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//# Copyright (C) 2001,2002,2004,2005
//# Associated Universities, Inc. Washington DC, USA.
//#
//# This library is free software; you can redistribute it and/or modify it
//# under the terms of the GNU Library General Public License as published by
//# the Free Software Foundation; either version 2 of the License, or (at your
//# option) any later version.
//#
//# This library is distributed in the hope that it will be useful, but WITHOUT
//# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
//# FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public
//# License for more details.
//#
//# You should have received a copy of the GNU Library General Public License
//# along with this library; if not, write to the Free Software Foundation,
//# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
//#
//# Correspondence concerning AIPS++ should be addressed as follows:
//# Internet email: aips2-request@nrao.edu.
//# Postal address: AIPS++ Project Office
//# National Radio Astronomy Observatory
//# 520 Edgemont Road
//# Charlottesville, VA 22903-2475 USA
//#
//# $Id$
#ifndef SCIMATH_GAUSSIANNDPARAM_H
#define SCIMATH_GAUSSIANNDPARAM_H
//# Includes
#include <casacore/casa/aips.h>
#include <casacore/scimath/Functionals/Function.h>
#include <casacore/casa/Arrays/Matrix.h>
#include <casacore/casa/Arrays/Vector.h>
#include <casacore/casa/BasicSL/String.h>
namespace casacore { //# NAMESPACE CASACORE - BEGIN
// <summary> A Multi-dimensional Gaussian parameter handling. </summary>
// <use visibility=local>
// <reviewed reviewer="UNKNOWN" date="before2004/08/25" tests="tGaussianND" demos="dGaussianND">
// </reviewed>
// <prerequisite>
// <li> <linkto class="FunctionParam">FunctionParam</linkto> class
// <li> <linkto class="Function">Function</linkto> class
// </prerequisite>
// <synopsis>
// A <src>GaussianND</src> is used to calculate Gaussian functions of any
// dimension. A <linkto class=Gaussian1D> Gaussian1D </linkto> class exists
// which is more appropriate for one dimensional Gaussian functions, and a
// <linkto class=Gaussian2D> Gaussian2D </linkto> class exists for two
// dimensional functions.
//
// A statistical description of the multi-dimensional Gaussian is used (see
// Kendall & Stuart "The Advanced Theory of Statistics"). A Gaussian is
// defined in terms of its height, mean (which is the location of the peak
// value), variance, (a measure of the width of the Gaussian), and
// covariance which skews the distribution with respect to the Axes.
//
// In the general description the variance and covariance are specified
// using a covariance matrix. This is defined as (for a 4 dimensional
// Gaussian):
// <srcblock>
// V = | s1*s1 r12*s1*s2 r13*s1*s3 r14*s1*s4 |
// | r12*s1*s2 s2*s2 r23*s2*s3 r24*s2*s4 |
// | r13*s1*s3 r23*s2*s3 s3*s3 r34*s3*s4 |
// | r14*s1*s4 r24*s2*s4 r34*s3*s4 s4*s4 |
// </srcblock>
// where s1 (<src>sigma1</src>) is the standard deviation of the Gaussian with
// respect to the first axis, and r12 (<src>rho12</src>) is the correlation
// between the the first and second axis. The correlation MUST be between -1
// and 1, and this class checks this as well as ensuring that the diagonal
// is positive.
//
// <note role=warning> It is possible to have symmetric matrices that are of
// the above described form (ie. symmetric with <src>-1 <= rho(ij) <=1</src>)
// that do
// not generate a Gaussian function. This is because the Matrix is NOT
// positive definite (The limits on <src>rho(ij)</src> are upper limits).
// This class
// does check that the covariance Matrix is positive definite and will throw
// an exception (AipsError) if it is not.</note>
//
// The covariance Matrix can be specified by only its upper or lower
// triangular regions (ie. with zeros in the other triangle), otherwise it
// MUST be symmetric.
//
// The Gaussian that is constructed from this covariance Matrix (V), along
// with mean (u) and height (h) is:
// <srcblock>
// f(x) = h*exp( -1/2 * (x-u) * V^(-1) * (x-u))
// </srcblock>
// where x, and u are vectors whose length is the dimensionality of the
// Gaussian and V^(-1) is the inverse of the covariance Matrix defined
// above. For a two dimensional Gaussian with zero mean this expression
// reduces to:
// <srcblock>
// f(x) = h*exp(-1/(2*(1-r12^2))*(x1^2/s1^2 - 2*r12*x1*x2/(s1*s2) + x2^2/s2^2))
// </srcblock>
//
// The amplitude of the Gaussian can be defined in two ways, either using
// the peak height (as is done in the constructors, and the setHeight
// function) or using the setFlux function. The flux in this context is the
// analytic integral of the Gaussian over all dimensions. Using the setFlux
// function does not modify the shape of the Gaussian just its height.
//
// All the parameters of the Gaussian except its dimensionality can be
// modified using the set/get functions.
//
// The parameter interface (see
// <linkto class="FunctionParam">FunctionParam</linkto> class),
// is used to provide an interface to the
// <linkto module="Fitting"> Fitting </linkto> classes.
// There are always 4 parameter sets.
// <note role=warning> Note that the actual variance/covariance
// parameters are the inverse matrix of the variance/covariance matrix given
// by the user</note>.
// The actual parameters are in order:
// <ol>
// <li> height (1 term). No assumptions on what quantity the height
// represents, and it can be negative (enumerated by <src>HEIGHT</src>)
// <li> mean (ndim terms) (enumerated by <src>CENTER</src>).
// <li> variance (ndim terms). The variance is always positive, and an
// exception (AipsError) will be thrown if you try to set a negative
// value.
