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 [section:minimax Minimax Approximations and the Remez Algorithm]

 The directory libs/math/minimax contains a command line driven
 program for the generation of minimax approximations using the Remez
 algorithm.  Both polynomial and rational approximations are supported,
 although the latter are tricky to converge: it is not uncommon for
 convergence of rational forms to fail.  No such limitations are present
 for polynomial approximations which should always converge smoothly.

 It's worth stressing that developing rational approximations to functions
 is often not an easy task, and one to which many books have been devoted.
 To use this tool, you will need to have a reasonable grasp of what the Remez
 algorithm is, and the general form of the approximation you want to achieve.

 Unless you already familar with the Remez method,
 you should first read the [link math_toolkit.backgrounders.remez
 brief background article explaining the principles behind the
 Remez algorithm].

 The program consists of two parts:

 [variablelist
 [[main.cpp][Contains the command line parser, and all the calls to the Remez code.]]
 [[f.cpp][Contains the function to approximate.]]
 ]

 Therefore to use this tool, you must modify f.cpp to return the function to
 approximate.  The tools supports multiple function approximations within
 the same compiled program: each as a separate variant:

    NTL::RR f(const NTL::RR& x, int variant);

 Returns the value of the function /variant/ at point /x/.  So if you
 wish you can just add the function to approximate as a new variant
 after the existing examples.

 In addition to those two files, the program needs to be linked to
 a [link math_toolkit.using_udt.use_ntl patched NTL library to compile].

 Note that the function /f/ must return the rational part of the
 approximation: for example if you are approximating a function
 /f(x)/ then it is quite common to use:

    f(x) = g(x)(Y + R(x))

 where /g(x)/ is the dominant part of /f(x)/, /Y/ is some constant, and
 /R(x)/ is the rational approximation part, usually optimised for a low
 absolute error compared to |Y|.

 In this case you would define /f/ to return ['f(x)/g(x)] and then set the
 y-offset of the approximation to /Y/ (see command line options below).

 Many other forms are possible, but in all cases the objective is to
 split /f(x)/ into a dominant part that you can evaluate easily using
 standard math functions, and a smooth and slowly changing rational approximation
 part.  Refer to your favourite textbook for more examples.

 Command line options for the program are as follows:

 [variablelist
 [[variant N][Sets the current function variant to N.  This allows multiple functions
              that are to be approximated to be compiled into the same executable.
              Defaults to 0.]]
 [[range a b][Sets the domain for the approximation to the range \[a,b\], defaults
              to \[0,1\].]]
 [[relative][Sets the Remez code to optimise for relative error.  This is the default
             at program startup.  Note that relative error can only be used
             if f(x) has no roots over the range being optimised.]]
 [[absolute][Sets the Remez code to optimise for absolute error.]]
 [[pin \[true|false\]]["Pins" the code so that the rational approximation
                      passes through the origin.  Obviously only set this to
                      /true/ if R(0) must be zero.  This is typically used when
                      trying to preserve a root at \[0,0\] while also optimising
                      for relative error.]]
 [[order N D][Sets the order of the approximation to /N/ in the numerator and /D/
             in the denominator.  If /D/ is zero then the result will be a polynomial
             approximation.  There will be N+D+2 coefficients in total, the first
             coefficient of the numerator is zero if /pin/ was set to true, and the
             first coefficient of the denominator is always one.]]
 [[working-precision N][Sets the working precision of NTL::RR to /N/ binary digits.  Defaults to 250.]]
 [[target-precision N][Sets the precision of printed output to /N/ binary digits:
                set to the same number of digits as the type that will be used to
                evaluate the approximation.  Defaults to 53 (for double precision).]]
 [[skew val]["Skews" the initial interpolated control points towards one
             end or the other of the range.  Positive values skew the
             initial control points towards the left hand side of the
             range, and negative values towards the right hand side.
             If an approximation won't converge (a common situation)
             try adjusting the skew parameter until the first step yields
             the smallest possible error.  /val/ should be in the range
             \[-100,+100\], the default is zero.]]
 [[brake val][Sets a brake on each step so that the change in the
             control points is braked by /val%/.  Defaults to 50,
             try a higher value if an approximation won't converge,
             or a lower value to get speedier convergence.]]
 [[x-offset val][Sets the x-offset to /val/: the approximation will
             be generated for `f(S * (x + X)) + Y` where /X/ is the
             x-offset, /S/ is the x-scale
             and /Y/ is the y-offset.  Defaults to zero.  To avoid
             rounding errors, take care to specify a value that can
             be exactly represented as a floating point number.]]
 [[x-scale val][Sets the x-scale to /val/: the approximation will
             be generated for `f(S * (x + X)) + Y` where /S/ is the
             x-scale, /X/ is the x-offset
             and /Y/ is the y-offset.  Defaults to one.  To avoid
             rounding errors, take care to specify a value that can
             be exactly represented as a floating point number.]]
 [[y-offset val][Sets the y-offset to /val/: the approximation will
             be generated for `f(S * (x + X)) + Y` where /X/
             is the x-offset, /S/ is the x-scale
             and /Y/ is the y-offset.  Defaults to zero.  To avoid
             rounding errors, take care to specify a value that can
             be exactly represented as a floating point number.]]
 [[y-offset auto][Sets the y-offset to the average value of f(x)
             evaluated at the two endpoints of the range plus the midpoint
             of the range.  The calculated value is deliberately truncated
             to /float/ precision (and should be stored as a /float/
             in your code).  The approximation will
             be generated for `f(x + X) + Y` where /X/ is the x-offset
             and /Y/ is the y-offset.  Defaults to zero.]]
 [[graph N][Prints N evaluations of f(x) at evenly spaced points over the
             range being optimised.  If unspecified then /N/ defaults
             to 3.  Use to check that f(x) is indeed smooth over the range
             of interest.]]
 [[step N][Performs /N/ steps, or one step if /N/ is unspecified.
          After each step prints: the peek error at the extrema of
          the error function of the approximation,
          the theoretical error term solved for on the last step,
          and the maximum relative change in the location of the
          Chebyshev control points.  The approximation is converged on the
          minimax solution when the two error terms are (approximately)
          equal, and the change in the control points has decreased to
          a suitably small value.]]
 [[test \[float|double|long\]][Tests the current approximation at float,
          double, or long double precision.  Useful to check for rounding
          errors in evaluating the approximation at fixed precision.
          Tests are conducted at the extrema of the error function of the
          approximation, and at the zeros of the error function.]]
 [[test \[float|double|long\] N] [Tests the current approximation at float,
          double, or long double precision.  Useful to check for rounding
          errors in evaluating the approximation at fixed precision.
          Tests are conducted at N evenly spaced points over the range
          of the approximation.  If none of \[float|double|long\] are specified
          then tests using NTL::RR, this can be used to obtain the error
          function of the approximation.]]
 [[rescale a b][Takes the current Chebeshev control points, and rescales them
          over a new interval \[a,b\].  Sometimes this can be used to obtain
          starting control points for an approximation that can not otherwise be
          converged.]]
 [[rotate][Moves one term from the numerator to the denominator, but keeps the
          Chebyshev control points the same.  Sometimes this can be used to obtain
          starting control points for an approximation that can not otherwise be
          converged.]]
 [[info][Prints out the current approximation: the location of the zeros of the
          error function, the location of the Chebyshev control points, the
          x and y offsets, and of course the coefficients of the polynomials.]]
 ]


