/usr/include/ossim/projection/ossimAlbersProjection.h is in libossim-dev 2.2.2-1.
This file is owned by root:root, with mode 0o644.
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// Copyright (C) 2000 ImageLinks Inc.
//
// License: See top level LICENSE.txt file.
//
// Author: Garrett Potts
//
// Description:
//
// Calls Geotrans Albers projection code.
//*******************************************************************
// $Id: ossimAlbersProjection.h 17815 2010-08-03 13:23:14Z dburken $
#ifndef ossimAlbersProjection_HEADER
#define ossimAlbersProjection_HEADER
#include <ossim/projection/ossimMapProjection.h>
//! Albers Equal Area Conic Projection
/*!
* A basic conic projection developed by H.C. Albers. Classified as a
* conic and equal area. A graphic can be found at:
* http://everest.hunter.cuny.edu/mp/pbander/albers.gif
*/
class OSSIMDLLEXPORT ossimAlbersProjection : public ossimMapProjection
{
public:
ossimAlbersProjection(const ossimEllipsoid& ellipsoid = ossimEllipsoid(),
const ossimGpt& origin = ossimGpt());
/**
* @param ellipsoid
* @param origin latitude longitude in decimal degrees.
* @param stdParallel1 First parallel in DEGREES.
* @param stdParallel2 Second parallel in DEGREES.
* @param falseEasting False easting in meters.
* @param falseNorthing False northing in meters.
*/
ossimAlbersProjection(const ossimEllipsoid& ellipsoid,
const ossimGpt& origin,
double stdParallel1,
double stdParallel2,
double falseEasting,
double falseNorthing);
ossimObject *dup()const;
virtual ossimDpt forward(const ossimGpt &worldPoint) const;
virtual ossimGpt inverse(const ossimDpt &projectedPoint)const;
virtual void update();
/*!
* The passed in Argument is in degrees and will convert it to radians
* for Geotrans. Update is then called so we can pre-compute paramters.
*/
void setStandardParallel1(double degree);
/*!
* The passed in Argument is in degrees and will convert it to radians
* for Geotrans. Update is then called so we can pre-compute paramters
*/
void setStandardParallel2(double degree);
/*!
* Will allow you to set both parallels. both are passed in degrees.
*/
void setStandardParallels(double parallel1Degree,
double prallel2Degree);
/*!
* SetFalseEasting. The value is in meters.
* Update is then called so we can pre-compute paramters
*/
void setFalseEasting(double falseEasting);
/*!
* SetFalseNorthing. The value is in meters.
* Update is then called so we can pre-compute paramters
*/
void setFalseNorthing(double falseNorthing);
/*!
* Sets both false easting and northing values. The values are
* expected to be in meters.
* Update is then called so we can pre-compute paramters
*/
void setFalseEastingNorthing(double falseEasting, double falseNorthing);
/*!
* Allows one to set all parameters for this projections. parallels are in
* degrees and easting northings are in meters.
* Update is then called so we can pre-compute paramters.
*/
void setParameters(double parallel1,
double parallel2,
double falseEasting,
double falseNorthing);
/** @returns the first standard parallel in decimal degrees. */
virtual double getStandardParallel1() const;
/** @returns the second standard parallel in decimal degrees. */
virtual double getStandardParallel2() const;
void setDefaults();
/*!
* Method to save the state of an object to a keyword list.
* Return true if ok or false on error.
*/
virtual bool saveState(ossimKeywordlist& kwl,
const char* prefix=0)const;
/*!
* Method to the load (recreate) the state of an object from a keyword
* list. Return true if ok or false on error.