// <li> covariance (ndim*(ndim-1)/2 terms) The order is (assuming ndim=5)
// v12,v13,v14,v15,v23,v24,v25,v34,v35,v45. The restrictions described
// above for the covariance (ie. -1 < r12 < +1) are enforced.
// </ol>
// </synopsis>
// <example>
// Construct a two dimensional Gaussian with mean=(0,1), variance=(.1,7) and
// height = 1;
// <srcblock>
// uInt ndim = 2;
// Float height = 1;
// Vector<Float> mean(ndim); mean(0) = 0, mean(1) = 1;
// Vector<Float> variance(ndim); variance(0) = .1, variance(1) = 7;
// GaussianND<Float> g(ndim, height, mean, variance);
// Vector<Float> x(ndim); x = 0;
// cout << "g("<< x <<") = " << g(x) <<endl; // g([0,0])=1*exp(-1/2*1/7);
// x(1)++;
// cout << "g("<< x <<") = " <<g(x) <<endl; // g([0,1])= 1
// cout << "Height: " << g.height() <<endl; // Height: 1
// cout << "Flux: " << g.flux() << endl; // Flux: 2*Pi*Sqrt(.1*7)
// cout << "Mean: " << g.mean() << endl; // Mean: [0, -1]
// cout << "Variance: " << g.variance() <<endl; // Variance: [.1, 7]
// cout << "Covariance: "<< g.covariance()<<endl;// Covariance: [.1, 0]
// // [0, 7]
// g.setFlux(1);
// cout << "g("<< x <<") = " <<g(x) <<endl; //g([0,1])=1/(2*Pi*Sqrt(.7))
// cout << "Height: " << g.height() <<endl; // Height: 1/(2*Pi*Sqrt(.7))
// cout << "Flux: " << g.flux() << endl; // Flux: 1
// cout << "Mean: " << g.mean() << endl; // Mean: [0, -1]
// cout << "Variance: " << g.variance() <<endl; // Variance: [.1, 7]
// cout << "Covariance: "<< g.covariance()<<endl;// Covariance: [.1, 0]
// // [0, 7]
// </srcblock>
// </example>
// <motivation>
// A Gaussian Functional was needed for modeling the sky with a series of
// components. It was later realised that it was too general and Gaussian2D
// was written.
// </motivation>
// <templating arg=T>
// <li> T should have standard numerical operators and exp() function. Current
// implementation only tested for real types.
// </templating>
// <todo asof="2001/08/19">
// <li> Nothing I know off, apart from possible optimization
// </todo>
template<class T> class GaussianNDParam : public Function<T>
{
public:
//# Enumerations
enum { HEIGHT=0, CENTER};
//# Constructors
// Constructs a Gaussian using the indicated height, mean, variance &
// covariance.
// ndim defaults to 2,
// mean defaults to 0,
// height to <src> Pi^(-ndim/2)</src> (the flux is unity)
// variance defaults to 1.0,
// covariance defaults to 0.0,
// <group>
GaussianNDParam();
explicit GaussianNDParam(uInt ndim);
GaussianNDParam(uInt ndim, const T &height);
GaussianNDParam(uInt ndim, const T &height, const Vector<T> &mean);
GaussianNDParam(uInt ndim, const T &height, const Vector<T> &mean,
const Vector<T> &variance);
GaussianNDParam(uInt ndim, const T &height, const Vector<T> &mean,
const Matrix<T> &covar);
// </group>
// Copy constructor (deep copy)
// <group>
GaussianNDParam(const GaussianNDParam &other);
template <class W>
GaussianNDParam(const GaussianNDParam<W> &other) :
Function<T>(other),
itsDim(other.itsDim), itsFlux2Hgt(other.itsFlux2Hgt) {}
// </group>
// Copy assignment (deep copy)
GaussianNDParam<T> &operator=(const GaussianNDParam<T> &other);
// Destructor
virtual ~GaussianNDParam();
//# Operators
//# Member functions
// Give name of function
virtual const String &name() const { static String x("gaussiannd");
return x; }
// Variable dimensionality
virtual uInt ndim() const { return itsDim; }
// Get or set the peak height of the Gaussian
// <group>
T height() const { return param_p[HEIGHT]; }
void setHeight(const T &height) { param_p[HEIGHT] = height; }
// </group>
// The analytical integrated area underneath the Gaussian. Use these
// functions as an alternative to the height functions.
// <group>
T flux() const;
void setFlux(const T &flux);
// </group>
// The center ordinate of the Gaussian
// <group>
Vector<T> mean() const;
void setMean(const Vector<T> &mean);
// </group>
// The FWHM of the Gaussian is <src>sqrt(8*variance*log(2))</src>.
// The variance MUST be positive
// <group>
Vector<T> variance() const;
void setVariance(const Vector<T> &variance);
// </group>
//The covariance Matrix defines the correlations between all the axes.
//<group>
Matrix<T> covariance() const;
void setCovariance(const Matrix<T> &covar);
// </group>
protected:
//# Data
// dimensionality
uInt itsDim;
// factor to convert from flux to height
T itsFlux2Hgt;
//# Methods
// Functions to convert between internal Vector of parameters
// and the Covariance
// Matrix
// <group>
void repack(Matrix<T> &covar) const;
void unpack(const Matrix<T> &covar);
// </group>
//# Make members of parent classes known.
protected:
using Function<T>::param_p;
public:
using Function<T>::nparameters;
};
} //# NAMESPACE CASACORE - END
#ifndef CASACORE_NO_AUTO_TEMPLATES
#include <casacore/scimath/Functionals/GaussianNDParam.tcc>
#endif //# CASACORE_NO_AUTO_TEMPLATES
#endif
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