/usr/include/ossim/base/ossimLeastSquaresBilin.h is in libossim-dev 1.8.16-4ubuntu1.
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//
// License: See top level LICENSE.txt file.
//
// Author: Garrett Potts (gpotts@imagelinks.com
//
// Description: Source code produced by Dave Knopp
//
//*******************************************************************
// $Id: ossimLeastSquaresBilin.h 9968 2006-11-29 14:01:53Z gpotts $
#ifndef ossimLeastSquaresBilin_INCLUDE
#define ossimLeastSquaresBilin_INCLUDE
#include <ossim/base/ossimConstants.h>
#include <ossim/matrix/newmat.h>
/**
* @brief Provide 2D Least Squares Bilinear model fitting
* The math model is that of a bilinear surface of the form:
@code
z(x,y) = a + b*x + c*y + d*x*y
@endcode
* The getLSParms() method returns parameter values which are the least
* squares solution associated with the samples added via addSample(). Note
* that it is necessary to add at least four sample to obtain a solution.
*/
class OSSIMDLLEXPORT ossimLeastSquaresBilin
{
public:
ossimLeastSquaresBilin(const ossimLeastSquaresBilin &);
/**
* Instantiate as zero surface.
*/
ossimLeastSquaresBilin();
ossimLeastSquaresBilin & operator = (const ossimLeastSquaresBilin &);
/**
* Free internal storage.
*/
virtual ~ossimLeastSquaresBilin();
/**
* Will clear everything and set it up to
* for another solve. Just add points
* and call the solve method.
*/
virtual void clear();
/**
* add a single data sample.
*
* @param xx "x" coordinate of sample location.
* @param yy "y" "y" coordinate of sample location.
* @param zmea sample value measured at (xx,yy)
*/
virtual void addSample(double x, double yy, double zmea);
/**
* return LS solution parameters.
*
* @param pa set to constant coefficient.
* @param pb_x set to linear coefficient of "x"
* @param pc_y set to linear coefficient of "y"
* @param pd_xy set to cross coefficient of "x*y"
*/
virtual bool getLSParms(double& pa, double& pb_x, double& pc_y, double& pd_xy)const;
/**
* @param pa set to constant coefficient.
* @param pb_x set to linear coefficient of "x"
* @param pc_y set to linear coefficient of "y"
* @param pd_xy set to cross coefficient of "x*y"
*/
virtual void setLSParams(double pa, //constant
double pb_x, // linear coefficient of x,
double pc_y, // linear coefficient of y
double pd_xy); // coefficient of x*y
/**
* interpolate LS-fit value at location (xx,yy) - returns z(xx,yy).
*
* @param xx "x" coordinate at which to interpolate.
* @param yy "y" "y" coordinate at which to interpolate.
*
*/
virtual inline double lsFitValue(double xx, double yy) const
{
return (bl_a + bl_b*xx + bl_c*yy + bl_d*xx*yy);
}
/**
* compute least squares parameter solution - true if succesfull.
*/
bool solveLS();
private:
/**
* constant term.
*/
double bl_a;
/**
* linear-X term.
*/
double bl_b;
/**
* linear-Y term.
*/
double bl_c;
/**
* cross-XY term
*/
double bl_d;
/**
* Normal system coefficient matrix.
*/
NEWMAT::Matrix* AtA;
/**
* Normal system RHS vector
*/
NEWMAT::Matrix* Atb;
};
#endif // LeastSquaresBilinilin_INCL_
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