vcglib/vcg/math/shot.h

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/****************************************************************************
* VCGLib o o *
* Visual and Computer Graphics Library o o *
* _ O _ *
* Copyright(C) 2004 \/)\/ *
* Visual Computing Lab /\/| *
* ISTI - Italian National Research Council | *
* \ *
* All rights reserved. *
* *
* This program is free software; you can redistribute it and/or modify *
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* it under the terms of the GNU General Public License as published by *
* the Free Software Foundation; either version 2 of the License, or *
* (at your option) any later version. *
* *
* This program 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 General Public License (http://www.gnu.org/licenses/gpl.txt) *
* for more details. *
* *
****************************************************************************/
/****************************************************************************
History
$Log: not supported by cvs2svn $
2008-04-11 14:22:32 +02:00
Revision 1.24 2008/02/22 17:41:48 ponchio
Changed to reflect quaternion toMatrix inversion.
Revision 1.23 2007/02/06 08:54:07 corsini
fix names
2007-02-06 09:54:07 +01:00
Revision 1.22 2007/02/05 14:17:21 corsini
add extrinsic parameters accessors
2007-02-05 15:17:21 +01:00
Revision 1.21 2006/12/18 16:02:55 matteodelle
minor eroor correction on variable names
Revision 1.20 2006/12/18 09:46:39 callieri
camera+shot revamp: changed field names to something with more sense, cleaning of various functions, correction of minor bugs/incongruences, removal of the infamous reference in shot.
Revision 1.19 2006/01/22 17:01:40 cignoni
Corrected intialization of flag, must be zero.
Revision 1.18 2005/12/12 16:53:43 callieri
corrected UnProject, it's necessary also a ZDepth value to perform inverse projection
Revision 1.17 2005/12/07 10:57:52 callieri
added commodity function ProjectWorldtoViewport() to obtain directly pixel indices without calling two separate function of two different objects
Revision 1.16 2005/12/02 16:14:35 callieri
in Shot<S>::Axis changed Row3 to GetRow3 . row3 was the old method name of Matrix44
Revision 1.15 2005/12/01 01:03:37 cignoni
Removed excess ';' from end of template functions, for gcc compiling
Revision 1.14 2005/11/23 14:18:35 ganovelli
added access to similarity (just for symmetry with Camera() )
Revision 1.13 2005/11/23 11:58:52 ganovelli
Empty constructor added, untemplated class Shotf and Shotd added
usage: Shotf myShot;
corrected member access rights
Revision 1.12 2005/07/11 13:12:35 cignoni
small gcc-related compiling issues (typenames,ending cr, initialization order)
Revision 1.11 2005/01/22 11:20:20 ponchio
<...Point3.h> -> <...point3.h>
2005-01-22 12:20:20 +01:00
Revision 1.10 2005/01/05 13:26:15 ganovelli
corretto cambiamento di sistema di rif.
Revision 1.9 2004/12/15 18:45:50 tommyfranken
*** empty log message ***
Revision 1.4 2004/10/07 14:41:31 fasano
Little fix on ViewPoint() method
2004-10-07 16:41:31 +02:00
Revision 1.3 2004/10/07 14:24:53 ganovelli
added LookAt,LookToward
2004-10-07 16:24:53 +02:00
Revision 1.2 2004/10/05 19:04:25 ganovelli
version 5-10-2004 in progress
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Revision 1.1 2004/09/15 22:58:05 ganovelli
re-creation
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Revision 1.2 2004/09/06 21:41:30 ganovelli
*** empty log message ***
Revision 1.1 2004/09/03 13:01:51 ganovelli
creation
****************************************************************************/
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/** class Shot
Shot is made of two elements:
* the Instrinsics paramaters, which are stored as a Camera type (see vcg/math/camera) and that
determines how a point in the frame of the camera is projected in the 2D projection plane
* the Extrinsics parameters, which are stored in the class Shot (type ReferenceFrame)
and that describe viewpoint and view direction.
Some important notes about the usage of this class:
* The World coordinates system is assumed to be RIGHT-HANDED.
* The Shot reference frame is assumed to be RIGHT-HANDED.
* The associated Camera is assumed to point in the negative direction of the Z axis of the Shot coordinates system (reference frame).
As a consequence, the Camera coordinates system is LEFT-HANDED.