*/
virtual bool loadState(const ossimKeywordlist& kwl,
const char* prefix=0);
//! Returns TRUE if principal parameters are within epsilon tolerance.
virtual bool operator==(const ossimProjection& projection) const;
protected:
virtual ~ossimAlbersProjection();
//________________________GEOTRANS__________________________
//
mutable double Albers_a; /* Semi-major axis of ellipsoid in meters */
mutable double Albers_f; /* Flattening of ellipsoid */
mutable double es; /* Eccentricity of ellipsoid */
mutable double es2; /* Eccentricity squared */
mutable double C; /* constant c */
mutable double rho0; /* height above ellipsoid */
mutable double n; /* ratio between meridians */
mutable double Albers_a_OVER_n; /* Albers_a / n */
mutable double one_MINUS_es2; /* 1 - es2 */
mutable double two_es; /* 2 * es */
/* Albers Projection Parameters */
mutable double Albers_Origin_Lat; /* Latitude of origin in radians */
mutable double Albers_Origin_Long; /* Longitude of origin in radians */
mutable double Albers_Std_Parallel_1;
mutable double Albers_Std_Parallel_2;
mutable double Albers_False_Easting;
mutable double Albers_False_Northing;
mutable double Albers_Delta_Northing;
mutable double Albers_Delta_Easting;
/*!
* The function Set_Albers_Parameters receives the ellipsoid parameters and
* projection parameters as inputs, and sets the corresponding state
* variables. If any errors occur, the error code(s) are returned by the function,
* otherwise ALBERS_NO_ERROR is returned.
*
* a : Semi-major axis of ellipsoid, in meters (input)
* f : Flattening of ellipsoid (input)
* Origin_Latitude : Latitude in radians at which the (input)
* point scale factor is 1.0
* Central_Meridian : Longitude in radians at the center of (input)
* the projection (central meridian)
* Std_Parallel_1 : First standard parallel (input)
* Std_Parallel_2 : Second standard parallel (input)
* False_Easting : A coordinate value in meters assigned to the
* central meridian of the projection. (input)
* False_Northing : A coordinate value in meters assigned to the
* origin latitude of the projection (input)
*/
long Set_Albers_Parameters(double a,
double f,
double Origin_Latitude,
double Central_Meridian,
double Std_Parallel_1,
double Std_Parallel_2,
double False_Easting,
double False_Northing);
/*!
* The function Get_Albers_Parameters returns the current ellipsoid
* parameters, and Albers projection parameters.
*
* a : Semi-major axis of ellipsoid, in meters (output)
* f : Flattening of ellipsoid (output)
* Origin_Latitude : Latitude in radians at which the (output)
* point scale factor is 1.0
* Central_Meridian : Longitude in radians at the center of (output)
* the projection
* Std_Parallel_1 : First standard parallel (output)
* Std_Parallel_2 : Second standard parallel (output)
* False_Easting : A coordinate value in meters assigned to the
* central meridian of the projection. (output)
* False_Northing : A coordinate value in meters assigned to the
* origin latitude of the projection (output)
*/
void Get_Albers_Parameters(double *a,
double *f,
double *Origin_Latitude,
double *Central_Meridian,
double *Std_Parallel_1,
double *Std_Parallel_2,
double *False_Easting,
double *False_Northing)const;
/*!
* The function Convert_Geodetic_To_Albers converts geodetic (latitude and
* longitude) coordinates to Albers projection (easting and northing)
* coordinates, according to the current ellipsoid and Albers projection
* parameters. If any errors occur, the error code(s) are returned by the
* function, otherwise ALBERS_NO_ERROR is returned.
*
* Latitude : Latitude (phi) in radians (input)
* Longitude : Longitude (lambda) in radians (input)
* Easting : Easting (X) in meters (output)
* Northing : Northing (Y) in meters (output)
*/
long Convert_Geodetic_To_Albers (double Latitude,
double Longitude,
double *Easting,
double *Northing)const;
/*!
* The function Convert_Albers_To_Geodetic converts Albers projection
* (easting and northing) coordinates to geodetic (latitude and longitude)
* coordinates, according to the current ellipsoid and Albers projection
* coordinates. If any errors occur, the error code(s) are returned by the
* function, otherwise ALBERS_NO_ERROR is returned.
*
* Easting : Easting (X) in meters (input)
* Northing : Northing (Y) in meters (input)
* Latitude : Latitude (phi) in radians (output)
* Longitude : Longitude (lambda) in radians (output)
*/
long Convert_Albers_To_Geodetic(double Easting,
double Northing,
double *Latitude,
double *Longitude)const;
/*
* RTTI information defined in data_types/rtti.h
*/
TYPE_DATA
};
#endif
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