 [endsect][/section:minimax Minimax Approximations and the Remez Algorithm]

 [/
   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).
 ]
	[section:minimax Minimax Approximations and the Remez Algorithm]

	The directory libs/math/minimax contains a command line driven
	program for the generation of minimax approximations using the Remez
	algorithm. Both polynomial and rational approximations are supported,
	although the latter are tricky to converge: it is not uncommon for
	convergence of rational forms to fail. No such limitations are present
	for polynomial approximations which should always converge smoothly.

	It's worth stressing that developing rational approximations to functions
	is often not an easy task, and one to which many books have been devoted.
	To use this tool, you will need to have a reasonable grasp of what the Remez
	algorithm is, and the general form of the approximation you want to achieve.

	Unless you already familar with the Remez method,
	you should first read the [link math_toolkit.backgrounders.remez
	brief background article explaining the principles behind the
	Remez algorithm].

	The program consists of two parts:

	[variablelist
	[[main.cpp][Contains the command line parser, and all the calls to the Remez code.]]
	[[f.cpp][Contains the function to approximate.]]
	]

	Therefore to use this tool, you must modify f.cpp to return the function to
	approximate. The tools supports multiple function approximations within
	the same compiled program: each as a separate variant:

	NTL::RR f(const NTL::RR& x, int variant);

	Returns the value of the function /variant/ at point /x/. So if you
	wish you can just add the function to approximate as a new variant
	after the existing examples.

	In addition to those two files, the program needs to be linked to
	a [link math_toolkit.using_udt.use_ntl patched NTL library to compile].

	Note that the function /f/ must return the rational part of the
	approximation: for example if you are approximating a function
	/f(x)/ then it is quite common to use:

	f(x) = g(x)(Y + R(x))

	where /g(x)/ is the dominant part of /f(x)/, /Y/ is some constant, and
	/R(x)/ is the rational approximation part, usually optimised for a low
	absolute error compared to \|Y\|.

	In this case you would define /f/ to return ['f(x)/g(x)] and then set the
	y-offset of the approximation to /Y/ (see command line options below).

	Many other forms are possible, but in all cases the objective is to
	split /f(x)/ into a dominant part that you can evaluate easily using
	standard math functions, and a smooth and slowly changing rational approximation
	part. Refer to your favourite textbook for more examples.