* The Extrinsics parameters are kept as a rotation matrix "rot" and a translation vector "tra"
The translation matrix "tra" corresponds to the viewpoint of the Shot while the rotation matrix
"rot" corresponds to the axis of the reference frame by row, i.e.
rot[0][0|1|2] == X axis
rot[1][0|1|2] == Y axis
rot[2][0|1|2] == Z axis
It follows that the matrix made with the upper left 3x3 equal to rot and the 4th colum equal to tra
and (0,0,0,1) in the bottom row transform a point from world coordiantes to the reference frame
of the shot.
**/
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#ifndef __VCGLIB_SHOT
#define __VCGLIB_SHOT
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#include <vcg/space/point2.h>
#include <vcg/space/point3.h>
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#include <vcg/math/similarity.h>
#include <vcg/math/camera.h>
namespace vcg{
template <class S, class RotationType = Matrix44<S> >
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class Shot {
public:
typedef Camera<S> CameraType;
typedef S ScalarType;
template <class ScalarType, class RotoType >
class ReferenceFrame {
friend class Shot<ScalarType, RotoType>;
RotoType rot; // rotation
Point3<S> tra; // viewpoint
public:
void SetIdentity(){ rot.SetIdentity(); tra = Point3<S>(0.0,0.0,0.0);}
void SetTra(const Point3<S> & tr) {tra = tr;}
void SetRot(const RotoType & rt) {rot = rt;}
Point3<ScalarType> Tra() const { return tra;}
RotoType Rot() const { return rot;}
};
Camera<S> Intrinsics; // the camera that made the shot
ReferenceFrame<S,RotationType> Extrinsics; // the position and orientation of the camera
Shot(Camera<S> c)
{
Intrinsics = c;
Extrinsics.SetIdentity();
}
Shot()
{
Extrinsics.SetIdentity();
}
/// GET the i-th axis of the coordinate system of the camera
vcg::Point3<S> Axis(const int & i)const;
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/// GET the viewdir
const vcg::Point3<S> GetViewDir()const;
/// GET the viewpoint
const vcg::Point3<S> GetViewPoint()const;
/// SET the viewpoint
void SetViewPoint(const vcg::Point3<S> & viewpoint);
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/// GET fov from focal
float GetFovFromFocal();
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/// look at (point+up)
void LookAt(const vcg::Point3<S> & point,const vcg::Point3<S> & up);
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/// look at (opengl-like)
void LookAt(const S & eye_x,const S & eye_y,const S & eye_z,
const S & at_x,const S & at_y,const S & at_z,
const S & up_x,const S & up_y,const S & up_z);
/// look towards (dir+up)
void LookTowards(const vcg::Point3<S> & z_dir,const vcg::Point3<S> & up);
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/* Sometimes the focal is given in pixels. In this case, this function can be used to convert it in millimiters
* given the CCD width (in mm). This method should be moved in vcg::Camera().
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* Equivalent focal length is obtained by setting the ccd width to 35 mm.
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*/
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void ConvertFocalToMM(S ccdwidth);
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/* Sometimes the 3D World coordinates are known up to a scale factor. This method adjust the camera/shot parameters
* to account for the re-scaling of the World. If the intrisic parameters are just reasonable values
* the cameras need only a re-positioning.
*/
void RescalingWorld(S scalefactor, bool adjustIntrinsics);
/// Given a pure roto-translation (4-by-4) modifies the reference frame accordingly.
void ApplyRigidTransformation(const Matrix44<S> & M);
/// Given a similarity transformation such that p' = s R p + T modifies the reference frame accordingly.
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void ApplySimilarity( Matrix44<S> M);
/// Given a similarity transformation such that p' = s R p + T modifies the reference frame accordingly.
