Provided by: pdl_2.018-1ubuntu4_amd64 bug

NAME

       PDL::Minuit -- a PDL interface to the Minuit library

DESCRIPTION

       This package implements an interface to the Minuit minimization routines (part of the CERN
       Library)

SYNOPSIS

       A basic fit with Minuit will call three functions in this package. First, a basic
       initialization is done with mn_init(). Then, the parameters are defined via the function
       mn_def_pars(), which allows setting upper and lower bounds. Then the function mn_excm()
       can be used to issue many Minuit commands, including simplex and migrad minimization
       algorithms (see Minuit manual for more details).

       See the test file minuit.t in the test (t/) directory for a basic example.

FUNCTIONS

   mninit
         Signature: (longlong a();longlong b(); longlong c())

       info not available

       mninit does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mn_abre
         Signature: (longlong l(); char* nombre; char* mode)

       info not available

       mn_abre does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mn_cierra
         Signature: (longlong l())

       info not available

       mn_cierra does not process bad values.  It will set the bad-value flag of all output
       piddles if the flag is set for any of the input piddles.

   mnparm
         Signature: (longlong a(); double b(); double c(); double d(); double e(); longlong [o] ia(); char* str)

       info not available

       mnparm does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mnexcm
         Signature: (double a(n); longlong ia(); longlong [o] ib(); char* str; SV* function; IV numelem)

       info not available

       mnexcm does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mnpout
         Signature: (longlong ia(); double [o] a(); double [o] b(); double [o] c(); double [o] d();longlong [o] ib(); SV* str)

       info not available

       mnpout does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mnstat
         Signature: (double [o] a(); double [o] b(); double [o] c(); longlong [o] ia(); longlong [o] ib(); longlong [o] ic())

       info not available

       mnstat does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mnemat
         Signature: (double [o] mat(n,n))

       info not available

       mnemat does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mnerrs
         Signature: (longlong ia(); double [o] a(); double [o] b(); double [o] c(); double [o] d())

       info not available

       mnerrs does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mncont
         Signature: (longlong ia(); longlong ib(); longlong ic(); double [o] a(n); double [o] b(n); longlong [o] id(); SV* function; IV numelem)

       info not available

       mncont does not process bad values.  It will set the bad-value flag of all output piddles
       if the flag is set for any of the input piddles.

   mn_init()
       The function mn_init() does the basic initialization of the fit. The first argument has to
       be a reference to the function to be minimized. The function to be minimized has to
       receive five arguments ($npar,$grad,$fval,$xval,$iflag). The first is the number of
       parameters currently variable. The second is the gradient of the function (which is not
       necessarily used, see the Minuit documentation). The third is the current value of the
       function. The fourth is a piddle with the values of the parameters.  The fifth is an
       integer flag, which indicates what the function is supposed to calculate. The function has
       to return the  values ($fval,$grad), the function value and the function gradient.

       There are three optional arguments to mn_init(). By default, the output of Minuit will
       come through STDOUT unless a filename $logfile is given in the Log option. Note that this
       will mercilessly erase $logfile if it already exists. Additionally, a title can be given
       to the fit by the Title option, the default is 'Minuit Fit'. If the output is written to a
       logfile, this is assigned Fortran unit number 88. If for whatever reason you want to have
       control over the unit number that Fortran associates to the logfile, you can pass the
       number through the Unit option.

       Usage:

        mn_init($function_ref,{Log=>$logfile,Title=>$title,Unit=>$unit})

       Example:

        mn_init(\&my_function);

        #same as above but outputting to a file 'log.out'.
        #title for fit is 'My fit'
        mn_init(\&my_function,
                {Log => 'log.out', Title => 'My fit'});

        sub my_function{
           # the five variables input to the function to be minimized
           # xval is a piddle containing the current values of the parameters
           my ($npar,$grad,$fval,$xval,$iflag) = @_;

           # Here is code computing the value of the function
           # and potentially also its gradient
           # ......

           # return the two variables. If no gradient is being computed
           # just return the $grad that came as input
           return ($fval, $grad);
        }

   mn_def_pars()
       The function mn_def_pars() defines the initial values of the parameters of the function to
       be minimized and the value of the initial steps around these values that the minimizer
       will use for the first variations of the parameters in the search for the minimum.  There
       are several optional arguments. One allows assigning names to these parameters which
       otherwise get names (Par_0, Par_1,....,Par_n) by default. Another two arguments can give
       lower and upper bounds for the parameters via two piddles. If the lower and upper bound
       for a given parameter are both equal to 0 then the parameter is unbound. By default these
       lower and upper bound piddles are set to  zeroes(n), where n is the number of parameters,
       i.e. the parameters are unbound by default.

       The function needs two input variables: a piddle giving the initial values of the
       parameters and another piddle giving the initial steps. An optional reference to a perl
       array with the  variable names can be passed, as well as piddles with upper and lower
       bounds for the parameters (see example below).

       It returns an integer variable which is 0 upon success.

