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gtsam/cpp/GaussianFactorGraph.h

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/**
* @file GaussianFactorGraph.h
* @brief Linear Factor Graph where all factors are Gaussians
* @author Kai Ni
* @author Christian Potthast
* @author Alireza Fathi
*/
// $Id: GaussianFactorGraph.h,v 1.24 2009/08/14 20:48:51 acunning Exp $
// \callgraph
#pragma once
#include <boost/shared_ptr.hpp>
#include "FactorGraph.h"
#include "GaussianFactor.h"
#include "GaussianBayesNet.h" // needed for MATLAB toolbox !!
namespace gtsam {
class Ordering;
/**
* A Linear Factor Graph is a factor graph where all factors are Gaussian, i.e.
* Factor == GaussianFactor
* VectorConfig = A configuration of vectors
* Most of the time, linear factor graphs arise by linearizing a non-linear factor graph.
*/
class GaussianFactorGraph : public FactorGraph<GaussianFactor> {
public:
/**
* Default constructor
*/
GaussianFactorGraph() {}
/**
* Constructor that receives a Chordal Bayes Net and returns a GaussianFactorGraph
*/
GaussianFactorGraph(const GaussianBayesNet& CBN);
/** Add a null factor */
inline void add(const Vector& b) {
push_back(sharedFactor(new GaussianFactor(b)));
}
/** Add a unary factor */
inline void add(const std::string& key1, const Matrix& A1,
const Vector& b, double sigma) {
push_back(sharedFactor(new GaussianFactor(key1,A1,b,sigma)));
}
/** Add a binary factor */
inline void add(const std::string& key1, const Matrix& A1,
const std::string& key2, const Matrix& A2,
const Vector& b, double sigma) {
push_back(sharedFactor(new GaussianFactor(key1,A1,key2,A2,b,sigma)));
}
/** Add a ternary factor */
inline void add(const std::string& key1, const Matrix& A1,
const std::string& key2, const Matrix& A2,
const std::string& key3, const Matrix& A3,
const Vector& b, double sigma) {
push_back(sharedFactor(new GaussianFactor(key1,A1,key2,A2,key3,A3,b,sigma)));
}
/** Add an n-ary factor */
inline void add(const std::vector<std::pair<std::string, Matrix> > &terms,
const Vector &b, double sigma) {
push_back(sharedFactor(new GaussianFactor(terms,b,sigma)));
}
/** unnormalized error */
double error(const VectorConfig& c) const {
double total_error = 0.;
// iterate over all the factors_ to accumulate the log probabilities
for (const_iterator factor = factors_.begin(); factor != factors_.end(); factor++)
total_error += (*factor)->error(c);
return total_error;
}
/** Unnormalized probability. O(n) */
double probPrime(const VectorConfig& c) const {
return exp(-0.5 * error(c));
}
/**
* find the separator, i.e. all the nodes that have at least one
* common factor with the given node. FD: not used AFAIK.
*/
std::set<std::string> find_separator(const std::string& key) const;
/**
* Eliminate a single node yielding a conditional Gaussian
* Eliminates the factors from the factor graph through findAndRemoveFactors
* and adds a new factor on the separator to the factor graph
*/
GaussianConditional::shared_ptr eliminateOne(const std::string& key);
/**
* eliminate factor graph in place(!) in the given order, yielding
* a chordal Bayes net. Allows for passing an incomplete ordering
* that does not completely eliminate the graph
*/
GaussianBayesNet eliminate(const Ordering& ordering);
/**
* optimize a linear factor graph
* @param ordering fg in order
*/
VectorConfig optimize(const Ordering& ordering);
/**
* shared pointer versions for MATLAB
*/
boost::shared_ptr<GaussianBayesNet> eliminate_(const Ordering&);
boost::shared_ptr<VectorConfig> optimize_(const Ordering&);
/**
* static function that combines two factor graphs
* @param const &lfg1 Linear factor graph
* @param const &lfg2 Linear factor graph
* @return a new combined factor graph
*/
static GaussianFactorGraph combine2(const GaussianFactorGraph& lfg1,
const GaussianFactorGraph& lfg2);
/**
* combine two factor graphs
* @param *lfg Linear factor graph
*/
void combine(const GaussianFactorGraph &lfg);
/**
* Find all variables and their dimensions
* @return The set of all variable/dimension pairs
*/
Dimensions dimensions() const;
/**
* Add zero-mean i.i.d. Gaussian prior terms to each variable
* @param sigma Standard deviation of Gaussian
*/
GaussianFactorGraph add_priors(double sigma) const;
/**
* Return (dense) matrix associated with factor graph
* @param ordering of variables needed for matrix column order
*/
std::pair<Matrix,Vector> matrix (const Ordering& ordering) const;
/**
* get the starting column indices for all variables
* @param ordering of variables needed for matrix column order
* @return The set of all variable/index pairs
*/
Dimensions columnIndices(const Ordering& ordering) const;
/**
* Return 3*nzmax matrix where the rows correspond to the vectors i, j, and s
* to generate an m-by-n sparse matrix, which can be given to MATLAB's sparse function.
* The standard deviations are baked into A and b
* @param ordering of variables needed for matrix column order
*/
Matrix sparse(const Ordering& ordering) const;
/**
* Calculate Gradient of 0.5*|Ax-b| for a given config
* @param x: VectorConfig specifying where to calculate gradient
* @return gradient, as a VectorConfig as well
*/
VectorConfig gradient(const VectorConfig& x) const;
/**
* Take an optimal step in direction d by calculating optimal step-size
* @param x: starting point for search
* @param d: search direction
*/
VectorConfig optimalUpdate(const VectorConfig& x0, const VectorConfig& d) const;
/**
* Find solution using gradient descent
* @param x0: VectorConfig specifying initial estimate
* @return solution
*/
VectorConfig gradientDescent(const VectorConfig& x0) const;
/**
* shared pointer versions for MATLAB
*/
boost::shared_ptr<VectorConfig>gradientDescent_(const VectorConfig& x0) const;
/**
* Find solution using conjugate gradient descent
* @param x0: VectorConfig specifying initial estimate
* @return solution
*/
VectorConfig conjugateGradientDescent(const VectorConfig& x0) const;
/**
* shared pointer versions for MATLAB
*/
boost::shared_ptr<VectorConfig> conjugateGradientDescent_(const VectorConfig& x0) const;
};
}
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