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CPosePDFGaussian.h
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1 /* +---------------------------------------------------------------------------+
2  | Mobile Robot Programming Toolkit (MRPT) |
3  | http://www.mrpt.org/ |
4  | |
5  | Copyright (c) 2005-2017, Individual contributors, see AUTHORS file |
6  | See: http://www.mrpt.org/Authors - All rights reserved. |
7  | Released under BSD License. See details in http://www.mrpt.org/License |
8  +---------------------------------------------------------------------------+ */
9 #ifndef CPosePDFGaussian_H
10 #define CPosePDFGaussian_H
11 
12 #include <mrpt/poses/CPosePDF.h>
14 
15 namespace mrpt
16 {
17 namespace poses
18 {
19  class CPose3DPDF;
20  class CPoint2DPDFGaussian;
21 
22  // This must be added to any CSerializable derived class:
23  DEFINE_SERIALIZABLE_PRE_CUSTOM_BASE( CPosePDFGaussian, CPosePDF )
24 
25  /** Declares a class that represents a Probability Density function (PDF) of a 2D pose \f$ p(\mathbf{x}) = [x ~ y ~ \phi ]^t \f$.
26  *
27  * This class implements that PDF using a mono-modal Gaussian distribution. See mrpt::poses::CPosePDF for more details.
28  *
29  * \sa CPose2D, CPosePDF, CPosePDFParticles
30  * \ingroup poses_pdf_grp
31  */
33  {
34  // This must be added to any CSerializable derived class:
36 
37  protected:
38  /** Assures the symmetry of the covariance matrix (eventually certain operations in the math-coprocessor lead to non-symmetric matrixes!)
39  */
40  void assureSymmetry();
41 
42  public:
43  /** @name Data fields
44  @{ */
45 
46  CPose2D mean; //!< The mean value
47  mrpt::math::CMatrixDouble33 cov; //!< The 3x3 covariance matrix
48 
49  /** @} */
50 
51  inline const CPose2D & getPoseMean() const { return mean; }
52  inline CPose2D & getPoseMean() { return mean; }
53 
54  /** Default constructor
55  */
57 
58  /** Constructor
59  */
60  explicit CPosePDFGaussian( const CPose2D &init_Mean );
61 
62  /** Constructor
63  */
64  CPosePDFGaussian( const CPose2D &init_Mean, const mrpt::math::CMatrixDouble33 &init_Cov );
65 
66  /** Copy constructor, including transformations between other PDFs */
67  explicit CPosePDFGaussian( const CPosePDF &o ) { copyFrom( o ); }
68 
69  /** Copy constructor, including transformations between other PDFs */
70  explicit CPosePDFGaussian( const CPose3DPDF &o ) { copyFrom( o ); }
71 
72  /** Returns an estimate of the pose, (the mean, or mathematical expectation of the PDF).
73  * \sa getCovariance
74  */
75  void getMean(CPose2D &mean_pose) const MRPT_OVERRIDE{
76  mean_pose = mean;
77  }
78 
79  /** Returns an estimate of the pose covariance matrix (3x3 cov matrix) and the mean, both at once.
80  * \sa getMean
81  */
83  mean_point = mean;
84  out_cov = this->cov;
85  }
86 
87  /** Copy operator, translating if necesary (for example, between particles and gaussian representations) */
88  void copyFrom(const CPosePDF &o) MRPT_OVERRIDE;
89 
90  /** Copy operator, translating if necesary (for example, between particles and gaussian representations) */
91  void copyFrom(const CPose3DPDF &o);
92 
93  /** Save PDF's particles to a text file, containing the 2D pose in the first line, then the covariance matrix in next 3 lines. */
94  void saveToTextFile(const std::string &file) const MRPT_OVERRIDE;
95 
96  /** this = p (+) this. This can be used to convert a PDF from local coordinates to global, providing the point (newReferenceBase) from which
97  * "to project" the current pdf. Result PDF substituted the currently stored one in the object.
98  */
99  void changeCoordinatesReference( const CPose3D &newReferenceBase ) MRPT_OVERRIDE;
100 
101  /** this = p (+) this. This can be used to convert a PDF from local coordinates to global, providing the point (newReferenceBase) from which
102  * "to project" the current pdf. Result PDF substituted the currently stored one in the object.
103  */
104  void changeCoordinatesReference( const CPose2D &newReferenceBase );
105 
106  /** Rotate the covariance matrix by replacing it by \f$ \mathbf{R}~\mathbf{COV}~\mathbf{R}^t \f$, where \f$ \mathbf{R} = \left[ \begin{array}{ccc} \cos\alpha & -\sin\alpha & 0 \\ \sin\alpha & \cos\alpha & 0 \\ 0 & 0 & 1 \end{array}\right] \f$.