void ApplySimilarity(const Similarity<S> & Sim);
/// convert a 3d point from world to camera coordinates (do not confuse with the Shot reference frame)
vcg::Point3<S> ConvertWorldToCameraCoordinates(const vcg::Point3<S> & p) const;
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/// convert a 3d point from camera (do not confuse with the Shot reference frame) to world coordinates
vcg::Point3<S> ConvertCameraToWorldCoordinates(const vcg::Point3<S> & p) const;
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/* convert a 3d point from camera (do not confuse with the Shot reference frame) to world coordinates
* it uses inverse instead of transpose for non-exactly-rigid rotation matrices (such as calculated by tsai and garcia)
*/
vcg::Point3<S> ConvertCameraToWorldCoordinates_Substitute(const vcg::Point3<S> & p) const;
/// project a 3d point from world coordinates to 2d camera viewport (the value returned is in pixels)
vcg::Point2<S> Project(const vcg::Point3<S> & p) const;
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/// inverse projection from 2d camera viewport (in pixels) to 3d world coordinates (it requires the original depth of the projected point)
vcg::Point3<S> UnProject(const vcg::Point2<S> & p, const S & d) const;
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/* inverse projection from 2d camera viewport (in pixels) to 3d world coordinates (it requires the original depth of the projected point)
* uses inverse instead of trranspose for non-exactly-rigid rotation matrices (such as calculated by tsai and garcia)
*/
vcg::Point3<S> UnProject_Substitute(const vcg::Point2<S> & p, const S & d) const;
/// returns the distance of point p from camera plane (z depth), required for unprojection operation
S Depth(const vcg::Point3<S> & p)const;
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// accessors
public:
/// Returns the (4-by-4) matrix M such that 3dpoint_in_world_coordinates = M * 3dpoint_in_local_coordinates
Matrix44<S> GetExtrinsicsToWorldMatrix() const
{
Matrix44<S> rotM;
Extrinsics.rot.ToMatrix(rotM);
return Matrix44<S>().SetTranslate(Extrinsics.tra) * rotM.transpose();
}
/// Returns the (4-by-4) matrix M such that 3dpoint_in_local_coordinates = M * 3dpoint_in_world_coordinates
Matrix44<S> GetWorldToExtrinsicsMatrix() const
{
Matrix44<S> rotM;
Extrinsics.rot.ToMatrix(rotM);
return rotM * Matrix44<S>().SetTranslate(-Extrinsics.tra) ;
}
/* multiply the current reference frame for the matrix passed
note: it is up to the caller to check the the matrix passed is a pure rototraslation
*/
void MultMatrix( vcg::Matrix44<S> m44)
{
Extrinsics.tra = m44 * Extrinsics.tra;
m44[0][3] = m44[1][3] = m44[2][3] = 0.0; //set no translation
const S k = m44.GetRow3(0).Norm(); //compute scaling (assumed uniform)
Extrinsics.rot = Extrinsics.rot * m44.transpose() * (1/k);
}
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/* multiply the current reference frame for the similarity passed
note: it is up to the caller to check the the matrix passed is a pure rototraslation
*/
void MultSimilarity( const Similarity<S> & s){ MultMatrix(s.Matrix());}
bool IsValid() const
{
return Intrinsics.PixelSizeMm[0]>0 && Intrinsics.PixelSizeMm[1]>0;
}
}; // end class definition
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template <class S, class RotationType>
const vcg::Point3<S> Shot<S,RotationType>::GetViewDir() const
{
return Extrinsics.Rot().GetRow3(2);
}
//---
/// GET the viewpoint
template <class S, class RotationType>
const vcg::Point3<S> Shot<S,RotationType>::GetViewPoint() const
{
return Extrinsics.tra;
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}
/// SET the viewpoint
template <class S, class RotationType>
void Shot<S,RotationType>::SetViewPoint(const vcg::Point3<S> & viewpoint)
{
Extrinsics.SetTra( viewpoint );
}
//---
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/// GET fov from focal
template <class S, class RotationType>
float Shot<S,RotationType>::GetFovFromFocal()
{
double viewportYMm= Intrinsics.PixelSizeMm[1]* Intrinsics.ViewportPx[1];
return 2*(vcg::math::ToDeg(atanf(viewportYMm/(2*Intrinsics.FocalMm))));
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}
//---
/// GET the i-th axis of the coordinate system of the camera
template <class S, class RotationType>
vcg::Point3<S> Shot<S,RotationType>::Axis(const int & i) const
{
vcg::Matrix44<S> m;
Extrinsics.rot.ToMatrix(m);
vcg::Point3<S> aa = m.GetRow3(i);
return aa;
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}
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/// look at (point+up)