       Usage:

        $iflag = mn_def_pars($pars, $steps,{Names => \@names,
                               Lower_bounds => $lbounds,
                               Upper_bounds => $ubounds})

       Example:

        #initial parameter values
        my $pars = pdl(2.5,3.0);

        #steps
        my $steps = pdl(0.3,0.5);

        #parameter names
        my @names = ('intercept','slope');

        #use mn_def_pars with default parameter names (Par_0,Par_1,...)
        my $iflag = mn_def_pars($pars,$steps);

        #use of mn_def_pars explicitly specify parameter names
        $iflag = mn_def_pars($pars,$steps,{Names => \@names});

        # specify lower and upper bounds for the parameters.
        # The example below leaves parameter 1 (intercept) unconstrained
        # and constrains parameter 2 (slope) to be between 0 and 100
        my $lbounds = pdl(0, 0);
        my $ubounds = pdl(0, 100);

        $iflag = mn_def_pars($pars,$steps,{Names => \@names,
                               Lower_bounds => $lbounds,
                               Upper_bounds => $ubounds}});

        #same as above because $lbounds is by default zeroes(n)
        $iflag = mn_def_pars($pars,$steps,{Names => \@names,
                               Upper_bounds => $ubounds}});

   mn_excm()
       The function mn_excm() executes a Minuit command passed as a string. The first argument is
       the command string and an optional second argument is a piddle with arguments to the
       command.  The available commands are listed in Chapter 4 of the Minuit manual (see url
       below).

       It returns an integer variable which is 0 upon success.

       Usage:

        $iflag = mn_excm($command_string, {$arglis})

       Example:

         #start a simplex minimization
         my $iflag = mn_excm('simplex');

         #same as above but specify the maximum allowed numbers of
         #function calls in the minimization
         my $arglist = pdl(1000);
         $iflag = mn_excm('simplex',$arglist);

         #start a migrad minimization
         $iflag = mn_excm('migrad')

         #set Minuit strategy in order to get the most reliable results
         $arglist = pdl(2)
         $iflag = mn_excm('set strategy',$arglist);

         # each command can be specified by a minimal string that uniquely
         # identifies it (see Chapter 4 of Minuit manual). The comannd above
         # is equivalent to:
         $iflag = mn_excm('set stra',$arglis);

   mn_pout()
       The function mn_pout() gets the current value of a parameter. It takes as input the
       parameter number and returns an array with the parameter value, the current estimate of
       its uncertainty (0 if parameter is constant), lower bound on the parameter, if any
       (otherwise 0), upper bound on the parameter, if any (otherwise 0), integer flag (which is
       equal to the parameter number if variable, zero if the parameter is constant and negative
       if parameter is not defined) and the parameter name.

       Usage:

            ($val,$err,$bnd1,$bnd2,$ivarbl,$par_name) = mn_pout($par_number);

   mn_stat()
       The function mn_stat() gets the current status of the minimization.  It returns an array
       with the best function value found so far, the estimated vertical distance remaining to
       minimum, the value of UP defining parameter uncertainties (default is 1), the number of
       currently variable parameters, the highest parameter defined and an integer flag
       indicating how good the covariance matrix is (0=not calculated at all; 1=diagonal
       approximation, not accurate; 2=full matrix, but forced positive definite; 3=full accurate
       matrix)

       Usage:

           ($fmin,$fedm,$errdef,$npari,$nparx,$istat) = mn_stat();

   mn_emat()
       The function mn_emat returns the covariance matrix as a piddle.

       Usage:

         $emat = mn_emat();

   mn_err()
       The function mn_err() returns the current existing values for the error in the fitted
       parameters. It returns an array with the positive error, the negative error, the
       "parabolic" parameter error from the error matrix and the global correlation coefficient,
       which is a number between 0 and 1 which gives the correlation between the requested
       parameter and that linear combination of all other parameters which is most strongly
       correlated with it. Unless the command 'MINOS' has been issued via the function mn_excm(),
       the first three values will be equal.

       Usage:

         ($eplus,$eminus,$eparab,$globcc) = mn_err($par_number);

   mn_contour()
       The function mn_contour() finds contours of the function being minimized with respect to
       two chosen parameters. The contour level is given by F_min + UP, where F_min is the
       minimum of the function and UP is the ERRordef specified by the user, or 1.0 by default
       (see Minuit manual). The contour calculated by this function is dynamic, in the sense that
       it represents the minimum of the function being minimized with respect to all the other
       NPAR-2 parameters (if any).

       The function takes as input the parameter numbers with respect to which the contour is to
       be determined (two) and the number of points $npt required on the contour (>4).  It
       returns an array with piddles $xpt,$ypt containing the coordinates of the contour and a
       variable $nfound indicating the number of points actually found in the contour.  If all
       goes well $nfound will be equal to $npt, but it can be negative if the input arguments are
       not valid, zero if less than four points have been found or <$npt if the program could not
       find $npt points.

       Usage:

         ($xpt,$ypt,$nfound) = mn_contour($par_number_1,$par_number_2,$npt)

SEE ALSO

       PDL

       The Minuit documentation is online at

         http://wwwasdoc.web.cern.ch/wwwasdoc/minuit/minmain.html

AUTHOR

       This file copyright (C) 2007 Andres Jordan <ajordan@eso.org>.  All rights reserved. There
       is no warranty. You are allowed to redistribute this software/documentation under certain
       conditions. For details, see the file COPYING in the PDL distribution. If this file is
       separated from the PDL distribution, the copyright notice should be included in the file.