
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converts the absolute error in its argument to a relative error in the
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result (explanation available if required), you effectively amplify the
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error further still.
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gamma_p_derivative is just a thin wrapper around some of the internals of
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the incomplete gamma, it does its utmost to avoid issues like this, because
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this function is responsible for virtually all of the error in the result.
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Hopefully further advances in the future might improve things even further
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(what is really needed is an 'accurate' pow(1+x) function, but that's a whole
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other story!).
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But calling pdf function makes repeated, redundant, checks on the value of mean and k,
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result += pdf(dist, i);
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so it may be faster to substitute the formula for the pdf in a summation loop
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result += exp(-mean) * pow(mean, i) / unchecked_factorial(i);
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(simplified by removing casting from RealType).
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Of course, mean is unchanged during this summation,
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so exp(mean) should only be calculated once, outside the loop.
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Optimising compilers 'might' do this, but one can easily ensure this.
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Obviously too, k must be small enough that unchecked_factorial is OK:
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34 is an obvious choice as the limit for 32-bit float.
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For larger k, the number of iterations is like to be uneconomic.
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Only experiment can determine the optimum value of k
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for any particular RealType (float, double...)
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But also note that
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The incomplete gamma already optimises this case
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(argument "a" is a small int),
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although only when the result q (1-p) would be < 0.5.
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And moreover, in the above series, each term can be calculated
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from the previous one much more efficiently:
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cdf = sum from 0 to k of C[k]
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with:
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C[0] = exp(-mean)
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C[N+1] = C[N] * mean / (N+1)
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So hopefully that's:
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{
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RealType result = exp(-mean);
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RealType term = result;
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for(int i = 1; i <= k; ++i)
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{ // cdf is sum of pdfs.
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term *= mean / i;
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result += term;
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}
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return result;
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}
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This is exactly the same finite sum as used by gamma_p/gamma_q internally.
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As explained previously it's only used when the result
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p > 0.5 or 1-p = q < 0.5.
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The slight danger when using the sum directly like this, is that if
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the mean is small and k is large then you're calculating a value ~1, so
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conceivably you might overshoot slightly. For this and other reasons in the
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case when p < 0.5 and q > 0.5 gamma_p/gamma_q use a different (infinite but
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rapidly converging) sum, so that danger isn't present since you always
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calculate the smaller of p and q.
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So... it's tempting to suggest that you just call gamma_p/gamma_q as
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required. However, there is a slight benefit for the k = 0 case because you
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avoid all the internal logic inside gamma_p/gamma_q trying to figure out
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which method to use etc.
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For the incomplete beta function, there are no simple finite sums
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available (that I know of yet anyway), so when there's a choice between a
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finite sum of the PDF and an incomplete beta call, the finite sum may indeed
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win out in that case.
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[endsect][/sect:optim Optimisation Examples}
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[/
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Copyright 2006 John Maddock and Paul A. Bristow.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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