template <class S, class RotationType>
void Shot<S,RotationType>::LookAt(const vcg::Point3<S> & z_dir,const vcg::Point3<S> & up)
{
LookTowards(z_dir-GetViewPoint(),up);
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}
/// look at (opengl-like)
template <class S, class RotationType>
void Shot<S,RotationType>::LookAt(const S & eye_x, const S & eye_y, const S & eye_z,
const S & at_x, const S & at_y, const S & at_z,
const S & up_x,const S & up_y,const S & up_z)
{
SetViewPoint(Point3<S>(eye_x,eye_y,eye_z));
LookAt(Point3<S>(at_x,at_y,at_z),Point3<S>(up_x,up_y,up_z));
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}
/// look towards
template <class S, class RotationType>
void Shot<S,RotationType>::LookTowards(const vcg::Point3<S> & z_dir,const vcg::Point3<S> & up)
{
vcg::Point3<S> x_dir = up ^-z_dir;
vcg::Point3<S> y_dir = -z_dir ^x_dir;
Matrix44<S> m;
m.SetIdentity();
*(vcg::Point3<S> *)&m[0][0] = x_dir/x_dir.Norm();
*(vcg::Point3<S> *)&m[1][0] = y_dir/y_dir.Norm();
*(vcg::Point3<S> *)&m[2][0] = -z_dir/z_dir.Norm();
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Extrinsics.rot.FromMatrix(m);
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}
//--- Space transformation methods
/// convert a 3d point from world to camera coordinates (do not confuse with the Shot reference frame)
template <class S, class RotationType>
vcg::Point3<S> Shot<S,RotationType>::ConvertWorldToCameraCoordinates(const vcg::Point3<S> & p) const
{
Matrix44<S> rotM;
Extrinsics.rot.ToMatrix(rotM);
vcg::Point3<S> cp = rotM * (p - GetViewPoint() );
cp[2]=-cp[2];
return cp;
}
/// convert a 3d point from camera coordinates (do not confuse with the Shot reference frame) to world coordinates
template <class S, class RotationType>
vcg::Point3<S> Shot<S,RotationType>::ConvertCameraToWorldCoordinates(const vcg::Point3<S> & p) const
{
Matrix44<S> rotM;
vcg::Point3<S> cp = p;
cp[2]=-cp[2];
Extrinsics.rot.ToMatrix(rotM);
cp = rotM.transpose() * cp + GetViewPoint();
return cp;
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}
/// convert a 3d point from camera to world coordinates, uses inverse instead of trranspose for non-exactly-rigid rotation matrices (such as calculated by tsai and garcia)
template <class S, class RotationType>
vcg::Point3<S> Shot<S,RotationType>::ConvertCameraToWorldCoordinates_Substitute(const vcg::Point3<S> & p) const
{
Matrix44<S> rotM;
vcg::Point3<S> cp = p;
cp[2]=-cp[2];
Extrinsics.rot.ToMatrix(rotM);
cp = Inverse(rotM) * cp + GetViewPoint();
return cp;
}
/// project a 3d point from world coordinates to 2d camera viewport (the value returned is in pixel)
template <class S, class RotationType>
vcg::Point2<S> Shot<S,RotationType>::Project(const vcg::Point3<S> & p) const
{
Point3<S> cp = ConvertWorldToCameraCoordinates(p);
Point2<S> pp = Intrinsics.Project(cp);
Point2<S> vp = Intrinsics.LocalToViewportPx(pp);
return vp;
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}
/// inverse projection from 2d camera viewport (in pixels) to 3d world coordinates (it requires the original depth of the point to unproject)
template <class S, class RotationType>
vcg::Point3<S> Shot<S,RotationType>::UnProject(const vcg::Point2<S> & p, const S & d) const
{
Point2<S> lp = Intrinsics.ViewportPxToLocal(p);
Point3<S> cp = Intrinsics.UnProject(lp,d);
Point3<S> wp = ConvertCameraToWorldCoordinates(cp);
return wp;
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}
/* inverse projection from 2d camera viewport (in pixels) to 3d world coordinates (it requires the original depth of the projected point)
* uses inverse instead of trranspose for non-exactly-rigid rotation matrices (such as calculated by tsai and garcia)
*/
template <class S, class RotationType>
vcg::Point3<S> Shot<S,RotationType>::UnProject_Substitute(const vcg::Point2<S> & p, const S & d) const
{
Point2<S> lp = Intrinsics.ViewportPxToLocal(p);
Point3<S> cp = Intrinsics.UnProject(lp,d);
Point3<S> wp = ConvertCameraToWorldCoordinates_Substitute(cp);
return wp;
}
/// returns the distance of point p from camera plane (z depth), required for unprojection operation
template <class S, class RotationType>
S Shot<S,RotationType>::Depth(const vcg::Point3<S> & p)const
{
return ConvertWorldToCameraCoordinates(p).Z();
}
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/* Sometimes the focal is given in pixels. In this case, this function can be used to convert it in millimiters
* given the CCD width (in mm). This method should be moved in vcg::Camera().
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* Equivalent focal length is obtained by setting the ccd width to 35 mm.