107  */
108  void rotateCov(const double ang);
109 
110  /** Set \f$ this = x1 \ominus x0 \f$ , computing the mean using the "-" operator and the covariances through the corresponding Jacobians (For 'x0' and 'x1' being independent variables!). */
111  void inverseComposition( const CPosePDFGaussian &x, const CPosePDFGaussian &ref );
112 
113  /** Set \f$ this = x1 \ominus x0 \f$ , computing the mean using the "-" operator and the covariances through the corresponding Jacobians (Given the 3x3 cross-covariance matrix of variables x0 and x1). */
114  void inverseComposition(
115  const CPosePDFGaussian &x1,
116  const CPosePDFGaussian &x0,
117  const mrpt::math::CMatrixDouble33 &COV_01
118  );
119 
120  /** Draws a single sample from the distribution
121  */
122  void drawSingleSample( CPose2D &outPart ) const MRPT_OVERRIDE;
123 
124  /** Draws a number of samples from the distribution, and saves as a list of 1x3 vectors, where each row contains a (x,y,phi) datum.
125  */
126  void drawManySamples( size_t N, std::vector<mrpt::math::CVectorDouble> & outSamples ) const MRPT_OVERRIDE;
127 
128  /** Bayesian fusion of two points gauss. distributions, then save the result in this object.
129  * The process is as follows:<br>
130  * - (x1,S1): Mean and variance of the p1 distribution.
131  * - (x2,S2): Mean and variance of the p2 distribution.
132  * - (x,S): Mean and variance of the resulting distribution.
133  *
134  * S = (S1<sup>-1</sup> + S2<sup>-1</sup>)<sup>-1</sup>;
135  * x = S * ( S1<sup>-1</sup>*x1 + S2<sup>-1</sup>*x2 );
136  */
137  void bayesianFusion(const CPosePDF &p1,const CPosePDF &p2, const double &minMahalanobisDistToDrop = 0 ) MRPT_OVERRIDE;
138 
139  /** Returns a new PDF such as: NEW_PDF = (0,0,0) - THIS_PDF
140  */
141  void inverse(CPosePDF &o) const MRPT_OVERRIDE;
142 
143  /** Makes: thisPDF = thisPDF + Ap, where "+" is pose composition (both the mean, and the covariance matrix are updated). */
144  void operator += ( const CPose2D &Ap);
145 
146  /** Evaluates the PDF at a given point. */
147  double evaluatePDF( const CPose2D &x ) const;
148 
149  /** Evaluates the ratio PDF(x) / PDF(MEAN), that is, the normalized PDF in the range [0,1]. */
150  double evaluateNormalizedPDF( const CPose2D &x ) const;
151 
152  /** Computes the Mahalanobis distance between the centers of two Gaussians. */
153  double mahalanobisDistanceTo( const CPosePDFGaussian& theOther );
154 
155  /** Substitutes the diagonal elements if (square) they are below some given minimum values (Use this before bayesianFusion, for example, to avoid inversion of singular matrixes, etc...) */
156  void assureMinCovariance( const double & minStdXY, const double &minStdPhi );
157 
158  /** Makes: thisPDF = thisPDF + Ap, where "+" is pose composition (both the mean, and the covariance matrix are updated) (see formulas in jacobiansPoseComposition ). */
159  void operator += ( const CPosePDFGaussian &Ap);
160 
161  /** Makes: thisPDF = thisPDF - Ap, where "-" is pose inverse composition (both the mean, and the covariance matrix are updated) */
162  inline void operator -=( const CPosePDFGaussian &ref ) {
163  this->inverseComposition(*this,ref);
164  }
165 
166  /** Returns the PDF of the 2D point \f$ g = q \oplus l\f$ with "q"=this pose and "l" a point without uncertainty */
167  void composePoint(const mrpt::math::TPoint2D &l, CPoint2DPDFGaussian &g ) const;
168 
169 
170  }; // End of class def.
