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168 lines
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168 lines
9.1 KiB
Plaintext
[section:minimax Minimax Approximations and the Remez Algorithm]
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The directory libs/math/minimax contains a command line driven
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program for the generation of minimax approximations using the Remez
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algorithm. Both polynomial and rational approximations are supported,
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although the latter are tricky to converge: it is not uncommon for
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convergence of rational forms to fail. No such limitations are present
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for polynomial approximations which should always converge smoothly.
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It's worth stressing that developing rational approximations to functions
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is often not an easy task, and one to which many books have been devoted.
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To use this tool, you will need to have a reasonable grasp of what the Remez
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algorithm is, and the general form of the approximation you want to achieve.
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Unless you already familar with the Remez method,
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you should first read the [link math_toolkit.remez
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brief background article explaining the principles behind the
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Remez algorithm].
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The program consists of two parts:
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[variablelist
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[[main.cpp][Contains the command line parser, and all the calls to the Remez code.]]
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[[f.cpp][Contains the function to approximate.]]
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]
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Therefore to use this tool, you must modify f.cpp to return the function to
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approximate. The tools supports multiple function approximations within
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the same compiled program: each as a separate variant:
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NTL::RR f(const NTL::RR& x, int variant);
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Returns the value of the function /variant/ at point /x/. So if you
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wish you can just add the function to approximate as a new variant
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after the existing examples.
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In addition to those two files, the program needs to be linked to
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a [link math_toolkit.high_precision.use_ntl patched NTL library to compile].
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Note that the function /f/ must return the rational part of the
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approximation: for example if you are approximating a function
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/f(x)/ then it is quite common to use:
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f(x) = g(x)(Y + R(x))
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where /g(x)/ is the dominant part of /f(x)/, /Y/ is some constant, and
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/R(x)/ is the rational approximation part, usually optimised for a low
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absolute error compared to |Y|.
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In this case you would define /f/ to return ['f(x)/g(x)] and then set the
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y-offset of the approximation to /Y/ (see command line options below).
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Many other forms are possible, but in all cases the objective is to
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split /f(x)/ into a dominant part that you can evaluate easily using
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standard math functions, and a smooth and slowly changing rational approximation
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part. Refer to your favourite textbook for more examples.
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Command line options for the program are as follows:
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[variablelist
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[[variant N][Sets the current function variant to N. This allows multiple functions
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that are to be approximated to be compiled into the same executable.
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Defaults to 0.]]
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[[range a b][Sets the domain for the approximation to the range \[a,b\], defaults
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to \[0,1\].]]
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[[relative][Sets the Remez code to optimise for relative error. This is the default
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at program startup. Note that relative error can only be used
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if f(x) has no roots over the range being optimised.]]
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[[absolute][Sets the Remez code to optimise for absolute error.]]
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[[pin \[true|false\]]["Pins" the code so that the rational approximation
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passes through the origin. Obviously only set this to
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/true/ if R(0) must be zero. This is typically used when
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trying to preserve a root at \[0,0\] while also optimising
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for relative error.]]
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[[order N D][Sets the order of the approximation to /N/ in the numerator and /D/
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in the denominator. If /D/ is zero then the result will be a polynomial
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approximation. There will be N+D+2 coefficients in total, the first
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coefficient of the numerator is zero if /pin/ was set to true, and the
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first coefficient of the denominator is always one.]]
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[[working-precision N][Sets the working precision of NTL::RR to /N/ binary digits. Defaults to 250.]]
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[[target-precision N][Sets the precision of printed output to /N/ binary digits:
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set to the same number of digits as the type that will be used to
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evaluate the approximation. Defaults to 53 (for double precision).]]
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[[skew val]["Skews" the initial interpolated control points towards one
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end or the other of the range. Positive values skew the
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initial control points towards the left hand side of the
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range, and negative values towards the right hand side.
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If an approximation won't converge (a common situation)
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try adjusting the skew parameter until the first step yields
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the smallest possible error. /val/ should be in the range
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\[-100,+100\], the default is zero.]]
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[[brake val][Sets a brake on each step so that the change in the
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control points is braked by /val%/. Defaults to 50,
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try a higher value if an approximation won't converge,
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or a lower value to get speedier convergence.]]
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[[x-offset val][Sets the x-offset to /val/: the approximation will
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be generated for `f(S * (x + X)) + Y` where /X/ is the
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x-offset, /S/ is the x-scale
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and /Y/ is the y-offset. Defaults to zero. To avoid
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rounding errors, take care to specify a value that can
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be exactly represented as a floating point number.]]
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[[x-scale val][Sets the x-scale to /val/: the approximation will
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be generated for `f(S * (x + X)) + Y` where /S/ is the
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x-scale, /X/ is the x-offset
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and /Y/ is the y-offset. Defaults to one. To avoid
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rounding errors, take care to specify a value that can
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be exactly represented as a floating point number.]]
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[[y-offset val][Sets the y-offset to /val/: the approximation will
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be generated for `f(S * (x + X)) + Y` where /X/
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is the x-offset, /S/ is the x-scale
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and /Y/ is the y-offset. Defaults to zero. To avoid
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rounding errors, take care to specify a value that can
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be exactly represented as a floating point number.]]
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[[y-offset auto][Sets the y-offset to the average value of f(x)
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evaluated at the two endpoints of the range plus the midpoint
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of the range. The calculated value is deliberately truncated
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to /float/ precision (and should be stored as a /float/
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in your code). The approximation will
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be generated for `f(x + X) + Y` where /X/ is the x-offset
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and /Y/ is the y-offset. Defaults to zero.]]
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[[graph N][Prints N evaluations of f(x) at evenly spaced points over the
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range being optimised. If unspecified then /N/ defaults
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to 3. Use to check that f(x) is indeed smooth over the range
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of interest.]]
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[[step N][Performs /N/ steps, or one step if /N/ is unspecified.
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After each step prints: the peek error at the extrema of
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the error function of the approximation,
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the theoretical error term solved for on the last step,
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and the maximum relative change in the location of the
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Chebyshev control points. The approximation is converged on the
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minimax solution when the two error terms are (approximately)
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equal, and the change in the control points has decreased to
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a suitably small value.]]
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[[test \[float|double|long\]][Tests the current approximation at float,
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double, or long double precision. Useful to check for rounding
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errors in evaluating the approximation at fixed precision.
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Tests are conducted at the extrema of the error function of the
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approximation, and at the zeros of the error function.]]
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[[test \[float|double|long\] N] [Tests the current approximation at float,
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double, or long double precision. Useful to check for rounding
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errors in evaluating the approximation at fixed precision.
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Tests are conducted at N evenly spaced points over the range
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of the approximation. If none of \[float|double|long\] are specified
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then tests using NTL::RR, this can be used to obtain the error
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function of the approximation.]]
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[[rescale a b][Takes the current Chebeshev control points, and rescales them
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over a new interval \[a,b\]. Sometimes this can be used to obtain
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starting control points for an approximation that can not otherwise be
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converged.]]
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[[rotate][Moves one term from the numerator to the denominator, but keeps the
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Chebyshev control points the same. Sometimes this can be used to obtain
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starting control points for an approximation that can not otherwise be
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converged.]]
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[[info][Prints out the current approximation: the location of the zeros of the
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error function, the location of the Chebyshev control points, the
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x and y offsets, and of course the coefficients of the polynomials.]]
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]
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[endsect][/section:minimax Minimax Approximations and the Remez Algorithm]
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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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