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*/
template <class S, class RotationType>
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void Shot<S, RotationType>::ConvertFocalToMM(S ccdwidth)
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{
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double ccd_width = ccdwidth; // ccd is assumed conventionally to be 35mm
double ccd_height = (ccd_width * Intrinsics.ViewportPx[1]) / Intrinsics.ViewportPx[0];
Intrinsics.PixelSizeMm[0] = (ccd_width / Intrinsics.ViewportPx[0]);
Intrinsics.PixelSizeMm[1] = (ccd_height / Intrinsics.ViewportPx[1]);
Intrinsics.FocalMm = (ccd_width * Intrinsics.FocalMm) / Intrinsics.ViewportPx[0]; // NOW FOCAL IS IN MM
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}
/* Sometimes the 3D World coordinates are known up to a scale factor. This method adjust the camera/shot parameters
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* to account for the re-scaling of the World. If the intrisic parameters are just reasonable values
* the cameras need only a re-positioning.
*/
template <class S, class RotationType>
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void Shot<S, RotationType>::RescalingWorld(S scalefactor, bool adjustIntrinsics)
{
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// adjust INTRINSICS (if required)
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if (adjustIntrinsics)
{
Intrinsics.FocalMm = Intrinsics.FocalMm * scalefactor;
double ccdwidth = static_cast<double>(Intrinsics.ViewportPx[0] * Intrinsics.PixelSizeMm[0]);
double ccdheight = static_cast<double>(Intrinsics.ViewportPx[1] * Intrinsics.PixelSizeMm[1]);
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Intrinsics.PixelSizeMm[0] = (ccdwidth * scalefactor) / Intrinsics.ViewportPx[0];
Intrinsics.PixelSizeMm[1] = (ccdheight * scalefactor) / Intrinsics.ViewportPx[1];
}
// adjust EXTRINSICS
// rotation remains the same (!)
// nothing to do..
// the viewpoint should be modified according to the scale factor
Extrinsics.tra *= scalefactor;
}
/// Given a pure roto-translation matrix (4-by-4) modify the reference frame accordingly.
template <class S, class RotationType>
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void Shot<S, RotationType>::ApplyRigidTransformation(const Matrix44<S> & M)
{
Matrix44<S> rotM;
Extrinsics.rot.ToMatrix(rotM);
// roto-translate the viewpoint
Extrinsics.tra = M * Extrinsics.tra;
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Matrix44<S> newRot = rotM * M.transpose();
newRot[3][0] = newRot[3][1] = newRot[3][2] = 0.0;
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Extrinsics.SetRot(newRot);
}
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/// Given a similarity transformation modifies the reference frame accordingly.
template <class S, class RotationType>
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void Shot<S, RotationType>::ApplySimilarity( Matrix44<S> M)
{
Matrix44<S> rotM;
Extrinsics.rot.ToMatrix(rotM);
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// normalize
M = M * (1/M.ElementAt(3,3));
M[3][3] = 1; // just for numeric precision
// compute scale factor
ScalarType scalefactor = 1.0 / pow(ScalarType(M.Determinant()),1/ScalarType(3.0));
// roto-translate the viewpoint
Extrinsics.tra = M * Extrinsics.tra;
vcg::Matrix44<S> M2 = M;
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M2 = M2 * scalefactor; // remove the scaling
M2[3][3] = 1.0;
M2[0][3] = M2[1][3] = M2[2][3] = 0; // remove the translation
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rotM = rotM * M2.transpose();
Extrinsics.SetRot(rotM);
}
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/// Given a similarity transformation modifies the reference frame accordingly.
template <class S, class RotationType>
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void Shot<S, RotationType>::ApplySimilarity(const Similarity<S> & Sm)
{
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Matrix44<S> rotM;
Extrinsics.rot.ToMatrix(rotM);
// similarity decomposition
vcg::Matrix44<S> R;
Sm.rot.ToMatrix(R);
vcg::Matrix44<S> T;
T.SetIdentity();
T.ElementAt(0,3) = Sm.tra[0];
T.ElementAt(1,3) = Sm.tra[1];
T.ElementAt(2,3) = Sm.tra[2];
vcg::Matrix44d S44;
S44.SetIdentity();
S44 *= Sm.sca;
S44.ElementAt(3,3) = 1.0;
vcg::Matrix44<S> M = T * R * S44;
// roto-translate the viewpoint
Extrinsics.tra = M * Extrinsics.tra;
vcg::Matrix44<S> M2 = M;
M2 = M2 * (1.0 / Sm.sca);
Extrinsics.rot = rotM * M2.transpose();
Extrinsics.rot.ElementAt(3,0) = 0;
Extrinsics.rot.ElementAt(3,1) = 0;
Extrinsics.rot.ElementAt(3,2) = 0;
Extrinsics.rot.ElementAt(3,3) = 1;
}
//--------------------------------
//--- utility definitions
typedef Shot<float> Shotf;
typedef Shot<double> Shotd;
//-----------------------
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} // end name space
#endif
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