171  DEFINE_SERIALIZABLE_POST_CUSTOM_BASE( CPosePDFGaussian, CPosePDF )
172 
173 
174  /** Pose compose operator: RES = A (+) B , computing both the mean and the covariance */
175  CPosePDFGaussian BASE_IMPEXP operator +( const CPosePDFGaussian &a, const CPosePDFGaussian &b );
176 
177  /** Pose inverse compose operator: RES = A (-) B , computing both the mean and the covariance */
178  CPosePDFGaussian BASE_IMPEXP operator -( const CPosePDFGaussian &a, const CPosePDFGaussian &b );
179 
180  /** Dumps the mean and covariance matrix to a text stream. */
181  std::ostream BASE_IMPEXP & operator << (std::ostream & out, const CPosePDFGaussian& obj);
182 
183  /** Returns the Gaussian distribution of \f$ \mathbf{C} \f$, for \f$ \mathbf{C} = \mathbf{A} \oplus \mathbf{B} \f$. */
185 
186  bool BASE_IMPEXP operator==(const CPosePDFGaussian &p1,const CPosePDFGaussian &p2);
187 
188  } // End of namespace
189 } // End of namespace
190 
191 #endif
CPosePDFGaussian(const CPosePDF &o)
Copy constructor, including transformations between other PDFs.
CPose2D mean
The mean value.
A gaussian distribution for 2D points.
#define MRPT_OVERRIDE
C++11 "override" for virtuals:
GLenum GLint ref
Definition: glext.h:3888
mrpt::math::TPoint2D BASE_IMPEXP operator+(const CPose2D &pose, const mrpt::math::TPoint2D &pnt)
Compose a 2D point from a new coordinate base given by a 2D pose.
Definition: CPose2D.cpp:359
void saveToTextFile(const std::string &file, mrpt::math::TMatrixTextFileFormat fileFormat=mrpt::math::MATRIX_FORMAT_ENG, bool appendMRPTHeader=false, const std::string &userHeader=std::string()) const
Save matrix to a text file, compatible with MATLAB text format (see also the methods of matrix classe...
GLsizei GLsizei GLuint * obj
Definition: glext.h:3902
const CPose2D & getPoseMean() const
mrpt::math::CMatrixDouble33 cov
The 3x3 covariance matrix.
void getCovarianceAndMean(mrpt::math::CMatrixDouble33 &out_cov, CPose2D &mean_point) const MRPT_OVERRIDE
Returns an estimate of the pose covariance matrix (3x3 cov matrix) and the mean, both at once...
Declares a class that represents a Probability Density function (PDF) of a 2D pose ...
Eigen::Matrix< typename MATRIX::Scalar, MATRIX::ColsAtCompileTime, MATRIX::ColsAtCompileTime > cov(const MATRIX &v)
Computes the covariance matrix from a list of samples in an NxM matrix, where each row is a sample...
Definition: ops_matrices.h:135
CPosePDFGaussian(const CPose3DPDF &o)
Copy constructor, including transformations between other PDFs.
CPose2D BASE_IMPEXP operator-(const CPose2D &p)
Unary - operator: return the inverse pose "-p" (Note that is NOT the same than a pose with negative x...
Definition: CPose2D.cpp:307
GLubyte g
Definition: glext.h:5575
Eigen::Matrix< dataType, 4, 4 > inverse(Eigen::Matrix< dataType, 4, 4 > &pose)
Definition: Miscellaneous.h:74
GLubyte GLubyte b
Definition: glext.h:5575
#define DEFINE_SERIALIZABLE_PRE_CUSTOM_BASE(class_name, base_name)
This declaration must be inserted in all CSerializable classes definition, before the class declarati...
GLsizei const GLchar ** string
Definition: glext.h:3919
Declares a class that represents a probability density function (pdf) of a 2D pose (x...
Definition: CPosePDF.h:39
This is the global namespace for all Mobile Robot Programming Toolkit (MRPT) libraries.
#define DEFINE_SERIALIZABLE(class_name)
This declaration must be inserted in all CSerializable classes definition, within the class declarati...
bool operator==(const CPoint< DERIVEDCLASS > &p1, const CPoint< DERIVEDCLASS > &p2)
Definition: CPoint.h:130
A class used to store a 2D pose, including the 2D coordinate point and a heading (phi) angle...
Definition: CPose2D.h:36
A class used to store a 3D pose (a 3D translation + a rotation in 3D).
Definition: CPose3D.h:72
void getMean(CPose2D &mean_pose) const MRPT_OVERRIDE
Returns an estimate of the pose, (the mean, or mathematical expectation of the PDF).
#define DEFINE_SERIALIZABLE_POST_CUSTOM_BASE(class_name, base_name)
GLenum GLint x
Definition: glext.h:3516
Lightweight 2D point.
GLubyte GLubyte GLubyte a
Definition: glext.h:5575
Declares a class that represents a Probability Density Function (PDF) of a 3D pose (6D actually)...
Definition: CPose3DPDF.h:40
EIGEN_STRONG_INLINE double mean() const
Computes the mean of the entire matrix.
std::ostream & operator<<(std::ostream &o, const CPoint< DERIVEDCLASS > &p)
Dumps a point as a string [x,y] or [x,y,z].
Definition: CPoint.h:106



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