	Command line options for the program are as follows:

	[variablelist
	[[variant N][Sets the current function variant to N. This allows multiple functions
	that are to be approximated to be compiled into the same executable.
	Defaults to 0.]]
	[[range a b][Sets the domain for the approximation to the range \[a,b\], defaults
	to \[0,1\].]]
	[[relative][Sets the Remez code to optimise for relative error. This is the default
	at program startup. Note that relative error can only be used
	if f(x) has no roots over the range being optimised.]]
	[[absolute][Sets the Remez code to optimise for absolute error.]]
	[[pin \[true\|false\]]["Pins" the code so that the rational approximation
	passes through the origin. Obviously only set this to
	/true/ if R(0) must be zero. This is typically used when
	trying to preserve a root at \[0,0\] while also optimising
	for relative error.]]
	[[order N D][Sets the order of the approximation to /N/ in the numerator and /D/
	in the denominator. If /D/ is zero then the result will be a polynomial
	approximation. There will be N+D+2 coefficients in total, the first
	coefficient of the numerator is zero if /pin/ was set to true, and the
	first coefficient of the denominator is always one.]]
	[[working-precision N][Sets the working precision of NTL::RR to /N/ binary digits. Defaults to 250.]]
	[[target-precision N][Sets the precision of printed output to /N/ binary digits:
	set to the same number of digits as the type that will be used to
	evaluate the approximation. Defaults to 53 (for double precision).]]
	[[skew val]["Skews" the initial interpolated control points towards one
	end or the other of the range. Positive values skew the
	initial control points towards the left hand side of the
	range, and negative values towards the right hand side.
	If an approximation won't converge (a common situation)
	try adjusting the skew parameter until the first step yields
	the smallest possible error. /val/ should be in the range
	\[-100,+100\], the default is zero.]]
	[[brake val][Sets a brake on each step so that the change in the
	control points is braked by /val%/. Defaults to 50,
	try a higher value if an approximation won't converge,
	or a lower value to get speedier convergence.]]
	[[x-offset val][Sets the x-offset to /val/: the approximation will
	be generated for `f(S * (x + X)) + Y` where /X/ is the
	x-offset, /S/ is the x-scale
	and /Y/ is the y-offset. Defaults to zero. To avoid
	rounding errors, take care to specify a value that can
	be exactly represented as a floating point number.]]
	[[x-scale val][Sets the x-scale to /val/: the approximation will
	be generated for `f(S * (x + X)) + Y` where /S/ is the
	x-scale, /X/ is the x-offset
	and /Y/ is the y-offset. Defaults to one. To avoid
	rounding errors, take care to specify a value that can
	be exactly represented as a floating point number.]]
	[[y-offset val][Sets the y-offset to /val/: the approximation will
	be generated for `f(S * (x + X)) + Y` where /X/
	is the x-offset, /S/ is the x-scale
	and /Y/ is the y-offset. Defaults to zero. To avoid
	rounding errors, take care to specify a value that can
	be exactly represented as a floating point number.]]
	[[y-offset auto][Sets the y-offset to the average value of f(x)
	evaluated at the two endpoints of the range plus the midpoint
	of the range. The calculated value is deliberately truncated
	to /float/ precision (and should be stored as a /float/
	in your code). The approximation will
	be generated for `f(x + X) + Y` where /X/ is the x-offset
	and /Y/ is the y-offset. Defaults to zero.]]
	[[graph N][Prints N evaluations of f(x) at evenly spaced points over the
	range being optimised. If unspecified then /N/ defaults
	to 3. Use to check that f(x) is indeed smooth over the range
	of interest.]]
	[[step N][Performs /N/ steps, or one step if /N/ is unspecified.
	After each step prints: the peek error at the extrema of
	the error function of the approximation,
	the theoretical error term solved for on the last step,
	and the maximum relative change in the location of the
	Chebyshev control points. The approximation is converged on the
	minimax solution when the two error terms are (approximately)
	equal, and the change in the control points has decreased to
	a suitably small value.]]
	[[test \[float\|double\|long\]][Tests the current approximation at float,
	double, or long double precision. Useful to check for rounding
	errors in evaluating the approximation at fixed precision.
	Tests are conducted at the extrema of the error function of the
	approximation, and at the zeros of the error function.]]
	[[test \[float\|double\|long\] N] [Tests the current approximation at float,
	double, or long double precision. Useful to check for rounding
	errors in evaluating the approximation at fixed precision.
	Tests are conducted at N evenly spaced points over the range
	of the approximation. If none of \[float\|double\|long\] are specified
	then tests using NTL::RR, this can be used to obtain the error
	function of the approximation.]]
	[[rescale a b][Takes the current Chebeshev control points, and rescales them
	over a new interval \[a,b\]. Sometimes this can be used to obtain
	starting control points for an approximation that can not otherwise be
	converged.]]
	[[rotate][Moves one term from the numerator to the denominator, but keeps the
	Chebyshev control points the same. Sometimes this can be used to obtain
	starting control points for an approximation that can not otherwise be
	converged.]]
	[[info][Prints out the current approximation: the location of the zeros of the
	error function, the location of the Chebyshev control points, the
	x and y offsets, and of course the coefficients of the polynomials.]]
	]


	[endsect][/section:minimax Minimax Approximations and the Remez Algorithm]

	[/
	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).
	]